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Review

Cytotoxic and Cytolytic Cnidarian Venoms. A Review on Health Implications and Possible Therapeutic Applications

Department of Earth, Environment and Life Sciences, University of Genova, Viale Benedetto XV 5, Genova I-16132, Italy
*
Author to whom correspondence should be addressed.
Toxins 2014, 6(1), 108-151; https://doi.org/10.3390/toxins6010108
Submission received: 5 November 2013 / Revised: 11 December 2013 / Accepted: 13 December 2013 / Published: 27 December 2013
(This article belongs to the Collection Marine and Freshwater Toxins)

Abstract

:
The toxicity of Cnidaria is a subject of concern for its influence on human activities and public health. During the last decades, the mechanisms of cell injury caused by cnidarian venoms have been studied utilizing extracts from several Cnidaria that have been tested in order to evaluate some fundamental parameters, such as the activity on cell survival, functioning and metabolism, and to improve the knowledge about the mechanisms of action of these compounds. In agreement with the modern tendency aimed to avoid the utilization of living animals in the experiments and to substitute them with in vitro systems, established cell lines or primary cultures have been employed to test cnidarian extracts or derivatives. Several cnidarian venoms have been found to have cytotoxic properties and have been also shown to cause hemolytic effects. Some studied substances have been shown to affect tumour cells and microorganisms, so making cnidarian extracts particularly interesting for their possible therapeutic employment. The review aims to emphasize the up-to-date knowledge about this subject taking in consideration the importance of such venoms in human pathology, the health implications and the possible therapeutic application of these natural compounds.

1. Introduction

In natural environments a lot of toxic substances are produced by organisms for defense/offence purposes. These compounds can have an impact on ecosystem functioning, on competition among species, as well as on some human activities and public health; nevertheless, in spite of this, several of them were seen to have potentially useful pharmacological properties. In particular, in aquatic environments, the biodiversity and the associated chemical diversity can be a practically unlimited source of new bioactive substances useful in developing new drugs [1].
In this framework, the interest around marine venoms has increased during the last three to four decades, even though to date their mechanism of action is still largely unknown and under debate [2].
Cnidarians are responsible for envenomations occurring during some human activities carried out in the marine environment, both in work situations, such as fishing, and recreational ones, such as bathing; these problems involve the management of public health and are especially connected to jellyfish outbreaks occurring in coastal marine ecosystems on a global scale [3]. Cnidarians are well known producers of complex mixtures of proteinaceous venoms used for defence as well as for prey capture [4], contained in capsules of protein nature—the nematocysts, which are secretory products of the Golgi apparatus synthesized by high specialized cells called nematocytes [5]. The capsule contains a tightly wrapped and spiralized thread which is extruded under adequate physico-chemical stimuli, injecting the venom in the prey or in the attacker. Cnidarian stinging can induce local and systemic symptoms and pose a serious threat to human health along Asian and Australian coasts as well as in tropical oceanic waters where extremely venomous jellyfish and anemones able to induce severe and also lethal envenomations are common. The damage induced by cnidarian venoms has been essentially ascribed to a pore formation mechanism or to oxidative stress [2].
In spite of their toxicity, Cnidaria have long been indicated as a potential source of natural bioactive compounds of pharmacological concern useful to develop new drugs or biomedical materials [6]. Some bioactive substances, such as prostaglandins (15R)-PGA2 from the gorgonian Plaxaura homomalla [7], the Palytoxin local anaesthetic and vasoconstrictive agent from the zoanthid Palythoa toxica [8], Pseudopterosin [9], Sarcodictyns and Eleutherobin have been discovered in these organisms. Hence, during recent decades, the interest for the biology and utilization of cnidarians has grown and a number of metabolites, anticancer and antioxidant compounds have been isolated in the interest of human health [3], and have been seen to have activity at the cellular level, making them a possible source of new drugs. Therefore, taking into account the modern tendency to utilize cultured cells in the research with the view to lower the need for in vivo experimentation, the aim of this paper is to review the up-to-date knowledge about the in vitro cytotoxicity of cnidarian venoms emphasizing their mechanisms of action and their possible therapeutic application against neurologic, haematologic, infectivologic and oncologic diseases, as well as their hemolytic properties.

2. Hemolytic Effects of Cnidarian Venoms

The hemolytic effects of some cnidarian venoms are long known [6]. During the second half of the last Century hemolysins have been recognized in the box jellyfish [10,11,12] in the Portuguese Man-of-War [13], in sea anemones [14,15,16,17,18], and in other Cnidaria [19,20]; the role of phospholipases in the hemolytic activity of cnidarian venoms was also emphasized [21]. To date, the research on the hemolytic effects of Cnidaria is focused mainly on Anthozoans (sea anemones, soft corals), Scyphozoans and Cubozoans and several species are known to be responsible for the cytolytic effects on different mammalian red blood cells (RBC). Other species have been considered in a recent paper [22] that concened the hemolysis induced in sheep RBC after treatment with extracts from the anthomedusan Pandea rubra, the trachimedusae Arctapodema sp., Colobonema sericeum, Crossota rufobrunnea, Halicreas minimum and Pantachogon haeckeli, the narcomedusae Aeginura grimaldii, Aegina citrea and Solmissus sp. and the scyphozoan Coronatae Atolla vanhoeffeni, Atolla wyvillei and Periphylla periphylla; only extracts from Arctapodema sp., Colobonema sericeum, and Crossota rufobrunnea were reported to be actively cytolytic with ED50 values of 110, 190 and 100 mg/mL, respectively.

2.1. Hemolytic Sea Anemone (Anthozoa) Venoms

In a comprehensive review, Anderluh and Maček [23] indicated that “more than 32 species of sea anemones have been reported to produce lethal cytolytic peptides and proteins” and classified the cytolysins into four polypeptide groups: I (5–8 kDa peptides) that are able to make pores in membranes containing phosphatidylcholine; II (20 kDa actinoporins) that typically associate with membranes containing sphingomyelin making cation-selective pores; III that includes lethal 30–40 kDa cytolytic phospholipases A2; IV including only metridiolysin from Metridium senile (80 kDa), a thiol-activated cytolysin inhibited by cholesterol or phosphatides [23].
In the late 1980s, a hemolytic toxin acting at the membrane level and having phospholipase activity was isolated from the sea anemone Stoichactis helianthus; its conjugate with an antibody towards IOR-T6 antigen expressed on immature T lymphocytes was tested as a potential anti-cancer agent. The hybrid molecule (IOR-T6-HT) did not exhibit hemolytic activity unless it was reduced, but was toxic for cells (CEM) expressing the IOR-T6 antigen and non-toxic for cells (K562) not bearing the antigen [24]. Subsequently, the basic protein UpI isolated from crude extract from Urticina piscivora was found to be hemolytic at concentrations as low as 10−10 M on rat, guinea pig, dog, pig and human RBC; this result was confirmed also through scanning electron microscopy observations that evidenced structural damage to rat and guinea pig RBC membranes. Sphingomyelin but not cholesterol was able to inhibit hemolytic effects in a concentration-dependent manner [25].
The importance of the N-terminal amphiphilic α-helix for the functionality of actinoporins was reported for the recombinant hemolytic Src I from the sea anemone Sagartia rosea; in fact, notwithstanding Src I was found to be strongly hemolytic (50% red blood cells lysed at a concentration of 0.43 μg/mL), the occurrence of an additional peptide at the N-terminus of Src I decreases the hemolytic activity of the fusion protein Trx-Src I, because the N-terminal α-helix of cytolysins, being strongly amphipathic, interacts with lipid membranes [26].
Recent results indicate that the crude venom from the sea anemone Aiptasia mutabilis has dose-response hemolytic effects against human erythrocytes probably due to a pore-forming mechanism that can be prevented by Ca2+, Ba2+ and Cu2+, papain and polyethylenglycole and to a minor extent by Mg2+ and K+ treatment [27].

2.2. Hemolytic Octocoral (Anthozoa) Venoms

Eunicellin-type diterpenoids Litophynols A and B, litophynins E and H, and I monoacetate from the mucus of the soft coral Litophyton sp. (Alcyonacea) were found to have hemolytic properties on a 2% rabbit erythrocyte suspension [28]. Recently a hemolytic toxin was identified in the soft coral Sarcophyton trocheliophorum (Alcyonacea); the crude extract was highly cytotoxic (EC50 = 50 ng/mL) against human erythrocytes and haemolytic, with a halo of 12 mm caused by 50 μg of protein. The hemolysis was observed to be increased in condition of alkaline and neutral pH and reduced at acidic pH; furthermore, hemolysis is reduced after toxin treatment with freezing-thawing cycles [29]. A modified steroid (18-acetoxipregna-1,4,20-trien-3-one) isolated from Carijoa riisei was shown to be not hemolytic at 12.5 μg/mL and slightly hemolytic (2.3% and 6%) at 25 μg/mL and 50 μg/mL, respectively [30].

2.3. Hemolytic Cubozoan Venoms

The hemolytic properties of cubozoans are long known [10]. In a comprehensive review about cubozoan cytolysins, Brinkman and Burnell [31] reported that three highly toxic lethal and hemolytic proteins (CrTX-I, CrTX-II and CrTX-III) were isolated from tentacle extracts of Carybdea rastoni and described; these proteins induced platelet aggregation, acted as calcium-dependent vasoconstrictors and damaged the uptake/storage mechanisms of noradrenaline [32,33,34]. In the 1990s haemolytic factors were partially purified from Carybdea rastoni [35] and furthermore a 107 kDa cytolysin from Carybdea marsupialis—CARTOX—lacking phospholipase C activity and acting as a pore-forming protein was found to be hemolytic to sheep erythrocytes [36]. From specimens collected in the Caribbean Sea, three cytolysins (220, 139 and 36 kDa) hemolytic to human erythrocytes were recently isolated [37].
The hemolytic properties of Carybdea alata venom were attributed to a protein (CAH1) with an apparent mass of 42 kDa which was subsequently purified studying sheep RBCs [38]; the same research group supposed that the hemolysis by CAH1 involves an initial docking or binding with cell surface carbohydrates or phospholipid groups [39]. An haemolysin has been isolated from Chiropsalmus quadrigatus [40] and two hemolytic proteins having a sigmoidal dose-response curve activity were isolated from Chironex fleckeri [41,42]; this species has several haemolysins with varied molecular masses [31].

2.4. Hemolytic Scyphozoan Venoms

Among Scyphozoans, the cytolytic action of venom of the common marine Mediterranean jellyfish Rhizostoma pulmo was analysed. After soaking of jellyfish oral arms in distilled water two fractions were obtained: the first, rich in nematocysts was discarded, while the second, free of organelles and considered the extranematocystic portion, was tested on human RBC observing a low hemolytic activity [43] and subsequently analyzed by HPLC. Five peaks (a–e) were isolated by C18 preparative column, and the high molecular weight fractions were eluted by countercurrent technique with a flow rate of 5 mL/min. The cytolytic activity was evaluated on human RBC by both turbidity decrease test (at 700 nm) and haemoglobin release (at 418 nm) on 0.05% erythrocyte suspensions in 0.02 M tris-HCl buffer, containing 10 mM CaCl2 at pH 7.4. A concentration of 32 μg/mL of toxin induced complete hemolysis of erythrocytes in 10 min, thus suggesting a good capacity for binding to membranes [44].
The hemolytic activity of the giant jellyfish Nemopilema nomurai (Rhizostomeae) was assessed on cat, dog, human, rabbit and rat erythrocytes and showed a concentration-dependent activity starting from 10 μg/mL of protein equivalents; dog erythrocytes were the most sensitive (EC50 = 151 μg/mL) [45].
Purified cnidocyst extracts from fishing and mesenteric tentacles of Cyanea capillata (Semaeostomeae) induced hemolysis on human RBC with a difference between extracts coming from smaller or larger specimens. A complete hemolysis was caused by extracts (20 μg/well) from fishing tentacles of C. capillata with an umbrella diameter larger than 20 cm [46]. Furthermore, the erythrocyte lysis (HE50) induced by crude venom from mesenteric tentacles of large jellyfish was greater (98 μg/mL) than that induced from small medusae extracts (177 μg/mL). Therefore, the size of fishing tentacles and of oral arms, and nematocyst (A-isorhizas and O-isorhizas) number and size that correspond to the size of umbrella, were correlated with the cytolytic potency in differently-sized Cyanea capillata (L.) showing that the greater the specimen, the higher the produced hemolysis [47]. A concentration-dependent increase of hemolysis induced by extracts from Cyanea capillata tentacles was observed also in rat erythrocytes in the presence of Ca2+; this increase was attenuated by Ca2+ channel blockers such as Diltiazem, Verapamil and Nifedipine [48]. The hemolytic activity of extracts from Cyanea lamarckii was documented recently; the nematocystic extracts from mesenteric tentacles caused strong hemolytic effects, while extracts from fishing tentacles were less active [46].
The crude venom from Pelagia noctiluca was shown to induce hemolysis of chicken and rabbit but was not effective on fish red blood cells [49]. The hemolytic properties of P. noctiluca venom could be due to a pore-forming mechanism [50] and can be counteracted by osmotic protectants, such as carbohydrates, cations, proteases and antioxidants [51].
The proteic fractions responsible for the hemolytic properties of the nematocystic crude venom from Pelagia noctiluca were recently underlined [52] using teleost (Carassius auratus, freshwater; Liza aurata, marine) RBC. The nematocyst venom was used at various concentrations to evaluate the hemolytic activity and the stability of lysosomal membrane. Sphyngomyelin was shown to strongly inhibit the hemolytic activity. SDS-PAGE electrophoresis and high performance liquid chromatography (HPLC) showed that at least four protein fractions represent the active hemolytic components of crude venom. The crude venom from Pelagia noctiluca induced also lysosomal membrane destabilisation of fish RBC in both species; on the whole, Carassius auratus was more susceptible to jellyfish venom than Liza aurata. Contrary to what was reported in other articles, the authors state that crude venom does not cause oxidative stress because significant differences in glutathione (GSH) levels were not observed between control and treated cells, but it recognizes specific targets, such as sphyngomyelin, in RBC plasmatic membrane [52].

3. Cytotoxicity of Cnidarian Extracts on Cultured Cells

3.1. Cytotoxicity of Extracts from Octocorallia (Anthozoa)

Extracts from soft corals and gorgonians (Anthozoa: Octocorallia) have been widely studied and several of them were found to affect growth and survival of cultured cells.
A number of papers concerned the study of extracts from Clavularia spp. (Alcyionacea). In the early 1980s, clavulones derived from the Japanese stolonifer Clavularia viridis were identified [53] and studied later for their activity on the growth of human cancer (HL-60 and HeLa) and normal (liver and lung fibroblasts) cultured cells found to be highly effective for antiproliferative and cytotoxic activity against HL-60 (IC50 = 0.4 μM or 0.2 μg/mL) and HeLa cells (significant cytotoxicity over 1.0 μM or 0.5 μg/mL); furthermore, clavulone was able to block the cells in G1-phase and to affect cell growth of HL-60 cells by inhibiting S-phase DNA synthesis [54]. Halogenated prostanoids (chlorovulone, bromovulone, and iodovulone) from Clavularia viridis were tested for antiproliferative and cytotoxic activities in cultured leukemic HL-60 cells; chlorovulone (IC50 growth inhibition = 0.03 μM or 0.01 μg/mL; cytotoxic effects >0.3 μM or 0.1 μg/mL) was highly effective being its activity stronger than that of prostaglandin A2; bromovulone and iodovulone showed comparable cytotoxic properties. The authors stated that “chlorovulone I transiently arrested the cell cycle progression from G1 to S after 24-h exposure to nontoxic concentrations (0.03 and 0.09 μM) and caused the lasting blockade of leukemia cells in G1 at the cytotoxic concentration” [55].
Marine diterpenoids (stolonidol and stolonidol monoacetate) isolated from Clavularia sp. showed strong cytotoxicity against P388 leukemia cells (both IC50s = 0.015 μg/mL); claenone, isolated from the same coral, was found to inhibit fertilized sea urchin (Pseudocentrotus depressus) eggs at a concentration of 2 μg/mL [56]. The induction of choline acetyl transferase (ChAT) by stolonidiol from Clavularia sp. was observed in cultured rat basal forebrain cells and in mouse clonal septal SN49 cells, a hybridoma cell line derived from primary cultured mouse basal forebrain cells [57]. This ChAT inducible activity on both primary cultures of cholinergic neurons and hybridoma suggested that stolonidol could act as a neurotrophic factor-like agent on the cholinergic nervous system.
Subsequently, Watanabe et al. [58] isolated five new halogenated prostanoids from Clavularia viridis; one of them was cytotoxic for human T lymphocyte leukemia cells (MOLT-4), human colorectal adenocarcinoma cancer cells (DLD-1), and human lung fibroblast (IMR-90) with IC50s of 0.52, 0.6, and 4.5 μg/mL, respectively.
A diterpene compound obtained through chromatography from the Formosan soft coral Clavularia inflata was found to be strongly cytotoxic to A-549, HT-29, and P-388 cell lines (ED50 values = 0.57, 0.31, and 0.052 μg/mL, respectively). Other five compounds were moderately cytotoxic to P-388 cells and little or nothing cytotoxic to A-549 and HT-29 cells [59].
The diterpene Sinugibberol extracted from Silularia gibberosa induced significant cytotoxicity to HT29 cells (ED50 = 0.5 μg/mL) and less damage to P388 cells (ED50 = 11.7 μg/mL) [60]. Iwashima et al. [61] isolated seven new diterpenoids having a cembrane skeleton from the Okinawan soft coral Clavularia koellikeri; One of these compounds (Compound 1) resulted cytotoxic to human colorectal adenocarcinoma cells (DLD-1), with an IC50 value of 4.2 μg/mL and a complete growth inhibition at 0.6 μM/mL, and affected the growth of MOLT-4 human T lymphocytic leukemia cells (IC50 = 0.9 μg/mL); similar results on the same cell lines were reported also for the diterpenoids kericembrenolides D and F.
Mild cytotoxic activity was pointed out for a briariane diterpene lactone isolated from the New Guinean gorgonian Solenopodium excavatum that induced mild cytotoxicity (ED50 = 23 μg/mL) to P388 cells [62]. The diterpenoids echinoclerodane A and echinolabdane A were isolated from the Formosan gorgonian coral Echinomuricea sp. (Alcyonacea); echinoclerodane A was shown to exhibit moderate cytotoxicity against cultured MOLT-4 (human acute lymphoblastic leukemia), HL-60 (human acute promyelocytic leukemia), DLD-1 (human colorectal adenocarcinoma) and LoVo (human colorectal adenocarcinoma) cells, while K562 (human erythromyeloblastoid leukemia) and DU-145 (human prostate carcinoma) cells showed higher IC50 values. A moderate inhibition (35.4%) of elastase release by human neutrophils was observed at 10 μg/mL of Echinoclerodane A [63]. Echinolabdane A, a labdane-type diterpenoid derived from Echinomuricea sp. collected off the coast of southern Taiwan, was weakly cytotoxic in vitro for human acute promyelocytic leukemia cells HL-60 (IC50 = 19.1 μg/mL), and mildly inhibited superoxide anions generation by human neutrophils (inhibiting concentration IC50 > 10 μg/mL; percentage of inhibition at 10 μg/mL = 2.52 ± 3.02) as well as elastase release (IC50 =>10.0; percentage of inhibition = 1.83 ± 3.46) [64]. On the contrary, the sterol 6-epi-yonarasterol B isolated from the same coral significantly inhibited the generation of superoxide anions by human neutrophils (IC50 = 2.98 ± 0.29 μg/mL; percentage of inhibition = 89.76 ± 5.63) and the release of elastase (IC50 = 1.13 ± 0.55 μg/mL; percentage of inhibition = 95.54 ± 6.17 [64].
Steroids extracted from the gorgonian Plexaurella grisea were tested on tumour cell lines P 388 (mouse lymphoid neoplasm), A 549 (human lung carcinoma) and HT 29 (human colon carcinoma); some compounds showed a selective activity against HT 29 cells (ED50 = 0.1 μg/mL) [65]. The same research group reported that the organic extract of Plexaurella grisea specimens from Punta Cana (Dominican Republic) exhibited cytotoxicity against mouse lymphoma P-388, human lung carcinoma A-549, and human colon carcinoma HT-29 (IC50 = 2.5 μg/mL) cells, and described new compounds: five acyclic sesquiterpenes, namely (3E,5E)-3,7,11-trimethyl-9-oxododeca-1,3,5-triene (compound 3), (3Z,5E)-3,7,11-trimethyl-9-oxododeca-1,3,5-triene (compound 4), (3E)-6-acetoxy-3,11-dimethyl-7-methylidendodeca-1,3,10-triene (compound 5), (3E,5E)-7-hydroxy-3,7,11-trimethyldodeca-1,3,5,10-tetraene (compound 6), and (3E,5E,9E)-8,11-diacetoxy-3,7,11-trimethyldodeca-1,3,5,9-tetraene (compound 7), and two linear norsesquiterpenes, namely (2E,4E,7Z)-2,6,10-trimethylundeca-2,4,7,9-tetraenal (compound 8) and (2E,4E)-2,6,10-trimethylundeca-2,4,9-trienal (compound 9). Compounds 3, 4, 5, 8, and 9, were tested for cytotoxicity against P-388 mouse lymphoma cells, A-549 human lung carcinoma cells, HT-29 human colon carcinoma cells, and MEL-28 human melanoma cells. Compound 9 showed the greatest cytotoxic potential and was selective for P-388 cells (IC50 = 0.5 μg/mL), compound 8 resulted inactive (IC50 > 10 μg/mL), while other compunds induced mild cytotoxicity with IC50 values ranging from 2.5 to 5 μg/mL [66].
As concerns the cytotoxicity of Alcyoniidae derivatives, studies carried out in the late 1990s report that singardin, a heptacyclic norcembranoid dimer and the sesquiterpene guaianediol from Sinularia gardineri, showed cytotoxicity to murine leukemia P-388 (1 μg/mL), human lung carcinoma A-549 (2.5 μg/mL), human colon carcinoma HT-29 (5 μg/mL), and human melanoma MEL-28 (5 μg/mL) cells. Singardin was found also to have weak antifungal activity against Candida albicans and Cryptococcus neoformans [67]. Furthermore, an acylated spermidine isolated from the Pacific soft coral Sinularia sp. was found to be cytotoxic to P-388 cells (ED50 = 0.04 μg/mL) [68]. It is noteworthy that as early as the late 1970s, aqueous alcohol extracts and cembranolides extracted from Sinularia flexibilis were observed to have antineoplastic activity against P-388 lymphocytic leukemia [69]. Studies on cembranoid diterpenes sinuflexolide, dihydrosinuflexolide, and sinuflexibilin from Sinularia flexibilis were carried out by Duh et al. [70]; sinuflexolide and sinuflexibilin were significantly cytotoxic for A549, HT-29, KB, and P-388 cells (ED50 ranging from 0.16 to 1.73 μg/mL), while dihydrosinuflexolide affected significantly the growth of P-388 cells (ED50 = 3.86 μg/mL). Sphingolipids extracted from Sinularia leptoclados were found to have not cytotoxic properties in vitro against Vero cells at a concentration of 2 mg/mL and africanene from the same cnidarian exhibited in vitro cytotoxicity against DLAT (Dalton’s lymphoma ascites tumour) and EAC (Ehrlich ascites carcinoma) cells killing all treated cells at concentrations of >10 and >20 μg/mL, respectively [71]. Hexane extracts from Sinularia inelegans showed significant cytotoxicity against human lung adenocarcinoma (A549) and mouse lymphocytic leukemia (P-388) cells; a lobane diterpene (ineleganene) isolated from these extracts exhibited cytotoxicity against A549 cells (GI50 = 3.63 μg/mL) and P-388 cells (GI50 = 0.20 μg/mL) [72]. The cembranolide Capillolide from the soft coral Sinularia capillosa showed moderate cytotoxic activity against P-388 and L1210 cells with ED50 values of 15.0 and 18.5 μg/mL, respectively; other cembranolides gave ED50 values ranging from 1.5–10.0 μg/mL [73]. Recently, the cytotoxicity of cembranoids extracted from Sinularia discrepans was determined to human T-cell acute lymphoblastic leukemia (CCRF-CEM) and human colon adenocarcinoma (DLD-1) cells but neither cytotoxic activity nor growth inhibition (all IC50 > 20 μg/mL) were shown by these compounds. In addition, the anti-inflammatory activity in vitro of metabolites of such cembranoids was assessed using a macrophage cell line (RAW264.7). The inhibition of lipopolysaccharide (LPS)-induced up-regulation of inducible nitric oxide synthetase (iNOS) and cyclooxygenase-2 (COX-2) pro-inflammatory proteins in macrophages was examined and reduced levels of iNOS in comparison with controls (stimulated with LPS alone) as well as reducton of COX-2 expression induced by one of metabolites (named compound 5) were observed at the concentration of 10 μM. Thus, the possibility to utilize these compounds as anti-inflammatory agents was suggested [74].
Strong cytotoxicity on cells established from DBA/MC fibrosarcoma was exhibited by lemnalone, a ketone derivative of the sesquiterpenoid lemnalol isolated from the soft coral Lemnalia tenuis [75] and the antiinflammatory properties of Lemnalol (8-isopropyl-5-methyl-4-methylene-decahydro-1,5-cyclo-naphthalen-3-ol) isolated from Lemnalia cervicorni were investigated in lipopolysaccharide (LPS)-stimulated RAW 264.7 cells (murine macrophages). This natural compound was seen to inhibit significantly the expression of pro-inflammatory proteins, inducible nitric oxide synthase (iNOS) and cyclooxygenase-2 (COX-2) [76].
Cembrenolide diterpenes (sarcocrassolide, crassolide, 13-acetoxysarcocrassolide, denticulatolide), isolated by Duh et al. [77] from the soft coral Sarcophyton crassocaule Moser (Alcyoniidae) exhibited strong cytotoxicity against P-388 (mouse lymphocytic leukemia) cells showing ED50 values ranging from 0.14 to 0.38 μg/mL. The same effect was recorded for the steroid (24S)-24-methylcholestane-3β,5α,6β-triol whose ED50 accounted to 0.14 μg/mL. The growth inhibition induced by these compounds on other cell lines, A549 (human lung adenocarcinoma), HT-29 (human colon adenocarcinoma), and KB (human epidermoid carcinoma) was less effective, with ED50s ranging from 4.29 to 9.15 μg/mL. Another steroid (24ξ-methylcholestane-3β,5α,6β,25-tetraol-25-monoacetate) furnished higher ED50 values and was effective only on P-388 (3.96 μg/mL) and HT-29 (4.32 μg/mL) cells [77]. In a contemporary study, 10 different compounds extracted from the soft coral Sarcophyton trocheliophorum were tested for cytotoxicity on a panel of three cell lines, HL60 (human leukemia), M14 (skin melanoma), MCF7 (breast carcinoma), and on normal human peripheral blood lymphocytes; only polyhydroxysterol, 23,24-dimethylcholest-16(17)-E-en-3β,5α,6β,20(S)-tetraol caused strong cytotoxicity on cell lines with EC50 values ranging from 2.8 (HL60) to 4.9 (MCF7) μg/mL and exhibited weak toxicity to human lymphocytes; other compounds showed higher EC50s ranging from 10.4 to >100 μg/mL [78].
The cytotoxicity of six metabolites extracted from the Taiwanese Gorgonian coral Subergorgia suberosa was tested to KB (human nasalpharyngeal carcinoma) and HeLa (cervix carcinoma) cancer cells; subergorgic acid methyl ester moderately inhibited the growth of HeLa cells (ED50 = 4.3 μg/mL) while the other metabolites resulted not cytotoxic (ED50 > 10 μg/mL) [79]. Wang et al. [80] from the same species isolated four β-caryophyllene-derived sesquiterpenes alcohols (suberosols A, B, C and D), and two β-caryophyllene-derived sesqueterpene ketones (buddledins C and D); all metabolites resulted cytotoxic to P-388 cells (mouse lymphocytic leukemia) with ED50 values ranging from 2.1 to 7.4 μg/mL. The other two cell lines, A549 (human lung adenocarcinoma) and HT-29 (human colon adenocarcinoma), were sensitive to suberosols C and D and to both buddlesins (ED50 ranges: 3.8–8.9 μg/mL and 2.3–6.6 μg/mL, respectively) but were not affected by treatment with suberosols A and B (ED50 values > 50 μg/mL).
Utilizing the same cell lines (P-388, A549, and HT-29), Wu et al. [81] studied the cytotoxicity of four polyoxygenated briarane-type diterpenoids (briaexcavatolides O, P, Q, R), isolated from the Taiwanese gorgonian Briareum excavatum (Gorgonaceae); one of these diterpenoids, Briaexcavatolide P, was found to be cytotoxic mainly to P-388 and HT-29 cancer cells (ED50s = 0.9 and 3.1 μg/mL, respectively) and was less active against A549 cells (ED50 = 4.8 μg/mL). The genus Briareum has been studied for cytotoxicity for decades. In fact, during the 1990s, crude extracts from Briareum asbestinum, a common inhabitant of shallow Caribbean reefs, were shown to be highly toxic to CHO-K1 cells at concentrations <25 μg/mL. Furthermore, four derivatives were significantly cytotoxic to the same cells with ED50 values of 3.35, 2.50, 3.55, and 4.82 μg/mL, respectively as well as active against Klebsiella pneumoniae [82]. Diterpenes 2β-acetoxy-2-(debutyryloxy)stecholide E, 9-deacetylstylatulide lactone, 4β-acetoxy-9-deacetylstylatulide lactone, brianthein W and 9-deacetylbriareolide H were isolated from the gorgonian Briareum sp.; their derivatives were found to be cytotoxic to P-388, KB, A-549, and HT-29 cancer cell lines [83]. Excavatolides A-E and brianolide from Briareum excavatum were studied for cytotoxicity. Three of them were found to be cytotoxic in particular to P-388 (ED50 = 0.3–1.8 μg/mL) but also to HT-29 (ED50 = 1.3–1.9 μg/mL) cancer cells and less effects were recorded against KB and A-549 cells [84]. Sung et al. [85] isolated eight new briarane-type diterpenes (excavatolides F-M) from the gorgonian Briareum excavatum. Only excavatolide M, with ED50 values ranging from 0.001 μg/mL (P-388) to 2.2 μg/mL (for HT-29) and excavatolide K, with ED50 values ranging from 0.9 μg/mL (for P-388) to 3.3 μg/mL (for KB), were cytotoxic to P-388, KB, A-549 and HT-29 cultured cells. Subsequently, Sung et al. [86] studied four new briarane diterpenes, briaexcavatolides K-N, and a known diterpene, compound 5, isolated from the Taiwanese gorgonian Briareum excavatum. Diterpenes K, M, and N resulted unactive for cytotoxicity against P-388 (mouse lymphocytic leukemia), A549 (human lung adenocarcinoma), and HT-29 (human colon adenocarcinoma) tumor cells; otherwise, Briaexcavatolide L was significantly cytotoxic to P-388 cells (ED50 = 0.5 μg/mL), and the compound 5 to both P-388 and HT-29 cells (ED50 = 0.4 and 1.1 μg/mL, respectively).
On the basis of the known lethality of crude extracts on brine shrimp (LC50 = 127 ppm) and cytotoxicity against P-388 cells (LC50 = 37 μg/mL), Rho et al. [87] isolated four new diterpenoids of the xenicane class (Acalycixeniolides C-F) from the gorgonian Acalycigorgia inermis. All compounds were cytotoxic to cultured human leukemia cells K562; Acalycixeniolide F showed the greatest cytotoxicity (LC50 = 0.2 μg/mL). The compounds C and E showed LC50 values of 1.6 and 4.7 μg/mL, respectively, while a weak cytotoxicity was shown by Acalycixeniolide D (LC50 = 52.0 μg/mL). The authors stated that Acalycixeniolide F “having a terminal dimethylvinyl moiety, exhibits cytotoxicity of an order of magnitude more potent than other xenicanes having an allene group at this position” and Acalycixeniolide D “bearing an α,β-unsaturated lactone group is considerably less active than the others” [87]. Subsequently, the same research group isolated eight diterpenes and norditerpenes, including five new xenicane metabolites (acalycixeniolides H-L), from the same gorgonian. 9-deoxyxeniolide A as well as the five new isolated compounds exhibited significant cytotoxicity to K562 human leukemia with LC50 values of 0.04, 3.9, 1.2, 2.0, 1.8, and 1.5 μg/mL, respectively; Acalycixeniolide E showed also antiangiogenic activity [88].
The soft coral Alcyonium patagonicum yielded a sterol (24-methylenecholest-4-ene-3β,6β-diol) that resulted cytotoxic against the P-388 cell line (IC50 = 1 μg/mL) [89]. Cytotoxic compounds were found also in subantarctic soft corals Alcyonium paessleri, a deep-living species collected near the South Georgia Islands. From this coral, 15 illudalane sesquiterpenoids, alcyopterosins A-O, were first isolated by Palermo et al. [90]; four of them were found to be mildly cytotoxic toward human tumor cell lines. Alcyopterosin A, C and H were effective against human colon carcinoma HT-29 cells with IC50 values of 10 μg/mL, and Alcyopterosin E affected human larynx carcinoma Hep-2 cells (IC50 = 13.5 μM) [90]. Another study reported that two sesquiterpenoids, paesslerins A and B, from the soft coral Alcyonium paessleri, showed moderate cytotoxicity against human tumor cell lines [91].
As concerns the genus Eunicea, four diterpenes (Edunone, Eduenone, Edudione and Edunol) isolated from the Caribbean gorgonian Eunicea laciniata showed weak cytotoxicity against HeLa cells with IC50 of 25, 50, 100 and 25 μg/mL, respectively [92] and diterpenoid cembranolides isolated from Eunicea mammosa were found to have moderate cytotoxicity against HeLa cells with IC50 values of 2.5 μg/mL for Uprolide D acetate, 5.0 μg/mL for Uprolide D, 3.0 μg/mL for Uprolide E acetate, and 5.1 μg/mL for Uprolide F diacetate. Uprolide D-acetate was cytotoxic also for human T-cell leukemia CCRF-CEM cells (IC50 = 7.0 μg/mL), HCT 116 colon cancer cells (IC50 = 7.0 μg/mL), and MCF-7 breast adenocarcinoma cells (IC50 = 0.6 μg/mL) [93]. The cembranoid diterpene asperdiol acetate from the Caribbean sea whip Eunicea succinea showed cytotoxic properties resulting in GI50 values of 6.25 × 10−7 M against SNB-75 CNS cancer cells and 8.28 × 10−6 against M14 (melanoma) and HS 578T (breast cancer) cell lines [94]. Eight γ-cembranolide-type diterpenes and a new saponin were isolated from the gorgonian octocoral Eunicea pinta by Shi et al. [95]. The diterpene 12-Epieupalmerone was cytotoxic to non-small cell lung cancer cells NCI-H332M (IC50 = 0.90 μg/mL) and also to renal cancer cells TK-10 (IC50 = 0.13 μg/mL) and Uprolide H strongly inhibited the growth of human T lymphocitic leukemia cells MOLT-4 (IC50 = 0.01 μg/mL) and SR (IC50 = 0.07 μg/mL). The saponin was cytotoxic only to renal cancer cells A498 (IC50 = 4.2 μg/mL), ACHN (IC50 = 2.8 μg/mL) and CAKI-1 (IC50 = 6.6 μg/mL) [95].
Nephtheoxydiol from the soft coral Nephthea sp. exhibited a significant growth-inhibitory effect on B-16 melanoma cells with IC50 of 0.1 μg/mL [96]. In a subsequent study, six sterols isolated from the same coral were studied for cytotoxicity. Five of them exhibited significant cytotoxicity and affected the growth of A549 (human lung adenocarcinoma), HT-29 (human colon adenocarcinoma), KB (human epidermoid carcinoma), and P-388 (murine lymphocytic leukemia) cell lines (ED50 values ranging from 0.07 to 1.76 μg/mL); the sixth compound was significantly cytotoxic only to P-388 and HT-29 cells [97].
On the basis of the known occurrence of bioactive terpenoids in soft corals of the genus Xenia (Alcyonacea), several diterpenoids were isolated and described in two different papers [98,99]. In the first paper, eight new compounds named blumiolide-A (1), blumiolide-B (2), 9-deoxy-isoxeniolide-A (3), 9-deoxy-7,8-epoxy-isoxeniolide-A (4), 9-deacetoxy-7,8-epoxy-13-epi-xenicin (5), 9-deoxy-7,8-epoxy-xeniolide-A (6), blumiolide-C (7), and blumicin-A (8), were isolated from Xenia blumi and were found to be cytotoxic to A549 (human lung adenocarcinoma), HT-29 (human colon adenocarcinoma), and P-388 (mouse lymphocytic leukemia) cells with ED50 values ranging from 0.2 (compound 7) to 6.9 (compound 6) μg/mL for P-388 and from 0.5 (compound 7) to 8.7 (compound 3) μg/mL for HT-29. Compounds 5 and 8 were practically inactive on both cell lines and compound 3 showed ED50 values >20 μg/mL on P-388 cells [98]. In the second paper, 11 diterpenoids, umbellacins A-G (1–7), 14,15-epoxy-xeniolide H (8), 3-acetyl-14,15-epoxy-xeniolide H (9), and umbellacins H and I (10, 11) were isolated from the soft coral Xenia umbellata (Alcyonacea). Compounds 2, 4, 5, 6, 10 and 11 were cytotoxic in vitro against murine P-388 lymphocytic leukemia cells with ED50 values of 1.6, 4.2, 3.8, 3.7, 3.4, and 3.6 μg/mL, respectively, but they were not cytotoxic to human lung adenocarcinoma cells (A549) and human colon adenocarcinoma cells (HT-29) [99].
Punaglandins—highly functionalized prostanoids provided with anti-inflammatory and antitumor activity—were seen to be active against cultured L1210 mouse leukemia cells [100]; 19 of these compounds produced by the Hawaiian octocoral Telesto riisei (Telestacea) were described by Baker and Scheuer [101]. The activity of punaglandins both in vitro and in vivo against Ehrlich ascites cells was stronger than that of prostaglandins and the induced cytotoxicity almost equalised that from vincristine; modified compounds were shown to enhance the mineralization of human osteoblasts in vitro [102]. Other compounds isolated from the octocoral Telesto riisei N-(2-phenylethyl)-9-oxohexadecacarboxamide and N-(2-phenylethyl)-9-hydroxyhexadecacarboxamide, acyl derivatives of β-phenylethylamine, and two tetrahydroxysterols were found to be mildly toxic to murine leukemia cells (P-388) with ED50 ranging from 1.3 to 2.4 μg/mL [103].
A screening with crude extracts from octocorals Carijoa sp. and Lophogorgia sp. and with other unidentified gorgonians showed that a high percentage (30%) displayed cytotoxic activities to cultured MCF-7 (breast), B16 (melanoma) and HCT8 (colon) cancer cells with values of growth inhibition in some cases (mainly for Carijoa sp.) higher than 75%. The antimycotic activity against Candida albicans was observed for one unidentified gorgonian [104].
A modified steroid (18-acetoxipregna-1,4,20-trien-3-one) isolated from Carijoa riisei was shown to be cytotoxic (IC50 = 10.6 μg/mL) to mammalian macrophages [30]. Another study [105] showed that this steroid was moderately cytotoxic against cancer cells with IC50 values of 12.4 μg/mL when tested on leukemia (HL60) cells, 14.4 μg/mL for SF295 glioblastoma cells, 22.0 μg/mL for colon HCT8 cells and 23.1 μg/mL for MDA.MB.435 ductal carcinoma cells, to date classified as melanoma. A pregnane steroid and two analogues isolated from Carijoa sp. exhibited cytotoxicity against Bel-7402 cells (human hepatoma) with IC50 values of 9.33, 11.02 and 18.68 µM, respectively [106].
As concerns the genus Lobophytum, Lobohedleolide, containing the α,β-unsaturated carboxylic acid system, isolated from the Japanese soft coral Lobophytum hedleyi, was shown to cause growth inhibition of HeLa cells in vitro [107]. Two cytotoxic cembranolides—lobomichaolide and crassolide—were studied in Lobophytum michaelae (Alcyoniidae); they exhibited significant cytotoxicity against A-549 human lung adenocarcinoma cells (ED50 = 0.38 and 0.39 μg/mL, respectively), HT-29 human colon adenocarcinoma cells (ED50 = 0.37 and 0.26 μg/mL, respectively), KB human nasopharyngeal carcinoma cells (ED50 = 0.59 and 0.85 μg/mL, respectively), and P-388 mouse lymphocytic leukemia cells (ED50 = 0.34 and 0.08 μg/mL, respectively) [108]. Later on, hexane extracts from the soft coral Lobophytum crassum showed significant cytotoxicity against human lung adenocarcinoma (A549), human colon adenocarcinoma (HT-29), human epidermoid carcinoma (KB), and mouse lymphocytic leukemia (P-388) cells. A cembrane diterpene (lobocrassolide) and a cembrenolide (lobohedleolide) were isolated from these extracts. Both compounds showed cytotoxicity; in particular, lobocrassolide was cytotoxic for all utilized cultured cells with ED50 values of 2.99, 2.70, 2.91, and 0.012 μg/mL for A549, HT-29, KB, and P-388 cells, respectively. Lobohedleolide was shown to be cytotoxic only to P-388 cells (ED50 = 2.44 μg/mL) [109].
Other octocorals and their extracts were studied for cytotoxicity from as early as the 1990s. 9,11-secosterol from the soft coral Gersemia fruticosa was found to be cytotoxic as well as to inhibit the growth of cultured human leukemia K562, human cervical cancer HeLa, and Ehrlich ascites tumor cells with IC50 values below 10 μM. The action mechanism seems to be linked to the induction of mitotic alterations with the blockade of cell cycle progression and accumulation of cells in the metaphase of mitosis. After treatment, Ehrlich tumor cells pursued DNA synthesis without entry into mitosis producing cells with high DNA ploidy [110]. Palmonines from the gorgonian Eunicella verrucosa were found to be weakly cytotoxic to murine (P-388 lymphoma), and human (A549 lung carcinoma, HT29 colon carcinoma, and MEL28 melanoma) cancer cells. Testings with these cell cultures furnished ED50 values of 10 μg/mL or higher in all cases; only the palmonine B was observed to be active against P-388 and MEL28 cells (ED50 = 5 μg/mL). On the basis of these results, the authors stated that “palmonines seem to offer one more example of the low potential pharmaceutical activities of compounds from octocorals” [111]. In 1998, from the gorgonian Muricella sp., five 9,10-secosteroids (astrogorgiadiol and calicoferols F-I) were studied for cytotoxicity by Seo et al. [112]. These compounds exhibited significant cytotoxicity against K-562 human leukemia cells with LC50 values of 12.1, 3.2, 2.1, 10.7, and 9.6 μg/mL, respectively [112]. The glycoside 19-norpregna-1,3,5(10),20-tetraen-3-O-α-fucopyranoside isolated from the soft coral Scleronephthya pallida was cytotoxic to the breast cancer cell line (BCA-1) with ED50 of 10 μg/mL; furthermore, this compound inhibited the growth of Plasmodium falciparum [113]. The sesquiterpene suberosenone and its dimer alertenone were extracted from the gorgonian Alertigorgia sp. The first compound caused strong growth inhibition of nonsmall cell lung (A549, HOP-92) and CNS (SF-295, SF-539, SNB-19) tumor cell lines, with IC50 ranging from 0.002 to 1.63 μg/mL, of melanoma cell lines (LOX, M14, MALME-3M) with IC50 ranging from 0.006 to 0.01 μg/mL, and of ovarian (OVCAR-3) and breast cell lines (MCF7), with IC50 of 0.02 and 0.43 μg/mL, respectively. Alertenone was practically devoid of cytotoxicity showing IC50 values ranging from 35 to >100 μg/mL [114]. Three steroids isolated from Leptogorgia sarmentosa showed significant but non selective cytotoxicity against suspension cultures of mouse lymphoid neoplasm (P-388) and monolayer cultures of human lung carcinoma (A 549), human colon carcinoma (HT 29), and human melanoma (MEL 28) with ED50 values of 1 μg/mL for all cases [115].
Six sesquiterpene metabolites (suberosenol A, suberosenol B, suberosanone, suberosenol A acetate, suberosenol B acetate and subergorgic acid) from the gorgonian Isis hippuris were studied by Sheu et al. [116]. Excluding subergorgic acid (ED50 values ranging from 13.3 to >50 μg/mL), all compounds showed significant cytotoxicity toward mouse lymphocytic leukemia (P-388), human lung adenocarcinoma (A549), and human colon adenocarcinoma (HT-29) cells with ED50s ranging from values lower than 5.0 × 10−6 μg/mL to 3.6 × 10−1 μg/mL except for suberosenol B that furnished ED50 results between 0.2 and 3.4 μg/mL. On the whole, suberosenol A was the most active compound showing high cytotoxicity toward all utilized cancer cells. The authors remark that this compound “contains a β-hydroxyl group at the allylic position of the 5,6-double bond” and suggest that “the molecular skeleton, not the functionalities, is the main factor for the potent cytotoxicity of these suberosane terpenoids” [116].
Three compounds, among which a new sesquiterpenoid (junceol A) and two known diterpenoids (sclerophytin A and cladiellisin), were isolated by Chen et al. [117] from sea pen octocoral Virgularia juncea and resulted cytotoxic to P-388 cancer cells showing ED50 values of 5.1, 2.3, and 2.0 μg/mL, respectively. A new briarane, juncenolide C, isolated from the Taiwanese red gorgonian Junceella juncea (Alcyonacea) exhibited mild cytotoxicity against human liver carcinoma HEPA 59T/VGH at a concentration of 6.6 μg/mL and oral epidermoid carcinoma cells (KB) at a concentration of 7.8 μg/mL [118]. (Z)-Sarcodictyin A from the soft coral Bellonella albiflora (Alcyonacea) collected from southern Japan was highly cytotoxic to human cervix HeLa tumour cells (IC50 = 90 ng/mL); other compounds (eleutherobin and (Z)-eleutherobin) from the same cnidarian showed IC50 values of 17 ng/mL [119]. Yoshikawa et al. [120] isolated two polyhydroxylated sterols, named dendronesterol A and B, from the octocoral Dendronephthya gigantea. Dendronesterol B was found to exhibit weak cytotoxicity toward lymphocytic leukemia cells (L1210) with IC50 value of 5.2 μg/mL. Guaiazulene-related pigments from gorgonians are known to have antifungal, antitumor, antibacterial and immunoregulatory activity as well as antiproliferative effects on fertilized sea urchin and ascidian eggs [121]. On this basis, three linderazulenes (compounds 1–3) isolated from the deep-sea gorgonian Paramuricea sp. (Alcyonacea) were tested for their cytotoxicity against P388 murine leukemia cells and PANC-1 pancreatic cells. The IC50 values calculated after treatment of P388 cells were 18.8, 2.7, and 15.6 μg/mL, respectively. Compound 2 was moderately cyotoxic (IC50 = 18.7 μg/mL) also to PANC-1 cells [121].
Chao et al. [122] isolated three steroidal carboxylic acids (paraminabic acids A–C) from the Formosan soft coral Paraminabea acronocephala. The compound C was highly cytotoxic (IC50 values ranging from 2.05 to 2.83 μg/mL) to cancer cell lines Hep3B, MDA-MB-231, MCF-7 and A-549.
Table 1. Cytotoxicity to different cell lines of compounds extracted from Octocorallia (Anthozoa).
Table 1. Cytotoxicity to different cell lines of compounds extracted from Octocorallia (Anthozoa).
SpeciesCompound or materialCellsTissue/organ/histologyOrganismIC50–ED50 (μg/mL)Ref.
Acalycigorgia inermisXenicane diterpenoidsK562LeukemiaHuman0.2–52.0[87,123]
Acalycigorgia inermisXenicane diterpenoidsK562LeukemiaHuman0.04–3.9[88]
Alcyonum patagonicum Dihydrohy sterolP388LymphomaMouse1.00[89]
Alcyonium paessleri SesquiterpenoidsHT-29Colon carcinomaHuman10.0[90]
Hep-2Larynx carcinomaHuman13.5
Alertigorgia sp.Suberosenone (sesquiterpene)A-549 Lung adenocarcinomaHuman1.63[114]
HOP-92 Lung adenocarcinomaHuman0.11
SF-295GlioblastomaHuman0.03
SF-539GliosarcomaHuman0.002
SNB-19GlioblastomaHuman0.006
LOXMelanomaHuman0.006
M14MelanomaHuman0.010
MALME.3MMelanomaHuman0.008
OVCAR.3Ovarian adenocarcinomaHuman0.02
MCF7Breast adenocarcinomaHuman0.43
Bellonella albiflora DiterpenoidsHeLaCervix carcinomaHuman17.0–90.0 (×)[119]
Briareum excavatum Briarane-type diterpenoidP388LymphomaMouse0.9[81]
A549Lung adenocarcinomaHuman 4.8
HT-29Colon adenocarcinomaHuman3.1
Briareum excavatum DiterpenesA549Lung adenocarcinomaHuman1.2–>50[84]
HT-29Colon adenocarcinomaHuman1.3–>50
KBEpidermoid carcinoma (#)Human0.8–>50
P388LymphomaMouse0.3–>50
Briareum excavatum Briarane diterpenesA549Lung adenocarcinomaHuman0.1–>50[85]
HT-29Colon adenocarcinomaHuman1.3–>50
KBEpidermoid carcinoma (#)Human1.0->50
P388LymphomaMouse0.001– >50
Briareum excavatum Briarane diterpenesP388LymphomaMouse0.40– 0.50[86]
HT-29Colon adenocarcinomaHuman1.1
Briareum asbestinum Asbestinin diterpenesCHO-K1Ovary (normal)Chinese hamster2.50–4.82[82]
Briareum sp.DiterpenesA549Lung adenocarcinomaHuman10.35–>50[83]
HT-29Colon adenocarcinomaHuman0.29–>50
KBEpidermoid carcinoma (#)Human0.27–>50
P388LymphomaMouse0.28–>50
Carijoa riisei Steroid-MacrophagesMouse10.6[30]
Carijoa riisei SteroidSF295Glioblastoma Human14.4[105]
MDA.MB.435Ductal carcinoma (°)Human23.1
HCT8Colon adenocarcinomaHuman22.0
HL60 Promyelocytic leukemiaHuman 12.4
Carijoa (Telesto) riiseiRiiseins (steroidal glycosides)HCT-116 Colon adenocarcinomaHuman2.0[124]
Telesto riisei AmidesP388LymphomaMouse2.1–2.2[103]
Sterols1.3–2.4
Carijoa sp.SteroidsBel-7402HepatomaHuman9.33–18.68[106]
Clavularia inflata Dolabellane diterpeneA-549Lung adenocarcinomaHuman0.57[59]
HT-29Colon adenocarcinomaHuman 0.31
P388Lymphocytic leukemiaMouse 0.052
Clavularia koellikeri Cembrane-type diterpenoidDLD-1MOLT-4Colorectal adenocarcinomaHuman4.2[61]
T lymphocytic leukemiaHuman0.9
Clavularia viridis ClavulonesHL60Promyelocytic leukemiaHuman0.2[54]
HeLaCervix adenocarcinomaHuman 0.5
Clavularia viridis ChlorovuloneHL60Promyelocytic leukemiaHuman0.01[55]
Clavularia viridis Halogenated prostanoid (7-Acetoxy-7,8-dihydroiodovulone I)MOLT-4 T lymphocytic leukemiaHuman0.52[58]
DLD-1Colorectal adenocarcinomaHuman0.6
IMR-90Lung fibroblastsHuman4.5
Clavularia sp.Stolonidol and Stolonidol monoacetateP388LymphomaMouse0.015[56]
Dendronephthya gigantea Dendronesterol B (sterol)L1210Lymphocytic leukemiaMouse5.2[120]
Echinomuricea sp.DiterpenoidMOLT-4Lymphoblastic leukemiaHuman13.18 (^)[63]
HL-60Promyelocytic leukemiaHuman14.89 (^)
DLD-1Colorectal adenocarcinomaHuman23.44 (^)
LoVoColorectal adenocarcinomaHuman21.69 (^)
K562Erythromyeloblastoid leukemiaHuman37.05 (^)
DU-145 Prostate carcinomaHuman53.93 (^)
Echinomuricea sp.DiterpenoidHL-60Promyelocytic leukemiaHuman19.1[64]
Eunicea laciniata Dolabellane diterpenesHeLaCervix carcinomaHuman25.0–100.0[92]
Eunicea mammosa Cembranolide diterpenoidsHeLaCervix carcinomaHuman2.5–5.1[93]
CCRF-CEMT-cell leukemiaHuman7.0
HCT 116Colon cancerHuman7.0
MCF-7Breast adenocarcinomaHuman0.6
Eunicea pinta γ-cembranolide-type diterpene (12-Epieupalmerone)NCI-H322MNon-small cell lung cancerHuman0.90[95]
TK-10Renal cancerHuman0.13
Uprolide H (diterpene)MOLT-4T lymphocytic leukemiaHuman0.01
SRLarge cell immunoblastic lymphomaHuman0.07
SaponinA498Renal cancerHuman4.2
ACHNRenal cancerHuman2.8
CAKI-1Renal cancerHuman6.6
Eunicea succinea Asperdiol acetate (diterpene)SNB-75CNS cancerHuman6.25 × 10−7 (* +)[94]
M14 Melanoma Human8.28 × 10−6 (* +)
HS 578TBreast cancerHuman8.28 × 10−6 (* +)
Eunicella verrucosa Palmonine B (diterpene)MEL28MelanomaHuman5.0[111]
P388LymphomaMouse 5.0
Isis hippuris SesquiterpenesA549Lung adenocarcinomaHuman0.005–>50[116]
HT-29Colon adenocarcinomaHuman<0.000005–>50
P388LymphomaMouse<0.000005–13.3
Lemnalia tenuis LemnaloneDBA/MCFibrosarcomaMouse2.5–40 (**)[75]
Leptogorgia sarmentosa SteroidsA549Lung adenocarcinomaHuman1[115]
HT-29Colon adenocarcinomaHuman1
MEL 28MelanomaHuman1
P388 LymphomaMouse1
Lobophytum crassum DiterpenesA549Lung adenocarcinomaHuman0.012–2.99[109]
HT-29Colon adenocarcinomaHuman
KBEpidermoid carcinoma (#) Human
P388LymphomaMouse
Lobophytum michaelae CembranolidesA549Lung adenocarcinomaHuman0.38–0.39[108]
HT-29Colon adenocarcinomaHuman0.26–0.37
KBEpidermoid carcinoma (#)Human0.59–0.85
P388 LymphomaMouse0.08–0.34
Muricella sp.SecosteroidsK-562LeukemiaHuman2.1–12.1[112]
Nephthea brassica Brassicolene (diterpenoid)A-549Lung adenocarcinomaHuman3.62[125]
P388LymphomaMouse0.86
Nephthea erecta SterolsA549Lung adenocarcinomaHuman0.41–4.09[97]
HT-29Colon adenocarcinomaHuman0.1–3.34
KBEpidermoid carcinoma (#)Human0.38–>50
P388LymphomaMouse0.07–0.45
Nephthea sp.Nephtheoxydiol (sesquiterpene)B-16MelanomaMouse0.1[96]
Pachyclavularia violacea Pachyclavulariolide F (diterpenoid)P388LymphomaMouse1.0[126]
Paraminabea acronocephala Paraminabic acid C (steroidal carboxylic acid)Hep G2Liver hepatocellular carcinomaHuman13.6–19.8[122]
Hep 3B Liver hepatocellular carcinomaHuman2.83–>20
MDA.MB.231Breast adenocarcinomaHuman2.25–>20
MCF-7Breast adenocarcinomaHuman2.23–>20
A-549 Lung adenocarcinomaHuman2.05–>20
Paramuricea sp.Linderazulenes (terpenes)P388LymphomaMouse2.7–18.8[121]
PANC-1Pancreatic carcinomaHuman18.7
Pseudopterogorgia americana SecogorgosterolsLnCapProstate carcinomaHuman15.5[127]
Calu-3Lung adenocarcinomaHuman11.0
Plexaurella grisea Polyhydroxylated sterolsP388LymphomaMouse>1[65]
A549Lung carcinomaHuman1
HT29Colon carcinomaHuman0.1–1
Plexaurella grisea Linear norsesquiterpenes P388LymphomaMouse0.5–5[66]
Acylic sesquiterpenesA549Lung carcinomaHuman
HT29Colon carcinomaHuman
MEL-28MelanomaHuman
Sarcophyton crassocaule Cembrenolide diterpenesA549Lung adenocarcinomaHuman4.29–8.31[77]
HT-29Colon adenocarcinomaHuman4.97–7.55
KBEpidermoid carcinoma (#)Human6.29–9.15
P388Lymphoma Mouse0.14–0.38
SteroidsA549Lung adenocarcinomaHuman6.26–22.43
HT-29Colon adenocarcinomaHuman4.32–8.35
KBP388Epidermoid carcinoma (#)Human5.38–26.84
LymphomaMouse0.14–3.96
Sarcophyton trocheliophorum PolyhydroxysterolHL60LeukemiaHuman2.8[78]
M14MelanomaHuman4.3
MCF7Breast carcinomaHuman4.9
Scleronephthya pallida Pregnane steroidsBCA-1Breast cancer Human10.0[113]
Sinularia capillosaCembranolide (capillolide)P388LymphomaMouse15.0[73]
L1210Lymphocytic leukemiaMouse 18.5
Sinularia capillosa Cembranolides P388LymphomaMouse1.5–8.5[73]
L1210Lymphocytic leukemiaMouse3.0–10.0
Sinularia flexibilis Cembranoid diterpenesA549Lung adenocarcinomaHuman0.68–16.8[70]
HT-29Colon adenocarcinomaHuman0.22–32.4
KBEpidermoid carcinoma (#)Human0.46–>50
P388LymphomaMouse0.16–3.86
Sinularia gibberosa Diterpene (sinugibberol)HT29Colon adenocarcinomaHuman0.50[60]
P388 lymphomaMouse11.7
Sinularia inelegans Diterpene (ineleganene)A549Lung adenocarcinomaHuman3.63 (*)[72]
P388LymphomaMouse0.20 (*)
Sinularia sp.Acylated spermidineP388LymphomaMouse0.04[68]
Sinularia sp.SterolsA549Lung adenocarcinomaHuman2.7–10.8[128]
HT-29 Colon adenocarcinomaHuman0.7–1.5
KB Epidermoid carcinoma (#)Human1.9–>50
P388 LymphomaMouse0.4–8.3
Subergorgia suberosa Sesquiterpene (Subergorgic acid methyl ester)HeLaCervix carcinomaHuman4.3[79]
Subergorgia suberosa Sesquiterpene alcoholsP388Lymphoma Mouse2.1–7.4[80]
A549Lung adenocarcinomaHuman4.2–>50
HT-29 Colon adenocarcinomaHuman2.3–>50
Sesquiterpene chetonesP388LymphomaMouse4.6–6.3
A549 Lung adenocarcinomaHuman3.8–8.9
HT-29 Colon adenocarcinomaHuman3.6–6.6
Virgularia juncea SesquiterpenoidP388LymphomaMouse5.1[117]
DiterpenoidsP388 LymphomaMouse2.0–2.3
Xenia blumi DiterpenoidsHT-29Colon adenocarcinomaHuman0.5–>20[98]
P388 LymphomaMouse0.2–>20
Xenia umbellata DiterpenoidsP388LymphomaMouse1.6–3.8 (§)[99]
(*) values expressed as GI50; (^) Values expressed as μM; (+) Values expressed as M; (×) Values expressed as ng/mL; (**) tested concentrations; IC/ED50 values not indicated; (§) only active compounds; (°) to date considered a melanoma; (#) to date considered a HeLa cell contaminant.
In a comprehensive review, Mayer and Gustafson [129] reviewed the available data of the antitumor and cytotoxic properties of 143 marine natural products among which some were derived from cnidarians; in particular, this paper reports that some diterpenes from corals were found to be active against human and murine tumour cell lines causing growth inhibition or cytotoxicity in the concentration range of 0.012–22.4 μg/mL [72,77,109,125,126]. Gorgonian and coral steroids were active in the concentration range of 0.4–18.43 μg/mL on human and murine tumor cells [115,123,127,128]; steroidal glycosides (riiseins A and B) from coral were found to be active to inhibit cell growth of human tumours at a concentration of 2.0 μg/mL [124] and a gorgonian sesquiterpene affected cell growth of murine and human tumour cell lines at concentrations of 5 × 10−6–50 μg/mL [128].
Table 1 shows a summary of data pertinent to the considered papers.

3.2. Cytotoxicity of Extracts from Hexacorallia (Anthozoa)

The studies about the cytotoxicity of hexacoral extracts using cultured cells are remarkably scarcer than those about octocorals. A Zoanthoxanthin alkaloid from zoanthid corals Epizoanthus sp. was shown to be cytotoxic in vitro against HCT8 human colon adenocarcinoma (IC50 = 1.61 μg/mL), A549 human lung carcinoma (IC50 = 2.38 μg/mL), HT29 human colon adenocarcinoma (IC50 = 0.824 μg/mL) and P-388 mouse lymphocytic leukemia (IC50 = 1.77 μg/mL) cells [130]. A fractionated extract of the stony coral Tubastrea faulkneri (Scleractinia) furnished macrolides and indole derivatives; among these compounds the macrolides mycalolides C and D induced modest cytotoxicity against 60 human tumor cell lines showing average LC50 values of 2.5 and 0.6 μM, respectively [131]. From eggs of the scleractinian coral Montipora digitata, the polyacetylene carboxylic acids montiporic acid A and B were isolated. These compounds exhibited cytotoxicity against P-388 murine leukemia cells with IC50 value of 12.0 μg/mL, and were active against bacteria Escherichia coli (IC50 = 5.0 μg/mL) [132]. Six acetylenic compounds have been isolated from the stony coral Montipora sp.; two of them (Compounds 1 and 3) showed high cytotoxicity (ranges of 1.4–3.7 μg/mL and 1.5–5.2 μg/mL, respectively) against SKOV-3 (human ovarian cancer), SK-MEL-2 (human skin cancer), XF498 (human CNS cancer), and HCT15 (human colon cancer) cell lines but had no activity on A549 (human lung cancer) cells [133].
Ten new and four known diacetylenes were isolated by a Korean Research Group from a fraction of the methanolic extract from the stony coral Montipora sp. active on brine shrimp [134]; a 15th compound, Montiporyne A, induced apoptosis in human HCT116 colon tumor cells with an increase of 19% of the apoptotic fraction in cells treated with 100 μg/mL for 24 h. These compounds were tested for cytotoxicity against five human cancer cell lines (A549: human lung cancer; SK-OV-3: human ovarian cancer; SK-MEL-2: human skin cancer; XF498: human CNS cancer; HCT15: human colon cancer); Montiporyne I resulted the most cytotoxic compound with ED50 values ranging from 1.40 to 4.17 μg/mL and showed significant cytotoxicity particularly against human ovarian cancer (SK-OV-3) and human skin cancer (SK-MEL-2) cells. The Montiporynes J, K and L as well as a diacetylene (compound 8) were also highly cytotoxic. The authors stated that “diacetylenes with the β-hydroxy ketone functionality were found to be more active” [134].
Palytoxin (PTX), at the beginning isolated in the hexacoral Palythoa toxica [8], is one of the most poisonous biotoxins [135,136] and has several important features: it is a human and mouse skin irritant, it was indicated to be a tumor promoter and to exert its activity extracellularly [137], and it is able to induce neurotoxicity, rhabdomyolysis and cardiovascular collapse in vivo on several mammals, including humans [138], as well as to modify the normal function of different biological systems [135]. PTX is a very complex molecule that presents both lipophilic and hydrophilic areas [139]. It was reported to affect cation transport across the plasma membranes [140,141,142] and to interact with Na+,K+-ATPase converting this ion pump into a non-specific cation channel and consequently causing perturbation of Na+, K+, Ca2+ and H+ ion fluxes resulting in cytotoxicity, cytolysis and cell death [135].
The effects of PTX were studied on human bronchial epithelial cells showing that it does not induce squamous differentiation of normal cells; the cytotoxicity of PTX does not change when normal human bronchial epithelial cells, human lung tumors, and human bronchial epithelial cells immortalized by infection with adenovirus 12-SV40 are used. Furthermore, PTX does not induce a change in free cytosolic Ca2+ concentration of BEAS-2B cells [143]. PTX was shown to induce ion currents (channels permeable to Na+ and K+ and slightly permeable to Ca2+, choline and tetramethylammonium) in mouse neuroblastoma cells [144]. As a matter of fact, the activity on cation transport is commonly recognized to be PTX’s main toxic mechanism [145].
PTX stimulates weak production of superoxide radicals by human neutrophils with maximum amounts of 10−4 μmol/106 neutrophils at nanomolar concentrations (half maximal stimulation at ~30 nM) and is toxic at very low concentrations to cultured human epidermal cells (50% loss of colony-forming efficiency at ~3 × 10−13 M) [137].
In a method useful for targeting PTX to tumor cells, a monoclonal antibody-enzyme conjugate activating the PTX prodrug N-(4'-hydroxyphenylacetyl)palytoxin (NHPAP) was described at the surface of tumor cells. PTX resulted remarkably toxic to H2981 human lung adenocarcinoma, cells, as well as to lymphoma cell lines. NHPAP was 1000 times less toxic than PTX but its cytotoxicity reached that of PTX after combination with penicillin G amidase from Escherichia coli. Immunologically specific activation of NHPAP took place after treatment of H2981 cells with the monoclonal antibody conjugate and NHPAP. The authors emphasized that this system is suitable because “the released drug exerts its activity extracellularly, has high potency, and may be able to overcome the multidrug resistant phenotype” [146].
The role of different protein kinases (calcium-dependent protein kinase C—PKC, extracellular signal-regulated kinase—ERK 2, c-Jun N-terminal protein kinases—JNK, mitogen activated protein kinases—MAPKs, MAPK kinase—MEK) for the activity of PTX on cytosolic calcium concentration and cytoxicity was investigated in primary cultures of cerebellar granule cells [147] observing that the inhibition of ERK 2 and MEK has an effect on PTX cytotoxicity, that at 10 nM is known to induce calcium increase and intracellular acidification [148,149]. In fact, the inhibition of ERK 2 completely inhibits the cytotoxic activity of the toxin, while a partial blockade was observed after MEK inhibition [147]. Recently, in a cytotoxicity research on neuroblastoma cells (Neuro-2a), PTX killed all treated cells at concentrations >10−9 M [150].
Head and neck squamous cell carcinoma (HNSCC) cell lines resulted highly sensitive (LD50 = 1.5–3.5 ng/mL) to PTX compared to normal epithelial cells. Both the release of LDH and the expression of the sodium/potassium-transporting ATPase subunit alpha1 gene were affected by PTX. The authors supposed a primary activity of PTX on plasma membrane caused loss of cellular integrity [139].
The effect of PTX on rat pheochromocytoma PC12 cells has been recently studied. The observed concentration-dependent cytotoxicity was ascribed to the disruption of plasma membrane and to the consequent nonoxidative necrotic damage. Antioxidants or reduced glutathione do not affect this behaviour that in addition does not cause chromatin condensation and DNA fragmentation. PTX seems to cause cell membrane damage through a non-oxidative necrotic process. The exposure to PTX was seen to cause release of lactate dehydrogenase into the culture medium [145]. In Caco-2 cells, PTX at a concentration of 8.9 ± 3.7 × 10−12 M reduced the mitochondrial activity by 50% and induced cytotoxicity when tested with Sulforhodamine B assay (EC50 = 2.0 ± 0.6 × 10−11 M) as well as with LDH release (EC50 = 4.5 ± 1.4 × 10−9 M) [151].
As concerns other compounds from Palythoa, four cell growth inhibitory peptides—palystatins A–D, with relatively low molecular weight (3000–5000)—were isolated from Palythoa liscia. Palystatins A–D showed cytotoxic properties against P388 murine lymphocytic leukemia (ED50 values = 0.0023 (A), 0.020 (B), 0.0018 (C) and 0.022 (D) μg/mL) [152]. Table 2 shows a summary of data pertinent to papers concerning Hexacorallia.
Table 2. Cytotoxicity to different cell lines of compounds extracted from Hexacorallia (Anthozoa).
Table 2. Cytotoxicity to different cell lines of compounds extracted from Hexacorallia (Anthozoa).
SpeciesCompound or materialCellsTissue/organ/histologyOrganismIC50–ED50 (μg/mL)Ref.
Epizoanthus sp.AlkaloidHCT8 Colon adenocarcinoma Human 1.61 [130]
A549 Lung carcinoma Human 2.38
HT29 Colon adenocarcinoma Human 0.82
P388LymphomaMouse1.77
Montipora digitataCarboxylic acidsP388LymphomaMouse5–12[132]
Montipora sp.Acetylenic compoundsA549 Lung carcinoma Human >50 [133]
SK-OV-3 Ovarian adenocarcinoma Human 2.5–>50
SK-MEL-2 Melanoma Human 1.4–>50
XF498 CNS cancer Human 1.9–>50
HCT15Colorectal adenocarcinomaHuman3.7–>50
Montipora sp.DiacetylenesA549 Lung carcinoma Human 3.9->30 [134]
SK-OV-3 Ovarian adenocarcinoma Human 1.8–>30
SK-MEL-2 Melanoma Human 1.4–>30
XF498 CNS cancer Human 3.7–>30
HCT15Colorectal adenocarcinomaHuman3.3–>30
Palythoa caribaeorumPalytoxinUKHN-1 Oropharynx squamous cell carcinoma Human 1.2 (×) [139]
UKHN-2 Esophagus squamous cell carcinomaHuman 2.2 (×) approx
UKHN-3Tongue squamous cell carcinomaHuman3.0 (×)
Palythoa lisciaPalystatins A-DP388LymphomaMouse0.0023–0.02[152]
Palythoa tuberculosaPalytoxinH2981Lung adenocarcinomaHuman3 × 10−12 (+)[146]
Commercial sourcePalytoxinPC12PheochromocytomaRat5–8 (♦) approx[145]
Tubastrea faulkneriMacrolides Tested on 60 tumour cell linesHuman0.6–2.5 (^)[131]
(+) Values expressed as M. (^) Values expressed as μM. (♦) Values expressed as nM. (×) Values expressed as ng/mL.

3.3. Cytotoxicity of Extracts from Sea Anemones (Anthozoa)

Reports concerning the cytotoxicity of sea anemones have been published since the late 1970s. Actinia equina L. has been widely studied from this point of view. To our knowledge, the first report about the cytotoxicity of Actinia equina venom was published in 1976 [153], when a potent cytotoxic activity of Equinatoxin was observed by dye exclusion test on Ehrlich carcinoma and L1210 leukaemia inoculated in swiss albino mice with ED50s of a few ng/mL. The authors observed that concentrations higher than ED50 produced extensive cell lysis and the cytotoxic effects of Equinatoxin were inhibited by phospholipids; on this basis, they suggested that the mechanism of action “may be related to interactions with lipids or other charged components of cell membrane”. The cytotoxic and cytolytic effects of Equinatoxin II (EqT II), as well as its concentration-dependent cytocidal and cytostatic effects, were subsequently emphasized on V-79-379 A cells [154]. On the basis of results showing that after treatment with EqT II pituitary glands bovine lactotrophs suffered a rapid rise in cytosolic Ca2+ activity and that Ca2+ permeable ion channels are produced after incorporation of EqT II into planar lipid bilayers, Zorec et al. [155] suggested the cytotoxicity of EqT II can be ascribed to the formation of cation (Ca2+) permeable channels in cell membranes. Subsequenty, EqT II was observed to produce pores affecting the permeability of V79-379 A cells plasmalemma for metabolites and ions. Treated cells were killed by approximately 75 μg/106 cells EqT II and the toxic effects were lowered by serum. Less than 37.5 μg EqT II/106 cells did not produce significant change in cell membrane fluidity [156]. In another study, crude extracts from nematocyst and surrounding tissues of the sea-anemone Actinia equina were tested on V79 fibroblasts observing that 150,000 nematocysts/mL caused a decrease of cell survival up to approximately 60%–70% according to the utilized method of evaluation (Trypan blue dye exclusion and neutral red assay, respectively) after one hour treatment and killed all treated cells after two hours. At doses ranging from 150,000 to 15,000 nematocysts/mL, the venom was not genotoxic [157]. Considering that the pore forming toxin EqT II damages cells through the activity of an amphiphilic N-terminal α-helix on membrane, and considering also that a “normally active N-terminal mutant, containing one single cys in the amphiphilic α-helix, becomes totally inactive when it is bound to avidin via a biotinylated linker”, in a interesting study Potrich et al. [158] chose a peptide containing a tumour protease cleavage site as a linker, making an enzymatically activable conjugate selective for tumour cells that was seen to be activated in vitro by cathepsin B and metalloproteinases, known to be involved in cancer progression and tumour migration [159,160]. The conjugate was partly activated by ZR 751 (human breast carcinoma), MCF 7 (human breast adenocarcinoma) and HT 1080 (human fibrosarcoma) cells, but was inactive on human red blood cells used as controls. The cytotoxicity was dependent on the expressed amount of cathepsin B activity. MCF 7 cells, expressing the highest enzymic activity, were found to be the most sensitive tumour cells; thus, these tumour cells could be killed by a conjugate of EqT II specifically activated by tumor proteases [158].
EqTx-II from Actinia equina was studied for cytotoxicity against human glioblastoma U87 and A172 cell lines at concentrations ranging from 0.001 to 10 mg/mL. After 24 h of treatment, 10 mg/mL EqTx-II was found to be remarkably cytotoxic and reduced the viability of U87 and A172 cells to 60% and 48%, respectively, but was not significantly toxic for normal cells (10 mg/mL EqTx-II decreased viability to 80%). Noncytotoxic concentrations of EqTx-II (0.3 mg/mL) were seen to improve the cytotoxicity of chemotherapeutics cytosine arabinoside, doxorubicin, and vincristine utilized at low concentrations. As these chemotherapeutics are known to be highly cytotoxic and to induce adverse effects, the utilization of sea anemone toxins could allow a reduction of the therapeutic dosage [161]. EqTx-II was found to decrease cell viability of U87 glioblastoma cells through a necrosis-like mechanism and increased lactate dehydrogenase (LDH) release in a concentration-dependent manner. It is also able to activate intracellular signaling pathways. Pre-treatment with inhibitors of mitogen-activated/extracellular regulated kinase (MEK1), protein kinase C (PKC) or Ca2+/calmodulin-dependent kinase II (CaMKII) prevents EqTx-II toxicity. This allowed the authors to suggest that calcium entry, activation of MEK1, PKC and CaMKII pathways are involved in the cytotoxicity induced by pore-forming toxins [162]. A recent article showed that non-cytotoxic concentrations of EqTx-II seems to fight the cytotoxicity induced by chemotherapeutics temozolomide (TMZ) and etoposide (VP-16) on glioblastoma cells in vivo and in vitro thus reducing the adverse effects of these drugs [163].
Other Mediterranean anemones were found to be cytotoxic: crude venom from sea-anemone Anemonia sulcata produced growth inhibition and rapid detachment of V79 cells; in particular, cells treated with the highest tested dose (150,000 nematocysts/mL) died within one day of treatment, and those treated with 30,000 nematocysts/mL died within two days [164,165]. Short-time tests (3 h treatment) on V79 cells gave an IC50 value of 65.0 × 103 nematocysts/mL [166]. Crude nematocystic extracts (0.6 nematocysts/μL) from the anthozoan Aiptasia mutabilis were found to be highly cytotoxic inducing significant cellular necrosis on renal monkey Vero cells, with an IC50 of approximately 2 nematocysts/μL, and on human epithelial HEp-2 cells. The venom was found to be inactivated by moderate heat, conservation at low temperature or freezing, and by non-neutral pH values. Two main cytolytic components with molecular masses of 95 and 31 kDa, respectively, were identified [167]. Therefore, in spite of the scarce toxicity in vivo of Mediterranean Cnidaria [168]), a strong cytotoxic activity in vitro was demonstrated for some Mediterranean sea-anemones.
As concerns other sea anemones, the crude extract from the Urticina piscivora and the basic protein UpI isolated from crude extract were investigated on oral human epidermoid carcinoma cells KB (ATCC CCL 17), mouse lymphocyte leukemia cells L1210, and human embryonic lung diploid cells HEL 299; the crude extract was more cytotoxic than the isolated protein [25]. Src I from the sea anemone Sagartia rosea was found to be cytotoxic for cultured NIH/3T3 (Swiss mouse embryo), U251 (glioblastoma), NSCLC (non-small cell lung carcinoma), BEL-7402 (liver carcinoma), and BGC-823 (stomach adenocarcinoma) cells, depending on toxin concentration and incubation time. IC50 values in the absence of serum ranged from 2.8 to 7.4 μg/m; NSCLC cells were the most sensitive. The presence of serum partially inhibited the cytotoxicity of Src I [26]. Fedorov et al. [169] studied the RTX-A actinoporin isolated from the tropical sea anemone Heteractis crispa (Radianthus macrodactylus) and discovered that it can prevent the malignant transformation of mouse epidermal JB6 P+ Cl41 cells with a useful INCC50 (inhibition of number of colonies formed in soft agar C50) value (0.034 nM), 17 times lower than the cytotoxic concentration (IC50 = 0.57 nM). RTX-A was demonstrated to be cytotoxic also to human cancer cell lines, including promyelocytic leukemia cells (HL-60; IC50 = 1.06 nM), breast cancer cells (MDA-MB-231; IC50 = 4.64 nM), cervix carcinoma cells (HeLa; IC50 = 2.26 nM), monocytic leukemia cells (THP-1; IC50 = 1.11 nM) and colon cancer cells (SNU-C4; IC50 = 4.66 nM), as well as to induce dose-dependent apoptosis in JB6 P+ Cl41 cells. The effects of RTX-A on the activity of proteins (AP-1, NF-κB) activating the expression of genes involved in tumor progression [170,171] were also studied in JB6 P+ Cl41 cells showing the time- and dose-dependent inhibition (10%–60%) of basal AP-1- and NF-κB-dependent transcriptional activity at concentrations 0.1–1.6 nM. At this concentration, RTX-A was shown to induce apoptosis with a p53-independent mechanism, suppressing time- and dose-dependently the p53-dependent transcriptional activity of JB6 P+ Cl41 cells [169]. The pore-forming cytolytic toxins (Bc2) produced by Bunodosoma caissarum was investigated for cytotoxicity against human glioblastoma U87 and A172 cell lines at concentrations ranging from 0.001 to 1 mg/mL. After 24 h of treatment, <0.1 mg/mL Bc2 did not exert cytotoxicity but 1 mg/mL reduced significantly U87 and A172 cell viability (50% and 65%, respectively). As already seen for EqTx-II, noncytotoxic concentrations of Bc2 (0.1 mg/mL) were seen to improve cytotoxicity of the chemotherapeutics cytosine arabinoside, doxorubicin, and vincristine, utilized at low concentrations, on GBM cells. Therefore, the utilization of Bc2 could allow a reduction 10–300-fold the dosage of these chemotherapeutics that are known to be highly cytotoxic and to induce adverse effects. Bc2 did not significantly reduce the viability of normal rat astrocytes [161]. Similar results were recently obtained stating that sea anemones produce compounds with pharmacological activities that may be useful to increase cisplatin efficacy. The expositions to 50 μg/mL crude venom from the sea anemone Bunodeopsis globulifera and to 25 μg/mL and 50 μg/ mL, respectively, of two derived fractions (F1 and F2) were seen to increase cisplatin cytotoxicity to human lung adenocarcinoma cells inducing a reduction in cell viability of approximately 50%. From these results, the authors conclude that “the combination of antineoplastic drugs and sea anemone toxins might allow a reduction of chemotherapeutic doses and thus mitigate side effects” [172]. Table 3 shows a summary of data pertinent to papers concerning sea anemones.
Table 3. Cytotoxicity to different cell lines of compounds extracted from sea anemones (Anthozoa).
Table 3. Cytotoxicity to different cell lines of compounds extracted from sea anemones (Anthozoa).
SpeciesCompound or materialCellsTissue/organ/histologyOrganismIC50–ED50 (μg/mL)Ref.
Bunodosoma caissarumBc2U87 Glioblastoma Human Not indicated [161]
A172GlioblastomaHuman
Actinia equinaEquinatoxin IIV-79-379 ANormal lung fibroblastsChinese hamster8.8 × 10−10 (*)[154]
Actinia equinaCrude venomV79Normal lung fibroblastsChinese hamster87.9 × 103 (**)[157]
Actinia equinaEquinatoxin II-I18C mutantMCF 7Breast adenocarcinomaHuman 0.2–0.3[158]
ZR 751 Breast carcinomaHuman 5.8
HT 1080FibrosarcomaHuman14.2
Actinia equinaEqTx-IIU87 Glioblastoma Human Not indicated [161]
A172GlioblastomaHuman
Aiptasia mutabilisCrude venomVero Normal kidney cells Monkey2000 (**) [167]
Hep-2Epithelial carcinomaHumanNot indicated
Anemonia sulcataCrude venomV79Normal lung fibroblastsChinese hamster65.0 × 103 (**)[166]
Heteractis crispaActinoporin RTX-AHL-60 Promyelocytic leukemia Human1.06 (♦) [169]
HeLaCervix carcinoma Human2.26 (♦)
THP-1 Monocytic leukemia Human1.11 (♦)
MDA-MB-231 Breast cancer Human4.64 (♦)
SNU-C4Colon cancer Human4.66 (♦)
Cl 41Epidermal cellsMouse0.57 (♦)
Sagartia roseaAcidic actinoporin Src IU251 Glioblastoma Human3.5[26]
NSCLC Non-small cell lung carcinomaHuman 2.8
BEL-7402Liver carcinoma Human 3.6
Human 7.4
BGC-823 Stomach adenocarcinomaMouse3.4
NIH/3T3NIH Swiss embryo
Urticina piscivoraCrude extractKB Epidermoid carcinoma (#)Human 6.54 [25]
HEL299Embryonic lungHuman 10.07
L1210Lymphocytic leukemiaMouse2.34
Urticina piscivoraUpI (protein)KB Epidermoid carcinoma (#)Human 40.32 [25]
HEL299Embryonic lung Human 29.99
L1210Lymphocytic leukemiaMouse29.74
(*) Values expressed as mole/L; (**) values expressed as nematocysts/mL; (♦) values expressed as nM; (#) to date considered a HeLa cell contaminant.

3.4. Cytotoxicity of Extracts from Scyphozoa

Jellyfish venoms have been studied since the early 1980s on cultured cells. High doses of crude or fractionated venom from sea nettle Chrysaora quinquecirrha (Semaeostomeae) were seen to produce morphological changes in CHO K-1 cells, to inhibit cell growth and to interfere with intracellular uridine and thymidine incorporation, while low doses induced mitogenic activity; furthermore, rabbit erythrocytes were agglutinated by partially purified venom in the presence of calcium [173]. A contemporary study showed that venom from Chrysaora quinquecirrha induced nuclear alterations on K-1 cells (Chinese hamster ovary) with production of multi-nucleated cells and multiple nucleoli as well as loss of peripheral chromatin and dissolution of intercellular collagen as a consequence of its enzymatic (collagenase, protease and lectin-like) activity [174]. Cao et al. [175] observed that the venom of Chrysaora quinquecirrha, which is composed of several polypeptides, is highly toxic for non-malignant human hepatocytes ATCC CCL-13. A transient increase and a subsequent decrease of metabolic activity, evaluated as production of acidic metabolites, followed by cell death was observed within 30 min caused by 28 μg protein/mL medium. Higher doses showed the same trend but delayed activity. On the contrary, the lowest studied dose (0.3 mg protein/mL medium) caused an increase of metabolic activity that did not fall within 2 h. Phosphorylation or alkylation of cell protein(s) was observed to interfere with the toxicity of sea nettle venom [175]. The venom of Chrysaora quinquecirrha was observed to also be toxic to cultured rat hepatocytes, but its activity was not Ca2+ dependent [176].
The jellyfish Cyanea capillata and Cyanea lamarckii (Semaeostomeae) were the subject of a study aimed to evaluate the enzymatic, cytotoxic and hemolytic potency of their venoms. Purified cnidocyst extracts from fishing and mesenteric tentacles of both jellyfish induced strong damage to hepatoma cells HepG2 (10% cell survival) after treatment with 33.3 μgprotein/mL. PLA2-like activity was demonstrated in extracts from mesenteric and fishing tentacles of both jellyfish [46]. Cultured rainbow trout gill cells RTgill-W1 exposed to increasing protein concentrations of crude venoms extracted from fishing tentacles and oral arms of Cyanea capillata and Aurelia aurita showed dose-dependent survival decrease evidenced by detachment, clumping and lysis and morphological changes after 1 h of treatment. The cytotoxic effect was evident starting from a concentration >2.0 μg/mL of venom (protein). C. capillata oral arms venom induced a percent cell viability ranging from 7.4 to 36.4 according to the size of the umbrella. The treatment with 0.2 μg 104 cells−1 oral arms and fishing tentacles venom from A. aurita allowed 15% and 18% cell survival, respectively. In this research, the venom from oral arm cnidocysts was indicated to be more cytotoxic that that from fishing tentacles at the same protein concentration [177]. A novel cytotoxic protein was isolated from the fishing tentacle venom of Cyanea capillata and tested on human hepatocytes HepG2. The purified protein CcTX-1 (MW of the main isoform = 31.17 kDa) showed strong cytotoxicity and caused the death of nearly all treated cells at a concentration of 1.3 μg/mL. The amino acid sequence of CcTX-1 was shown to be similar to that of haemolysins from Cubozoans Carybdea alata (CaTX-1) and Carybdea rastonii (CrTX-1) [4]. In another paper, the size of fishing tentacles and oral arms as well as the nematocyst (A-isorhizas and O-isorhizas) number and size that correspond to the size of the umbrella, were correlated with the cytotoxic and neurotoxic potency in differently-sized Cyanea capillata (L.) showing that the greater the specimen, the higher the cytotoxicity and neurotoxicity. Rainbow trout (RTgill-W1) cells were highly sensitive to the crude venom with a minimal effect at concentrations of 1 μg/mL and 2 μg/mL for venoms from oral arms and from fishing tentacles, respectively, and EC50 values ranging from 3.9–10.1 μg/mL for small medusae and from 8.0 to 4.5 μg/mL for a large medusa. All samples, both from large and from small medusae, showed a dose-dependent neurotoxic activity in vitro on mouse neuroblastoma Neuro 2A CCL 131 cell line, with a remarkable neurotoxic activity of fishing tentacle venom from the large medusa [47]. The venom from the nematocysts of Cyanea nozakii Kishinouye was assessed for cytotoxicity on Bel-7402 and SMMC-7721 human hepatoma cells and on H630 human colon cancer cells. H630 cells showed the highest sensitivity (IC50 = 15.9, 8.8 and 5.1 μg/mL after incubation for 12, 24 and 48 h, respectively) followed by Bel-7402 (17.9 μg/mL) and SMMC-7721 (24.3 μg/mL). The cytotoxicity was time- and dose-dependent, showed the best efficacy at pH values ranging from 4.5 to 8.5, was affected by temperature and lost its efficacy when pre-incubated at temperatures of 60 and 80 °C. The venom seems to be able to damage cell membrane as verified with the percent Lactate dehydrogenase (LDH) release which increased with time and venom concentration [178].
The mauve stinger Pelagia noctiluca is the main stinging Mediterranean jellyfish, able to cause remarkable toxicity and systemic damage [168,179]. The first evidence of cytotoxicity induced by crude venom of this jellyfish was reported in mid-1990s when long-term treatment with the crude venom (150,000 nematocysts/mL) caused cell growth decrease (38%) of V79 cells in comparison to controls. Lower doses (30,000 and 15,000 nematocysts/mL) caused cell growth decreases of 45% and 61%, respectively [165]. Subsequently, the crude venom of this jellyfish was seen to induce ATP increase in treated V79 cells and remarkable survival decrease of 1–3 hour-treated cells with IC50 values ranging from 74.2 × 103 to 29.8 × 103 nematocysts/mL [180]. Recently, Pelagia noctiluca venom was shown to cause overproduction of ROS with oxidative damage, increasing catalase activity and induction of lipid peroxidation (increasing malondialdehyde generation) with consequent genotoxic effects and DNA fragmentation in human colon (HCT 116) cancer cells [181]. Morabito et al. [2] studied the effect of nematocyst crude venom from Pelagia noctiluca on neuronal-like cells derived from human neuroblastoma SH-SY5Y. Doses ranging from 0.05 to 0.5 μg/mL of lyophilized and re-suspended in PBS crude venom were shown to induce oxidative stress and to affect cell viability through a dose- and time-dependent production of intracellular reactive oxygen species (ROS) and changes in mitochondrial transmembrane potential. The antioxidant N-acetyl-cysteine was able to counteract cell viability decrease and ROS production. The induction of oxidative stress was supposed to be caused by disruption of mitochondrial membrane with the consequence to inhibit mitochondrial respiration and uncouple oxidative phosphorylation [2].
The anti-tumoral activity of crude venom and of four crude venom fractions (F1, F2, F3, F4) extracted from Pelagia noctiluca through sephadex G-75 chromatography was investigated for anti-proliferative and anti-cell adhesion of human glioblastoma (U87) cells. The cytotoxicity of unfractionated crude venom and of two fractions (F1 and F3) was emphasized (IC50 values of 180, 125 and 179 μg/mL, respectively). An important time-dependent, anti-proliferative activity was observed in treatments with F1 and F2 while less evidence was shown by crude venom (fair activity) and F3 (low activity). The crude venom and F1, F2 and F3 fractions also caused a dose-dependent inhibition of cell adhesion to fibrinogen. The authors attributed this activity to the interaction of venom with integrins [1] and stated that Pelagia noctiluca venom may play a role in the development of anti-cancer drugs. Very recent results indicate that the toxicity of Pelagia noctiluca seems to be caused by the generation of reactive oxygen species (ROS). In fact, the dose- and time-dependent mortality observed on Vero cells (green monkey kidney) after treatment with crude extracts from P. noctiluca nematocysts was lowered by Vitamin E, which therefore seems to have a cytoprotective effect against the oxidative stress that was supposed to be the major mechanism of toxicity of Pelagia noctiluca [182].
As concerns the Rhizostomeae, the crude toxin from Rhizostoma pulmo was found to produce cytotoxic effects and growth inhibition on V79 cells both after short- and long-time treatments with an IC50 value of 39.9 × 103 nematocysts/mL [43,165,166]. The crude venom from Rhizostoma pulmo was analyzed by HPLC after soaking of oral arms in distilled water, obtaining a sample devoid of nematocysts. HPLC analysis provided five peaks and the subsequent preliminary cytotoxic assays on V79 cells using the single HPLC fractions indicated that a fraction, named fraction “b”, was highly cytotoxic [44]. The cytotoxicity of collagen from Rhizostoma pulmo and the effects on cell adhesion of primary fibroblasts, osteoblastic (MG-63), epithelial (HaCat) and fibrosarcoma (HT-1080) cell lines cultured on jellyfish collagen-coated wells was studied recently. After two and eight days, the amount of viable cells was not significantly different from controls indicating the harmlessness of jellyfish collagen [183].
Cotylorhiza tuberculata was always considered a non-dangerous jellyfish. In spite of this very recent result, [3] indicate that fractionated extracts of whole jellyfish characterized by HPLC, GC-MS and SDS-PAGE showed antioxidant activity and affected cell viability and intercellular communication of breast cancer cells (MCF-7) and human epidermal keratinocytes (HEKa). MCF-7 cells were found to be more sensitive to the extracts. The modulation of intercellular communication was hypothesized to play a role in the anticancer bioactivity [3].
The incidence and growth of SNC tumors induced by N-Ethyl-N-Nitrosourea were shown to be affected by the crude venom of Cassiopea xamachana [184]. Crude venom from the giant jellyfish Nemopilema nomurai (Rhizostomeae) occurring in the waters of China, Korea and Japan was found to be cytotoxic and hemolytic in vitro and showed high cytotoxicity against H9C2 heart myoblasts (LC50 = 2 μg/mL). These findings allowed the authors to assert that Nemopilema nomurai venom can exert a selective toxicity on cardiac tissue in vivo. Venom activity was retained at low temperature (≤20 °C) and high pH (pH ≤ 12), but was lost at high temperature (≥60 °C) and at low pH (pH ≤ 4) [45].
Cell-damaging activity of other scyphozoans has been related with the proteolytic activity of their venoms. Assessing the cytotoxicity of four Scyphozoan jellyfish (Nemopilema nomurai, Rhopilema esculenta, Cyanea nozakii, and Aurelia aurita) on NIH 3T3 cells, a cytotoxic potency scale C. nozakii > N. nomurai > A. aurita > R. esculenta was reported. The metalloproteinases were indicated to play an important role in jellyfish toxicity [185]. A very recent paper [22] evaluated the activity of extracts from Coronatae scyphozoans Atolla vanhoeffeni, Atolla wyvillei and Periphylla periphylla on mouse leukemia L1210. Only for Atolla vanhoeffeni was it possible to calculate the IC50 value which was found to be very high (740 mg/mL). Table 4 shows a summary of data pertinent to papers concerning Scyphozoa.
Table 4. Cytotoxicity to different cell lines of compounds extracted from jellyfish (Scyphozoa).
Table 4. Cytotoxicity to different cell lines of compounds extracted from jellyfish (Scyphozoa).
SpeciesCompound or materialCellsTissue/organ/histologyOrganismIC50–ED50 (μg/mL)Ref.
Atolla vanhoeffeni Water soluble extractL1210Lymphocytic leukemiaMouse740 (°)[22]
Cyanea capillata Fishing tentacle extractHepG2HepatomaHuman20.3[46]
Cyanea capillataPreparations from nematocyst suspensionsRTgill W1 Neuro 2ANormal gill NeuroblastomaRainbow trout Mouse3.9–10.1[47]
Not indicated
Cyanea nozakiiCrude extractBel-7402 Hepatoma Human17.9 [178]
SMMC-7721 HepatomaHuman24.3
H630Colon cancerHuman5.1–15.9
Pelagia noctiluca Crude venomV79Normal lung fibroblastsChinese hamster29.8–74.2 × 103 (**)[180]
Pelagia noctiluca Crude venomHCT 116Colon cancerHuman320[181]
Pelagia noctiluca Crude venomU87GlioblastomaHuman180[1]
Pelagia noctiluca Crude venomVeroNormal kidney cellsMonkey64–112 × 103 (**) (MTT) 20–90 × 103 (**) (NR)[182]
Rhizostoma pulmo Crude venomV79Normal lung fibroblastsChinese hamster39.9 × 103 (**)[43,165,166]
Cotylorhiza tuberculata Extract (pigments, fatty acids, polypeptides)MCF-7 Breast adenocarcinomaHuman 0.015[3]
HEKaNormal keratinocytesHuman
Nemopilema nomurai Crude venomH9C2 Heart myoblastsRat 2.0 (*)[45]
C2C12Muscle myoblastsMouse12.2 (*)
(*) Values expressed as LC50; (**) values expressed as nematocysts/mL; (°) as reported in the paper in the legend of Table 1.

3.5. Cytotoxicity of Extracts from Hydrozoa

Reports of the cytotoxic properties of extracts from hydrozoans are quite scarce; in early 1980s, a study showed that venom from Portugese man-o’war Physalia physalis induced nuclear alterations on K-1 cells (Chinese hamster ovary) with production of multi-nucleated cells and multiple nucleoli, as well as loss of peripheral chromatin and dissolution of intercellular collagen, as a consequence of the enzymatic activity (collagenase, protease and lectin-like) of venom [174]. Subsequently, the separation of nematocysts of Physalia physalis on the basis of size emphasized that venom from small nematocysts (10.6 nm diameter) was lethal to in vitro cultured chick embryonic cardiocytes at 0.6 μg protein/culture; on the contrary, the venom from great nematocysts (23.5 nm diameter) at 20 μg protein/culture was ineffective [186]. Recently, the venom of Physalia physalis was tested on mouse fibroblast cell line L-929 [187], and two novel toxins (PpV9.4, PpV19.3, with molecular weights 550.7 and 4720.9 Da, respectively) were purified from this siphonophore. Pancreatic beta-cells cultured for one day in RPMI-1640 increased insulin secretion and showed cytosolic Ca2+ increase after treatment with both toxins [188]. The evaluation of cytotoxicity to V79 cells of crude venom from Aequorea aequorea, a species that was never studied before from the toxicological point of view, indicated an IC50 value of 76.6 × 103 nematocysts/mL [166] and a remarkable activity after long-time treatment [165]; therefore, this jellyfish seems to be able to affect cell growth rate with slow activity in time. A noncnidocystic toxin, homologous with pore-forming proteins having specific activity toward arthropods, was isolated in green hydra Chlorohydra viridissima [189]. Its toxicity was seen to be differential toward insect (SF-9) and human (HEK293) cultured cells. Large amounts of this depolarizing toxin found in Hydra could be secreted into the coelenteric fluid and have a role in keeping the prey paralyzed after ingestion perhaps allowing also an extracellular digestion [189]. Kawabata et al. [22] recently evaluated on mouse leukemia L1210 cells the activity of extracts from deep-sea hydrozoan jellyfish, the anthomedusan Pandea rubra, the trachymedusae Arctapodema sp., Colobonema sericeum, Crossota rufobrunnea, Halicreas minimum, Pantachogon haeckeli, and the narcomedusae Aeginura grimaldii, Aegina citrea, Solmissus sp. A clear cytotoxicity was caused especially by Aegina citrea (IC50 = 100 μg/mL), Pantachogon haeckeli (IC50 = 160 μg/mL), Aeginura grimaldii (IC50 = 170 μg/mL), and Arctapodema sp. (IC50 = 190 μg/mL) extracts; higher values were obtained with Colobonema sericeum (IC50 = 420 μg/mL) and Halicreas minimum (IC50 = 750 μg/mL) extracts. As heat- and methanol-treated extracts did not show bioactivity, a high incidence of water-soluble bioactive substances and the presence of unstable bioactive proteins in water-soluble extracts were supposed to occur in these hydrozoans [22].

3.6. Cytotoxicity of Extracts from Cubozoa

Cubozoans are well known for their danger and for the potential lethal effects that they can induce on humans. In spite of this, the research on the activity of cubozoan venoms at cellular level is still scarcely developed. Sun et al. [190] demonstrated that the growth of human U251 and rat C6 malignant glioma cells and that of transformed vascular endothelial ECV 304 cells was inhibited by box jellyfish Chiropsalmus quadrigatus venom that caused also DNA fragmentation and signs of apoptosis. In U251 cells, the increase of p53 expression was recorded. This was indicated as one of mechanisms through which the venom of Chiropsalmus quadrigatus induces apoptosis in glioma and endotelial cells, thus the possible application of apoptosis-inducing venom in the therapy of gliomas has been emphasized. The venom from the box jellyfish Chironex fleckeri specimens collected in different zones of Northern Australia was screened for cytotoxicity on rat aortic smooth muscle cell line A7r5. A concentration-dependent cytotoxicity (IC50 values ranging from 0.7 to 0.03 μg/mL) was observed but this activity differed according to the season in which the specimens were collected. These differences were observed also in the composition of venom that was analyzed by size exclusion HPLC and SDS-PAGE profiles. The authors concluded that “there is considerable geographical variation in the composition of C. fleckeri venoms which [...] may explain the geographical variation in reported deaths” [191]. The unfractionated (whole) venom from C. fleckeri was see to cause dose-response detachment of human cardiac myocytes from culture wells. After fractionation of the venom with size exclusion chromatography (FPLC), one portion of the venom (mean size approximately 65 kDa) was seen to cause approximately 80% cell detachment from substratum and death after 30 min [192].

4. Conclusions

Natural venoms produced by cnidarians—as a rule utilized for defense/offense purposes and for predation—are a research subject of great concern because many of these compounds can have pharmacological activity and could be used as future drugs. As a matter of fact, it is well known that approximately one third of the best selling drugs are derived from natural sources or have been developed on the basis of lead natural structures [193]. For this reason, the research of novel drugs is focused on the discovery of new compounds among which those derived from marine organisms are viewed with particular interest. The cytotoxicity of cnidarian venoms has been studied for decades leading to results that emphasize the strong activity of several of them, in particular against cancer cells, and the literature on this subject is enormous. Several cnidarian venoms have been demostrated to inhibit cell growth—for example, interfering with cell metabolism or inhibing DNA synthesis—and some of them were seen to be able to block the cell cycle. Furthermore, because some cnidarian venoms were indicated to be apoptosis-inducing, this could be another tool to be used against target malignant cells. Several cnidarian venoms were found to be aspecifically cytotoxic on different cancer or normal cells but some of them showed specificity for definite cell lines. On the whole, many types of venom were found to be active on leukemic cells and colorectal adenocarcinoma cells. In addition, the importance of some compounds extracted from cnidarians is a matter of concern because they seem to improve the activity of chemotherapeutic drugs at appropriate venom concentration. This could allow a reduction in the amount of administered chemotherapeutics reducing also their unpleasant effects. In conclusion, cnidarian venoms, due to some remarkable features such as their capability to produce damage at cellular and tissue levels, to affect the permeability of cell membrane and ion exchange, to cause cell lysis or to modify metabolic pathways, could be utilized as weapons against specific targets or for different therapeutic purposes. Therefore, further research about these compounds is essential to elucidate their action mechanisms and to make them useful for therapy.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Ayed, Y.; Bousabbeh, M.; Mabrouk, H.B.; Morjen, M.; Marrakchi, N.; Bacha, H. Impairment of the cell-to-matrix adhesion and cytotoxicity induced by the Mediterranean jellyfish Pelagia noctiluca venom and its fractions in cultured glioblastoma cells. Lipids Health Dis. 2012, 11, 84. [Google Scholar]
  2. Morabito, R.; Condello, S.; Currò, M.; Marino, A.; Ientile, R.; La Spada, G. Oxidative stress induced by crude venom from the jellyfish Pelagia noctiluca in neuronal-like differentiated SH-SY5Y cells. Toxicol. In Vitro 2012, 26, 694–699. [Google Scholar]
  3. Leone, A.; Lecci, R.M.; Durante, M.; Piraino, S. Extract from the zooxanthellate jellyfish Cotylorhiza tuberculata modulates gap junction intercellular communication in human cell cultures. Mar. Drugs 2013, 11, 1728–1762. [Google Scholar] [CrossRef]
  4. Lassen, S.; Helmholz, H.; Ruhnau, C.; Prange, A. A novel proteinaceous cytotoxin from the northern Scyphozoa Cyanea capillata (L.) with structural homology to cubozoan haemolysins. Toxicon 2011, 57, 721–729. [Google Scholar]
  5. Marino, A.; Morabito, R.; La Spada, G. Physiology of Nematocytes. In Proceedings of the 83° Congresso Nazionale SIBS, Palermo, Italy, 24–25 October 2013. Abstract Number 36.
  6. Mariscal, R.N. Nematocysts. In Coelenterate Biology; Muscatine, L., Lenhoff, H.M., Eds.; Academic Press: New York, NY, USA, 1974; pp. 129–178. [Google Scholar]
  7. Weinheimer, A.J.; Spraggins, R.L. The occurrence of two new prostaglandin derivatives (15-epi-PGA2 and its acetate, methyl ester) in the Gorgonian Plaxaura homomalla. Chemistry of Coelenterates. XV. Tetrahedron Lett. 1969, 10, 5185–5188. [Google Scholar] [CrossRef]
  8. Moore, R.E.; Scheuer, P.J. Palytoxin: A new marine toxin from a Coelenterate. Science 1971, 172, 495–498. [Google Scholar]
  9. Kohl, A.C.; Kerr, R.G. Pseudopterosin biosynthesis: Aromatization of the diterpene cyclase product, Elisabethatriene. Mar. Drugs 2003, 1, 54–65. [Google Scholar] [CrossRef]
  10. Crone, H.D.; Keen, T.E.B. Chromatographic properties of the hemolysin from the cnidarian Chironex fleckeri. Toxicon 1969, 7, 79–87. [Google Scholar] [CrossRef]
  11. Keen, T.E.B.; Crone, H.D. The hemolytic properties of extracts of tentacles from the cnidarian Chironex fleckeri. Toxicon 1969, 7, 55–63. [Google Scholar] [CrossRef]
  12. Keen, T.E.B. Surface properties of the hemolytic fraction derived from tentacles extracts of Chironex fleckeri. Toxicon 1972, 10, 587–596. [Google Scholar] [CrossRef]
  13. Tamkun, M.M.; Hessinger, D.A. Isolation and partial characterization of a hemolytic and toxic protein from the nematocyst venom of the Portuguese Man-of-War, Physalia physalis. Biochim. Biophys. Acta 1981, 667, 87–98. [Google Scholar] [CrossRef]
  14. Hessinger, D.A.; Lenhoff, H.M. Binding of active and inactive hemolytic factor of sea anemone nematocyst venom to red blood cells. Biochem. Biophys. Res. Commun. 1973, 53, 475–481. [Google Scholar] [CrossRef]
  15. Hessinger, D.A.; Lenhoff, H.M. Assay and properties of the hemolysis activity of pure venom from the nematocysts of the acontia of the sea anemone Aiptasia pallida. Arch. Biochem. Biophys. 1973, 159, 629–638. [Google Scholar] [CrossRef]
  16. Macek, P.; Lebez, D. Kinetics of hemolysis induced by equinatoxin, a cytolytic toxin from the sea anemone Actinia equina. Effect of some ions and pH. Toxicon 1981, 19, 233–240. [Google Scholar] [CrossRef]
  17. Turk, T.; Macek, P. Effect of different membrane lipids on the hemolytic activity of equinatoxin II from Actinia equina. Period. Biol. 1986, 88, 216–217. [Google Scholar]
  18. Macek, P.; Lebez, D. Isolation and characterization of three lethal and hemolytic toxins from the sea anemone Actinia equina L. Toxicon 1988, 26, 441–451. [Google Scholar] [CrossRef]
  19. Cariello, L.; Romano, G.; Spagnuolo, A.; Zanetti, L. Isolation and partial characterization of rhizolysin, a high molecular weight protein with hemolytic activity from the jellyfish Rhizostoma pulmo. Toxicon 1988, 26, 1057–1065. [Google Scholar] [CrossRef]
  20. Long, K.O.; Burnett, J.W. Isolation, characterization, and comparison of hemolytic peptides in nematocyst venoms of two species of jellyfish (Chrysaora quinquecirrha and Cyanea capillata). Comp. Biochem. Physiol. B 1989, 94, 641–646. [Google Scholar]
  21. Hessinger, D.A.; Lenhoff, H.M. Membrane structure and function. Mechanism of hemolysis induced by nematocyst venom: Roles of phospholipase A and direct lytic factor. Arch. Biochem. Biophys. 1976, 176, 603–613. [Google Scholar] [CrossRef]
  22. Kawabata, T.; Lindsay, D.J.; Kitamura, M.; Konishi, S.; Nishikawa, J.; Nishida, S.; Kamio, M.; Nagai, H. Evaluation of the bioactivities of water-soluble extracts from twelve deep-sea jellyfish species. Fish. Sci. 2013, 79, 487–494. [Google Scholar] [CrossRef]
  23. Anderluh, G.; Maček, P. Cytolytic peptide and protein toxins from sea anemones (Anthozoa: Actiniaria). Toxicon 2002, 40, 111–124. [Google Scholar]
  24. Avila, A.D.; Mateo de Acosta, C.; Lage, A. A new immunotoxin built by linking a hemolytic toxin to a monoclonal antibody specific for immature T lymphocytes. Int. J. Cancer 1988, 42, 568–571. [Google Scholar] [CrossRef]
  25. Cline, E.I.; Wiebe, L.I.; Young, J.D.; Samuel, J. Toxic effects of the novel protein UpI from the sea anemone Urticina piscivora. Pharmacol. Res. 1995, 32, 309–314. [Google Scholar] [CrossRef]
  26. Jiang, X.; Chen, H.; Yang, W.; Liu, Y.; Liu, W.; Wei, J.; Tu, H.; Xie, X.; Wang, L.; Xu, A. Functional expression and characterization of an acidic actinoporin from sea anemone Sagartia rosea. Biochem. Biophys. Res. Commun. 2003, 312, 562–570. [Google Scholar] [CrossRef]
  27. Marino, A.; Morabito, R.; La Spada, G. Factors altering the haemolytic power of crude venom from Aiptasia. mutabilis (Anthozoa) nematocysts. Comp. Biochem. Physiol. A 2009, 152, 418–422. [Google Scholar] [CrossRef]
  28. Miyamoto, T.; Yamada, K.; Ikeda, N.; Komori, T.; Higuchi, R. Bioactive terpenoids from Octocorallia, I. Bioactive diterpenoids: Litophynols A and B from the mucus of the soft coral Litophyton sp. J. Nat. Prod. 1994, 57, 1212–1219. [Google Scholar] [CrossRef]
  29. Karthikayalu, S.; Rama, V.; Kirubagaran, R.; Venkatesan, R. Hemolytic toxin from the soft coral Sarcophyton trocheliophorum: Isolation and physiological characterization. J. Venom. Anim. Toxins. Incl. Trop. Dis. 2010, 16, 107–120. [Google Scholar]
  30. Reimão, J.Q.; Migotto, A.E.; Kossuga, M.H.; Berlinck, R.G.; Tempone, A.G. Antiprotozoan activity of Brazilian marine cnidarian extracts and of a modified steroid from the octocoral Carijoa riisei. Parasitol. Res. 2008, 103, 1445–1450. [Google Scholar] [CrossRef]
  31. Brinkman, D.L.; Burnell, J.N. Biochemical and molecular characterisation of cubozoan protein toxins. Toxicon 2009, 54, 1162–1173. [Google Scholar] [CrossRef]
  32. Azuma, H.; Ishikawa, M.; Nakajima, T.; Satoh, A.; Sekizaki, S. Calcium-dependent contractile response of arterial smooth muscle to a jellyfish toxin (pCrTX: Carybdea rastonii). Br. J. Pharmacol. 1986, 88, 549–559. [Google Scholar] [CrossRef]
  33. Azuma, H.; Sekizaki, S.; Satoh, A.; Nakajima, T.; Ishikawa, M. Platelet aggregation caused by a partially purified jellyfish toxin from Carybdea rastonii. Toxicon 1986, 24, 489–499. [Google Scholar] [CrossRef]
  34. Azuma, H.; Sekizaki, S.; Satoh, A.; Nakajima, T. Platelet aggregation caused by Carybdea rastonii toxins (CrTX-I, II and III) obtained from a jellyfish, Carybdea rastonii (42305). Proc. Soc. Exp. Biol. Med. 1986, 182, 34–42. [Google Scholar] [CrossRef]
  35. Othman, I.; Eldila, M.T.; Mustafa, M.R.; Musa, M.Y.; Nor Azila, M.A. Studies on the jellyfish Carybdea rastoni. Toxicon 1996, 34, 167–168. [Google Scholar]
  36. Rottini, G.; Gusmani, L.; Parovel, E.; Avian, M.; Patriarca, P. Purification and properties of a cytolytic toxin in venom of the jellyfish Carybdea marsupialis. Toxicon 1995, 33, 315–326. [Google Scholar] [CrossRef]
  37. Sánchez-Rodríguez, J.; Torrens, E.; Segura-Puertas, L. Partial purification and characterisation of a novel neurotoxin and three cytolysins from the box jellyfish (Carybdea marsupialis) nematocyst venom. Arch. Toxicol. 2006, 80, 163–168. [Google Scholar] [CrossRef]
  38. Chung, J.J.; Fernandez, K.; Ratnapala, L.A.; Cooke, I.M.; Yanagihara, A.A. Partial purification and characterization of Hawaiian box jellyfish (Carybdea alata) venom. Pac. Sci. 2000, 54, 90. [Google Scholar]
  39. Chung, J.J.; Ratnapala, L.A.; Cooke, I.M.; Yanagihara, A.A. Partial purification and characterization of a hemolysin (CAH1) from Hawaiian box jellyfish (Carybdea alata) venom. Toxicon 2001, 39, 981–990. [Google Scholar] [CrossRef]
  40. Nagai, H.; Takuwa-Kuroda, K.; Nakao, M.; Oshiro, N.; Iwanaga, S.; Nakajima, T. A novel protein toxin from the deadly box jellyfish (sea wasp, habu-kurage) Chiropsalmus quadrigatus. Biosci. Biotechnol. Biochem. 2002, 66, 97–102. [Google Scholar] [CrossRef]
  41. Brinkman, D.; Burnell, J. Identification, cloning and sequencing of two major venom proteins from the box jellyfish, Chironex fleckeri. Toxicon 2007, 50, 850–860. [Google Scholar] [CrossRef]
  42. Brinkman, D.; Burnell, J. Partial purification of cytolytic venom proteins from the box jellyfish, Chironex fleckeri. Toxicon 2008, 51, 853–863. [Google Scholar] [CrossRef]
  43. Allavena, A.; Mariottini, G.L.; Carli, A.M.; Contini, S.; Martelli, A. In vitro evaluation of the cytotoxic, hemolytic and clastogenic activities of Rhizostoma pulmo toxin(s). Toxicon 1998, 36, 933–936. [Google Scholar] [CrossRef]
  44. Mazzei, M.; Allavena, A.; Garzoglio, R.; Mariottini, G.L.; Carli, A. Chemical and chromatographic characteristics of toxin from the jellyfish Rhizostoma pulmo Agassiz (Cnidaria: Scyphozoa). Pharmacol. Toxicol. 1995, 76, 38. [Google Scholar]
  45. Kang, C.; Munawir, A.; Cha, M.; Sohn, E.-T.; Lee, H.; Kim, J.-S.; Yoon, W.D.; Lim, D.; Kim, E. Cytotoxicity and hemolytic activity of jellyfish Nemopilema nomurai (Scyphozoa: Rhizostomeae) venom. Comp. Biochem. Physiol. C 2009, 150, 85–90. [Google Scholar]
  46. Helmholz, H.; Ruhnau, C.; Schütt, C.; Prange, A. Comparative study on the cell toxicity and enzymatic activity of two northern scyphozoan species Cyanea capillata (L.) and Cyanea lamarckii (Péron & Léslieur). Toxicon 2007, 50, 53–64. [Google Scholar] [CrossRef]
  47. Helmholz, H.; Wiebring, A.; Lassen, S.; Ruhnau, C.; Schuett, C.; Prange, A. Cnidom analysis combined with an in vitro evaluation of the lytic, cyto- and neurotoxic potential of Cyanea capillata (Cnidaria: Scyphozoa). Sci. Mar. 2012, 76, 339–348. [Google Scholar] [CrossRef]
  48. Wang, T; Wen, X.J.; Mei, X.B.; Wang, Q.Q.; He, Q.; Zheng, J.M.; Zhao, J.; Xiao, L.; Zhang, L.M. Lipid peroxidation is another potential mechanism besides pore-formation underlying hemolysis of tentacle extract from the jellyfish Cyanea capillata. Mar. Drugs 2013, 11, 67–80. [Google Scholar] [CrossRef]
  49. Marino, A.; Crupi, R.; Rizzo, G.; Morabito, R.; Musci, G.; La Spada, G. The unusual toxicity and stability properties of crude venom from isolated nematocysts of Pelagia noctiluca. Cell. Mol. Biol. 2007, 53, 994–1002. [Google Scholar]
  50. Marino, A.; Morabito, R.; La Spada, G. Toxicity of crude venom from the Scyphozoan Pelagia noctiluca. Comp. Biochem. Physiol. A 2009, 154, 30. [Google Scholar] [CrossRef]
  51. Marino, A.; Morabito, R.; Pizzata, T.; La Spada, G. Effect of various factors on Pelagia noctiluca (Cnidaria, Scyphozoa) crude venom-induced haemolysis. Comp. Biochem. Physiol. A 2008, 151, 144–149. [Google Scholar] [CrossRef]
  52. Maisano, M.; Trapani, M.R.; Parrino, V.; Parisi, M.G.; Cappello, T.; D’Agata, A.; Benenati, G.; Natalotto, A.; Mauceri, A.; Cammarata, M. Haemolytic activity and characterization of nematocyst venom from Pelagia noctiluca (Cnidaria: Scyphozoa). Ital. J. Zool. 2013, 80, 168–176. [Google Scholar] [CrossRef] [Green Version]
  53. Kikuchi, H.; Tsukitani, Y.; Iguchi, K.; Yamada, Y. Clavulones, new type of prostanoids from the stolonifer Clavularia viridis Quoy and Gaimard. Tetrahedron Lett. 1982, 23, 5171–5174. [Google Scholar] [CrossRef]
  54. Honda, A.; Yamamoto, Y.; Mori, Y.; Yamada, Y.; Kikuchi, H. Antileukemic effect of coral-prostanoids clavulones from the stolonifer Clavularia viridis on human myeloid leukemia (HL-60) cells. Biochem. Biophys. Res. Commun. 1985, 130, 515–523. [Google Scholar] [CrossRef]
  55. Hondo, A.; Mori, Y.; Iguchi, K.; Yamada, Y. Antiproliferative and cytotoxic effects of newly discovered halogenated coral prostanoids from the Japanese stolonifer Clavularia viridis on human myeloid leukemia cells in culture. Mol. Pharmacol. 1987, 32, 530–535. [Google Scholar]
  56. Mori, K.; Iguchi, K.; Yamada, N.; Yamada, Y.; Inouye, Y. Bioactive marine diterpenoids from Japanese soft coral of Clavularia sp. Chem. Pharm. Bull. 1988, 36, 2840–2852. [Google Scholar] [CrossRef]
  57. Yabe, T.; Yamada, H.; Shimomura, M.; Miyaoka, H.; Yamada, Y. Induction of choline acetyltransferase activity in cholinergic neurons by stolonidiol: Structure-activity relationship. J. Nat. Prod. 2000, 63, 433–435. [Google Scholar] [CrossRef]
  58. Watanabe, K.; Sekine, M.; Takahashi, H.; Iguchi, K. New halogenated marine prostanoids with cytotoxic activity from the Okinawan soft coral Clavularia viridis. J. Nat. Prod. 2001, 64, 1421–1425. [Google Scholar] [CrossRef]
  59. Duh, C.-Y.; Chia, M.-C.; Wang, S.-K.; Chen, H.-J.; El-Gamal, A.A.H.; Dai, C.-F. Cytotoxic dolabellane diterpenes from the Formosan soft coral Clavularia inflata. J. Nat. Prod. 2001, 64, 1028–1031. [Google Scholar] [CrossRef]
  60. Hou, R.-S.; Duh, C.-Y.; Chiang, M.Y.; Lin, C.-N. Sinugibberol, a new cytotoxic cembranoid diterpene from the soft Coral Sinularia gibberosa. J. Nat. Prod. 1995, 58, 1126–1130. [Google Scholar] [CrossRef]
  61. Iwashima, M.; Matsumoto, Y.; Takahashi, H.; Iguchi, K. New marine cembrane-type diterpenoids from the okinawan soft coral Clavularia koellikeri. J. Nat. Prod. 2000, 63, 1647–1652. [Google Scholar] [CrossRef]
  62. Schmitz, F.J.; Schulz, M.M.; Siripitayananon, J.; Hossain, M.B.; van der Helm, D. New diterpenes from the gorgonian Solenopodium excavatum. J. Nat. Prod. 1993, 56, 1339–1349. [Google Scholar] [CrossRef]
  63. Cheng, C.-H.; Chung, H.-M.; Hwang, T.-L.; Lu, M.-C.; Wen, Z.-H.; Kuo, Y.-H.; Wang, W.-H.; Sung, P.-J. Echinoclerodane A: A new bioactive clerodane-type diterpenoid from a gorgonian coral Echinomuricea sp. Molecules 2012, 17, 9443–9450. [Google Scholar] [CrossRef]
  64. Chung, H.-M.; Hong, P.-H.; Su, J.-H.; Hwang, T.-L.; Lu, M.-C.; Fang, L.-S.; Wu, Y.-C.; Li, J.-J.; Chen, J.-J.; Wang, W.-H.; et al. Bioactive compounds from a gorgonian coral Echinomuricea sp. (Plexauridae). Mar. Drugs 2012, 10, 1169–1179. [Google Scholar] [CrossRef]
  65. Rueda, A.; Zubía, E.; Ortega, M.J.; Salvá, J. Structure and cytotoxicity of new polyhydroxylated sterols from the Caribbean gorgonian Plexaurella grisea. Steroids 2001, 66, 897–904. [Google Scholar] [CrossRef]
  66. Rueda, A.; Zubía, E.; Ortega, M.J.; Salvá, J. New acyclic sesquiterpenes and norsesquiterpenes from the Caribbean Gorgonian Plexaurella grisea. J. Nat. Prod. 2001, 64, 401–405. [Google Scholar] [CrossRef]
  67. El Sayed, K.A.; Hamann, M.T. A new norcembranoid dimer from the Red Sea soft coral Sinularia gardineri. J. Nat. Prod. 1996, 59, 687–689. [Google Scholar] [CrossRef]
  68. Choi, Y.-H.; Schmitz, F.J. Cytotoxic acylated spermidine from a soft coral, Sinularia sp. J. Nat. Prod. 1997, 60, 495–496. [Google Scholar] [CrossRef]
  69. Weinheimer, A.J.; Matson, J.A.; Hossain, M.B.; van der Helm, D. Marine anticancer agents: Sinularin and dihydrosinularin, new cembranolides from the soft coral, Sinularia flexibilis. Tetrahedron Lett. 1977, 18, 2923–2926. [Google Scholar] [CrossRef]
  70. Duh, C.Y.; Wang, S.K.; Tseng, H.-K.; Sheu, J.-H.; Chiang, M.Y. Novel cytotoxic cembranoids from the soft coral Sinularia flexibilis. J. Nat. Prod. 1998, 61, 844–847. [Google Scholar] [CrossRef]
  71. Reddy, B.S.; Rao, V.D.; Rao, B.S.; Dhananjaya, N.; Kuttan, R.; Babu, T.D. Isolation and structural determination of new sphingolipids and pharmacological activity of Africanene and other metabolites from Sinularia leptoclados. Chem. Pharm. Bull. 1999, 47, 1214–1220. [Google Scholar] [CrossRef]
  72. Chai, M.C.; Wang, S.K.; Dai, C.F.; Duh, C.-Y. A cytotoxic lobane diterpene from the formosan soft coral Sinularia inelegans. J. Nat. Prod. 2000, 63, 843–844. [Google Scholar] [CrossRef]
  73. Su, J.; Yang, R.; Kuang, Y.; Zeng, L. A new cembranolide from the soft coral Sinularia capillosa. J. Nat. Prod. 2000, 63, 1543–1545. [Google Scholar] [CrossRef]
  74. Lu, Y.; Su, H.-J.; Chen, Y.-H.; Wen, Z.-H.; Sheu, J.-H.; Su, J.-H. Anti-inflammatory Cembranoids from the Formosan soft coral Sinularia discrepans. Arch. Pharm. Res. 2011, 34, 1263–1267. [Google Scholar] [CrossRef]
  75. Kikuchi, H.; Manda, T.; Kobayashi, K.; Yamada, Y.; Iguchi, K. Anti-tumor activity of lemnalol isolated from the soft coral Lemnalia tenuis Verseveldt. Chem. Pharm. Bull. 1983, 31, 1086–1088. [Google Scholar] [CrossRef]
  76. Jean, Y.H.; Chen, W.F.; Duh, C.Y.; Huang, S.Y.; Hsu, C.H.; Lin, C.S.; Sung, C.S.; Chen, I.M.; Wen, Z.H. Inducible nitric oxide synthase and cyclooxygenase-2 participate in anti-inflammatory and analgesic effects of the natural marine compound lemnalol from Formosan soft coral Lemnalia cervicorni. Eur. J. Pharmacol. 2008, 578, 323–331. [Google Scholar] [CrossRef]
  77. Duh, C.Y.; Wang, S.K.; Chung, S.G.; Chou, G.-C.; Dai, C.-F. Cytotoxic cembrenolides and steroids from the formosan soft coral Sarcophyton crassocaule. J. Nat. Prod. 2000, 63, 1634–1637. [Google Scholar] [CrossRef]
  78. Dong, H.; Gou, Y.-L.; Kini, R.M.; Xu, H.-X.; Chen, S.-X.; Teo, S.L.M.; But, P.P.-H. A new cytotoxic polyhydroxysterol from soft coral Sarcophyton trocheliophorum. Chem. Pharm. Bull. 2000, 48, 1087–1089. [Google Scholar] [CrossRef]
  79. Wang, G.-H.; Ahmed, A.F.; Kuo, Y.-H.; Sheu, J.-H. Two new subergane-based sesquiterpenes from a Taiwanese Gorgonian coral Subergorgia suberosa. J. Nat. Prod. 2002, 65, 1033–1036. [Google Scholar] [CrossRef]
  80. Wang, G.-H.; Ahmed, A.F.; Sheu, J.-H.; Duh, C.-Y.; Shen, Y.-C.; Wang, L.-T. Suberosols A–D, four new sesquiterpenes with β-caryophyllene skeletons from a Taiwanese gorgonian coral Subergorgia suberosa. J. Nat. Prod. 2002, 65, 887–891. [Google Scholar] [CrossRef]
  81. Wu, S.-L.; Sung, P.-J.; Chiang, M.Y.; Wu, J.-Y.; Sheu, J.-H. New polyoxygenated briarane diterpenoids, briaexcavatolides O-R, from the gorgonian Briareum excavatum. J. Nat. Prod. 2001, 64, 1415–1420. [Google Scholar] [CrossRef]
  82. Morales, J.J.; Lorenzo, D.; Rodríguez, A.D. Application of two-dimensional NMR spectroscopy in the structural determination of marine natural products. Isolation and total structural assignment of 4-deoxyasbestinin diterpenes from the Caribbean gorgonian Briareum asbestinum. J. Nat. Prod. 1991, 54, 1368–1382. [Google Scholar] [CrossRef]
  83. Sheu, J.-H.; Sung, P.-J.; Huang, L.-H.; Lee, S.-F.; Wu, T.; Chang, B.-Y.; Duh, C.-Y.; Fang, L.-S.; Soong, K.; Lee, T.-J. New cytotoxic briaran diterpenes from the Formosan gorgonian Briareum sp. J. Nat. Prod. 1996, 59, 935–938. [Google Scholar] [CrossRef]
  84. Sheu, J.-H.; Sung, P.-J.; Cheng, M.-C.; Liu, H.-Y.; Fang, L.-S.; Duh, C.-Y.; Chiang, M.Y. Novel cytotoxic diterpenes, Excavatolides A-E, isolated from the Formosan gorgonian Briareum excavatum. J. Nat. Prod. 1998, 61, 602–608. [Google Scholar] [CrossRef]
  85. Sung, P.-J.; Su, J.-H.; Wang, G.-H.; Lin, S.-F.; Duh, C.-Y.; Sheu, J.-H. Excavatolides F-M, new briarane diterpenes from the gorgonian Briareum excavatum. J. Nat. Prod. 1999, 62, 457–463. [Google Scholar] [CrossRef]
  86. Sung, P.-J.; Su, J.-H.; Duh, C.-Y.; Chiang, M.Y.; Sheu, J.-H. Briaexcavatolides K-N, new briarane diterpenes from the gorgonian Briareum excavatum. J. Nat. Prod. 2001, 64, 318–323. [Google Scholar] [CrossRef]
  87. Rho, J.-R.; Lee, H.-S.; Seo, Y.; Cho, K.W.; Shin, J. New xenicane diterpenoids from the gorgonian Acalycigorgia inermis. J. Nat. Prod. 2000, 63, 254–257. [Google Scholar] [CrossRef]
  88. Rho, J.-R.; Oh, M.-S.; Jang, K.H.; Cho, K.W.; Shin, J. New xenicane diterpenoids from the gorgonian Acalycigorgia inermis. J. Nat. Prod. 2001, 64, 540–543. [Google Scholar] [CrossRef]
  89. Zeng, L.M.; Li, X.; Su, J.; Fu, X.; Schmitz, F.J. A new cytotoxic dihydroxy sterol from the soft coral Alcyonium patagonicum. J. Nat. Prod. 1995, 58, 296–298. [Google Scholar] [CrossRef]
  90. Palermo, J.A.; Rodríguez Brasco, M.F.; Spagnuolo, C.; Seldes, A.M. Illudalane sesquiterpenoids from the soft coral Alcyonium paessleri: The first natural nitrate esters. J. Org. Chem. 2000, 65, 4482–4486. [Google Scholar] [CrossRef]
  91. Rodríguez Brasco, M.F.; Seldes, A.M.; Palermo, J.A. Paesslerins A and B: Novel tricyclic sesquiterpenoids from the soft coral Alcyonium paessleri. Org. Lett. 2001, 3, 1415–1417. [Google Scholar] [CrossRef]
  92. Rodríguez, A.D.; González, E.; González, C. Additional dolabellane diterpenes from the Caribbean gorgonian octocoral Eunicea laciniata. J. Nat. Prod. 1995, 58, 226–232. [Google Scholar] [CrossRef]
  93. Rodríguez, A.D.; Soto, J.J.; Pina, I.C. Uprolides D-G, 2. A rare family of 4,7-oxa-bridged cembranolides from the caribbean gorgonian Eunicea mammosa. J. Nat. Prod. 1995, 58, 1209–1216. [Google Scholar] [CrossRef]
  94. Rodríguez, A.D.; Acosta, A.L. New cembranoid diterpenes and a geranylgeraniol derivative from the common Caribbean sea whip Eunicea succinea. J. Nat. Prod. 1997, 60, 1134–1138. [Google Scholar] [CrossRef]
  95. Shi, Y.-P.; Rodríguez, A.D.; Barnes, C.L.; Sánchez, J.A.; Raptis, R.G.; Baran, P. New terpenoid constituents from Eunicea pinta. J. Nat. Prod. 2002, 65, 1232–1241. [Google Scholar] [CrossRef]
  96. Kitagawa, I.; Cui, Z.; Byeng Wha, S.; Kobayashi, M.; Kyogoku, Y. Marine natural products XVII. Nephtheoxydiol, a new cytotoxic hydroperoxy-germacrane sesquiterpene, and related sesquiterpenoids from an okinawan soft coral of Nephthea sp. (Nephtheidae). Chem. Pharm. Bull. 1987, 35, 124–135. [Google Scholar] [CrossRef]
  97. Duh, C.Y.; Wang, S.K.; Chu, M.-J.; Sheu, J.-H. Cytotoxic sterols from the soft coral Nephthea erecta. J. Nat. Prod. 1998, 61, 1022–1024. [Google Scholar] [CrossRef]
  98. El-Gamal, A.A.H.; Chiang, C.-Y.; Huang, S.-H.; Wang, S.-K.; Duh, C.-Y. Xenia diterpenoids from the Formosan soft coral Xenia blumi. J. Nat. Prod. 2005, 68, 1336–1340. [Google Scholar] [CrossRef]
  99. El-Gamal, A.A.H.; Wang, S.-K.; Duh, C.-Y. Cytotoxic xenia diterpenoids from the soft coral Xenia umbellata. J. Nat. Prod. 2006, 69, 338–341. [Google Scholar] [CrossRef]
  100. Kato, T.; Fukushima, M. Advances in Prostaglandin, Thromboxane, and Leukotriene Research; Hayaishi, O., Yamamoto, S., Eds.; Raven Press: New York, NY, USA, 1985; Volumm 15, pp. 415–418. [Google Scholar]
  101. Baker, B.J.; Scheuer, P.J. The punaglandins: 10-chloroprostanoids from the octocoral Telesto riisei. J. Nat. Prod. 1994, 57, 1346–1353. [Google Scholar] [CrossRef]
  102. Kioshihara, Y.; Takamori, R.; Nomura, K.; Sugiura, S.; Kurozumi, S. Enhancement of in vitro mineralization in human osteoblasts by a novel prostaglandin A1 derivative TEI-3313. J. Pharmacol. Exp. Ther. 1991, 258, 1120–1126. [Google Scholar]
  103. Liyanage, G.K.; Schmitz, F.J. Cytotoxic amides from the octocoral Telesto riisei. J. Nat. Prod. 1996, 59, 148–151. [Google Scholar] [CrossRef]
  104. Seleghim, M.H.R.; Lira, S.P.; Kossuga, M.H.; Batista, T.; Berlinck, R.G.S.; Hajdu, E.; Muricy, G.; da Rocha, R.M.; do Nascimento, G.G.F.; Silva, M.; et al. Antibiotic, cytotoxic and enzyme inhibitory activity of crude extracts from Brazilian marine invertebrates. Braz. J. Pharmacogn. 2007, 17, 287–318. [Google Scholar]
  105. Kossuga, M.H.; Lira, S.P.; Nascimento, A.M.; Gambardella, M.T.P.; Berlinck, R.G.S.; Torres, Y.R.; Nascimento, G.G.F.; Pimenta, E.F.; Silva, M.; Thiemann, O.H.; et al. Isolamento e atividades biológicas de produtos naturais das esponjas Monanchora arbuscula, Aplysina sp., Petromica ciocalyptoides e Topsentia ophiraphidites, da Ascídia Didemnum ligulum e do Octocoral Carijoa riisei. Química Nova 2007, 30, 1194–1202. [Google Scholar]
  106. Zhao, H.Y.; Shao, C.L.; Li, Z.Y.; Han, L.; Cao, F.; Wang, C.Y. Bioactive pregnane steroids from a South China Sea gorgonian Carijoa sp. Molecules 2013, 18, 3458–3466. [Google Scholar] [CrossRef]
  107. Uchio, Y.; Toyota, J.; Nozaki, H.; Nakayama, M.; Nishizono, Y.; Hase, T. Lobohedleolide and (7Z)-lobohedleolide, new cembranolides from the soft coral Lobophytum hedleyi Whitelegge. Tetrahedron Lett. 1981, 22, 4089–4092. [Google Scholar] [CrossRef]
  108. Wang, S.-K.; Duh, C.-Y.; Wu, Y.-C.; Wang, Y.; Cheng, M.-C.; Soong, K.; Fang, L.-S. Studies on formosan soft corals, II. Cytotoxic cembranolides from the soft coral Lobophytum michaelae. J. Nat. Prod. 1992, 55, 1430–1435. [Google Scholar] [CrossRef]
  109. Duh, C.Y.; Wang, S.K.; Huang, B.T.; Dai, C.-F. Cytotoxic cembrenolide diterpenes from the formosan soft coral Lobophytum crassum. J. Nat. Prod. 2000, 63, 884–885. [Google Scholar] [CrossRef]
  110. Lopp, A.; Pihlak, A.; Paves, H.; Samuel, K.; Koljak, R.; Samel, N. The effect of 9,11-secosterol, a newly discovered compound from the soft coral Gersemia fruticosa, on the growth and cell cycle progression of various tumor cells in culture. Steroids 1994, 59, 274–281. [Google Scholar] [CrossRef]
  111. Ortega, M.J.; Zubía, E.; Salva, J. Structure and absolute configuration of palmonine F, a new eunicellin-based diterpene from the gorgonian Eunicella verrucosa. J. Nat. Prod. 1994, 57, 1584–1586. [Google Scholar] [CrossRef]
  112. Seo, Y.; Cho, K.W.; Chung, H.; Lee, H.-S.; Shin, J. New secosteroids from a gorgonian of the genus Muricella. J. Nat. Prod. 1998, 61, 1441–1443. [Google Scholar] [CrossRef]
  113. Kittakoop, P.; Suttisri, R.; Chaichantipyuth, C.; Vethchagarun, S.; Suwanborirux, K. Norpregnane glycosides from a Thai soft coral, Scleronephthya pallida. J. Nat. Prod. 1999, 62, 318–320. [Google Scholar] [CrossRef]
  114. Bokesch, H.R.; Blunt, J.W.; Westergaard, C.K.; Cardellina, J.H., II; Johnson, T.R.; Michael, J.A.; McKee, T.C.; Hollingshead, M.G.; Boyd, M.R. Alertenone, a dimer of suberosenone from Alertigorgia sp. J. Nat. Prod. 1999, 62, 633–635. [Google Scholar] [CrossRef]
  115. Garrido, L.; Zubía, E.; Ortega, M.J.; Salvá, J. Isolation and structure elucidation of new cytotoxic steroids from the gorgonian Leptogorgia sarmentosa. Steroids 2000, 65, 85–88. [Google Scholar] [CrossRef]
  116. Sheu, J.-H.; Hung, K.-C.; Wang, G.-H.; Duh, C.-Y. New cytotoxic sesquiterpenes from the gorgonian Isis hippuris. J. Nat. Prod. 2000, 63, 1603–1607. [Google Scholar] [CrossRef]
  117. Chen, S.-P.; Sung, P.-J.; Duh, C.-Y.; Dai, C.-F.; Sheu, J.-H. Junceol A, a new sesquiterpenoid from the sea pen Virgularia juncea. J. Nat. Prod. 2001, 64, 1241–1242. [Google Scholar] [CrossRef]
  118. Shen, Y.-C.; Lin, Y.-C.; Ko, C.-L.; Wang, L.-T. New briaranes from the taiwanese Gorgonian Junceella juncea. J. Nat. Prod. 2003, 66, 302–305. [Google Scholar] [CrossRef]
  119. Nakao, Y.; Yoshida, S.; Matsunaga, S.; Fusetani, N. (Z)-Sarcodictyin A, a new highly cytotoxic diterpenoid from the soft coral Bellonella albiflora. J. Nat. Prod. 2003, 66, 524–527. [Google Scholar] [CrossRef]
  120. Yoshikawa, K.; Kanekuni, S.; Hanahusa, M.; Arihara, S.; Ohta, T. Polyhydroxylated sterols from the octocoral Dendronephthya gigantea. J. Nat. Prod. 2000, 63, 670–672. [Google Scholar] [CrossRef]
  121. Reddy, N.S.; Reed, J.K.; Longley, R.E.; Wright, A.E. Two new cytotoxic linderazulenes from a deep-sea gorgonian of the genus Paramuricea. J. Nat. Prod. 2005, 68, 248–250. [Google Scholar] [CrossRef]
  122. Chao, C.H.; Wu, Y.C.; Wen, Z.H.; Sheu, J.H. Steroidal carboxylic acids from soft coral Paraminabea acronocephala. Mar. Drugs 2013, 11, 136–145. [Google Scholar] [CrossRef]
  123. Rho, J. New bioactive steroids from the Gorgonian Acalycigorgia inermis. Bull. Korean Chem. Soc. 2000, 21, 518–520. [Google Scholar]
  124. Maia, L.F.; Epifanio, R.A.; Fenical, W. New cytotoxic sterol glycosides from the octocoral Carijoa (Telesto) riisei. J. Nat. Prod. 2000, 63, 1427–1430. [Google Scholar] [CrossRef]
  125. Duh, C.Y.; Wang, S.K.; Weng, Y.L. Brassicolene, a novel cytotoxic diterpenoid from the Formosan soft coral Nephthea brassica. Tetrahedron Lett. 2000, 41, 1401–1403. [Google Scholar] [CrossRef]
  126. Xu, L.; Patrick, B.O.; Roberge, M.; Allen, T.; van Ofwegen, L.; Andersen, R.J. New diterpenoids from the octocoral Pachyclavularia violacea collected in Papua New Guinea. Tetrahedron 2000, 56, 9031–9037. [Google Scholar] [CrossRef]
  127. Naz, S.; Kerr, R.G.; Narayanan, R. New antiproliferative epoxysecosterols from Pseudopterogorgia americana. Tetrahedron Lett. 2000, 41, 6035–6040. [Google Scholar] [CrossRef]
  128. Sheu, J.H.; Chang, K.C.; Duh, C.Y. A cytotoxic 5α,8α-epidioxysterol from a soft coral Sinularia species. J. Nat. Prod. 2000, 63, 149–151. [Google Scholar] [CrossRef]
  129. Mayer, A.M.S.; Gustafson, K.R. Marine pharmacology in 2000: Antitumor and cytotoxic compounds. Int. J. Cancer 2003, 105, 291–299. [Google Scholar] [CrossRef]
  130. Jiménez, C.; Crews, P. 13C-NMR assignments and cytotoxicity assessment of zoanthoxanthin alkaloids from zoanthid corals. J. Nat. Prod. 1993, 56, 9–14. [Google Scholar] [CrossRef]
  131. Rashid, M.A.; Gustafson, K.R.; Cardellina, J.H., II; Boyd, M.R. Mycalolides D and E, new cytotoxic macrolides from a collection of the stony coral Tubastrea faulkneri. J. Nat. Prod. 1995, 58, 1120–1125. [Google Scholar] [CrossRef]
  132. Fusetani, N.; Toyoda, T.; Asai, N.; Matsunaga, S.; Maruyama, T. Montiporic acids A and B, cytotoxic and antimicrobial polyacetylene carboxylic acids from eggs of the Scleractinian coral Montipora digitata. J. Nat. Prod. 1996, 59, 796–797. [Google Scholar] [CrossRef]
  133. Bae, B.H.; Im, K.S.; Choi, W.C.; Hong, J.; Lee, C.-O.; Choi, J.S.; Son, B.W.; Song, J.-I.; Jung, J.H. New acetylenic compounds from the stony coral Montipora sp. J. Nat. Prod. 2000, 63, 1511–1514. [Google Scholar] [CrossRef]
  134. Alam, N.; Bae, B.H.; Hong, J.; Lee, C.O.; Im, K.S.; Jung, J.H. Cytotoxic diacetylenes from the stony coral Montipora species. J. Nat. Prod. 2001, 64, 1059–1063. [Google Scholar] [CrossRef]
  135. Bellocci, M.; Sala, G.L.; Prandi, S. The cytolytic and cytotoxic activities of palytoxin. Toxicon 2011, 57, 449–459. [Google Scholar] [CrossRef]
  136. Mariottini, G.L.; Pane, L. The role of Cnidaria in drug discovery. A review on CNS implications and new perspectives. Rec. Pat. CNS Drug Discov. 2013, 8, 110–122. [Google Scholar] [CrossRef]
  137. Gabrielson, E.W.; Kuppusamy, P.; Povey, A.C.; Zweier, J.L.; Harris, C.C. Measurement of neutrophil activation and epidermal cell toxicity by palytoxin and 12-O-tetradecanoylphorbol-13-acetate. Carcinogenesis 1992, 13, 1671–1674. [Google Scholar] [CrossRef]
  138. Hoffmann, K.; Hermanns-Clausen, M.; Buhl, C.; Buchler, M.W.; Schemmer, P.; Mebs, D.; Kauferstein, S. A case of palytoxin poisoning due to contact with zoanthid corals through a skin injury. Toxicon 2008, 51, 1535–1537. [Google Scholar] [CrossRef]
  139. Görögh, T.; Bèress, L.; Quabius, E.S.; Ambrosch, P.; Hoffmann, M. Head and neck cancer cells and xenografts are very sensitive to palytoxin: Decrease of c-jun n-terminale kinase-3 expression enhances palytoxin toxicity. Mol. Cancer 2013, 12, 12. [Google Scholar] [CrossRef]
  140. Tosteson, M.T.; Halperin, J.A.; Kishi, Y.; Tosteson, D.C. Palytoxin induces an increase in the cation conductance of red cells. J. Gen. Physiol. 1991, 98, 969–985. [Google Scholar] [CrossRef]
  141. Tosteson, M.T.; Scriven, D.R.; Bharadwaj, A.K.; Kishi, Y.; Tosteson, D.C. Interaction of palytoxin with red cells: Structure-function studies. Toxicon 1995, 33, 799–807. [Google Scholar] [CrossRef]
  142. Tosteson, M.T.; Thomas, J.; Arnadottir, J.; Tosteson, D.C. Effects of palytoxin on cation occlusion and phosphorylation of the (Na+,K+)-ATPase. J. Membr. Biol. 2003, 192, 181–189. [Google Scholar] [CrossRef]
  143. Bonnard, C.; Lechner, J.F.; Gerwin, B.I.; Fujiki, H.; Harris, C.C. Effects of palytoxin or ouabain on growth and squamous differentiation of human bronchial epithelial cells in vitro. Carcinogenesis 1988, 9, 2245–2249. [Google Scholar] [CrossRef]
  144. Rouzaire-Dubois, B.; Dubois, J.M. Characterization of palytoxin-induced channels in mouse neuroblastoma cells. Toxicon. 1990, 28, 1147–1158. [Google Scholar] [CrossRef]
  145. Sagara, T.; Nishibori, N.; Itoh, M.; Morita, K.; Her, S. Palytoxin causes nonoxidative necrotic damage to PC12 cells in culture. J. Appl. Toxicol. 2013, 33, 120–124. [Google Scholar] [CrossRef]
  146. Bignami, G.S.; Senter, P.D.; Grothaus, P.G.; Fischer, K.J.; Humphreys, T.; Wallace, P.M. N-(4'-hydroxyphenylacetyl)palytoxin: A palytoxin prodrug that can be activated by a monoclonal antibody-penicillin G amidase conjugate. Cancer Res. 1992, 52, 5759–5764. [Google Scholar]
  147. Vale, C.; Gómez-Limia, B.; Vieytes, M.R.; Botana, L.M. Mitogen-activated protein kinases regulate palytoxin-induced calcium influx and cytotoxicity in cultured neurons. Br. J. Pharmacol. 2007, 152, 256–266. [Google Scholar] [CrossRef]
  148. Vale, C.; Alfonso, A.; Sunol, C.; Vieytes, M.R.; Botana, L.M. Modulation of calcium entry and glutamate release in cultured cerebellar granule cells by palytoxin. J. Neurosci. Res. 2006, 83, 1393–1406. [Google Scholar] [CrossRef]
  149. Vale-Gonzalez, C.; Gomez-Limia, B.; Vieytes, M.R.; Botana, L.M. Effects of the marine phycotoxin palytoxin on neuronal pH in primary cultures of cerebellar granule cells. J. Neurosci. Res. 2007, 85, 90–98. [Google Scholar] [CrossRef]
  150. Kerbrat, A.S.; Amzil, Z.; Pawlowiez, R.; Golubic, S.; Sibat, M.; Darius, H.T.; Chinain, M.; Laurent, D. First evidence of Palytoxin and 42-Hydroxy-palytoxin in the marine cyanobacterium Trichodesmium. Mar. Drugs 2011, 9, 543–560. [Google Scholar] [CrossRef]
  151. Pelin, M.; Sosa, S.; Della Loggia, R.; Poli, M.; Tubaro, A.; Decorti, G.; Florio, C. The cytotoxic effect of palytoxin on Caco-2 cells hinders their use for in vitro absorption studies. Food Chem. Toxicol 2012, 50, 206–211. [Google Scholar] [CrossRef]
  152. Pettit, G.R.; Fujii, Y.; Hasler, J.A.; Schmidt, J.M. Isolation and characterization of palystatins A-D. J. Nat. Prod. 1982, 45, 272–276. [Google Scholar] [CrossRef]
  153. Giraldi, T.; Ferlan, I.; Romeo, D. Antitumor activity of equinatoxin. Chem. Biol. Interact. 1976, 13, 199–203. [Google Scholar] [CrossRef]
  154. Batista, U.; Macek, P.; Sedmak, B. The cytotoxic and cytolytic activity of equinatoxin II from the sea anemone Actinia equina. Cell Biol. Int. Rep. 1990, 14, 1013–1024. [Google Scholar] [CrossRef]
  155. Zorec, R.; Tester, M.; Macek, P.; Mason, W.T. Cytotoxicity of equinatoxin II from the sea anemone Actinia equina involves ion channel formation and an increase in intracellular calcium activity. J. Membr. Biol. 1990, 118, 243–249. [Google Scholar] [CrossRef]
  156. Batista, U.; Sentjurc, M. EPR study of the sea anemone cytolysin, equinatoxin II, cytotoxicity on V-79 cells. Cell Biol. Int. 1995, 19, 215–222. [Google Scholar] [CrossRef]
  157. Mariottini, G.L.; Robbiano, L.; Carli, A. Toxicity of Actinia equina (Cnidaria: Anthozoa) crude venom on cultured cells. Boll. Soc. Ital. Biol. Sper. 1998, 74, 103–110. [Google Scholar]
  158. Potrich, C.; Tomazzolli, R.; Dalla Serra, M.; Anderluh, G.; Malovrh, P.; Maček, P.; Menestrina, G.; Tejuca, M. Cytotoxic activity of a tumor protease-activated pore-forming toxin. Bioconjugate Chem. 2005, 16, 369–376. [Google Scholar] [CrossRef]
  159. Koblinski, J.E.; Ahram, M.; Sloane, B.F. Unraveling the role of proteases in cancer. Clin. Chim. Acta 2000, 291, 113–135. [Google Scholar] [CrossRef]
  160. Podgorski, I.; Sloane, B.F. Cathepsin B and its role(s) in cancer progression. Biochem. Soc. Symp. 2003, 70, 263–276. [Google Scholar]
  161. Soletti, R.C.; de Faria, G.P.; Vernal, J.; Terenzi, H.; Anderluh, G.; Borges, H.L.; Moura-Neto, V.; Gabilan, N.H. Potentiation of anticancer-drug cytotoxicity by sea anemone pore-forming proteins in human glioblastoma cells. Anti-Cancer Drugs 2008, 19, 517–525. [Google Scholar] [CrossRef]
  162. Soletti, R.C.; Alves, T.; Vernal, J.; Terenzi, H.; Anderluh, G.; Borges, H.L.; Gabilan, N.H.; Moura-Neto, V. Inhibition of MAPK/ERK, PKC and CaMKII signaling blocks cytolysin-induced human glioma cell death. Anti-Cancer Res. 2010, 30, 1209–1215. [Google Scholar]
  163. Kahn, S.A.; Biasoli, D.; Garcia, C.; Geraldo, L.H.; Pontes, B.; Sobrinho, M.; Frauches, A.C.; Romão, L.; Soletti, R.C.; Assunção Fdos, S.; et al. Equinatoxin II potentiates temozolomide- and etoposide-induced glioblastoma cell death. Curr. Top. Med. Chem. 2012, 12, 2082–2093. [Google Scholar]
  164. Mariottini, G.L.; Bussotti, S.; Carli, A. Cytotoxic effects produced on a continuous cell line by the nematocyst venom of Anemonia. sulcata (Cnidaria: Anthozoa). I. Cytotechnology 1993, 11, S158–S159. [Google Scholar]
  165. Carli, A.; Mariottini, G.L.; Pane, L. Ecological and Medical Aspects of Jellyfish Poisoning. In Epidemiological Studies Related to the Environmental Quality Criteria for Bathing Waters, Shellfish-Growing Waters and Edible Marine Organisms; UNEP: Athens, Greece, 1995; pp. 1–21. [Google Scholar]
  166. Carli, A.; Bussotti, S.; Mariottini, G.L.; Robbiano, L. Toxicity of jellyfish and sea-anemone venoms on cultured V79 cells. Toxicon 1996, 34, 496–500. [Google Scholar] [CrossRef]
  167. Marino, A.; Valveri, V.; Muià, C.; Crupi, R.; Rizzo, G.; Musci, G.; La Spada, G. Cytotoxicity of the nematocyst venom from the sea anemone Aiptasia mutabilis. Comp. Biochem. Physiol. C 2004, 139, 295–301. [Google Scholar]
  168. Mariottini, G.L.; Pane, L. Mediterranean jellyfish venoms: A review on Scyphomedusae. Mar. Drugs 2010, 8, 1122–1152. [Google Scholar] [CrossRef]
  169. Fedorov, S.; Dyshlovoy, S.; Monastyrnaya, M.; Shubina, L.; Leychenko, E.; Kozlovskaya, E.; Jin, J.-O.; Kwak, J.-Y.; Bode, A.M.; Dong, Z.; et al. The anticancer effects of actinoporin RTX-A from the sea anemone Heteractis crispa (=Radianthus macrodactylus). Toxicon 2010, 55, 811–817. [Google Scholar] [CrossRef]
  170. Young, M.R.; Li, J.J.; Rincon, M.; Flavell, R.A.; Sathyanarayana, B.K.; Hunziker, R.; Colburn, N. Transgenic mice demonstrate AP-1 (activator protein-1) transactivation is required for tumor promotion. Proc. Natl. Acad. Sci. USA 1999, 96, 9827–9832. [Google Scholar] [CrossRef]
  171. Amit, S.; Ben-Neriah, Y. NF-κB activation in cancer: A challenge for ubiquitination- and proteasome-based therapeutic approach. Semin. Cancer Biol. 2003, 13, 15–28. [Google Scholar] [CrossRef]
  172. Monroy-Estrada, H.I.; Chirino, Y.I.; Soria-Mercado, I.E.; Sánchez-Rodríguez, J. Toxins from the Caribbean sea anemone Bunodeopsis globulifera increase cisplatin-induced cytotoxicity of lung adenocarcinoma cells. J. Venom. Anim. Toxins 2013, 19, 12. [Google Scholar]
  173. Neeman, I.; Calton, G.J.; Burnett, J.W. Cytotoxicity and dermonecrosis of sea nettle (Chrysaora quinquecirrha) venom. Toxicon 1980, 18, 55–63. [Google Scholar] [CrossRef]
  174. Neeman, I.; Calton, G.J.; Burnett, J.W. An ultrastructural study of the cytotoxic effect of the venoms from the sea nettle (Chrysaora quinquecirrha) and Portuguese man-of-war (Physalia physalis) on cultured Chinese hamster ovary K-1 cells. Toxicon 1980, 18, 495–501. [Google Scholar] [CrossRef]
  175. Cao, C.J.; Eldefrawi, M.E.; Eldefrawi, A.T.; Burnett, J.W.; Mioduszewski, R.J.; Menking, D.E.; Valdes, J.J. Toxicity of sea nettle toxin to human hepatocytes and the protective effects of phosphorylating and alkylating agents. Toxicon 1998, 36, 269–281. [Google Scholar] [CrossRef]
  176. Houck, H.E.; Lipsky, M.M.; Marzella, L.; Burnett, J.V. Toxicity of sea nettle (Chrysaora quinquecirrha) fishing tentacle nematocyst venom in cultured rat hepatocytes. Toxicon 1996, 34, 771–778. [Google Scholar] [CrossRef]
  177. Helmholz, H.; Johnston, B.D.; Ruhnau, C.; Prange, A. Gill cell toxicity of northern boreal scyphomedusae Cyanea capillata and Aurelia aurita measured by an in vitro cell assay. Hydrobiologia 2010, 645, 223–234. [Google Scholar] [CrossRef]
  178. Li, C.; Li, P.; Feng, J.; Li, R.; Yu, H. Cytotoxicity of the venom from the nematocysts of jellyfish Cyanea nozakii Kishinouye. Toxicol. Ind. Health 2012, 28, 186–192. [Google Scholar] [CrossRef]
  179. Mariottini, G.L.; Giacco, E.; Pane, L. The Mauve Stinger Pelagia noctiluca (Forsskål, 1775). Distribution, ecology, toxicity and epidemiology of stings. A review. Mar. Drugs 2008, 6, 496–513. [Google Scholar]
  180. Mariottini, G.L.; Sottofattori, E.; Mazzei, M.; Robbiano, L.; Carli, A. Cytotoxicity of the venom of Pelagia noctiluca Forskal (Cnidaria: Scyphozoa). Toxicon 2002, 40, 695–698. [Google Scholar] [CrossRef]
  181. Ayed, Y.; Boussabbeh, M.; Zakhama, W.; Bouaziz, C.; Abid, S.; Hassen, B. Induction of cytotoxicity of Pelagia noctiluca venom causes reactive oxygen species generation, lipid peroxydation induction and DNA damage in human colon cancer cells. Lipids Health Dis. 2011, 10, 232. [Google Scholar] [CrossRef]
  182. Ayed, Y.; Chayma, B.; Hayla, A.; Abid, S.; Bacha, H. Is cell death induced by nematocysts extract of medusa Pelagia noctiluca related to oxidative stress? Environ. Toxicol. 2013, 28, 498–506. [Google Scholar] [CrossRef]
  183. Addad, S.; Exposito, J.-Y.; Faye, C.; Ricard-Blum, S.; Lethias, C. Isolation, characterization and biological evaluation of jellyfish collagen for use in biomedical applications. Mar. Drugs 2011, 9, 967–983. [Google Scholar] [CrossRef]
  184. Orduña-Novoa, K.; Segura-Puertas, L.; Sánchez-Rodríguez, J.; Meléndez, A.; Nava-Ruíz, C.; Rembao, D.; Santamaría, A.; Galván-Arzate, S. Possible antitumoral effect of the crude venom of Cassiopea xamachana (Cnidaria: Scyphozoa) on tumors of the central nervous system induced by N-Ethyl-N-Nitrosourea (ENU) in rats. Proc. West. Pharmacol. Soc. 2003, 46, 85–87. [Google Scholar]
  185. Lee, H.; Jung, E.-S.; Kang, C.; Yoon, W.D.; Kim, J.-S.; Kim, E. Scyphozoan jellyfish venom metalloproteinases and their role in the cytotoxicity. Toxicon 2011, 58, 277–284. [Google Scholar] [CrossRef]
  186. Burnett, J.W.; Ordonez, J.V.; Calton, G.J. Differential toxicity of Physalia physalis (Portuguese man-o’war) nematocysts separated by flow cytometry. Toxicon 1986, 24, 514–518. [Google Scholar] [CrossRef]
  187. Edwards, L.P.; Whitter, E.; Hessinger, D.A. Apparent membrane pore formation by Portuguese man-of-war (Physalia physalis) venom in intact cultured cells. Toxicon 2002, 40, 1299–1305. [Google Scholar] [CrossRef]
  188. Diaz-Garcia, C.M.; Fuentes-Silva, D.; Sanchez-Soto, C.; Domínguez-Pérez, D.; García-Delgado, N.; Varela, C.; Mendoza-Hernández, G.; Rodriguez-Romero, A.; Castaneda, O.; Hiriart, M. Toxins from Physalia physalis (Cnidaria) raise the intracellular Ca2+ of beta-cells and promote insulin secretion. Curr. Med. Chem. 2012, 19, 5414–5423. [Google Scholar] [CrossRef]
  189. Zhang, M.; Fishman, Y.; Sher, D.; Zlotkin, E. Hydralysin, a novel animal group-selective paralytic and cytolytic protein from a noncnidocystic origin in Hydra. Biochemistry 2003, 42, 8939–8944. [Google Scholar] [CrossRef]
  190. Sun, L.-K.; Yoshii, Y.; Hyodo, A.; Tsurushima, H.; Saito, A.; Harakuni, T.; Li, Y.-P.; Nozaki, M.; Morine, N. Apoptosis induced by box jellyfish (Chiropsalmus quadrigatus) toxin in glioma and vascular endothelial cell lines. Toxicon 2002, 40, 441–446. [Google Scholar] [CrossRef]
  191. Winter, K.L.; Isbister, G.K.; McGowan, S.; Konstantakopoulos, N.; Seymour, J.E.; Hodgson, W.C. A pharmacological and biochemical examination of the geographical variation of Chironex fleckeri venom. Toxicol. Lett. 2010, 192, 419–424. [Google Scholar] [CrossRef]
  192. Saggiomo, S.L.A.; Seymour, J.E. Cardiotoxic effects of venom fractions from the Australian box jellyfish Chironex fleckeri on human myocardiocytes. Toxicon 2012, 60, 391–395. [Google Scholar] [CrossRef]
  193. Proksch, P.; Edrada-Ebel, R.A.; Ebel, R. Drugs from the sea—Opportunities and obstacles. Mar. Drugs 2003, 1, 5–17. [Google Scholar] [CrossRef]

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Mariottini, G.L.; Pane, L. Cytotoxic and Cytolytic Cnidarian Venoms. A Review on Health Implications and Possible Therapeutic Applications. Toxins 2014, 6, 108-151. https://doi.org/10.3390/toxins6010108

AMA Style

Mariottini GL, Pane L. Cytotoxic and Cytolytic Cnidarian Venoms. A Review on Health Implications and Possible Therapeutic Applications. Toxins. 2014; 6(1):108-151. https://doi.org/10.3390/toxins6010108

Chicago/Turabian Style

Mariottini, Gian Luigi, and Luigi Pane. 2014. "Cytotoxic and Cytolytic Cnidarian Venoms. A Review on Health Implications and Possible Therapeutic Applications" Toxins 6, no. 1: 108-151. https://doi.org/10.3390/toxins6010108

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