Marine-Derived Indole Alkaloids and Their Biological and Pharmacological Activities

Novel secondary metabolites from marine macroorganisms and marine-derived microorganisms have been intensively investigated in the last few decades. Several classes of compounds, especially indole alkaloids, have been a target for evaluating biological and pharmacological activities. As one of the most promising classes of compounds, indole alkaloids possess not only intriguing structural features but also a wide range of biological/pharmacological activities including antimicrobial, anti-inflammatory, anticancer, antidiabetic, and antiparasitic activities. This review reports the indole alkaloids isolated during the period of 2016–2021 and their relevant biological/pharmacological activities. The marine-derived indole alkaloids reported from 2016 to 2021 were collected from various scientific databases. A total of 186 indole alkaloids from various marine organisms including fungi, bacteria, sponges, bryozoans, mangroves, and algae, are described. Despite the described bioactivities, further evaluation including their mechanisms of action and biological targets is needed to determine which of these indole alkaloids are worth studying to obtain lead compounds for the development of new drugs.


Introduction
Marine natural products (MNPs) have drawn much attention from both natural product chemists and pharmacologists due to their potential bioactivities. These chemical compounds have made a major contribution for the treatment of a myriad of diseases including cancer and infectious diseases as well as other therapeutic areas such as multidrug resistances (MDRs), cardiovascular diseases, and multiple sclerosis [1,2]. Compared to conventional synthetic molecules, MNPs present several advantages due to their unique structural features and complex scaffolds that are beneficial for drug discovery. MNPs usually possess high molecular weight and a large number of carbon and oxygen atoms. Moreover, marine-derived bioactive compounds have fewer but unique nitrogen and halogen atoms.
Indole alkaloids are a class of alkaloids containing an indole moiety. Generally, indole alkaloids can be classified into four groups, viz. simple indole alkaloids, prenylated indoles, bis-/tris-indoles, and annelated indoles [5] (Figure 1). Simple indole alkaloids are mostly derived from the amino acid tryptophan (Trp) or its direct precursor, indole, in microorganisms or plants. On the other hand, prenylated indoles represent diverse groups of indole alkaloids that are commonly derived from Trp and isoprene unit(s) whereas bisand tris-indoles are biosynthetically derived from two or three indole building blocks. For annelated indoles, a single indole core is fused with non-prenyl-derived (hetero)cyclic ring systems. Besides several specific reviews on marine-derived indole alkaloids focusing on their biological and pharmacological activities [3,4,6], a comprehensive review by Netz and Opatz [5] has previously been published. In the present review, we have updated the indole alkaloids, isolated from various marine macro-and microorganisms including fungi, bacteria, sponges, bryozoans, mangrove plants, and algae during the period of January 2016 to October 2021. However, we only report the previously undescribed compounds isolated during this period, while the compounds reported before this period and are mentioned in the references used in this review are not included. The relevant biological and pharmacological activities of some potential alkaloids are also highlighted. The search engines used to find the compounds in this review were PubMed, MEDLINE, Web of Science, and Scopus.
Since our main research topics involved a discovery of new secondary metabolites from marine-derived fungi, marine invertebrates, and algae, which led to the isolation of a number of undescribed and structurally diverse indoles such as prenylated and annelated indoles with antibacterial and antibiofilm activities, this topic can provide us and other researchers who work with marine natural products to gain more insight into this class of compounds in both structural and biological activity aspects.

Sources of Marine-Derived Indole Alkaloids Isolated from January 2016 to October 2021
The marine ecosystem has raised the awareness of natural product chemists due to the prospects of biologically active MNPs as a great potential for pharmaceuticals and cosmeceuticals. One of the most interesting classes of MNPs is indole alkaloids. Based on the literature search, 186 previously undescribed marine indole alkaloids that were isolated from various phyla of marine organisms including fungi, bacteria, sponges, bryozoans, mangrove trees, and algae have been reported between January 2016 and October 2021 ( Figure 2). Intriguingly, many of these indole alkaloids possess unique structural features as well as interesting biological and pharmacological activities.

Marine-Derived Fungi
Marine-derived fungi have been shown to be a prolific source of indole alkaloids, especially the prenylated indole alkaloids. For practical aspects and a better insight for the readers, the previously unreported indole alkaloids isolated from marine-derived fungi (and other marine organisms) are divided into four groups as above-mentioned.

Simple Indole Alkaloids
Although marine sponges and soft coral-associated fungi are rich sources of indole alkaloids, other marine invertebrates such as sea star and sea cucumber are also found to host indole alkaloid-producing fungi. In order to facilitate the perception, the compounds of this group are not ordered according to the type of host organisms, but according to the complexity of the substituents of the indole core, starting from acyclic substituents to cyclic ones. For cyclic substituents, the order of the compounds is from monocyclic and progressing to bi-, tri-, and polycyclic, respectively.
Supplementation of L-Trp into Glucose-Yeast-Peptone (GYP) culture medium of the fungus Fusarium sp. L1, which was isolated from the inner tissue of a sea star Acanthaster planci collected from the Xisha Islands in China, resulted in the production of two previously unreported simple indole alkaloids, fusariumindole C (1) and (±)-isoalternatine A (2) (Figure 3) [7].
A marine-derived fungus Dichotomomyces cejpii F31-1, obtained from the inner tissue of a soft coral Lobophytum crassum that was collected from the Hainan Sanya National Coral Reef Reserve, China, yielded an indole-containing amide, dichotomocej D (3) (Figure 3) [8]. Pseudellone D (4) (Figure 3), a metylsulfanyldiketopiperazine-containing indole, was also obtained from the culture of the fungus Pseudallescheria ellipsoidea F42-3, which was isolated from the inner tissue of the soft coral L. crassum collected from the Hainan Sanya National Coral Reef Reserve, China [9].
Mycelia of a fungus Scedosporium apiospermum F41-1, also obtained from the inner tissue of the soft coral L. crassum that was collected from the Hainan Sanya National Coral Reef Reserve, China, yielded scequinadoline J (6) (Figure 3). The absolute configuration of the stereogenic carbon (C-14) in 6 was established by a comparison of the calculated and experimental electronic circular dichroism (ECD) spectra [11]. Interestingly, the same fungus produced different metabolites including an undescribed pyrazinoquinazolinone-containing indole, scequinadoline G (7), when cultured in the GYP medium supplementation of L-Trp, L-Phe, L-Thr, and D,L-Met from when it was cultured solely in GPY medium [12].
Sartoryglabramide B (8) (Figure 3), an indole-containing tetrapeptide, was isolated from the culture of a marine sponge-associated fungus Neosartorya glabra KUFA 0702A, which was isolated from the marine sponge Mycale sp., collected at Samaesarn Island in the Gulf of Thailand. The absolute configurations of the amino acid constituents were determined by X-ray analysis and confirmed by chiral high performance liquid chromatography (HPLC) analysis of its hydrolysate and compared with D-and L-amino acid standards [13].

Prenylated Indoles
Similar to the simple indole alkaloids, the prenylated indoles are not ordered according to the producing fungi, but according to their structural complexity, starting from a simple indole core with acyclic prenyl substituents to cyclic prenyl substituents, progressing to the indole core fused with a prenyl-derived ring system, and the number of rings fused with the indole core determines their degree of complexity.
The ethyl acetate (EtOAc) extract of the culture of Pseudallescheria boydii F19-1, which was isolated from the inner tissue of a soft coral L. crassum, collected in the Hainan Sanya National Coral Reef Reserve, China, yielded a cyclopiazonic acid analogue, pseuboydone E (20) (Figure 4). The absolute configurations of C-4 and C-8 in 20 were established by comparison of the calculated and experimental ECD spectra [19].
Co-culture of A. sulphureus KMM 4640 with I. felina KMM 4639 also yielded 17hydroxynotoamide D (23) (Figure 4), consisting of a hexahydropyrrolo [2,3-b]indole skeleton, similar to that of 21 and 22, which is angularly fused with a 2,2-dimethylpyran ring. The absolute configurations of the stereogenic carbons in 23 were established by comparison of the calculated and experimental ECD spectra [17].
The EtOAc extract of a solid rice culture of the fungus Penicillium dimorphosporum KMM 4689, isolated from soft coral samples that were collected from various points in the South China Sea, yielded seven unreported deoxyisoaustamide derivatives, namely 16α-hydroxy-17βmethoxydeoxydihydroisoaustamide (24), 16β-hydroxy-17α-methoxydeoxydihydroisoaustamide (25), 16α-hydroxy-17α-methoxydeoxydihydroisoaustamide (26), 16,17-dihydroxydeoxydih ydroisoaustamide (27), 16β,17α-dihydroxydeoxydihydroisoaustamide (28), 16α,17α-dihy droxydeoxydihydroisoaustamide (29), and 3β-hydroxydeoxyisoaustamide (30) ( Figure 5). The structures of the compounds of this group are characterized by a 6/5/8/6/5 pentacyclic ring system whose indole and 1,4-diketopiperazine moieties are linked through the eight-membered hexahydroazocine ring. The structures of 24-30 were elucidated by extensive analysis of their 1D and 2D NMR spectra. The relative configurations of the stereogenic carbons in 24 were determined by single-crystal X-ray analysis whereas those of 25-30 were established by NOESY correlations. The absolute structure of 24 was based on its biogenic relationship with that of the previously described (+)-deoxyisoaustramide. The absolute configurations of the stereogenic carbons of the rest of the compounds were based on their biogenetic consideration as well as a comparison of their CD spectra [20].
Aspergillus versicolor from the mud, collected in the South China Sea, also produced rare linearly fused dimethypyranoindoles containing an amine fused-imine pyrrole ring system, asperversamides A-E (34-38) ( Figure 6). Compounds 34-36 and 38 each contain a rare anti bicyclo[2.2.2]diaza-octane ring, while 37 contains an analog syn ring. Moreover, 35/36 and 37/38 are pairs of C-3 and C-21 epimers, respectively. The relative configurations of all the compounds were established by NOESY correlations. In the case of 34, the absolute configurations of its stereogenic carbons were established by comparison of the calculated and experimental ECD spectra, while the absolute structure of 35 was established by the characteristic positive Cotton effect (CE) at 223 nm (+25.9) and negative CE at 242 nm (−28.6) in the experimental ECD spectrum and confirmed by a single-crystal X-ray diffraction analysis. The absolute configurations of the stereogenic carbons in 37 and 38 were established based on a similarity of their ECD spectra to that of the previously reported compound, (+)-6-epi-stephacidin A, and in the case of 37, its absolute structure was confirmed by X-ray analysis [18]. Brevianamides X (39) and Y (40) (Figure 6), two spiro 2-oxindole containing a bicyclo [2.2.2]diaza-octane ring system, were obtained from an acetone extract of the culture of a marine-derived fungus Penicillium brevicompactum DFFSCS025, which was isolated from a deep-sea sediment sample collected in the South China Sea in Hainan Province, China. The planar structures of both compounds were established by detailed analysis of 1D and 2D NMR spectra. NOESY correlations were used to determine the relative configurations of the stereogenic carbons of both compounds while their absolute configurations were established by a comparison of the calculated and experimental ECD spectra. Interestingly, 39 was found to be a diastereomer of the previously described (−)-depyranoversicolamide B [21].
The ethyl acetate extract of a culture of Aspergillus sp. YJ191021, isolated from a soil sample collected from the intertidal zone of Zhoushan, Zhejiang, China, yielded unreported prenylated diketopiperazine indole alkaloids, asperthins A-F (41-46) ( Figure 6). Compounds 41-44 share the same feature consisting of a bicyclo[2.2.2]diaza-octane-containing indole Noxide, which is angularly fused with a dimethylpyran moiety, while 45 is a bicyclo[2.2.2]diazaoctane-containing spiro 2-oxindole, angularly fused with dimethyl pyran. Compound 46 features an angularly fused pyranoindole containing a diketopiperazine-fused amine pyrrole ring system. The planar structures of 41-46 were established by extensive analysis of 1D and 2D NMR spectra while the absolute configurations of their stereogenic carbons were determined by comparison of the calculated and experimental ECD spectra [22].
The EtOAc extract of a culture of Penicillium janthinellum HK1-6, which was isolated from a mangrove rhizosphere soil collected from the Dongzhaigang mangrove natural reserve in Hainan Island, yielded an unreported paraherquamide J (47) ( Figure 6) whose structure consists of a prenylated indole featuring a spiro oxindole angularly fused with a dimethylpyran ring, which is connected with a bicyclo[2.2.2]diaza-octane-containing diketopiperazine-fused amine pyrrole ring system. The relative configurations of the stereogenic carbons in 47 were established by NOESY correlations while their absolute configurations were established by comparison of its ECD spectrum with that of man-grovamide A, a previously reported compound whose absolute structure was established by ECD data and X-ray analysis [23]. The EtOAc extract of a culture of Fusarium sp. L1 from a GPY liquid medium supplemented with L-Trp also produced fusaindoterpenes A (48) and B (49) (Figure 6). Compound 48 is a rearranged prenylated indole containing a 8,9-dihydro-1,3-oxazonine-2,6 (3H,7H)-dione ring, while 49 features an indole fused with a substituted dodecahydro-1H-cyclopenta[a]naphthalene ring system. The relative configurations of 48 and 49 were established by NOESY correlations. The absolute configurations of the estereogenic carbons of 48 were established by X-ray analysis, while those of 49 were established by a comparison of the calculated and experimental ECD spectra [7].
The EtOAc extract of a fermentation broth of Penicillium sp. KFD28, isolated from a bivalve mollusc, Meretrix lusoria, which was collected from Haikou Bay, China, furnished four indolediterpenoids, named penerpenes A-D (50-53) (Figure 7). Compound 50 features a hexacyclic ring system comprising 1,2-dihydro-2 H-spiro [3,1-benzoxazine-4,1 -cyclopentan]-2 -one fused with a decalin ring system, while 51-53 share a common feature, having an indole ring system fused with a cyclopentane ring of the dodecahydro-1H-cyclopenta[a]naphthalene ring system. However, the structure of 51 is unique since it has a pyridine ring fused with a decalin moiety. The planar structures of 50-53 were elucidated by extensive analysis of their 1D and 2D NMR data. The absolute configurations of the stereogenic carbons in 50 and 51 were established by comparison of the calculated and experimental ECD spectra while only the relative configurations of 52 were established by ROESY correlations. On the other hand, the absolute configurations of the stereogenic carbons in 53 were established using the ECD exciton chirality models [24]. The presence of a spiro 1,4-dihydro-2H-3,1 benzoxazine ring in 50 and the presence of a pyridine ring in 51, together with a new carbon skeleton in 52 and 53, led Kong et al. [24] to propose the biosynthesis of these compounds as a degradation and rearrangement of the carbon skeletons of paxilline-type indole terpenoids, paxilline (I) and emindole SB (VI), which were co-isolated with 50-53. Compounds 50, 52, and 53 are hypothesized to derive from paxilline (I) (Figure 8a). N-methylation and oxidation of the indole portion of paxilline (I) yields V with Nhydroxymethyl and an epoxide between C-8 and C-9. Nucleophillic substitution of C-8 by OH-28 with a concomitant opening of the epoxide ring and a cleavage of C-9-N leads to thee formation of a spiro 1,4-dihydro-2H-3,1 benzoxazine ring in 50. On the other hand, Baeyer-Villinger oxidation of I gives II, with a 1,3-dioxepan-4-one ring, and III, with a 1,4-dioxepan-5-one ring. Rearrangement of the 1,3-dioxepan-4-one ring in II yields 53, while ring cleavage, dehydration, and oxidation of III gives IV. Lactonization of IV yielded 52 (Figure 8a). Emindole SB (VI) was proposed to be a biosynthetic precursor of 51. Oxidation of VI gives rise to VII, followed by transamination to give VIII. Nucleophillic addition of the ketone at C-13 by NH 2 -21 yields an imine in IX. Oxidation and epoxidation of IX gives X, which, after enolization, yields XI. Nucleophillic substitution on C-23 of the epoxide by OH-18 leads to a formation of a 3-hydroxydihydropyran ring in 51 (Figure 8b).
Further investigation of the same fungal extract by the same research group led to the isolation of an additional five paxilline-type indolediterpenoids, penerpenes E-I (54-58) (Figure 7) [25]. Compound 54 has a unique skeleton comprising a hexahydrofuro [3,2b]furan-containing heptacyclic ring system, while 55 corresponds to a loss of three carbons of the side chain of paxilline by the retro-aldol reaction. Compound 56 contains a 1,3dioxepan-4-one ring, corresponding to a Baeyer-Villiger oxidation product of paxilline. Compound 58 derived from the cleavage of a pyrrole ring of the indole moiety. The planar structures of 54-58 were established by extensive analysis of 1D and 2D NMR spectra as well as high resolution mass spectrometry (HRMS). The absolute configurations of the stereogenic carbons in 54 were determined by a comparison of the calculated and experimental ECD spectra while the absolute structures of 55-57 were established by a comparison of their ECD curves with that of paxilline. In contrast, the absolute configurations of the stereogenic carbons in 58 were established based on a biogenic consideration [25].
Tao et al. reported the isolation of four undescribed prenylated indoles, mangrovamides D-G (59-62) (Figure 7) from the culture extract of Penicillium sp. SCSIO041218, which was obtained from a mangrove sediment in Sanya, China. All compounds feature a 5,8diazatricyclo[5,2,2,0 1,5 ]undecan-9-one moiety that incorporates proline (Pro). In particular, 59 and 60 contain a spiro 2-oxindole, similar to that found in 35, 36, 39, and 40 ( Figure 6). The structures of 59-62 were established by HRMS and interpretation of 1D and 2D data. The relative configurations of the stereogenic carbons in 59 were established by NOESY correlations and comparison of its ECD profile with that of mangrovamide A, which was previously isolated from the same fungus, and whose absolute structure has been established by a single-crystal X-ray analysis. The stereostructures of 60-62 were determined based on a comparison of their ECD profiles with that of 59 [26].
Ascandinines A-D (63-66) (Figure 9), paxiline-like indolediterpenoids, were obtained from the culture of Aspergillus candidus HDN15-152, which was associated with an unidentified Antarctic sponge. Compound 63 has an unprecedented 7-chloroindole-substituted 6/6/6/6/6 pentacyclic skeleton with a 2-oxabicyclo[2.2.2]octan-3-ol motif, which is structurally derived from a cleavage of the C-17 and C-18 bond in the paxilline-like indolediterpenoids. On the other hand, 64-66 also share the same 2-oxabicyclo[2.2.2]octan-3-ol motif, however, they have a heptacyclic skeleton comprising the indole ring system fused with the dodecahydro-1H-cyclopenta[a]naphthalene ring system. The difference between 64 and 65 is the presence of a chlorine substituent in the benzene ring of the indole moiety in 64. The relative configurations of 63-66 were determined by analysis of NOESY correlations and the absolute configurations of their stereogenic carbons were established by comparison of the calculated and experimental ECD spectra as well as by biogenetic considerations [27].
Asperindoles A-D (67-70) ( Figure 9) are indolediterpenes with the same scaffold as those of 64-66. Compounds 67-70 were obtained from the solid rice culture extract of Aspergillus sp. KMM4676, which was isolated from an unidentified colonial ascidian in Shikotan Island, Pacific Ocean. It is interesting to note that both 67 and 69 are chlorinated analogues of 68 and 70, similar to 63 and 65. Although chlorinated indolediterpenes are not very common, the occurrence of 63, 67, and 69 demonstrates that some marine-derived Aspergillus species have the capacity to introduce a chlorine atom to the benzene ring of the indole moiety. The structures of 67-70 were elucidated by extensive analysis of 1D and 2D spectral data. The relative configurations of the stereogenic carbons in 70 were established by NOESY correlations, however, their absolute configurations were proposed based on biogenetic consideration. The relative configurations of the stereogenic carbons in 69 were established by ROESY correlations and their absolute configurations were determined based on a comparison of its experimental ECD spectrum with that of 67 [28]. A pair of enantiomeric diketopiperazine prenylated indole alkaloid dimers, (−)-and (+)-asperginulin A (71a and 71b) (Figure 9), was obtained as a racemic mixture from the EtOAc extract from the wheat cultures of an endophytic fungus, Aspergillus sp. SK-28A, which was isolated from the leaves of the mangrove plant Kandelia candel from the South China Sea. The structure elucidation of the compounds was carried out by a combination of extensive 1D and 2D NMR spectral analysis and X-ray diffraction analysis to obtain a planar structure and relative configurations of the compounds. By using a HPLC equipped with a chiral INA column, it was possible to separate the two enantiomers. Both enantiomers were separately recrystallized to obtain a suitable crystal for X-ray diffraction analysis using CuKα radiation to obtain crystal structures with good Flack parameters, thus allowing the determination of the absolute configurations of the stereogenic carbons of each enantiomer. The absolute configurations were also confirmed by a comparison of the calculated and experimental ECD spectra. It is interesting to note that the indole nucleus is substituted by a reverse prenyl group and a dimerization occurs by intermolecular cycloaddition of the hexahydropyrrolo [1,2-a]1,4-diketopiperazine moieties, forming a rare 6/5/4/5/6 pentacyclic skeleton [29].
The EtOAc extract of the rice culture of Aspergillus austroafricanus Y32-2, isolated from a seawater sample, which was collected from the Indian Ocean at the depth of 30 m, yielded two diketopiperazine-containing prenylated indole dimers, di-6-hydroxydeoxybrevianamide E (72) and dinotoamide J (73) (Figure 9). The structures of the compounds were elucidated by extensive analysis of 1D and 2D NMR spectral data together with HRMS. The absolute configurations of their stereogenic carbons were established by a comparison of thee calculated and experimental ECD spectra. It is interesting to note that, unlike 71b/71b, both 72 and 73 were derived from dimerization of the activated carbon of the benzene ring of the indole moieties. However, there was a difference between the 72 and 73 resides in the indole nucleus. While 72 contains an indole nucleus substituted with a reverse prenyl group at C-2, 73 contains an oxindole whose reverse prenyl substituent is on C-3 [30].

Bis-/Tris-Indoles
Bis-and tris-indoles can be derived either from two (or three) direct linkage between the same indole monomers to give homodimers (or homotrimers) or different indole monomers to give heterodimers (or heterotrimers). Moreover, these indole monomers can also link together through different side chains.
Fusariumindole B (74), a bis-indole derivative comprising two indole moieties linked through C-2 and C-2 , and fusariumindole A (75) ( Figure 10) were also isolated from the extract of the marine-derived Fusarium sp. L1, cultured in L-Trp-supplemented GYP medium. Compound 74 comprises two indole moieties linked through C-2 and C-2 , while in 75, both indole moieties are linked together not directly but by an ethyl acetate ester through C-3 of the indole ring [7].
A diketopiperazine derivative, fellutanine A epoxide (79), was isolated from the culture extract of a marine sponge-associated fungus Neosartorya glabra KUFA 0702. The structures of 79 were established based on extensive 1D and 2D NMR spectral analysis. The absolute configurations of the stereogenic carbons of the epoxide ring (C-2 and C-3 ) were determined based on NOESY correlations, in conjunction with conformational search, molecular dynamics, and ab initio molecular modeling [13].
The EtOAc extract of the culture of Aspergillus candidus KUFA0062, isolated from a marine sponge Epipolasis sp., which was collected by scuba diving at a depth of 15-20 m from the coral reef at Similan Island National Park, Southern Thailand, produced a bis-indolyl benzenoid analogue, candidusin D (80) [33]. The culture extract of an endophytic fungus, Penicillium chrysogenum V11, isolated from the vein of a semi-mangrove tree, Myoporum bontioides A. Gray, which was collected in Leizhou Peninsula, China, furnished chaetoglobosin alkaloids, penochalasins I (81), and J (82) ( Figure 10). Compound 81 features a 6/5/6/5/6/13 hexacyclic ring system, while 82 consists of two indole moieties, one of which is fused with a 13-membered macrocyclic ring. The structures of both compounds were elucidated by a combination of HRMS with 1D and 2D NMR spectral analysis. The absolute configurations of the stereogenic carbons were established by comparison of the calculated and experimental ECD spectra [34]. Further study of the same fungus led to the isolation of another chaetoglobosin indole alkaloid with a 6/5/6/5/6/13 hexacyclic fused ring system, named penochalasin K (83). The only difference between 81 and 83 is that the hydroxyl group of the 13-membered macrocyclic ring in 81 is replaced by a ketone function in 83 [35].
Cytoglobosin X (84) ( Figure 10) was obtained from a culture extract of the endophytic fungus Chaetomium globosum strain E-C-2, which was isolated from the surface muscle of a sea cucumber, Apostichopus japonicus, collected from Chengshantou Island, Weihai City, the Yellow Sea, China [36]. The culture of a coral-associated fungus C. globosum C2F17, isolated from a coral Pocillopora damicornis, which was collected from the seashore near Sanya Bay, Hainan Province, China, yielded a cytochalasan alkaloid 6-O-methylchaetoglobosin Q (85) (Figure 10). The structure of 85 was determined using extensive spectroscopic analysis whereas the configurations of its stereogenic carbons were determined through a comparison of the calculated and experimental ECD spectra. The authors speculated that 85 was probably an artifact derived from acidic solvolysis of the previously reported epoxide of chaetoglobosin A [37]. Cytoglobosin H (86) and its C-6 epimer, cytoglobosins I (87) ( Figure 10) were obtained from the extract of a solid rice culture of C. globosum, which was isolated from deep-sea sediments collected from the Indian Ocean. The structures of both compounds were established by extensive 1D and 2D NMR spectral analysis. Their relative configurations were determined by ROESY correlations, however, the absolute configurations of their stereogenic carbons were not determined [38].

Annelated Indoles
Two methylsulfinyldiketopiperazine-containing annelated indoles, dichocerazines A (88) and B (89) (Figure 11), were isolated from the culture extract from a soft coral-associated fungus Dichotomomyces cejpii F31-1, cultured in a GYP medium supplemented with L-Trp and L-Phe. The structures of 88 and 89 were elucidated by the analysis of 1D and 2D NMR spectra as well as HRMS data. Compound 88 was isolated as a racemate since it showed no optical rotation, and an effort to separate the enantiomers by a HPLC equipped with a Chiralcel OD column was not successful. In contrast, 89 was isolated as a pure compound and the absolute configurations of its stereogenic carbons were established by comparison of the calculated and experimental ECD spectra [8]. Structurally, 88 was derived from a condensation of Trp and Gly whereas 89 was derived from a condensation of Trp and Ser, and methylsulfinyl substituents were introduced in a later stage to the carbon adjacent to the carbonyl function.
A diketopiperazine-containing oxindole alkaloid, raistrickindole A (90) (Figure 11), was obtained from the EtOAc extract from a solid rice culture of Penicillium raistrickii IMB17-034, which was isolated from marine sediments collected in a mangrove swamp in Sanya, Hainan Province, China. Structurally, 90 was derived from a condensation of Trp and Phe, therefore the absolute configuration of L-Phe was established by the advanced Marfey's analysis. The absolute configurations of the rest of the stereogenic carbons were determined by comparison of the calculated and experimental ECD spectra [39].
The EtOAc extract of a culture broth of Aspergillus sp. HNMF114, isolated from a bivalve mollusk Sanguinolaria chinensis, which was collected from Haikou Bay, Hainan Province, China, furnished aspertoryadins F (91) and G (92) ( Figure 11). Compounds 91 and 92 contain 2-indolone moiety linked to a quinazolinone ring system through a five-membered spiro lactone. The planar structures of the compounds were elucidated by analysis of 1D and 2D spectra as well as HRMS data. However, the ECD spectra of 91 and 92 are mirror images through the Cotton effects (CEs) around 210 and 230 nm. According to the ECD exciton coupling rule, the absolute configurations of C-3 and C-12 of 91 and 92 were determined as 3S, 12S, and 3R, 12R, respectively. However, the absolute configuration of the stereogenic carbon in the side chain of the quinazolinone moiety was the same [40].
Fumigatoside E (93) (Figure 11), whose indole moiety is fused with a pyrazinone ring of the pyrazinoquinazolinone moiety, was obtained from a culture extract of Aspergillus fumigatus SCSIO 41012 isolated from deep-sea sediments that were collected from the Indian Ocean. The planar structure of the compound was elucidated by HRMS and extensive 1D and 2D NMR spectral analysis. The absolute configurations of its stereogenic carbons were established as 3R, 14R by comparison of the calculated and experimental ECD spectra [41].
Scedapin E (94) (Figure 11), an indole alkaloid comprising an oxindole moiety linked to a pyrazinoquinazolinone moiety via a spiro pyran ring, was isolated from the extract of a marine-derived fungus Scedosporium apiospermum F41−1, cultured in a GYP medium supplemented with L-Trp, L-Phe, L-Thr, and D,L-Met. The planar structure of 94 was elucidated by HRMS and 1D and 2D NMR spectral analysis. The stereostructure of 94 was established by a single-crystal X-ray analysis [12]. Fumigatoside F (95) (Figure 11), an indole alkaloid comprising a 6-5-5-imidazoindolone ring linked to a quinazolinone ring system via an ethylene bridge, was obtained from a culture extract of A. fumigatus SCSIO 41012, isolated from deep-sea sediments that were collected from the Indian Ocean. The planar structure of the compound was established by 1D and 2D NMR spectral analysis as well as HRMS data. The proton chemical shift values suggest that the structure of 95 was derived from the opening of the lactone ring in tryptoquivaline E, however, the absolute configurations of its stereogenic carbons were not determined [41].
Aspertoryadins I (96) and J (97) ( Figure 11) were isolated from the culture extract of the fungus Aspergillus sp. HNMF114, obtained from a mollusk Sanguinolaria chinensis. These alkaloids comprise an indole moiety fused with an imidazolone ring to form a 6-5-5imidazoindolone ring system, which is linked to a quinazolinone ring system through a five-membered spiro lactone such as in tryptoquivalines [42]. Aspertoryadins A−E (98-102) (Figure 11), which also contain an imidazoindolone moiety linked to a quinazolinone ring system through a five-membered spiro lactone, were also isolated from the same fungus. Compound 98 has an unusual methylsulfonyl group attached to the nitrogen atom of the imidazolone moiety while the rest of the compounds, except for 101, has a hydroxyl group on this nitrogen atom. The stereostructure of 98 was established by X-ray analysis and was confirmed by the comparison of the calculated and experimental ECD spectra. Compounds 99 and 100 are C-27 epimers whose absolute configurations of C-27 were determined by comparison of their C-27 chemical shift values with that of 98. The relative configurations of 101 and 102 were established based on ROESY correlations, however, the absolute configurations of their stereogenic carbons were not determined [40].
Scetryptoquivaline A (103), an N-methylsulfonyl imidazoindolone connected to quinazolinone moiety through a five-membered lactone, and scequinadoline I (104) (Figure 12), an imidazoindolone connected to an isopropyl pyrazinoquinazolinone moiety through a methylene bridge (Figure 12), were also isolated from the culture extract of a coralassociated fungus Scedosporium apiospermum F41-1 [11] while aspertoryadin H (105), another imidazoindolone connected to isopropylquinazolinone moiety through a methylene bridge, was also isolated from a mollusk-associated fungus Aspergillus sp. HNMF114 [42]. Scequinadolines A−F (106-111) (Figure 12), comprising an imidazoindolone connected to an isopropylpyrazinoquinazolinone moiety through a methylene bridge, and scedapins A-D (112-115) ( Figure 12), whose imidazoindolone moiety is connected to a pyrazinoquinazolinone through a spiro tetrahydrofuran, were also isolated from the culture extract of a soft coral-associated fungus S. apiospermum F41-1 [12]. A heterodimer of an indolodiketopiperazine derivative, named SF5280-415 (116) (Figure 12) was obtained from the culture extract of Aspergillus sp. SF-5280, isolated from an unidentified sponge that was collected at Cheju Island, Korea. The structure of the compound was established by a combination of HRMS and 1D and 2D NMR spectral analysis. The configurations of the amino acid constituents, Phe and Leu, were determined by Mafrey's method while the relative configurations of the stereogenic centers of the diketopiperazine ring and C-2 and C-3 of the indole moiety were established by observation of NOESY correlations and compared with those of the previously described compounds (WIN 64745 and ditryptophenaline) [43].

Marine-Derived Bacteria
In comparison with marine-derived fungi, marine-derived bacteria are less prolific in terms of indole alkaloid production. Most of the indole alkaloids discovered in this period are simple, bis-, and tris-indoles.

Simple Indoles
A simple indole alkaloid comprising an oxindole with an amide side chain, named bacilsubteramide A (117) (Figure 13), was isolated from an EtOAc extract of the culture of Bacillus subterraneus 11593, which was collected from the South China Sea with the depth of 2918 m. The structure of 117 was elucidated by 1D and 2D NMR spectral analysis while the absolute configuration of its stereogenic carbon was established by a comparison of the calculated and experimental ECD spectra [44]. Indolepyrazine B (118) (Figure 13) is a pyrazine-containing simple indole, obtained from an extract of a marine-derived Acinetobacter sp. ZZ1275, which was isolated from a mud sample collected from the coastal area of Karachi, Sindh, Pakistan [45].

Bis-/Tris-Indoles
A culture extract of Streptomyces sp. SCSIO 11791, isolated from a sediment sample collected from the South China Sea at a depth of 1765 m yielded two chlorinated bisindole alkaloids, dienomycin (119) and 6-methoxy-7 ,7 -dichlorochromopyrrolic acid (120) (Figure 13). Compound 119 contains two indole moieties linked together through 1Hpyrrole-2,5-dione, while the two indole moieties in 120 are linked through dimethyl 2,5dihydro-1H-pyrrole-2,5-dicarboxylate. The structures of both compounds were elucidated by analysis of HRMS and 1D and 2D NMR spectra [46]. Besides the simple indole 118, the culture of a marine-derived Acinetobacter sp. ZZ1275 also furnished a bis-indole alkaloid indolepyrazine A (121) (Figure 13) comprising one indole and one oxindole ring system linked by a 2, 2-dimethylpyrazine unit. The structure of 121 was elucidated by HRMS and 1D and 2D NMR spectral analysis. The configuration of the stereogenic carbon on the oxindole moiety was established through a comparison of the calculated and experimental ECD spectra [45].
Tricepyridinium (122) (Figure 13), a novel pyridinium with three indole moieties, was isolated from the culture extracts of the Escherichia coli transfected by metagenomic DNA prepared from the marine sponge Discoderma calyx collected from Shikine-jima Island in Japan. The structure of 122 was elucidated by a combination of HRMS with 1D and 2D NMR spectral analysis [47].

Marine Sponges
Marine sponges are also a source of structurally diverse indoles. However, only simple indoles and bis-/tris-indoles were reported from marine sponges in this period.

Simple Indole Alkaloids
Simple indole alkaloids consisting of an indole nucleus linked to a N-substituted-γlactams, named psammocindoles A-C (123-125) (Figure 14), were isolated from a marine sponge Psammocinia vermis (order Dictyoceratida, family Irciniidae) collected from Chujado, Korea. The structures of 123-125 were elucidated based on a combination of a highresolution fast atom bombardment mass spectrometry (HRFABMS) and 1D and 2D spectral analysis. In the case of 123, the absolute configuration of the stereogenic carbon was determined by a comparison of its optical rotation with that of a synthetic version [48].
The 5-azaindole derivatives, guitarrins A-E (126-130) and an aluminum complex compound, aluminumguitarrin A (126a), (Figure 14), were isolated from the marine sponge Guitarra fimbriata. Compounds 126-129 and 126a were isolated from the sample of G. fimbriata, collected by dredging near Chirpoy Island in the Pacific Ocean, while 130 was isolated from a sample of the same sponge but collected near Urup Island, Sea of Okhotsk. The structures of all the isolated compounds were elucidated by HRMS and 1D and 2D NMR spectral analysis. In the case of 126 and 126a, their structures were confirmed by a single-crystal X-ray diffraction analysis [49].
Seven pairs of oxygenated aplysinopsin-type enantiomers, (+)-and (−)-oxoaplysinopsins A-G (131-137) (Figures 14 and 15) were isolated from a marine sponge Fascaplysinopsis reticulata, which was collected from Xisha Island in the South China Sea. The enantiomers were separated by a chiral HPLC equipped with a chiral analytical column (CHIRALPAK IC column). The planar structures of all compounds were determined by extensive analysis of NMR spectroscopic and HRMS data while the absolute configurations of the stereogenic carbons in the compounds were established by a comparison of their calculated and experimental ECD spectra [50].
An alkyl-guarnidine-substituted diketopiperazine-containing bromooxindole, geobarrettin A (138), an alkylguarnidine-substituted diketopiperazine-containing bromoindole, geobarrettin B (139), and geobarrettin C (140) (Figure 15), a trimethyloxoammoniumcontaining bromoindole, were isolated from a sub-Arctic sponge Geodia barretti collected from the west of Iceland. The structures of 138-140 were elucidated by interpretation of HRMS and 1D and 2D NMR spectral data. The configuration of C-3 of the oxindole moiety in 138 was determined by a comparison of the ECD spectra of the hydrolysis product of 138 and of (R)-3-proplyldioxindole, while the absolute configuration of C-12 of the diketopiperazine ring was determined by Marfey's method [51].

Bis-/Tris-Indole Alkaloids
Dragmacidin G (141) (Figure 16), a bis-bromoindole linked by a pyrazine ring with a N-(2-mercaptoethyl)-guanidine side chain, was isolated from the marine sponge of an unidentified species of Spongosorites (Family Halichondriidae) collected from Long Island, Bahamas by the Johnson-Sea-Link I manned submersible at a depth of 630 m. The structure of the compound was elucidated by extensive analysis of NMR spectra and HRMS [52]. Compound 141 was also isolated, together with dragmacidin H (142) (Figure 16), from a marine sponge Lipastrotethya sp., which was collected by dredging at Kurose, north of Hachijo Island, Japan [53]. Compound 142 differs from 141 in that only one indole moiety is brominated and the side chain of the pyrazine ring is N-(2-mercaptomethyl)-guanidine instead of N-(2-mercaptoethyl)-guanidine.
Dihydrospongotine C (143) (Figure 16), a member of bis-indole alkaloids comprising two bromoindole moieties linked together by 4,5-dihydro-1H-imidazol-2ylmethanol, was isolated from a deep-sea sponge Topsentia sp. collected in Palau at the depth of 140 m. The structure of the compound was established by extensive analysis of 1D and 2D spectra and HRMS data. The absolute configurations of the stereogenic carbons were established by a comparison of the calculated and experimental ECD spectra as 4S, 6S [54].
Calcicamides A (151) and B (152) (Figure 16), two bis-indole alkaloids comprising one indole and one 6-bromoindole connected through an aminoalkyl α-ketoamide moiety, were isolated from a marine sponge Spongosorites calcicole collected at Rathlin Island (Co. Antrim), Northern Ireland, at a 18 m depth. Compounds 151 and 152 are constitutional isomers as they have the same molecular formula. 1D and 2D-NMR spectral analysis revealed that both compounds have an indole portion linked to the α-ketoamide moiety that is connected to C-8 and C-9 of 6-bromotryptamine in 151 and 152, respectively. The absolute configuration of the stereogenic carbon (C-8) of both compounds was established as S through a comparison of the calculated and experimental ECD spectra. The structures of 151 and 152 were hypothesized as intermediates in the biosynthesis of a cyclic structure that linked to both indole moieties such as spongotine and toptensin as well as the hamacanthin B derivative [57].
Dragmacidins I (153) and J (154) (Figure 17), bis-indole alkaloids featuring one indole and one 6-bromoindole linked to C-2 and C-5 of a piperazine ring, were isolated from a marine sponge Dragmacidon sp., which was collected from Kashani Island in Tanzania. The absolute configurations of the stereogenic carbons in 153 and 154 were proposed to be 2R,5S on the basis of their measured optical rotation values, which were very close to those reported for dragmacidin A, prepared by enantioselective total synthesis [58].
Spongosoritins A-D (155-158) (Figure 17), bis-indole alkaloids comprising two indole moieties linked through a 2-keto-2-methoxy-1-imidazole-5-one core, along with spongocarbamides A (159) and B (160) (Figure 17), another two bis-indoles whose two indole moieties were connected through a linear type keto urea, were isolated from a marine sponge Spongosorites sp. collected at the depth of 25-30 m offshore Seogwipo, Jeju Island, Korea. The structures of 155-160 were elucidated by a combination of HRMS and 1D and 2D NMR spectral analysis. The absolute configuration of the stereogenic carbon in the imidazolone ring of 155-158 was established by comparison of the calculated and experimental ECD spectra [59]. Tulongicin A (161) ( Figure 17) is a tris-indole alkaloid featuring an imidazole ring connected to three 6-bromoindole units. One of the 6-bromoindole is directly linked to C-4 of the indole core while another two 6-bromoindole units formed a bis(indolyl) methane moiety and linked to C-2 of the imidazole ring. Compound 161 was isolated together with 141 from a deep-water marine sponge Topsentia sp. [54]. 5-Bromotrisindoline (162) and 6-bromotrisindoline (163) (Figure 17) are tris-indole alkaloids comprising two indoles and one bromooxindole linked together through C-3 of each indole unit. The difference between 162 and 163 is that the bromine atom is on C-5 of the oxindole ring in 162, but on C-6 in 163. Although 162 and 163 were first isolated as new natural products from a marine sponge Callyspongia siphonella collected from Hurghada, Egypt, along the Red Sea Coast, they have already been reported as synthetic intermediates [60].
A bis-indole alkaloid, myrindole A (164) (Figure 17), was isolated from a marine sponge Myrmekioderma sp. collected in Sagosone, Japan. Compound 164 features a tetrahydroquinoxaline ring system fused with imidazolidin-2-imine as a central core, having the cyclohexane ring fused with 6-bromoindole while C-2 of the pyrazine ring is linked to an indole moiety. Besides the usual 1D and 2D NMR spectral analysis, 1 H-15 N HMBC and 1,n-ADEQUATE correlations were used to unravel this complex structure. The absolute configurations of C-5 and C-6 in 164 were determined as 5S,6R by comparison of the calculated and experimental ECD spectra [61].

Bryozoans
Bryozoans are another rich source of indole alkaloids. Simple, prenylayed, and annelated indoles have been reported from bryozoans.

Prenylated Indoles
The organic extract of a marine bryozoan Flustra foliacea, collected near the southwest coast of Iceland at 13 m depth, furnished 13 prenylated indole alkaloids, viz. flustramines Q-W (166-172) and flustraminols C−H (173-178) ( Figure 18). Although the structures of 166 and 168 apparently do not contain the indole ring system, they were derived from the degradation and rearrangement of the indole nucleus. Compound 167 shows interesting features with N,N-dimethylaminoethyl and thiomorpholine 1,1-dioxide ring substituents, while 169 is a bis-indole with one of the indole rings fused with a prenyl-derived bicyclic system. Compounds 175-177 are diprenylated pyrrolidine-fused indoles. The structures of the compounds were elucidated by extensive analysis of 1D and 2D NMR spectra and HRMS data. In the case of 167, the absolute configurations of the stereogenic carbons were determined by a comparison of the calculated and experimental ECD spectra of its bis-trifluoroacetate double salt. The absolute configurations of the stereogenic carbons in 171, 172, 174, 175-178 were established based on a comparison of the CEs of their ECD spectra with those of the compounds containing related chromophores and whose absolute structures have been established. Only relative configurations of the stereogenic carbons of 173 and 178 were determined by NOESY correlations and by observation of the 1 H chemical shift values, respectively [63].

Annelated Indole Alkaloids
Securamines H-J (179-181) (Figure 18), hexacyclic annelated indole alkaloids featuring an imidazolone-containing bromoindole fused with pyrrolidinone moiety, were isolated from the Arctic bryozoan Securiflustra securifrons, collected by an Agassiz trawl at 73 m depth from west Spitzbergen. The structures of the compounds were established by extensive analysis of 1D and 2D NMR spectra and HRMS data, however, the absolute configurations of their stereogenic carbons were not determined [64].

Marine Plants
Marine plants seem to not be very good producers of indole alkaloids. Only one marine alga and one mangrove plant have been reported as sources of indole alkaloids during this period.

Algae
Four brominated indoles (182-185) ( Figure 19) were isolated from the organic extract of the marine alga Laurencia similis collected in the South China Sea. Compound 182 is a simple dibromoindole with a benzyl group on C-3 of the indole core while 183 is an oxindole with a 2-propylidene on C-3. On the other hand, 184 is an annelated bromoindole while 185 features a carbamate-containing benzoic acid derivative resulting from the oxidative ring opening of a pyrrole ring of the indole nucleus [65].
A bromide salt of a synthetic version of tricepyridinium (122) (Figure 13) was found to display a significant antibacterial activity against Bacillus cereus with a MIC value of 0.78 µg/mL and methicillin-sensitive S. aureus (MSSA) with a MIC value of 1.56 µg/mL as well as a moderate antifungal activity against C. albicans with a MIC value of 12.5 µg/mL. However, the compound did not show any activity against E. coli at 100 µg/mL. Structureactivity relationship study with a synthetic version and two indole moieties revealed that the three indole moieties of 122 and the charged pyridinium were mainly responsible for a strong cytotoxicity toward Gram-positive bacteria and fungi. Moreover, it was found that the indole group at the 3-or 5-position was more important than an indole group at the 8 -position [47].
A pyrazino bis-indole dragmacidin G (141) (Figure 16) was found to exhibit a potent antibacterial activity against S. aureus and MRSA with MIC values of 0.62 µg/mL (1 µM) for both strains. Compound 141 also displayed an anti-mycobacterial activity in the assay that used Mycobacterium tuberculosis CDC1551 carrying the pMV306hsp-LuxG13 integrative plasmid, which provides constitutive expression of the luxCDABE operon [52].
The bis-indole alkaloid myrindole A (164) (Figure 17) was found to inhibit the growth of E. coli and B. subtilis with MIC values of 37.5 and 18.5 µM, respectively [61]. The structure of 164 was quite similar to that of dragmacidin E, except for the substitution pattern of the pyrazine ring [67].

Antiviral Activity
Fusariumindole C (1), (±)-isoalternatine A (2) (Figure 3), fusaindoterpenes A (48) and B (49) (Figure 6), and fusariumindoles A (75) and B (74) (Figure 10), were evaluated for their antiviral activity against the Zika virus (ZIKV) by a plaque assay on A549 (human lung carcinoma) cell cultures . Compounds 48, 49, 74, and 75 exhibited anti-ZIKV activity with EC 50 values of 12, 7.5, 50, and 48 µM, respectively. Interestingly, 49 was two-fold more potent against ZIKV than the adenosine analog NITD008, which is a potent inhibitor of ZIKV (NITD008, a positive control, showed an EC 50 value of 15 µM). Preliminary structureactivity relationship study of these compounds, in comparison with the related compounds previously reported, revealed that the intact pyrrole ring of the indole moiety fused with the cyclopentane ring is required for the activity since introducing an oxygen atom to the pyrrole ring caused a loss of activity in 48 when compared to 49 [7].
Dihydrospongotine C (143) ( Figure 16) and tulongicin A (161) ( Figure 17) were evaluated for their anti-HIV activity in HIV infectivity assays against the CCR5-tropic primary isolate YU2 and the CXCR4-tropic strain HxB2. Compounds 143 and 161 displayed IC 50 values of 3.5 and 3.9 µM against YU2 and 4.5 and 2.5 µM against HxB2, respectively [54].  (Figure 4) were evaluated for their effects on the viability of human non-malignant and prostate cancer cells as well as on the colony formation of human prostate cancer cells 22Rv1, which are known to be resistant to hormone therapy including the novel second generation drugs abiraterone and enzalutamide due to the presence of androgen receptor splice variant AR-V7. Compound 16 did not display cytotoxicity to non-malignant human lung (MRC-9) and human kidney (HEK 293 T) cell lines as well as malignant prostate cancer (22Rv1, PC-3, and LNCaP) cell lines at concentrations up to 100 µM after 48 h of treatment. Moreover, 16 inhibited the colony formation of 22Rv1 cells at a concentration of 100 µM and significantly decreased colony formation at a concentration of 10 µM by 25% [17].
Asperindoles A (67) and C (69) (Figure 9) were assayed for cell viability, cell cycle progression, and induction of apoptosis in human prostate cancer cell lines 22Rv1, PC-3, and LNCaP. Compound 67 exhibited cytotoxicity in all three cell lines, with IC 50 values of 69.4, 47.8, and 4.86 µM, respectively (a positive control, docetaxel, showed IC 50 values of 15.4, 3.8, and 12.7 nM, respectively). Compound 67 was able to induce apoptosis in 22Rv1 cells at low-micromolar concentration and revealed the S-phase arrest in cell cycle progression analysis. In contrast, 69 was non-cytotoxic against PC-3, LNCaP (androgensensitive human prostrate adenocarcinoma cells), and 22Rv1 cell line with IC 50 >100 µM. Moreover, 22Rv cells treated with 100 µM of 69 displayed only minimal induction of apoptosis as well as no significant changes in cell cycle progression [28].
The bromide salt of a synthetic version of tricepyridinium (122) ( Figure 13) displayed cytotoxicity against murine leukemia P388 cells with an IC 50 value of 1.0 µM. Comparison of the cytotoxicity among various synthetic analogs revealed that the presence of the indole group at the ethyl side chain of the pyridinium ring of 122 did not enhance cytotoxicity against P388 cells. This structure−activity relationship assessment indicated that the two indole moieties played a concerted role with the 1-ethylpyridinium moiety to induce cytotoxicity of P388 cells. [47].
Dragmacidins G (141) and H (142) (Figure 16), isolated from a marine sponge Lipastrotethya sp., showed toxicity against HeLa cells with IC 50 values of 4.2 µM and 4.6 µM, respectively [53]. Later on, 142, isolated from a deep-water marine sponge of an unidentified species of Spongosorites, was assayed against a panel of pancreatic cancer cell lines and exhibited a moderate cytotoxicity against PANC-1 (human pancreatic carcinoma), MIA PaCa-2 (human pancreatic carcinoma), BxPC-3 (human pancreatic adenocarcinoma), and ASPC-1 (human pancreatic adenocarcinoma) with IC 50 23.72, 11.17, 17.24, and 25.09 µM, respectively (the IC 50 value of a positive control, MG132, was 0.17 µM). Since the tested compounds exhibited weak activity (IC 50 values more than 100 µM) against Raw264.7 cells, their inhibitory effects were not related to cell viability. Moreover, molecular docking studies between 18 and iNOS revealed that 18 adopted an extended conformation and fit well into the ligand binding site of the mutant iNOS. Moreover, hydrogen bonds were predicted between the carbonyl (C-12) and Asn115 as well as between the carbonyl (C-18) and Gln257, in addition to a possible π−π stacking interaction between the diketopiperazine or the double bond at C-10 and the HEME. The results of molecular docking led the authors to conclude that the planarity of the molecule is important for its binding capacity, as this conformation provides enough space for the two carbonyls to form strong hydrogen bonds with the HEME [18].
Sponge-derived diketopiperazine-containing bromooxindoles, geobarrettins A-C (138-140) (Figure 15), were assayed for their anti-inflammatory activity on human dendritic cell (DC) secretion of pro-inflammatory cytokine IL-12p40 and anti-inflammatory cytokine IL-10 production. At a concentration of 10 µg/mL, during 24 h, 139 decreased DC secretion of IL-12p40 by 29% without affecting the secretion of IL-10 while 140 slightly decreased the DC secretion of IL-12p40 by 13% but increased IL-10 production by 40%. Moreover, it was found that the effects of 139 and 140 on IL-12p40 and IL-10 secretion by DCs were not dose-dependent, although 139 showed a tendency of an increasing effect on the secretion of IL-12p40 at higher concentrations. To further elucidate the anti-inflammatory activity of the compounds, DCs matured in the presence of 139 and 140 were co-cultured with allogeneic CD4 + T cells and the differentiation of the T cells was investigated by determination of the secretion of the cytokines IL-10, IL-17, and IFN-γ. It was found that T cells co-cultured with DCs matured in the presence of 139 and 140 secreted less IL-10 and IFN-γ than T cells co-cultured with DCs matured without the compounds, however, maturing DCs in the presence of 139 and 140 did not affect T cell secretion of IL-17 [51].
The prenylated indoles, flustramines Q−W (166-172) and flustraminols C−H (173-178) ( Figure 18), were evaluated for their anti-inflammatory activities by evaluating their effects, at a concentration of 10 µg/mL, on DC secretion of the cytokines IL-12p40 and IL-10 and comparing them to the effect of solvent alone. This model is based on the fact that if a compound either decreases DC secretion of IL-12 or increases secretion of IL-10, it is considered to have an anti-inflammatory effect. The results showed that 166, 168, 170, and 178 decreased DC secretion of the pro-inflammatory cytokine IL-12p40 in the range of 32% to 55% whereas 169 increased DC secretion of the anti-inflammatory cytokine IL-10 by 19−30%, and therefore had modest anti-inflammatory effects. Since none of the active compounds affected the viability of DCs at 10 µg/mL, it was concluded that the decrease in IL12p40 secretion was not due to impaired cell viability [63].

Antidiabetic Activity
Scequinadoline J (6) (Figure 3) was screened for its potentiality as an anti-diabetes mellitus type 2 (T2DM) agent by using the 3T3-L1 fibroblast cell line. Compound 6 was found to promote triglyceride (TG) accumulation in 3T3-L1 cells with an EC 50 value of 1.03 µM (rosiglitazone, a clinically used medication for T2DM, was used as a positive control and showed an EC 50 value of 0.12 µM). Moreover, 6 did not show cytotoxicity against 3T3-L1 cells at a concentration of 50 µM. Furthermore, it was found that 6 promoted TG accumulation mainly by facilitating adipogenesis and not lipogenesis, which is similar to rosiglitazone [11].
Since hypoadiponectinemia is a major symptom of diverse human metabolic diseases such as obesity, type 2 diabetes, atherosclerosis, and non-alcoholic steatohepatitis, compounds that stimulate adiponectin secretion could be promising for the treatment of metabolic diseases such as T2DM. For these reasons, psammocindoles A-C (123-125) ( Figure 14) were evaluated for the adiponectin-secretion-stimulating activities in hBM-MSCs using an adipogenic cocktail consisting of insulin, dexamethasone, and isobutyl methylxanthine (IDX). Compounds 123-125 (at 10 µM) significantly increased adiponectin secretion during adipogenesis in hBM-MSCs compared to that in the IDX control. In a concentration-response analysis, 123 and 124 were found to be more potent (EC 50 = 9.86 and 6.20 µM, respectively) than bezafibrate (EC 50 > 10 µM), a currently prescribed pan-PPAR agonist, while 125 was less potent (EC 50 > 10 µM). Moreover, 123 and 124 also increased the lipid accumulation in differentiated adipocytes in hBM-MSCs compared to that of the IDX control, suggesting that, similar to pioglitazone, 123 and 124 are able to improve insulin sensitivity. Thus, these compounds could represent a novel pharmacophore for the development of therapeutic agents for the treatment of human metabolic diseases [48]. (±)-Oxoaplysinopsin B (132a/132b) ( Figure 14) showed inhibitory activity against PTP1B with an IC 50 value of 20.8 µM. Interestingly, the optically pure (+)-132a was more potent (IC 50 = 18.3 µM) than both the racemate and (−)-132a (IC 50 = 26.5 µM) [50].

Neuroprotective Activity
The deoxyisoaustamide derivatives 24-30 ( Figure 5) were examined for their potential protective effects against the acute toxicity of paraquat (PQ) in murine neuroblastoma Neuro-2a cells. Treatment of Neuro-2a cells with 500 µM of PQ induced a decrease in cell viability by 51.8%. However, co-treatment with 1 µM of 27 and 29 increased a viability of PQ-treated cells by 38.6% and 30.3%, respectively, whereas 28 increased a viability of the cells by 36.5% and 39.4% at concentrations of 1 µM and 10 µM, respectively. Moreover, 27, 28, and 29 were not cytotoxic to Neuro-2a cells [17].

Enzyme Inhibitors
Guitarrins A-E (126-130) ( Figure 14) were assayed for the inhibitory activity against the enzyme alkaline phosphatase (ALP) from the marine bacterium Cobetia marina. Reasons for interest in this ALP are its possible application as a tool for structural and functional studies of nucleic acids as well as for the preparation of Ig-enzyme conjugates for immunologic assays. ALP produced by C. marina was found to have very high specific activity. Compound 128 was found to be a potent inhibitor of ALP from C. marina with an IC 50 value of 2.0 µM when compared to a positive control, ethylenediaminetetraacetic acid (EDTA, IC 50 = 80,000 µM), which is the most active inhibitor of C. marina alkaline phos-phatase (CmAP) described to date. On the other hand, 129 showed weak inhibitory activity (IC 50 = 100 µM) whereas 126, 127, and 130 did not inhibit this enzyme [49].

Other Activities
Dinotoamide J (73) (Figure 9) was tested for its pro-angiogenic activity in a vatalanib (PTK787)-induced vascular injury zebrafish model. At a concentration of 70 µg/mL, 73 exhibited a significant effect in a dose-dependent manner. Ginsenoside Rg1 (120 µg/mL) was used as a positive control [30].

Conclusions
Marine organisms have been proven to be valuable sources of structurally diverse and unique indole compounds. Their structures vary from simple to complex and incorporate different types of compounds ranging from simple prenyl groups to diterpene moieties or other molecules or scaffolds such as pyrazine, diketopiperazine, guanidine, and quinazoline. The indole ring system can be present as an intact indole or undergoes oxidation or/and rearrangements to form different scaffolds or even incorporate a nitrogen atom to form azaindole derivatives or halogen and sulfur atoms to form bromoindoles, sulfonyl, and sulfinyl side chains. Moreover, these marine-derived indoles can have a single indole unit or contain two or three indole units as found in bis-indoles, tris-indoles, homo-, and heterodimers of indole compounds. This structural diversity of marine-derived indoles is reflected by a variety of biological and pharmacological activities that they manifest such as antibacterial, antiviral, anticancer, antiparasitic activities, and enzyme inhibition. Thus, marine-derived indole compounds are excellent sources to be explored for pharmacophores to serve for the development of drug leads or even therapeutic agents for the treatments of infectious diseases, cancer, or even some metabolic diseases.