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Review

Traditional Uses, Phytochemistry and Pharmacological Activities of Annonacae

by
Bassam S. M. Al Kazman
,
Joanna E. Harnett
and
Jane R. Hanrahan
*
Faculty of Medicine and Health, The School of Pharmacy, The University of Sydney, Camperdown, NSW 2006, Australia
*
Author to whom correspondence should be addressed.
Molecules 2022, 27(11), 3462; https://doi.org/10.3390/molecules27113462
Submission received: 27 April 2022 / Revised: 17 May 2022 / Accepted: 23 May 2022 / Published: 27 May 2022
(This article belongs to the Special Issue Biomolecules from Plant and Animal Wastes: From Processing to Application in Food and Medicine II)
Browse Figure
Versions Notes

Abstract

:
In 1789, the Annonaceae family was catalogued by de Jussieu. It encompasses tropical and subtropical plants which are widespread in distribution across various continents such as Asia, South and Central America, Australia and Africa. The genus of Annona is one of 120 genera of the Annonaceae family and contains more than 119 species of trees and shrubs. Most species are found in tropical America, where over 105 species have been identified. Due to its edible fruits and medicinal properties, Annona is the most studied genus of Annonaceae family. To date, only a limited number of these species have economic value, including A. squamosa L. (sugar apple), A. cherimola Mill. (Cherimoya), A. muricata L. (guanabana or soursop), A. atemoya Mabb. (atemoya), a hybrid between A. cherimola and A. squamosa, A. reticulata L. (custard apple), A. glabra L. (pond-apple) and A. macroprophyllata Donn. Sm. (ilama). Phytochemically, several classes of secondary metabolites, including acetogenins, essential oils, alkaloids, terpenoids and flavonoids. The pharmacological activities of Annona species leaves and seeds include antibacterial, anticancer, antidiabetic and anti-inflammatory properties.

1. Introduction

In 1789, the Annonaceae family was cataloged by de Jussieu [1,2]. It encompasses tropical and subtropical plants, which are widespread in distribution across various continents such as Asia, South and Central America, Australia and Africa [3]. It is one of the largest Mangnoliidae families and the number of its genera and species is still debated [4,5,6]. Bailey and Popenoe believe that it has between 40 and 50 genera and from 500 to 600 species [6]; however, many studies have indicated that the Annonaceae family is comprised of more than 2400 species distributed in approximately 120 genera [4,5]. The family of Annonaceae involves trees, lianas and bushes arranged in four large subfamilies: Malmeoideae, Annonoideae, Ambavioideae and Anaxagoreoideae [7,8]. Economically, species of Annonaceae are important as a source of edible fruits, for instance, the pawpaw (Asimina), custard apple, sweetsop, soursop and cherimoya [1]. It has also been reported that some oils from the seeds might be used for the production of edible oils and as an ingredient in soaps, and the woods of some species have been reported for alcohol production [3]. Chemical studies of Annonaceae species have reported the isolation of a wide diversity of phytochemical components, including acetogenins, alkaloids and flavonoids from the bark, fruits, leaves, seeds and pulp of Annonaceae [9]. This review aims to provide a comprehensive summary of the botanical features, phytochemistry, pharmacological properties, and the traditional and ethnomedicinal uses of the Annonaceae family and, specifically, Annona species.

2. Botanical Features of Annonaceae Species

2.1. Distribution and Classification

Annonaceae has been listed as a diverse family of aromatic trees, bushes or shrubs, and climbers or lianas, which are predominantly found in the tropical and subtropical regions, with a limited number growing in temperate zones [1,10]. In tropical America, the Annonaceae species are usually shrubby and most grow in open grasslands [1]. In contrast, species that are climbers mostly grow in the tropical area of the old world [1]. In temperate zones like North America, the only genus reported is Asimina [1,3]. In Brazil, more than 385 species have been reported, with the majority of them reported in the Amazonian region [2]. According to the Takhtajan system of flowering plant classification, the majority of Annonaceae plants can be found in both Asia and Australasia with approximately 51 genera and more than 950 species, while 40 genera with approximately 450 species are confined to Africa and Madagascar, and about 38 genera and 740 species are native to the American continent [3]. The first classification of the Annonaceae family was described by Dunal in 1817 and was limited to only fruit morphology [11]. Subsequently, a new classification of the Annonaceae family based on flower characteristics was introduced by Diels and Alder in 1932 [11]. However, a later classification by Fries in 1959 was found to be more comprehensive and authentic, using a combination of fruit morphology and flora characteristics [11]. The Annonaceae family are characterised by the presence of a variety of primitive and archaic features, leading to them being described by Darwin as “living fossil” due to their ability to survive the mass extinction [1,11]. Under the Takhtajan system, the Annonaceae family is related to Magnoliaceae, which is one of the largest families of Magnoliales with other families such as Degeneriaceae, Canellaceae, Himantandraceae and Myristicaceae [1,11].

2.2. Diagnostic Features

From one species to another, the botanical features of Annonaceae families vary greatly based on their origin, geography, and climate. Based on morphology and habitat, the Annonaceae family is known among the homogeneous plant families [1,4]. The aromatic flowers are commonly open before other parts are entirely developed. The flowers are terminal, axillary, hermaphrodite, singular or grouped and regular [1,11]. The stamens are typically abundant, spirally arranged and hypogenous [1,11]. The leaves are characterised by having a glaucous or metallic sheen, and they are alternate, exstipulate and regular [1,11]. The fruits are typically made up of clusters of berries with an edible fleshy receptacle, particularly in the Annona genera and they are extensively consumed due to their high nutritional value [1,11]. Finally, the seeds are enlarged and have a copious, irregular-surfaced endosperm with a minute embryo [1,11].

2.3. Traditional Uses

Annonaceae species are famous in tropical regions and used traditionally across tropical regions due to their widespread distribution. Various parts of the species are used traditionally, including leaves, seeds, bark, fruit, stem, roots and twigs. A range of different methods for preparation is reported, such as infusions, pastes and decoctions [11]. For instance, the fresh fruit of Annona dioica is used for wound healing in Brazil [11]. The dried leaves of Annona muricata are used orally for analgesic effects in some parts of Indonesia [11]. In Burkina-Faso, the bark and roots of Annona muricata are used for dysentery and as an anthelmintic medicine, whereas the leaves are utilized for both fever and dysentery [12]. In the northwestern part of Brazil, both leaves and twigs of Duguetia chrysocarpa are ground and the extract of this mixture are utilized for treating gastrointestinal ulcers as well as a remedy for bowel disease [11]. A decoction of the stem bark of Annickia chlorantha is used orally as a remedy for the treatment of wounds and fever in Cameroon [13]. Further data on the traditional uses of the most widely used Annonaceae species are presented in Table 1.

3. Phytochemistry of Annonaceae Family

A wide array of chemical compounds from various parts of Annonaceae plants have been discovered, isolated and characterised. The results of both phytochemical investigations and biological studies on various plants from this family have led to the identification of a wide diversity of compounds such as annonaceous acetogenins, flavonoids, alkaloids and essential oils, as summarized in (Table 2). These phytochemical constituents have been found to exhibit a broad range of biological activities such as immunosuppressive, antineoplastic, cytotoxic, antimicrobial, anti-inflammatory effects (Table 3). However, it is the Annona genera that are the most widely used as a food source and in traditional medicines.

4. Annona Genera

The genus of Annona is one of the 120 genera of the Annonaceae family and contains more than 119 species of trees and shrubs, most of them distributed in tropical areas of the Americas and Africa [6]. The majority of these species are found in tropical America, with more than 105 species (26 of them are endemic) and 10 species distributed in tropical Africa [10,34]. It has been reported that this genus is the second or the third largest genus in the Annonaceae family [35]. Its generic name derives from the Latin Hispaniolan Taino “annual harvest” [6,35]. Due to its edible fruits and medicinal properties, Annona is the most important genus of Annonaceae family [2]. Numerous Annona species furnish edible fruits like Annona muricata (“graviola”), Annona crassiflora (“araticum”) and Annona sqaumosa (“fruta do conde”) [2]. Most of the fruits are consumed either in fresh form or used in desserts, juices and ice cream preparations [34]. Despite Annona having many species, only limited species of this family are economically important such as A. squamosa L. (sugar apple), A. cherimola Mill. (Cherimoya), A. muricata L. (guanabana or soursop), A. atemoya Mabb. (atemoya), a hybrid between A. cherimola and A. squamosa, A. reticulata L. (custard apple), A. glabra L. (pond-apple) and A. macroprophyllata Donn. Sm. (ilama) [6]. Phytochemically, several classes of secondary metabolites such as acetogenins, essential oils, alkaloids, terpenoids and flavonoids have been described in this genus [34,36]. A variety of pharmacological activities have been reported from various parts of Annona species specially leaves and seeds including applications against antibacterial [37], antinociceptive [38], anticancer [39], anticonvulsant [40], antidiarrhea [41], antidiabetic [42], antimalarial [39], anti-inflammatory [43], antioxidant [44], antileishmanial [45], antiulcer [46] and antidepressant [47].

4.1. Botanical Features

Generally, Annona species are small trees or shrubs with a height from 5 to 11 m depending on various factors including soil, climate, species, and crop management [2]. In relation to the botanical characteristics of Annona species, the majority of them are moderately erect with brown bark that is frequently furrowed (Table 4) [10]. The stems are rust-coloured (ferruginous) and covered with densely matted hairs (tomentose) when young, becoming smooth and hairless (glabrous) as they mature [6,10]. It has thin lateral roots and a taproot that is not generally pronounced [2]. With regard to the flowers, they are hermaphrodites, solitary or fascicle containing from two to four flowers. The flowers are usually fragrant, with six petals and three green sepals, in a circular arrangement of two verticils [6]. Flowering of the plant usually starts at 3 to 4 years and flower opening usually occurs by separation of the apex of external petals [6,10]. Finally, the leaves may be shiny or hairy and have an impressed vein on the upper side, and the fruits are syncarpous and comprised of seeds and many carpels [6,10].

4.1.1. Annona Cherimola

Annona cherimola Mill (Cherimoya) belongs to the genus Annona in the Annonaceae family in magnolias order, which means “cold seeds”, and is a small tree that produces heart-shaped and conical edible fruit [55]. It is a steep, semi-momentary and a low bunched tree that is widespread in Ecuador and Peru and distributed throughout Asia, South Europe, America and Africa [56]. In Mexican traditional medicine, this plant has been used to treat various diseases such as diabetes, cough, fever, headache, worms and inflammation either alone or in combination with other plant species [48,57,58,59,60]. Recently, various parts of A. cherimola have been phytochemically profiled and contain various polyphenols and alkaloids. The leaves were found to be a source of bioactive compounds with potential for use as treatments for skin and eye diseases and gastric, cardiovascular and intestinal disorders [55].

4.1.2. Annona Squamosa

Annon squamosa L., commonly known as custard apple, is a tropical, endemic species of the West Indies, Ecuador, Peru, Brazil, South and Central America, Mexico, Bahamas, Bermuda, and Egypt [61]. This plant is extensively cultivated in various states of India, including Maharashtra, Gujarat, Madhya Pradesh, Chhattisgarh, Assam, Uttar Pradesh, Bihar, Rajasthan, Andhra Pradesh, and Tamil Nadu. The total area of cultivation has been reported by the Indian Council of Agricultural Research (ICAR) as 40,000 ha [62]. Its tree grows as a small sapling from 3 m to 8 m, with large branches having brownish or light brownish bark and it has thin leaves and is known for its edible fruit [61]. In the Aligarh district village in Uttar Pradesh, A. squamosa is well-known for its antidiabetic properties [63]. Its seeds, bark and leaves possess various pharmacological properties, mainly anti-tumour properties [64].

4.1.3. Annona Muricata

Annona muricata is a commonly known as soursop and graviola and is native to Central and South America. It is a small tree 5–10 m tall and 15–83 cm in diameter; it has low branches and edible fruit that are used commercially for the production of candy, juice and sherbets [65]. Traditionally, the aerial parts of this plant have been used to treat various diseases like diabetes and malaria and nowadays, it is widely used by people diagnosed with cancer [66]. Moreover, this species possesses several pharmacological properties, including vasodilator, cardio-depressive, antispasmodic, antimutagen, anticonvulsant, antiviral, antidiabetic and antihypertensive effects [67]. Both the leaves and seeds of A. muricata have been evaluated for their constituents resulting in the identification and isolation of more than 50 mono-THF acetogenins, alkaloids, terpenoids, saponins, flavonoids, coumarins, cardiac glycosides, phenols, tannins and anthraquinones [67].

4.1.4. Annona Reticulata

Annona reticulata Linn is a traditionally important plant utilized in traditional medicines [68]. It is indigenous to the West Indies and widely distributed in tropical and subtropical regions of the world [54]. It is a small tree with a height between 6 and 7.5 m and contains numerous lateral branches [54]. It has a cylindrical stem that contains lenticels and very short coffee-colored hairs [54]. The leaves of A. reticulata are lanceolate, membranous, oblong, and rounded or curate at the base. Fruits are edible, rough, somewhat heart-shaped and yellow in color that shifts to yellowish-red on ripening, and the seed is smooth and blackish in color [69]. Traditionally, A. reticulata has been utilized for the treatment of epilepsy, dysentery, cardiac problem, constipation, haemorrhage, bacterial infection, parasite and worm infestations, fever, ulcers and as an insecticide [68,69]. Its leaves are used for helminthiasis treatment while bark is a powerful astringent and used as a tonic [68,69].

4.1.5. Annona Coriacea

Annona coriacea Mart. is a species belonging to the Annona genera, commonly known as “marolo”, “araticum” and “araticum-liso” [70]. This plant is distributed across Paraguay and Brazil, with little available information about its ethnomedicinal uses [71]. It is a small tree (3–6 m) and its edible fruit consist of an ovoid-obtuse syncarp and weighing up to 1.5 kg [72]. The leaves are glabrous on the ventral surface, obovate, and the base is frequently cordate and margin undulate [73]. The flowers are terminal, thick, solitary and having fleshy petals with colors shifting between orange and pink [73]. The leaves are traditionally used as carminatives, anthelmintics, antirheumatics and in the treatment of stomatitis, headaches, abscesses, neuralgia, rheumatism, ulcers and dermatitis [74,75]. Both seeds and fruits are toxic when crushed and exhibited effects against ectoparasites like lice [75].

4.1.6. Annona Senegalensis

Annona senegalensis is a small tree 2–6 m tall that is commonly known as wild custard apple and wild soursop [76]. This plant is native to tropical east and northeast, west and west-central, and southern Africa and islands in the western Indian Ocean [76]. Its leaves are simple, alternate, oblong, green to bluish-green, ovate or elliptic, and mainly lack hairs on the upper surface and brownish hairs on the lower surface [77]. This plant has been used in traditional medicine as a pain reliever, antioxidant, antidiarrheal, antitrypanosomal, antimalarial, anti-inflammatory, antimicrobial, antiparasitic, anticonvulsant and as an anti-snake venom [78]. It has been reported that the leaves of A. senegalensis are used for the treatment of tuberculosis, yellow fever and smallpox, whereas stem bark is reported for the treatment of injury from venomous animals [79]. The root was also reported for treating erectile dysfunction, tuberculosis, gastritis, reproductive deficiency and in the management of malaria and diabetes [80].

4.1.7. Annona Vepretorum Mart

Annona vepretorum is commonly recognized as ‘bruteira’, is a small tree of 2.5–10 m high native to the Brazilian biome Caatinga [81]. The fruits of A. vepretorum can be consumed either raw or as juice for nutritional purposes [82]. Traditionally, a decoction of the leaves have been used to bathe in for the treatment of allergies, yeast, skin diseases and microbial infections, whereas the root is traditionally used to treat snake and bee bites, inflammatory conditions and heart pain [81].

4.1.8. Annona Salzmannii

Annona salzmannii is a tree of 6–20 m high that known as “araticum-da-mata” and “araticum“apé” [83]. It is commonly cultivated in Brazil especially in the States of Bahia, Pernambuco, and Paraíba [83]. Its root, seeds and leaves are used in folk medicine for treating several illnesses like ulcers, dysentery and inflammatory conditions [83]. The leaves and bark of A. salzmannii are utilized for the treatment of tumors, diabetes and inflammatory conditions [84].

4.1.9. Annona Crassiflor

Annona crassiflor is known as araticum of cerrado or cerradão [85]. It is a small tree that bears a typical fruit known as araticum of cerrado or cerradão [86]. The fruits are highly consumed “in natura” by native people and can be used to make juice, jelly and ice-cream [85,86]. In folk medicine, the seeds are used to treat scalp infections, and infusions of the leaves and seeds are utilized for their antidiarrheal and antitumor properties [85]. For more details about the botanical characteristics and traditional uses of Annona species, see Table 4 and Table 5.

4.2. Traditional and Ethnomedicinal Uses of Annona Genus

Traditionally, the Annona species have been used widely. For instance, antidiarrheal effects have been reported for A. reticulata, A. muricata and A. salzmannii, whereas A. cherimola, A. squamosa and A. reticulata have been reported for their antiparasitic effects (Table 5) [10]. Moreover, both A. vepretorum and A. salzmannii have been also reported for anti-inflammatory effects [10]. A. purpurea and A. reticulata have been used to treat fever, while anticancer effects have been reported for A. senegalensis and A. muricata [105,106]. Furthermore, A. foetida, A. muricata and A. glabra have been traditionally used to treat rheumatism [107], while A. reticulata, A. salzmannii, A. foetida and A. squamosa have been described for treating ulcers [4]. In Indonesia, the fruit juice of A. muricata has used as a diuretic and to treat liver ailments and leprosy [108], whereas leaves was used to treat spasms, boils and as an aphrodisiac [36]. The leaves of A. diversifolia have been used as anti-inflammatory, anticonvulsant and analgesic agents [52]. Ethnobotanically, despite reports of the toxicity of A. muricata seeds, the powder of toasted seeds has been reported to be used as an emetic and cathartic in the traditional Mexican pharmacopeia [36]. To Southeast Asian people, the immature fruit of A. reticulata was used to treat both dysentery and diarrhea, and a decoction of roots was used to cure toothache and as an antipyretic [109]. Additionally, a decoction of leaves has been used internally against worms and topically to treat abscesses and boils [109]. Finally, the leaves of A. squamosa have been used as tonic and cold remedy in tropical America and systemically to cure dysentery in India [108].

5. Phytochemistry of Annona Species

A wide range of secondary metabolites, including acetogenins, flavonoids, alkaloids and essential oils (Figure 1), from nearly every part of Annona plants, have been discovered, isolated and characterised (Table 6). The plants of the Annona genera are also found to be rich in minerals and vitamins, for instance, calcium, potassium, magnesium, sodium, copper, zinc, selenium, phosphorus, iron, vitamin C, pantothenic acid B5, thiamine and riboflavin [6].

6. Pharmacological Properties of Annona Species

The species of the Annona genera have a been reported to elicit a diversity of biological activities such as antitumor, anti-inflammatory, antioxidant, antinociceptive, antiprotozoal, antipyretic, antiulcer, antihyperglycemic, anthelmintic, antileishmanial, antimalarial, antidiarrheal, antifungal and antimicrobial promoted by whole extracts, fractions, or pure compounds (Table 7).

6.1. Antibacterial Activity

The antibacterial activities of Annona species have been reported in many studies, for example, both methanolic and ethanolic leaf extracts of A. muricata exhibited antimicrobial activity against Staphylococcus aureus, and this activity was attributed due to the presence of flavonoids, alkaloids and steroids in the extract [165,166]. In contrast, an aqueous extract of the peel of A. muricata did not show any activity [165,166]. The root of A. reticulata has also been investigated for its antibacterial activity against Gram-positive Staphylococcus aureus, Bacillus cereus and Bacillus subtilis, and Gram-negative Pseudomonas aeruginosa, Escherichia coli and Salmonella typhi [54]. The root extract was found to possess pronounced activity against Bacillus cereus as well as notable inhibition against all tested strains [54]. Moreover, the leaves of A. cherimola have been reported for antibacterial activity against Staphylococcus aureus and Bacillus subtilis with growth inhibition zone diameters of 11 mm and 14 mm, respectively [37]. The aqueous and methanolic seed extracts of A. squamosa have reported activity against Staphylococcus aureus with Minimum Inhibitory Concentrations (MIC) of 50 mg/mL and Minimum Bactericidal Concentrations (MBC) of 100 mg/mL [167]. The activity of the isolated compounds from Annona species has been reported in various studies; for instance, the fatty alcohol 11-hydroxy-16-hentriacontanone isolated from leaves of A. squamosa has a reported activity against Gram-positive and Gram-negative bacterial strains, with MIC values of 25–50 µg/mL [168]. Additionally, the alkaloids liriodenine, annonaine, asimilobine, reticuline and cleistopholine isolated from A. salzmannii demonstrated activity against a range of Gram-positive bacteria, including Kocuria rhizophila, Staphylococcus aureus, Staphylococcus epidermidis and Enterococcus faecalis with MIC values from 25 to 500 µg/mL [36]. Notably, annonaine and asimilobine had activity equal to or better than the control chloramphenicol (MIC 50 µg/mL) against many of the species tested [36].

6.2. Anticancer and Antiproliferative Activity

Various studies have reported the anticancer activity of either crude extracts or isolated compounds from Annona species. For example, the leaves extract of both A. squamosa and A. reticulata exhibited potent antiproliferative effects against two human T-lymphotropic virus type = 1 infected cell lines (MT-1 and MT-2) with EC50 values from 0.1 to 1 µg/mL [169]. In in vitro studies, the ethanolic extract of A. muricata leaves was reported for its cytotoxicity against promonocytic leukemic cells (U-937) with an LC50 = 7.8 µg/mL [170]. Isocoreximine isolated from A. cherimola demonstrated cytotoxicity against multiple cancer cell lines. At a concentration of 50 µg/mL, isocoreximine inhibited cell viability of the breast cancer cell line (MCF-7) by 85.76%, human colorectal carcinoma cell line (HCT-15) by 63.05%, human prostate tumor cell line (PC-3) by 78.71%, human astrocytoma cell line (U-251) by 65.23% and human leukemia cell line (K-562) by 94.15% [112].
The antiproliferative activity of methanolic extracts from the leaves and seeds of A. coriacea was tested in vitro against a range of human tumor cell lines; including melanoma (UACC-62), non-small cell lung cancer cells (NCI-H460), colon cancer cell line (HT29), breast cancer (MCF-7) and leukemia (K-562). The seed extracts displayed potent antitumor activity with GI50 values between 0.02 and 3.83 µg/mL, and the leaf extracts exhibited anticancer activity at concentrations ranging from 0.02 to 0.08 µg/mL [35,171]. The cytotoxicity of annonacin, found in many Annona species, has been reported against various cell lines derived from cervical cancer (HeLa and HeLa S3] with IC50 0.219 and 0.426 µg/mL, and ovarian cancer (PA-1 and SKOV3) with IC50s of 0.452 and 0.411 µg/mL [172]. The cytotoxicity of annonacin has also been demonstrated against bladder cancer (T24), breast cancer (MCH7) and skin cancer (BCC-1) with IC50s 0.324, 0.433 and 0.427 µg/mL, respectively [172]. The cytotoxicity of five other acetogenins (squamocin M, annofolin, isolongimicin B, glaucanisin, and annotacin) isolated from A. cornifolia against human breast cancer (MCF-7) was reported, with IC50s of approximately 0.3 µM [173]. In an in vitro study, the annoaceous acetogenins laherradurin and cherimolin-2 isolated from A. diversifolia were shown to have ED50s of 0.015 and 0.05 µg/mL, respectively, against the cervical cancer cell line (HeLa) [174].
In clinical studies, the anticancer activity of A. muricata has been reported in a small number of studies. A patient diagnosed with breast cancer has maintained stable disease activity with no reported side effects after using an aqueous extract of A. muricata leaves for more than five years [175]. Another patient with metastatic ovarian cancer experienced disease stability after starting to take a complementary medication containing A. muricata as a tablet [176]. Finally, the effect of A. muricata leaves extract revealed higher cytotoxicity in the supplemented group with colorectal cancer compared with the placebo group in a randomized controlled trial [177].

6.3. Antidabetic and Antilipidemic Activity

Multiple studies have investigated the antidiabetic activity of various extracts from Annona plants such as A. cherimola, A. squamosa, A. muricata and A. reticulata. The ethanolic leaf extract of A. cherimola (300 mg/kg) was administered to alloxan-induced type 2 diabetic rats, and four hours later, blood glucose level had decreased from 331.5 mg/dL to 149.2 mg/dL [58]. The young leaves of A. squamosa, often in combination with black pepper (Piper nigrum), have been used in northern Indian traditional medicine as an anti-diabetic, and are still in use today. Administration of aqueous A. squamosa leaf extract to streptozotocin-nicotinamide type-2 diabetic rats resulted in decreased blood glucose and increased levels of serum insulin [178]. Another traditional Indian medicine used as an antidiabetic and anti-lipidemic is a polyherbal formulation of A. squamosa fruits and Nigella sativa seeds. The polyherbal formulation administered over a one-month period, dose-dependently decreased blood glucose and increased insulin in streptozotocin-induced diabetic rats, with a dose of 200 mg/kg showing similar to the effects of a dose of 250 mg/kg tolbutamide [179]. A single dose of 100 or 200 mg/kg of aqueous leaf extract of A. muricata did not inhibit blood glucose levels in normal rats; however, the same doses administered to the diabetic rats effectively lowered blood glucose levels by 31.77% and 45.77%, respectively [180]. Finally, a dose of 100 mg/kg of both methanolic extract and the residual fractions of A. reticulata leaves decreased blood glucose levels from 432.33 to 371.67 mg/dL and 417.83 to 402.50 mg/dL, respectively, in streptozotocin-induced diabetic rats [181]. A. cherimola leaf extract was also found to decrease HbA1c by 7% and lead to a significant decrease in urine glucose over a 28-day subchronic study in streptozotocin-induced diabetic mice [182]. These studies support the traditional use of Annona species as antidiabetics, suggesting that further identification of the active constituent(s) with antidiabetic properties and clinical studies of a longer duration are warranted.
Limited studies have also investigated the antilipidemic activity of some Annona species. The polyherbal formulation of A. squamosa fruits and Nigella sativa seeds (200 mg/kg) administered to streptozotocin-induced diabetic rats for one month also resulted in significant inhibition of the formation of both lipid peroxide and tissue lipids [179]. Administration of an extract of A. muricata extracts resulted in reductions in the serum total cholesterol, low-density lipoprotein cholesterol and triglycerides in diabetic rats [183]. The tea infusion of leaves from A. cherimola (1.5 g) also elicited a reduction in the total cholesterol, triglycerides, and low-density lipoprotein by 15.4, 21.9 and 63.2%, respectively, in streptozotocin-induced diabetic rats [182].

6.4. Anti-Inflammatory Activity

The anti-inflammatory effects of Annona plants have been reported in many studies; for instance, after one day of orally administered doses of 200 and 400 mg/kg of A. squamosa root extract in an acute carrageenan-induced rat paw edema model, significant inhibition was produced with 24% and 47% inhibition respectively compared to diclofenac sodium inhibiting inflammation by 72% [184]. In an in vitro study, the chloroform extract of A. muricata leaves significantly inhibited activity of phospholipase A2 [185]. With doses of 0.2–0.6 mg/mL, the enzyme activity was inhibited by 23.91%–43.48% [185]. In the same study, the chloroform extract of A. muricata leaves at 0.5 and 1.0 mg/mL also inhibited prostaglandin synthase activity by 87.46% and 82.92%, respectively, compared to the positive control indomethacin at 1 mg/mL which reduced enzyme activity by 87.46% [185].
Extracts of A. senegalensis roots were assessed for anti-inflammatory activity through in vitro inhibition of protein denaturation, hyaluronidase and xanthine oxidase. The ethyl acetate fraction was found to have the greatest activity inhibiting protein denaturation (70.6%), hyaluronidase (72.2%) and xanthine oxidase (78.7%) at a concentration of 100 µg/mL [186]. The ethanolic extract of A. muricata leaves exhibited anti-inflammatory effects in the carrageenan-induced rat paw acute edema model. Paw edema was reduced after orally administered doses of 200 and 400 mg/kg with (23.16% and 29.33%) and (29.50% and 37.33%), respectively, after 60 and 90 min of treatment [187]. Additionally, A. muricata fruit has been shown to exert an anti-inflammatory effect in a xylene-induced ear edema test [188]. Additional information regards pharmacological activities of Annona species, see (Table 7).
The lyophilized fruit extract at 50 mg/kg and 100 mg/kg inhibited the xylene-induced ear edema by 82.35% and 76.47%, respectively, compared to prednisolone, which reduced ear edema by 47.06% [188]. At intraperitoneal doses of 25, 50 and 100 mg/kg, the ethanolic extract of A. vepretorum leaves, inhibited carrageenan-induced leukocyte migration to the peritoneal cavity by 62%, 76% and 98%, compared to dexamethasone (2 mg/kg, i.p.). which reduced leukocyte migration by 89% [104]. The flavonoids, quercetin and kaempferol isolated from leaves of A. dioica exhibited potent dose- and time-dependent anti-inflammatory activity in a carrageenan-induced paw oedema model with IC50s of 8.53 and 10.57 µg/mL, respectively. The crude methanolic extract of A. dioica also reduced myeloperoxidase activity 6 h after the induction of paw oedema with a maximal inhibition of 51% at a dose of 300 mg/kg. [189]. Finally, hinesol, z-caryophyllene and beta-maaliene isolated from leaves of A. sylvatica also inhibited leukocyte migration at concentrations from 36.04 to 45.37 µg/mL in both carrageenan- and complete Freund’s adjuvant-induced mouse paw edema [33].

6.5. Antioxidant Activity

An extract of A. coriacea seeds was investigated for its antioxidant activity using free radical 2,2-diphenyl-1-picrilhidrazil (DPPH) and bleaching of β-carotene, and a moderate antioxidant effect was reported of 31.53% in the DPPH test and 51.59% for the β-carotene bleaching test [190]. The pulp of A. coriacea fruit displayed a weaker antioxidant activity compared to the seeds, with 13.49% for the DPPH test and 32.32% for the β-carotene assay [190]. Additionally, various parts of A. muricata, including bark, leaves and stem, exhibited antioxidant activity using DPPH assay and the EC50 value was recorded as 90 mg/g for bark, 290 mg/g for leaves, and 116 mg/g for the stem, compared to ascorbic acid with 157.5 mg/g [44]. Finally, an ethanolic extract of A. squamosa leaves was also reported as having antioxidant activity when evaluating DPPH, nitric oxide and superoxide radical assays. The activity was reported as 75.12%, 34.69% and 10.29%, respectively, at a concentration of 100 µg/mL [191].

6.6. Antileishmanial Activity

Many extracts and pure compounds from Annona plants have been tested against Leishmania, such as methanolic seed and leaf extracts of A. squamosa, for activity against L. amazonensis, with resulting showing IC50s of 46.54 µg/mL and 28.32 µg/mL, respectively [192]. Alkaloids and acetogenins isolated from both leaves and seeds of A. squamosa were also reported for their activity against promastigote forms of L. chagasi, with the EC50 value reported as 23.3 µg/mL for alkaloids and from 25.9–37.6 µg/mL for acetogenins [192]. Alkaloids like liriodenin isolated from the leaves of A. mucosa exhibited antileishmanial activity against promastigote forms of L. braziliensis, L. guyanensis and L. amazonensis with IC50s of 55.92 μg/mL, 0.84 μg/mL 1.43 μg/mL respectively [193]. Finally, O-methylarmepavine isolated from leaves A. squamosa displayed antileishmanial activity against both promastigote and amastigote forms of L. chagasi with EC50s of 23.3 μg/mL and 25.3 μg/mL, respectively [45].

6.7. Antiviral Activity

The antiviral activity of various Annona species was reported in several studies using either whole extract or pure compounds. For instance, 16ß,17-dihydroxy-ent-kauran-19-oic acid was isolated from the fruits of A. squamosa and showed significant activity against human immunodeficiency virus (HIV) replication using H9 lymphocyte cell assay with EC50 value of 0.8 μg/mL [194]. The ethanolic extract of A. squamosa seeds at 0.15 μg/mL, 0.25 μg/mL and 0.35 μg/mL also exhibited dose-dependent antiviral activity against the Avian influenza virus with the percentage of antiviral activity at 33.33%, 43.06% and 59.72%, respectively [195]. The leaves of A. squamosa extract were also tested against dengue virus type-2 (DENV-2) in Vero cells using Viral ToxGLoTM assay. At a concentration of 6.25 μg/mL, DENV-2 replication was reduced with IC50 73.78 μg/mL in Vero cells [196]. The methanolic extracts from the peels of A. squamosa and A. reticulata demonstrated antiviral activity against human immunodeficiency virus 1 (HIV-1) using a non-radioactive immune/colorimetric assay. Both A. squamosa and A. reticulata revealed high antiviral activity by inhibition of HIV-1 reverse transcriptase with values of 96.45% and 78.63% [197]. Moreover, A. cherimola was also evaluated for its antiviral activity against herpes simplex virus type 2 (HSV-2) using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-2H-tetrazolium bromide (MTT) assay. The leaf extract inhibited HSV-2 replication and showed antiherpetic activity with a therapeutic index 8.40 [198]. Finally, the ethanolic stem extraction of A. muricata demonstrated antiviral activity against herpes simplex virus type 1 (HSV-1) with a minimum inhibitory concentration (MIC) of 1 mg/mL [199].

7. Pharmacological Activity of Isolated Compounds from Annona Species and their Mechanism of Action

The in vitro and in vivo biological activity of compounds that have been isolated from various parts of Annona plants will be discussed. Squamins C–F were isolated from the seeds of A. globifora and tested in vitro against trophozoites of Acanthamoeba spp. strains such as A. castellanii Neff, A. polyphaga, A. griffin and A. quina (Table 8) [200]. All tested compounds exhibited antiamoeboid activity against the strains by inducing programmed cell death [200]. The same compounds were also tested for their cytotoxicity against murine macrophage cell line J774A.1 (ATCCTIB-67) and showed no cytotoxicity effect with CC50 values greater than 200 μM [200].
Rollinicin and rolliniastatin-1 isolated from the seed of A. mucosa were also reported for their larvicidal effect against Aedes aegypti and Aedes albopictus larvae [201]. Rolliniastatin-1 exhibited the best larvicidal effect against both Aedes aegypti and Aedes albopictus with LC50s of 0.43 and 0.20 μg/mL−1, respectively. Rollinicin displayed similar activity against Aedes aegypti and Aedes albopictus with LC50s of 0.78 μg/mL and 1.128 μg/mL, respectively [201]. However, the larvicidal mechanism action of these compounds was not reported. Annonacin isolated from the seed of A. muricata was evaluated for its larvicidal activity on Aedes aegypti and Aedes albopictus larvae [202]. The greater larvicidal activity was reported against Aedes aegypti with a LC50 of 2.65 μg/mL compared to Aedes albopictus with LC50 of 8.34 μg/mL. The mechanism of action was reported as being inhibition of their metabolic enzymes, particularly proteases and amylases that are important for the development of Aedes spp. larvae [202]. Twelve acetogenins isolated from the seed of A. cornifolia were tested for their antioxidant activity against DPPH [90]. These acetogenins were identified as 9-hydroxyfolianain, 4-desoxylongimicin, squamocin M, squamocin L, folianin A, folianin B, annofolin, isolongimicina B, bullatacin, asimicin, cornifolin and anotacin, and showed a strong DPPH radical scavenging with IC50s ranging from 0.99 ± 0.18 to 1.95 ± 0.34 μg/mL compared to ascorbic acid with an IC50 1.62 ± 0.35 μg/mL [90]. It has been suggested that the antiradical activity of acetogenins may be related to the α,β-unsaturated lactone ring moiety, which is also present in ascorbic acid [90]. Furthermore, the antioxidant activity of pure compounds from the bark of A. salzmanni after isolation of five alkaloids identified as liriodenine, anonaine, asimilobine, reticuline and cleistopholine [203]. The antioxidant activity was assessed through the Oxygen Radical Absorbance Capacity (ORAC) assay and asimilobine was found to be the most active alkaloid with ORAC value of 2.09 [203]. The rest of the compounds exhibited antioxidant activity with ORAC values ranging from 0.25 to 0.85 [203]. These same compounds were also examined for their antimicrobial activity against Kocuria rhizophila, Staphylococcus aureus, Staphylococcus epidermidis and Enterococcus faecalis with MIC values from 25 to 100 μg/mL [203]. In an in vitro study, the antimicrobial activity of isolated alkaloids from aerial parts of A. senegalensis was assessed in a microdilution assay [154]. These alkaloids were identified as anonaine and asimilobine, and demonstrated against Streptococcus mutans with MIC values of 0.12 and 0.25 mg/mL, respectively [154]. For trypanocidal activity, three alkaloids liriodenine, annomontine, and O-methylmoschatoline were isolated from the branch of A. foetida and tested against both epimastigote and trypomastigote forms of Trypanosoma cruzi [101]. A potent trypanocidal effect was demonstrated against epimastigote forms with IC50s ranging from 92.0 ± 18.4 to 198.0 ± 4.2 μg/mL, and from 3.8 ± 1.8 to 4.2 ± 1.9 μg/mL for trypomastigote forms [101]. Additionally, N-hydroxyannomontine isolated from the bark of A. foetida, demonstrated antileishmanial activity versus Leishmania. braziliensis and L. guyanensis with IC50 values of 252.7 ± 2.2 and 437.5 ± 2.5 μM, respectively [204].
Many compounds isolated from various Annona species have demonstrated cytotoxicity against different cancer cell lines (Table 9). Three alkaloids were isolated from leaves of A. crassiflora identified as crassiflorine, xylopine and stephalagine and tested for their activity against colon carcinoma cells (HCT-116) using MTT assay [204]. The cytotoxicity activity for the tested compounds was reported with IC50 values of 143.4 μM, 30.2 μM and 48.5 μM, respectively [204]. Muricin J–K isolated from the fruit of A. muricata exhibited anticancer activity against human prostate cancer cell lines (PC-3) through inhibition of the mitochondrial complex I in an in vitro study [205]. The anticancer activity was also reported for the alkaloid coclaurin isolated from aerial parts of A. squamosa. Cytotoxicity studies against human breast cancer cells (MCF-7), human colon cancer cells (HCT116) and human liver cancer cells (HEPG-2) reported IC50 values of 15.345 μg/mL, 8.233 μg/mL and 1.674 μg/mL, respectively [206]. Bullatacin isolated from A. cherimola demonstrated inhibition of tumor growth at a dose of 15 μg/kg in mice bearing HepS and S180 xenografts and tumor growth was reduced by 63.4% and 65.8%, respectively [207]. In the same study, annonacin administrated orally (10 mg/kg) to hybrid mice (BDF-1) models significantly reduced lung cancer by 57.9% [207]. However, the mechanism of action of these acetogenins was not described in this study. Finally, stephalagin, an alkaloid isolated from the peel of A. crassiflora fruit, was reported as pancreatic lipase inhibitor with an IC50 of 8.35 μg/mL−1 in vitro study [208].

8. Toxicity and Interactions

Generally, the safety of natural medicines can be assessed according to their effects and drug-drug interactions. An epidemiological study has reported that consumption of fruits of Annonaceae led to the prevalence of atypical parkinsonism in Guadeloupe due to the presence of acetogenins in the plant fruits [238]. According to Champy et al. 2005, the amount of annonacin per a single fruit is approximately 15 mg, and an adult who consumes a daily intake of one fruit for one year is equivalent to the amount of annonacin injected into rats, which induced the brain lesions [239]. It has been suggested that the toxicity might be related to the capacity of the tetrahydrofuran ring to chelate calcium ions [35]. Moreover, the fruit of A. squamosa has been analysed for its quantity of squamocin using HPLC-MS and reported 13.5–36.4 mg of squamocin for each fruit, and that long-term consumption of A. squamosa fruit may be a risk factor in the development of neurodegenerative disorders [240]. Additionally, the use of a dietary supplement sold in the USA containing an extract of A. muricata has been found to exhibit neurotoxic effects in human neuron cultures [241].
The interactions of Annona species with other drugs have been reported in other studies; for instance, administration of capsules of A. muricata leaves in combination with glibenclamide resulted in improved glycaemic control compared to patients who received only glibenclamide [242]. An additional study reported that a combination of aqueous custard apple leaf extract and glipizide enabled a decrease in the dose of glipizide by up to half in rats with type-2 diabetes and reduced the risk of requiring insulin therapy [243]. These outcomes suggest the potential use of certain Annona species in conjunction with antidiabetic medications to maximize the efficacy of a lower therapeutic dose.

9. Conclusions

This review provides a comprehensive summary of the botanical features, ethnomedical uses, pharmacology and phytochemistry of the main species of Annonacae family and, in particular, the Annona genera used in traditional medicine practices. Of the many members of the Annonacae family, the Annona species is heavily used in traditional medicines across the world. Among the 30 reviewed Annona species, six species A. squamosa, A. muricata, A. cherimola, A. senegalensis, A. reticulata and A. coriacea are the most widely studied for their pharmacological activities and phytochemical profiles of their bark, leaves, fruits and seeds. Various pharmacological properties have been reported, including antidiabetic, hepatoprotective, anti-inflammatory, antiprotozoal, antitumor, antioxidant, antimicrobial and anticonvulsant activity.
With regard to the phytochemistry of Annona species, the main classes of constituents identified to date are acetogenins, alkaloids, phenols and essential oils. The alkaloids are mainly present in the leaves, whereas acetogenins are present in the seeds and found in smaller quantities in the pulp and leaves of Annona species. The chemical profiles of the acetogenins present in different species have been extensively studied and their anticancer activity investigated, with low concentrations exhibiting chemotoxicity against several cancer cell lines. These preclinical results, along with the reported case studies, suggest that further clinical studies evaluating the role of acetogenins in the treatment of various types of cancers are warranted. Importantly, formulations, including the parts of the Annona species used, agricultural practices and the extraction methods vary considerably, leading to likely variations in the phytochemical and pharmacological profiles. In this respect, further characterization of standardized formulations of Annona species is required to predict likely clinical effects. Additional interesting results on the antidiabetic effects of fruits from Annona species also warrant further investigation as nutraceuticals to assist in the therapy of diabetes.

Author Contributions

Conceptualization, J.R.H.; methodology, B.S.M.A.K.; validation, J.R.H.; formal analysis, B.S.M.A.K.; investigation, B.S.M.A.K.; writing—original draft preparation, B.S.M.A.K.; writing—review and editing, J.R.H. and J.E.H.; supervision, J.R.H. and J.E.H. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

No new data were created or analyzed in this study. Data sharing is not applicable to this article.

Conflicts of Interest

The authors declare no conflict of interest.

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Molecules 27 03462 g001 550
Figure 1. Structure of selected compounds identified in Annona species.
Figure 1. Structure of selected compounds identified in Annona species.
Molecules 27 03462 g001
Table
Table 1. Uses of most commonly used Annonaceae family in traditional medicines.
Table 1. Uses of most commonly used Annonaceae family in traditional medicines.
Annonaceae SpeciesRegionLocal NameMedicinal UsesPart UsedMode of UsageReferences
Alphonsea javanica Scheff.IndonesiaAku BattuRheumatism and
edema		LeaveEthanolic extract[14]
Annickia chlorantha (Oliv).CameroonAfrican yellow wood (c)
Moambe Jaune		Treatment of sores
Antipyretic
Antiemetic
Stimulant
Tuberculosis
Treatment of jaundice
Urinary tract infection		BarkPowder
Crushed bark and drink extract
Decoction
Decoction in baths
Decoction
Decoction		[12,13]
Annickia affinis (Exell) Versteegh & Sosef
CameroonAfrican yellow woodWound healing
Antiemetic
Antipyretic		Stem barkDecoction of stem bark[13]
Anonidium floribundum PellegrCameroonEboum, Libanga
Ebom		Poison antidote
Dysentery
Antipyretic		Roots
Root/Bark
Leaves		Decoction taken orally[12,15]
Anonidium mannii (Oliv.)CameroonEbome; Npole Wapo’o, Ebome AfanAntipyreticStem barkDecoction of stem bark[13]
Boutiquea platypetala (Engl.)CameroonNot reportedTo treat fresh woundsLeavesPounded fresh leaves[12]
Cananga odorata (Lam.) Hook and ThomsonMalaysia and IndiaKenanga utan, Perfume tree, Cananga oil,
Ylang ylang		Rheumatism
Ophthalmic inflammation and wound healing		BarkBark extract eye drops for inflammation and decoction are used to
wash fresh wounds		[11]
Duguetia chrysocarpa MaasBrazilPindaíba-da-mataBowl and rheumatism inflammationLeave and twigsLeaves and
twigs extract taken to relieve inflammation		[16]
Enicosanthellum pulchrum (King) HeusdenMalaysiaDisepalumRheumatism fever, edema and asthmaLeaveDecoction can be used for asthma and rheumatism[17]
Enantia chlorantha var. soyauxii Engler and DielsAfricaAfrican yellow woodArthritis and wound healingBarkPowdered bark with
citrus lemon used as
dressing		[11]
Friesodielsia enghiana (Diels.) VerdcCameroonLonkossoAnalgesicBarkDecoction of bark is taken orally[15]
Friesodielsia gracilipes (Benth.) SteenisCameroonNtondaTreatment of sores, skin infection, ulcers, and jaundiceBark and woodDecoction of bark and wood[12]
Fissistigma oldhamii
(Hemsl.) Merr		Southern ChinaOldhamiiRheumatoid arthritisStems and rootsPowdered of stems and roots and orally ingested[11]
Greenwayodendron Suaveolens (Engl and Diels) VerdcNot reportedOtoungaAphrodisiac and
Vermifuge
Rheumatic pains,
fevers, headache,
stomach-ache		Root
Leaves and bark		Chew roots
Pulverized leaves or bark and mixed with seeds of Aframomum melegueta		[15]
Isolona hexaloba (Pierre) Engl & Diels
Democratic Republic of CongoBodzungu
MalariaStem barkDecoction of stem bark
[18]
Monodora myristica
(Gaertn.) Dunal		Ivory coastM Kpo. Abidjan districtEye diseases and
hemorrhoids, febrile pains and headache		Fruits SeedFruits and seeds consumed whole or ground to be used in soup and stews[19]
Monodora tenuifolia BenthNot reportedAfrican nutmeg
Ebom osoé Grandes feuilles		Toothache
Dysentery and fevers		Root
Bark and root		Clean the roots, boil and rinse the mouth
Prepared as a decoction and used as an enema		[12]
Polyalthia suaveolens Engl and DielsCameroonDiels; Otungui; NtoungaAnalgesic, Antiepileptic Antipyretic
Treatment of jaundice		Stem barkDecoction of stem bark[13]
Polyalthia longifolia (Sonn.) ThwaitesIndiaAshokaFeverBarkDecoction of bark[20]
Xylopia aethiopica
(Dunal) A.Rich		SudanEthiopia or Negro pepperRheumatism, colic pain, headache, and neuralgiaFruitsEthanolic fruit extract or dried fruits are used as whole[21]
Xylopia aromatic Lam. MartColumbiaMonkey pepperPulmonary
inflammation and
hemorrhoids		Roots
Leaves		Insertion of root
pieces into rectum
and leaves burnt and
smoke inhaled		[22]
Xylopia parvifolia Hook.f. and ThomsonEast and Central
Africa, India		Netawu/Athu ketiyaGastrointestinal ulcers
Analgesic		RootsDecoction Finely
dried powder		[23]
Xylopia staudtii Engl & DielsNot reportedNtom, Odjobi Bush pepper (c)Cold and headache treatmentBarkPowder[12]
Monodora tenuifolia BenthCameroonEbome ossoJoint and muscle pain, promotion of breast milk production and headacheStem barkDecoction of stem bark powder[13]
Uvaria acuminata OlivCameroonNosonaback
Typhoid and Yellow fever
Headache and epilepsy		Stem barkDecoction of stem bark[13]
Table
Table 2. Representative phytochemicals isolated from plants of Annonaceae.
Table 2. Representative phytochemicals isolated from plants of Annonaceae.
SpeciesPartCompoundsClassReferences
Anaxagoma dolichocarpa Sprague and SandwithFruitsp-Cymene
Spathulenol
Caryophyllene oxide
Guaiene		ESO[5]
Anomianthus dulcis (Dunal) J. SinclairStem(−)-Anolobine
(−)-Anonaine		ALK[24]
Artabotrys pierreanus Engl. & DielsStem barkCyperene
Caryophyllene oxide
Cyperermone
Cadalene		ESO[5]
Artabotrys hexapetalus (L.f.) BhandariAerial parts9-Oxo-asimicinone
Artapetalin-A
Artapetalin-B		ACT[25,26]
Goniothalamus giganteus Hook.f. & ThomsonBarkPyranicin
Pyragonicin
Goniotrionin		ACT[27]
Miliusa balansae Finet & GagnepLeaves and branchesOmbuine
Chrysosplenol
Pachypodol
Chrysosplenol C		FLA[28]
ALK (Alkaloids), ACT (Acetogenins), ESO (Essential oils) and FLA (Flavonoids).
Table
Table 3. Pharmacological activities of some isolated compounds from Annonaceae species.
Table 3. Pharmacological activities of some isolated compounds from Annonaceae species.
SpeciesPart UsedIsolated CompoundsPharmacological ActivityMechanism of ActionReferences
Alphonsea javanica ScheffLeaves(+)-Altholactone
(+)-Goniothalmin		Anti-inflammatoryInhibited lipopolysaccharide (LPS) induced NO production in RAW 264.7 macrophages with IC50 = 0.8 µM.[14]
Artabotrys hexapetalus (L.f.) BhandariRoots, stems,
and leaves		Artabonatine B
Squamolone		AnticancerExhibited activity against 2,2,15 and Hep G2 cell lines with IC50 11.0 and 9.1 µg/mL.
Displayed activity against Hep G2 cell lines with IC50 2.8 µg/mL.		[29]
Cananga odorata (Lam.) Hook.f. & ThomsonFruitsCleistopholineCytotoxicExhibited cytotoxicity against both Hep 2,2,15 and Hep G2 cell lines with IC50 0.54 and 0.22 µg/mL, respectively.[30]
Goniothalamus tamirensis
Pierre ex Finet & Gagnep		Stem barkDielsiquinoneCytotoxicDisplayed cytotoxic activity against U251, RPMI, MCF7, HT029 and A549. with ED50 0.37, 0.11, 0.11 1.12 and 0.11, respectively.[31]
Guatteria blepharophylla MartBarkIsocoreximineAnti-proliferative activityExhibited activity against UACC-62, NCI-H460, HT-29 and MCF-7 with TGI > 764.52 µM.[32]
Rollinia sylvatica A.St.-HilLeavesHinesol
z-Caryophyllene beta-Maaliene		Anti-inflammatoryLeukocytes migration was significantly reduced at concentrations of 36.04–45.37 µg/mL.[33]
Table
Table 4. Botanical information of some Annona species.
Table 4. Botanical information of some Annona species.
SpeciesSynonymsLocal NamesGeographic DistributionReferences
A. cherimolaA. tripetala Aiton
A. pubescens Salisb		Chirimoya
Chirimolia
Cerimoya
Cherimoyer Momona		South Africa, China
Egypt
Eritrea
Myanmar
Philippines
India
France
Italy
Mexico, Ecuador
Portugal
Peru		[6,48]
A. coriaceaA. coriacea var. amplexicaulis S.Moore,
A. coriacea var. cuneate, A. coriacea var. pygmaea Warm		Marolo
Araticum
Marolino		Brazil (Cerrado,
Caatinga)		[10,49]
A. cornifoliaA. walkeri S. MooreAraticum-mirimBrazil[50]
A. crassifloraA. macrocarpa Barb
A. rodriguesii Barb		Araticum
Pinha-docerrado
Cerrado pinecone
Marolo
Cabeça de negro		Brazil[51]
A. macroprophyllataA. diversifolia SaffIlama,
Papauce
Anona blanca		Mexico
China
India		[52,53]
A. montana MacfadA. Montana f. marcgravii
(Mart.) Porto		Mountain soursop
False graviola
jacá do Pará
Araticum grande
Shan di fan li zhi		Southern Asia,
South America Amazon Rainforest and
Atlantic Forest		[10]
A. muricataA. macrocarpa Barb
A. muricata Guanabanus
A. cearensis Morales		Brazilian pawpaw Soursop, ci guo fan li zhi, Graviola Araticum grande Mullu Raama Phala, Corossol CatucheTropical regions of Americas
Malaysia, Myanmar, Pakistan, India, Indonesia, China		[6,10]
A. reticulataA. excelsa Kunt
A. laevis Kunth
A. longifolia Moc
A. riparia Kunth		Custard apple
Bullock’s heart		Indonesia, West Indies, Bangladesh, China, India[54]
A. sclerophylla SaffSulcata Urb
A. spinescens Mart		Not reportedBrazil[10]
A. senegalensisA. senegalensis var. arenaria Sillans
A. senegalensis var. Bail. Wild
A. senegalensis var. glabrescens Oliv
$A. senegalensis var. cuneata Oliv
A. arenaria Thonn
A. chrysophylla
A. chrysophylla var. porpetac Bail
A. porpetac Bail		Wild soursop
Sour soup
Abo
Uburuochaand Gwandar		Nigeria[6]
A. squamosaA. asiatica L.
A. squamosa f. Parvifolia Kuntze
A. cinerea Dunal
Guanabanus squamosus (L.) M.Gómez		Custard apple
Sweetsop
Tiep baay
Amritaphala
Chirimoya
Fruta do conde
Squamosus
Gomez
Guanabanus		Egypt, Sudan, Pakistan, Thailand, China, India, Costa Rica,[6,10]
Table
Table 5. Traditional uses of common Annona species.
Table 5. Traditional uses of common Annona species.
SpeciesRegionLocal NameMedicinal UsesPart UsedMode of UsageReferences
A. ambotay Aubl
French GuianaNot reportedTreating feverLeaves and barkLeaves and bark crushed and rubbed on body[18]
A. cherimola Mill.Tropical America
Asia
Gabon
Cultivated in Spain and
Australia		Cherimola
Cherimoya
Chirimoya
Custard apple
Mao ye fan li zhi		Abortion
Anti-anxiety
Cough
Diarrhea
Hypercholesterolemia
Infections
Painful inflammations
Parasitic
Sedative		Aerial parts
Fruit
Leaf
Root
Seed
Stem		Not reported[87,88]
A. coriacea Mart.Brazilian (Cerrado,
Caatinga)		Araticum
Marolino
Marolo		Anthelmintic
Chronic diarrhea
Inflammation
Leishmaniasis
Malaria
Rheuma		Leaves
Root
Seeds		Not reported[89]
A. cornifolia St-HilBolivian and Brazilian
savannah		Not reportedAntiulcerative (green fruit)SeedsNot reported[90]
A. crassiflora
Mart.		Brazil (Cerrado)Araticum of the Cerrado
Araticum-mirim
Marolo
Panã		Analgesic
Antimicrobial
Antirheumatic
Carminative
Digestive
Rheumatism,
Anti-inflammatoryWound healing		Leaves
Root bark
Root wood
Seeds
Fruit		Not reported[43,91,92]
A. cuneata (Oliv.) R.E. FrCongoNot reportedAsthenia
Female sterility
Hernia
Parasitic infections
Venereal diseases		Root bark
Stem bark		Not reported[93]
A. dioica A. St.-Hil.Brazil (Cerrado, Pantanal)Ceraticum and ariticumDiarrhea
Rheumatism		Fruits
Leaves		Dried leave paste and
fresh fruit decoction		[11,33]
A. diversifolia SaffTropical forest of Central America
China		Ilama
Papausa
White anona,
Yi ye fan li zhi		Arthritic pain
Anti-spasmodic		Leaves
Seeds		Not reported[40,53]
A. foetida Mart
Brazil
Araticum-da-caatingaMalariaBark and leavesDecoction of bark and leaf[94]
A. glabra L
Caribbean
Mamain
FeverLeavesNot reported[95]
A. glauca Schumach. & ThonnWest Tropical Africa
(Senegal, Ghana, Suriname)		Dangan
Mampihege,
Mandé sunsun
Tangasu		Arachnicides
Blennorrhoea
Diuretic
Fish-poisons
Insecticides		Roots
Seeds		Not reported[96]
A. haematantha Miq
French Guiana
South American tropical rainforest		Not reportedFeverLeaves
Bark
Roots		Leaves and bark crushed rubbed on body
[18,97]
A. montana Macfad.South America
Southern Asia
The Amazon
Brazil (Mata Atlántica, Pantanal)		Mountain soursop
Shan
Di fan li zhi false
Graviola
Araticum grande
Jacá do Pará		Against snake bite Against obesityLeaf
Pulp juice
Seed
Stem
Twig		Not reported[98,99]
A. muricata LinnBrazilAraticum
Condessa
Graviola		Anthelmintic
Analgesic, neuralgia, rheumatism, arthritis pain		Fruit, juice, and crushed seeds
Fruit and leaves		Juice of fruit
Water extraction of the leaf		[66]
A. pickelii (Diels) H. RainerMexico
Caribbean Central America
Venezuela Colombia
BelizeCentral America
South America Southern Asia
Africa
Madagascar		Sincollo
Soncoyo
Bullock’s-heart Custard apple
Anona blanca
Anona
Niiu xin fan li zhi		Contraceptive
Blood dysentery
Cold
Stomachache
Fainting spinal disorders
Fever
Hysteria
Influenza
Mental depression
Skin diseases
Unhealthy ulcers
Wounds		Leaf
Leaf
Root
Stem
Seed
Aerial parts
Bark
Fruit
Leaf
Root
Seed
Stem bark		Not reported[100,101]
A. reticulata LinnWest IndiesRamphalBronchitis
Asthma
Bowel inflammation		Fruit
Seeds
Leaves		Decoction of fruit
Oral ingestion of powdered seeds
Oral ingestion of the leaf powder		[102]
A. senegalensis PersoonNigeriaUkopko (Idoma)Anti-inflammatory
Analgesic
Anthelmintic
Cancer
Diarrhea
Epilepsy
Infectious diseases
Inflammations
Sleeping sickness
Snakebite
Cardiovascular diseases
Diabetes
Febrile seizures
Gout
Mental disorders
Painful		Leaves
Seed
Stem
Bark
Root bark		Roots and bark are ground together and their decoction is used[103]
A. squamosa LinnCameroonSugar apple (English); Kedahan
(Yambetta)		Vomiting, abscesses, muscle aches, fever, and skin diseaseLeavesDecoction of leaves[13]
A. vepretorum
Mart		BrazilAraticum
Bruteira		Analgesic and
anti-inflammatory		LeavesMethanolic leaf
extract		[104]
Table
Table 6. Compounds isolated from plants of Annona genus.
Table 6. Compounds isolated from plants of Annona genus.
SpeciesPartIsolated CompoundsReferences
A. amazonica R.E. FriesStemsCassythicine
Liriodenine (ALK)		[110]
A. cherimolaRootCorytenchine, Isocoreximine (ALK)[111,112,113,114,115,116]
Fruitα-Pinene, α-Thujene, Terpinen-4-ol, Germacrene D (ESO)
Seed2,4-cis-Annocherinones, Annocherin, 2,4-trans-Isoannonacins, Annocherimolin, Annomolin,
Annomocherin, Annomontacin, Annonacin, Asimicin, Tucumanin, 2,4-trans-Annocherinones, 2,4-cis-Isoannonacins, cis-Annonacin, Annogalene, Annosenegalin, Annomolon A, Annomolon B, Cherimolacyclopeptide C (ACT)
StemAnnocherine A and B, Artabonatine B, Romucosine H, Cherianoine (ALK)
A. coriacea Mart. BulbCrolechinic acid, Crolechinic acid (methyl ester), Annonene, Annonalide (ESO)[117,118,119,120,121,122,123]
SeedGigantecin, Coriapentocin A and B, Bullacin (ACT)
LeafQuercetin-3-O-β-(6″-O-β-glucosyl)-glucoside, Quercetin-3-O-β-(6″-O-α-rhamnosyl)-galactoside, Trigonelline, Rutin, Hyperin, Hyperin, Isorhamnetin-3-O-β-glucoside, Isorhamnetin-3-O-β-galactoside,
Isoquercitrin, Isoquercitrin, Nicotiflorin, Biorobin, Keioside, Cacticin, Isorhamnetin-3-O-β-glucoside, Narcissin, Rutin (FLA)
RootCoriacin, Coriadienin, Coriaheptocin A and B, Coriacyclodienin, Coriacycloenin, 4-Deoxycoriacin, Annoheptocin A and B (ACT)
A. crassifloraLeafKaempferol-3-O-β-diglucoside, Kaempferol-3-O-β-glucoside, Quercetin-3-O-β-D-galactopyranoside, Epicatechin, Quercetin-3-O-β-L-arabinopiranoside (FLA)[124]
A. foetidaBarkAnnomontine, N-Hydroxyannomontine, Liriodenine, O-methylmoschatoline (ALK)[125,126,127]
Leaf(E)-caryophyllene, Bicyclogermacrene, α-Copaene (ESO)
BranchAtherospermidine (ALK)
A. glabraFruit16α-17-Dihydroxy-ent-kauran-19-oic acid, 16α-Hydro-ent-kauran-17-oic acid, 16β-Hydroxy-17-acetoxy-ent-kauran-19-oic acid, 16α-Hydro-19-al-ent-kauran-17-oic acid, 16β-Hydro-ent-kauran-17-oic acid, 19-nor-ent-Kauran-4α-ol-17-oic acid, Annoglabasin A and B, ent-Kaur-15-ene-17,19-diol, ent-Kaur-16-en-19-ol, ent-Kaur-16-en-19-oic acid, Methyl-16α-hydro-19-al-ent-kauran-17-oate (ALK)[128,129,130,131,132]
Fruit & stemAnnoglabasin A, B, C, D, E and F, (−)-Anonaine, (−)-Asimilobine, (−)-Kikemanine, (−)-Nornuciferine, (+)-Stepharine, Blumenol A, Liriodenine, N-p-Coumaroyltyramine, (−)-N-Formylanonaine, (+)-Nordomesticine, Annobraine, Dehydrocorydalmine, Lysicamine, N-trans-Feruloyltyramine (ALK),
6-O-Palmitoyl-β-sitosteryl-D-glucoside, β-Sitosteryl-glucoside, Stigmasteryl-D-glucoside, β-Sitosterol, Stigmasterol (STE)
SeedIsodesacetyluvaricin (ACT)
LeafBullatanocin, Glabracins A and B, Javoricin, Glacins A and B (ACT),
3-O-α-L-Arabinopyranoside, 3-O-β-D-Glucopyranoside (GLU)
(–)-Actinodaphnine, (−)-Asimilobine, (−)-Anolobine, (−)-N-Methylactinodaphnine, (−)-Roemeroline, (+)-Boldine, (+)-Norisodomesticine, (+)-Stepharine, Liriodenine, (−)-Pallidine, (+)-1S,2S-Reticuline N-oxide, (+)-Magnoflorine, (+)-Reticuline (ALK)
Quercetin, Quercetin−3-O-β-D-galactopyranoside (FLA)
Annona leptopetala (R.E.Fr.) H. RainerLeaves and branchesLaurotetanine, Nornuciferine, Corypalmine, NorannuradhapurineAnonaine (ALK)[133]
A. montanaLeafAnnolatine, Annoretine, Liriodenine, Argentinine (ALK), β-Sitosterol-β-D-glucoside, β-Sitosterol (STE), Montanacin-K, L, C, D, B and E, Annonacin-10-one, Annonacin-A, cis-Annonacin-10-one, Annonacin, cis-Annonacin (ACT)[134,135,136,137]
SeedsMontalicins G, Montalicins H Monlicins A & B, Murisolin, 4-Deoxyannomontacin, Muricatacin (ACT)
StemN-trans-Feruloyltyramine, N-p-Coumaroyltyramine, N-trans-Caffeoyltyramine (PHE)
A. muricataSeed2,4-cis-Gigantetrocinone, 2,4-trans-Isoaiinonacin, 2,4-trans-Gigantetrocinone, 2,4-trans-Isoannonacin-10-one, Gigantetrocin-A, Muricatenol, Annomontacin, Gigantetronenin, Annonacin A, Annoreticum-9-one, cis-Annomontacin, Murisolin, Muricin H, Xylomaticin, Muricin I, cis-Annonacin, cis-Goniothalamicin, cis-Annonacin-10-one, Arianacin, Javoricin, Donhexocin, Murihexol, Cohibins C, Cohibins D, Gigantetrocin B, Longifolicin, Muricin A, B, C, D, E, F and G, Annomuricatin B and C (ACT)
Stem barkMuricatin A, B and C (ACT)
FruitEpomuricenins-A and B, Epomurinins-A and B, Epomusenins-A and B, Muricin J, K and L (ACT)
Asimilobine, Nomuciferine, Annonaine (ALK)		[138,139,140,141,142,143,144,145,146]
Fruit & RootSabadelin (ACT)
LeafAnnonacin, Annomuricin C, Muricatocin C, (2,4-cis)-10R-annonacin-A-one, (2,4-trans)-10R-annonacin-A-one, Annohexocin, Annomutacin, Annopentocins A, B and C, Annomuricine, Muricapentocin, Annomuricins A and B, cis-annomuricin-D-ones, trans-annomuricin-D-ones, Muricatocins A and B, Murihexocin A and B, Muricoreacin, Murihexocin C (ACT)
(R)-4-O-methylcoclaurine, (R)-O, O-dimethylcoclaurine, (R)-Anonaine, Annonamine, (S)-Norcorydine, Anonaine,
Isolaureline, Xylopine (ALK)
Catechine, Epicatechine, Gallic acid, Chlorogenic acid, Kaempferol, Kaempferol-3-O-rutinoside, Quercetin-3-O-rutinoside,
Quercetin-3-O-glucoside, Quercetin-3-O-neohispredoside, Quercetin-3-O-robinoside, Annoionols A and B, Annoionoside (FLA)
Leaf & seedAnnonacin, Annocatacin A and B, Annonacinone, Annocatalin, cis-Corossolone, Goniothalamicin, Isoannonacin, Corossolone (ACT)
PericarpAnnonacin, Annonacin A, Annomuricin A (ACT)
RootAnnonacin, Muridienins-1, 2,3 and 4, Chatenaytrienins-1, 2 and 3, Muricadienin, Montecristin, cis-Panatellin, cis-Reticulatacin-10-one, cis-Uvariamicin IV, Coronin, cis-reticulatacin, cis-Solamin, Cohibins A and B (ACT)
A. purpurea
LeafLirinidine, 7-Formyl-dehydrothalicsimidine, 7-Hydroxy-dehydrothalicsimidine, N-Methylasimilobine, N-Methyllaurotetanine, Thalicsimidine, Norpurpureine (ALK)[105,147]
RootAnnomontine (ALK)
A. reticlataLeafDopamine, Salsolinol, Spathenelol, Muurolene, Coclaurine, Copaene, Eudesmol (ESO), Squamone, Solamin, Rolliniastatin 2, Annoreticuin-9-one, Annomonicin, Annonaretin A (ACT)[54,148,149,150,151,152]
Stem barkDopamine, Salsolinol (ESO), Reticullacinone, Rolliniastatin-2, (ACT)
RootLiriodenine, Norushinsunine, Neoannonin, Reticuline (ALK)
Spathenelol, Copaene, Eudesmol, Muurolene (ESO)
BarkReticulatacin, Liriodenine, Copaene, Coclaurine (ALK)
Patchoulane (ESO)
Molvizarin, Bullatacin (ACT)
SeedSquamocin, cis-/trans-isomurisolenin, Bullatacin, cis-/trans-Bullatacinone, Annoreticuin, Annoreticuin-9-one, Solamin, Annomonicin, Isoannonareticin, Rolliniastatin-1, 2 Squamone, Annonareticin, 2, 4-cis-Isoannonareticin, Solamin, Murisolin, Reticulacinone, Annomonicin, Sitosterol, Annoreticuin (ACT), Myrcene, Limonene, Germacrene D (ESO)
FruitTerpinen-4-ol, Germacrene D, Limonene, Pinene, Myrcene (ESO)
Root barkAnonaine, Michelalbine, Reticuline, Oxoushinsunine (ALK)
A. senegalensisLeaf(−)-Roemerine, α-Humulene, γ-Cadinene, Germacrene D, β-Caryophyllene (ESO)[153,154]
Aerial parts(−)-Anonaine, (−)-Asimilobine, (+)-Nornantenine (ALK)
(+)-Catechin (FLA)
SeedAnnogalene, Annosenegalin (ACT)
Annona sericea DunalLeafNornantenine, Nornuciferine, Isoboldine, Lysicamine, Hydroxynornuciferine (ALK[155]
A. squamosaLeaf(−) Anonaine, O-Methylarmepavine, β-Caryophyllene, β-Cedrene, (E)-Caryophyllene, Germacrene D, Bicyclogermacrene, Quercetin-3-O-glucoside (ESO)[156,157]
Bark2,4-cis-Mosinone A, 2,4-trans-Mosinone A, Annoreticum-9-one, Mosin B and C, Bullatacin, Bullatacinone, Squamone (ACT)
Pulp fruitα-Pinene, Limonene, Sabinene (ESO)
Stem11 ent-Kauranes, 10-nor-ent-Kaurane-4α,16β,17-triol, 16α,17-Dihydroxy-ent-kauran-19-oic acid, 16β,17-Dihydroxy-ent-kauran-19-al, 16β-Hydro-ent-kauran-17,19-dioic acid, 17-Hydroxy-16β-ent-kauran-19 oic acid, ent-Kaur-16-en-19-oic acid, 16α,17-Dihydroxy-ent-kauran-19-al, 16α-Hydro-19-al-ent-kauran-17-oic acid, 16β,17-Dihydroxy-ent-kauran-19-oic acid, 16β-Hydroxy-17-acetoxy-ent-kauran-19-oic acid, 4α-Hydroxy-19-nor-ent-kauran-17-oic acid (ALK)
SeedNeoannonin-B, Annosquamins A, B and C, Annosquacin-I, Annosquamin A, B and C, Annosquatin A and B, Annotemoyin-1 and 2, Cherimolin-1 and 2, Diepomuricanin A and B, Dieporeticenin, Dieposabadelin, Squadiolin A, B and C, D, E, F, G, H, I, J, K, L, M and N, Squamostanin A, B, C, D, E and F, Cyclosquamosin A, B, C, D, E, F, G, H and I, Squamin A and B (ACT)
A. vepretorumLeafSpathulenol, Bicyclogermacrene, α-Phellandrene (ESO)[116,158]
ALK (Alkaloids), ACT (Acetogenins), ESO (Essential oils). STE (Sterols), FLA (Flavonoids), PHE (Phenolics).
Table
Table 7. Pharmacological activities of Annona species.
Table 7. Pharmacological activities of Annona species.
SpeciesBiogeographical DistributionUsed PartTraditional UsePharmacological ActivitiesExtract/Compound EvaluatedReferences
A. ambotaySouth American tropical rainforestTrunkwoodAntipyreticAntimicrobialAlkaloids
[159]
A. bullataEndemic of CubaBarkNot reportedAntitumoral32-Hydroxybullatacinone[160]
A. cherimolaTropical America,
Asia, Spain
Australia, Gabon		Aerial partsFruit
Leaf
Root
Seed
Stem		Abortion
Anti-anxiety
Cough
Diarrhea
Hypercholesterolemia
Infections
Painful inflammations
Parasitic
Sedative		Antidepressant
Antifungal
Antiprotozoal
Antitumoral
Antihypercholesterolemic
Antiulcerative
Antiviral
Insecticidal
Vasodilator		Acetogenins: Molvizarin, Squamocin, Cherimolin−1, Motrilin,
Aherradurin, Tucumanin Annomocherin, Annonacin, Annomontacin,
Alkaloids: Roemerine, Anonaine, Dehydroroemerine		[37,161]
A. coriaceaBrazilia (Cerrado and Caatinga)Leaf
Root
Seed		Leishmaniasis
Malaria
Rheuma
Anthelmintic
Chronic diarrhea
Inflammation		Antifungal
Anti-inflammatory
Antitumoral
Insecticidal
Leishmanicidal
Trypanocidal		Acetogenins: Annoheptocins A-B, coriacin, 4-Deoxycoriacin, Coriaheptocins A-B,
Coriadienin, Gigantecin		[10]
A. muricataAmerica, Asia, AfricaBark
Leaf
Fruit
Root
Root bark
Seed
Stem bark		Anthelmintic
Antiscorbutic
Asthma
Cancer
Cough
Cystitis
Diabetes
Diuretic		Anti-arthritic
Antidepressant,
Antidiabetic
Anti-inflammatory
Antimicrobial
Antimalarial
Antiviral
Hepatoprotective		Acetogenins:
Solamin, Muricin H, Muricin I, cis-Annonacin, Muricins A-G, Muricoreacin, Muricapentocin, Gigantetrocin A, Annopentocins A-C		[162,163]
A. salzmanniiBrazilBark
Leaf		Not reportedAntioxidant
Antimicrobial		Alkaloids:
Reticuline, Anonaine, Laurelliptine, Isoboldine		[101]
A. senegalensisMadagascar, Comoros, Cape
Verde, Tropical Africa		Leaves
Seed
Stem
Bark
Root bark		Anti-inflammatory and
Analgesic
Anthelmintic
Cancer
Diarrhea
Epilepsy
Infectious diseases
Inflammations
Sleeping sickness
Snakebite		Anticonvulsant
Antidiabetic
Antidiarrheal
anthelmintic
Anti-inflammatory
Antimalarial
Antimicrobial
Antioxidant
Insecticidal
Hepatoprotective
Antitumoral
Aqueous extract.
Ethanolic extract Terpenoids, coumarins, flavonoids, tannins, alkaloids, quinones.
Methanolic extract containing Annosenegalin, Annogalene.		[10,164]
A. squamosaTropical America, Asia AustraliaSeed
Stem
Bark
Root bark		Analgesic
Anthelmintic
Antirheumatic
Cancer
Digestive
Headache
Anti-inflammatory
Antimicrobial
Carminative		Antibacterial
Antidiabetic
Antilipidemic
Antioxidant
Antimalarial
Antigenotoxicity
Antileishmanial		Acetogenins:
Squadiolins A and B, Squafosacin B, Bullatacinona, Squamona, Tetrahydrosquamone
Monoterpenes:
Limonene, β-Cubebene,
β-Caryophyllene, Spathulenol, Caryophyllene oxide		[10]
Table
Table 8. Antiamoebic activity of squamins C-F versus Acanthamoeba spp. Strains.
Table 8. Antiamoebic activity of squamins C-F versus Acanthamoeba spp. Strains.
CompoundsA. castellanii Neff IC50 (μM)A. polyphaga IC50 (μM)A. griffin IC50 (μM)A. quina IC50 (μM)
Squamin C20.77 ± 3.4871.78 ± 0.4138.81 ± 7.3424.28 ± 0.64
Squamin D18.38 ± 1.1471.57 ± 0.1439.53 ± 5.9026.52 ± 0.87
Squamin E21.00 ± 0.8662.19 ± 15.5244.75 ± 2.0625.82 ± 0.99
Squamin F18.02 ± 3.2864.08 ± 12.4250.49 ± 6.9230.32 ± 0.27
Table
Table 9. Anticancer activity of isolated compounds from Annona species and their mode of action.
Table 9. Anticancer activity of isolated compounds from Annona species and their mode of action.
Annona SpeciesPlant PartIsolated ComponentsCell Line or Animal ModelMechanism of ActionReferences
A. cherimolaSeedsAnnomolin and AnnocherimolinProstate tumor cell line (PC-3), breast (MCF- 7) and colon (HT-29) cancer cell linesExhibited potent cytotoxicity[209]
LeavesAsimilobineAcute myeloid leukemia cell lineUpregulation of Bax, downregulation of Bcl2, and
cleavage of PARP		[210]
A. crassiflorCrude extractCatechinCervical cancer cellApoptosis via intrinsic pathway[211]
A. glabraFruitsAnnoglabasin HLung adenocarcinoma cell line (LU-1), human breast carcinoma (MCF-7), human melanoma (SK-Mel2)Exhibited significant cytotoxic activity[212]
AnnoglabayinHuman liver cancer cell line (Hep G2)Apoptosis via mitochondrial
pathway		[132]
Cunabic acid and ent-kauran-19-al-17-oic acidLiver cancer (HLC) cell line SMMC-7721Apoptosis via down-regulation of BCL-2 gene and upregulation of bax gene[213]
LeavesAsinicinHuman monocytic leukemia cells (CRL-12253)Mitochondria mediated anticancer and antiproliferative effects[214]
Annoglacin A and BHuman breast carcinoma (MCF-7) and Pancreatic carcinoma (PACA-2) cell linesSuppressed proliferation[215]
Icariside D2Human leukemia cell line (HL-60)Induced apoptosis and decreased phosphorylation of AKT in cells[216]
A. muricataLeavesAnnomuricinBreast cancer cellSuppressed breast cancer proliferation and induced apoptosis[217]
Muricoreacin, MurihexocinColon cancer cell (HT-29, HCT-116)Up-regulation of Bax, downregulation
of Bcl-2 proteins and activated initiator and executioner caspases		[218]
Annomuricine, MuricapentocinPancreatic carcinoma (PACA-2) and colon adenocarcinoma (HT-29) cellExhibited repressive effect[219]
Muricatocins A and BLung tumor cell line (A-549)Enhanced cytotoxic activity[146]
FruitsMuricin M and Muricin NProstate cancer (PC-3) cellsExhibited cytotoxicity[220]
A. purpureaRootsAnnopurpurici-ns A–DHeLa and HepG2 cellsMitochondrial membrane
depolarization and apoptosis		[221]
A. reticulataFruitsCatechinBreast cancer cell line (MCF-7)Inhibition via apoptosis[222]
SeedsAnnonacinT24 bladder cancer cellsBax expression was induced, caspase-3 activity enhanced and caused apoptosis[172]
BullatacinLeukemia cell line (K562) and breast cancer cell line (MCF-7)Cell death via apoptosis[223]
LeavesAnnomonicinColon cancer (HCT15), human lung cancer (Hop65) and human hepatoma (HEPG2) cell linesExhibited cytotoxic effect[224]
RolliniastatinBreast cancer cell (T-47D)Caspases dependent apoptosis[225]
A. senegalensisLeaves(−) RoemerineBreast cancer MDA-MB-231 cellsExhibited dose-dependent
cytotoxicity via targeting the
ribosomal protein eL42 and
arresting the crosslinking reaction with tRNAox		[226]
BarkKaurenoic acidPancreatic tumor (PANC-1) cell lines and Henrietta Lacks’ cervical cancer cell line (HeLa)Exhibited significant cytotoxic activity[227]
StemEnt-kaurenoidsBreast cancer (MCF-7) cells, prostate cancer (PC-3) cellsExhibited significant cytotoxic activity[228]
A. squamosaLeavesAnnoreticuinBreast cancer cell (MCF-7)Induced Apoptosis[229]
SeedsDieporeticenin B, Squamocin,
Annosquatin III		Nasopharyngeal cancer (KB) cells, breast cancer (MCF-7) cellsExerted inhibitory activity[230]
AsimilobineHuman colon cancer cell (WiDr)Increased expression of caspase-3[231]
Annosquatin A, BHuman leukemia cell line (K-562), human colon carcinoma (COLO-205)Reduced intracellular glutathione levels and
regulation of Bcl-2 and PS externalization		[232]
Annosquacins A-D, Annosquatin A, BHuman breast cancer cell line (MCF-7), human lung adenocarcinoma cell line (A-549)Exhibited cytotoxic activity[233]
(−)-AnonaineH22 solid tumor cellInhibition of IL-6/Jak/Stat3
pathway		[234]
BarkCoclaurineDMBA painted hamstersEnhanced lipid peroxidation[235]
Fruits(−)-Ent-kaur-16-en-19 oic acid, 16α,17 dihydroxy-ent-kauran-19-oic acidDalton’s lymphoma cells, HeLa cellsExhibited cytotoxic activity[236]
A. sylvatica A.St.-HilLeavesQuercetin
Kaempferol		Anti-inflammatoryLeukocytes migration was significantly reduced at IC50 8.53 and 10.57 µg/mL, respectively.[189]
A. vepretorum Mart.LeavesBicyclogermacreneAntimicrobial
Against Candida tropicalis with a MIC value of 100 µg ·mL−1.[237]
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Al Kazman, B.S.M.; Harnett, J.E.; Hanrahan, J.R. Traditional Uses, Phytochemistry and Pharmacological Activities of Annonacae. Molecules 2022, 27, 3462. https://doi.org/10.3390/molecules27113462

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Al Kazman BSM, Harnett JE, Hanrahan JR. Traditional Uses, Phytochemistry and Pharmacological Activities of Annonacae. Molecules. 2022; 27(11):3462. https://doi.org/10.3390/molecules27113462

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Al Kazman, Bassam S. M., Joanna E. Harnett, and Jane R. Hanrahan. 2022. "Traditional Uses, Phytochemistry and Pharmacological Activities of Annonacae" Molecules 27, no. 11: 3462. https://doi.org/10.3390/molecules27113462

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