The potential of anti-malarial compounds derived from African medicinal plants, part I: a pharmacological evaluation of alkaloids and terpenoids.

Traditional medicine caters for about 80% of the health care needs of many rural populations around the world, especially in developing countries. In addition, plant-derived compounds have played key roles in drug discovery. Malaria is currently a public health concern in many countries in the world due to factors such as chemotherapy faced by resistance, poor hygienic conditions, poorly managed vector control programmes and no approved vaccines. In this review, an attempt has been made to assess the value of African medicinal plants for drug discovery by discussing the anti-malarial virtue of the derived phytochemicals that have been tested by in vitro and in vivo assays. This survey was focused on pure compounds derived from African flora which have exhibited anti-malarial properties with activities ranging from "very active" to "weakly active". However, only the compounds which showed anti-malarial activities from "very active" to "moderately active" are discussed in this review. The activity of 278 compounds, mainly alkaloids, terpenoids, flavonoids, coumarines, phenolics, polyacetylenes, xanthones, quinones, steroids, and lignans have been discussed. The first part of this review series covers the activity of 171 compounds belonging to the alkaloid and terpenoid classes. Data available in the literature indicated that African flora hold an enormous potential for the development of phytomedicines for malaria.

Background

Malaria is an infectious disease with ravaging effects in the world. The World Health Organization (WHO) has published statistics which reveal that half the world’s population is at risk of malaria and that one to two million annual deaths can be attributed to malaria alone [1,2]. Four protozoan species of the genus Plasmodium (Plasmodium falciparum, Plasmodium malariae, Plasmodium ovale, and Plasmodium vivax) are responsible for this infection, although the majority of fatal cases are caused by P. falciparum[3]. Malaria has been treated with quinine, chloroquine, mefloquine, and artemisinin (Figure 1), among other drugs. However, the protozoans have developed resistance against many of the current treatment regimens [4]. In the quest to identify new anti-malarial chemotherapeutic agents, many research groups have resorted to plant sources [3,5,6]. This is because of the use of many of these plant materials in the treatment of malaria and fevers in African traditional medicine (ATM) [7]. There has been a general call for the use of natural products as drugs for malaria or as sources of inspiration for the development of novel anti-malarials [8-11] in order to possibly avoid problems related to drug resistance [12].

Figure 1

Some plant-derived anti-malarial drugs.

The African continent is very rich in floral biodiversity and its plant materials are endowed with natural products (NPs) with intriguing chemical structures and promising biological activities. Therefore, the next generation anti-malarials or the scaffolds necessary for their synthesis may be found in plants currently used in ATM [13,14]. It should also be mentioned that malaria mostly affects the populations of Africa, Asia and Latin Africa. Asia has offered artemisinin to humanity while Latin America has offered quinine. Many researchers are therefore of the opinion that it is Africa’s turn to offer a new anti-malarial drug to humanity. Why do we not yet find a (real) anti-malarial drug from Africa? This brings us to the need to have an overview of the anti-malarial/anti-plasmodial activity of compounds from bitter African plants (alkaloids and terpenoids). Several research groups in Africa have been involved in the bioassay-guided fractionation of plant extracts, leading to the isolation, purification and characterization of a significant number of NPs, some with remarkable anti-malarial activities. The literature survey reported in this work has led to the identification of several vast screening efforts of crude extracts derived from plants used in ATM, harvested from the following countries, just to mention a few: the Democratic Republic of Congo [15,16], Nigeria [17-19], Mozambique, Cape Verde, Guinea-Bissau, São Tomé and Príncipe and Angola [20], Mali and São Tomé and Príncipe [21], Madagascar [22-24], Congo [25], Benin [26], Burkina Faso [27], South Africa [28], Ivory Coast [29], West African countries [30], Tanzania [31], Kenya [32], and East African countries [33,34].

The potential of plant-derived NPs for anti-malarial drug discovery has been examined in a number of review papers [3,35-41]. Other review articles have concentrated on anti-malarials from specific countries/regions in Africa [19,20,42-46]. However, there has been no review offering coverage of promising anti-malarials from the entire African continent in the last ten years [13]. In this review series, the potential of plant-derived NPs that could be developed into drugs have been discussed, by giving an overview of the most pertinent in vitro and in vivo screening results reported in the literature.

Promising anti-malarial alkaloids and terpenoids derived from African flora

Alkaloids

Previous studies have shown that plant-derived alkaloids have a great potential for anti-malarial drug development [33-36,39,40,42-44]. Tables 1 and 2 summarize the most promising alkaloids derived from African medicinal plants with significant anti-malarial properties. The chemical structures are shown in Figures 2, 3, 4, 5, 6 and 7, according to the alkaloid subclasses.

Table 1

Summary of anti-malarial alkaloids derived from the African flora – indoles, naphthoisoquinolines and furoquinolines

Compound subclass	Isolated metabolites	Plant species (Family)	Part of plant studied	Place of harvest (locality, country)	Author, reference
Indole alkaloids	1, 2, 3, 4, 5, 6 and 7	Monodora angolensis (Annonaceae)	Stem and root bark	Kiwanda, Tanzania	Nkunya et al.[47]
	8 and 9	Isolona cauliflora (Annonaceae)	Stem and root bark, and flower stalks	Namikwe Island, Tanzania	Nkunya et al.[47]
	10	Strychnos usambarensis (Loganiaceae)	Leaves	Akagera National Park, Rwanda	Cao et al.[48]
	11 and 12	Penianthus longifolius (Menispermaceae)	Stem bark	Cameroon	Bidla et al.[49]
	13	Glossocalyx brevipes (Siparunaceae)	Leaves	Kumba, Cameroon	Mbah et al. [50]
	14	Fagara zanthoxyloides (Rutaceae)	Roots	Nigeria	Odebiyi et al.[51]
	15	Picralima nitida (Apocynaceae)	Fruits	Nnewi, Nigeria	Okunji et al.[52]
	16	Strychnos usambarensis (Loganiaceae)	Roots	Akagera National Park, Rwanda	Frédérich et al.[55]
	17, 18 and 19	Strychnos usambarensis (Loganiaceae)	Leaves	Akagera National Park, Rwanda	Frédérich et al.[56]
Naphthoisoquinolines	20, 21, 22, 23 and 24	Ancistrocladus robertsoniorum (Acistrocladaceae)	Stems and leaves	Buda Mafisini Forest, Kenya	Bringmann et al.[57]
	25, 26, 27, 28 and 29	Ancistrocladus tanzaniensis (Acistrocladaceae)	Leaves	Uzungwa Mountains, Tanzania	Bringmann et al.[58]
	30	Triphyophyllum peltatum (Dioncophyllaceae)	Roots	Parc de Taï, West Ivory Coast	Bringmann et al.[59]
	31	Triphyophyllum peltatum (Dioncophyllaceae)	Root bark	West Ivory Coast	Bringmann et al.[60]
	32	Mixture of Triphyophyllum peltatum, a Dioncophyllum thollonii b and Habropetalum daweic (Dioncophyllaceae)	Root and bark a	West Ivory Coast a	Bringmann et al.[61]
			Twigs b, c	Gabon b
				Sierra Leone c
	33, 34, 35 and 36	Triphyophyllum peltatum (Dioncophyllaceae)	Leaves and twigs	Mt. Nabemba, Congo Republic a and	Bringmann et al.[62-65] a
				West Ivory Coast b	François et al. [66] b
Furoquinolines	37 and 38	Vepris uguenensis (Rutaceae)	Roots	Baringo District, Kenya	Cheplogoi et al.[68]
	39 and 40	Toddalia asiatica (Rutaceae)	Roots	Ol Ari Nyiro Ranch, Kenya	Gakunju et al.[69]
	41	Teclea gerrardii (Rutaceae)	Root bark	Durban, South Africa	Waffo et al.[70]

a,b and ccorrespond to the respective references.

Table 2

Summary of anti-malarial alkaloids derived from the African flora – acridones, amides and cryptolepines

Compound subclass	Isolated metabolites	Plant species (Family)	Part of plant studied	Place of harvest (locality, country)	Author, reference
Acridones	42 a, b, c and 43 b	Teclea gerrardii a	Root bark a	Durban, South Africa a	Waffo et al.[70] a
		Zanthoxylum leprieurii b	Fruits b	Yaoundé, Cameroon b	Tchinda et al.[71] b
		Teclea trichocarpa c	Leaves c
		(Rutaceae)
	44, 45, 46, 47, 48 and 49	Teclea trichocarpa (Rutaceae)	Leaves	Nairobi, Kenya	Wurithi et al.[72]
	50	Vepris uguenensis (Rutaceae)	Roots	Baringo District, Kenya	Cheplogoi et al.[68], Kiplimo [73]
Amides	51	Hugonia castaneifolia (Linaceae)	Root bark	Pugu forest, Tanzania	Baraza et al.[74]
	52	Beilschmiedia zenkeri (Lauraceae)	Bark	Yaoundé, Cameroon	Lenta et al.[75]
Cryptolepines	53	Sida acuta (Malvaceae)	Aerial parts	Ivory Coast	Banzounzi et al.[76]
	53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, and 63′	Cryptolepis sanguinolenta (Periplocaceae)	Stems a	Mampong-Akwapim, Ghana, Guinea Bissau and other regions	Barku et al.[77] a
			Root bark b		Cimanga et al. [78,79] a, b
			Roots c		Ablordeppey et al. [80] a
					Paulo et al. [81] c
					Hadden et al. [82]

a,b and ccorrespond to the respective references.

Figure 2

Anti-malarial indole alkaloids derived from the African flora.

Figure 3

Naphthoisoquinolines with anti-plasmodial activity, derived from plants used in African traditional medicine.

Figure 4

Promising anti-malarial furoquinolines from African medicinal plants.

Figure 5

Promising anti-malarial acridones from African medicinal plants.

Figure 6

Some anti-malarial amides from African medicinal plants.

Figure 7

Anti-malarial cryptolepines from African medicinal plants.

Indole alkaloids

Several indole alkaloids, derived from African medicinal plants, have shown interesting in vitro anti-malarial activities, among them compounds 1, 2 and 10 to 19. Nkunya et al. have isolated prenylated indole alkaloids from Monodora and Isolona species (Annonaceae) growing in Tanzania [47]. According to their report, 6-(3-methyl-but-2-enyl)-1,3-dihydro-indol-2-one (1), 3-[6-(3-methyl-but-2-enyl)-1H-indolyl]-6-(3- methyl-but-2-enyl)-1H-indole or annonidine F (2), 1H-indole-5-carbaldehyde (3), 6-(3-methyl-2-butenyl)-1H-indole (4), 6-(3-methylbuta-1,3-dienyl)-1H-indole (5), 6-(4-oxo-but-2-enyl)-1H-indole (6) and 3-geranylindole (7) were isolated from Monodora angolensis while 3-(1,1-dimethyl-but-2-enyl)-5-(3-methyl-but-2-enyl)-1H-indole or caulidine A (8), 4-[3-(1,1-dimethyl-but-2-enyl)-1H-indol-5-yl]-but-3-en-2-one or caulidine B (9), 5-(3-methyl-2-butenyl)-1H-indole and 5-(3-methylbuta-1,3-dienyl)-1H-indole were obtained from Isolona cauliflora. The compounds with the most promising, measured, anti-malarial activities were 1 and 2, both having in vitro anti-malarial activities against the multidrug resistant strain K1 of P. falciparum (IC50 = 21 μg mL-1 for each compound). Moreover, their measured cytotoxicities, in the brine shrimp test were IC50 = 4.08 and 5.28 μg mL-1, respectively.

The compound 17-O-acetyl,10-hydroxycorynantheol (10) was isolated from Strychnos usambarensis (harvested in Rwanda), along with isostrychnopentamine (18), the main alkaloid responsible for the anti-plasmodial activity of the plant, by Cao et al. [48]. The study showed that compound 10 is one of the most promising, monomeric indole alkaloids known to date, showing an in vitro activity against P. falciparum close to 5 μM and a high selectivity.

Indoles with interesting anti-malarial properties have also been derived from two plant species growing in Cameroon: Penianthus longifolius and Glossocalyx brevipes[49,50]. Bilda et al. have isolated palmitine (11) and jatrorrhizine (12) from the stem bark of Penianthus longifolius. Compounds 11 and 12 showed promising in vitro activities on various strains of P. falciparum with IC50 values ranging from 0.28 to 0.35 μg mL-1[49], meanwhile Mbah et al. isolated liriodenine (13) from Glossocalyx brevipes (Siparunaceae), which exhibited anti-malarial activity against the D-6 drug sensitive strain from Sierra Leone and the NF54 strain with IC50 values of 2.37 μM and 1.32 μM, respectively [50].

From the plant species growing in Nigeria, fagaronine (14) and alstonine (15) were derived from Fagara zanthoxyloides (Rutaceae) and Picralima nitida (Apocynaceae) respectively [51,52]. While fagaronine (14) inhibited P. falciparum growth in vitro at IC50 = 0.018 μg mL-1, alstonine (15) has been noted to be the most active indole alkaloid derived from Picralima nitida[53]. It is noteworthy that indole and dihydroindole alkaloids are common in Picralima nitida growing in Nigeria, the major constituents including akuammiline, akuammidine, akuammine, akuammigine, akuammicine, picraline, and alstonine [54]. Some of the aforementioned alkaloids have exhibited in vitro anti-malarial activity against P. falciparum comparable to chloroquine and quinine [52], the IC50 values varying from 0.01 to 0.9 μg mL-1[53].

Frédérich et al. examined the roots and leaves of Strychnos usambarensis (Loganiaceae) growing in Rwanda [55,56]. Four potent anti-malarial bisindole alkaloids; 10′-hydroxyusambarensine (16), strychnopentamine (17), isostrychnopentamine (18) and chrysopentamine (19) have been isolated. Compounds 17 to 19 showed interesting anti-malarial activities against chloroquine-sensitive line (FCA 20) from Ghana (IC50 values from 117 to 579 nM), against moderately chloroquine-resistant line (FCB1-R) from Colombia (IC50 values from 107 to 550 nM) and against chloroquine-resistant line (W2) from Indochina (Laos) (IC50 values from 145 to 507 nM). The results of anti-plasmodial activities were comparable to those of the anti-malarial drugs quinine and chloroquine, which is indicative of the absence of cross-resistance with chloroquine. Meanwhile, compound 16 had moderate in vitro activity against two strains of P. falciparum.

Naphthoisoquinolines

These compounds are characterized by the C5/C8’ linkage between the naphthalene and the isoquinoline portions of these alkaloids (Figure 3). They have been isolated from Ancistrocladus (Acistrocladaceae), Triphyophyllum, Dioncophyllum, and Habropetalum (Dioncophyllaceae) species. The chemical significance of naphthylisoquinoline alkaloids rests on their unique structure and their biological activities [45,46].

The anti-malarial properties of some of these species have been investigated by Bringmann et al.[57-66]. Regarding the Acistrocladaceae-derived naphthoisoquinolines, compounds 20 to 24, derived from the stems and leaves of Ancistrocladus robertsoniorum growing in Kenya, exhibited moderate anti-malarial activities (IC50 values from 2.0 to 15.9 μM) against the K-1 and NF54 strains of P. falciparum[57], meanwhile the Tanzanian species, Ancistrocladus tanzaniensis, gave compounds 25 to 29 with IC50 values ranging from 0.1 to 3.6 μg mL-1 against the K1 strain and between 1.9 and 34.1 μg mL-1 against the 3D7 strain [58]. Habropetaline A (30) and 5′-O-demethyl-dioncohylline A (31) were derived from the roots of Triphyophyllum peltatum, harvested in the Parc de Taï, in west Ivory Coast [59,60]. Both naphthoisoquinolines exhibited interesting anti-plasmodial activities against drug-sensitive and drug-resistant strains of the parasite. Habropetaline A (30) showed very good effect against P. falciparum, without cytotoxicity, with respective IC50 values of 5.0 and 2.3 ng mL-1 for the strains K1 (chloroquine and pyrimethamine resistant) and NF54 (sensitive to all known drugs). Compound 30 was almost as active as artemisinin (K1: 1.2 ng mL-1, NF54: 1.2 ng mL-1) and is known to be one of the most potent NPs used against P. falciparum[59]. On the other hand, 5′-O-demethyl-dioncophylline A (31) showed improved in vitro anti-malarial activity (IC50 = 0.340 μg mL-1) against the erythrocytic forms of P. falciparum[60]. Jozipeltine A (32), the dimer of the highly hydroxylated naphthylisoquinoline alkaloid dioncopeltine A (36), was derived from a mixture of root and bark of Triphyophyllum peltatum and Dioncophyllum thollonii, along with twigs of Habropetalum dawei (Dioncophyllaceae), harvested from different regions on the continent [61]. Although this compound showed some in vitro anti-plasmodial activity against P. falciparum (K1 = 875 ng mL-1, NF54 = 2530 ng mL-1), it is significantly less active than its monomeric precursor, dioncopeltine A (36) (K1 = 4.8 ng mL-1, NF54 = 3.3 ng mL-1). This observation could lead to the conclusion that only naphthoisoquinolines containing one phenolic OH group each (such as dioncophylline A (36) and ancistrocladine (28)), could easily undergo the required dimerization reaction, implying that doubling of the number of free OH groups would increase the anti-plasmodial activity [61]. Dioncophyllines A (33), B (34) and C (35) and dioncopeltine A (36) were also active in the in vivo rodent model [66], with dioncophylline C (35) exhibiting a 50% effective dosage (ED50) of 10.71 mg kg-1 day-1. Four daily treatments with 50 mg kg-1 day-1 were needed to achieve radical cure, one oral dose being sufficient to kill 99.6% of the parasites. Intravenous application of dioncophylline C was shown to be even more effective, with an ED50 of 1.90 mg kg-1 day-1 and no noticeable toxic effects. Compound 35 also suppressed more established Plasmodium berghei infections when orally applied at day 3 after infection. It should be mentioned that rodent malaria is a well-known animal model for testing new compounds and plant extracts. However, trial in human being is decisive to identify a “hit” as “a real hit”; and this is a good way to assess toxicity and safety. Both dioncopeltine A (36) and dioncophylline C (35) were active against the chloroquine-resistant P. berghei Anka CRS parasites. The naphthoisoquinolines are also known to exhibit other biological activities, e.g. dioncophylline A (33), is the main cytotoxin in Ancistrocladus letestui[67]. The above observations all point to the fact that naphthylisoquinoline alkaloids are promising lead compounds for the development of anti-malarial drugs.

Furoquinolines

This subclass of alkaloids is easily identified with the Vepris, Toddalia and Teclea genera of the Rutaceae family. From the roots of Vepris uguenensis, Cheplogoi et al. isolated flindersiamine (37) and maculosidine (38) [68]. Although compound 37 lacked anti-malarial efficacy against all tested strains, maculosidine (38) exhibited moderate anti-malarial activity against two strains of P. falciparum, with IC50 values of 29.2 and 40.4 μg mL-1 against the chloroquine-susceptible 3D7 and the chloroquine-resistant FCM29 strains respectively. Nitidine (39) has been derived from the roots of Toddalia asiatica harvested in Kenya and modified to yield the reduced derivative 5,6-dihydronitidine (40) [69]. Even though nitidine is mostly known for its potential anticancer properties, the investigations of Gakunju et al. showed the alkaloidal extract of the roots of this plant to have high activity against the chloroquine-resistant K39 strain of P. falciparum, with an IC50 value of 0.04 μg mL-1. Further phytochemical analysis on the extract by these authors yielded nitidine as a major compound. In vitro screening against the K39 strain of P. falciparum revealed that nitidine exhibited high anti-plasmodial activity, with an IC50 of 0.045 μg mL-1, in addition to its known cytotoxic property. In order to remove toxicity, synthetic modification led to 5,6-dihydronitidine (40), with a much weaker anti-malarial activity (IC50 of 1.03 μg mL-1, 23 times weaker than nitidine). Evoxine (41), derived from Teclea gerrardii (Rutaceae) harvested from Durban, South Africa, displayed moderate anti-plasmodial activity against the CQS D10 strain of P. falciparum, with IC50 value 24.5 μM [70].

Acridones

The most promising anti-plasmodial acridones derived from the African flora include arborinine (42), xanthoxoline (43), normelicopicine (44), skimmianine (45), dictamnine (46), melicopicine (47), tecleanthine (48) and 6-methoxytecleanthine (49), shown in Figure 5, isolated from Teclea and Zanthoxylum species. Compound 42 was derived from Teclea gerrardii, Zanthoxylum leprieurii and Teclea trichocarpa (Rutaceae) and has shown anti-plasmodial activity against 3D7 strains (IC50 = 4.5 μg mL-1), almost equally active as compound 43 (IC50 = 4.6 μg mL-1) [70,71]. Compounds 44 to 49 showed moderate activity against the chloroquine-sensitive HB3 and the chloroquine-resistant K-1 strains of P. falciparum, with respective anti-plasmodial IC50 values of 14.7, 9.3, 59.0, 53.0, and 56.9 μM [72]. Compound 50 (maculosidine), derived from Vepris uguenensis (Rutaceae), exhibited anti-malarial activities at 13.8 and 40.4 μg mL-1 against the 3D7 (chloroquine susceptible, CQS) and FCM29 (chloroquine resistant, CQR) strains of P. falciparum, respectively [73].

Amides

N-isobutyldeca-2,4-dienamide (51) and pipyahyine (52), Figure 6, are two amides respectively derived from Hugonia castaneifolia (Linaceae) and Beilschmiedia zenkeri (Lauraceae) [74,75]. It has been shown that compound 51 had moderate anti-plasmodial activity against the K-1 strain of P. falciparum, with an IC50 value of 5.4 μg mL-1[74], while compound 52 showed activity against the chloroquine-resistant W2 strain of P. falciparum, with an IC50 value of 3.7 μM [75].

Cryptolepines

Cryptolepine (53), derived from Sida acuta (Malvaceae), growing in Ivory Coast, has shown very good anti-malarial activity [76]. According to Banzouzi et al., the IC50 values obtained for the extracts from this plant ranged from 3.9 to 5.4 μg mL-1. Purification of this active fraction led to the identification of cryptolepine (53) as the active anti-plasmodial constituent of the plant. Compound 53 exhibited IC50 values against the chloroquine-sensitive strain (respectively 0.13 and 0.17 μg mL-1 after 24 and 72 hours) from Nigeria and the Fcm29 chloroquine-resistant strain (respectively 0.17 and 0.17 μg mL-1 after 24 and 72 hours) from Cameroon. Cryptolepine derivatives (54 to 63), Figure 7, isolated from the stems, roots and root bark of Cryptolepis sanguinolenta (Periplocaceae) growing in diverse regions in Africa, have also exhibited potent anti-malarial properties [77-80].

Cimanga et al. assessed three different extracts and four alkaloids from the root bark of Cryptolepis sanguinolenta in vitro against P. falciparum D-6 (chloroquine-sensitive strain), K-1, and W-2 (chloroquine-resistant strains). Cryptolepine (53) and its hydrochloride salt, 11-hydroxycryptolepine (56), and neocryptolepine (61) showed strong anti-plasmodial activity against P. falciparum chloroquine-resistant strains. Quindoline (54) was less active. The highest activity was obtained with cryptolepine (53). In vivo tests on infected mice showed that cryptolepine exhibited a significant chemosuppressive effect against Plasmodium yoelii and Plasmodium berghei, while cryptolepine (53) had the same effect against P. yoelii only. Compounds 54 and 56 did not show activity in this in vivo test system [79].

Another study by Paulo et al. on the roots of Cryptolepis sanguinolenta harvested from Guinea-Bissau led to the isolation of cryptolepinoic acid (62) and methyl cryptolepinoate (63) in addition to 53, 54 and 56 from the ethanol and chlorophorm extracts of the leaves [81]. The isolated compounds and extracts were tested in vitro against P. falciparum K1 (multidrug-resistant strain) and T996 (chloroquine-sensitive clone). All extracts had 90% inhibition of P. falciparum K1 growth at concentrations <23 μg mL-1. Cryptolepine (53) was the most active alkaloid tested with IC50 values (0.23 μM to K1; 0.059 μM to T996), compared to chloroquine (0.26 μM to K1; 0.019 μM to T996). The indolobenzazepine alkaloid cryptoheptine (57) was the second most active with IC50 values of 0.8 μM (K1) and 1.2 μM (T996). Cryptolepinoic acid (62) showed no significant activity while its ethyl ester derivative (63′) was active against P. falciparum K1 (IC50 = 3.7 μM). All the indoloquinoline alkaloids showed cross-resistance with chloroquine but not the indolobenzazepine cryptoheptine (57). It was noticed that alkaloids with weakly basic characteristics were active whereas other structurally related alkaloids with different acid–base profiles were inactive. These observations are in agreement with the anti-malarial mechanism of action for quinolines. According to Hadden et al., the unusual incorporation of the isopropyl group at the 11-position of the indolo [3,2-b] quinoline nucleus in 11-isopropylcryptolepine (56) is suggestive of a mixed biosynthetic origin for the alkaloid [82].

Terpenoids

Terpenoids with most promising anti-malarial properties are summarized in Tables 3, 4 and 5 (according to their subclasses), while the chemical structures are shown in Figures 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18 and 19.

Table 3

Summary of anti-malarial terpenoids derived from the African flora, part 1: clerodanes, labdanes, limonoids, bisnorterpenes and acyclic triterpenes

Compound subclass	Isolated metabolites	Plant species (Family)	Part of plant studied	Place of harvest (locality, country)	Author, reference
Clerodane and labdane diterpenoids	64 to 70	Nuxia sphaerocephala (Loganiaceae)	Leaves	Ankazobe, Madagascar	Mambu et al.[83]
	71 to 74	Aframomum latifolium or sceptrum (Zingiberaceae)	Fruits and Leaves	Acrra, Ghana	Duker-Eshun et al.[84]
	75, 76 and 77	Turreanthus africanus (Meliaceae)	Seeds	Mt. Cameroon, Cameroon	Ngemenya et al.[85]
	78, 79, 80, and 81	Aframomum zambesiacum (Zingiberaceae)	Seeds	Nyasoso, Cameroon	Kenmogne et al. [86]
	74 a, b , 82 a and 83 b	Aframomum	Seeds a	Mogbi, Cameroon a	Ayimele et al. [87] a
		escapum a	Fruits and leaves b
		(Zingiberaceae) Aframomum latifolium and sceptrum b		Acrra, Ghana b	Duker-Eshun et al.[84] b
		(Zingiberaceae)
	84, 85, 86, and 87	Aframomum arundinaceum (Zingiberaceae)	Seeds	Maha, Cameroon	Wabo et al.[88]
Limonoids	88	Vepris uguenensis (Rutaceae)	Roots	Baringo District, Kenya	Cheplogoi et al.[73], Kiplimo [73]
	89, 90, 91, 92, and 93	Khaya grandifoliola (Meliaceae)	Bark and seeds	Foumban, Cameroon	Bickii et al.[89]
	94 and 95	Entandrophragma angolense (Meliaceae)	Stem bark	Awae forest reserve, Cameroon	Bickii et al.[90]
	96, 97, 98, and 99	Ekebergia capensis (Zingiberaceae)	Stem bark	Mt Kenya, Kenya	Murata et al.[91]
Bisnorterpenes	100, 101, 102, and 103	Salacia madagascariensis (Celastraceae)	Roots	Tanzania	Thiem et al.[92]
Acyclic triterpenes	104, 105, 106, and 107	Ekebergia capensis (Zingiberaceae)	Stem bark	Mt Kenya, Kenya	Murata et al.[91]
	108	Aframomum escapum (Zingiberaceae)	Seeds	Mogbi, Cameroon	Ayimele et al. [87]
					Lopez et al. [93]

a,b and ccorrespond to the respective references.

Table 4

Summary of anti-malarial terpenoids derived from the African flora, part 2: cassane furanoditerpenes, abietane diterpenes and sesquiterpenes

Compound subclass	Isolated metabolites	Plant species (Family)	Part of plant studied	Place of harvest (locality, country)	Author, reference
Cassane furanoditerpenes	109 and 110	Caesalpinia volkensii (Leguminosae)	Root bark	Gatamaiyo forest, Kenya	Ochieng et al.[94]
Abietane diterpenes	111 and 112	Plectranthus hadiensis (Lamiaceae)	Leaves	South Africa	van Zyla et al.[95]
	113	Plectranthus lucidus (Lamiaceae)	Leaves	South Africa	van Zyla et al.[95]
	114	Plectranthus ecklonii (Lamiaceae)	Leaves	South Africa	van Zyla et al.[95]
	115, 116 and 117	Plectranthus purpuratus (Lamiaceae)	Leaves	South Africa	van Zyla et al.[95]
	118	Fuerstia africana (Lamiaceae)	Aerial parts	Ngong Hills, Kenya	Koch et al. [96]
	119	Hoslundia opposita (Lamiaceae)	Root bark	Tanzania	Achenbach et al.[97]
	120	Hyptis suaveolens (Lamiaceae)	Leaves	Southeastern Nigeria	Chukwujekwu et al.[98]
Sesquiterpenes and sesquiterpene lactones	121, 122, 123, and 124	Vernonia amygdalina (Asteraceae)	Leaves	Mahale National Mountains Park, Tanzania	Ohigashi et al.[99]
	125	Vernonia brachycalyx (Asteraceae)	Leaves	Machakos District, Kenya	Oketch-Rabah et al. [100]
	126	Ajuga remota (Lamiaceae)	Aerial parts	Nairobi, Kenya	Kuria et al. [101]
	127, 128 and 129	Reneilmia cincinnata (Zingiberaceae)	Fruits	Bafut, Cameroon	Tchuendem et al. [102]
	130 and 131	Acanthospermum hispidum (Asteraceae)	Flowers, leaves and stems	Danto/Porto-Novo, Benin	Ganfon et al. [103]
	132, 133, 134, and 135	Vernonia angulifolia (Asteraceae)	Aerial parts	University of KwaZulu-Natal, South Africa	Pedersen et al. [104]
	136	Dicoma tomentosa (Asteraceae)	Whole plant	Poun, Burkina Faso	Jansen et al. [105]
	137	Artemisia annua (Asteraceae)	Seeds	Kjenzi (Bugarama), Burundi	Reale et al. [106]
	138	Dicoma anomala subsp. gerrardii (Asteraceae)	Root stocks	Brits region, South Africa	Becker et al. [107]
	139	Tithonia diversifolia (Asteraceae)	Aerial parts	São Tomé and Príncipe islands	Goffin et al.[108]
	140	Scleria striatinux (Cyperaceae)	Roots	Oku, Cameroon	Efange et al.[109]
Coloratane sesquiterpenes	141 to 148	Warburgia ugandensis (Canellaceae)	Stem bark	Dello Menna, Ethiopia	Wube et al.[110]

Table 5

Summary of anti-malarial triterpenoids derived from the African flora, part 3: Beilshmiedic acid derivatives and pentacyclic triterpenes

Compound subclass	Isolated metabolites	Plant species (Family)	Part of plant studied	Place of harvest (locality, country)	Author, reference
Beilshmiedic acid derivatives	149, 150, 151, 152, and 153	Beilschmiedia cryptocaryoides (Lauraceae)	Bark	Ranomafana-Ifanadiana, Madagascar	Talontsi et al.[111]
Pentacyclic triterpenes	154	Schefflera umbellifera (Araliaceae)	Leaves	South Africa	Mthembu [112]
	155	Maytenus senegalensis (Celastraceae)	Root bark	Eastern region of Sudan	Khalid et al. [113]
	156, 157, 158, 159, and 160	Nuxia sphaerocephala (Loganiaceae)	Leaves	Ankazobe, Madagascar	Mambu et al.[83]
	161 and 162	Hymenocardia acida (Phyllanthaceae)	Bark	Chad	Mahmout et al.[114]
	161	Cassia siamea (Fabaceae)	Stems	Otu (Oyo State), Nigeria	Ajaiyeoba et al.[115]
	163 and 164	Entandrophragma angolense (Meliaceae)	Stem bark	Awae forest reserve, Cameroon	Bickii et al.[90]
	165	Hypericum lanceolatum (Hypericaceae)	Stem bark	Mt. Bamboutos, Cameroon	Zofou et al. [116]
	166	Psorospermum glaberrimum (Hypericaceae)	Stem bark	Ekombitié, Cameroon	Lenta et al. [117]
	167	Baillonella toxisperma (Sapotaceae)	Stem bark	Korup forest reserve, Cameroon	Mbah et al. [118]
	168	Kigelia africana (Bignoniaceae)	Stem bark	Bandjoun, Cameroon	Zofou et al. [119]
	169, 170 and 171	Cogniauxia podolaena (Cucurbitaceae)	Stem bark	Congo	Banzouzi et al. [120]

Figure 8

Clerodane and labdane diterpenoids from African medicinal plants with anti-malarial activity - I.

Figure 9

Clerodane and labdane diterpenoids from African medicinal plants with anti-malarial activity – II.

Figure 10

Limonoids from African medicinal plants with antiplasmodial activity.

Figure 11

Bisnorterpenes from African medicinal plants with anti-malarial activity.

Figure 12

Anti-malarial acyclic triterpenes from African medicinal plants.

Figure 13

Promising anti-malarial cassane furanoditerpenes from African medicinal plants.

Figure 14

Promising anti-malarial abietane diterpenes from African medicinal plants.

Figure 15

Some anti-malarial sesquiterpenes and sesquiterpene lactones from African medicinal plants - I.

Figure 16

Some anti-malarial sesquiterpenes and sesquiterpene lactones from African medicinal plants - II.

Figure 17

Coloratane sesquiterpenes from African medicinal plants with anti-malarial activity.

Figure 18

Beilshmiedic acid derivatives from African medicinal plants with anti-malarial activity.

Figure 19

Pentacyclic triterpenes from African medicinal plants with antiplasmodial activity.

Clerodane and labdane diterpenoids

Mambu et al. isolated the clerodanes (13S)-ent-7β-hydroxy-3-cleroden-15-oic acid (64), ent-7β-hydroxy- 2-oxo-3-cleroden-15-oic acid (65), ent-2,7-dioxo-3-clero-den-15-oic acid (66) and ent-18-(E)-caffeoyloxy-7β-hydroxy-3-cleroden-15- oic acid (67) and the labdanes (13S)-ent-18-(E)-coumaroyloxy-8(17)-labden-15-oic acid (68), ent-18-(E)-caffeoyloxy-8(17)-labden-15-oic acid (69) and ent-15-E-caffeoyloxy-8(17)-labden-18-oic acid (70) from Nuxia sphaerocephala, growing in Ankazobe, 100 km from Antananarivo, Madagascar [83]. The compounds showed in vitro anti-plasmodial activities against the FcB1 P. falciparum strain, with respective IC50 values 14.6, 4.3, 8.0, 7.3, 11.4, 21.0, 16.0 μg mL-1. Duker-Eshun et al. obtained aframodial (71), (E)-8(17), 12-labddiene-15,16-dial (72), (E)-15,15-diethoxylabda-8(17),12-dien-16-al (73) and coronarin B (74) from the fruits and leaves of Aframomum latifolium or Aframomum sceptrum (Zingiberaceae) harvested in Accra, Ghana. Respective IC50 values of 25, 48, 24, and 26 μM against the chloroquine-sensistive strain (3D7) were obtained for these compounds [84]. Anti-plasmodial activites were also obtained for labdanes 16-oxolabda-8(17),12(E)-dien- 15-oic acid (75), methyl-14,15-epoxylabda-8(17), 12(E)-diene-16-oate (76) and turraeanin A (77), from the seeds of Turreanthus africanus (Meliaceae), a plant generally used in preparations against fevers and malaria in ATM [85]. Compound 75 showed the highest anti-plasmodial activity (IC50 of 26 μg mL-1) on chloroquine-sensitive P. falciparum F 32, in vitro, while compounds 76 and 77 rather had moderate activities [85]. Other anti-malarial labdanes of Aframomum sp. include 3-deoxyaulacocarpin A (78), zambesiacolactones A (79) and B (80) and aulacocarpin A (81) from seeds of Aframomum zambesiacum[86]; coranarin B (82) from the seeds of Aframomum escapum[87]; galanal A (83) from the leaves of Aframomum sceptrum[84]; galanal B (84), galanolactone (85), (E)- 8β,17-epoxylabd-12-ene-5,16 dial (86) and (E) labda-8,12-diene-15,16 dial (87) from the seeds of Aframomum arundinaceum[88]. Among these compounds, compound 76 (3-deoxyaulacocarpin A), derived from Aframomum zambesiacum, was both the least polar and the most active compound, with an IC50 of 4.97 μM (1.73 μg/ml) [86].

Limonoids

Limonoids with good anti-plasmodial activities have been isolated from Vepris uguenensis (Rutaceae), harvested in Kenya [68,73], as well as from Khaya grandifoliola (Meliaceae) and Entandrophragma angolense (Meliaceae) harvested in Cameroon [89,90]. The chemical structures are shown in Figure 10. Methyl uguenesonate (88) from Vepris uguenensis displayed mild activity, with IC50 values of 10.4 and 13.8 μg mL-1, against the CQS and CQR strains of P. falciparum, respectively [68,73]. The bark and seed extracts of Khaya grandifoliola (Meliaceae), a plant species widely used in the Central African subregion to treat various ailments, including malaria have also been investigated. Seven limonoids were isolated, among which five were significantly active (with IC50 values ranging between 1.25 and 9.63 μg mL-1). These include: methylangolensate (89); gedunin (1.25 μg mL-1) (90); 7-deacetylkhivorin (91); 1-deacetylkhivorin (92) and 6-acetylswietenolide (93). The same authors also investigated the stem bark of Entandrophragma angolense (Meliaceae) and isolated known limonoids with anti-malarial activity; 7α-acetoxydihydronomilin (94), 7α-obacunylacetate (95) and methylangolensate (89). Compounds 89 and 95 were considerably active against P. falciparum W2 with respective IC50 values of 2.0 and 19.5 μg mL-1.

Among the four limonoids derived from the stem bark of Ekebergia capensis, namely 7-deacetoxy-7-oxogedunin (96), ekeberins C1 (97), C2 (98) and C3 (99), only compound 96 exhibited significant activity against the chloroquine-susceptible FCR-3 strain of P. falciparum, with an IC50 of 6 μM, but it lacked efficacy against the chloroquine-resistant K-1 strain [91].

Bisnorterpenes

Bisnorterpenes with interesting anti-plasmodial properties were purified from the roots of Salacia madagascariensis (Celastraceae), a shrub found in East Africa whose roots are used in the treatment of malaria, fever and menorrhagia specifically in Tanzania [92]. This plant is a rich source of bisnortriterpenes with potent antiprotozoal activity [45]. Four bisnortriterpenes; isoiguesterin (100), 20-epi-isoiguesterinol (101), isoiguesterinol (102) and 6-oxoisoiguesterin (103), were reported from the roots of this plant [92], Figure 11. However, only the first two showed high activity, with respective IC50 values of 200 and 68 ng mL-1 against the D6 strain of P. falciparum, and 170 and 68 ng mL-1 (against the W2 strain of P. falciparum), respectively.

Acyclic triterpenes

The most active acyclic triterpenes have been found in the stem back of Ekebergia capensis (Zingiberaceae) by Murata et al. [91]. Four triterpenes from the stem bark of this species, comprising two new acyclic triterpenoids, namely ekeberin D4 (104) and D5 (105) and two known ones (3R,22R)-2,3,22,23-tetrahydroxy-2,6,10,15,19,23-hexamethyl-6,10,14,18-tetracosatetraene (106) and (2R,3R,22R)-2-hydroxymethyl-2,3,22,23-tetrahydroxy- 2,6,10,15,19,23-hexamethyl-6,10,14,18-tetracosatetraene (107) have been identified, Figure 12. Compounds 106 and 107 exhibited moderate anti-malarial activity against the FCR-3 strain of P. falciparum, with IC50 values of 55 and 18 μM respectively, in addition to the good activities against the chloroquine-resistant K-1 strain, against which they had respective IC50 values of 7 and 59 μM. The triterpene 104 lacked efficacy, while 105 had an IC50 of 137 μM against the same parasite [91]. (+) S-nerolidol (108) isolated from the seeds of Aframomum escapum[87], is an important constituent of essential oils used in the treatment of malaria. This compound is also found in Artemisia herba alba and in lemon grass, and is able to arrest development of the intraerythrocytic stages of the parasite. Compound 108 was identified as the active constituent leading to 100% growth inhibition at the schizont stage [93].

Cassane furanoditerpenes

Ochieng et al. isolated the cassane furanoditerpenes; deoxycaesaldekarin C (109) and caesaldekarin C (110) from the the chloroform and ethyl acetate extracts of the root bark of Caesalpinia volkensii from Kenya (Figure 13). These two compounds have exhibited antinociceptive and anti-plasmodial activities [94]. The anti-plasmodial activities were evaluated against chloroquine-sensitive (D6) and chloroquine-resistant (W2), with respective IC50 values of 25.67 and 30.33 μg mL-1 for compound 109 and respective IC50 values of 34.44 and 30.69 μg mL-1 for compound 110. The results however demonstrated that Caesalpinia volkensii and other members of this genus contain cassane furanoditerpenes, which play a role in the medicinal properties of their plant root barks. The antinociceptive action in chemical models of nociception in mice suggests that the root bark extract and the active principles (furanoditerpenes) represent potential therapeutic options for the management of pain related ailments and not malaria [94].

Abietane diterpenes

The anti-malarial properties of Plectranthus sp. (Lamiaceae), harvested in South Africa, have been determined by van Zyla et al. [95]. Seven abietane diterpenes (see Figure 14) were isolated from Plectranthus hadiensis, Plectranthus lucidus, Plectranthus ecklonii, Plectranthus purpuratus subsp. purpuratus and Plectranthus purpuratus subsp. tongaensis; 7α-formyloxy-6,12-dihydroxy-abieta- 8,12-diene-11,14-dione (111), 7α-acetoxy-6,12-dihydroxy-abieta-8,12- diene-11,14-dione (112), 11-hydroxy-2α-(4-hydroxybenzoyloxy)- abieta-5,7,9(11),13-tetraene-12-one (113), 11-hydroxy-2α-(3,4-dihydroxybenzoyloxy) abieta-5,7,9(11),13-tetraene-12-one (114), 11-hydroxy-19-(methyl-buten-2-oyloxy)-abieta -5,7,9 (11),13-tetraene-12-one (115), 11-hydroxy-19-(4-hydroxy-benzoyloxy)-abieta-5,7,9(11),13-tetraene-12-one (116) and 11-hydroxy-19-(3,4-dihydroxybenzoyloxy)-abieta-5,7,9(11),13-tetraene-12-one (117). These compounds were tested for their anti-plasmodial activity and for their ability to inhibit β-haematin formation. Overall, they showed good activity (IC50 values ranging from 3.11 to 14.65 μM), with compound 114 being 62% as effective as chloroquine in inhibiting β-haematin formation. Compounds 111, 114 and 117 were more active than quinine. However, the cytotoxicity profile indicated a low degree of specificity towards the malaria parasite. When combined with quinine, three compounds (114, 115 and 117) interacted in an additive manner whereas compound 111 interacted synergistically [95].

Two other abietane diterpenes with anti-plasmodial activities; ferruginol (118) and 3-O-benzoylhosloppone (119), were respectively isolated by Koch et al. [96] and Achenbach et al. [97]. Compound 118 was isolated from the methanol extract of dried aerial parts (leaves and stems) of Fuerstia africana (Lamiaceae), a low-growing herb endemic to tropical East Africa [96], while compound 119 was isolated from the root bark of Hoslundia opposita (Lamiaceae), harvested in Tanzania [97]. The anti-malarial activity of compound 118, determined using the D6 (chloroquine-sensitive derived from CDC Sierra Leone) clone of P. falciparum, showed a strong activity with an IC50 of 1.95 μg mL-1 compared to chloroquine IC50 = 1.94 μg mL-1[96]. Meanwhile, 3-O-benzoylhosloppone (119) inhibited the growth of the multidrug resistant strain K1 of P. falciparum in vitro with an IC50 value of 0.4 μg mL-1[97]. A bioactivity-guided fractionation of the petroleum ether extract of the leaves of Hyptis suaveolens, from Nigeria, led to the isolation of the abietane-type diterpenoid endoperoxide, 13α-epi-dioxiabiet-8(14)-en-18-ol (120), a molecule with high anti-plasmodial activity (IC50 = 0.1 μg mL-1) [98].

Sesquiterpenes and sequiterpene lactones

Sequiterpenes derived from Vernonia sp. are known to have interesting anti-plasmodial activities. The compounds include vernodalin (121), vernodalol (122), vernolide (123), hydroxyvernolide (124), derived from the leaves of Vernonia amygdalina by Ohigashi et al. [99], in addition to 16,17- dihydrobrachycalyxolide (125) isolated from the leaves of the sister species, Vernonia brachycalyx, as a major anti-plasmodial compound, by Oketch-Rabah et al., Figures 15 and 16[100]. These compounds exhibited moderate anti-plasmodial activity against the multidrug-resistant K-1 strain of P. falciparum, vernodalin (121) being the most active compound with an IC50 value of 4 μg mL-1. Meanwhile, compounds 122, 123 and 124 had IC50 values of 4.2, 8.4 and 11.4 μg mL-1, respectively [99]. The measured activities of the compounds correlates with the uses of the plants in ATM (the leaves of Vernonia amygdalina are used in the treatment of various diseases, including malaria). Quantitative analysis showed that young leaves of this species have a higher concentration of compound 121 than the other derived compounds, suggesting that the anti-malarial efficacy of the leaf extracts of this species may be partly due to the high content of this NP. It has also been reported that dry leaves of Vernonia brachycalyx contain 0.2-0.4% of the sesquiterpene dilactone 125. This compound exhibited moderate to high anti-plasmodial activity against the K39, 3D7, V1/S and Dd2 P. falciparum strains, with IC50 values of 4.2, 13.7, 3.0, and 16 μg mL-1, respectively [100]. In spite of the anti-plasmodial activity of this compound, it also had higher toxicity against human lymphocytes, indicating that the anti-plasmodial activity may have been due to the general toxicity the compound had on cells. Despite these observations, the leaves of this species are still used in the treatment of malaria and parasitic infections in East Africa [45]. Ajugarin-1 (126) is another sesquiterpene, which has been reported from aerial parts of Ajuga remota, harvested in Kenya [101]. The compound has exhibited moderate anti-malarial properties against the chloroquine-sensitive FCA20/GHA strain of P. falciparum, with an IC50 of 23 μM [101].

The sesquiterpenoids oplodiol (127), 5E,10(14)-germacradien-1β,4β-diol (128) and 1(10) E,5E-germacradien-4α-ol (129), derived from Reneilmia cincinnata, with respective IC50 values of 4.17, 1.63 and 1.54 μM, were used to validate the use of this plant in ATM to cure malaria and other fevers in Cameroon [102]. In addition, Ganfon et al. investigated the antiparasitic activities of two sesquiterpenic lactones isolated from Acanthospermum hispidum harvested in Benin Republic [103]. From their results, two known sesquiterpenic lactones were isolated: 15-acetoxy-8β-[(2-methylbutyryloxy)]-14-oxo-4,5-cis-acanthospermolide), 130 and 9α-acetoxy-15-hydroxy-8β-(2-methylbutyryloxy)-14-oxo- 4,5-trans-acanthospermolide), 131. Compounds 130 and 131 showed in vitro anti-plasmodial activity against the chloroquine-sensitive strain (3D7) with IC50 values of 2.9 and 2.23 μM, respectively. Only 131 showed a high selectivity index (SI: 18.4) on Plasmodium compared to cytotoxicity against human fibroblasts cell line (WI38). Furthermore, the crude acidic water extract and fractions containing one of the two isolated compounds displayed a weak in vivo anti-malarial activity against P. berghei berghei with a long half-life causing a delayed effect. In vivo acute (2000 mg kg-1) and sub-acute (1000 mg kg-1) toxicity tests of the crude acidic water extract did not show toxicity. Moreover, the crude acidic water extract, fractions and pure isolated compounds from Acanthospermum hispidum showed promising in vitro anti-plasmodial activity. Despite the fact that this study did not show in vivo acute and subacute toxicities of the crude acidic water extract, its weak in vivo anti-malarial activity and the in vitro cytotoxicity of pure compounds and enriched extracts containing 130 and 131 indicate that the aerial parts of this plant should be used with caution for malaria treatments [103].

The combined use of bioassay-guided fractionation based on in vitro anti-plasmodial assay and dereplication based on HPLC–PDA–MS–SPE–NMR by Pederson et al. [104], led to isolation of (6S,7R,8S)-14-acetoxy-8-[2-hydroxymethylacrylat]-15-helianga-1(10),4,11(13)-trien-15-al-6,12-olid or vernangulide A (132) and (5R,6R,7R,8S,10S)-14-acetoxy-8-[2-hydroxymethylacrylat]-elema-1,3,11(13)-trien-15-al-6,12-olid or vernangulide B (133), along with vernodalol (134), vernodalin (135) and 11,13β-dihydroxyvernodalin (136) from the dichloromethane/methanol 1:1 and methanol extracts of the aerial parts of Distephanus angulifolius. The isolated compounds showed IC50 values in the range 1.6 to 3.8 μM and 2.1 to 4.9 μM against chloroquine-sensitive D10 and chloroquine-resistant W2 P. falciparum strains, respectively. Janson et al. identified urospermal A-15-O-acetate (136) as the main active compound responsible for the anti-plasmodial activity of Dicoma tomentosa (Asteraceae) from Burkina Faso [105]. Based on their results, the IC50 of the compound was <1 μg mL-1 against both 3D7 and W2 strains. Compound 136 was found to be the main cytotoxic compound (SI = 3.3). A rapid quantification of the anti-malarial drug, artemisinin (137) in Artemisia annua plants cultivated for the first time in Burundi by Reale et al., revealed the prospect of cultivating Artemisia and eventually using the active principle to offer the population of Burundi a fundamental resource in a country where malaria is endemic [106].

Standard phytochemical analysis techniques, including solvent-solvent extraction, thin-layer- and column chromatography, were used by Becker et al. to isolate a eudesmanolide-type sesquiterpene lactone, dehydrobrachylaenolide (138), as the main active constituent of Dicoma anomala subsp. gerrardii from the Brits region of North West Province of South Africa [107]. The compound demonstrated an in vitro IC50 of 1.865 μM against a chloroquine-sensitive strain (D10) of P. falciparum. The biological activities of synthetic analogues of compound 138 showed that a methylene lactone group must be present in the eudesmanolide before any significant anti-malarial activity could be observed. This feature is absent in the artemisinins and suggests that eudesmanolide-type sesquiterpene lactones have a different mode of action from artemisinins. This hypothesis was further confirmed by microarray gene ontology analysis [107]. The ether extract from aerial parts of Tithonia diversifolia collected in São Tomé and Príncipe demonstrated good anti-plasmodial activity (IC50 of 0.75 μg mL-1 against the FCA strain) and fractionation of this extract yielded the sesquiterpene lactone tagitinin C (139) as an active compound against P. falciparum (IC50 of 0.33 μg mL-1 against the FCA strain) [108].

Okundoperoxide (140), a new compound with a cyclic endoperoxide moiety, was isolated by Efange et al. from Scleria striatinux (Cyperaceae), a spice commonly used in Cameroonian folk medicine to treat malaria and other fevers. This molecule exhibited significant anti-plasmodial activity, with IC50 values of 0.47, 0.48, 1.49, and 1.30 μg mL-1, on P. falciparum W2, D6, K1, and NF54, respectively. Moreover, the molecule showed no significant toxicity against mammalian cells [109].

Coloratane sesquiterpenes

Wube et al. demonstrated the antiprotozoal activity of Warburgia ugandensis (Canellaceae) from Ethiopia towards Trypanosoma brucei rhodesiense and P. falciparum in vitro and attributed the anti-plasmodial activity to the presence of drimane and coloratane sesquiterpenes. These include 4(13),7-coloratadiene-12,11-olide (141), 11α-hydroxymuzigadiolide (142), muzigadial (143), 6α,9α-dihydroxy-4(13),7-coloratadiene-11,12-dial (144), cinnamolide (145), cinnamolide-3β-acetate (146), mukaadial (147) and ugandensidial (148), Figure 17. The anti-plasmodial assays also revealed that the six coloratane and six drimane sesquiterpenes isolated from this extract exhibited significant antitrypanosomal activity with IC50 values ranging from 0.45 to >114 μM. Among the compounds tested against the malaria parasite P. falciparum 11α-hydroxymuzigadiolide (142) was most active with an IC50 value of 6.40 μM [110].

Beilshmiedic acid derivatives

Beilschmiedic acid derivatives exhibiting antibacterial and anti-plasmodial activities were obtained from Beilschmiedia cryptocaryoides (Lauraceae) collected from Madagascar (Table 5). The work of Talontsi et al. [111] led to the isolation of four new beilschmiedic acid derivatives, cryptobeilic acids A - D (149 to 152), and tsangibeilin B (153), Figure 19. Compounds 149 to 153 exhibited anti-plasmodial activity against erythrocytic stages of chloroquine-resistant P. falciparum strain NF54 (with IC50 values ranging from 5.35 to 17.70 μM) and weak cytotoxicity against L6 cell lines (with IC50 values ranging from 20.4 to 61.0 μM), the most promising antiplasmodial activity being shown by compound 150.

Pentacyclic triterpenes

The crude organic (methanol/dichloromethane (1:1)) extract of the leaves of Schefflera umbellifera (Araliaceae) exhibits promising anti-malarial activity. Bioassay-guided fractionation of this extract yielded the active compound, 3-hydroxy-20(29)-lupen-28-ol (154), Figure 19, which exhibited good anti-plasmodial activity (IC50 of 3.2 μg mL-1), when tested against a chloroquine-susceptible malarial strain (D10). The reference compound (chloroquine) gave an IC50 of 27.2 ng mL-1[112]. The quinonemethide triterpene, pristimerin or (20α)-3-hydroxy-2-oxo-24-nor-friedela-1(10),3,5,7-tetraen-carboxylic acid-(29)-methylester (155) was obtained by a bioactivity directed fractionation of the chloroform extract of the root bark of Maytenus senegalensis (Celasterceae) harvested from Sudan by Khalid et al. [113]. The in vitro anti-plasmodial activity of the isolated compound against chloroquine-resistant strain (Dd2) of P. falciparum was IC50 = 0.5 μg mL-1, while the cytotoxicity on lymphocyte proliferation model was detected at IC50 = 6.8 μg mL-1. The lupane-type triterpenoids 3-oxolupenal (3-oxolup-20(29)-en-30-al) (156), 3β-hydroxylupenal (3β-hydroxylup-20(29)-en-30-al) (157) and 3-oxolupenol (30-hydroxylup-20(29)-en-3-one) (158) were obtained from the leaves of Nuxia sphaerocephala (Loganiaceae), along with oleanolic acid (160), its acetylated ester (159), lupeol, uvaol, ursolic acid, and 3β-acetylursolic acid [83]. Among the compounds isolated from this study, 156 and 157 showed the best inhibitory activity against P. falciparum with the IC50 values between 1.55 and 4.67 μg mL-1in vitro, respectively.

Another lupane-type triterpene, lupeyl docosanoate (162), was isolated from the bark extract of Hymenocardia acida (Phyllanthaceae) collected in Chad, along with lupeol (161) and β-sitosterol by Mahmout et al. [114]. The anti-malarial property of compound 162 justifies the ethnobotanic use of the plant in the treatment of malaria. Cassia siamea (Fabaceae) was identified from an ethnobotanical survey of southwest Nigeria as a remedy for febrile illness. Bioassay-guided fractionation of stem bark of the plant extract, using the parasite lactate dehydrogenase assay and multi-resistant strain of P. falciparum (K1) for assessing the in vitro anti-malarial activity led to the isolation of emodin and lupeol (161) from the ethyl acetate extract [115]. Both compounds were found to be the active principles responsible for the anti-plasmodial property with IC50 values of 5 μg mL1, for each compound. The compounds 22-hydroxyhopan-3-one (163) and 24-methylene cycloartenol (164) from the stem bark of Entandrophragma angolense (Meliaceae) had moderate activities against P. falciparum W2 [90]. Zofou et al. evaluated the anti-plasmodial activity of betulinic acid (165) from the stem bark of the African St John’s wort, Hypericum lanceolatum (Hypericaceae). The compound had an IC50 of 2.05 μg mL-1[116]. The n-hexane extract of Psorospermum glaberrimum from Cameroon showed good anti-plasmodial activity against the P. falciparum W2 strain, with IC50 of 0.87 μg mL-1[117]. Lenta et al. isolated betulinic acid (165) and friedelan-3-ol (166) from this extract. The measured in vitro activity of compound 165 against the P. falciparum W2 strain gave an IC50 of 2.33 μg mL-1. Mbah et al. isolated 3-O-betulinic acid p-coumarate (167) from Baillonella toxisperma, with an IC50 of 1.65 μM [118]. The triterpenoid 2β,3β,19α-trihydroxy-urs-12-20-en-28-oic acid (168) was isolated by Zofou et al. [119] from the stem bark of Kigelia africana (Bignoniaceae). This compound exhibited an IC50 of 0.90 μg mL-1 against the W2 strain of P. falciparum.

Cogniauxia podolaena (Cucurbitaceae) is traditionally used in Congo Brazzaville for the treatment of malaria. The anti-plasmodial activity of the plant and some of the isolated compounds responsible for its activity were assessed by Banzouzi et al. [120]. Cucurbitacin B (169), cucurbitacin D (170) and 20-epibryonolic acid (171) were assayed for anti-plasmodial activity (on FcM29, a chloroquine-resistant strain of P. falciparum) and cytotoxicity (on KB and Vero cell lines). The compounds showed respective IC50 values of 1.6, 4.0 and 2.0 μg mL-1 on FcM29. Compounds 169 and 170 both showed high cytotoxicity whereas 171 showed a better selectivity index.

Conclusions

In this review an attempt has been made to document anti-malarial activities of NPs derived from African medicinal plants. It covers results published until the time of submission of the article. The first part of the review involves naturally occurring, anti-plasmodial/anti-malarial alkaloids and terpenoids while the second part of the review focuses on the remaining classes of compounds. Some of the compounds have been isolated from plants reputed to have a long history of usage in ATM, inferring that knowledge from ATM could be very useful in drug discovery efforts from African medicinal plants. From every indication, recent research efforts on new anti-malarial agents should focus on two main areas: the search for new chemical entities (NCEs) of natural/semisynthetic origin, and the development of phytomedicines [37]. It should be mentioned that African researchers have, knowingly or unknowingly, blown the former avenue out of proportion. This is basically as a result of the fact that most of the research activities on medicinal plants going on in Africa are carried out by academic research groups and the focus is on publications, not application. This calls for the need to develop the necessary applications required to turn acquired knowledge on NPs derived from African medicinal plants into concrete applications in phytomedicine, within an industrial setting. It has been noticed that among the anti-malarials mentioned in this review, most have never been tested for cytotoxicity and very few have been tested for in vivo antoplasmodial activity. Another limitation is the, often small, quantities of compounds isolated from the plants which frustrate ambitions of large-scale screening efforts. Since some complex anti-malarial mixtures derived from plant extracts sometimes loose their anti-malarial properties when pure compounds are isolated, due to synergism of molecules in mixture, the trend towards the development of total extracts into phytomedicines or improved traditional preparations is to be encouraged. Moreover, the isolation and characterization of NPs is an expensive endeavour, not within the reach of the average African research group. However, the attempt to validate ATM remedies as drugs will also face a number of limitations, among which are dosage determinations, variations of the concentration of the active ingredients in the plants with seasonal variations, the rapid loss of tropical forests and the extinction of key species, intellectual property rights management, the intervariability of plant species, quality control, and the conservation of biodiversity. The reconciliation between academic-oriented research and the development of phytomedicines could be feasible with the establishment of African centres of excellence in drug discovery [121], an initiative of the African Network for Drugs and Diagnostics Innovation (ANDI) [122], ATM being a major hub in this endeavour. In order to enhance modern drug discovery efforts from phytochemicals derived from the African flora, a recent effort by the authors of this paper has been to develop virtual libraries including NPs derived from African medicinal plants that have been reported in the literature, for computer-aided drug discovery (CADD). These include the CamMedNP database, containing three-dimensional structures of NPs derived from Cameroonian medicinal plants [123], the ConMedNP database, which covers ten countries in the Central African geographical region, converging the Congo Basin [124] and the AfroDb database, which is a select highly potent dataset, covering compounds with remarkable activities derived from plants across the entire continent [125]. Such databases could serve as starting points for virtual screening (VS) and CADD, leading to the identification of in silico hits, followed by validation by biological assays. These efforts have been in line with the prediction of DMPK profiles of the NPs, with a view to prioritizing hit selection during VS campaigns [125-127].

Abbreviations

AfroDb: African medicinal plants active compound database; ATM: African traditional medicine; ADME/T: Absorption, distribution, metabolism, excretion, and toxicology; ANDI: African network for drugs and diagnostics innovation; CADD: Computer-aided drug design; CamMedNP: Cameroonian medicinal plant and natural products database; ConMedNP: Congo basin medicinal plant and natural products database; DMPK: Drug metabolism and pharmacokinetics; NP: Natural product; VS: Virtual screening; WHO: World Health Organization.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

FNK, LLL, JCN, and LMM conceived the idea. FNK, LLL and PAO participated in the data collection. FNK and PAO contributed in the data analysis, the discussion of results and the conception of the paper under the supervision of LMM, WS, LLL, and JCN. FNK and PAO wrote the first draft of the paper and all authors agreed on the final version before submission.