Key words
Symphonia globulifera
- Clusiaceae - ethnomedicine - secondary metabolites - biosynthesis - biological activities
Introduction
Higher plants are known to be a rich source of various bioactive compounds [1], some of which have found practical applications in traditional medicine [2]. Symphonia globulifera L. f. has been widely used in traditional medicine to fight against various disorders
such as parasitic disease [3], [4] or body pain [5]. Extracts of this plant have shown very good biological activities against several
pathologies, opening a vast field of research towards the identification of complex
metabolites. Since the first publication in 1992 [6] describing some polycyclic polyprenylated acylphloroglucinols (PPAPs) from S. globulifera as HIV inhibitors, the interest for this plant and its bioactive compounds has been
ever growing. Like the plants of the Garcinia genus, which also contain PPAPs [7], the plants of the species S. globulifera have emerged on both American and African continents, and show some morphological
diversity through sites [8]. This morphological differentiation and the existence of some subfamilies and differences
in country soil and climate have probably induced a variation in the metabolome and
generated a pool of chemodiversity. The purpose of this review is to describe the
botanical aspects, the ethnomedical uses, metabolites, and biogenesis, as well as
the biological activities of all compounds from this species depending on their provenance.
Classification and Botanical Characteristics of Symphonia globulifera
Classification and Botanical Characteristics of Symphonia globulifera
The family Clusiaceae (Guttiferae) comprises about 40 genera and more than a thousand
species. The genus Symphonia includes 17 species [9]. S. globulifera is broadly distributed across the Neotropics and equatorial Africa. It is the only
Symphonia species found outside Madagascar [10].
Some of the vernacular names of this plant are “manil marécage”, “palétuvier jaune”
(French Guiana), “barillo” (Guatemala, Honduras), “cerillo” (Costa Rica, Panama),
“machare” (Colombia), “mani”, “paraman” (Venezuela), “mataki” (Surinam), “manni” (Guiana),
“anany” (Brazil), and “brea-caspi” (Peru). S. globulifera plants are generally tall trees (in general more than 15 m high) with opposite leaves
exhibiting characteristic aerial roots and producing a bright yellow latex. The flowers
are red with a red staminal column and black anthers and organized as a sympodium.
Fruits are drupes (4–5 cm), ovoid, or globular. Seeds are intensively red inside [10], [11], [12].
This species is also characterized by important morphological variations, which seem
to be dependent of its ecological distribution [8]. Indeed, at least three varieties exist, var. angustifolia Maguire, var. macoubea Vesque, and var. major Diels [8], [13], and a small number of supposed subspecies such as Symphonia sp1. However, none of these differences have been yet considered sufficient to merit
splitting into more than one species.
Phylogenetic analyses have demonstrated that marine dispersal played a primary role
in the migration and establishment of S. globulifera in the Neotropics. The regional populations were genetically isolated through the
Pleistocene and earlier [9]. In Central Africa, S. globulifera survived the Pleistocene glacial periods in a few major shelters, essentially centered
on mountainous regions close to the Atlantic Ocean [14]. The capacity for adaptation in different geographical and climate conditions contributed
to the survival and to the genetic and morphological diversity of the species.
Ethnomedicine
Medicinal plants have been playing an important role in providing health care to a
large section of the population, especially in developing countries. S. globulifera has been used for the treatment of several disorders, mainly in Africa and South
America.
Africa
The African traditional medicine proposes an accurate use of local plants though poorly
scientifically studied. Concerning S. globulifera, preparations are mainly decoctions, with applications ranging from serious disorders,
such as scabies, to spiritual remedies ([Table 1]).
Table 1 Traditional use of S. globulifera in Africa and South America.
|
Localization
|
Part of plant
|
Preparation method
|
Therapeutic use
|
|
Africa
|
|
Gabon
|
Bark
|
Decoction
|
Scabies [15]
|
|
South Uganda
|
Bark
|
Decoction
|
Coughs, intestinal worms, prehepatic jaundice, fever [4]
|
|
South Uganda
|
Sap
|
Sap burned like incense
|
Chasing away evil spirits [4]
|
|
Cameroon
|
Leaves
|
Decoction
|
Antiparasitic [17]
|
|
Nigeria
|
Leaves
|
Decoction
|
Skin disease, malaria, diabetes [16]
|
|
South America
|
|
Panama
|
Leaves
|
Cataplasm
|
Body pain, skin ailments [5]
|
|
Brazil
|
Latex
|
Plaster
|
To get pregnant, pulled muscles, fractures [18]
|
|
Brazil
|
Bark
|
Infusion or with soda
|
Vaginal discharge [18]
|
|
Colombia
|
Bark
|
Decoction
|
Cutaneous leishmaniasis [3]
|
Ethnopharmaceutical studies presented in [Table 1] were performed on a large panel of medicinal plants (around 120 plants). The establishment
of this panel was based on several criteria such as the use defined by an ethnic group,
an area of the country, or the country in general. For instance, the Gabonese studies
focused on the use of medicinal plants relating to the single Masango ethnic group
[15], chosen because it is one of the few ethnic groups in Gabon that have kept medical
practices as part of its cultural heritage. Therefore, among the plants used by the
Masango, decoctions of S. globulifera bark are produced to cure the serious problem of scabies.
More recently, studies from Nigeria [16] and Uganda [4] describe the use of S. globulifera not only in terms of ethnicity but also depending on the region of occurrence: Akwa
Ibom State (Nigeria) and the Sango bay area (Uganda). In Nigeria, leaves of S. globulifera are used as a decoction and are applied on the body to treat skin disease, which
is the largest application followed by malaria and diabetes. Other traditional uses
in Nigeria are described in the literature to treat erective problems, venereal diseases,
or wounds using the fruits and leaves of S. globulifera
[19]. However, information regarding the type of preparation was not described; the data
has been discarded from [Table 1].
The Ssegawaʼs study [4] highlights the medicinal plants used by 13 villages in three subcounties surrounding
the Sango bay ecosystem in the Rakai district, Central Uganda. A questionnaire has
been distributed to collect data on local plant names, uses, parts used, and modes
of preparation and administration. From this study, it appears that the S. globulifera biological activities are dependent on the vegetal parts. Thus, the bark extract
presents broad applications ranging from treating coughs and prehepatic jaundice to
fever and intestinal worms. A different application has been observed for the sap
extract, which is used for spiritual application to chase away evil spirits. While
this traditional use of S. globulifera has been proven to exist, the obvious lack of scientific meaning makes its difficult
to understand.
Leishmaniasis and others protozoal diseases are a plague without a sustainable cure,
which dramatically affects the African continent. Considering the great potential
of Cameroon in terms of biodiversity, traditional knowledge, and practice, Lenta et
al. [17] undertook an ethnopharmacological survey on medicinal plants used against protozoal
diseases in this country. Data were collected by contact and interviews with local
traditional healers in the Ndé and Mifi divisions of the West Province of Cameroon.
The selected plants, including S. globulifera, were collected and further evaluated for their in vitro antiprotozoal activity and cytotoxicity ([Table 2]).
Table 2 In vitro activity of S. globulifera leaf methanolic extract.
|
S. globulifera from Cameroon
|
|
Local name: Kebanti
|
Place of collection: Bangangté
|
Voucher No. 32192/HNC
|
Part used: leaves
|
|
Methanolic extract
|
|
IC50 (µg/ml)
|
SI
|
|
* SI (selectivity index): ratio of cytotoxic activity on L-6 cells to antiparasitic
activity
|
|
Plasmodium falciparum
|
4.1 ± 0.5
|
12.75*
|
|
Trypanosoma cruzi
|
> 30
|
1.5*
|
|
Trypanosoma brucei rhodesiense
|
11.5 ± 0.5
|
4.5*
|
|
Leishmania donovani
|
2.1 ± 0.8
|
24.9*
|
|
Cytotoxicity
|
52.3 ± 5.6
|
|
Overall, mainly decoctions of bark or leaves of S. globulifera are used in the African traditional medicine, indicating the presence of polar metabolites
as the main source of activity. The results of the study presented in [Table 2] may participate in understanding the traditional use and strengthen the presence
of active metabolites in polar extracts. Remarkably, South American traditional remedies
are slightly different and present other panels of applications.
South America
The traditional use of S. globulifera in South America is not as widespread as in the African continent. Literature resources
highlight its use principally in Panama, Brazil, and Colombia ([Table 1]). Similar to Africa, the bark, which is the most used part of the plant, is prepared
as a decoction or infusion.
In Panama, the need to explore the ethnobotanical resources in order to develop appropriate
programs for their agricultural, medical, pharmaceutical, silvicultural, and commercial
use is increasing [5]. Moreover, since massive deforestation has been accelerated, there is a high emergency
to collect information and try to save the renewable botanical resources in order
to develop appropriate programs in silviculture and agriculture. For this purpose,
a study was performed on the local plants. S. globulifera was part of the study, and its fresh latex was shown to be used and applied as a
cataplasm against skin ailments and body pain.
The Brazilian Amazon region has a considerable coastline [18]. In Pará State, for example, more than 1500 km of coastline extends from the Amazon
Riverʼs estuary to the state of Maranhão, covered by mangroves and swamps, defined
by abundant natural resources and great scenic beauty. As secondary vegetation, S. globulifera has been described in this mangrove area. It has been shown that the use of its latex
favors pregnancy and is active against pulled muscles and fractures. The latex is
thus used under a plaster form and is therefore easy to apply on bone fractures. Regarding
the barks, they are prepared as an infusion or with soda against vaginal discharge.
In Colombia [3], the plants were collected in four different areas guided by local knowledgeable
healers. S. globulifera was harvested on the Bajo Calima site. The decoction of the bark is traditionally
rubbed on the skin for the treatment of cutaneous leishmaniasis.
In summary, the traditional uses of S. globulifera on both the African and American continents are specific but present some similarities.
The application of cataplasm directly on the body to treat skin diseases or cutaneous
leishmaniasis revealed the presence of polar molecules, which are attractive for cosmetic,
dermatologic, and antiparasitic applications. Comparing the practices in both continents,
the bark seems to contain the main active metabolites, while the leaves and fruits
are poorly used. Finally, from all these surveys, a potent and promising antiparasitic
activity of S. globulifera metabolites emerges.
Secondary Metabolites
Secondary metabolites of S. globulifera are mainly PPAPs. Up to now, a total of 15 of them have been isolated from this species
in addition to the xanthone derivatives of PPAPs: two oxy-PPAPs ([Table 3] and [Fig. 1]). In [Table 3], each compound is described (name, plant part, and country of collection). It is
worth noticing that most PPAPs and oxy-PPAPs described in the literature are numbered
as a bicyclo[3.3.1]nonane-1,3,9-trione, although Ciochina et al. [20] numbered PPAPs as a bicyclo[3.3.1]nonane-2,4,9-trione. The first numbering is the
one that will be followed here. All the compounds are detailed in [Table 3] and described in subsections.
Fig. 1 Chemical structures of polycyclic polyprenylated acylphloroglucinols and oxy-polycyclic
polyprenylated acylphloroglucinols of S. globulifera.
Table 3 Secondary metabolites isolated from S. globulifera.
|
No.
|
Name
|
Plant part
|
Country
|
Molecular weight*
|
Ref.
|
|
* Molecular weights are calculated
|
|
Polycyclic polyprenylated acylphloroglucinols and oxy-PPAPs
|
|
1
|
Guttiferone A
|
seeds
|
Cameroon
|
602.36
|
[21]
|
|
|
|
roots
|
Central African Republic
|
|
[6]
|
|
|
|
leaves
|
Cameroon
|
|
[17]
|
|
2
|
Guttiferone B
|
roots
|
Central African Republic
|
670.42
|
[6]
|
|
3
|
Guttiferone C
|
roots
|
Central African Republic
|
670.42
|
[6]
|
|
4
|
guttiferone D
|
roots
|
Central African Republic
|
670.42
|
[6]
|
|
5
|
14-Deoxy-7-epi-isogarcinol
|
root barks
|
French Guyana
|
586.37
|
[22]
|
|
6
|
Symphonone A
|
root barks
|
French Guyana
|
600.35
|
[22]
|
|
7
|
Symphonone B
|
root barks
|
French Guyana
|
670.42
|
[22]
|
|
8
|
Symphonone C
|
root barks
|
French Guyana
|
618.36
|
[22]
|
|
9
|
7-epi-Coccinone B
|
root barks
|
French Guyana
|
618.36
|
[22]
|
|
10
|
Symphonone D
|
root barks
|
French Guyana
|
636.37
|
[22]
|
|
11
|
Symphonone E
|
root barks
|
French Guyana
|
636.37
|
[22]
|
|
12
|
Symphonone F
|
root barks
|
French Guyana
|
618.36
|
[22]
|
|
13
|
Symphonone G
|
root barks
|
French Guyana
|
618.36
|
[22]
|
|
14
|
Symphonone H
|
root barks
|
French Guyana
|
600.35
|
[22]
|
|
15
|
Symphonone I
|
root barks
|
French Guyana
|
600.35
|
[22]
|
|
16
|
7-epi-Garcinol
|
root barks
|
French Guyana
|
602.36
|
[22]
|
|
17
|
7-epi-Isogarcinol
|
root barks
|
French Guyana
|
602.36
|
[22]
|
|
Polyhydroxylated polyprenylated xanthones and benzophenones
|
|
18
|
Globulixanthone C
|
root barks
|
Cameroon
|
326.08
|
[23]
|
|
19
|
Globulixanthone D
|
root barks
|
Cameroon
|
326.12
|
[23]
|
|
20
|
Globulixanthone E
|
root barks
|
Cameroon
|
618.19
|
[23]
|
|
21
|
Gaboxanthone
|
seeds
|
Cameroon
|
438.17
|
[21]
|
|
22
|
Globuliferin
|
seeds
|
Cameroon
|
440.18
|
[21]
|
|
23
|
Symphonin
|
seeds
|
Cameroon
|
438.17
|
[21]
|
|
24
|
Globulixanthone A
|
root barks
|
Cameroon
|
324.10
|
[24]
|
|
25
|
Globulixanthone B
|
root barks
|
Cameroon
|
380.16
|
[24]
|
|
26
|
Xanthone V1
|
leaves
|
Cameroun
|
394.14
|
[17]
|
|
27
|
Ananixanthone
|
bark
|
Brazil
|
378.15
|
[25]
|
|
28
|
1,7-Dihydroxyxanthone
|
heartwood
|
Uganda
|
228.04
|
[26]
|
|
29
|
1,5,6-Trihydroxyxanthone
|
heartwood
|
Uganda
|
244.04
|
[26]
|
|
30
|
1,3,5,6-Tetrahydroxyxanthone
|
heartwood
|
Uganda
|
260.03
|
[26]
|
|
|
|
twigs
|
Cameroon
|
260.03
|
[27]
|
|
31
|
Norathyriol
|
heartwood
|
Uganda
|
|
[26]
|
|
|
|
twigs
|
Cameroon
|
|
[27]
|
|
32
|
Symphoxanthone
|
heartwood
|
Uganda
|
328.09
|
[28]
|
|
33
|
Globuxanthone
|
heartwood
|
Uganda
|
312.10
|
[28]
|
|
34
|
Ugaxanthone
|
heartwood
|
Uganda
|
328.09
|
[29]
|
|
35
|
Mbarraxanthone
|
heartwood
|
Uganda
|
312.10
|
[29]
|
|
36
|
Maclurin
|
heartwood
|
Uganda
|
262.05
|
[30]
|
|
37
|
Gentisein
|
twigs
|
Cameroon
|
244.04
|
[27]
|
|
38
|
Globulixanthone E
|
twigs
|
Cameroon
|
342.11
|
[27]
|
|
Biflavonoids
|
|
39
|
Morelloflavone
|
leaves
|
–
|
556.10
|
[31]
|
|
40
|
GB-2
|
leaves
|
–
|
574.11
|
[31]
|
|
|
|
twigs
|
Cameroon
|
|
[27]
|
|
41
|
GB3
|
twigs
|
Cameroon
|
590.11
|
[27]
|
Polycyclic polyprenylated acylphloroglucinols
Even if three types of PPAPs are described (A, B, and C) [38], all the PPAPs characterized from S. globulifera belong to the type B family ([Fig. 1]). All of them have been isolated from roots; however, guttiferone A (1) has also been isolated from leaves and seeds. To date and with the exception of
the guttiferones A (1) and B (2), all isolated PPAPs have not been described in any other plant. Guttiferone B (2) has also been isolated from Garcinia oblongifolia and Garcinia cowa
[32], [33], [34] and guttiferone A (1) from about ten other plant species like Garcinia livingstonei
[35], Rheedia edulis
[36], Garcinia macrophylla
[37], Garcinia virgate
[38], Garcinia brasiliensis
[39]. As for many type B PPAPs, secondary cyclization has been observed, as illustrated
with the presence of a dimethylpyran (5, 6, 7, 8, 9, 10, 11, 17) or furan moiety (12, 13) obtained from the epoxydation of a prenyl followed by a ring closure. Compounds
14 and 15 belong to the oxy-PPAPs category, cyclized PPAPs into xanthones. To date, 14 natural
type B oxy-PPAPs have been reported, three have been obtained via chemical reactions
or biotransformation from garcinol (47) [40] and guttiferone A (1) [41]. The biogenesis of oxy-PPAPs is discussed later in this review.
Polyhydroxylated polyprenylated xanthones and maclurin
Besides these PPAPs, maclurin (36), 21 polyhydroxylated polyprenylated xanthones, and benzophenone have been isolated
from S. globulifera ([Fig. 2] and [Table 3]). Prenylated xanthones, such as the well-known gambogic acid, are extensively represented
in the Clusiaceae and Hypericaceae families [42], [43]. These molecules have been isolated from several plant parts of S. globulifera, such as heartwood, twigs, roots, seeds and leaves. Most of the compounds show side
decoration-like prenylated moieties, which can later be involved in the formation
of a dimethyldihydropyran core (18, 20, 21, 23, 26, and 27). Only one dimer (20) resulting from the phenolic coupling has been isolated.
Fig. 2 Chemical structure of xanthones and maclurin from S. globulifera.
Biflavonoids
Another interesting group of natural products has been isolated and described from
S. globulifera ([Fig. 3]). The latter is a small number of biflavonoids comprising three members that could
be depicted as the heterodimerization of apigenin (39, 40) or a luteolin (41) moiety on one hand, with a luteolin (39) or dehydroquercetin moiety (40, 41) on the other hand. They all present a junction between C-3 and C-8. To date, three
biflavonoids have been isolated from the leaves and twigs of this plant. Biflavonoids
are restricted to a few groups of plants and are commonly isolated from species of
the Clusiaceae family. Morelloflavone (39) was also isolated from other species belonging to the Clusiaceae, such as G. livingstonei
[35] or Garcinia xanthochymus
[44].
Fig. 3 Chemical structure of biflavonoides from S. globulifera.
Methyl nervonate
A last metabolite has been recently isolated and named methyl nervonate (42) by the authors [45]. It has been characterized in the anther oil of S. globulifera from Brazil ([Fig. 4]). This fatty acid may have an important functional role in the pollination process.
Fig. 4 Chemical structure of methyl nervonate (42).
Harvesting location plays a role in the metabolic profile, especially for PPAPs present
in the root bark extract. Indeed, Marti et al. [22] did not identify guttiferones A–D (1–4) described by Gustafson et al. [6], highlighting notable disparities in the metabolome of the species between those
two continents (harvested in May 2006 and March 1988, respectively). The collection
of different subspecies could eventually be considered the origin of the metabolic
disparities. Moreover, such differences in the nature of major metabolites are uncommon,
even for a single species growing in two different locations. As we pointed out, S. globulifera has a high rate of acclimatization and might adapt its defensive metabolites according
to, for example, the microbial environment. However, there is a need to clearly report
the phenomena, which requires further investigations.
Biosynthesis
All the secondary metabolites isolated from S. globulifera have the same biosynthetic origin ([Fig. 5]). The biosynthesis starts from shikimic acid to generate amino acids such as tyrosine
or phenylalanine [46].
Fig. 5 Biosynthesis pathway of S. globulifera secondary metabolites.
Phenylalanine is converted into cinnamic acid, by phenylalanine ammonia lyase (PAL)
[47]. Cinnamic acid can then follow two different pathways to generate either biflavonoids
or prenylated xanthones and PPAPs. Concerning biflavonoids, there is an early enzymatic
hydroxylation to convert cinnamic acid into 4-hydroxy-coumaric acid [48], [49]. A polyketide synthase generates then the phloroglucinol moiety of the chalcone
[50]. A chalcone isomerase is responsible for the cyclization of the chalcone into the
corresponding flavones [51], [52]. Two hypotheses can be cited for the biflavonoids biosynthesis, the chalcone, or
the flavonoid dimerization. Yamaguchi et al. [53] have highlighted the participation of some peroxidase enzymes to accomplish the
dimerization of flavones into biflavonoids. Some biomimetic syntheses of biflavonoids
validate this hypothesis [54]. Dimers are generated from monomers in the presence of an oxidant (potassium ferricyanide),
which is well known to be able to generate phenolic oxidative coupling.
The biosynthesis of xanthones and PPAPs also starts from phenylalanine being converted
into a phenyl-CoA moiety, which is reduced into protocatechuic acid. It has been shown
that coumaric acid, cinnamic acid, and phenylalanine were well incorporated during
xanthone-labeled biosynthesis experiments. As for the flavonoids, this moiety is subjected
to an enzyme-assisted hydroxylation to afford the catechol acyl-CoA, which is then
taken in charge by a PKS to generate the phloroglucinol part. The latter is finally
transformed in the polyhydroxylated benzophenone [55], [56], [57], [58]. This polyhydroxylated benzophenone is the starting point of both prenylated xanthones
and PPAPs.
This pathway is a major divergence between plants and bacteria/fungi. Indeed, xanthones
of the microorganism world are generally synthesized from full polyketides [59], [60]. Peters et al. pointed out evidence of enzymatic participation in the xanthone synthesis
from the polyhydroxylated benzophenone. The ring closure to generate the xanthone
core is mediated via a P450 cytochrome and a xanthone synthase, and occurs through
an oxidative coupling [61]. Atkinson and coworkers predicted the implication of a hydroxylated benzophenone
for the xanthone biosynthesis through a phenol oxidative coupling [62]. As for the biflavonoids dimers, these compounds can be obtained using potassium
ferricyanide as an oxidant. Further functionalization (hydroxylation, methoxylation,
prenylation) occurs once this xanthone core (synthesis) is obtained.
The hypothetic PPAPs biosynthesis has already been described by Kumar et al. [7] in their review on Garcinia species ([Fig. 6]). All compounds of this family (1 to 17) seem to be derived from maclurin (36), after being taken in charge by prenyl transferases. Several studies have been done
on hyperforin [63], [64], [65] to elucidate the mechanism and the sequence of crucial steps. Prenylation occurs
first on position 6, then on position 4, and finally one more on position 6. The nine-membered
ring is formed by a concerted mechanism where the next prenyl transfer involves an
intramolecular activation and cyclization leading to the unique backbone. This reactivity
was confirmed by some biomimetic syntheses [66]. In the presence of an oxidant, the prenylated acylphloroglucinol moiety can itself
be cyclized to generate the bicyclo[3.3.1]nonane-9-one skeleton.
Fig. 6 Biosynthesis of type B polycyclic polyprenylated acylphloroglucinols.
Further modifications can also be performed by the plant, such as additional prenylation,
hydroxylation, condensation into tetrahydropyran, or condensation in a more complex
cycle. Considering those side modifications and the different stereochemistry possibilities,
S. globulifera is able to produce a number of different analogs.
Symphonone H (14) belongs to the oxy-PPAPs family present in the Garcinia genus. The biosynthesis of such compounds has been discussed by several authors.
In 2008, Xu et al. identified two compounds structurally related, guttiferone L (43) and garciyunnanin B (44), in their study of G. yunnanensi and in the same organ (pericarp) [34]. As represented in [Fig. 7], the authors proposed a biosynthetic pathway for the conversion of guttiferone L
(43) into garciyunnanin B (44). Their hypothesis involves the unique 3,4,6-trihydroxyphenyl skeleton converting
into an intramolecular cyclization. The activation of the carbonyl in C-3 in enolate
leads to the subsequent condensation on the C-16 position with the loss of water and
formation of the xanthone. Even if this cyclization mechanism is possible, guttiferone
L (43) ([Fig. 7]) is, to date, the only tri-hydroxylated type B PPAP isolated, while several other
type of oxy-PPAPs (including trihydroxylated xanthones) have been found, suggesting
another mechanism and thus a poor probability of this pathway.
Fig. 7 Proposed pathways for the biosynthesis of oxy-polycyclic polyprenylated acylphloroglucinols.
In their recent study of thorelione A (45), Nʼguyen et al. [67] provided a mechanism involving a pseudo-Michael addition ([Fig. 7]). Their hypothesis is based on the attack of the free doublet of the enol C-3 in
the C-16 position of the aromatic ring. The delocalization of the negative charge
on the ketone followed by a return to aromaticity leads to the loss of a proton and
the formation of the oxy-thorelione A (46).
The third mechanism ([Fig. 7]) proposed by the Sang [40], [68] and Huang groups [33] involves a radical intermediate. The oxidation of the enolate to the enolate radical
results in the formation of a Car-O bond. These fully conjugated compounds allow for the delocalization to the mono
ketone form. The keto-enol equilibrium allows for the return on the most stable tautomer.
The free rotation of the acyl then allows the formation of the angular (C1–C16) and
linear xanthones (C3-C16) found in some other species such as G. indica
[34].
This mechanism is supported by the Huang group, who used the oxidants 2,2-diphenyl-1-picrylhydrazyl
(DPPH) or azo-bis-(isobutyronitril) (AIBN) ([Fig. 8]) that generate radical species and transformed garcinol (47) into the two corresponding xanthones 48 and 49.
Fig. 8 Synthesis of xanthones 48 and 49 using 2,2-diphenyl-1-picrylhydrazyl (DPPH) and azo-bis-(isobutyronitril) (AIBN).
In 1969, Atkinson et al. already reported this mechanism as a classical biomimetic
oxidative coupling leading to xanthones [62]. They managed to perform this oxidative coupling using potassium ferricyanide (known
as a radical donating reagent) with 2,3′-dihydroxybenzophenone, which is structurally
close to maclurin (37).
Recently, our group has selectively converted guttiferone A (1) into the corresponding oxy-PPAP, 3,16-oxy-guttiferone, and maclurin (36) into norathyriol (31) using yeast [41] ([Fig. 9]). This work involves an enzymatic reaction whose mechanism has not yet been defined.
Enzymes might also be responsible for the biosynthesis of these derivatives in plants.
In S. globulifera, symphonone H (14) is strongly related to 7-epi-garcinol (16), which is probably the biosynthetic precursor of this oxy-PPAP.
Fig. 9 Intramolecular cyclization of maclurin and guttiferone A.
Biological Activities
Phytochemical studies performed on the isolated metabolites of S. globulifera were extended to the study of their biological activities. Remarkably, a number of
them were performed on protozoal or microbial diseases. The potent biological activities
of these isolated molecules would confirm the traditional use of the plants ([Table 4]).
Table 4 Biological activities of S. globulifera secondary metabolites.
|
Antiplasmodial activity
|
|
|
|
IC50 (μΜ)
|
IC50 (μΜ)
|
|
No.
|
Name
|
P. falciparum W2
|
P. falciparum FcB1
|
|
1
|
Guttiferone A
|
3.17
|
–
|
|
5
|
14-Deoxy7-epi-isogarcinol
|
–
|
2.5
|
|
6
|
Symphonone A
|
–
|
2.8
|
|
7
|
Symphonone B
|
–
|
3.3
|
|
8
|
Symphonone C
|
–
|
2.6
|
|
9
|
7-epi-Coccinone B
|
–
|
3.3
|
|
10
|
Symphonone D
|
–
|
2.1
|
|
11
|
Symphonone E
|
–
|
2.7
|
|
12
|
Symphonone F
|
–
|
3.2
|
|
13
|
Symphonone G
|
–
|
2.1
|
|
14
|
Symphonone H
|
–
|
3
|
|
15
|
Symphonone I
|
–
|
6.7
|
|
16
|
7-epi-Garcinol
|
–
|
10.1
|
|
17
|
7-epi-Isogarcinol
|
–
|
3.2
|
|
21
|
Gaboxanthone
|
3.53
|
–
|
|
22
|
Globuliferin
|
1.29
|
–
|
|
23
|
Symphonin
|
3.86
|
–
|
|
Antioxidant activity
|
|
% Inhibition DPPH free radical
|
|
21
|
Gaboxanthone
|
28
|
|
|
22
|
Globuliferin
|
23
|
|
|
23
|
Symphonin
|
54
|
|
|
1
|
Guttiferone A
|
89
|
|
|
Antiparasitic activity
|
|
IC50 (μΜ)
L. donovani
|
|
1
|
Guttiferone A
|
0.16
|
|
|
26
|
Xanthone V1
|
1.4
|
|
|
Antimicrobial activity (minimum inhibitory concentration µg/mL)
|
|
|
|
Gram-positive bacteria
|
Gram-negative bacteria
|
|
|
|
S. aureus
|
B. subtilis
|
E. coli
|
|
18
|
Globulixanthone C
|
14.05
|
8.24
|
Inactive
|
|
19
|
Globulixanthone D
|
8
|
12.5
|
Inactive
|
|
20
|
Globulixanthone E
|
4.51
|
3.12
|
Inactive
|
|
–
|
Streptomycin
|
6.25
|
0.85
|
Inactive
|
|
Cytotoxic activity (IC50 KB cells µg/mL)
|
|
24
|
Globulixanthone A
|
2.15
|
|
|
25
|
Globulixanthone B
|
1.78
|
|
Antimalarial activity
Among the exhaustive list of NPs possessing such activity, polyhydroxyxanthones, oxygenated,
and prenylated xanthones, bixanthones and xantholignoids have been reported to potentially
be a novel class of antimalarial agents with enhanced efficacy on multidrug resistant
Plasmodium parasites. Seed shell extracts of S. globulifera contain three novel prenylated xanthones [gaboxanthone (21), globuliferin (22), symphonin (23)] and guttiferone A (1) ([Fig. 1]). Compound 1 possesses interesting antiplasmodial activities on P. falciparum W2 strains [21] ([Table 4]). This first study on the potential of S. globulifera part extracts led to the exploration of the bark roots and the identification of
12 new PPAPs. The new PPAPs were evaluated for their antimalarial activity [22] (P. falciparum FcB1) and presented good to moderate IC50 values ranging from 2.1 to 10.1 µM ([Table 4]).
Antioxidant activity
It has been proven that the Plasmodium infected red blood cells are under constant oxidative stress caused by exogenous
reactive oxidant species and reactive nitrogen species produced by the immune system
of the host and by the endogenous production of reactive oxidant species. Therefore,
compounds able to exhibit both antiplasmodial and antioxidant activities are promising
candidates as antimalarial agents. Thus, compounds 1, 21, 22, and 23 have been engaged in the free radical scavenging DPPH assay ([Table 4]). The xanthones (21, 22, and 23) possess a limited antioxidant activity, while guttiferone A (1) has shown the best activity with 89 % of inhibition of the DPPH radical.
Antileishmanial activity
The antiplasmodial activities of PPAPs and xanthones from S. globulifera mentioned before were confirmed, as they also possess interesting antileishmanial
properties. Guttiferone A (1) is the lead compound of the series [69] ([Table 4]). Furthermore, xanthone V1 (26) extracted from the leaves of S. globulifera also exhibits an interesting antiparasitic activity ([Table 4]). One of the major drawbacks of antileishmanial agents actually used in therapeutics
is their substantial cytotoxicity towards the host cells due to an evident lack of
selectivity. The relative cytotoxicity of compounds 1 and 26 was then evaluated towards normal rat skeletal muscles cells (L-6 cells). Interestingly,
the aforementioned compounds have demonstrated a low cytotoxicity (IC50 = 7.3 and 18 µM, respectively, [Table 4]) allowing consideration for future development against the Leishmania donovani parasite.
Antimicrobial activity
The bioguided isolation from S. globulifera extracts that exerted antimicrobial activity led to the identification of globulixanthones
C, D, and E (18–20). Compounds 18–20 were then tested for their antimicrobial effect on gram-positive (Staphylococcus aureus, Bacillus subtilis, Vibrio anguillarium) and gram-negative (E. coli) bacteria in an agar well diffusion assay [23]. As depicted in [Table 4], compounds 18–20 possess activities in the same range as streptomycin on gram-positive bacteria. However,
they possess no activity on gram-negative bacteria, suggesting a selective killing.
Biflavonoids 40 and 41 and xanthones 30 and 31 extracted from the stems of S. globulifera
[27] have also shown good antimicrobial activity.
Anticancer activity
Natural products have played a consequent role in this course as it is estimated that
20 % of anticancer drugs actually sold are derived from natural products. Root bark
extracts of S. globulifera have been shown to possess interesting cytotoxic activity and the bioguided extraction
led to the identification of globulixanthone A (24) and B (25) [24]. These two compounds were evaluated for their cytotoxic activity towards human epidermoid
carcinoma of the nasopharynx (KB cell line, [Table 4]). Compounds 24 and 25 possess good properties, but no mechanistic studies have been run to date.
Anti-HIV activity
PPAPs from Clusia torresii (clusianone, 7-epi-clusianone, 18,19-dihydroxyclusianone) have been proven to be
potent anti-HIV agents that act by inhibiting gp120-sCD4 interaction. This mechanism
of action denotes a probable interference with the viral attachment to the CD4 membrane
receptor implying an effect on infection. The MeOH extracts of S. globulifera have shown an activity in vitro toward HIV infected human cells (CEM-SS cells) [6]. The bioguided extraction has led to the identification of guttiferones A, B, C,
and D (compounds 1–4) as the active ingredients with an EC50 comprised between 1–10 µg/mL, but no indications of a corresponding decrease of viral
replication has been observed [6]. However, further mechanistic studies should be pursued.
Anti-FAS activity
Lipid biosynthesis is essential for the cell viability of all cellular living organisms
and is notably ruled by FAS (fatty acid synthase) activity. As differences exist between
the FAS of different organisms, FAS became an emerging target for diseases caused
by microorganisms such as fungi or bacteria [70], [71]. Two major types of FAS prevailed: type I exists in animal and fungi, and consists
in a single multifunctional polypeptide [73], while type II exists in bacteria and plants, and comprises several enzymes, each
of them assuring a step of the carbon chain elongation [72]. In a study aiming to identify new types of FAS inhibitors [31], ethanolic extracts of S. globulifera leaves were evaluated. The structural elucidation of the active compounds has led
to the first identification of morelloflavone (39) and GB-2 (40), two original biflavonoids. Compounds 26 and 27 were active against FAS prepared from Saccharomyces cerevisiae with IC50 values of 30 and 23 µg/mL, respectively.
Anticholinesterase activity
Acetylcholinesterase is a hydrolase responsible for the hydrolysis of acetylcholine
to acetate and choline. It is found mainly in neuromuscular junctions and synapses,
and plays a critical role in the transmission of nervous information. Its inhibition,
leading to an accumulation of acetylcholine and the blockade of neurotransmission,
is of importance notably for drug detoxification [74] or Alzheimerʼs disease treatment (improvement of cognitive function) [75]. Compound 1 isolated from S. globulifera is a potent inhibitor of acetylcholinesterase and butyrylcholinesterase [IC50 = AChE 0.88 μΜ (galanthamine = 0.5) and BChE = 2.77 μΜ (galanthamine = 8.5)] ([Table 4]).
Conclusion
Interest in S. globulifera has been growing for several years for two reasons: the bioactivity of its secondary
metabolites and a curious morphological diversification through times and sites. These
differentiations have probably induced variations in the metabolome in order for the
plant to adapt to the different African and American environments. A species able
to rapidly acclimate to its environment by adapting its metabolome is an obvious rich
source of new compounds and deserves to be studied in more detail. S. globulifera thus encloses various and complex secondary metabolites, such as PPAPs or flavonoid
dimers. Moreover, the possible biogenesis of complex xanthones through oxidative ring
closure from phloroglucinol derivatives is unprecedented. The traditional use by African
or South American populations was then confirmed by biological assays, highlighting
the impressive knowledge of nature gathered in those parts of the world, though still
understudied. All the secondary metabolites isolated from S. globulifera have shown moderate to good antimicrobial activities. Especially, guttiferone A,
a major metabolite and lead compound, presents an impressive panel of diverse biological
activities, and hemisynthetic derivatives have been proven to be potent antiparasitic
agents [76]. Finally, S. globulifera could be illustrated as the perfect example of the paradigm of modern phytochemistry:
a widespread source of complex metabolites with potent biological activities.
