Background
Although the malaria burden has decreased worldwide over the last 15 years, this mosquito-borne parasitic disease continues to cause high morbidity and mortality, particularly in children in Africa south of Sahara [
1]. According to World Health Organization (WHO) estimates, in 2016 there were about 195 million cases and 406,000 deaths in the African Region. Eighty percent of these cases and deaths occurred in 15 sub-Saharan countries and one-third in only two, namely Nigeria and the Democratic Republic of the Congo [
1].
Significant achievements in rolling back malaria have been obtained in areas of relatively low malaria transmission within countries which are socio-economically better off and/or capable to achieve a high coverage of the recommended key control tools, as insecticide-treated bed nets and artemisinin-based combination therapy (ACT). However, even countries which have been relatively successful may not be able to maintain their achievements in the fight against malaria. In fact, diffusion of insecticide resistance has reached alarming levels. In 2015, over three quarters of the 73 malaria endemic countries monitoring pyrethroid efficacy have reported resistance to this class of insecticides, used to treat the bed nets [
2]. Furthermore, malaria control attainments are threatened by the emergence and diffusion of artemisinin resistance, to date confirmed in five countries of the Greater Mekong sub-region in Asia [
3].
In this scenario, medicinal plant research may contribute to develop new pharmacological control tools pursuing the following objectives: (1) to identify new anti-malarial drug leads of plant origin, active against the asexual blood stages of Plasmodium, responsible for the disease, and/or against the stages responsible for its transmission, i.e. the gametocytes in the vertebrate host and the sporogonic stages in the mosquito; (2) to develop standardized, effective and safe anti-malarial phytomedicines (curative and transmission-blocking), based on a detailed chemical and biological characterization of plants.
Azadirachta indica (
Meliaceae), well known as neem tree and renowned as a medicinal plant able to cure a wide range of ailments, makes part of the pharmacopeia of various traditional medicine systems worldwide and is used in different African countries for the prevention and treatment of malaria [
4]. For the management of malaria fevers, homemade neem infusions from leaves and bark—also in combination with other plants—are frequently employed. Nowadays, several standardized, commercial preparations are available, as, e.g. neem tea bags (NEEM & MUARUBAINI 25S TEA BAGS) in Kenya and capsules containing fractionated leaf extract (IRACARP) in Nigeria [
5].
The perceived efficacy of
Azadirachta indica for the management of malaria fevers may in part be due to its antipyretic properties, reported for leaves, stem bark, roots and fruits [
6]. From a wide spectrum of experiments, conducted on various plant parts in vitro and in vivo, it emerges that the plant most likely harbours a variety of molecules able to interfere with the pathophysiology of fever, with the inflammatory response and with the regulation of humoral and cell-mediated immunity [
4].
Chemical and biological characterization studies allowed more than 300 neem compounds from various plant parts to be identified [
7], including at least 50 limonoids [
8]. Among these, in vitro anti-malarial effects have been evidenced for gedunin [
9], nimbin [
10], nimbolide [
10], azadirone and neemfruitin A [
11]. The latter two, isolated from
Azadirachta indica fruits, inhibit
Plasmodium falciparum (W2 chloroquine-resistant strain) schizogonic replication by 50% at a concentration lower than 2 μM [
11]. Azadirachtin—not active against blood stages—was found to interfere with early sporogonic development in the mosquito vector [
12,
13], inhibiting 50% of ookinete formation in vitro at about 17 µM [
14].
Most studies exploring the in vivo anti-malarial activity of
Azadirachta indica employed the 4-day suppressive test, which assesses impact on asexual blood stages multiplication (parasitaemia) in an infect-and-treat scheme. Results from leaves and bark extracts administered at relatively high dosages (0.2 to 1 g/kg) have been overall moderate, ranging from 0 to 80% suppression of parasitaemia in mice infected with
Plasmodium berghei or
Plasmodium yoelii (reviewed by Willcox and Bodeker [
4]). Preventive potential emerged from a ripe fruit ethanol extract that reduced parasitaemia by about 45% in mice treated for 9 days at 200 mg/kg/day [
15].
Taking into account the various anti-malarial effects demonstrated by
Azadirachta indica fruit preparations and considering literature evidence on the immune-modulatory properties of the plant [
4,
7], this study aims at exploring the effects of
Azadirachta indica fruits (seed kernel part) on the parasite-host association, considering the characteristics of the treated hosts’ reactions to parasitaemia. Accordingly, we measured matrix-metalloproteinase-9 (MMP-9) and tumour necrosis factor (TNF) levels as indicators of pro-inflammatory response activation in BALB/c and C57BL/6 mice, two strains exhibiting different immune competency characteristics [
16].
Methods
Plant material
The Azadirachta indica ripe and green fruits were collected near Farakoba, in Burkina Faso in May 2014 by R. S. Y. and Dr. Pascal Dipama of the Institut de Recherche en Sciences de la Santé (IRSS), Bobo Dioulasso. The plant was identified by Dr. Paulette Tahita (Institut de l’Environnement et de Recherches Agricole, Centre de la Protection des Végétaux) and deposited at the Unit of Parcelle expérimentale de l’IRSS Bobo Dioulasso, voucher number Azadirachta indica RF052014 and Azadirachta indica GF052014 for Azadirachta indica ripe and green fruits, respectively.
Epicarp and mesocarp parts were removed from both ripe and unripe Azadirachta indica fruits and peeled seeds grounded to obtain fine powders of the ripe and unripe fruit kernel. Fruit kernel powders were extracted with methanol (100 ml × 3 times) at room temperature for 24 h and then concentrated under vacuum to obtain the extracts for the biological experiments.
For chemical characterization, ripe fruit kernel powder (135 g) was repeatedly extracted with MeOH (1.5 l × 3 times) at room temperature for 24 h and then concentrated under vacuum to obtain a crude methanol extract (26 g). The obtained material was then partitioned between H
2O and Ethyl Acetate (EtOAc) to yield an organic extract (12 g). This was subjected to chromatography over silica column (230–400 mesh) eluted with a solvent gradient of increasing polarity from
n-hexane to EtOAc. Fractions eluted with
n-hexane/EtOAc 9:1 provided azadirone (120 mg) in pure state. Fractions eluted with
n-hexane/EtOAc 8:2 contained epoxyazadiradione and azadiradione (ca. 100 mg). Fractions eluted with
n-hexane/EtOAc 7:3 contained nimbin (100 mg). Fractions eluted with
n-hexane/EtOAc 6:4 provided deacetylnimbin (420 mg). Fractions eluted with
n-hexane/EtOAc 1:1 contained pure salannin (376 mg). Finally, fractions eluted with increasing polarity from
n-hexane/EtOAc 5:5 to 2:8 gave a mixture of azadirachtin A and analogues (ca. 1 g). The same procedure was repeated with the powder (130 g) of unripe fruit kernel to obtain a crude methanol extract of 24 g. Separation of the EtOAc phase (12.6 g) of unripe fruit provided the same metabolites and the same amounts compared to ripe fruit with the following exceptions: (a) nimbin was practically undetectable in unripe fruit; (b) deacetylnimbin was consistently less abundant in unripe fruit (300 mg); (c) salannin was more abundant in unripe fruit (451 mg) than in ripe fruit. Chromatogram of methanol extract from neem fruit kernel is shown in Additional file
1.
Animals
Two inbred mouse strains with different immune response characteristics, namely BALB/c and C57BL/6, were chosen for this study. On the basis of differences in their respective Major Histocompatibility Complex [
17], the former is a prototypical Th2 response strain, while the latter is prone to develop a Th1 type of response [
16].
The BALB/c mice were reared and maintained under standard conditions at 24 °C of temperature, 14 h light/10 h dark cycle and 70% humidity in the animal facility of the University of Camerino (Italy). The C57BL/6 mice were purchased from ENVIGO Laboratories, Inc., (Udine, Italy) and maintained under the same standard conditions as described above.
This study was carried out in accordance with the recommendations of the Italian Legislative Decree on the “Use and protection of laboratory animals” (D. Lgs. 116 of 10/27/92) and in full adherence with the European Directive 2010/63/UE, adopted on 22nd September, 2010. The protocol was approved by the University Research Ethics Committee of the University of Camerino—protection of animals used for experimental and other scientific purposes (protocol number: UREC_CAM_2015/18).
Parasite strain
The chloroquine sensitive
Plasmodium berghei strain ANKA was used to assess the in vivo effects of the neem extracts. The ANKA strain, specific for rodent hosts, is widely employed in anti-malarial drug discovery studies [
18] and is lethal for both, BALB/c and C57BL/6 mice. This parasite strain is routinely maintained in the laboratory of parasitology at the University of Camerino by mouse to mouse (acyclic) and mouse to
Anopheles stephensi mosquito (cyclic) passages. Blood aliquots from mice infected after cyclic passage are stored at − 120 °C in liquid nitrogen using haematocrit capillaries.
Assessment of parasitaemia progression in BALB/c and C57BL/6 mice
The development of parasitaemia was comparatively assessed in BALB/c and C57BL/6 mice. Five to six mice per strain were i.p. infected with 107 P. berghei-infected red blood cells (iRBCs) and parasitaemia was measured daily on Giemsa-stained blood smears, starting from day 3 until mice began to show general signs of illness such as ruffled fur, squinted eyes, hunched position and reluctance to move. These signs started appearing on day 12 for BALB/c and on day 9 for C57BL6 mice. Thin blood smears were prepared using a drop of blood from the tail tip. After fixation of the smears with methanol, slides were stained with 10% Giemsa diluted in PBS (pH 7.3) for 60 min. Percent parasitaemia was determined by enumerating infected and un-infected RBCs over three optical fields (1000× magnification) with at least 200 RBCs per field.
Four-day suppressive test
To assess the in vivo activity of kernel methanol extracts (ME) on parasitaemia of
P. berghei in BALB/c and C57BL/6 mice, the 4-day suppressive test was employed [
19]. Briefly, healthy female donor mice (3 BALB/c and 3 C57BL/6) were inoculated intraperitoneally (i.p.) with parasitized blood from freshly thawed haematocrit capillaries. Mice parasitaemias were assessed at day 5 to 6 post-infection and animals with parasitaemia ranging between 2 and 5% were selected as blood donors for the infection of experimental mice. At day zero, 28 female BALB/c and 28 female C57BL/6 mice (6 week old) were i.p. injected with 10
7 iRBCs each from donor mice, diluted in 200 μl of PBS. After infection, mice of each strain were randomly divided into 4 groups of six animals and treated orally as follows: group (a) control, treated with solvent (H
2O containing 10% DMSO and 5% Tween 80); group (b) artesunate 10 mg/kg; group (c) ripe fruit kernel ME 150 mg/kg and group (d) unripe fruit kernel ME 150 mg/kg. A total of 4 treatments were effected from day 0 to day 3 by oral gavage (200 µl/mouse/treatment). The first treatment was given 2 h post infection. Parasitaemia of individual mice was evaluated at day 4 post infection by microscopic examination of Giemsa-stained blood smears as described above.
Plasma level determination of matrix-metalloproteinase-9 (MMP-9) and tumor necrosis factor
At the end of the 4 days suppressive test, blood was collected from each experimental mouse by heart puncture, using heparinized (1000 IU/ml) 1 ml insulin syringes, and their plasma isolated by centrifugation at 3000 rpm for 10 min. Plasma levels of MMP-9 were measured by a sandwich ELISA commercial kit (Raybiotech, Norcross—Georgia, USA), which employs a biotinylated monoclonal antibody specific for both the pro- and the active forms of MMP-9, with a threshold sensitivity of 50 pg/ml. Plasma levels of TNF were assessed by a similar sandwich ELISA kit (eBioscience Inc., San Diego, California, USA), based on a biotinylated monoclonal antibody specific for the mouse TNF cytokine, with a threshold sensitivity of 8 pg/ml. Plates were read with a Victor3® Multilabel Plate Reader (Perkin-Elmer) at 450 nm.
Statistical analysis
Parasitaemia values of treated and control mice were compared employing GraphPad PRISM 5 software and using the parametric unpaired t test. The enzymes’ plasma levels were compared by a two-ways ANOVA, using as post-test the Bonferroni analysis and by Dunnett’s Multiple Comparison Test. Significant differences were considered when p < 0.05.
Discussion
With the aim of exploring the biological effects of neem preparations on parasite-host interactions, two genetically different mouse strains, i.e. C57BL/6 and BALB/c, known to be prone to develop a Th1 response and a Th2-biased adaptive immune response, respectively, were employed. The mouse malaria parasite
P. berghei causes lethal infections in both strains, but C57BL/6 mice tend to die of cerebral malaria while BALB/c mice prevailingly show severe anaemia and prostration [
20].
Comparing the course of
P. berghei blood stage infection in the two mouse strains, similar levels of parasitaemia were observed in the initial phase of infection. On day 4 after i.p. inoculation of infected red blood cells, parasitaemia measured in BALB/c and C57BL/6 mice amounted 9.9% and 13.1% (preliminary, comparative experiment) and 6.5% and 7.5% (control groups of the neem study). However, from day 6 to 9, C57BL/6 mice showed a rapid increase in parasitaemia and signs of clinical illness, whereas BALB/c mice displayed a slower parasite proliferation and signs of disease only by day 12. Very similar patterns of parasite proliferation have been observed in the two mouse strains in other studies conducted with
P. berghei [
21,
22] and with
Plasmodium yoelii [
23]. Exploring cytokine response in the course of
P. berghei infection, the relatively slower parasite proliferation in BALB/c mice during the second week of infection has been associated to markedly higher levels of the Th2 cytokines, namely IL4 from day 5 of infection and IL10 from day 7 onwards, indicating the onset of a Th2-orchestrated humoral response in this mouse strain [
22].
In this study, TNF levels, measured on day 4 after infection, resulted notably lower in BALB/c than in C57BL/6 mice, irrespective of the treatment group. This indicates different, specific patterns of innate immune response to infection with
P. berghei in the two mouse strains. A strain-specific early immune response has been observed also with
Chlamidia muridarum, a bacterial agent causing pulmonary infections in mice [
24]: 2 days after nasal infection, recruitment of macrophages and myeloid dendritic cells in the lung was found to be significantly higher in C57BL/6 than in BALB/c mice. When cytokine production by peritoneal macrophages was explored in these two mouse strains, notably higher TNF production was observed in lipopolysaccharide or MALP-2 (synthetic lipopeptide) stimulated macrophages from C57BL/6 mice than in those from BALB/c [
16].
After i.p. inoculation of infected blood in healthy mice, elimination of
Plasmodium infected erythrocytes occurs mainly in the spleen by cells of the monocyte-macrophage lineage [
25]. Studies conducted with
P. yoelii in various mouse strains showed that IFN-γ and TNF are essential for macrophage activation and early control of parasitaemia, as these cytokines are produced already 24 h after infection by γδ T lymphocytes and natural killer cells [
26].
In vivo findings of higher plasma levels of TNF in P. berghei-infected C57BL/6 as compared to uninfected mice are fully in line with the above-quoted results.
Besides confirming the findings of TNF levels generally higher in C57BL/6 mice than in BALB/c mice, our experiments showed that C57BL/6 mice treated with methanol extract from seed kernel of Azadirachta indica unripe fruits had higher TNF and markedly higher MMP-9 levels than the other treatment groups. Interestingly, in this treatment group a slight decrease of parasitaemia was observed 4 days after infection and after 4 days of treatment. On the basis of the summarized knowledge on early unspecific immune response, this result may indicate an adjuvant-like effect of the plant preparation, enhancing initial pro-inflammatory response and/or macrophage activation.
Both extracts obtained from seed kernels of ripe and unripe fruits are a very complex mixture of secondary metabolites, dominated by limonoids, a class of highly oxidized tetranotriterpenes, usually characterized by complex polycyclic structures. The preliminary investigation of the limonoid content of
Azadirachta indica seed kernel revealed some significant differences according to their stage of maturation. This is not surprising, having been already observed for limonoids of other plants [
27]. More specifically, in our study the extract from unripe fruits showed a higher amount of salannin and a much lower amount of nimbin/deacetylnimbin than that detected in the ripe fruit. It can be hypothesized that these differences are responsible for the observed differential effect on parasitaemia and pro-inflammatory response in C57BL/mice, although the contribution of complex synergic effects cannot be evaluated at this stage.
The fact that
Azadirachta indica extracts increase the levels of MMP-9 as well as of TNF are apparently contradictory with the observed antipyretic effects of leaves, stem bark, roots and fruits from this plant. Information on traditional use of neem (leaves, stem bark roots and fruits) as an antipyretic stems from the ethnobotanical studies conducted in India [
6]. Re-looking at the original paper, it is difficult to sort out the question since it is not specified whether ripe or unripe fruits are used. On the basis of these results it is plausible that traditionally ripe fruits are employed.
Immuno-modulatory properties have been reported for various parts of
Azadirachta indica, such as leaves, fruits and barks. For example, neem seed oil (also rich in limonoids) injected i.p. in BALB/c mice was found to increase peritoneal leukocyte counts, enhance the phagocytic activity of macrophages and induce the production of IFN-γ by spleen cells [
28]. Weekly administration of a neem leaf preparation for 1 month to Swiss albino mice was found to increase total red blood cell, white blood cell and platelet counts at all experimental doses. In addition, an increase of spleen T lymphocytes (CD4+ and CD8+) and NK cells was observed in neem treated mice [
29].
Immuno-modulatory effects have been also reported for other plants and have been associated to compounds biogenetically different from limonoids. For example, anti-inflammatory effects have been reported for
Punica granatum, a plant traditionally used in India to treat malaria. A tannin rich fraction of the fruit and the isolated constituents ellagic acid and punicalagin inhibited MMP-9 expression and secretion in human THP-1 monocytic leukaemia cells, fed with haemozoin or TNF [
30]. Since the same fraction and constituents inhibited the in vitro growth of
P. falciparum asexual blood stages [
31], the authors suggested that
Punica granatum treatments may be beneficial to manage uncomplicated malaria disease and limit the risk of onset of cerebral malaria by controlling the excessive inflammatory response of the host [
30].
Exploring the potential of
Azadirachta indica for the management of leishmaniasis, both, anti-protozoan and immune-modulatory effects have been detected on infected mononuclear cells treated with an ethyl-acetate fraction of neem leaves [
32] and with ethanol extracts from neem leaves and seeds [
33]. This latter extract exerted anti-amastigote activity in RAW 264.7 cells (macrophage-like cell line), while both extracts reduced organ parasite burden in the liver and spleen by more than 80%. Spleen cells from infected BALB/c mice treated with the two extracts were found to produce higher levels of Th1 cytokines TNF, INF-γ and IL-2 in comparison with infected controls [
33].
Taken together, the results obtained in this study with the rodent malaria model and those discussed on immunomodulatory effects of neem preparations evidence the potential of Azadirachta indica for the management of complex parasitic diseases in which the parasite-host balance is determined by the host’s capacity to mount an adequate immune response, avoiding both immune evasion, as a result of an excess of suppression, and immuno-pathological responses, as a result of an excess of activation.
The obtained results could suggest to the reader a possible direct effect of MMP-9 on parasite survival, since this enzyme increases in animals with lower parasitaemia, but further studies are needed to prove this. Furthermore, in this study Th1 response was not evaluated, but only a pro-inflammatory innate one.
Aiming at the design of a neem phytomedicine able to prevent clinical episodes of malaria, in vitro characterization of neem fractions and isolated constituents on haemozoin-fed human THP-1 monocytic leukaemia cells [
30] may allow to identify candidate fractions and molecules able to stimulate innate immunity, known to be essential in the clearance of
Plasmodium blood stages. As emerged from this study, in vivo validation of candidates must involve different rodent
Plasmodium species and genetically diverse mouse strains, in order to account for heterogeneity of parasite-host interactions.
Authors’ contributions
AH and FB planned the study. AH, FE, FB, ST wrote the manuscript. ST, JN, MS, BP conducted the experimental work and ELISA assays. RSY provided the Azadirachta indica plant material and GC, AL, OT prepared the extracts and conducted the chemical analysis. ART, OT, BP participated in the revision of the manuscript. BP carried out the statistical analyses. All authors read and approved the final manuscript.