- Open Access
Allicin enhances host pro-inflammatory immune responses and protects against acute murine malaria infection
© Feng et al.; licensee BioMed Central Ltd. 2012
Received: 6 May 2012
Accepted: 22 July 2012
Published: 8 August 2012
During malaria infection, multiple pro-inflammatory mediators including IFN-γ, TNF and nitric oxide (NO) play a crucial role in the protection against the parasites. Modulation of host immunity is an important strategy to improve the outcome of malaria infection. Allicin is the major biologically active component of garlic and shows anti-microbial activity. Allicin is also active against protozoan parasites including Plasmodium, which is thought to be mediated by inhibiting cysteine proteases. In this study, the immunomodulatory activities of allicin were assessed during acute malaria infection using a rodent malaria model Plasmodium yoelii 17XL.
To determine whether allicin modulates host immune responses against malaria infection, mice were treated with allicin after infection with P. yoelii 17XL. Mortality was checked daily and parasitaemia was determined every other day. Pro-inflammatory mediators and IL-4 were quantified by ELISA, while NO level was determined by the Griess method. The populations of dendritic cells (DCs), macrophages, CD4+ T and regulatory T cells (Treg) were assessed by FACS.
Allicin reduced parasitaemia and prolonged survival of the host in a dose-dependent manner. This effect is at least partially due to improved host immune responses. Results showed that allicin treatment enhanced the production of pro-inflammatory mediators such as IFN-γ, TNF, IL-12p70 and NO. The absolute numbers of CD4+ T cells, DCs and macrophages were significantly higher in allicin-treated mice. In addition, allicin promoted the maturation of CD11c+ DCs, whereas it did not cause major changes in IL-4 and the level of anti-inflammatory cytokine IL-10.
Allicin could partially protect host against P. yoelii 17XL through enhancement of the host innate and adaptive immune responses.
Malaria with its ~250 million clinical cases and a human death toll of 0.9 million per year remains a huge problem in many tropical and subtropical countries. To realize the ambitious goal of malaria elimination, novel integrated strategies are needed. Among them, vaccines to reduce the morbidity and mortality associated with malaria have been intensively pursued, but so far no malaria vaccine is available. Vaccine development efforts are thwarted partially by incomplete understanding of the mechanisms of protective immunity against malaria, which normally develops in populations residing in hyperendemic areas after repeated exposure to malaria infections.
To identify the key targets and mechanisms of protective immunity against malaria, experimental murine malaria models have significantly advanced our understanding of how Plasmodium parasites interact with the host immune responses in vivo. It has become evident that Th1 type pro-inflammatory immune responses are essential for controlling the parasite load during the early phase of infection[3–5]. Protective CD4+ T cells release IFN-γ to activate effector cells such as macrophages, which may exert anti-malarial effects by releasing TNF and nitric oxide (NO)[6, 7]. NO can reduce parasitaemia during the initial phase of blood-stage malaria infection[8, 9]. During malaria infection, regulatory T cells (Treg) can expand and suppress the establishment of Th1 immune response, resulting in increased parasitaemia and mortality of the host[11, 12]. Dendritic cells (DCs) are critical players in innate immunity and priming T cell-dependent, specific immune responses to malaria infection. DCs activated in the spleen are major antigen-presenting cells (APCs), and also a source of cytokines that help shape up cell-mediated and humoral immunity[13, 14]. Therefore, immunomodulatory drugs that improve the functions of DCs may lead to enhanced immunity against malaria parasites.
Many natural products possess immunomodulatory activities, which have long been sought for treating human diseases. Garlic (Allium sativum) is one of the most ancient vegetables and its medicinal uses are dated back > 5,000 years. Garlic possesses evident pharmacological properties, such as antimicrobial[16, 17], antioxidant[18, 19], and anticancer activities[20, 21]. Garlic and its components have potent antiparasitic activities against many human and animal parasites, such as Leishmania[23, 24], Schistosoma[25, 26], Trypanosoma, Giardia, Entamoeba[27, 28], and Plasmodium[29, 30]. Allicin (diallyl thiosulfinate), rapidly converted from allin by allinase in crushed fresh garlic cloves, is a major component and thiosulphinate compound responsible for the biological activity of garlic. A recent study reported that the potent anti-plasmodial and anti-trypanosomal activity of allicin is associated with its inhibitory effect on the cysteine proteases of the parasites. In addition to the proclaimed nutritional and antimicrobial effects, garlic has immunomodulatory activities[15, 34]. As an immune stimulant, garlic components stimulate the proliferation of splenocytes[34, 35] and synthesis of NO and TNF[36, 37]. However, under certain circumstances, allicin or garlic extract may also work as an immune suppressant to down-regulate inflammatory responses and inhibit the interaction of T cells with the endothelial cells.
Although the anti-parasitic effects of garlic extract and allicin have been investigated, little is known about the immunomodulatory effects of garlic on parasitic infections. In Leishmania major-infected susceptible mice, treatment with garlic extract promoted the shift towards a Th1 response and enhanced the phagocytic activity of peritoneal macrophages, which significantly improved the disease outcome[39, 40]. Here, the murine malaria model was used to investigate the effects of allicin on the course of infection of BALB/c mice with the lethal strain of Plasmodium yoelii 17XL. The results indicated that allicin treatments promoted the production of pro-inflammatory mediators and protected the host from Plasmodium infection.
Mice, parasite, and infection
Female, six to eight weeks old, BALB/c mice were purchased from Academia Sinica Shanghai experimental animal centre. Plasmodium yoelii 17XL infections were initiated by intraperitoneal (IP) injection of 1 × 106P. yoelii 17XL parasitized red blood cells (pRBCs) per mouse. Parasitaemia was determined every other day by light microscopic examination of at least 1,000 erythrocytes on Giemsa-stained blood smears. Mortality was checked daily. All experiments were performed in compliance with local animal ethics committee requirements.
Allicin was purchased from Jinkongfu Pharmaceutical (Wuhan, China). The stock solution was prepared by dissolving allicin in ethanol at a concentration of 10 mg/ml. It was diluted to 1 mg/ml with phosphate buffered saline (PBS) before use. For animal experiment, BALB/c mice were randomly divided into three groups. Allicin was orally administered by gavage at a dose of 3 or 9 mg/kg/day on days 0–2 post-infection (PI). Mice in the control group received 0.2 ml PBS at the same time points. Three mice in each group were sacrificed on day 3 and 5, respectively. The experiment was repeated three times.
Spleen cell culture and quantification of cytokines
Spleens from BALB/c mice were removed aseptically and splenocytes were cultured as previously described. Splenocytes were adjusted to a final concentration of 1 × 107 cells/ml in RPMI1640 supplemented with 10% heat-inactivated foetal calf serum (FCS). Aliquots of the cell suspension (5 × 106 cells/well) were seeded into 24-well, flat-bottom, tissue culture plates in triplicate, and incubated for 48 hr at 37°C in a humidified 5% CO2 incubator. The supernatants were collected and stored at −80°C until assayed for cytokines.
Levels of IFN-γ, TNF, IL-12p70, IL-4 and IL-10 were measured by commercial enzyme-linked immunosorbent assay (ELISA) kits according to the manufacturer's protocols (R&D Systems, Minneapolis, MN, USA). As a measure of NO production, concentrations of NO2- in cell culture supernatants were determined by the Griess reaction.
At the indicated time points, splenocytes were obtained from infected BALB/c mice for flow cytometric analysis to determine the subsets of spleen DCs: CD11c+CD11b+ myeloid DCs (mDCs) and CD11c+CD45R/B220+ plasmacytoid DCs (pDCs), the population of CD11c+DCs expressing MHCII or TLR9, macrophages and Treg. Antibodies and their sources were described previously. Flow cytometry was performed on a FACS Calibur (BD Biosciences, San Diego, CA, USA) and analysed using the FlowJo software (Treestar, San Carlos, CA, USA).
For each experiment, three mice were used to obtain an average, and the average values from three experiments were used to calculate the mean and standard error (SEM). Statistical analysis was performed by one-way ANOVA using the statistical software SPSS version 16.0. Fisher’s LSD post-hoc test was applied to assess differences of each group. Time-to-event data were statistically analysed with the Kaplan-Meier approach to survival analysis using the statistical software SPSS version 16.0. P values less than 0.05 were considered statistically significant.
Allicin improves survival by reducing parasitaemia
Allicin preferentially enhances pro-inflammatory immune responses
Allicin treatments stimulate expansion of CD4+ T cells and macrophages
Allicin treatments promote the activation of dendritic cells
Maturation of DCs is essential to induce Th1 immune response for antigen presentation to T cells. To study whether allicin treatment had any effect on activation of DCs, the numbers of DCs expressing MHCII and TLR9 between the control and treatment groups were compared. Infection with P. yoelii 17XL significantly increased the total numbers of mature DCs expressing MHC II on day 3 PI, but no significant difference was observed among the treatment groups (Figure 5C). On day 5 PI, however, 9 mg/kg allicin treatment group produced significantly more MHC II-expressing DCs than control (P < 0.05) or 3 mg/kg allicin treatment group (P < 0.01) (Figure 5C). Analysis of TLR9-expressing DCs revealed a similar trend as that of the MHCII-expressing DCs (Figure 5D). Collectively, these results indicate that allicin treatment at 9 mg/kg promoted expansion of matured DCs and enhanced TLR9-mediated innate immune activation on day 5 during P. yoelii 17XL infection.
Allicin has no effect on IL-10 production or Treg
Allicin, a sulphur compound produced in garlic, has antibacterial, antifungal and antiparasitic activities. The main mechanism and mode of action of allicin is generally considered to be its reaction with the SH group on cysteine residues of enzymes in the pathogens, resulting in their inactivation[52, 53]. The antiparasitic activity of allicin on Plasmodium and Trypanosoma was attributed to the inhibition of cysteine proteases in these parasites. Previous studies have shown that allicin inhibited P. berghei circumsporozoite protein processing and prevented sporozoite invasion of host cells in vitro as well as protected the P. berghei-infected mice from early death[30, 54]. This study assessed the immunomodulatory effect of allicin on P. yoelii 17XL-infected mice. The results showed the anti-malarial activity of allicin in P. yoelii 17XL infected mice was partially due to its enhancement of the pro-inflammatory immune response by expanding the populations of CD4+ T cells, mDCs and macrophages as well as stimulating DCs maturation.
Pro-inflammatory mediators play an important role in controlling parasitaemia at the early stage during P. yoelii 17XL infection[6, 11, 55, 56]. Expansion of macrophages and elevated TNF level are critical for controlling parasitaemia, while IFN-γ forms a central mediator of protective immune responses against pre-erythrocytic and blood-stage malaria parasites. During the acute phase of malaria infection, native T cells may be stimulated to produce IFN-γ and TNF. Allicin treatment significantly elevated the levels of these pro-inflammatory mediators (IFN-γ, TNF and NO) in a dose-dependent manner in P. yoelii 17XL-infected BALB/c mice, consistent with allicin’s function as an immune stimulant[34–37]. To a lower extent, allicin treatment also enhanced the production of IL-12p70 of cultured spleen cells, another indicator for enhanced Th1 response. Finally, allicin treatment stimulated expansion of CD4+ T cells, which further supports the activation of Th1 immune response. As a hallmark of Th2 immune response, IL-4 level in allicin treated mice was comparable to that in control mice, indicating that allicin treatment did not affect Th2 immune response during early P. yoelii 17XL infection.
DCs bridge the innate and adaptive immune response as APCs via antigen presentation to helper T cells, which can activate native T cells and polarize CD4+ T cells response. Stimulation of T-cell responses, and more importantly, induction of Th1 cell development, is associated with maturation of DCs as well as their production of Th1 cytokines[61, 62]. Thus, the strategy to improve the maturation and activation of DCs is key to the initiation of a protective immune response against malaria infection. The results suggested that allicin treatment could significantly promote the maturation of DCs with increasing expression of the co-stimulatory molecules.
Toll like receptors (TLRs) expressed on the innate immune cells (such as DCs) engaged in the recognition of constituents of protozoan parasites[63, 64]. Upon TLR-driven activation, DCs produce pro-inflammatory and protective cytokines that contribute to innate immunity. TLR9 mediates innate immune activation by the malaria haemozoin and protein-DNA complex. TLR9 mediates parasite recognition and initiates IFN-γ production to prime host innate responses against malaria[67, 68]. In summary, allicin could expand the population of TLR9-expressing DCs, resulting in increases of the IFN-γ level.
Another aspect of allicin’s immunomodulatory effect is down-regulation of pro-inflammatory response. Allicin could reduce the TNF level in a dose-dependent manner and suppress both spontaneous and TNF stimulated secretion of cytokines IL-1, IL-6 and IL-8[38, 69]. This is largely due to regulation of the host Treg and anti-inflammatory cytokine IL-10. Depletion of Treg protects BALB/c mice infected with P. yoelii 17XL from overwhelming parasitaemia and death. Therefore, Treg provide an essential mechanism for the parasites to evade host-mediated immunity. In addition, TLR9 engagement in DCs is required for natural Treg activation by malaria parasites. The higher dose of allicin treatment increased the TLR9 expression on DCs on day 5 PI, which in turn increased the number of Treg. However, the level of IL-10 was not correspondently elevated, suggesting that allicin treatment did not drastically modify the function of Treg during the acute malaria infection.
In summary, allicin treatment can protect host against malaria infection by activating pro-inflammatory immune responses in a dose-dependent manner. The immune-stimulatory effect of allicin is characterized by induced mature DCs during early phase of P. yoelii 17XL infection, which leads to increased levels of pro-inflammatory mediators from proliferative macrophages and CD4+ T cells. The results provide important insights into the in vivo parasite-inhibitory mechanism of allicin, which suggests the involvement of both direct inhibition of parasite enzymes and stimulation of antiparasitic immune response of the host.
Allicin treatment could enhance host immunity against malaria infection in a rodent malaria model. It was observed that treatment with allicin during P. yoelii 17XL infection could enhance host innate and adaptive immunity evidenced by elevated numbers of macrophages and CD4+ T cells and cytokines. In addition, allicin treatment promoted the expansion and maturation of DCs, which play an essential role in initiating adaptive immunity. However, the function of Treg was not altered by allicin treatment. Collective findings from this study suggest that allicin partially protects host against malaria infection through enhancement of the host’s innate and adaptive immune responses.
This work was supported by grants from the National Natural Science Foundation of China (30800962).
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