Background
Plasmodium vivax is widely distributed around the world, with more than 2.5 billion subjects exposed to risk of infection.
Plasmodium vivax malaria is highly prevalent in Latin America, Asian and some Pacific regions [
1]. In the past,
P. vivax was considered the causative agent of “benign malaria” and was associated with low lethality. However, after several reports of severe forms of
P. vivax malaria, this assumption has been challenged [
2,
3]. Recent studies have shown that vivax malaria can be associated with a spectrum of severe syndrome, with risk of death similar to that observed for
Plasmodium falciparum infection [
4‐
9].
In Brazil, the Amazon region concentrates almost all cases of
P. vivax infections registered countrywide, with more than 300 thousand cases per year [
10]. Although the Amazon region has low transmission levels as compared to other regions in sub-Saharan Africa, the most affected population in the Amazon Basin are adults and the incidence of complications has been already reported [
11,
12].
The recurrence of
P. vivax malaria is a phenomenon that commonly occurs within a few months after the treatment of primary infection. The recurrence is defined as the reappearance of asexual forms of the parasite in the blood, up to 6 months after post-therapeutic monitoring period [
13]. Usually, relapse/recrudescence may also occur for different reasons such as resistance of the parasite to the chemotherapy used [
14], therapeutic failure, non-adherence to the treatment [
15] and reactivation of the hypnozoites [
16]. Recurrence has been rather considered a new malaria episode occurring in endemic areas after effective therapeutic intervention [
17].
Although the mechanisms underlying the recurrence of are still unknown, cases of “recurrent malaria” are usually associated with impaired clinical recovery and higher morbidity, worsening the socio-economic impact of the disease [
18‐
20]. From the epidemiologic point of view, it is likely that the recurrence favors the maintenance and transmission of the parasite, considering the early and continual presence of sexual forms of the
P. vivax [
21].
Several evidences suggest that an exacerbated inflammatory response associated to a high parasitaemia is likely to aggravate the malaria symptoms [
22‐
27]. The exacerbated activation of the host immune system, especially T-lymphocytes is the core factor to the severe malaria pathogenicity, related to the high and out of proportion levels of the pro-inflammatory cytokines, which can be observed during the erythrocytic phase of the parasite life cycle [
9,
28‐
30]. In general, the severity of the disease has been associated with high systemic levels of IFN-γ and TNF [
31‐
33]. In the
P. vivax malaria, the simultaneous increase of the TNF, IFN-γ and IL-10 has been correlated to disease progression towards a severe clinical outcome [
9,
34,
35].
Counterbalancing the exacerbated inflammatory response that induces immunopathological mechanisms [
28], the host immune response develops modulatory events, especially in the lymphocytic compartment [
36‐
40]. It stands out the role of the regulatory T-cells (Treg), which may act as an important key both to the homoeostatic balance and to the control of the immunopathogenesis through the modulation of the excessive inflammatory response [
41]. Treg cells are necessary to control the cellular immune response through a direct contact with the effector immune cells and by the production of regulatory cytokines including IL-10 and TGF-β [
42‐
44]. Furthermore, anti-inflammatory cytokines, included as IL-10, have been found to regulate type 1 responses during infection during a secondary parasitic challenge in the best available mouse model for human severe malaria, demonstrating a regulatory role in the control of pathogenic responses [
44].
Nevertheless little information regarding the immunological events underlying the recurrent malaria episodes are currently available. In the present study, the ex vivo phenotypic features of circulating leukocyte subsets as well as the plasmatic cytokine profile were assessed, aiming at establishing patterns of immune response characteristic of recurrent malaria.
Methods
Study population
This was a cross-sectional study performed during 10 months with malaria patients seeking for healthcare at the Ambulatory of the Fundação de Medicina Tropical Dr. Heitor Vieira Dourado (FMT-HVD), Manaus, Amazonas State, Brazil. The selection of malaria patients was performed by convenience, excluding individuals with chronic/degenerative diseases or pregnant women. Only those patients with positive microscopic diagnosis of
P. vivax infection with parasitaemia higher than 500 parasite/mm
3 were included in the study. Two sets of patients were selected for this study: patients with “primary malaria” and “recurrent malaria”. The inclusion criteria for cases of
P. vivax “recurrent malaria” were defined as patients that presented new malaria infection within a six-month interval apart from the last episode. The occurrence of relapse/recrudescence episodes was minimized, since all patients with “recurrent malaria” underwent therapeutic regimens as recommended by the Brazilian Ministry of Health to
P. vivax malaria (chloroquine for 3 days and primaquine for 7 or 14 days) [
45‐
48], with strict follow-up after treatment to monitor therapeutic effectiveness, according to FMT-HVD guidelines for cure-monitoring. The periodic cure-monitoring consisted of microscopic examination of thin and thick blood smears during the first 2 months (2, 4, 7, 14, 21, 28, 40 and 60 days) after the initiation of treatment. In cases of positive microscopic results after the maximum time limit specified above, but before 6 months, the patients should be classified as new cases or “recurrent malaria”. Using this criterion, 13 patients with presumed “recurrent malaria” were excluded, as they reported presented parasitaemia levels lower than 500 parasite/mm
3.
Fifty-five patients with
P. vivax mono-infection [
49], age ranging from 16 to 70 years, 39 males and 16 females, all presenting negative serology for dengue virus infection, were selected to compose the malaria group. Upon clinical evaluation, malaria patients were categorized into two subgroups referred as: “primary malaria” (n = 36) and “recurrent malaria” (n = 19).
Twenty healthy subjects, resident in the same geographic area was enrolled as the “endemic control” group, with age ranging 19–48 years, nine man and 11 women.
Ethical issues and blood sampling
This study was approved by the Ethics Committee and the Superior Council at FMT-HVD (CAEE process #0044.0.114.000-11). Each participant read and signed the written informed consent form. EDTA whole blood samples (5 mL) were collected from each participant. All patients were treated according to the recommendations provided by the Brazilian Ministry of Health.
Assessment of Plasmodium vivax mono-infection status
Total genomic DNA was extracted from EDTA whole blood samples, using the gDNA Blood kit (Invitrogen™, Carlsbad, CA, USA), following the instructions provided by the manufacturer.
Plasmodium vivax mono-infection status was confirmed by Nested PCR, in the presence of specific oligonucleotides for
P. vivax,
P. falciparum and
Plasmodium malariae, according to the protocol described by Snounou and Singh [
50].
Monoclonal antibody panel for immunophenotypic analyses
Anti-human cell surface/cytoplasm monoclonal antibody (mAbs) panel labeled with distinct fluorochromes were used for flow cytometric immunophenotypic analysis, including: anti-CD3-PECy7(SK7), anti-CD4-PE(RPA-T4), anti-CD8-FITC(HIT8a), anti-CD69-APC(FN50), anti-CD25-PERCP-Cy5(M-A251), anti-FoxP3-AF647(259D/C7), anti-CD19-FITC(HIB19), anti-CD5-PE(UCHT2), anti-CD16-FITC(3G8) and anti-CD56-PE(B159), all purchased from BD Bioscience, San Diego, CA, USA.
Haematological parameters and flow cytometric analysis of lymphocyte subsets
EDTA whole blood samples were employed for assessing haematological parameters using an automated haematological analyzer (Sysmex KX-21 N
®). An additional flow cytometric immunophenotypic analysis was also carried out as follows: briefly, 50 mL aliquots of whole blood were incubated with 5–10 mL of fluorescent mAbs for 30 min, at room temperature, in the dark. After incubation, the red blood cells were lysed with 2 mL of lysing solution (BD FACS™ Lysing Solution, BD
® Biosciences San Diego, CA, USA) for 10 min at room temperature, in the dark. For FoxP3 immunostaining, cells were permeabilized for 10 min at room temperature, in the dark with 2 mL of perm buffer (phosphate-buffered saline-PBS, 0.5 % saponin, 0.5 % bovine serum albumin). After one wash step with PBS, stained cells were fixed in FACS fix solution (10 g/L of paraformaldehyde, 10.2 g/L of sodium cacodylate and 6.63 g/L of sodium chloride, pH 7.2). Cells were run in a FACSCanto II
® flow cytometer (Becton–Dickinson Company, San Jose, CA, USA) and a total of 10,000 (100,000 for CD4/CD25/FoxP3) events collected for data analyses. Lymphocyte subsets were quantified first by specific gating strategies, using the
FlowJo software (version 9.4.1, TreeStar Inc. Ashland, OR, USA) as represented in Additional file
1. The results were expressed initially as percentage of positive cells within the lymphocyte gate. Absolute counts for lymphocyte subsets were calculated by multiplying the percentage of gated lymphocytes obtained by flow cytometry by the absolute lymphocyte count provided from the automated haematological analyzer.
Plasmatic cytokine quantification
The plasmatic cytokines were quantified by human Cytometric Bead Array kit for IL-2, IL-4, IL-6, IL-10, TNF and IFN-γ, all purchased from BD Biosciences Pharmingen (San Diego, CA, USA), following the instructions provided by the manufacturer. Data analysis was performed using the FCAP ArrayTM software, V.2.0 (BD Biosciences, San Jose, CA, USA). Initially, the mean fluorescence intensity (MFI) of each bead cluster was determined and forth logistic regression applied to build the standard curves. Cytokine concentrations for each sample were then extrapolated from the standard curves and data was expressed as pg/mL for each plasmatic cytokine.
Data mining and statistical analysis
Statistical analyses were carried out using the GraphPad Prism software, version 5.0 (San Diego, CA, USA). Comparative analyses of continuous variables (age, haematological parameters, leukocyte subsets and plasmatic cytokines) amongst groups (endemic controls vs primary malaria vs recurrent malaria) were performed by Kruskal–Wallis followed by multiple comparisons performed by Dunn’s post-test.
The analysis of overall biomarker profile was performed by converting the original data (leukocyte subsets and plasmatic cytokine profile), obtained as continuous variables, into categorical parameters using the global median cut-off calculated for the study population. Global median values for each haematological parameter, lymphocyte subset and plasmatic cytokine were used to segregate and calculate the proportion of subjects with high biomarker levels (above the cut-off edge). The data were assembled as proposed previously by Luiza-Silva et al. [
47] and Souza-Cruz et al. [
48] and the biomarker profile for endemic controls used as reference curve for comparative analyses with malaria patients. The χ
2 test was used to compare the proportions of subjects with biomarker levels above the cut-offs amongst groups.
Spearman’s test was used to sort variables that provided significant correlation. Linear regression analysis was applied to generate the best fitted line and the 95 % confidence interval bands.
In all cases, significance was considered at p < 0.05. Significance level was underscored by asterisks, as follows: (*) if p < 0.05; (**) if p < 0.005 and (***) if p < 0.0005.
Discussion
Plasmodium vivax is highly prevalent around the world [
1]. Regardless its former association with benign malaria [
3,
22], complications of
P. vivax malaria have been reported in adult patients living in Amazon Basin endemic areas [
11,
12]. It has been proposed that a balance between the pro- and anti-inflammatory responses can account for the control against the development of the severe malaria episodes [
54].
Infections with
Plasmodium ssp. are capable of inducing major changes in leukocyte profiling [
9,
55‐
62]. In the present study, data demonstrated that patients with
P. vivax recurrent malaria presented an unbalanced CD4
+/CD8
+ T-cell ratio, which was associated with a significant increase in the plasmatic IL-10 levels. Interestingly, it was verified that the IL-10 levels in patients with recurrent malaria were directly proportional to the number of malaria episodes.
In details, the ex vivo phenotypic profile of circulating leukocytes was characterized in patients with
P. vivax primary and recurrent malaria. Relevant changes in the proportion of subjects with high levels of circulating lymphocyte subsets were found (Fig.
2). In particular, patients with recurrent malaria presented significant reduction of CD4
+, CD8
+ T-cells and activated T-cells (CD69-expressing CD4
+and CD8
+ T-cells) (Fig.
3). The reduction among those subpopulations was also evident in other studies carried out with
P. vivax naturally infected individuals [
55,
59,
63,
64]. Those authors interpreted the reduction in the lymphocyte subpopulations in the peripheral blood as a suppressant effect in the response to the
P. vivax [
55,
56,
63‐
65]. According to them, such reduction could be due to the high apoptosis levels or to the relocation of the cells in the liver and in other lymphoid compartments [
55,
64,
66‐
68]. In the present study, the major changes, occurred in T-lymphocyte subsets, were observed in the group with recurrent malaria; however, further investigations must be performed to elucidate it, as the phenomenon is more accentuated in this group.
Comparison of plasmatic cytokine levels showed specific characteristics suggestive of a massive cytokine storm in patients with primary and recurrent malaria as compared to healthy endemic controls (Fig.
2). In malaria patients, the levels of IL-6 and IL-10 were increased expressively in relation to other cytokines (Fig.
4), supporting what was noted in other studies on non-complicated malaria [
69‐
72]. It is well established that the unbalance of the pro- and anti-inflammatory mediators is a fundamental component in the malaria pathogenesis by the
P. vivax [
9,
35,
46,
58,
64,
73‐
76]. In this study, levels of the IL-10, IL-6 and IL-4 were higher in patients with recurrent malaria. Nonetheless, it could not be directly compared to data found in the literature due to the different methodology used. It must be mentioned that no patient participating in this study developed any complication during the acute infection. This is an important indication that within a short period of time, recurrent infections by the
P. vivax did not increase the risk for complications, as reported previously in other studies [
77,
78]. Probably, such risk is associated to the hyper-reactivity of the immune system, as it is verified in African children after recent malaria episode [
79‐
81].
Although several studies have shown the dynamics of the subpopulations during
P. vivax infection, the correlation between such findings and the number of malaria episodes were less explored [
9,
55‐
62]. The findings indicate a direct association between the CD4
+/CD8
+ T-cells ratio and plasmatic IL-10 cytokine levels, selectively in patients with recurrent malaria (Fig.
5). Recent studies determined that after the first malaria infection, the T-cells secreting IL-10 are more stable and have a longer life span as compared to IFN-γ-producing T-cells [
82‐
84].
Supporting these findings, the data presented here demonstrated that the levels of IL-10 were directly proportional to the number of malaria episodes [
64,
83,
84]. Several reports have proposed that the resistance pattern or susceptibility to the infection by the
Plasmodium is related to the cytokine microenvironment, with resistance to the parasite relying on cytokines such as IFN-γ, TNF, IL-12, and GM-CSF, while susceptibility is associated to the IL-10, IL-4 and TGF-β [
43,
85].
The IL-10 plays an important effect inasmuch as it is capable of deactivating macrophages, and it is indirectly responsible by decreasing the production of the IFN-γ. In this way, IL-10 actuates by cushioning the potentially harmful effects of the macrophage activation on the host tissue [
86]. In this study, the high production of IL-10 was remarkable in patients with recurrent malaria, being very low in patients with primary malaria. IL-10 has been indicated as an important regulator of the harmful immune responses to the host [
87]. However, due to its inhibitory ability over the macrophagic hyperactivation, the secretion of such cytokine would reduce the control of the host over the circulating parasites, thus possibly favoring the relapse of the infection [
85].
One of the limitations of this study was the impossibility to define which mechanisms are involved in the development of the recurrent infection, considering the multiple etiological factors involved in this phenomenon. Nevertheless, the data indicate the crucial immunoregulatory effect of the IL-10 in recurrent infections. It is also required that further investigation should be undertaken to shed light on the association between the decreased CD4+/CD8+ T-cell ratio and the increased plasmatic IL-10 levels during recurrent malaria. The findings suggest that the gradual immunity acquisition is dependent on the exposition involving a control of the immune response mediated by IL-10. Future prospective studies are required in order to assess the risk factors associated to the relapse of the P. vivax malaria and its relationship with different components of the immune response.
Authors’ contributions
YOC, AGC, PPO and PAN designed, performed the experiments and analysed the data. MVGL, JGCdR, OAMF, ATC, AM, WMM, CRFM and PAN discussed the results. MVGL, PPO and PAN conceived and designed the study. CRFM, MLMP, JGCdR, ATC, OAMF and PAN wrote the manuscript. All authors read and approved the final manuscript.