Figures
Abstract
Background
Plasmodium vivax is the most geographically widespread human malaria parasite. Cohort studies in Papua New Guinea have identified a rapid onset of immunity against vivax-malaria in children living in highly endemic areas. Although numerous P. vivax merozoite antigens are targets of naturally acquired antibodies, the role of many of these antibodies in protective immunity is yet unknown.
Methodology/Principal Findings
In a cohort of children aged 1–3 years, antibodies to different regions of Merozoite Surface Protein 3α (PvMSP3α) and Merozoite Surface Protein 9 (PvMSP9) were measured and related to prospective risk of P. vivax malaria during 16 months of active follow-up. Overall, there was a low prevalence of antibodies to PvMSP3α and PvMSP9 proteins (9–65%). Antibodies to the PvMSP3α N-terminal, Block I and Block II regions increased significantly with age while antibodies to the PvMSP3α Block I and PvMSP9 N-terminal regions were positively associated with concurrent P. vivax infection. Independent of exposure (defined as the number of genetically distinct blood-stage infection acquired over time (molFOB)) and age, antibodies specific to both PvMSP3α Block II (adjusted incidence ratio (aIRR) = 0.59, p = 0.011) and PvMSP9 N-terminus (aIRR = 0.68, p = 0.035) were associated with protection against clinical P. vivax malaria. This protection was most pronounced against high-density infections. For PvMSP3α Block II, the effect was stronger with higher levels of antibodies.
Author Summary
Plasmodium vivax is the most geographically widespread human malaria parasite. In highly endemic areas such as Papua New Guinea, a very rapid onset of immunity against vivax-malaria is observed. Although it is known that numerous P. vivax merozoite antigens are targets of naturally acquired antibodies, the role of many of these antibodies in protective immunity is yet unknown. In a cohort of 183 children aged 1–3 years, we now show that the presence of antibodies to Merozoite Surface Protein 3α (PvMSP3α) and Merozoite Surface Protein 9 (PvMSP9) are associated with a significant reduction in the burden P. vivax malaria. Antibodies increased with age and in the presence of concurrent P. vivax infections. After adjusting for both age and individual differences in exposure, the strongest reductions in risk were seen in children with antibodies to PvMSP3α Block II (41% reduction, p = 0.001) and PvMSP9 N-terminal region. (32% reduction, p = 0.035). These results indicate that PvMSP3α Block II and PvMSP9 N-terminus should be further investigated for their potential as P. vivax vaccine antigens.
Citation: Stanisic DI, Javati S, Kiniboro B, Lin E, Jiang J, Singh B, et al. (2013) Naturally Acquired Immune Responses to P. vivax Merozoite Surface Protein 3α and Merozoite Surface Protein 9 Are Associated with Reduced Risk of P. vivax Malaria in Young Papua New Guinean Children. PLoS Negl Trop Dis 7(11): e2498. https://doi.org/10.1371/journal.pntd.0002498
Editor: James S. McCarthy, Queensland Institute for Medical Research, Australia
Received: December 5, 2012; Accepted: September 10, 2013; Published: November 14, 2013
Copyright: © 2013 Stanisic et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by the National Institutes of Health (AI063135), the Australian Agency for International Development (AusAID) and the National Health and Medical Research Council (Grant no. 516735). IM is supported by an NHMRC Senior Research Fellowship (Grant no. 1043345). This work was made possible through Victorian State Government Operational Infrastructure Support and Australian Government NHMRC IRIISS. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Historically, most malaria vaccine research and development has been focused on Plasmodium falciparum. However, the importance of developing a P. vivax specific or combination P. falciparum/P. vivax vaccine is increasingly being recognised [1]. P. vivax is the most geographically widespread malaria parasite with up to 2.5 billion people at risk and an estimated 80–300 million clinical cases every year [2]. It is not the benign parasite it was long assumed to be; while severe manifestations are less common [3], there is a spectrum of severe disease associated with P. vivax infection that in many ways resembles that seen with P. falciparum [4]. Furthermore, case fatality rates associated with severe P. vivax or mixed P. falciparum/P. vivax infections are comparable with P. falciparum [3], [5], [6]. Unique aspects of the biology of this particular species of Plasmodium make it a challenge to treat and eradicate with currently available strategies [7], [8], [9], [10]. P. vivax forms dormant stages in the liver (hypnozoites), which can result in relapses following effective anti-malarial treatment of blood-stage infection [8]. It is also able to produce gametocytes early in infection which may appear in the peripheral circulation before the development of clinical symptoms [9]. Therefore, an infected, asymptomatic but untreated individual serves as a ‘reservoir’, maintaining successful transmission of the parasite. An effective P. vivax vaccine is a desirable, additional tool for P. vivax elimination.
Prioritisation of malaria vaccine candidates is informed by their site and stage expression, apparent function in vitro and role in protective immunity in malaria exposed populations. The identification and subsequent development of candidates for a P. vivax specific vaccine has been challenging due to a number of practical factors including the lack of a reliable in vitro culture system and limited data with respect to antigen diversity. Several antigens expressed during the blood stage of P. vivax infection have been identified as potential vaccine candidates including the Duffy Binding Protein (PvDBP, one of the primary erythrocyte invasion ligands), Merozoite Surface Protein 3 (PvMSP3) and Merozoite Protein 9 (PvMSP9) [11]–[14]. Antibodies against the most studied P. vivax vaccine candidate, the PvDBP, have been shown to inhibit binding of the parasite to receptors on the red blood cell and have been associated with protection [15]. PvDBP Region II (RII), the critical region for binding, is however quite polymorphic and the protection observed in this study had a degree of strain specificity [15]. This suggests that a vaccine based on PvDBP RII should either target conserved epitopes and be able to induce broadly inhibitory antibodies as recently demonstrated in vitro [16] or it may need to include multiple allelic types. Additionally, recent observations that P. vivax can utilise a Duffy antigen-independent invasion pathway and invade Duffy-negative red cells [17] suggests that a vaccine based solely on the PvDBP will not be effective against all P. vivax strains. Consequently, it is essential that additional P. vivax antigens are also critically assessed for their potential as vaccine candidates.
The P. vivax MSP3 multigene family is expressed during the erythrocytic stage of the life-cycle, with the majority of the proteins expressed in the schizont stage when merozoites are being formed [13], [14], [18]. Members are structurally related to P. falciparum MSP3, which has been shown to mediate antibody-dependent cellular-mediated inhibition [19] and is a vaccine candidate that showed some efficacy in human trials following preliminary analyses [20]. PvMSP3 lacks a hydrophobic region which indicates the presence of a transmembrane domain that could link it to the merozoite surface, rather it is thought to associate with other surface anchored proteins [13]. Its central alanine-rich domain with heptad repeats is predicted to form coiled-coil tertiary structures which mediate protein-protein interactions.
One of the members of the PvMSP3 family, originally identified as PvMSP3α, has been the focus of several specific bodies of research. Expression of PvMSP3α has been detected in trophozoites and schizonts and is displayed at the surface of merozoites [18], [21]. This protein is highly polymorphic and it has therefore been used as a molecular marker in P. vivax epidemiological and population studies [22], [23], [24], [25]. However, the hydrophilic, extreme N-terminal and the acidic C-terminal domains of the protein are relatively conserved [26]. Polymorphisms are clustered in specific domains, mainly confined to the N-terminal half of the central alanine-rich coiled-coil domain (designated as Block I, residues 104–396) while the C-terminal portion of this domain (designated Block II, residues 434–687) displays less variability [26]. Block I may be deleted in some isolates while retention of the relatively highly conserved Block II appears to be necessary. Due to the relative conservation of Block II of the alanine rich domain and the acidic C-terminal region, across a range of geographically distinct isolates, it has been suggested that vaccine-based research should focus on these regions [26]. PvMSP3α specific antibodies have been detected in naturally exposed individuals resident in a malaria endemic area of the Brazilian Amazon [21], and a number of linear B cell epitopes defined, located primarily in the 2 blocks of repeats [27].
PvMSP9 is also expressed during schizogony and is associated with the surface of the merozoite [29], [30]. The deduced protein contains a hydrophobic signal sequence, highly conserved N-terminal domain with a cluster of 4 cysteines and a C-terminal region containing 2 species-specific blocks of repeated amino acids, designated PvMSP9-RI and PvMSP9-RII [29]. Its importance as a vaccine candidate has been highlighted by the ability of a PvMSP9 monoclonal antibody to block the entry of P. vivax into erythrocytes [30]. Studies examining the immunogenicity of different regions of PvMSP9 have demonstrated the presence of both antibody and T cell responses specific for this protein in individuals resident in malaria endemic areas [12], [31], [32].
Recent cohort studies in Papua New Guinea (PNG), where both P. falciparum and P. vivax co-exist, have identified an age-dependent onset of immunity to the different Plasmodium species. The incidence of P. vivax attributable illness peaks in the second year of life, compared to P. falciparum where it continues to increase until the 4th year of life, suggesting that immunity against P. vivax appears to be acquired at a younger age than that seen with P. falciparum [33]. This immunity is associated with an increased ability to control parasite densities so that they remain below the threshold above which symptoms are apparent. Despite these observations, little is known about immune responses against P. vivax antigens in young children and how these may contribute to the acquisition of protective immunity. To address this, we examined associations between antibodies to different regions of the blood-stage antigens PvMSP3α and PvMSP9 and prospective risk of P. vivax malaria in a cohort of children aged 1–3 years residing in a malaria endemic region of PNG.
Materials and Methods
Study description
This study was conducted in a rural area near Maprik, East Sepik Province, Papua New Guinea. A detailed description of the study is given elsewhere [33]. Briefly, 264 study participants aged 1–3 years (median 1.70; range 0.9–3.1 years) were enrolled between March and September 2006 and venous blood collected. Of these, 190 were enrolled at the study start and 74 over the subsequent 6 months. Antibody assays were performed using samples from 183 of the 190 children enrolled at the study start; all data presented for the current analysis relates to these 183 children only. Following enrolment, children were clinically examined every 2 weeks for signs and symptoms of malaria for a period of up to 16 months (until July 2007). In addition, children were actively checked every 8 weeks, with visits scheduled over 2 consecutive days (with 2 samples collected 24 hours apart) to improve detection of low-level infection. A passive case detection system was maintained at the local health centres and aid post throughout the entire study period. At each episode of febrile illness, a blood sample was collected, a rapid diagnostic test (RDT) was performed and haemoglobin measured using Hemacue (Angholm, Sweden). Anti-malarial treatment with Coartem® (Novartis, Switzerland) was administered to any individual with a positive RDT or if haemoglobin levels were <7.5 g/dl. In children with a negative RDT, blood slides were read within 24 hours and microscopy positive children were treated with Coartem.
For the current analysis, a symptomatic episode of P. vivax malaria was defined as the presence of fever plus parasitemia >500 parasites/µl [34]. Parasitemia (ie absence/presence of parasite) was determined by a semi-quantitative post-PCR ligase detection reaction-fluorescent microsphere assay (LDR-FMA) [35] and light microscopy was used to determine parasite density. All analyses were performed using parasitemia determined by LDR-FMA unless otherwise indicated.
Written informed consent was obtained from all parents or guardians prior to recruitment of each child. Scientific approval and ethical clearance for the study was obtained from the Medical Research and Advisory Committee (MRAC) of the Ministry of Health in PNG and the Human Research Ethics Committee, the Walter and Eliza Hall Institute.
Antigens
PvMSP3α recombinant proteins, representing the N-terminal (nucleotides 73–309), Block I (nucleotides 316–1242), Block II (nucleotides 1246–2058) and the C-terminal (nucleotides 2059–2353) regions were used. They were initially amplified from P. vivax (Belem strain), expressed as His-tag recombinant proteins and purified as previously described [27].
PvMSP9 recombinant proteins, representing the N-terminal region (aa 34–193) and the C-terminal region containing the repeated Blocks I and II (aa 729–972), were used. They were initially amplified from P. vivax (Belem strain), expressed as GST fusion proteins and purified as previously described [12], [31].
The proteins were assessed on SDS-PAGE gels and via western immunoblots using standard conditions. A single batch of each protein was used for this was well as earlier Brazilian studies [12], [31].
Antibody assays
Samples collected from the enrolment bleed (n = 183) were used in an enzyme linked immunosorbent assay (ELISA). All available samples were tested for IgG. ELISAs were performed using established methods [36]. Ninety-six well plates (Nunc, Roskilde, Denmark) were coated with MSP3α and MSP9 recombinant proteins in PBS and incubated overnight at 4°C. For MSP9 proteins, GST alone was used as a control antigen. Skim milk-PBS-0.05% Tween was used for blocking and for diluting plasma and antibodies. Plasma was added in duplicate at previously determined dilutions. For measurement of total IgG, horseradish peroxidase-conjugated sheep anti-human IgG (Chemicon, Melbourne, Australia) was used at a dilution of 1, 2∶500. Finally, o-phenylenediamine dihydrochloride substrate (Sigma, Castle Hill, Australia) was added and the reaction stopped using 3M HCl with optical density determined at 492 nm. All samples were tested in duplicate. Standardization of the plates was achieved using positive control plasma pools on each plate. Background (determined from the wells with no plasma) was deducted from the mean of each sample and a cut-off threshold for positivity determined as the mean plus 3 standard deviations of negative control plasma samples (Australian residents) included in each assay. For MSP9 proteins, final OD values were determined by subtracting the mean OD value to GST alone from the mean OD value of the same plasma for the recombinant proteins.
Measuring Force of Blood-stage infection (molFOB)
The molFOB was used to define the number of new P. vivax blood-stage clones acquired during the study follow-up period [37]. For genotyping individual P. vivax clones, the highly polymorphic molecular markers Merozoite Surface Protein 1 F3 fragment and the microsatellite MS16 were typed using capillary electrophoresis for precise fragment sizing. Details of the genotyping techniques have been described elsewhere [38].
Statistical analyses
Antibody levels were not normally distributed, so non-parametric tests (Mann-Whitney U tests) were used for analyses of antibody titres. Differences in the prevalence of antibodies with age and infection status as well as associations between antibodies to different proteins were assessed using Chi-square test with the strength of the association between antibodies of different specificities measured by the phi coefficient (rφ). The association of antibody prevalence and parasite density were assessed using generalised estimating equation (GEE) models.
Children were followed up for a maximum of 8 periods during the study, each spanning 8–9 weeks and consisting of 3 fortnightly surveillance visits and each concluding with the collection of 2 blood samples 24 hours apart for active detection of malaria infection. Incidence of clinical malaria in each 8–9 week follow-up interval was estimated as previously described, with P. vivax clinical episodes defined as febrile illness (axillary temperature ≥37.5°C or history of fever in preceding 48 hrs) with a concurrent P. vivax parasitemia >500 parasites/µl. A negative binomial GEE model (based on XTNBREG procedure in STATA 12.0), an exchangeable correlation structure and semi-robust variance estimator were used for the analysis of incidence of P. vivax malaria. For each follow-up interval, children were considered at risk from the first day after the second or only blood sample for active follow-up was taken. Therefore, cross-sectional bleeds were considered as part of the preceding 8–9 week interval and clinical episodes detected during those cross-sectional bleeds (2 samples taken 24 hours apart) were included in that interval. Children were not considered at risk for 2 weeks after treatment with Coartem®.
Three different models were used to assess the association of antibodies with protection: i) ‘crude’: adjustment only for seasonal (month, year) and spatial variation (village or residence) as well as for individual differences in exposure: aIRR(exp); ii) age-adjusted: additional adjustment for age of child (as a correlate of overall immune status): aIRR(exp+age), iii) multivariate age-adjusted: multivariate analyses of all antibodies univariately associated with protection: aIRR(multi), with the best model determined by backward elimination using Wald's Chi-square tests for individual variables.
Individual differences in exposure were described by the number of genetically distinct P. vivax clones a child acquired during 2 month intervals, expressed as the number of new blood-stage infections per unit of time. Samples from scheduled bleeds as well as morbidity surveillance were used. The force of infection for each child was therefore defined as the number of new blood-stage clones acquired per year at risk (i.e. the molecular force of infection molFOB [39]). In order to improve the fit, molFOB was cube-root transformed [37].
Results
P. vivax prevalence in the cohort
A total of 183 children 0.9–3.1 years (47.5% ≥21 months, 56.8% male) were enrolled in late March 2006 and actively followed for 16 months for the development of malaria infection. At enrolment, the prevalence of P. vivax was 39.9% and 49.2% by light microscopy (LM) and post-PCR LDR-FMA, respectively. During follow-up, P. vivax prevalence ranged from 59.9–79.2% by post-PCR LDR-FMA and 47.3–59.9% by LM. Children experienced an average of 2.47 (CI95 [2.15, 2.85]) P. vivax episodes with any level of parasitemia and 1.49 (CI95 [1.24, 1.79]) episodes with P. vivax >500 parasites/µl per year at risk. The patterns of P. vivax infection and disease in the immunology sub-cohort are therefore comparable to those observed in the entire cohort [33], [38].
Presence of IgG antibodies and their association with age and infection status
The frequency of IgG responses at enrolment to the different antigens ranged from 8.7%–65% (Table 1). When comparing different regions of PvMSP3α, significantly more children had IgG antibodies to the C-terminal than to the N-terminal, Block I and Block II proteins of PvMSP3α (65.0% vs. 36.1–38.3%, p<0.001). The presence of antibodies to the different protein constructs derived from PvMSP3α were highly associated with each other (p<0.0001 for any pair) with the strongest association found between antibodies to Block II and Block I (rφ = 0.67). Overall, 43 children (23.5%) had antibodies to all 4 PvMSP3α proteins while 51 (27.9%) had antibodies to none (Figure 1a).
(a) Cumulative IgG positivity for different PvMSP3α proteins. Data are plotted as the percentage of 183 individuals who are antibody positive for 0–4 of the proteins tested. (b) Associations between age and IgG positivity to PvMSP3α and PvMSP9 proteins. Children were divided into two age groups (<21 mths: n = 96, ≥21 mths: n = 87) to examine associations with age. P values≤0.05 were considered significant and are shown. (c) Associations between P. vivax infection status (post-PCR LDR-FMA positive: n = 90, negative: n = 93) and IgG positivity to PvMSP3α and PvMSP9 proteins. As indicated, the presence of P. vivax was determined by a semi-quantitative post-PCR ligase detection reaction-fluorescent microsphere assay (LDR-FMA). P values≤0.05 were considered significant and are shown.
Children ≥21 months were significantly more likely to have antibodies to the PvMSP3α N-terminal protein (Odds ratio (OR = 2.06, CI95 [1.08, 3.95], p = 0.019), Block I (OR = 2.53, CI95 [1.30, 4.95], p = 0.003) and Block II (OR = 2.27, CI95 [1.18, 4.37], p = 0.008) but not to the C-terminal protein (Figure 1b). Antibodies to Block I (OR = 2.06, CI95 [1.07, 4.00], p = 0.020) were also significantly more common in children with concurrent P. vivax infection (Figure 1c). There were no significant associations with antibody levels and either age or infection status among children that were antibody-positive for any of the PvMSP3α proteins (p>0.26).
Eighty-four (45.9%) children had antibodies to the PvMSP9 N-Terminal region, and 16 (8.7%) had antibodies to the MSP9 protein spanning RI-RII (Table 1). Children that were positive for any of the PvMSP3α proteins were more likely to also be positive for the PvMSP9 N-Terminus (OR = 2.30–4.78, p<0.009). Antibodies specific for the PvMSP9 N-Terminus were more common in children with concurrent P. vivax infection (OR = 2.38, CI95 [1.26, 4.51], p = 0.004). No other significant associations between antibodies specific for PvMSP9 derived proteins and either age or infection status were observed.
Association between presence of antibodies and prospective risk of P. vivax malaria
When assessing associations between the presence of IgG antibodies specific for the different PvMSP3α and PvMSP9 proteins and prospective risk of P. vivax clinical episodes (>500 parasites/µl, Table 2) during the 16 months of follow-up, adjustments were made first for different measures of malaria exposure as described in the materials and methods section, designated aIRR(exp). This was followed by a further adjustment for age, designated aIRR(exp+age).
After adjusting for malaria exposure, a significant decrease in the risk of clinical P. vivax malaria was associated with the presence of antibodies for PvMSP3α Block II (aIRR(exp) = 0.46, p<0.001), PvMSP3α N-terminus (aIRR(exp) = 0.67, p = 0.048), and PvMSP9 N-Terminus (aIRR(exp) = 0.58, p = 0.004) (Table 2).
Following a further adjustment for age, a significantly decreased risk remained for individuals who were antibody positive for PvMSP3α Block II (aIRR(exp+age) = 0.53, p = 0.001) and PvMSP9 N-Terminus (aIRR(exp+age) = 0.60, p = 0.004) (Table 2). For antibodies specific for both these proteins there was a tendency for protection to increase with increasing levels of parasitaemia (Figure 2). However, whereas the presence of antibodies for PvMSP3α Block II was associated with protection against all clinical episodes with a P. vivax parasitaemia ≥500/µl (p = 0.003–0.057), antibodies against PvMSP9 N-Terminus were associated only with significant protection against episodes with ≥2000/µl (p = 0.001–0.002) but not those with densities ranging from 500–1999/µl (p = 0.92).
Data are plotted as exposure and age adjusted incidence rate ratios (aIRR(exp)) ± 95% confidence intervals for febrile episodes with different levels of concurrent P. vivax parasitaemia.
To assess the effect of antibody levels on protection against risk of P. vivax clinical episodes, children who were antibody positive for PvMSP3α Block II or PvMSP9 N-Terminus were stratified into 2 equal sized groups: those with high levels and those with low levels of antibodies. High levels (OD>0.77) of PvMSP3α Block II specific antibodies were significantly associated with protection (aIRR = 0.42, p = 0.001) whereas, this was not observed with lower levels (IRR = 0.68, p = 0.114). No such differences were observed with antibodies to PvMSP9 N-Terminus.
In multivariate analyses, both antibodies to PvMSP3α Block II (aIRR(multi) = 0.59, p = 0.011) and PvMSP9 N-Terminus (aIRR(multi) = 0.68, p = 0.035) remained significantly associated with a reduced risk of P. vivax (Table 2). A significant interaction between the presence of antibodies to PvMSP9 N-Terminus and concurrent P. vivax infection was observed (X2 = 4.55, p = 0.033) with PvMSP9 N-Terminus antibodies associated with protection only in children without concurrent P. vivax infection (aIRR(multi) = 0.48, CI95[0.28, 0.80], p = 0.006), while in children with concurrent infection PvMSP9 N-Terminus, antibodies did not add any extra protection (aIRR(multi) = 1.03, CI95[0.62, 1.71], p = 0.9) besides that associated with concurrent infection itself (aIRR(multi) = 0.59, CI95[0.41, 0.87], p = 0.007).
As multivariate analyses examining the relationship between the presence of antibodies and risk of clinical P.vivax malaria showed a protective effect with only PvMSP3α Block II and MSP9 N-terminus, further analyses examining the effect of antibody levels were restricted to these 2 proteins. Antibody positive children were stratified into 2 equal sized groups and designated as high or low responders. Children with high antibody levels to both PvMSP3α Block II (high: aIRR = 0.46, CI95[0.28, 0.77], low: aIRR = 0.72, CI95[0.45, 1.17]) and PvMSP9 N-Terminus (without concurrent infection, high: aIRR = 0.30, CI95[0.14, 0.62], low: IRR = 0.76, CI95[0.40, 1.45]), had a lower risk of clinical P. vivax malaria compared to children with low antibody levels but that difference was only significant for PvMSP9 N-Terminus (p = 0.04) and not PvMSP3α Block II (p = 0.15).
There were no significant associations observed with antibodies to any of the P. vivax proteins and risk of P. falciparum clinical episodes (p>0.16).
Discussion
Antigens on the surface of the merozoite have long been considered as promising vaccine candidates based on their accessibility to the immune system. Antibodies against P. vivax merozoite surface proteins and their P. falciparum orthologues are thought to function by directly inhibiting invasion of erythrocytes, opsonising merozoites for uptake by phagocytes and through antibody-dependent cell-mediated immune mechanisms [19], [30], [40], [41], [42], [43], [44], [45]. Although studies have established the immunogenicity of a number of P. vivax merozoite antigens using serum from malaria exposed individuals [10], [12], [21], [27], [28], [31], [46], [47], [48], few have examined the contribution of antibodies to protective immune responses against P. vivax infection in malaria exposed populations [15], [27], [31], [49], [50]. Our results demonstrate that IgG specific responses against defined regions of PvMSP3α and PvMSP9 are significantly associated with protection from symptomatic P. vivax infection in young children resident in a malaria endemic region of PNG. Antibody responses against these proteins have been previously examined in malaria-exposed populations [27], [31] however, these studies were limited in their ability to precisely define the role of these antibodies. We employed a longitudinal study design with active screening for re-infection and morbidity and related antibody responses at baseline with prospective risk of developing symptomatic P. vivax infection over the 16-month follow-up period.
Overall, the prevalence of IgG specific responses to the different PvMSP3α and PvMSP9 antigens was low. Patterns of responsiveness to the recombinant proteins were different to that observed in previous studies [27], [31]. This is likely to reflect differences in age ranges, malaria transmission levels and potentially population genetics. However, we cannot rule out that differences in the reactivities of the non-exposed donors that were used to establish the threshold for seropositivity in the different studies may have contributed to disparity between studies. Although the age range of this cohort was narrow, the prevalence of antibodies against all PvMSP3α proteins and the PvMSP9 RI-RII domain increased with age (and presumably exposure). This was only significant however for antibodies against the N-terminal and the Block I and II regions of PvMSP3α. Interestingly, there was no apparent effect of age on the prevalence of antibodies against the PvMSP9 N-terminus. As this region of PvMSP9 is known to be highly conserved [29], [30] this may reflect the presence and recognition of conserved epitopes. Antibodies against all of the PvMSP3α and PvMSP9 antigens were also more commonly found in individuals with concurrent P. vivax infection, although this difference was only significant for Block I PvMSP3α and the PvMSP9 N-terminus. This effect of active parasite infection on antibody positivity reflects the induction and/or boosting of existing antibody responses.
After adjusting for age and exposure, associations with protection from symptomatic P. vivax malaria were seen for antibodies against the PvMSP3α Block II and the PvMSP9 N-terminal domains. This association remained following multivariate analyses. Additionally, antibodies against these proteins were associated with stronger reduction in risk of high compared to low infections. This density-dependent effect is in keeping with the proposed mechanism of action of these antibodies (i.e., to prevent/interfere with merozoite invasion of red blood cells and/or opsonisation of merozoites). This is most evident for PvMSP3α Block II, where higher levels of antibodies were associated with a significantly stronger protection compared with lower levels. Although PvMSP9 specific antibodies were more prevalent in children with concurrent infections, these antibodies were only associated with protection in children who did not have concurrent P. vivax infections at the time of antibody measurement. This indicates the existence of at least two separate types of antibodies targeting the PvMSP9 N-terminal domain: one that is easily boosted by infection and another that is longer lasting and continues to be present after an infection is cleared. Only the latter appear to be associated with protection against clinical P. vivax malaria. Whether these differential antibody types indicate the induction of different IgG subclass responses or target different epitopes is yet unknown.
A recent study demonstrated that the majority of sequences containing linear B cell epitopes within PvMSP3α are localised within the Block I and II repeat regions, although a few epitopes were detected in the more conserved N- and C-terminal flanking regions [27]. While the central domain of PvMSP3α is highly polymorphic, the C-terminal half containing the Block II repeat region is relatively conserved with only 2 major regions of polymorphism [26]. The PvMSP9 N-terminus is also known to be highly conserved across Plasmodium species [29], [30]. The conservation of these antigens amongst P. vivax isolates highlights their potential as vaccine candidates. Additionally, it has recently been shown that anti-sera generated against individual recombinant proteins representing the central alanine-rich domain of different PvMSP3 family members (including PvMSP3α), contain antibodies capable of recognising the central domain of other PvMSP3 family members [18]. While this suggests that an immune response generated against a single PvMSP3 protein may consist of a broad antibody response against multiple antigenic targets, further studies are required to determine whether the B cell epitopes recognised by these cross-reactive antibodies are contained within the C-terminal half of this domain. Studies to identify and characterise B cell epitopes that are targets of protective antibodies would inform the development and use of these molecules. Furthermore, investigating the functionality of antibodies against the PvMSP9 N-terminus and PvMSP3α Block II would confirm the utility and importance of these proteins as vaccine candidates. Undertaking ex vivo invasion assays with affinity purified serum containing antibodies specific for these proteins together with a range of P.vivax isolates would also shed light on the strain-transcending nature of the antibody response. In conclusion, these findings have significant implications for the development of a P. vivax specific vaccine. Controlling for molFOB ensures that the observed associations of antibodies specific for the PvMSP9 N-terminus and PvMSP3α Block II with protection against P. vivax malaria in this study are not confounded by individual differences in exposure. Our results support further investigation of the PvMSP9 N-terminus and PvMSP3α Block II as vaccine candidates.
Acknowledgments
We would like to thank all study participants and their families and the field teams at the Institute of Medical Research. We would also like to thank Moses Lagog and Anselm Masalan for assistance with sample processing.
Author Contributions
Conceived and designed the experiments: DIS MRG IM. Performed the experiments: DIS SJ BK EL CK. Analyzed the data: DIS IM. Contributed reagents/materials/analysis tools: JJ BS EVSM PS IF. Wrote the paper: DIS SJ MRG IM.
References
- 1. Galinski MR, Barnwell JW (2008) Plasmodium vivax: who cares? Malaria Journal 7: S9.
- 2. Mueller I, Galinski MR, Baird JK, Carlton JM, Kochar DK, et al. (2009) Key gaps in the knowledge of Plasmodium vivax, a neglected human malaria parasite. Lancet Infect Dis 9: 555–566.
- 3. Manning L, Laman M, Law I, Bona C, Aipit S, et al. (2012) Features and prognosis of severe malaria caused by Plasmodium falciparum, Plasmodium vivax and mixed Plasmodium species in Papua New Guinean children. PLoS One 6: e29203.
- 4. Bassat Q, Alonso PL (2011) Defying malaria: Fathoming severe Plasmodium vivax disease. Nat Med 17: 48–49.
- 5. Tjitra E, Anstey NM, Sugiarto P, Warikar N, Kenangalem E, et al. (2008) Multidrug-resistant Plasmodium vivax associated with severe and fatal malaria: a prospective study in Papua, Indonesia. PLoS medicine 5: e128.
- 6. Barcus MJ, Basri H, Picarima H, Manyakori C, Sekartuti , et al. (2007) Demographic risk factors for severe and fatal vivax and falciparum malaria among hospital admissions in northeastern Indonesian Papua. Am J Trop Med Hyg 77: 984–991.
- 7. Akinyi S, Hanssen E, Meyer EV, Jiang J, Korir CC, et al. (2012) A 95 kDa protein of Plasmodium vivax and P. cynomolgi visualized by three-dimensional tomography in the caveola-vesicle complexes (Schuffner's dots) of infected erythrocytes is a member of the PHIST family. Mol Microbiol 84: 816–831.
- 8. Krotoski WA, Collins WE, Bray RS, Garnham PC, Cogswell FB, et al. (1982) Demonstration of hypnozoites in sporozoite-transmitted Plasmodium vivax infection. Am J Trop Med Hyg 31: 1291–1293.
- 9. Boyd M, Kitchen S (1937) On the infectiousness of patients infected with Plasmodium vivax and Plasmodium falciparum. Am J Trop Med Hyg s1–17: 253–262.
- 10. Kitchen S (1938) The infection of reticulocytes by Plasmodium vivax. Am J Trop Med Hyg s1–18: 347–359.
- 11. Yazdani SS, Shakri AR, Mukherjee P, Baniwal SK, Chitnis CE (2004) Evaluation of immune responses elicited in mice against a recombinant malaria vaccine based on Plasmodium vivax Duffy binding protein. Vaccine 22: 3727–3737.
- 12. Oliveira-Ferreira J, Vargas-Serrato E, Barnwell JW, Moreno A, Galinski MR (2004) Immunogenicity of Plasmodium vivax merozoite surface protein-9 recombinant proteins expressed in E. coli. Vaccine 22: 2023–2030.
- 13. Galinski MR, Corredor-Medina C, Povoa M, Crosby J, Ingravallo P, et al. (1999) Plasmodium vivax merozoite surface protein-3 contains coiled-coil motifs in an alanine-rich central domain. Mol Biochem Parasitol 101: 131–147.
- 14. Galinski MR, Ingravallo P, Corredor-Medina C, Al-Khedery B, Povoa M, et al. (2001) Plasmodium vivax merozoite surface proteins-3beta and-3gamma share structural similarities with P. vivax merozoite surface protein-3alpha and define a new gene family. Mol Biochem Parasitol 115: 41–53.
- 15. King C, Michon P, Shakri A, Marcotty A, Stanisic D, et al. (2008) Naturally acquired Duffy-binding protein-specific binding inhibitory antibodies confer protection from blood-stage Plasmodium vivax infection. Proc Natl Scad Sci USA 105: 8363–8368.
- 16. Ntumngia FB, Schloegel J, Barnes SJ, McHenry AM, Singh S, et al. (2012) Conserved and Variant Epitopes of Plasmodium vivax Duffy Binding Protein as Targets of Inhibitory Monoclonal Antibodies. Infect Immun 80: 1203–1208.
- 17. Ménard D, Barnadas C, Bouchier C, Henry-Halldin C, Gray L, et al. (2010) Plasmodium vivax Clinical Malaria is Commonly Observed in Duffy-negative Malagasy People. Proc Natl Acad Sci USA 106: 5967–5971.
- 18. Jiang J, Barnwell JW, Meyer EV, Galinski M (2013) Plasmodium vivax Merozoite Surface Protein-3 (PvMSP3): Expression of an 11 member multigene family in blood-stage parasites. Plos One Accepted.
- 19. Oeuvray C, Bouharoun-Tayoun H, Gras-Masse H, Bottius E, Kaidoh T, et al. (1994) Merozoite surface protein-3: a malaria protein inducing antibodies that promote Plasmodium falciparum killing by cooperation with blood monocytes. Blood 84: 1594–1602.
- 20. Sirima SB, Cousens S, Druilhe P (2011) Protection against malaria by MSP3 candidate vaccine. N Engl J Med 365: 1062–1064.
- 21. Bitencourt AR, Vicentin EC, Jimenez MC, Ricci R, Leite JA, et al. (2013) Antigenicity and immunogenicity of Plasmodium vivax merozoite surface protein-3. PLoS One 8: e56061.
- 22. Bruce MC, Galinski MR, Barnwell JW, Snounou G, Day KP (1999) Polymorphism at the merozoite surface protein-3alpha locus of Plasmodium vivax: global and local diversity. Am J Trop Med Hyg 61: 518–525.
- 23. Mueller I, Kaiok J, Reeder JC, Cortes A (2002) The population structure of Plasmodium falciparum and Plasmodium vivax during an epidemic of malaria in the Eastern Highlands of Papua New Guinea. Am J Trop Med Hyg 67: 459–464.
- 24. Ord R, Polley S, Tami A, Sutherland CJ (2005) High sequence diversity and evidence of balancing selection in the PvMSP3alpha gene of Plasmodium vivax in the Venezuelan Amazon. Mol Biochem Parasitol 144: 86–93.
- 25. Cui L, Mascorro CN, Fan Q, Rzomp KA, Khuntirat B, et al. (2003) Genetic diversity and multiple infections of Plasmodium vivax malaria in Western Thailand. Am J Trop Med Hyg 68: 613–619.
- 26. Rayner JC, Corredor V, Feldman D, Ingravallo P, Iderabdullah F, et al. (2002) Extensive polymorphism in the Plasmodium vivax merozoite surface coat protein MSP-3alpha is limited to specific domains. Parasitology 125: 393–405.
- 27. Lima-Junior JC, Jiang J, Rodrigues-da-Silva RN, Banic DM, Tran TM, et al. (2011) B cell epitope mapping and characterization of naturally acquired antibodies to the Plasmodium vivax merozoite surface protein-3alpha (PvMSP-3alpha) in malaria exposed individuals from Brazilian Amazon. Vaccine 29: 1801–1811.
- 28. Lima-Junior JC, Rodrigues-da-Silva RN, Banic DM, Jiang J, Singh B, et al. (2012) Influence of HLA-DRB1 and HLA-DQB1 Alleles on IgG Antibody Response to the P. vivax MSP-1, MSP-3alpha and MSP-9 in Individuals from Brazilian Endemic Area. Plos One 7: e36419.
- 29. Vargas-Serrato E, Barnwell JW, Ingravallo P, Perler FB, Galinski MR (2002) Merozoite surface protein-9 of Plasmodium vivax and related simian malaria parasites is orthologous to p101/ABRA of P. falciparum. Mol Biochem Parasitol 120: 41–52.
- 30. Barnwell JW, Galinski MR, DeSimone SG, Perler F, Ingravallo P (1999) Plasmodium vivax, P. cynomolgi, and P. knowlesi: identification of homologue proteins associated with the surface of merozoites. Exp Parasitol 91: 238–249.
- 31. Lima-Junior JC, Tran TM, Meyer EV, Singh B, De-Simone SG, et al. (2008) Naturally acquired humoral and cellular immune responses to Plasmodium vivax merozoite surface protein 9 in Northwestern Amazon individuals. Vaccine 26: 6645–6654.
- 32. Lima-Junior JC, Banic DM, Tran TM, Meyer VS, De-Simone SG, et al. (2010) Promiscuous T-cell epitopes of Plasmodium merozoite surface protein 9 (PvMSP9) induces IFN-gamma and IL-4 responses in individuals naturally exposed to malaria in the Brazilian Amazon. Vaccine 28: 3185–3191.
- 33. Lin E, Kiniboro B, Gray L, Dobbie S, Robinson L, et al. (2010) Differential patterns of infection and disease with P. falciparum and P. vivax in young Papua New Guinean children. Plos One 5: e9047.
- 34. Mueller I, Genton B, Rare L, Kiniboro B, Kastens W, et al. (2009) Three different Plasmodium species show similar patterns of clinical tolerance of malaria infection. Malaria journal 8: 158.
- 35. McNamara D, Thomson J, Kasehagen L, Zimmerman P (2004) Development of multiplex PCR-ligase detection reaction assay for diagnosis of infection by the four parasite species causing malaria in humans. J Clin Micro 42: 2403–2410.
- 36. Stanisic D, Richards J, McCallum F, Michon P, King C, et al. (2009) IgG subclass-specific responses against Plasmodium falciparum merozoite antigens are associated with control of parasitemia and protection from symptomatic illness. Infect Immun 77: 1165–1174.
- 37. Koepfli C, Benton KL, Lin E, Kiniboro B, Zimmerman PA, et al. (submitted) A high force of Plasmodium vivax blood-stage infection drives the rapid acquisition of immunity in Papua New Guinean children. PLoS Neglected Tropical Diseases
- 38. Koepfli C, Ross A, Kiniboro B, Smith TA, Zimmerman PA, et al. (2011) Multiplicity and Diversity of Plasmodium vivax Infections in a Highly Endemic Region in Papua New Guinea. PLoS neglected tropical diseases 5: e1424.
- 39. Mueller I, Schoepflin S, Smith TA, Benton KL, Bretscher MT, et al. (2012) Force of infection is key to understanding the epidemiology of Plasmodium falciparum malaria in Papua New Guinean children. Proc Natl Acad Sci U S A 109: 10030–10035.
- 40. Bouharoun-Tayoun H, Attanath P, Sabchareon A, Chongsuphajaisiddhi T, Druilhe P (1990) Antibodies that protect humans against Plasmodium falciparum blood stages do not on their own inhibit parasite growth and invasion in vitro, but act in cooperation with monocytes. J Exp Med 172: 1633–1641.
- 41. Egan A, Burghaus P, Druilhe P, Holder A, Riley E (1999) Human antibodies to the 19 kDa C-terminal fragment of Plasmodium falciparum merozoite surface protein 1 inhibit parasite growth in vitro. Para Immunol 21: 133–139.
- 42. Khusmith S, Druilhe P (1983) Antibody-dependent ingestion of P. falciparum merozoites by human blood monocytes. Para Immunol 5: 357–368.
- 43. Khusmith S, Druilhe P (1983) Cooperation between antibodies and monocytes that inhibit in vitro proliferation of Plasmodium falciparum. Infect Immun 41: 219–223.
- 44. Blackman M, Heidrich H-G, Donachie S, McBride J, Holder A (1990) A single fragment of a malaria merozoite surface protein remains on the parasite during red cell invasion and is the target of invasion-inhibiting antibodies. Journal of Experimental Medicine 172: 379–382.
- 45. Grimberg BT, Udomsangpetch R, Xainli J, McHenry A, Panichakul T, et al. (2007) Plasmodium vivax invasion of human erythrocytes inhibited by antibodies directed against the Duffy binding protein. PLoS Med 4: e337.
- 46. Cole-Tobian JL, Cortes A, Baisor M, Kastens W, Xainli J, et al. (2002) Age-acquired immunity to a Plasmodium vivax invasion ligand, the duffy binding protein. J Infect Dis 186: 531–539.
- 47. Levitus G, Mertens F, Speranca MA, Camargo LM, Ferreira MU, et al. (1994) Characterization of naturally acquired human IgG responses against the N-terminal region of the merozoite surface protein 1 of Plasmodium vivax. Am J Trop Med Hyg 51: 68–76.
- 48. Seth RK, Bhat AA, Rao DN, Biswas S (2010) Acquired immune response to defined Plasmodium vivax antigens in individuals residing in northern India. Microbes Infect 12: 199–206.
- 49. Nogueira P, Alves F, Fernandez-Becerra C, Pein O, Santos N, et al. (2006) A reduced risk of infection with Plasmodium vivax and clinical protection against malaria are associated with antibodies against the N terminus but not the C terminus of merozoite surface protein 1. Infect Immun 74: 2726–2733.
- 50. Cole-Tobian JL, Michon P, Biasor M, Richards JS, Beeson JG, et al. (2009) Strain-specific duffy binding protein antibodies correlate with protection against infection with homologous compared to heterologous plasmodium vivax strains in Papua New Guinean children. Infect Immun 77: 4009–4017.