Pro-inflammatory Cytokine Response and Genetic Diversity in Merozoite Surface Protein 2 of Plasmodium falciparum Isolates from Nigeria
Olusola Ajibaye1, Akinniyi A Osuntoki2, Albert OT Ebuehi2, Bamidele A Iwalokun3, Emmanuel O Balogun4, Kathleen N Egbuna3
1 Biochemistry and Nutrition Division, Nigerian Institute of Medical Research; Department of Biochemistry, College of Medicine, University of Lagos, Lagos, Nigeria
2 Department of Biochemistry, College of Medicine, University of Lagos, Lagos, Nigeria
3 Biochemistry and Nutrition Division, Nigerian Institute of Medical Research, Lagos, Nigeria
4 Department of Biomedical Chemistry, Graduate School of Medicine, University of Tokyo, Tokyo 113-0033, Japan; Department of Biochemistry, Ahmadu Bello University, Zaria 2222, Nigeria
|Date of Web Publication||10-Nov-2017|
Biochemistry and Nutrition Division, Nigerian Institute of Medical Research, Lagos
Source of Support: None, Conflict of Interest: None
Background: Polymorphisms in Plasmodium falciparum merozoite surface protein-2 (msp-2) and associated parasite genetic diversity which varies between malaria-endemic regions remain a limitation in malaria vaccine development. Pro-inflammatory cytokines are important in immunity against malaria, understanding the influence of genetic diversity on cytokine response is important for effective vaccine design. Methods: P. falciparum isolates obtained from 300 Nigerians with uncomplicated falciparum malaria at Ijede General Hospital, Ijede (IJE), General Hospital Ajeromi, Ajeromi (AJE) and Saint Kizito Mission Hospital, Lekki, were genotyped by nested polymerase chain reaction of msp-2 block 3 while ELISA was used to determine the pro-inflammatory cytokine response to describe the genetic diversity of P. falciparum. Results: Eighteen alleles were observed for msp-2 loci. Of the 195 isolates, 61 (31.0%) had only FC27-type alleles, 38 (19.7%) had only 3D7-type alleles, and 49.3% had multiple parasite lines with both alleles. Band sizes were 275–625 bp for FC27 and 150–425 bp for 3D7. Four alleles were observed from LEK, 2 (375–425 bp) and 2 (275–325 bp) of FC27-and 3D7-types, respectively; 12 alleles from AJE, 9 (275–625 bp) and 3 (325–425 bp) of FC27-types and 3D7-types, respectively; while IJE had a total of 12 alleles, 9 (275–625 bp) and 3 (325–425 bp) of FC27-types and 3D7-types, respectively. Mean multiplicity of infection (MOI) was 1.54. Heterozygosity (HE) ranged from 0.77 to 0.87 and was highest for IJE (0.87). Cytokine response was higher among <5 years and was significantly associated with MOI (P > 0.05) but with neither parasite density nor infection type. Conclusion: P. falciparum genetic diversity is extensive in Nigeria, protection via pro-inflammatory cytokines have little or no interplay with infection multiplicity.
Keywords: Cytokinemia, falciparum malaria, multiplicity of infection, polymorphism, pro-inflammatory cytokine
|How to cite this article:|
Ajibaye O, Osuntoki AA, Ebuehi AO, Iwalokun BA, Balogun EO, Egbuna KN. Pro-inflammatory Cytokine Response and Genetic Diversity in Merozoite Surface Protein 2 of Plasmodium falciparum Isolates from Nigeria. Adv Biomed Res 2017;6:142
|How to cite this URL:|
Ajibaye O, Osuntoki AA, Ebuehi AO, Iwalokun BA, Balogun EO, Egbuna KN. Pro-inflammatory Cytokine Response and Genetic Diversity in Merozoite Surface Protein 2 of Plasmodium falciparum Isolates from Nigeria. Adv Biomed Res [serial online] 2017 [cited 2017 Nov 22];6:142. Available from: http://www.advbiores.net/text.asp?2017/6/1/142/192631
| Introduction|| |
Apicomplexan parasites constitute one of the most important groups of human and animal pathogens, none more so than the malaria parasites, which cause devastating death and disease globally. Malaria, an important protozoan parasitic disease in Nigeria, is caused by Plasmodium parasites transmitted to man through the bite of infected female Anopheles mosquitoes during blood meal. Due to a limited number of drugs available for treatment of Plasmodium falciparum malaria as a result of the spread of multi-drug resistance strains of the parasites, the only reliable intervention, malaria vaccine also faces huge limitations posed by genetic diversity of the parasite.
Molecular studies have demonstrated that individuals living in endemic areas generally harbor multiple P. falciparum strains that are genetically distinct and play an important role in the development of strain-specific immunity.,, Such individuals, however, may develop immunity to infection from some but not all the strains to which they are exposed. The multiplicity of infection (MOI) which is an epidemiological measure refers to the number of different parasite genotypes co-infecting a single host also reported as an indicator of immune status and transmission intensity.
Merozoite surface proteins (msp) of P. falciparum are essential parasite antigens involved in erythrocyte invasion affecting parasite density and eventually severe pathology of which msp- 2 is a good candidate for inclusion into a malaria vaccine. As part of immune evasion mechanism, msp-2 DNA sequences include variable block 3 which generates antigenically diverse forms that can be used to distinguish by size the different alleles after polymerase chain reaction (PCR) amplification., This gene is represented as a single copy on P. falciparum genome, and a high degree of polymorphism has been reported in the central variable region for msp-2 gene. Typing of this polymorphic P. falciparum genome region has permitted the determination of malaria infection indicators, e.g. diversity of P. falciparum strains and MOI, which contribute to the description of malaria situation in a given location. Genotyping of the msp-2 gene, therefore, is a standard method for assessing MOI in P. falciparum studies, as it is highly polymorphic in length and sequence.
The human immune system comprises a complex network of specialized cells and organs that function in harmony to achieve protection against foreign invaders. Acquired immunity to malaria involves both antibody-mediated and cell-mediated immunity. Naturally acquired immunity to malaria takes as long as 10–15 years of exposure to develop, it is nonsterile and is species-, stage-, strain-, and variant-specific for which residents in malaria endemic areas frequently have premunition (parasitemia and antibodies without symptoms). Lymphocytes play a central role in the regulation of both cell-mediated and antibody-mediated responses against different antigens. It is well established that B cells and antibodies play a major role in immunity to malaria however; it is now evident that T cells mediate the acquisition and maintenance of protective immune responses to malaria infection.
Cytokines play both protective and pathological roles in malaria, however, early and effective inflammatory response is crucial in the control of parasitemia and resolution of malaria infection through the mechanism of tumor necrosis factor alpha (TNF-α). TNF-α, interleukin-1β (IL-1β), and IL-12 are pro-inflammatory cytokines which are mediators of inflammation but crucial in malaria immunity. IL-12 is an immunoregulatory molecule which stimulates endogenous interferon-γ production by T lymphocytes and natural killer cells thereby increasing parasites clearance but with improved erythropoiesis. IL-1β is an endogenous pyrogen that plays a significant role in protection against malaria as does TNF-α. MOI which is an indicator of the malaria transmission in a given location is a function of parasite allelic variation suggesting a possible relationship between MOI and cytokine response.
The influence of P. falciparum genetic diversity and MOI on immunity against malaria has been reported; however, the relationship between the varying multiplicity of P. falciparum infections on innate immune response, especially pro-inflammatory cytokines in malaria has not yet been fully understood. We studied the diversity of P. falciparum isolates from Nigeria to determine MOI and its relationship with pro-inflammatory cytokine response.
| Methods|| |
Study design and sites
In this cross-sectional study, participants were recruited at the peak of malaria transmission (i.e. March–September) 2013 at three health facilities in Lagos State, South–Western Nigeria, namely: (a) Ijede General Hospital, Ijede (IJE), a secondary public health care facility; (b) Ajeromi General Hospital, Ajegunle, a secondary public health care facility; (c) St. Kizito Primary Healthcare Centre, Lekki, a not for-profit primary healthcare facility [Figure 1]. Malaria transmission is high in these areas while the selected facilities have above 500 outpatients a week. After obtaining informed consent (parental consent and/or assent from under-16 participants), patients presenting at these sites with symptoms suggestive of malaria, (axillary temperature ≥37.5 or history of fever in the last 48 h) with P. falciparum mono-infection (a minimum of 5000 P. falciparum parasites/μL estimated by thick film examination) who consented were enrolled into the study after they were treated with artemether-lumefantrine (20–120 mg) according to national policies (FMoH, 2005). Laboratory investigations were done at the Malaria Research Laboratory (Biochemistry and Nutrition Division), Public Health Division (TDR Laboratory) and Microbiology Division (Immunology Laboratory) of the Nigerian Institute of Medical Research, Lagos.
|Figure 1: Map showing location of the three study sites in Lagos Nigeria = The health facility used for study, located in the different local government areas in Lagos Nigeria; = Other local government areas in Lagos state; = Ibeju-Lekki local government area; = Ajeromi local government area; = Ikorodu local government area, Lagos, Nigeria|
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Approval was obtained from the Nigerian Institute of Medical research (NIMR) Institutional Ethics Review Board (IRB) for clearance to carry out the research.
Finger-pricked blood samples were collected from each participant. Slides were prepared according to WHO standard protocol, Giemsa stained and independently read by two microscopists for the estimation of parasite densities and species in the thick blood films, assuming an average white-blood-cell count of 8000/μL. Venous blood samples of positive participants were collected into plain bottles for ELISA.
Evaluation of cytokine response
Levels of TNF-α, IL-12, and IL-1β were assessed in sera of included participants using antigen capture ELISA.
Malaria parasite DNA extraction from dried blood spots and polymerase chain reaction amplification
Extraction of genomic DNA was carried out using QIAGEN QIAamp ® DNA Extraction Mini-kit (Qiagen, UK, cat no: 51306) from the individual dried blood spots. The extracted DNA samples were stored at −20°C until PCR. The quality as well as quantity of each DNA sample was determined using Nanodrop 1000 (Thermo Fisher Scientific, USA). The oligonucleotide primers were designed from published sequences as listed in the Nucleotide Blast Database, to amplify block 3 of msp-2. The genes were amplified by nested PCR in which DNA regions were amplified in 50 μL reaction mixtures containing: 1.25U BioTaq TM DNA polymerase (Bioline, London, UK), 1× Taq polymerase reaction buffer, 2.5 mM MgCl2, 0.25 mM dNTPs, and 1 μM of each primer. The following thermocycling profile was used for the primer sets: An initial denaturation step at 95°C for 5 min, followed by thirty cycles consisting of 1 min of denaturation step at 94°C, 2 min of annealing at 55°C, and 2 min of extension t 72°C followed by a final extension at 72°C for 5 min. The same cycling conditions were used for the secondary PCR (Nest 2) reaction except that the extension in the cycle was for 1 min. Each amplification with conserved or family-specific primer pair [Table 1], being done separately as described. PCR products were electrophoresed on 1.2% Agarose gels using 0.5 × TBE buffer at 100 V, and DNA bands visualized with the gel documentation system (Infinity 3026, Vilber Lourmat, Marnela Valled, France) after ethidium bromide staining. The sizes of the fragments obtained were estimated by comparison to the 1.3 kb (100 bp) DNA ladder (Jena Bioscience GmbH, Germany) as marker in comparison with standard purified genomic DNA from 3D7 laboratory strains similarly electrophoresed.
|Table 1: Sequences of oligonucleotide primers used to amplify merozoite surface protein 2 polymorphic regions of Plasmodium falciparum isolates from Nigeria|
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Detection of alleles
The PCR products were visualized by ultraviolet transillumination on gel documentation system [Plate 1] and [Plate 2]. Alleles in each family were considered the same if fragment sizes were within 2 bp interval.
The MOI, or number of genotypes per infection, was determined by dividing the total number of fragments detected by the number of samples positive for the same marker. Samples possessing only one genotype per family were considered monoclonal while those with multiple genotypes were described as polyclonal. Relationships were studied using Spearman correlation test. The prevalence of each family was calculated as the percentage of samples containing allele(s) of this family. The distribution of the specific families was estimated at each of the loci as the percentage of fragments assigned to one family within the overall number of fragments. Analysis was done with SPSS (version 20) (Armonk, NY: IBM Corp) software. As a measure of genetic diversity, the expected heterozygosity (HE) which represents the probability of being infected by two parasites with different alleles at a given locus and ranging between 0 and 1 was calculated by use of the formula:
where n = sample size, Pi= allele frequency.
HE estimates the fraction of all parasites that would be heterozygous for msp- 2 loci.
The MOI was determined by dividing the total number of fragments detected by the number of samples positive for the same marker. Samples possessing only one genotype per family were considered monoclonal while those with multiple genotypes were described as polyclonal.
| Results|| |
From the three sites, 1883 patients were screened, 300 (100 per site) out of the 384 P. falciparum positive patients were included having met the inclusion criteria. The median age was 10 years while 60 (20%) were <5 years with significantly higher geometric mean parasite density (GMPD) 136,267 ± 1,449 parasites/μL (P< 0.05) compared to 240 (80%) ≥5 years with GMPD 32,912 ± 1,256 parasites/μL. Malaria prevalence was observed to be 20.39% while 155 (51.67%) participants were male and 145 (48.33%) female.
Genetic diversity and allelic frequency
Nested PCR on msp- 2 confirmed samples revealed that both 3D7 and FC27 allele classes of P. falciparum msp- 2 were present in the study sites. Of the 300 isolates, only 195 were PCR positive for msp- 2. Eighteen different alleles were observed for msp-2 locus, FC27 family being more polymorphic. Analysis showed that 61 (31.0%) had only FC27-type alleles, 38 (19.7%) had only 3D7-type alleles, and 96 (49.3%) had multiple parasite lines with both alleles. Of the total 330 fragments, 145 (43.9%) and 185 (56.1%) belonged to 3D7 and FC27 alleles, respectively [Table 2]. The band sizes were 275–625 bp for FC27 and 150–425 bp for 3D7. Four alleles were observed from LEK, 2 (375–425 bp) and 2 (275–325 bp) of FC27-types and 3D7-types, respectively; 12 alleles from Ajeromi (AJE), 9 (275–625 bp) and 3 (325–425 bp) of FC27-types and 3D7-types, respectively, while IJE had a total of 12 alleles 9 (275–625 bp) and 3 (325–425 bp) of FC27–types and 3D7-types, respectively [Table 3]. The three sites recorded relatively high expected HE values (0.77–0.87) which were highest for IJE (0.87).
|Table 2: Distribution of merozoite surface protein 2 alleles in isolates from the sites studied|
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|Table 3: Merozoite surface protein 2 polymorphism in isolates from 195 Nigerians presenting with Plasmodium falciparum malaria|
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Multiplicity of Plasmodium falciparum infection
Mean MOI was 1.54, while in IJE, Lekki and AJE the MOI was 2.12, 0.86 and 1.33, respectively. MOI was significantly higher in IJE P < 0.05 [Table 3].
Evaluation of cytokine response
IL-1β and IL-12 were significantly higher among participants below 5 years than those ≥5 years [Table 4]. MOI was found to be strongly positively correlated with age (r = 0.79, P = 0.003). There was no significant correlation between MOI and any of Sex, IL-12, IL-1β, TNF-α or type of disease (P > 0.05) [Table 5]. TNF-α response was highest among participants from LEK [Figure 2] and [Figure 3].
|Figure 2: Levels of tumor necrosis factor-α, interleukin-1β and interleukin-12 of participants from the three study sites. = Ijede General Hospital Ijede, Lagos, Nigeria; = St. Kizito Primary Healthcare Centre, Lekki, Lagos, Nigeria; = Ajeromi General Hospital, Ajegunle, Lagos, Nigeria|
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|Figure 3: Distribution of merozoite surface protein-2 families during the cross-sectional sample collection at the three sites. : 3D7: One of the two allelic families of Plasmodium falciparum merozoite surface protein-2; : FC27: The second allelic family of Plasmodium falciparum merozoite surface protein-2|
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|Table 4: Relationship multiplicity of infection with age, sex, cytokines and type of malaria|
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|Table 5: Relationship of merozoite surface protein 2 polymorphisms with pro-in? ammatory cytokines|
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| Discussion|| |
This study investigated the polymorphism of P. falciparum sub-population in Nigeria by nested-PCR typing. The method may not allow differentiation of alleles identical in size but differing in sequence. Acquired immunity to malaria develops as a result of exposure to diverse P. falciparum strains in malaria endemic areas. Increase in the knowledge of the genetic diversity of P. falciparum is required to improve understanding of the pathological mechanisms of malaria, the processes of acquired immunity, the spread and genetic background of drug resistance, and transmission conditions.
MOI and parasite genetic diversity are indicators of malaria infection with significant consideration for place and time in relation to immunity including innate T-Cell immunity in malaria. Contrary to reports by Oyedeji et al. from the northern region of Nigeria and Aubouy et al. from Gabon, our study found higher proportions of FC27-type alleles of msp- 2 than the 3D7-type which was consistent with findings by Kiwuwa et al. from their study in Uganda. These clearly underscore the significance of spatial dynamics in P. falciparum genetic diversity. Over all Mean MOI was low compared to what was reported by Amodu et al. and Ojurongbe et al. This could be expected in view of the myriad of intervention and control measures that must have played a significant role in curbing malaria transmission regardless of seasonality and intensity of infection. MOI was observed for the first time in Ajegunle area of Lagos state to be 1.33 for which IJE community had the highest MOI (2.12) among the three study sites. IJE is the most remote setting of the sites studied with higher proportions of the dwellers being of low socioeconomic status; majorly farmers and low-level civil servants. Malaria transmission is highest in IJE and lowest in LEK as deduced from the MOIs. In all the sites, there was a predominance of FC27 alleles consistent with reports from previous investigations in Nigeria, but contrary to reports from Oceania, Barry et al., and Mohammed et al. This identified the importance of determination of P. falciparum genetic diversity in control, elimination and in vaccine design which has been shown to be strongly related with distance and population differentiation.
The genetic diversity of a parasite population is shaped by various influences, including genetic drift, mutation, natural selection, and gene flow. Msp-2 is the second most abundant protein on the surface of the merozoite and a target of naturally acquired antibodies, and therefore diversity is influenced by immune (balancing) selection.,, Expected HE was found to be high with a narrow range in the three populations studied connoting diverse genetic structure of P. falciparum in these populations taken together. One explanation for the high levels of diversity in all the populations studied is that parasite populations in the region are panmictic. This study also revealed that there was no dependence of genetic diversity or number of genotypes of P. falciparum on the T-cell response and invariably innate immune responses regardless of their involvement in establishing natural immunity against malaria. IL-12, IL-1β, and TNF-α were not significantly correlated with number of genotypes of P. falciparum although IL-1β was significantly correlated with the number of 3D7alleles of msp-2. Findings reported here suggest that the diversity of P. falciparum parasite populations and therefore the resilience to antimalarial interventions will remain high unless the MOI can be significantly reduced. A robust understanding and management of the relationship between immune response, MOI, and genetic diversity is needed in the context of actualizing malaria control in Nigeria. High levels of diversity indicate a malaria population with a greater capacity to evade interventions and thus more difficult to control. Findings from this study will be important in implementing malaria control strategies in the country, as elimination may influence genetic diversity and the resultant heterozygosity of the parasite in Nigeria
| Conclusion|| |
The results of this study showed genetic diversity and allelic distribution in msp-2 in P. falciparum i solates from Lagos, Nigeria. MOI could be instrumental in the evaluation of intervention against malaria, especially involving innate immune responses. However, this needs further studies in several parts of the country, to examine the spatial/periodic changes in the genetic diversity of P. falciparum in Nigeria.
Authors are grateful to the patients who contributed samples for this study, and to the staff, nurses, and doctors of the hospitals visited who facilitated sample collection and the Microbiology Division of the Nigerian Institute of Medical Research, Nigeria, for their support.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
| References|| |
Baum J, Chen L, Healer J, Lopaticki S, Boyle M, Triglia T, et al.
Reticulocyte-binding protein homologue 5 – An essential adhesin involved in invasion of human erythrocytes by Plasmodium falciparum
. Int J Parasitol 2009;39:371-80.
Kyabayinze DJ, Karamagi C, Kiggundu M, Kamya MR, Wabwire-Mangen F, Kironde F, et al.
Multiplicity of Plasmodium falciparum
infection predicts antimalarial treatment outcome in Ugandan children. Afr Health Sci 2008;8:200-5.
Takala SL, Escalante AA, Branch OH, Kariuki S, Biswas S, Chaiyaroj SC, et al.
Genetic diversity in the block 2 region of the merozoite surface protein 1 (MSP-1) of Plasmodium falciparum
: Additional complexity and selection and convergence in fragment size polymorphism. Infect Genet Evol 2006;6:417-24.
Ferreira MU, Hartl DL. Plasmodium falciparum
: Worldwide sequence diversity and evolution of the malaria vaccine candidate merozoite surface protein-2 (MSP-2). Exp Parasitol 2007;115:32-40.
Assefa SA, Preston MD, Campino S, Ocholla H, Sutherland CJ, Clark TG. estMOI: Estimating multiplicity of infection using parasite deep sequencing data. Bioinformatics 2014;30:1292-4.
Ibara-Okabande R, Koukouikila-Koussounda F, Ndounga M, Vouvoungui J, Malonga V, Casimiro PN, Ibara JR, Sidibe A, and Ntoumi F. Reduction of multiplicity of infections but no change in msp2 genetic diversity in Plasmodium falciparum
isolates from Congolese children after introduction of artemisinin-combination therapy. Malar J 2012;11:410.
Aubouy A, Migot-Nabias F, Deloron P. Polymorphism in two merozoite surface proteins of Plasmodium falciparum
isolates from Gabon. Malar J 2003;2:12.
Ntoumi F, Contamin H, Rogier C, Bonnefoy S, Trape JF, Mercereau-Puijalon O. Age-dependent carriage of multiple Plasmodium falciparum
merozoite surface antigen-2 alleles in asymptomatic malaria infections. Am J Trop Med Hyg 1995;52:81-8.
Farouk SE, Dolo A, Bereczky S, Kouriba B, Maiga B, Farnet A, et al
. Different antibody- and cytokine mediated responses to Plasmodium falciparum parasite in two sympatric ethnic tribes living in Mali. Microbes and Infection 2005;7:110-7.
Moncunill G, Mayor A, Jiménez A, Nhabomba A, Puyol L, Manaca MN, et al.
Cytokine and antibody responses to Plasmodium falciparum
in naïve individuals during a first malaria episode: Effect of age and malaria exposure. PLoS One 2013;8:e55756.
Wroczynska A, Nahorski W, Bakowska A, Pietkiewicz H. Cytokines and clinical manifestations of malaria in adults with severe and uncomplicated disease. Int Marit Health 2005;56:103-14.
Fillol F, Sarr JB, Boulanger D, Cisse B, Sokhna C, Riveau G, et al.
Impact of child malnutrition on the specific anti-Plasmodium falciparum
antibody response. Malar J 2009;8:116.
Zhang G, Manaca MN, McNamara-Smith M, Mayor A, Nhabomba A, Berthoud TK, et al.
Interleukin-10 (IL-10) polymorphisms are associated with IL-10 production and clinical malaria in young children. Infect Immun 2012;80:2316-22.
Lyke KE, Burges R, Cissoko Y, Sangare L, Dao M, Diarra I, et al.
Serum levels of the proinflammatory cytokines interleukin-1 beta (IL-1beta), IL-6, IL-8, IL-10, tumor necrosis factor alpha, and IL-12(p70) in Malian children with severe Plasmodium falciparum
malaria and matched uncomplicated malaria or healthy controls. Infect Immun 2004;72:5630-7.
Borges QI, Fontes CJ, Damazo AS. Analysis of lymphocytes in patients with Plasmodium vivax
malaria and its relation to the annexin-A1 and IL-10. Malar J 2013;12:455.
Mayengue PI, Ndounga M, Malonga FV, Bitemo M, Ntoumi F. Genetic polymorphism of merozoite surface protein-1 and merozoite surface protein-2 in Plasmodium falciparum
isolates from Brazzaville, Republic of Congo. Malar J 2011;10:276.
Miller LH, Roberts T, Shahabuddin M, McCutchan TF. Analysis of sequence diversity in the Plasmodium falciparum
merozoite surface protein-1 (MSP-1). Mol Biochem Parasitol 1993;59:1-14.
Oyedeji SI, Awobode HO, Kun J. Limited Genetic diversity and low multiplicity of Plasmodium falciparum infections in children with severe malaria in Lafia, North-central Nigeria. J Exp Clin Med
2013; 5: 143-147.
Kiwuwa MS, Ribacke U, Moll K, Byarugaba J, Lundblom K, Färnert A, et al.
Genetic diversity of Plasmodium falciparum
infections in mild and severe malaria of children from Kampala, Uganda. Parasitol Res 2013;112:1691-700.
|20.|Amodu OK, Olaniyan SA, Omotade OO.
Changes in Plasmodium falciparum
population dynamics in two populations at different time periods in Ibadan, South West Nigeria. Afr J Biomed Res 2015;18:17-22.
Ojurongbe O, Ogungbamigbe TO, Fagbenro-Beyioku AF, Fendel R, Kremsner PG, Kun JF. Rapid detection of Pfcrt and Pfmdr1 mutations in Plasmodium falciparum
isolates by FRET andin vivo
response to chloroquine among children from Osogbo, Nigeria. Malar J 2007;6:41.
Oyebola MK, Idowu ET, Olukosi YA, Iwalokun BA, Agomo CO, Ajibaye OO, et al.
Genetic diversity and complexity of Plasmodium falciparum
infections in Lagos, Nigeria. Asian Pac J Trop Biomed 2014;4 Suppl 1:S87-91.
Barry AE, Schultz L, Senn N, Nale J, Kiniboro B, Siba PM, et al.
High levels of genetic diversity of Plasmodium falciparum
populations in Papua New Guinea despite variable infection prevalence. Am J Trop Med Hyg 2013;88:718-25.
Mohammed H, Mindaye T, Belayneh M, Kassa M, Assefa A, Tadesse M,et al
. Genetic diversity of Plasmodium falciparum isolates based on MSP-1 and MSP-2 genes from Kolla-Shele area, Arbaminch Zuria District, southwest Ethiopia. Malaria journal. 2015;1:1.
Hartl DL, Clark AG. Principles of Population Genetics. Sunderland, MD: Sinauer Associates; 1997.
Sanders PR, Gilson PR, Cantin GT, Greenbaum DC, Nebl T, Carucci DJ, et al.
Distinct protein classes including novel merozoite surface antigens in raft-like membranes of Plasmodium falciparum
. J Biol Chem 2005;280:40169-76.
al-Yaman F, Genton B, Anders R, Taraika J, Ginny M, Mellor S, et al.
Assessment of the role of the humoral response to Plasmodium falciparum
MSP2 compared to RESA and SPf66 in protecting Papua New Guinean children from clinical malaria. Parasite Immunol 1995;17:493-501.
Stanisic DI, Richards JS, McCallum FJ, Michon P, King CL, Schoepflin S, et al.
Immunoglobulin G subclass-specific responses against Plasmodium falciparum
merozoite antigens are associated with control of parasitemia and protection from symptomatic illness. Infect Immun 2009;77:1165-74.
[Figure 1], [Figure 2], [Figure 3]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5]