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ASSOCIATION OF FC RECEPTOR IIA (CD32) POLYMORPHISM WITH MALARIAL ANEMIA AND HIGH-DENSITY PARASITEMIA IN INFANTS AND YOUNG CHILDREN

ABSTRACT

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Protective immunity against Plasmodium falciparum is partially mediated through binding of malaria-specific IgG antibodies to Fc receptors. Polymorphic variability in Fc RIIa (H/R-131) is associated with differential binding of IgG subtypes and malaria disease outcomes. However, the role of Fc RIIa-131 variability in conditioning susceptibility to severe malarial anemia, the primary manifestation of severe malaria in holoendemic P. falciparum transmission areas, is largely undefined. Thus, Fc RIIa-H131R polymorphism was investigated in 493 children who came to a hospital with acute malaria. Variation in Fc RIIa-131 was not significantly associated with severe malarial anemia (hemoglobin [Hb] < 6.0 g/dL) or malaria anemia (Hb < 8.0 g/dL). However, relative to the heterozygous genotype, homozygotes for the R131 alleles were protected against high-density parasitemia ( 10,000 parasites/µL; odds ratio [OR] = 0.58, 95% confidence interval [CI] = 0.37–0.92, P = 0.02), while homozygotes for the H131 alleles were mildly protective (OR = 0.71, 95% CI = 0.45–1.13, P = 0.14). Additional multivariate analyses showed that infection with human immunodeficiency virus type 1 did not influence the associations between FcRIIa-H131R polymorphism and malaria disease outcomes. Genotypic results presented here parallel data illustrating that parasite density is unrelated to the severity of anemia in children with acute malaria. Thus, although homozygosity for the R131 allele protects against high-density parasitemia, FcRIIa-131 polymorphism does not protect against malaria anemia.

INTRODUCTION

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One of the most common causes of morbidity and mortality in African children is Plasmodium falciparum malaria in which severe manifestations of disease are defined by one or more of the following: high-density parasitemia (HDP), hypoglycemia, cerebral malaria (CM), severe malarial anemia (SMA), and respiratory distress. Among these disease sequelae, SMA is responsible for the greatest degree of malaria-associated morbidity and mortality worldwide.¹

Naturally acquired antibodies are important for protection against asexual blood stages of malaria as shown by passive transfer of immunoglobulin (IgG) from malaria-immune adults to malaria-naive children.² Binding of the heavy chain immunoglobulin domain to Fc receptors on phagocytic cells is important for protective immunity against malaria. FcRIIa (CD32) is a predominate low-affinity Fc-receptor expressed on monocytes and macrophages, and other immune cells, that binds to all IgG subtypes (IgG_1–4),³ thereby providing an important link between humoral and cellular malarial immunity.

A non-synonymous single nucleotide polymorphism in FcRIIa that changes a histidine (H) to an arginine (R) residue at position 131 is associated with differing susceptibilities to severe malaria. Previous studies in a holoendemic P. falciparum transmission area of western Kenya showed that the R/R131 genotype that preferentially binds IgG₁ and IgG₃⁴ is protective against parasitemia (> 5,000 parasite/µL) relative to the H/R131 genotype.⁵ Additional investigations in The Gambia demonstrated that homozygous H131 alleles that preferentially bind IgG₂⁶ increase susceptibility to malaria in children with a mixed clinical phenotype of severe disease: CM, SMA, and/or hypoglycemia.⁷ In contrast, although none of the FcRIIa-131 genotypes were associated with susceptibility to CM in Thai adults, haplotype analysis showed that the FcRIIIB-NA2 and FcRIIa-HH131 alleles together increased susceptibility to CM.⁸ Defining the association between FcRIIa-131 genotypes and malarial anemia (MA) in infants and young children residing in holoendemic P. falciparum transmission areas is important because this clinical phenotype accounts for the largest degree of malaria-induced morbidity and mortality. The role of FcRIIa-131 polymorphism in regulating susceptibility to SMA (hemoglobin [Hb] < 6.0 g/dL) and MA (Hb < 8.0 g/dL) was therefore examined in children less than three years of age who came to a hospital in a rural holoendemic P. falciparum area of western Kenya. The association between FcRIIa-131 polymorphism and HDP ( 10,000 parasites/µL) was also determined.

METHODS

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Study participants. A total of 493 children were recruited as part of an ongoing study of SMA at Siaya District Hospital in western Kenya. Data presented are for the cross-sectional analyses in which study participants had their first hospital contact for malaria. In this holoendemic area of P. falciparum transmission,⁹ SMA and hyperparasitemia are the most common clinical manifestations of severe malaria, with CM occurring only in rare cases.¹⁰ Greater than 99% of the study participants were from the Luo ethnic group. Definitions of disease severity were based on a previous large-scale longitudinal study examining the distribution of Hb concentrations in children less than four years of age in western Kenya.¹¹ Children were categorized into four groups based on the presence of parasitemia (any density) and severity of anemia (Table 1). Administration of antimalarials and appropriate supportive therapy was provided to all children as per Kenya Ministry of Health guidelines.

Laboratory procedures. Parasitemia and Hb concentrations were determined in heel or finger prick blood (< 100 µL) and venipuncture samples (< 2.0 mL), respectively. Asexual malaria parasites were counted against 300 leukocytes in peripheral blood smears stained with Giemsa, assuming a count of 8,000 white blood cells/µL of blood. Hemoglobin concentrations were determined on a Beckman Coulter AcT diff2^TM (Beckman-Coulter Corporation, Miami, FL).

Diagnosis of HIV-1 status. Exposure to HIV-1 was determined through the use of two rapid serologic test methods (Unigold^TM and Determine^TM). Children with single- or double-positive serologic results were further evaluated for HIV-1 infection by a nested PCR of proviral DNA extracted from dried blood spots collected on foam tipped applicators (FTA) classic cards (Whatman Inc., Florham Park, NJ). HIV-1 gp41 primers were selected for highly conserved HIV-1 group M, N, and O sequences for use in western Kenya.^12,13 The PCR results were confirmed on fresh samples approximately three months after the initial test.

Genotyping. DNA was extracted from blood spots using the Chelex method.¹⁴ FcRIIa-131 genotypes were determined using previously described methods by gene-specific PCR amplification on a PTC-100^TM thermocycler (MJ Research Inc.), followed by allele-specific restriction enzyme digestion with Bst UI (New England Biolabs, Beverly, MA).¹⁵ The BstUI digestion of the PCR product (366 basepairs) produced a 322-basepair fragment for the RR131 genotype, a 343-basepair fragment for the HH131 genotype, and both fragments for the HR131 genotype.

Statistical analyses. Statistical analyses were conducted using Minitab Release 13.32 (Minitab Inc., State College, PA). Kruskal-Wallis tests were used for multiple group comparisons and differences between proportions were determined by chi-square analyses. Logistic regression controlling for age, sex, and prevalence of sickle-cell trait (HbAS), was used to examine the association of FcRIIa-131 polymorphism with SMA, MA, and HDP. Additional multivariate analyses controlling for HIV-1 infection were also conducted to determine the impact of HIV-1 on the association between FcRIIa-131 polymorphism and malaria disease outcomes. Based on a previous study that reported more than 10,000 longitudinal Hb measurements in an age- and geographically matched reference population,¹¹ SMA was classified as an Hb concentration < 6.0 g/dL and any density parasitemia. Malarial anemia was defined as an Hb concentration < 8.0 g/dL and any density parasitemia because this criteria identifies those children at greatest risk of malaria-related morbidity and mortality,¹⁶ while HDP was based on a standard definition with parasites/µL 10,000. The HR131 genotype was used as the reference in the logistic regression analyses because it was the most prevalent genotype in the population. Statistical significance was defined as P 0.05.

RESULTS

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Characteristics of study participants. A total of 493 children with acute malaria were included in the study. When categorized according to the case definitions shown in Table 1, 38 (7.7%) had uncomplicated malaria (UM), 155 (31.4%) had mild MA (MlMA), 141 (28.6%) had moderate MA (MdMA), and 159 (32.3%) had SMA. Demographic and clinical characteristics of the study participants are shown in Table 2. There were significant differences in age (months) and Hb concentrations (g/dL) between the groups (P < 0.001 and P < 0.001, respectively, Table 2). The proportion of males versus females, parasite density (parasites/µL), and the proportion of children with HDP ( 10,000 parasites/µL) were not significantly different between the groups (P = 0.08, P = 0.59, and P = 0.87, respectively, Table 2).

Distribution of FcRIIa genotypes among disease categories.

View this table: [in this window] [in a new window]   TABLE 3 Distribution of FcRIIa-131 genotypes in the different disease categories*

Association of FcRIIa genotypes with malaria disease severity.

View this table: [in this window] [in a new window]   TABLE 4 Association of FcRIIa-131 genotypes with malaria disease severity*

DISCUSSION

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Results presented here demonstrate that the R/R131 genotype is significantly associated with protection against HDP and that homozygous H131 alleles were mildly protective against HDP. These results are similar to previous studies in an adjacent area of western Kenya in which the R/R131 genotype was associated with protection against a lower threshold of parasitemia (> 5,000 parasites/µL) during the first year of life.⁵ Although the association between FcRIIa-131 variation and MA has not been reported for holoendemic P. falciparum transmission areas, results presented here show that the R/R131 and H/H131 genotypes were non-significantly associated with a decrease in the risk of MA (Hb < 8.0 g/dL), but not with SMA (Hb < 6.0 g/dL). These results may reflect that parasite density and the degree of anemia are not strongly associated in infants and young children with acute malaria in this geographic location.

In a large cohort in The Gambia, cross-sectional analyses showed that the H/H131 genotype was associated with increased malaria disease severity, particularly in children less than five years of age.⁷ Although severe malaria in this population was defined by a mixed phenotype of disease (CM, SMA, and/or hypoglycemia), the H/H131 genotype was non-significantly more prevalent in those with SMA compared with aparasitemic children.⁷ Another cross-sectional study in Thai adults showed that the H/H131 genotype, together with the FcRIIIB-NA2 allele, was associated with increased susceptibility to CM.⁸ Differences in results presented here showing that homozygosity for the H131 allele was non-significantly protective against HDP and MA versus previous findings likely reflect diverse immunoprotective responses to malaria conditioned by different exposure rates (i.e., hyper-endemic versus holoendemic). In addition, since CM is a rare clinical manifestation of severe malaria in the study cohort and homozygous H131 alleles apparently increase susceptibility to CM, the effect of the H/H131 genotype may not be observed in a population in which the primary disease outcome of severe malaria is MA.

Previous findings showed that relative to H/R131 genotype, 1) homozygous H131 alleles are associated with increased HIV-1 prevalence in children born to HIV-positive mothers,¹⁹ and 2) the H/H131 genotype is correlated with increased prevalence of placental malaria in HIV-positive women.²⁰ However, results presented here demonstrate that HIV-1 infection did not impact on the association of the FcRIIa-131 genotypes with SMA, MA, and HDP.

The protective role of R/R131 against HDP may be due to the preferential binding of cytophilic IgG1 and IgG3 subtypes, which have been shown to mediate opsonization of parasitized red blood cells in vitro and enhance phagocytosis of these cells by monocyte/macrophages.²¹ Furthermore, previous in vitro studies demonstrated that cytophilic IgG₁ and IgG₃ subtypes, as opposed to IgG₂ and IgG₄, provide protective immunity against malaria through the ability of monocytes to mediate antibody-dependent cellular inhibition (ADCI) of asexual blood stage merozoites.²² However, it is unclear if ADCI can affect merozoite clearance in vivo because merozoites rapidly invade red blood cells and additionally, schizonts surrounded by rosettes of red blood cells may be protected against ADCI. In the context of findings presented here, which showed a protective effect against HDP and non-significant protection against MA, the selectivity of the R/R131 genotype for binding to IgG₁ and IgG₃ suggests that homozygous R131 alleles may increase parasite clearance, but may not be highly protective against MA in infants and young children who are largely malaria-naive. These results are consistent with the fact that both parasite density and HDP are relatively equivalent in the different disease categories, even though the degree of anemia during acute malaria is markedly different between the groups. Since MA is multifactorial and is influenced by nutritional deficiencies, hemoglobinopathies, and co-infection with other anemia-promoting pathogens, it is not unexpected that genetic variation can be associated with protection against HDP, but not MA. By following the children longitudinally and determining the co-factors responsible for anemia, it should be possible to determine the effect of FcRIIa-131 polymorphic variants on susceptibility to MA as the children acquire protective malarial immunity during the first three years of life. The fact that homozygous R131 alleles protect against HDP, but not MA, the primary cause of morbidity and mortality in holoendemic P. falciparum transmission areas, underscores the complexity associated with determining critical host immune response genes that protect against severe disease outcomes.

In addition to IgG₁ and IgG₃, protective immunity against malaria may also involve IgG₄, as shown by studies demonstrating a significant decrease in the level of IgG₃ and enhancement of IgG₄ anti–variant surface antigens (VSA) responses in aparasitemic malaria-exposed children.²³ In those studies, clinical protection and prolonged intervals between malaria parasitemia were associated with high levels of IgG₄ and antibodies to VSA IgG₁ in severe and mild P. falciparum malaria, respectively. In results presented here, the H/H131 genotype that binds efficiently to IgG₂, as well as IgG₁ and IgG₃,⁴ was associated with mild protection against HDP. This is in agreement with previous observations that IgG₂ antigen-specific responses may correlate with disease protection, even though these antibodies appear less protective than IgG₁ and IgG₃.²⁴ Additional studies are required to resolve the role of IgG₂ in mediating protective immunity against malaria and the impact of FcRIIa polymorphic variants on conditioning disease outcomes.

Received August 12, 2005. Accepted for publication September 27, 2005.

Acknowledgments: We thank the Siaya District Hospital team and the University of Pittsburgh/Kenya Medical Research Institute staff for their technical support. We also thank all the parents and guardians of the study participants and the children who participated in the study. These data are published with the approval of Dr. Davy Koech, Director of Kenya Medical Research Institute.

Financial support: This work was supported by grants from the National Institute of Health (AI51305-02 and TW05884-02) to Douglas J. Perkins.

Disclosure: None of the authors has any conflicts of interest due to commercial or other affiliations.

^* Address correspondence to Douglas J. Perkins, Department of Infectious Diseases and Microbiology, University of Pittsburgh Graduate School of Public Health, 130 DeSoto Street, 603 Parran Hall, Pittsburgh, PA 15261. E-mail: djp{at}pitt.edu

Authors’ addresses: Collins Ouma, Dorothy A. Opondo, Tom Were, Richard O. Otieno, and John M. Ong’echa, University of Pittsburgh/Kenya Medical Research Institute Laboratories of Parasitic and Viral Diseases, Kisumu, Kenya and Center for Vector Biology and Control Research, Medical Research Institute, P.O. Box 1578, Kisumu, Kenya. Christopher C. Keller and Douglas J. Perkins, Department of Infectious Diseases and Microbiology, University of Pittsburgh, 603 Parran Hall, 130 DeSoto Street, Pittsburgh, PA 15261, PA, Telephone: 412-624-5894, Fax: 412-624-4953, E-mail: djp{at}pitt.edu. Michael F. Otieno, Department of Pre-Clinical Sciences, Kenyatta University, P.O. Box 43844, Nairobi, Kenya. Alloys S. S. Orago, National AIDS Control Council, P.O. Box 61307, Nairobi, Kenya. John M. Vulule, Center for Vector Biology and Control Research, P.O. Box 1578, Kisumu, Kenya. Robert E. Ferrell, Department of Human Genetics, University of Pittsburgh, Graduate School of Public Health, A304 Crabtree Hall, DeSoto Street, Pittsburgh, PA 15261, Telephone: 412-624-3018, Fax: 412-624-3020.

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This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via ISI Web of Science (2) Citing Articles via Google Scholar Google Scholar Articles by OUMA, C. Articles by PERKINS, D. J. Search for Related Content PubMed PubMed Citation Articles by OUMA, C. Articles by PERKINS, D. J. Pubmed/NCBI databases Gene GEO Profiles HomoloGene UniGene Medline Plus Health Information Anemia