BACKGROUND: A potential problem for malaria vaccine development and testing is between-host variation in antibody responses to specific malaria antigens. Previous work in adults in an area highly endemic for Plasmodium falciparum in Papua New Guinea found that genetic regulation partly explained heterogeneity in responsiveness. We have now assessed the relative contributions of environmental and genetic factors in total IgG responses to specific malaria antigens in children, and quantified temporal variation within individuals of total IgG responses. METHODS: Total IgG responses against schizont extract, merozoite surface protein-1, merozoite surface protein-2, ring-infected erythrocyte surface antigen, and SPf66 were measured by ELISA. Variance component analysis was used to estimate the variation explained by genetic and environmental factors in these antibody responses. Intra- and inter-class correlations of antibody responses within relative pairs were estimated. We adjusted for age, P. falciparum density, sex and village differences either within or prior to the analysis. RESULTS: For all malaria antigens, temporal variation in the total IgG response was the predominant source of variation. There was substantial familial aggregation of all IgG responses, but it remained unclear how much this clustering was attributable to genetic factors and how much to a common environment in the household. The remaining variance, which could not be explained by either of the above, was very small for most of the antigens. CONCLUSIONS: Temporal variation and clustering of immune responses to specific malaria antigens need to be taken into account when planning, conducting and interpreting immuno-epidemiological and vaccine studies.
BACKGROUND: A potential problem for malaria vaccine development and testing is between-host variation in antibody responses to specific malaria antigens. Previous work in adults in an area highly endemic for Plasmodium falciparum in Papua New Guinea found that genetic regulation partly explained heterogeneity in responsiveness. We have now assessed the relative contributions of environmental and genetic factors in total IgG responses to specific malaria antigens in children, and quantified temporal variation within individuals of total IgG responses. METHODS: Total IgG responses against schizont extract, merozoite surface protein-1, merozoite surface protein-2, ring-infected erythrocyte surface antigen, and SPf66 were measured by ELISA. Variance component analysis was used to estimate the variation explained by genetic and environmental factors in these antibody responses. Intra- and inter-class correlations of antibody responses within relative pairs were estimated. We adjusted for age, P. falciparum density, sex and village differences either within or prior to the analysis. RESULTS: For all malaria antigens, temporal variation in the total IgG response was the predominant source of variation. There was substantial familial aggregation of all IgG responses, but it remained unclear how much this clustering was attributable to genetic factors and how much to a common environment in the household. The remaining variance, which could not be explained by either of the above, was very small for most of the antigens. CONCLUSIONS: Temporal variation and clustering of immune responses to specific malaria antigens need to be taken into account when planning, conducting and interpreting immuno-epidemiological and vaccine studies.
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Keywords:
Age Factors; Antibodies; Antigen-antibody Reactions; Biology; Child; Clinical Research; Demographic Factors; Developing Countries; Diseases; Hematological Effects; Hemic System; Immunity; Immunoglobulin Alterations; Immunologic Factors; Malaria; Melanesia; Oceania; Papua New Guinea; Parasitic Diseases; Physiology; Population; Population Characteristics; Research Methodology; Research Report; Youth
Authors: Kpandja Djawe; Kieran R Daly; Sergio L Vargas; M Elena Santolaya; Carolina A Ponce; Rebeca Bustamante; Judith Koch; Linda Levin; Peter D Walzer Journal: Int J Infect Dis Date: 2010-12 Impact factor: 3.623
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Authors: Samia E Mirghani; Bakri Y M Nour; Sayed M Bushra; Ibrahim M Elhassan; Robert W Snow; Abdisalan M Noor Journal: Malar J Date: 2010-06-18 Impact factor: 2.979
Authors: Margaret J Mackinnon; Tabitha W Mwangi; Robert W Snow; Kevin Marsh; Thomas N Williams Journal: PLoS Med Date: 2005-11-08 Impact factor: 11.069