TY - JOUR
T1 - An evolutionary approach to major histocompatibility diversity based on allele supertypes
AU - Naugler, Christopher
AU - Liwski, Robert
PY - 2008
Y1 - 2008
N2 - Human leukocyte antigens are traditionally classified by serologic or molecular techniques into a bewildering variety of alleles. It is generally believed that this allelic diversity is maintained by selection pressures for inbreeding avoidance and/or maximal immune system diversity. While the usual antigen-based classification of individual alleles may be most appropriate in the artificial situation of tissue transplantation, we hypothesize that a functional classification based on allele supertypes may represent a more biologically relevant way to view MHC diversity in the contexts of mate choice and disease pathogenesis. Furthermore, immune system diversity could be quantitatively estimated by calculating a Supertype Diversity Index (SDI) which is the number of different MHC supertypes possessed by an individual. This hypothesis generates a number of testable predictions. First, it predicts that a reduced inherited diversity of MHC allele supertypes may predispose to the development of malignancies because of a decreased native ability to present different tumor-associated antigens. Furthermore, specific autoimmune diseases may be associated with the presence or absence of a particular MHC supertype rather than a particular MHC haplotype. In transplant medicine, it is possible that unmatched alleles may trigger a weaker foreign antigen response if they are matched by allele supertype. Finally, there have been several studies documenting dissortative mating in humans for dissimilar MHC alleles. We predict that natural selection should favor maximization of the heterozygosity of allele supertypes instead of the heterozygosity of individual alleles and that the previously observed dissortative mating may actually be an adaptive strategy to maximize allele supertype diversity.
AB - Human leukocyte antigens are traditionally classified by serologic or molecular techniques into a bewildering variety of alleles. It is generally believed that this allelic diversity is maintained by selection pressures for inbreeding avoidance and/or maximal immune system diversity. While the usual antigen-based classification of individual alleles may be most appropriate in the artificial situation of tissue transplantation, we hypothesize that a functional classification based on allele supertypes may represent a more biologically relevant way to view MHC diversity in the contexts of mate choice and disease pathogenesis. Furthermore, immune system diversity could be quantitatively estimated by calculating a Supertype Diversity Index (SDI) which is the number of different MHC supertypes possessed by an individual. This hypothesis generates a number of testable predictions. First, it predicts that a reduced inherited diversity of MHC allele supertypes may predispose to the development of malignancies because of a decreased native ability to present different tumor-associated antigens. Furthermore, specific autoimmune diseases may be associated with the presence or absence of a particular MHC supertype rather than a particular MHC haplotype. In transplant medicine, it is possible that unmatched alleles may trigger a weaker foreign antigen response if they are matched by allele supertype. Finally, there have been several studies documenting dissortative mating in humans for dissimilar MHC alleles. We predict that natural selection should favor maximization of the heterozygosity of allele supertypes instead of the heterozygosity of individual alleles and that the previously observed dissortative mating may actually be an adaptive strategy to maximize allele supertype diversity.
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U2 - 10.1016/j.mehy.2007.09.015
DO - 10.1016/j.mehy.2007.09.015
M3 - Article
C2 - 18063318
AN - SCOPUS:40849098908
SN - 0306-9877
VL - 70
SP - 933
EP - 937
JO - Medical Hypotheses
JF - Medical Hypotheses
IS - 5
ER -