A method for cloning full-length HLA-A,B cDNA (1.1 kilobases) by using the polymerase chain reaction (PCR) is described. Six HLA-AB alleles (HLA-A2, -A25, -B7, -B37, -B51, and -B57) were cloned, and their structures were determined. Multiple PCR clones for each allele were sequenced to obtain both an accurate consensus sequence and an "authentic" done having that sequence. Sequences from 50 clones encoding five different alleles permit assessment of the frequency and nature of PCR-produced errors. These include recombinations, deletions, and insertions in addition to point substitutions. Authentic clones were obtained at a frequency of between 30% and 70%, and analysis of three or four clones generally should be sufficient for characterization of an allele.
The Kaingang and Guarani are culturally and linguistically distinct tribes of southern Brazil. Like all Amerindian groups they show limited HLA polymorphism, which probably reflects the small founder populations that colonized America by overland migration from Asia 11,000-40,000 years ago. We find the nucleotide sequences of HLA-B alleles from the Kaingang and Guarani to be distinct from those characterized in caucasian, oriental and other populations. By comparison, the HLA-A and C alleles are familiar. These results and those reported in the accompanying paper on the Waorani of Ecuador reveal that a marked evolution of HLA-B has occurred since humans first entered South America. New alleles have been formed through recombination between pre-existing alleles, not by point mutation, giving rise to distinctive diversification of HLA-B in different South American Indian tribes.
SummaryThe HLA-C locus remains an enigma. The serological polymorphism is poorly defined, HLA-C molecules are expressed at the cell surface at about 10% the levels of HLA-A and -B, and their importance for antigen presentation to either CDS-bearing T cells or natural killer cells is undear. Our understanding of HLA-C polymorphism has also lagged behind that of HLA-A and -B. We have applied the polymerase chain reaction to the characterization of eDNA encoding HLA-C antigens. Combining the recent results with previously characterized HLA-C alleles gives a data base of 26 sequences, which was used to analyze the nature of HLA-C polymorphism and compare it to the variation seen in HLA-A and -B. The sequences form 10 families of alleles that correlate well with the patterns of serological crossreactivity, including the C blanks, and all major HLA-C allelic families appear to have been sampled. The families further divide into two groups of HLA-C alleles defined on the basis of linked substitutions in the 3' exons. In comparison with HLA-A and -B, HLA-C alleles are more closely related to each other, there being less variation in residues of the antigen recognition site and more variation at other positions. In particular, the helix of the (xl domain of HLA-C molecules is unusually conserved. Despite the reduced diversity in the antigen recognition site, it is evident that HLA-C genes have been the target of past selection for polymorphism. Within the antigen recognition site, it is the ol1 domain that is most diagnostic of HLA-C, whereas the o~2 domain is similar to that of HLA-B, the locus to which HLA-C is most closely related. In particular, conserved motifs in the or1 helix and the conserved glycine at the base of the B pocket (position 45) provide a combination of features that is uniquely found in HLA-C molecules. We hypothesize that these features restrict the peptides bound by HLA-C molecules and in this manner reduce the efficiency of HLA-C assembly and expression at the cell surface. The overall picture of HLA-C polymorphism obtained from this sampling of HLA-C alleles is unlikely to change as further alleles are characterized.
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