Two different primate species express an identical functional MHC class I allele

 The products of the highly polymorphic and variable major histocompatibility complex (MHC) class I loci play a crucial role in host defenses against infectious disease. While similar alleles have been found in closely related species, sharing of a functional MHC class I allele between two species has never been reported. Here we show that an identical functional MHC class I molecule is present in two different primate species with an approximate divergence time of 0.7 million years. Lymphocytes from the red-crested tamarin (Saguinus geoffroyi) expressed an MHC class I allele (Sage-G ^* 01) that was identical in coding sequence to an MHC class I allele (Saoe-G ^* 08) found in the cotton-top tamarin (Saguinus oedipus). Furthermore, influenza virus-specific cytotoxic T lymphocytes (CTLs) generated in the cotton-top tamarin killed lymphocytes expressing the influenza virus nucleoprotein (NP) from the red-crested tamarin. Since the influenza virus NP epitope is bound by Saoe-G^*08 in the cotton-top tamarin, it is likely that this molecule is functional in both species. These data provide the first evidence that functional MHC class I molecules can be maintained entirely intact in two separate species. Received: 6 June 1997 / Revised: 21 July 1997     

Cytotoxic T lymphocytes from mice with soluble class I Q10 molecules in their serum are not tolerant to membrane-bound Q10

Q10 is a class I Qa-2 region-encoded molecule that is secreted by the liver and present in serum at high concentrations (about 10 to 60 micrograms/ml) in most strains of mice. The amino terminal portion of this molecule can also be expressed as an integral membrane protein by splicing the 5' end of the Q10 gene to the 3' end of H-2Ld and transfecting the hybrid gene into murine L cells. Because CTL primarily recognize polymorphic determinants controlled by the alpha 1 and alpha 2 domains of class I molecules and because the Q10d/Ld product expressed by transfected L cells includes the alpha 1 and alpha 2 domains of Q10d, we could address whether mice bearing serum Q10 were tolerant to this molecule at the CTL level. The results of these experiments demonstrate that Q10+ mice are able to generate H-2-unrestricted CTL activity against Q10d expressed on transfected L cells, and this response was not inhibitable by the addition of Q10-containing normal mouse serum. It is unlikely that this CTL activity is due to possible polymorphic differences in Q10 alleles, since semisyngeneic BALB/c (H-2d) mice, from which the Q10d hybrid gene construct was derived, are able to generate anti-Q10d effector cells. The Q10d molecule was shown to cross-react with H-2Ld, lending support to the concept that Qa genes can serve as donors for polymorphic sequences found in H-2K, -D, and -L. That mice can generate anti-Q10 CTL activity suggests that this soluble class I protein does not act as a toleragen for these cells. The implications of these findings for an understanding of self-tolerance are discussed.     

Individual MHC class I and MHC class IIB diversities are associated with male and female reproductive traits in the three-spined stickleback

Genes of the major histocompatibility complex (MHC) are indispensable for pathogen defence in vertebrates. With wild-caught three-spined sticklebacks (Gasterosteus aculeatus) we conducted the first study to relate individual reproductive parameters to both MHC class I and II diversities. An optimal MHC class IIB diversity was found for male nest quality. However, male breeding colouration was most intense at a maximal MHC class I diversity. One MHC class I allele was associated with male redness. Similarly, one MHC class IIB allele was associated with continuous rather than early female reproduction, possibly extending the reproductive period. Both alleles occurred more frequently with increasing individual allele diversity. We suggest that if an allele is currently not part of the optimum, it had not been propagated by choosy females. The parasite against which this allele provides resistance is therefore unlikely to have been predominant the previous year - a step to negative frequency-dependent selection.     

Secretion of a soluble class I molecule encoded by the Q10 gene of the C57BL/10 mouse

The DNA sequence of the Q10 genes appears to be highly conserved amongst strains of mice and has only been found to be transcribed in the liver. An examination of the nucleotide sequence of the exon that normally encodes the transmembrane domain of class I molecules suggested that the Q10 gene encodes a secreted protein. We have established this by showing that L cells transformed with an expression vector containing the Q10 gene secrete a class I molecule which was identified with an antiserum raised against a peptide predicted by the Q10 transmembrane exon. Both the L cell-derived Q10 molecule and a class I protein immunoprecipitated from serum with this anti-peptide antiserum have mol. wts. of approximately 38 000; the Q10 molecule secreted by L cells is heterogeneous in mol. wt. This heterogeneity was drastically reduced after endoglycosidase F treatment, suggesting that Q10 molecules secreted into the serum by the liver may be glycosylated differently from those secreted by L cells. Endoglycosidase F treatment of both the L cell and serum forms of the soluble molecule yielded two products with mol. wts. of approximately 32 000 and 35 000; this is consistent with the observation that the predicted Q10 protein sequence has two potential glycosylation sites. In contrast to previous published results, the Q10 molecule reacted with rabbit anti-H-2 antisera which is consistent with its greater than 80% homology to the classical transplantation antigens.     

Sequence of the mouse Q4 class I gene and characterization of the gene product

The Q4 class I gene has been shown to participate in gene conversion events within the mouse major histocompatibility complex. Its complete genomic nucleotide sequence has been determined. The 5 half of Q4 resembles H-2 genes more strongly than other Q genes. Its 3 end, in contrast, is Q-like and contains a translational stop signal in exon 5 which predicts a polypeptide with an incomplete membrane spanning segment. The presence of two inverted B1 repeats suggests that part of the Q4 gene may be mobile within the genome. Gene transfer experiments have shown that the Q4 gene encodes a ²-microglobulin associated polypeptide of M_r 41 000. A similar protein was found in activated mouse spleen cells. The Q4 polypeptide was found to be secreted both by spleen cells and by transfected fibroblasts and was not detectable on the cell surface. Antibody binding and two-dimensional gel electrophoresis indicate that the Q4 molecule is identical to a mouse class I polypeptide, Qb-1, which has been previously described.