Human cytomegalovirus (HCMV) infects a number of organs and cell types in vivo, leading to the hypothesis that HCMV disease and tissue tropism may be related to specific sequence variants. A potential component of HCMV variant strains is the UL144 open reading frame (ORF), which encodes a homologue of the herpesvirus entry mediator, HveA, a member of the tumor necrosis factor receptor superfamily. Sequence analysis of the UL144 ORF in 45 low-passage clinical isolates demonstrated significant strain-specific variability. In individual isolates, nucleotide substitutions occur at up to 21% of the 531 positions, resulting in approximately the same percentage of substitutions in the predicted 176-amino-acid sequence. Phylogenetic analysis indicated that the nucleotide and amino acid sequences diverge into three major groups. For genotypic comparison, the known hypervariable region encompassing the proteolytic cleavage site of the glycoprotein B (gB) gene was also sequenced. All of the isolates could be typed according to the four known gB groups; however, the gB and UL144 sequence groups appeared to be phylogenetically unlinked. The predicted UL144 product homology with tumor necrosis factor receptor family members, along with the unexpectedly high level of sequence variability of the UL144 ORF, suggests that the predicted product may play a role in HCMV infectivity and subsequent host disease.
A unique feature of rabbit Ig is the presence of VH region allotypic specificities. In normal rabbits, more than 80% of circulating immunoglobulin molecules bear the VHa allotypic specificities, al, a2 or a3; the remaining 10% to 20% of immunoglobulin molecules lack VHa allotypic specificities and are designated VHa-. A mutant rabbit designated Alicia, in contrast, has predominantly serum immunoglobulin molecules that lack the VHa allotypic specificities (Kelus and Weiss, Proc. Natl. Acad. Sci. USA 1986. 83: 4883). To study the nature and molecular complexity of VHa- molecules, we cloned and determined the nucleotide sequence of seven cDNA prepared from splenic RNA of an Alicia rabbit. Six of the clones appeared to encode VHa- molecules; the framework regions encoded by these clones were remarkably similar to each other, each having an unusual insertion of four amino acids at position 10. This insertion of four amino acids has been seen in only 2 of 54 sequenced rabbit VH genes. The similarity of the sequences of the six VHa- clones to each other and their dissimilarity to most other VH genes leads us to suggest that the VHa- molecules in Alicia rabbits are derived predominantly from one or a small number of very similar VH genes. Such preferential utilization of a small number of VH genes may explain the allelic inheritance of VH allotypes.
In this study we investigate the molecular genetic basis for VHa- Ig. Knowing that the expression of VHa allotype Ig is suppressed by neonatal injection of rabbits with anti-VHa allotype antibody, and that the decreased level of VHa allotype Ig, VHa+, in the suppressed rabbits is compensated for by an increase in VHa- Ig, we determined the nucleotide sequences of 41 VDJ genes from a2/a2 rabbits neonatally suppressed for the expression of a2 Ig. We compared these nucleotide sequences to each other and identified two groups of VH sequences. We predict that the molecules of each group are encoded by one germline VH gene. Inasmuch as VHa+ Ig is encoded predominantly by one germline VH gene, VH1, it appears that more than 95% of the VDJ repertoire of rabbits may be encoded by as few as three germline VH genes. A genomic VDJ gene whose VH sequence was similar to those of group I molecules was expressed in vitro and was shown by ELISA to encode molecules of the VHa- allotype, y33. Analysis of the D regions in the VDJ gene indicated that germline D2b and D3 gene segments were preferentially used in the VDJ gene rearrangement. A comparison of sequences of D regions of the 41 VDJ gene rearrangements in 3-, 6-, and 9-wk-old rabbits to sequences of germline D gene segments showed an accumulation of mutations in the D region. Inasmuch as we have previously shown that V regions of rabbit VDJ genes are diversified, in part, by somatic gene conversion, it appears now that rabbit VDJ genes diversify by a combination of somatic mutation and somatic gene conversion.
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