HLA class I genes: from structure to expression, serology and function.

HLA class I genes have been isolated from phage and cosmid libraries and assayed by transfection into murine L cells. The transfection step proved to be very important because of the large number of genes (and pseudogenes) in this family. All functional genes characterized so far in this way are "classical" class I genes, i.e. members of the HLA-A, -B or -C families. Three of these have been sequenced (HLA-A3, -Aw24; HLA-Cw3) in addition to the pHLA 12.4 pseudogene. Sequence comparisons indicate, in particular, extreme conservation of the 3' non-coding region between allelic HLA-A locus genes; the general organization of all these genes (8 exons) is very similar. Restriction mapping around the functional genes has been performed to investigate the degree of conservation (e.g. between HLA-A3 regions from 2 different individuals) and examine allelism at the DNA level (e.g. between HLA-A3 and HLA-Aw24 regions). Exon shuffling experiments followed by serological analysis of the expressed product indicate that, as expected, specificities are determined by the first two domains of the molecule. However, further constructs show that as soon as a single exon is exchanged most specific reactivities disappear. CTL analysis of murine cells expressing HLA molecules has run into many difficulties but still holds promise for the study of structure-function relationships in this system.

Allelism in the HLA class I multigene family.

Recent data on the structure of functional HLA class I genes shows that, at least at the HLA-A locus, the allelic genes are more related to each other than to HLA genes from other loci. This "A-ness" is discernible at the protein sequence level but much more evident when nucleotide sequences are compared; the homology is particularly striking in the 3' non-coding region. Genes coding for the same HLA specificity in different genetic backgrounds show no obvious difference, although in one case the 3' flanking regions are clearly different; the restriction maps around the HLA-A3 and HLA-AW24 genes are also compared to see whether the chromosomal environments of these two genes are recognizably similar.

Complete nucleotide sequence of a gene encoding a functional human class I histocompatibility antigen (HLA-CW3).

The HLA-CW3 gene contained in a cosmid clone identified by transfection expression experiments has been completely sequenced. This provides, for the first time, data on the structure of HLA-C locus products and constitutes, together with that of the gene coding for HLA-A3, the first complete nucleotide sequences of genes coding for serologically defined class I HLA molecules. In contrast to the organisation of the two class I HLA pseudogenes whose sequences have previously been determined, the sequence of the HLA-CW3 gene reveals an additional cytoplasmic encoding domain, making the organisation of this gene very similar to that of known H-2 class I genes and also the HLA-A3 gene. The deduced amino acid sequences of HLA-CW3 and HLA-A3 now allow a systematic comparison of such sequences of HLA class I molecules from the three classical transplantation antigen loci A, B, C. The compared sequences include the previously determined partial amino acid sequences of HLA-B7, HLA-B40, HLA-A2 and HLA-A28. The comparisons confirm the extreme polymorphism of HLA classical class I molecules, and permit a study of the level of diversity and the location of sequence differences. The distribution of differences is not uniform, most of them being located in the first and second extracellular domains, the third extracellular domain is extremely conserved, and the cytoplasmic domain is also a variable region. Although it is difficult to determine locus-specific regions, we have identified several candidate positions which may be C locus-specific.

Complete nucleotide sequence of a functional class I HLA gene, HLA-A3: implications for the evolution of HLA genes.

The complete nucleotide sequence of an active class I HLA gene, HLA-A3, has been determined. This sequence, together with that obtained for the HLA-CW3 gene, represents the first complete nucleotide sequence to be determined for functional class I HLA genes. The gene organisation of HLA-A3 closely resembles that of class I H-2 genes in mouse: it shows a signal exon, three exons encoding the three extracellular domains, one exon encoding the transmembrane region and three exons encoding the cytoplasmic domain. The complete nucleotide sequences of the active HLA genes, HLA-A3 and HLA-CW3, now permit a meaningful comparison of the nucleotide sequences of class I HLA genes by alignment with the sequence established for a HLA-B7-specific cDNA clone and the sequences of two HLA class I pseudogenes HLA 12.4 and LN- 11A . The comparisons show that there is a non-random pattern of nucleotide differences in both exonic and intronic regions featuring segmental homologies over short regions, which is indicative of a gene conversion mechanism. In addition, analysis of the frequency of nucleotide substitution at the three base positions within the codons of the functional genes HLA-A3, HLA-B7 and HLA-CW3 shows that the pattern of nucleotide substitution in the exon coding for the 3rd extracellular domain is consistent with strong selection pressure to conserve the sequence. The distribution of nucleotide variation in the other exons specifying the mature protein is nearly random with respect to the frequencies of substitution at the three nucleotide positions of their codons. The evolutionary implications of these findings are discussed.

HLA cosmid clones show complete, widely spaced human class I genes with occasional clusters.

To understand the organization of the human leukocyte antigen (HLA) gene region and its relationship to the transplantation antigens expressed at the cell surface we have isolated clones containing HLA class I genes from a cosmid library (Grosveld et al., Gene 13, 227, 1981) constructed with the DNA from an individual of defined haplotype. Most of the cosmids contain a single HLA gene in 30-40 kb of human DNA, indicating that human class I genes are rather widely spaced; two contain two genes and one contains three. Most of these genes appear to be complete; the double or multiple genes are found in the same orientation. Differences in restriction maps are evident but some common features are observed in particular in the 5' half of these genes.

Coding and spacer sequences in the 5.8S-2S region of Sciara coprophila ribosomal DNA.

The sequence of 436 nucleotides around the region coding for 5.8S RNA in the Sciara coprophila rDNA transcription unit (1) has been determined. Regions coding for 5.8S and 2S RNAs have been identified; they are 80 - 90% homologous to the corresponding Drosophila sequences and are separated by a 22 nucleotide long spacer. This sequence as well as the two before the 5.8 and after the 2S coding region are very different from the corresponding Drosophila sequences. The main features reported in the Drosophila study (2) are however also found, i.e. all three spacers are very rich in A-T; the sequence of the internal spacer allows base pairing; 5.8S and 2S RNAs can pair through their 3' and 5' terminal regions respectively. The features previously proposed as processing sites in the Drosophila case are thus all found in Sciara in spite of very different spacer sequences.

Relative order of glg mutations affecting glycogen biosynthesis in Escherichia coli K12.

Mutations affecting the glycogen biosynthesis in E. coli can be mapped at three different loci, glg A, glg B and glg C lying between asd and mal A. Transduction tests suggest the following order for the genes in this region: mal A--glg A--glg C--glg B--asd.