John Trowsdale

Structure, Sequence and Polymorphism in the HLA‐D Region

Molecular analysis of the HLA-D region has uncovered a complex array of related genes encompassing a minimum of 6 alpha and 7 beta chain sequences. A high level of polymorphism is characteristic of the DQ alpha and beta genes, as well as DR beta. The DP genes, both alpha and beta, are also polymorphic, though to a lesser extent. The genes fit into the previously established loci: DP, DQ and DR, except for a newly-discovered sequence, DZ alpha, which is approximately equally related to all of the other alpha chain genes. Analysis of the polymorphism and evolution of the HLA-D region, by examination of the sequences, calls for several independent duplication events in the generation of this family of genes.

Genomic structure and function in the MHC

The major histocompatibility complex (MHC) is a fascinating region of the human genome. More is known about this 4 Mb of DNA (0.1% of the genome) on the short arm of chromosome 6 than about any other region of similar size. Among the 80 or so MHC genes found so far are several clusters with related functions in antigen processing and presentation. In addition to its importance in immunology, the MHC is a useful model for investigating gene organization, polymorphism, linkage disequilibrium and recombination. A large number of diseases, many of the autoimmune type, are associated with the region.

Proteasome components with reciprocal expression to that of the MHC-encoded LMP proteins

BACKGROUND Intracellular proteins are processed into small peptides that bind HLA class I molecules of the major histocompatibility complex (MHC) in order to be presented to T lymphocytes. The proteasome, a multi-subunit protease, has recently been implicated in the generation of these peptides. Two genes encoding proteasome subunits, LMP2 and LMP7, are tightly linked to the TAP peptide transport loci in the class II region of the human MHC. Inclusion of the LMP subunits may alter proteasome activity, biasing it towards the production of peptides with carboxyl termini appropriate for binding HLA class I molecules. Nevertheless, mutant cells that lack the LMP genes are able to process and present antigens at the cell surface at similar levels to wild-type cells. These results raise questions about the role of the proteasome, and in particular of the LMP subunits, in antigen processing. RESULTS We have cloned the genes encoding a new proteasome subunit, MB1, which is closely related to LMP7, and that encoding a second subunit, Delta, which is closely related to LMP2. Expression of the MB1 and delta genes is reciprocal to that of the LMP genes: MB1 and delta are up-regulated in mutant cell lines lacking LMPs and down-regulated in the presence of gamma-interferon. The MB1 and delta genes are found to be located on chromosomes 14 and 17, respectively, raising interesting evolutionary questions about how the LMP genes independently became incorporated into the MHC. CONCLUSIONS We suggest that the subtle phenotype of LMP-deficient cell lines results from the compensatory expression in these lines of two other proteasome subunits, MB1 and Delta.

A mouse zinc finger gene which is transiently expressed during spermatogenesis.

Zinc finger proteins are polypeptides with sequence‐specific, nucleic acid‐binding properties. Substantial evidence has established them as a class of trans‐acting molecules with regulatory roles in cellular growth and differentiation. We have screened an 11.5 day post coitum urogenital ridge cDNA library with an oligonucleotide encoding a sequence conserved between a variety of zinc finger proteins. By cDNA cloning and sequencing we show that a novel mouse gene, Zfp‐35, encodes a protein with a block of 18 zinc finger domains and an N‐terminal region rich in acidic residues. The 2.4 kb mRNA encoding this polypeptide is selectively expressed in adult testis, by comparison with other organs. We have analysed Zfp‐35 expression in whole testes of sex‐reversed mice, whole testes of prepuberal XY animals, germ cell fractions from XY adult testes and by in situ hybridization to sections from adult XY testes. Our studies show that a considerable increase in expression is restricted to spermatocytes at the pachytene stage of meiotic prophase. These experiments suggest that Zfp‐35 may act to control gene activity during this particular stage of spermatogenesis.

Limited MHC polymorphism in whales

Little is known about disease and genetic variation in aquatic mammalian species such as whales. In this paper human HLA class I and class 11 probes were used to study major histocompatibility complex (MHC) genes from two species of whale: Fin (Balaenoptera physalus) and Sei (B. borealis). Stronger signals were obtained on whale than on equivalent concentrations of mouse DNA. Evidence was obtained for severalDRB-related genes, aDNA gene, oneDQA gene, and multiple class I genes in whales. Interestingly, the whale genes, from the small panel studied, were less polymorphic than those of humans or mice. The aquatic environment of this mammalian species may be a unique factor in shaping its immune response through the MHC.

MHC class II sequences of an HLA-DR2 narcoleptic

Narcolepsy has a 98% association with the DR2-Dw2/DQw1 haplotype. To establish if a disease-specific allele is present in narcolepsy, a cDNA library was made from a B-cell line from a DR2,4/DQw1,3 narcoleptic. Clones encoding the two expressed DR2β chains, along with DQw1 α and β chains, were isolated and completely sequenced. The coding regions of these four genes were similar to published nucleotide and protein sequences from corresponding healthy controls, with some minor exceptions. The 3′ untranslated region of one of the DR2β genes in the narcoleptic was extended by 42 bp. Complete sequences were not available for DQw1.2 α or β from healthy individuals, but first domain nucleotide sequences showed only a single nonproductive difference in DQα. Partial protein sequences of both DQ α and β from published data were identical. Although the effects of minor differences cannot be ruled out completely, it is concluded that there are probably no narcolepsy-specific DRβ or DQ α/β sequences, and that the alleles found in narcolepsy are representative of those found in the healthy population.

The human homologue of the mouse t-complex gene, TCP1, is located on chromosome 6 but is not near the HLA region.

Southern blot analysis indicates that there are four sequences in the human genome related to the mouse t‐complex gene Tcp‐1. All four genes were cloned and partial sequencing showed that one of them was a functional gene, and the other three were pseudogenes. The human sequences were all approximately 90% related to each other and 82‐89% related to the mouse Tcp‐1a sequence. Human TCP1 cDNA clones from both fibrosarcoma and B cell lines confirmed that there was a single expressed gene. mRNA transcripts of different sizes were accounted for by two different polyadenylation signals. The human TCP1 gene shared some amino acid substitutions with the mouse t‐complex allele (Tcp‐1a) which were not found in Tcp‐1b. The functional human TCP1 gene was mapped, using a panel of somatic cell hybrids, as well as in situ analysis, to the long arm of chromosome 6 at 6q23‐qter and thus is not closely linked to the HLA complex on the short arm. For this reason and others it is unlikely that there is a human equivalent of the mouse t‐complex.

Proteasome and class I antigen processing and presentation

The recent discovery of two proteasome homologous genes,LMP2 andLMP7, in the class II region of the human MHC, has implicated this multi-subunit protease in an early step of the immune response; the degradation of intracellular and viral proteins. Short peptides produced by the proteasome are transported into the ER by the product of another set of MHC class II genes,TAP1 andTAP2, where they bind and stabilise HLA class I molecules. Antigenic peptides displayed at the cell surface by HLA class I molecules mark cells for destruction by cytotoxic T lymphocytes. The role of the proteasome in antigen processing was questioned when mutant cells, which lack theLMP genes, were able to process and present antigens normally. The discovery that two proteasome β-subunits, delta andMB1, highly homologous toLMP2 andLMP7 and expressed in reciprocal manner, is now consistent with a role for the proteasome in antigen processing. The incorporation of different β-subunits into the proteasome may be a mechanism to modulate catalytic activity of the proteasome complex, allowing production of peptides that are more suitable to enter into the ER by the TAP transporters and to bind HLA class I molecules. But, in the absence of the LMPs, the other subunits permit processing of most antigens reasonably efficiently.

A testis-expressed Zn finger gene (ZNF76) in human 6p21.3 centromeric to the MHC is closely linked to the human homolog of the t-complex gene tcp-11

A novel testis-expressed Zn finger gene (ZNF76) was identified by screening cDNA libraries with cosmids derived from 6p21. ZNF76 is a member of the GLI-Krüppel family of DNA binding proteins. It is conserved in mouse where transcription in testis is initiated at Day 20 after birth. The mouse tcp-11 gene is located in the distal inversion of the t-complex and is developmentally regulated in the same manner as ZNF76. The human homolog of tcp-11 was isolated to allow a precise chromosomal localization. By using a combination of somatic cell hybrids, radiation hybrids, metaphase and interphase fluorescent in situ hybridization, and pulsed-field gel electrophoresis, we mapped the two genes to the 6p21.2 to 6p21.3 region and linked them to each other within 300 kb of DNA, approximately 2 Mb centromeric to the major histocompatibility complex.

Chromosomal localization, gene structure and transcription pattern of the ORFX gene, a homologue of the MHC-linked RING3 gene

We have mapped the human ORFX gene to chromosome 9q34 and determined its complete gene structure. Comparison with RING3, the human MHC-linked homologue on 6p21.3, shows the two gene structures to be highly conserved but with an approximate threefold expansion in the ORFX introns. RING3 and ORFX are found to be ubiquitously expressed in human adult and foetal tissues. Evidence suggests that the two genes may have arisen from an ancient duplication in a common ancestral chromosome.