Analysis of a 26-kb region linked to the Mhc in zebrafish: genomic organization of the proteasome component beta/transporter associated with antigen processing-2 gene cluster and identification of five new proteasome beta subunit genes.

Sequencing of zebrafish (Danio rerio) bacterial artificial chromosome and P1 artificial chromosome genomic clone fragments and of cDNA clones has led to the identification of five new loci coding for beta subunits of proteasomes (PSMB). Together with the four genes identified previously, nine PSMB genes have now been defined in the zebrafish. Six of the nine genes reside in the zebrafish MHC (Mhc) class I region, four of them reside in a single cluster closely associated with TAP2 on a 26-kb long genomic fragment, and two reside at some distance from the fragment. In addition to homologues of the human genes PSMB5 through PSMB9, two new genes, PSMB11 and PSMB12, have been found for which there are no known corresponding genes in humans. The new genes reside in the PSMB cluster in the Mhc. Homology and promoter region analysis suggest that the Mhc-associated genes might be inducible by IFN-gamma. The zebrafish class I region contains representatives of three phylogenetically distinguishable groups of PSMB genes, X, Y, and Z. It is proposed that these genes were present in the ancestral PSMB region before Mhc class I genes became associated with it.     

Intermediates in the formation of mouse 20S proteasomes: implications for the assembly of precursor beta subunits.

The assembly of individual proteasome subunits into catalytically active mammalian 20S proteasomes is not well understood. Using subunit-specific antibodies, we characterized both precursor and mature proteasome complexes. Antibodies to PSMA4 (C9) immunoprecipitated complexes composed of alpha, precursor beta and processed beta subunits. However, antibodies to PSMA3 (C8) and PSMB9 (LMP2) immunoprecipitated complexes made up of alpha and precursor beta but no processed beta subunits. These complexes possess short half-lives, are enzymatically inactive and their molecular weight is approximately 300 kDa. Radioactivity chases from these complexes into mature, long-lived approximately 700 kDa proteasomes. Therefore, these structures represent precursor proteasomes and are probably made up of two rings: one containing alpha subunits and the other, precursor beta subunits. The assembly of precursor proteasomes occurs in at least two stages, with precursor beta subunits PSMB2 (C7-I), PSMB3 (C10-II), PSMB7 (Z), PSMB9 (LMP2) and PSMB10 (LMP10) being incorporated before others [PSMB1 (C5), PSMB6 (delta), and PSMB8 (LMP7)]. Proteasome maturation (processing of the beta subunits and juxtaposition of the two beta rings) is accompanied by conformational changes in the (outer) alpha rings, and may be inefficient. Finally, interferon-gamma had no significant effect on the half-lives or total amounts of precursor or mature proteasomes.     

Dimorphisms of the proteasome subunit beta type 8 gene (PSMB8) of ectothermic tetrapods originated in multiple independent evolutionary events

The proteasome subunit beta type 8 gene (PSMB8) encodes one of the beta subunits of the immunoproteasome responsible for the generation of peptides presented by major histocompatibility complex class I molecules. Dimorphic alleles of the PSMB8 gene, termed A and F types, based on the deduced 31st amino acid residue of the mature protein have been reported from various vertebrates. Phylogenetic analysis revealed the presence of dichotomous ancient lineages, one comprising the F-type PSMB8 of basal ray-finned fishes, and the other comprising the A-type PSMB8 of these animals and both the F- and A-type PSMB8 of Xenopus and acanthopterygians, indicating that evolutionary history of the PSMB8 dimorphism was not straightforward. We analyzed the PSMB8 gene of five reptile and one amphibian species and found both the A and F types from all six. Phylogenetic analysis indicated that the PSMB8 F type was apparently regenerated from the PSMB8 A type at least five times independently during tetrapod evolution. Genomic typing of wild individuals of geckos and newts indicated that the frequencies of the A- and F-type alleles are not highly biased in these species. Phylogenetic analysis of each exon of the reptile PSMB8 gene suggested interallelic sequence homogenization as a possible evolutionary mechanism for the apparent recurrent regeneration of PSMB8 dimorphism in tetrapods. An extremely strong balancing selection acting on PSMB8 dimorphism was implicated in an unprecedented pattern of allele evolution.     

Evolution of dimorphisms of the proteasome subunit beta type 8 gene (PSMB8) in basal ray-finned fish

The proteasome subunit beta type 8 (PSMB8) gene encodes a catalytic subunit of immunoproteasome that plays a central role in the processing of antigenic peptides presented by major histocompatibility complex class I molecules. The A- and F-type alleles defined by the 31st amino acid residue determining cleaving specificity have been identified from ray-finned fish, amphibia, and reptiles. These two types show extremely long-term trans-species polymorphism in Polypteriformes, Cypriniformes, and Salmoniformes, suggesting the presence of very ancient lineages termed A and F. To elucidate the evolution of the PSMB8 dimorphism in basal ray-finned fish, we analyzed Pantodon buchholzi (Osteoglossiformes), seven species of Anguilliformes, and Hypomesus nipponensis (Osmeriformes). Both A and F lineage sequences were identified from P. buchholzi and H. nipponensis, confirming that these two lineages have been conserved by basal ray-finned fish. However, both the A- and F-type alleles found in Anguilliformes species belonged to the F lineage irrespective of their types. This apparently suggests that the A lineage was lost in the common ancestor of Anguilliformes, and recovery of the A type within the F lineage occurred in Anguilliformes. The apparent loss of the F lineage and recovery of the F type within the A lineage have already been reported from tetrapods and higher teleosts. However, this is the first report on the reverse situation and reveals the dynamic evolution of the PSMB8 dimorphism.     

Characterization of the MHC class I region of the Japanese pufferfish (Fugu rubripes)

A BAC map of the Japanese pufferfish (Fugu) MHC class I region was constructed using a mixture of sequence scanning and sequence-tagged site mapping methodologies. The Fugu MHC class Ia genes are linked to genes which are found within the human classical MHC class II and extended class II regions, a situation which has been found in the MHC of all teleosts mapped so far. The 300-kb contig comprises 24 MHC-related genes and is bounded by six non-MHC genes, which are thought to represent an evolutionary breakpoint within the region. Comparative analysis with both human and zebrafish MHC maps indicates two blocks of genes (KNSL2, ZNF297, DAXX, TAPBP, FLOTILLIN; and PSMB8, PSMB10, PSMB9, ABCB3, FABGL, BRD2, COL11A2, RXRB) which have remained linked over 400 million years and may represent an ancestral arrangement of the vertebrate MHC. Zebrafish and Fugu diverged between 100-200 million years ago and differences exist between these two fish species. The position and number of MHC class Ia genes is not conserved between species, there is an inversion of a block of nine genes centering on the PSMB cluster, and additional genes are present in zebrafish coding for a transport-associated protein and a beta proteasome subunit. The extent of these differences has implications for the extrapolation of fish model organism data to commercial aquaculture species. The data presented here represent the most extensive analysis of a fish MHC class Ia region described so far and clearly delimit the extent of this region in Fugu and, potentially, all teleosts.     

Comparative genomic analysis of the major histocompatibility complex class I region in the teleost genus <Emphasis Type="Italic">Oryzias</Emphasis>

The major histocompatibility complex (MHC) class I region of teleosts harbors a tight cluster of the class IA genes and several other genes directly involved in class I antigen presentation. Moreover, the dichotomous haplotypic lineages (termed d- and N- lineages) of the proteasome subunit beta genes, PSMB8 and PSMB10, are present in this region of the medaka, Oryzias latipes. To understand the evolution of the Oryzias MHC class I region at the nucleotide sequence level, we analyzed bacterial artificial chromosome clones covering the MHC class I region containing the d- lineage of Oryzias luzonensis and the d- and N- lineages of Oryzias dancena. Comparison among these three elucidated sequences and the published sequences of the d- and N- lineages of O. latipes indicated that the order and orientation of the encoded genes were completely conserved among these five genomic regions, except for the class IA genes, which showed species-specific variation in copy number. The PSMB8 and PSMB10 genes showed trans-species dimorphism. The remaining regions flanking the PSMB10, PSMB8, and class IA genes showed high degrees of sequence conservation at interspecies as well as intraspecies levels. Thus, the three independent evolutionary patterns under apparently distinctive selective pressures are recognized in the Oryzias MHC class I region. Electronic Supplementary Material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The complete primary structure of mouse 20S proteasomes

 The proteasome is a large multicatalytic proteinase that plays a role in the generation of peptides for presentation by major histocompatibility complex class I molecules. The 20S proteolytic core of mammalian proteasomes is assembled from a group of 17 protein subunits that generate a distinctive pattern of spots upon two-dimensional gel electrophoresis. The genes for most of these subunits have been cloned from humans and rats. We isolated cDNA clones for the mouse orthologues of ten of the subunits [PSMA1 (C2), PSMA2 (C3), PSMA3 (C8), PSMA4 (C9), PSMA5 (ZETA), PSMA6 (IOTA), PSMA7 (C6-I), PSMB2 (C7-I), PSMB3 (C10-II), and PSMB5 (X)] to complete the cloning of all of the mouse subunits. Using antisera raised against these subunits or their orthologues, we verified the identity of these proteins by two-dimensional NEPHGE-PAGE. Received: 8 March 1999 / Accepted: 8 April 1999     

Enhanced Inflammatory Potential of CD4+ T-Cells That Lack Proteasome Immunosubunit Expression,in a T-Cell Transfer-Based Colitis Model

Proteasomes play a fundamental role in intracellular protein degradation and therewith regulate a variety of cellular processes. Exposure of cells to (pro)inflammatory cytokines upregulates the expression of three inducible catalytic proteasome subunits, the immunosubunits, which incorporate into newly assembled proteasome complexes and alter the catalytic activity of the cellular proteasome population. Single gene-deficient mice lacking one of the three immunosubunits are resistant to dextran sulfate sodium (DSS)-induced colitis development and, likewise, inhibition of one single immunosubunit protects mice against the development of DSS-induced colitis. The observed diminished disease susceptibility has been attributed to altered cytokine production and CD4⁺ T-cell differentiation in the absence of immunosubunits. To further test whether the catalytic activity conferred by immunosubunits plays an essential role in CD4⁺ T-cell function and to distinguish between the role of immunosubunits in effector T-cells versus inflamed tissue, we used a T-cell transfer-induced colitis model. Naïve wt or immunosubunit-deficient CD4⁺ T-cells were adoptively transferred into RAG1^−/− and immunosubunit-deficient RAG1^−/− mice and colitis development was determined six weeks later. While immunosubunit expression in recipient mice had no effect on colitis development, transferred immunosubunit-deficient T- cells were more potent in inducing colitis and produced more proinflammatory IL17 than wt T-cells. Taken together, our data show that modifications in proteasome-mediated proteolysis in T-cells, conferred by lack of immunosubunit incorporation, do not attenuate but enhance CD4⁺ T-cell-induced inflammation.