Expression, linkage, and polymorphism of MHC-related genes in rainbow trout, Oncorhynchus mykiss.

The architecture of the MHC in teleost fish, which display a lack of linkage between class I and II genes, differs from all other vertebrates. Because rainbow trout have been examined for a variety of immunologically relevant genes, they present a good teleost model for examining both the expression and organization of MHC-related genes. Full-length cDNA and partial gDNA clones for proteasome delta, low molecular mass polypeptide (LMP) 2, TAP1, TAP2A, TAP2B, class Ia, and class IIB were isolated for this study. Aside from the expected polymorphisms associated with class I genes, LMP2 and TAP2 are polygenic. More specifically, we found a unique lineage of LMP2 (LMP2/delta) that shares identity to both LMP2 and delta but is expressed like the standard LMP2. Additionally, two very different TAP2 loci were found, one of which encodes polymorphic alleles. In general, the class I pathway genes are expressed in most tissues, with highest levels in lymphoid tissue. We then analyzed the basic genomic organization of the trout MHC in an isogenic backcross. The main class Ia region does not cosegregate with the class IIB locus, but LMP2, LMP2/delta, TAP1A, and TAP2B are linked to the class Ia locus. Interestingly, TAP2A (second TAP2 locus) is a unique lineage in sequence composition that appears not to be linked to this cluster or to class IIB. These results support and extend the recent findings of nonlinkage between class I and II in a different teleost order (cyprinids), suggesting that this unique arrangement is common to all teleosts.     

Hsp70 genes are linked to the Xenopus major histocompatibility complex

Some of the inducible forms of the heat shock protein 70 (Hsp70) gene family are encoded in the class III region of the major histocompatibility complex (MHC) of mammals. This study was undertaken to determine whether Hsp 70 genes are linked to the MHC of Xenopus, an amphibian last sharing a common ancestor with mammals 300–350 million years ago. Segregation analyses involving seven haplotypes demonstrated the linkage of two or three inducible Hsp70 genes to the frog MHC. Another Hsp70 gene is not closely linked to the MHC. We conclude that the physical association of MHC class I and class II genes with Hsp70 genes is ancient. Correspondence to: M. F. Flajnik.     

Proteasome, transporter associated with antigen processing, and class I genes in the nurse shark Ginglymostoma cirratum: evidence for a stable class I region and MHC haplotype lineages.

Cartilaginous fish (e.g., sharks) are derived from the oldest vertebrate ancestor having an adaptive immune system, and thus are key models for examining MHC evolution. Previously, family studies in two shark species showed that classical class I (UAA) and class II genes are genetically linked. In this study, we show that proteasome genes LMP2 and LMP7, shark-specific LMP7-like, and the TAP1/2 genes are linked to class I/II. Functional LMP7 and LMP7-like genes, as well as multiple LMP2 genes or gene fragments, are found only in some sharks, suggesting that different sets of peptides might be generated depending upon inherited MHC haplotypes. Cosmid clones bearing the MHC-linked classical class I genes were isolated and shown to contain proteasome gene fragments. A non-MHC-linked LMP7 gene also was identified on another cosmid, but only two exons of this gene were detected, closely linked to a class I pseudogene (UAA-NC2); this region probably resulted from a recent duplication and translocation from the functional MHC. Tight linkage of proteasome and class I genes, in comparison with gene organizations of other vertebrates, suggests a primordial MHC organization. Another nonclassical class I gene (UAA-NC1) was detected that is linked neither to MHC nor to UAA-NC2; its high level of sequence similarity to UAA suggests that UAA-NC1 also was recently derived from UAA and translocated from MHC. These data further support the principle of a primordial class I region with few class I genes. Finally, multiple paternities in one family were demonstrated, with potential segregation distortions.     

Sequence, linkage to H2-K, and function of mouse tapasin in MHC class I assembly

 Assembly of major histocompatibility complex (MHC) class I molecules in human cells is dependent on the accessory protein tapasin, which mediates their interaction with the transporters associated with antigen processing (TAP) and thereby ensures efficient peptide binding. Analysis of a mouse tapasin complementary DNA defined a conserved polypeptide sharing sequences diagnostic of a transmembrane protein related to the immunoglobulin superfamily, and an endoplasmic reticulum retention motif. The mouse tapasin gene was mapped about 70 kilobases from H2-K at the centromeric end of the mouse MHC. Expression of mouse tapasin in a tapasin-deficient human mutant cell line restored the normal assembly and expression of class I alleles. Thus, tapasin is a structurally and functionally conserved component of the MHC class I antigen processing pathway. Its genetic linkage to the class I and TAP subunit genes in the MHC may be of significance in the coordinate expression and functional coadaptation of the diverse gene products. Received: 1 February 1998 / Revised: 23 March 1998     

Evolution of the proteasome components

 A phylogenetic analysis of proteasome subunits revealed two major families (α and β) which originated by an ancient gene duplication prior to the divergence of archaebacteria and eukaryotes. Numerous gene duplications have subsequently occurred in eukaryotes; at least nine of these duplications were shown to have occurred prior to the divergence of animals and fungi. In mammals, two genes encoding proteasome subunits (LMP2 and LMP7) are located in the major histocompatibility complex (MHC) region and play a specific role in generation of peptides for presentation by class I MHC molecules. Phylogenetic analysis of LMP7 and related sequences from mammals and lower vertebrates indicated that this locus arose by gene duplication prior to the divergence of jawed and jawless vertebrates; the time of this duplication was estimated to have been about 600 million years ago. The evolutionary history of the proteasome subunits provides support for a model of the evolution of new gene function postulating that, after gene duplication, the proteins encoded by daughter loci can adapt to specialized functions previously performed by the product of a single generalized ancestral locus. Received: 19 August 1996 / Revised: 24 December 1996     

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 -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 -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.Abbreviations ABC ATP-binding cassete - 2m 2-microglobulin - ER endoplasmic reticulum - IFN interferon - LMP low molecular weight peptide - MHC major histocompatibility complex - TAP transporter associated with antigen processing     

IFN-beta mediates coordinate expression of antigen-processing genes in RSV-infected pulmonary epithelial cells

Major histocompatibility complex (MHC) class I-restricted cytotoxic T lymphocytes (CTLs) clear respiratory tract infections caused by the pneumovirus respiratory syncytial virus (RSV) and also mediate vaccine-induced pulmonary injury. Herein we examined the mechanism for RSV-induced MHC class I presentation. Like infectious viruses, conditioned medium from RSV-infected cells (RSV-CM) induces naive cells to coordinately express a gene cluster encoding the transporter associated with antigen presentation 1 (TAP1) and low molecular mass protein (LMP) 2 and LMP7. Neutralization of RSV-CM with antibodies to interferon (IFN)-beta largely blocked TAP1/LMP2/LMP7 expression, whereas anti-interleukin-1 antibodies were without effect, and recombinant IFN-beta increased TAP1/LMP2/LMP7 expression to levels produced by RSV-CM. LMP2, LMP7, and TAP1 expression were required for MHC class I upregulation because the irreversible proteasome inhibitor lactacystin or transfection with a competitive TAP1 inhibitor blocked inducible class I expression. We conclude that RSV infection coordinately increases MHC class I expression and proteasome activity through the paracrine action of IFN-beta to induce expression of the TAP1/LMP2/LMP7 locus, an event that may be important in the initiation of CTL-mediated lung injury.     

The dominant MHC class I gene is adjacent to the polymorphic<Emphasis Type="Italic"> TAP2</Emphasis> gene in the duck,<Emphasis Type="Italic"> Anas platyrhynchos</Emphasis>

We are investigating the expression and linkage of major histocompatibility complex (MHC) class I genes in the duck (Anas platyrhynchos) with a view toward understanding the susceptibility of ducks to two medically important viruses: influenza A and hepatitis B. In mammals, there are multiple MHC class I loci, and alleles at a locus are polymorphic and co-dominantly expressed. In contrast, in lower vertebrates the expression of one locus predominates. Southern-blot analysis and amplification of genomic sequences suggested that ducks have at least four loci encoding MHC class I. To identify expressed MHC genes, we constructed an unamplified cDNA library from the spleen of a single duck and screened for MHC class I. We sequenced 44 positive clones and identified four MHC class I sequences, each sharing approximately 85% nucleotide identity. Allele-specific oligonucleotide hybridization to a Northern blot indicated that only two of these sequences were abundantly expressed. In chickens, the dominantly expressed MHC class I gene lies adjacent to the transporter of antigen processing (TAP2) gene. To investigate whether this organization is also found in ducks, we cloned the gene encoding TAP2 from the cDNA library. PCR amplification from genomic DNA allowed us to determine that the dominantly expressed MHC class I gene was adjacent to TAP2. Furthermore, we amplified two alleles of the TAP2 gene from this duck that have significant and clustered amino acid differences that may influence the peptides transported. This organization has implications for the ability of ducks to eliminate viral pathogens.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers AY294416–22     

Two ancient allelic lineages at the single classical class I locus in the Xenopus MHC

Unlike all other vertebrates examined to date, there is only one detectable class I locus in the Xenopus MHC. On the bases of a nearly ubiquitous and high tissue expression, extensive polymorphism, and MHC linkage, this gene is of the classical or class Ia type. Sequencing analysis of class Ia cDNAs encoded by eight defined MHC haplotypes reveals two very old allelic lineages that perhaps emerged when humans and mice diverged from a common ancestor up to 100 million years ago. The unprecedented age of these lineages suggests that different class Ia genes from ancestors of the laboratory model Xenopus laevis are now expressed as alleles in this species. The lineages are best defined by their cytoplasmic and alpha2 peptide-binding domains, and there are highly diverse alleles (defined by the alpha1 peptide-binding domain) in each lineage. Surprisingly, the alpha3 domains are homogenized in both lineages, suggesting that interallelic gene conversion/recombination maintains the high sequence similarity.     

Association of antigen processing machinery and HLA class I defects with clinicopathological outcome in cervical carcinoma

HLA class I loss is a significant mechanism of immune evasion by cervical carcinoma, interfering with the development of immunotherapies and cancer vaccines. We report the systematic investigation of HLA class I and antigen processing machinery component expression and association with clinical outcome. A tissue microarray containing carcinoma lesions from 109 cervical carcinoma patients was stained for HLA class I heavy chains, β₂-microglobulin, LMP2, LMP7, LMP10, TAP1, TAP2, ERAP1, tapasin, calreticulin, calnexin and ERp57. A novel staining evaluation method was used to ensure optimal accuracy and reliability of expression data, which were correlated with known clinicopathological parameters. Partial HLA class I loss was significantly associated with decreased 5-years overall survival (61% vs. 83% for normal expression; P < 0.05) and was associated with decreased 5-years disease-free survival (DFS) (65% vs. 82% for normal expression; P = 0.05). All APM components except LMP10, calnexin and calreticulin were down-regulated in a substantial number of cases and, except ERAP1, correlated significantly with HLA class I down-regulation. LMP7, TAP1 and ERAP1 loss was significantly associated with decreased overall and (except LMP7) DFS (P < 0.05 and 0.005, respectively). ERAP1 down-regulation was an independent predictor for worse overall and DFS in multivariate analysis (HR 3.08; P < 0.05 and HR 2.84; P < 0.05, respectively). HLA class I and APM component down-regulation occur frequently in cervical carcinoma, while peptide repertoire alterations due to ERAP1 loss are a major contributing factor to tumour progression and mortality.     

Reduced Expression of the Antigen Processing Machinery Components TAP2, LMP2, and LMP7 in Tonsillar and Base of Tongue Cancer and Implications for Clinical Outcome

OBJECTIVES: Patients with human papillomavirus (HPV)–positive tonsillar squamous cell carcinoma (TSCC) and base of tongue squamous cell carcinoma (BOTSCC) have a better clinical outcome than those with corresponding HPV-negative tumors. Moreover, there is a strong positive correlation between absent/low as opposed to strong HLA class I expression and favorable clinical outcome for HPV-positive tumors, while the reverse applies to HPV-negative tumors. The expression of the antigen processing machinery (APM) components TAP1, TAP2, LMP2, and LMP7 in these tumors in relation to HPV status, HLA class I expression, each other, and clinical outcome was therefore investigated. MATERIAL AND METHODS: Formalin-fixed paraffin-embedded TSCC and BOTSCC, derived from 151 patients and previously analyzed for HPV DNA, HLA class I, and LMP10 expression were stained by immunohistochemistry for TAP1, TAP2, LMP2, and LMP7. RESULTS: Absent/low TAP2, LMP2, and LMP7 expression, similar to HLA class I and LMP10, was common in TSCC and BOTSCC, irrespective of HPV status. Expression of TAP1 and TAP2 was correlated, as was LMP2 to LMP7. LMP2 and LMP7 expression was also associated to HLA class I expression. Moreover, absence of LMP7 was linked to increased disease-free survival in both HPV-positive and HPV-negative cases. CONCLUSION: Reduced expression of TAP2, LMP2, and LMP7 was frequent in TSCC and BOTSCC and their expression as well as that of TAP1 was often interrelated. Furthermore, low LMP7 expression correlated to better clinical outcome and may, together with HPV status, potentially be used for prediction of treatment response.     

Evolution of an MHC class Ia gene fragment in four North American Morone species

A nucleotide sequence analysis of a fragment of a Morone MHC class Ia gene detected high levels of polymorphism in striped bass Morone saxatilis, white perch Morone americana and yellow bass Morone mississippiensis. Extremely low levels of MHC diversity, however, were detected in white bass Morone chrysops, suggesting the possibility of a severe population bottleneck for this species.     

Features of the immune proteasome expression in ascite Zajdela hepatoma after implantation into Brattleboro rats with the hereditary defect of arginine-vasopressin synthesis

The expression of the total proteasome pool, immune subunits LMP2 and LMP7, TAP1 and TAP2 transporters, and RT1A molecules of the major histocompatibility complex (MHC) class I in ascite Zajdela hepatoma cells was studied on the 10th day after implantation into Brattleboro rats with the hereditary defect in the synthesis of arginine-vasopressin (AVP) in the hypothalamus and WAG rats with normal AVP expression. Western-blot analysis revealed a threefold increase in the total number of proteasomes and immune subunit LMP2 and an eightfold increase in the immune subunits LMP7 in Zajdela hepatoma after its implantation in Brattleboro rats as compared with WAG rats. Differences in the expression of immune subunits LMP2 and LMP7 in Zajdela hepatoma in Brattleboro rats may contribute to different functions of these proteasomes, namely, the important role of the subunit LMP7 in antitumor immunity. Zajdela hepatoma growth in WAG rats was accompanied by a fall in both the total proteasome pool and immune proteasomes as compared with their content in Brattleboro rats, whose tumors regressed. The analysis of the content of peptide transporters TAP1 and TAP2 in Zajdela hepatoma implanted into Brattleboro and WAG rats showed their pronounced expression in tumor cells of both rat strains. In Zajdela hepatoma implanted into Brattleboro rats, a threefold increase in the basic molecule of MHC class I-RT1A was identified as compared with its expression in the tumor implanted to WAG rats. Furthermore, the content of CD8 and CD4 T-lymphocytes in the spleen of WAG and Brattleboro rats on the 10th day after implantation of Zajdela hepatoma was analyzed with flow cytometry. An increase in T-lymphocytes expressing the CD8 and CD4 antigens in the spleen of Brattleboro rats after implantation of the tumor as compared with WAG rats was shown. Increased numbers of both cytotoxic T lymphocytes and helper T-cells may facilitate tumor regression in Brattleboro rats. At the same time, a reduced number of subpopulations of T-lymphocytes in the spleen of WAG rats after implantation of hepatoma was accompanied by splenomegaly and growth of the tumor. Based on analysis of the data obtained it can be concluded that the deficiency of AVP in Brattleboro rats in Zajdela hepatoma leads to an increased expression of immune subunit LMP7 and basic molecules of MHC class I resulting in tumor immunogenicity and its elimination by the adaptive immune system.     

Linkage analysis of HSP70 genes and historecognition locus in Botryllus schlosseri

 The protochordate allorecognition system has long invited comparison with the vertebrate major histocompatibility complex (MHC). In the colonial species Botryllus schlosseri, a rapid fusion or rejection response resembling graft acceptance or rejection in vertebrates is controlled by a single highly polymorphic genetic region. Because linkage between heat shock protein 70 (HSP70) genes and the MHC appears to be conserved within the vertebrate lineage, linkage relationships between two HSP70 genes (HSP70.1 and HSP70.2) and the historecognition locus (FuHC) have been analyzed in B. schlosseri. Segregation patterns of restriction fragment length polymorphisms located in the 3′ flanking regions of HSP70.1 and HSP70.2 were determined for progeny of defined crosses. These progeny were also analyzed for fusibility type by an in vivo cut colony assay. No close linkage was detected between any of the three loci. These results do not support the hypothesis that the allorecognition response in B. schlosseri is determined by an MHC homologue. However, it remains a possibility that orthologues of other MHC-linked genes will be linked to the B. schlosseri FuHC. Received: 29 June 1997 / Revised: 6 October 1997     

A major histocompatibility complex class I allele shared by two species of chimpanzee

 Little is known regarding the rates at which natural selection can modify or retain antigen presenting alleles at the major histocompatibility complex (MHC). Discovery of identical [1101 base pairs (bp)] coding regions at the MHC class I C locus in Pan troglodytes and Pan paniscus, chimpanzee species that diverged ∼2.3 million years ago, now indicates that a class I allotype can survive for at least this period. Remarkable conservation was also reflected in the (1799 bp) introns where a maximum of only six substitutions distinguished five alleles (three from P. troglodytes and two from P. paniscus) that encoded the identical heavy chain allotype. Analysis of a more distantly related human allele, HLA-Cw ^* 0702, corroborated that intron variation was non-uniform along the gene. Thus we provide a clear reference frame for the lifetime of an MHC class I allotype, a direct estimate of allelic substitution rates, and evidence for an unusual evolution of MHC class I introns. Received: 13 August 1997     

Unprecedented intraspecific diversity of the MHC class I region of a teleost medaka, Oryzias latipes

The major histocompatibility complex (MHC) is present at a single chromosomal locus of all jawed vertebrate analyzed so far, from sharks to mammals, except for teleosts whose orthologs of the mammalian MHC-encoded genes are dispersed at several chromosomal loci. Even in teleosts, several class IA genes and those genes directly involved in class I antigen presentation preserve their linkage, defining the teleost MHC class I region. We determined the complete nucleotide sequence of the MHC class I region of the inbred HNI strain of medaka, Oryzias latipes (northern Japan population-derived), from four overlapping bacterial artificial chromosome (BAC) clones spanning 540,982 bp, and compared it with the published sequence of the corresponding region of the inbred Hd-rR strain of medaka (425,935 bp, southern Japan population-derived) as the first extensive study of intraspecies polymorphisms of the ectotherm MHC regions. A segment of about 100 kb in the middle of the compared sequences encompassing two class Ia genes and two immunoproteasome subunit genes, PSMB8 and PSMB10, was so divergent between these two inbred strains that a reliable sequence alignment could not be made. The rest of the compared region (about 320 kb) showed a fair correspondence, and an approximately 96% nucleotide identity was observed upon gap-free segmental alignment. These results indicate that the medaka MHC class I region contains an ∼100-kb polymorphic core, which is most probably evolving adaptively by accumulation of point mutations and extensive genetic rearrangements such as insertions, deletions and duplications. The nucleotide sequence data of HNI MHC class I region reported in this paper have been submitted to the DDBJ/EMBL/GenBank and were assigned the accession number AB183488.     

PA28 subunits of the mouse proteasome: primary structures and chromosomal localization of the genes

 The 20S proteasome is a multi-subunit protease responsible for the production of peptides presented by major histocompatibility complex (MHC) class I molecules. Recent evidence indicates that an interferon-γ (IFN-γ)-inducible PA28 activator complex enhances the generation of class I binding peptides by altering the cleavage pattern of the proteasome. In the present study, we determined the primary structures of the mouse PA28 α- and β-subunits. The deduced amino acid sequences of the α- and β-subunits were 49% identical. We also determined the primary structure of the mouse PA28 γ-subunit (Ki antigen), a protein of unknown function structurally related to the α- and β-subunits. The amino acid sequence identity of the γ-subunit to the α- and β-subunits was 40% and 32%, respectively. Interspecific backcross mapping showed that the mouse genes coding for the α- and β-subunits (designated Psme1 and Psme2, respectively) are tightly linked and map close to the Atp5g1 locus on chromosome 14. Thus, unlike the LMP2 and LMP7 subunits, the IFN-γ-inducible subunits of PA28 are encoded outside the MHC. The gene coding for the γ-subunit (designated Psme3) was mapped to the vicinity of the Brca1 locus on chromosome 11. A computer search of the DNA databases identified a γ-subunit-like protein in ticks and Caenorhabditis elegans, the organisms with no adaptive immune system. It appears that the IFN-γ-inducible α- and β-subunits emerged by gene duplication from a γ-subunit-like precursor. Received: 11 March 1997     

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.