A trans-acting major histocompatibility complex-linked gene whose alleles determine gain and loss changes in the antigenic structure of a classical class I molecule

Natural polymorphisms in Tap2 influence negative selection and CD4∶CD8 lineage commitment in the rat

Genetic variation in the major histocompatibility complex (MHC) affects CD4∶CD8 lineage commitment and MHC expression. However, the contribution of specific genes in this gene-dense region has not yet been resolved. Nor has it been established whether the same genes regulate MHC expression and T cell selection. Here, we assessed the impact of natural genetic variation on MHC expression and CD4∶CD8 lineage commitment using two genetic models in the rat. First, we mapped Quantitative Trait Loci (QTLs) associated with variation in MHC class I and II protein expression and the CD4∶CD8 T cell ratio in outbred Heterogeneous Stock rats. We identified 10 QTLs across the genome and found that QTLs for the individual traits colocalized within a region spanning the MHC. To identify the genes underlying these overlapping QTLs, we generated a large panel of MHC-recombinant congenic strains, and refined the QTLs to two adjacent intervals of ∼0.25 Mb in the MHC-I and II regions, respectively. An interaction between these intervals affected MHC class I expression as well as negative selection and lineage commitment of CD8 single-positive (SP) thymocytes. We mapped this effect to the transporter associated with antigen processing 2 (Tap2) in the MHC-II region and the classical MHC class I gene(s) (RT1-A) in the MHC-I region. This interaction was revealed by a recombination between RT1-A and Tap2, which occurred in 0.2% of the rats. Variants of Tap2 have previously been shown to influence the antigenicity of MHC class I molecules by altering the MHC class I ligandome. Our results show that a restricted peptide repertoire on MHC class I molecules leads to reduced negative selection of CD8SP cells. To our knowledge, this is the first study showing how a recombination between natural alleles of genes in the MHC influences lineage commitment of T cells.

Peptides from degraded cytoplasmic proteins are transported via TAP into the endoplasmic reticulum for loading onto MHC class I molecules. TAP is encoded by Tap1 and Tap2, which in rodents are located close to the MHC class I genes. In the rat, genetic variation in Tap2 gives rise to two different transporters: a promiscuous A variant (TAP-A) and a more restrictive B variant (TAP-B). It has been proposed that the class I molecule in the DA rat (RT1-A^a) has co-evolved with TAP-A and it has been shown that RT1-A^a antigenicity is changed when co-expressed with TAP-B. To study the contribution of different allelic combinations of RT1-A and Tap2 to the variation in MHC expression and T cell selection, we generated DA rats with either congenic or background alleles in the RT1-A and Tap2 loci. We found increased numbers of mature CD8SP cells in the thymus of rats which co-expressed RT1-A^a and TAP-B. This increase of CD8 cells could be explained by reduced negative selection, but did not correlate with RT1-A^a expression levels on thymic antigen presenting cells. Thus, our results identify a crucial role of the TAP and the quality of the MHC class I repertoire in regulating T cell selection.

Chicken TAP genes differ from their human orthologues in locus organisation, size, sequence features and polymorphism

We have previously shown that in the chicken major histocompatibility complex, the two transporters associated with antigen processing genes (TAP1 and TAP2) are located head to head between two classical class I genes. Here we show that the region between these two TAP genes has transcription factor-binding sites in common with class I gene promoters. The TAP genes are also up-regulated by interferon-gamma in a similar way to mammalian TAP genes and in a way that suggests they are both transcribed from a bi-directional promoter. The gene structures of TAP1 and TAP2 differ from that of human TAPs in that TAP1 has a truncated exon 1 and TAP2 has fused exons, resulting in a much smaller gene size. The truncation of TAP1 results in the loss of approximately 150 amino acids, which are thought to be involved in endoplasmic reticulum retention, heterodimer formation and tapasin binding, compared to human TAP1. Most of the protein sequence features involved in binding ATP are conserved, with two exceptions: chicken TAP1 has a glycine in the switch region where other TAPs have glutamine or histidine, and both chicken TAP genes have serines in the C motif where mammalian TAP2 has an alanine. Lastly, the chicken TAP genes are highly polymorphic, with at least as many TAP alleles as there are class I alleles, as seen by investigating nine inbred lines of chicken. The close proximity of the TAP genes to the class I genes and the high level of polymorphism may allow co-evolution of the genes, allowing TAP molecules to transport peptides specifically for the class I molecules of that haplotype.

Peptide selection by class I molecules of the major histocompatibility complex

Class I molecules of the major histocompatibility complex (MHC) bind peptides derived from cytoplasmic proteins. Comparison of over 100 such peptides reveals the importance of the carboxy-terminal residue in selective binding. Recent evidence implicates the proteases and transporters of the processing pathway in providing peptides with the correct residues at the carboxyl terminus.

Competition for Access to the Rat Major Histocompatibility Complex Class I Peptide-loading Complex Reveals Optimization of Peptide Cargo in the Absence of Transporter Associated with Antigen Processing (TAP) Association

Major histocompatibility complex (MHC) class I molecules load peptides in the endoplasmic reticulum in a process during which the peptide cargo is normally optimized in favor of stable MHC-peptide interactions. A dynamic multimolecular assembly termed the peptide-loading complex (PLC) participates in this process and is composed of MHC class I molecules, calreticulin, ERp57, and tapasin bound to the transporter associated with antigen processing (TAP) peptide transporter. We have exploited the observation that the rat MHC class I allele RT1-Aa, when expressed in the rat C58 thymoma cell line, effectively competes and prevents the endogenous RT1-Au molecule from associating with TAP. However, stable RT1-Au molecules are assembled efficiently in competition with RT1-Aa, demonstrating that cargo optimization can occur in the absence of TAP association. Defined mutants of RT1-Aa, which do not allow formation of the PLC, fail to become thermostable in C58 cells. Wild-type RT1-Aa, which does allow PLC formation, also fails to become thermostable in this cell line, which carries the rat TAPB transporter that supplies peptides incompatible for RT1-Aa binding. Full optimization of RT1-Aa requires the presence of the TAP2A allele, which is capable of supplying suitable peptides. Thus, formation of the PLC alone is not sufficient for optimization of the MHC class I peptide cargo.

The Rat RT1-A1cMHC Molecule Is a Xenogeneic Ligand Recognized by the Mouse Activating Ly-49W and Inhibitory Ly-49G Receptors

Mouse Ly-49 receptors are known to recognize xenogeneic ligands from hamster and rat. However, until now, there has been no description of a specific rat xenogeneic ligand for any mouse Ly-49 receptor. In this report, we identify RT1-A1c, a rat classical class I MHC molecule, as a ligand for the Ly-49G(BALB/c) inhibitory receptor and the closely related activating receptor, Ly-49W. Xenogeneic class I recognition of targets from PVG but not DA strain rats was mapped to the classical region of the RT1c haplotype by using Con A blasts from RT1c/RT1av1 intra-MHC recombinant rats as targets for RNK-16 cells expressing either Ly-49W or Ly-49G(BALB/c) receptors. Individual expression of class I molecules from PVG and DA rat strains in YB2/0 target cells demonstrate the xenogeneic recognition to be allele specific, because other class I molecules of the RT1c haplotype, RT1-A2c and RT1-U2c, and a classical class I molecule encoded by the RT1av1 haplotype, RT1-Aa, are not recognized by Ly-49W and -G(BALB/c). Furthermore, specificity for RT1-Ac can be transferred from Ly-49W to Ly-49P, which is normally unable to recognize RT1-Ac, by substitution of three residues shared by Ly-49W and -G(BALB/c) but not Ly-49P. These residues are located in the Ly-49 beta4-beta5 loop, which can determine class I allele specificity in mouse Ly-49 receptor interactions with mouse class I ligands, suggesting that mouse Ly-49 recognition of rat class I molecules follows similar principles of interaction. These findings have implications for xenotransplantation studies and for discerning Ly-49 recognition motifs present in MHC molecules.

A novel instance of class I modification (cim) affecting two of three rat class I RT1-A molecules within one MHC haplotype

MHC class I expression by rats of the RT1(o), RT1(d), and RT1(m) MHC haplotypes was investigated. Identical, functional cDNAs were obtained from RT1(o) and BDIX (RT1(dv1)) rats for three MHC class I molecules. RT1-A1(o/d) and -A2(o/d) are closely related in sequence to other cloned rat class Ia genes that have been shown to map to the RT1-A region, while RT1-A3 degrees is highly homologous to a class I gene identified by sequencing an RT1-A(n) genomic contig and is named A3(n). Detailed analysis of the three molecules was undertaken using serology with mAbs, two-dimensional gel analysis of immunoprecipitates, and killing assays using cytotoxic T cells. Arguments are presented suggesting that A1 degrees is the principal MHC class Ia (classical) restricting element of this haplotype. A2 degrees, which is highly cross-reactive with A1 degrees, and A3 degrees probably play more minor or distinct roles in Ag presentation. Unexpectedly, cDNAs encoding exactly the same three molecules were cloned from rats of the RT1(m) haplotype, an MHC that until now was thought to possess unique class Ia genes. RT1(m) contains the TAP-B allele of the TAP transporter, and we present evidence that functional polymorphism in rat TAP has an even greater impact on the expression of RT1-A1 degrees and -A2 degrees than it does on RT1-A(a) in the established case of class I modification (cim). Historically, this led to the misclassification of RT1(m) class Ia molecules as separate and distinct.

Crystal structures of two rat MHC class Ia (RT1-A) molecules that are associated differentially with peptide transporter alleles TAP-A and TAP-B

Antigenic peptides are loaded onto class I MHC molecules in the endoplasmic reticulum (ER) by a complex consisting of the MHC class I heavy chain, beta(2)-microglobulin, calreticulin, tapasin, Erp57 (ER60) and the transporter associated with antigen processing (TAP). While most mammalian species transport these peptides into the ER via a single allele of TAP, rats have evolved different TAPs, TAP-A and TAP-B, that are present in different inbred strains. Each TAP delivers a different spectrum of peptides and is associated genetically with distinct subsets of MHC class Ia alleles, but the molecular basis for the conservation (or co-evolution) of the two transporter alleles is unknown. We have determined the crystal structures of a representative of each MHC subset, viz RT1-A(a) and RT1-A1(c), in association with high-affinity nonamer peptides. The structures reveal how the chemical properties of the two different rat MHC F-pockets match those of the corresponding C termini of the peptides, corroborating biochemical data on the rates of peptide-MHC complex assembly. An unusual sequence in RT1-A1(c) leads to a major deviation from the highly conserved beta(3)/alpha(1) loop (residues 40-59) conformation in mouse and human MHC class I structures. This loop change contributes to profound changes in the shape of the A-pocket in the peptide-binding groove and may explain the function of RT1-A1(c) as an inhibitory natural killer cell ligand.

Two different, highly exposed, bulged structures for an unusually long peptide bound to rat MHC class I RT1-Aa

The rat MHC class Ia molecule RT1-Aa has the unusual capacity to bind long peptides ending in arginine, such as MTF-E, a thirteen-residue, maternally transmitted minor histocompatibility antigen. The antigenic structure of MTF-E was unpredictable due to its extraordinary length and two arginines that could serve as potential anchor residues. The crystal structure of RT1-Aa-MTF-E at 2.55 A shows that both peptide termini are anchored, as in other class I molecules, but the central residues in two independent pMHC complexes adopt completely different bulged conformations based on local environment. The MTF-E epitope is fully exposed within the putative T cell receptor (TCR) footprint. The flexibility demonstrated by the MTF-E structures illustrates how different TCRs may be raised against chemically identical, but structurally dissimilar, pMHC complexes.

Cytotoxic T-cell-mediated response against Yersinia pseudotuberculosis in HLA-B27 transgenic rat

Yersinia-induced reactive arthritis is highly associated with HLA-B27, the role of which in defense against the triggering bacteria remains unclear. The aim of this study was to examine the capacity of rats transgenic for HLA-B27 to mount a cytotoxic T-lymphocyte (CTL) response against Y. pseudotuberculosis and to determine the influence of the HLA-B27 transgene on this response. Rats transgenic for HLA-B*2705 and human beta(2)-microglobulin of the 21-4L line, which do not spontaneously develop disease, and nontransgenic syngeneic Lewis (LEW) rats were infected with Y. pseudotuberculosis. Lymph node cells were restimulated in vitro, and the presence of for Y. pseudotuberculosis-specific CTLs against infected targets was determined. Infection of 21-4L rats triggered a CD8(+) T cell-mediated cytotoxic response specific for Y. pseudotuberculosis. Analysis of this response demonstrated restriction by an endogenous major histocompatibility complex molecule. However, no restriction by HLA-B27 was detected. In addition, kinetics studies revealed a weaker anti-Yersinia CTL response in 21-4L rats than in nontransgenic LEW rats, and the level of cytotoxicity against 21-4L lymphoblast targets sensitized with Y. pseudotuberculosis was lower than that against nontransgenic LEW targets. We conclude that HLA-B27 transgenic rats mount a CTL response against Y. pseudotuberculosis that is not restricted by HLA-B27. Yet, HLA-B27 exerts a negative effect on the level of this response, which could contribute to impaired defense against Yersinia.

Coordinate Involvement of Invasin and Yop Proteins in a Yersinia pseudotuberculosis-Specific Class I-Restricted Cytotoxic T Cell-Mediated Response

Yersinia pseudotuberculosis is a pathogenic enteric bacteria that evades host cellular immune response and resides extracellularly in vivo. Nevertheless, an important contribution of T cells to defense against Yersinia has been previously established. In this study we demonstrate that Lewis rats infected with virulent strains of Y. pseudotuberculosis, mount a Yersinia-specific, RT1-A-restricted, CD8+ T cell-mediated, cytotoxic response. Sensitization of lymphoblast target cells for cytolysis by Yersinia-specific CTLs required their incubation with live Yersinia and was independent of endocytosis. Although fully virulent Yersinia did not invade those cells, they attached to their surface. In contrast, invasin-deficient strain failed to bind to blast targets or to sensitize them for cytolysis. Furthermore, an intact virulence plasmid was an absolute requirement for Yersinia to sensitize blast targets for cytolysis. Using a series of Y. pseudotuberculosis mutants selectively deficient in virulence plasmid-encoded proteins, we found no evidence for a specific role played by YadA, YopH, YpkA, or YopJ in the sensitization process of blast targets. In contrast, mutations suppressing YopB, YopD, or YopE expression abolished the capacity of Yersinia to sensitize blast targets. These results are consistent with a model in which extracellular Yersinia bound to lymphoblast targets via invasin translocate inside eukaryotic cytosol YopE, which is presented in a class I-restricted fashion to CD8+ cytotoxic T cells. This system could represent a more general mechanism by which bacteria harboring a host cell contact-dependent or type III secretion apparatus trigger a class I-restricted CD8+ T cell response.

MHC Class I Molecules Compete in the Endoplasmic Reticulum for Access to Transporter Associated with Antigen Processing

We have used the functionally distinct TAP alleles of the rat in cellular transfectants as tools to investigate how newly formed rat class I (RT1.A) molecules with distinct peptide requirements gain access to suitable peptides in the endoplasmic reticulum (ER). Normal maturation of RT1.Aa depends on the presence in the ER of peptides with C-terminal arginine, while restrictive TAP-B allelic group transporters fail to transport such peptides. In this situation, RT1.Aa is retained in the ER. We show that this retention is accompanied by accumulation of RT1.Aa in the ER, partly associated with TAP and partly free. In such cells, access to TAP of a second allelic product, RT1.Au, which does not require C-terminal arginine peptides, is competitively inhibited by the build-up of RT1.Aa. Nevertheless, RT1.Au loads and matures normally. Introduction of a permissive TAP-A allele competent to transport C-terminal arginine peptides releases RT1.Aa from the ER and restores RT1.Au interaction with TAP. Both class I alleles associate indiscriminately with permissive and restrictive TAP alleles. The data support the view that interaction with TAP is not a prerequisite for peptide loading by class I molecules, so long as suitable peptides are available in the ER. They further show that TAP association of a class I molecule depends on a competitive balance in the ER defined by the extent to which the peptide requirements of other class I molecules present are satisfied and not only by the intrinsic strength of the interaction with TAP.

Antigen processing and autoimmunity. Evaluation of mRNA abundance and function of HLA-linked genes

Quantitative defects in the density of conformationally correct human lymphocyte antigen (HLA) class I complexes on the surface of lymphocytes are apparent in patients with diverse HLA-linked autoimmune diseases, including Type I diabetes and Sjögren's syndrome. First, HLA class I expression was investigated in individuals with two rare and genetically divergent polyglandular autoimmune diseases. Polyglandular failure patients whose disease showed HLA linkage, but not those whose disease was not HLA linked, exhibited decreased HLA class I expression on the surface of their lymphocytes as well as a reduced abundance of transcripts of the HLA-linked genes Tap1 and Tap2, both of which encode proteins that contribute to HLA class I processing. Second, lymphocytes from patients with insulin-dependent diabetes mellitus (IDDM), Sjögren's syndrome, Graves' disease, and Hashimoto's disease showed varying degrees of decreased abundance of mRNAs that encode Tap1, Tap2, Lmp2, or Lmp7 (the latter two proteins also contribute to HLA class I processing). Third, in twins discordant for IDDM, reduced transcript abundance was preferential to diabetic subjects. Fourth, functional assays of isolated diabetic proteasomes, the peptide cutting complex containing LMP2 and LMP7 proteins, revealed altered peptidase activity. These data suggest that defective transcription of HLA class I-processing genes could contribute to the quantitative defect in cell-surface expression in autoimmune lymphocytes of HLA-controlled disease.

Functional Analysis by Site-Directed Mutagenesis of the Complex Polymorphism in Rat Transporter Associated with Antigen Processing

The transporter associated with Ag processing, TAP, is an endoplasmic reticulum resident heterodimeric member of the ATP-binding cassette transporter family. TAP transports short peptides from cytosol to the endoplasmic reticulum lumen for loading into recently synthesized class I MHC molecules. In the rat, two alleles of the TAP2 chain differ in their permissiveness to the transport of peptides with small hydrophobic, polar, or charged amino acids at the C terminus, and this correlates with differences between the peptide sets loaded into certain class I molecules in vivo. We have used segmental exchanges and site-directed mutagenesis to identify the residues in rat TAP2 responsible for differential transport between the two alleles of peptides terminating above all in the positively charged residue, arginine. Of the 25 residues by which the two functional TAP2 alleles differ, we have localized differential transport of peptides with a C-terminal arginine to two adjacent clusters of exchanges in the membrane domain involving a total of five amino acids. Each cluster, transferred by site-directed mutagenesis from the permissive to the restrictive sequence, can independently confer on TAP a partial ability to transport peptides with arginine at the C terminus. The results suggest that the permissive TAP2-A allele evolved in at least two steps, each partially permissive for peptides with charged C termini.

Peptide transport in human lymphoblastoid and tumor cells: effect of transporter associated with antigen presentation (TAP) polymorphism

CD8+ T-cells recognize antigenic peptides presented by major histocompatibility complex (MHC) class I molecules. These peptides bind to MHC class I molecules in the endoplasmic reticulum (ER) lumen. Antigenic peptides are translocated from the cytosol to the lumen of ER by transporter associated with antigen presentation (TAP) proteins. In this study, it is shown that TAP1 polymorphism influences the peptide substrate specificity in human B-lymphoblastoid and tumor cell lines. TAP1A and 1C alleles specifically enhance translocation of model peptides containing basic C-terminal amino acid residue. However, TAP1B allele does not show specificity for the peptide C-terminus. Human basophilic leukemia (Ku812), and hepatocellular carcinoma (PLC/PRF/5) cells express TAP1 molecules and exhibit TAP-mediated allele-specific peptide uptake after gamma-interferon (gamma-IFN) treatment. Ku812 cells express TAP1A and preferentially take up antigenic peptides with a basic C-terminus, however, PLC/PRF/5 cells with the TAP1B allele take up low but equivalent levels of peptides regardless of basic, acidic, or hydrophobic C-termini. Moreover, TAP2 polymorphisms have no influence on the peptide translocation in normal or tumor cell lines. In addition, Daudi, a beta2-microglobulin (beta2m) deficient human Burkitt lymphoma, cell line also showed TAP-dependent peptide uptake. Taken together, these results suggest that human TAP1 but not TAP2 polymorphisms influence the antigenic peptide transport and that this transport is independent of beta2m in this system.

A new MHC locus that influences class I peptide presentation

We have investigated the HLA-B27-restricted CTL response to HY minor histocompatibility antigens in rats and mice transgenic for HLA-B27 and human beta2-microglobulin. A polymorphism was found at a locus within the H2 complex, producing two distinct but overlapping sets of B27-presented HY peptides. The locus, named Cim2, mapped between the K and Pb loci, and its product is therefore distinct from TAP, LMP, and tapasin. Identical findings in rats and mice, including identical HY peptide sequences and the failure of a rat Tap2A transgene to alter CTL recognition, suggest that a homologous locus with similar polymorphism exists in the rat. Cim2, or a closely linked locus, was found to exert a broad effect on peptide loading of both HLA-B27 and mouse class I alleles. The data thus establish a strong, previously unrecognized MHC-encoded influence on the class I antigen pathway.

MHC class I antigen expression in patients with IDDM and their siblings

MHC class I antigen expression was found to be low on the lymphocytes of patients with insulin dependent diabetes mellitus (IDDM). Thus, it has been proposed that the defective expression of MHC antigens could lead to faulty immunological responses with the eventual destruction of the pancreatic beta cells. The objective in this study was to compare MHC antigen expression in IDDM patients and their presently healthy siblings. Nineteen children (mean age 10.8 +/- 3.9 years) with diabetes and their 25 siblings (mean age 10.7 +/- 4.6 years) were enrolled in the study. Peripheral blood lymphocytes isolated from venous blood samples were incubated with FITC conjugated monoclonal antibody W6/32. The amount of antibody binding by cell surface MHC class I antigens was assessed by flow cytometry. MHC class I molecule expression did not differ significantly among IDDM patients and their siblings. It was concluded that MHC class I antigen expression did not appear to be indicative of a susceptibility to develop autoimmune diabetes.

Human TAP1 polymorphisms detected by denaturing gradient gel electrophoresis

Presentation of endogenous peptides by major histocompatibility complex class I (MHC) molecules is controlled, in part, by the Tap1 and Tap2 genes in the MHC class II region that encode a heterodimeric peptide transporter. Polymorphisms of human Tap1 in normal individuals have now been investigated systematically by denaturing gradient gel electrophoresis (DGGE) analysis of fragments of genomic DNA generated by the polymerase chain reaction. Polymorphisms identified by distinctive DGGE band patterns were confirmed by DNA sequencing. In addition to four previously described polymorphisms in the open reading frame, DGGE detected three new polymorphisms: a G-->T substitution in the promoter region, a 10-bp insert in intron 9, and a G-->T substitution 80-bp downstream of the translation termination codon.

Positive and negative MHC class I recognition by rat NK cells

The prompt rejection of transplanted allogeneic lymphocytes by rat NK cells in non-sensitized recipients (allogeneic lymphocyte cytotoxicity or ALC) is determined by MHC genes as well as by genes located in the NK complex. The same genetic control is found when NK alloreactivity is measured by an in vitro assay, and we have employed this assay to delineate the specificity of NK cells for the MHC. The MHC of the rat, RT1, contains class I genes situated on either side of the class II/class III region. The majority of these class I genes are located in the RT1.C region and expressed class I products usually behave as non-classical (class Ib) molecules. They do not serve as restriction elements for the vast majority of conventional alpha/beta T-cells, in contrast to those class I molecules encoded by one or more loci in the classical (class Ia) region, RT1.A. However, NK cells appear to recognize the products of either class I region. Immunogenetic studies suggest that NK cells are inhibited by RT1. A molecules, whereas RT1.C region molecules may have a dual role in regulating NK cytolytic activity, i.e. they either inhibit or activate natural killing. Based on these premises, a model is proposed in which identification of a target as self or non-self depends on different receptors for class I in single NK cells, interpreting coincident positive and negative signals from the various target class I molecules. The putative role of peptides presented by class I, the biological implications, and the evolution of the NK receptors and their ligands are discussed.

Peptide selection for presentation by HLA class I: a role for the human transporter associated with antigen processing?

Peptide epitopes presented by HLA class I are supplied by an elaborate system of antigen processing which subjects candidate epitopes to a process of selection according to little-understood rules. Transport of peptides from the cytosol into the endoplasmic reticulum by the TAP (transporter associated with antigen processing) complex is likely to play an important role in peptide selection for presentation. The recent development of an assay measuring substrate binding to the TAP complex has led to the identification of the major structural properties of peptides selected by the human transporter. Human TAP favors transport of peptides with structural features common to HLA class I ligands. However, TAP dislikes peptide ligands preferred by some HLA class I alleles, which may therefore frequently rely on alternative sources of peptide ligands.

Transporter associated with antigen-processing-1 (TAP1) alleles in Gorilla gorilla: diversification of the locus postspeciation

The transporter associated with antigen-processing (TAP) proteins are required for the transport of cytosolic peptides into the endoplasmic reticulum for assembly with class I major histocompatibility molecules. In the rat, allelic variants of the TAP genes impart specificity to the process of peptide transport. However, differential transport has yet to be demonstrated with the human molecules. TAP genes from humans and rodents have been studied thus far; analysis of another species more closely related to humans is necessary for a clearer understanding of the evolution of TAP genes. Three TAP1 alleles from four gorilla cell lines were characterized in this study. There is limited genetic distance at the locus, either within the gorilla (0.2%) or between the two hominoid species (0.8%). Nucleotide substitution analysis demonstrates that TAP1 and TAP2 are evolving at comparable rates under similar selection pressures. This pattern is in marked contrast to that observed for MHC class I genes of hominoids or rodents. Although there is limited evidence for trans-species evolution of the gorilla locus, the bulk of the diversification occurred after speciation as evidenced by a lack of shared amino acid polymorphism with human homologues. An evolutionary scheme predicts that the ancestral hominoid TAP1 molecule most closely resembled the human TAP1*02011.

Molecular mechanisms of class I major histocompatibility complex antigen processing and presentation

The presentation of antigenic peptides by class I major histocompatibility complex molecules plays a central role in the cellular immune response, since immune surveillance for detection of viral infections or malignant transformations is achieved by CD8+ T lymphocytes which inspect peptides, derived from intracellular proteins, bind to class I molecules on the surface of most cells. The transporter associated with antigen processing selectively translocates cytoplasmically derived peptides of appropriate sequence and length into the lumen of the endoplasmic reticulum where they associate with newly synthesized class I molecules. The translocated peptides are generated by multicatalytic and multisubunit proteasomes which degrade cytoplasmic proteins in a ATP-ubiquitin-dependent manner. This review discusses our current molecular understanding of class I antigen processing and presentation.

Lack of effect of mouse adenovirus type 1 infection on cell surface expression of major histocompatibility complex class I antigens

It has been proposed that adenoviruses establish and maintain persistent infections by reducing the class I major histocompatibility complex-associated presentation of viral antigens to cytotoxic T lymphocytes, leading to ineffective cell-mediated immunity and impaired clearance of infected cells (W.S.M. Wold and L. R. Gooding, Virology 184:1-8, 1991). Early region 3 of human adenovirus types 2 and 5 encodes a 19-kDa glycoprotein that associates with the class I major histocompatibility complex (MHC) antigens in the endoplasmic reticulum and prevents their maturation and transport to the cell surface. Early region 1A of human adenovirus type 12 encodes a protein that inhibits class I MHC mRNA production at the transcriptional or posttranscriptional processing level. Unlike human adenovirus infections, however, mouse adenovirus type 1 (MAV-1) infection of a variety of cell types did not affect the surface expression of 10 different mouse class I MHC allotypes. MAV-1-infected cells also regenerated cell surface class I MHC antigens following proteolytic removal as efficiently as mock-infected cells. The ability of cells to present antigen to class I MHC (Kb)-ovalbumin-specific T-cell hybridoma cells was likewise unaltered by MAV-1 infection. Thus, the ability of MAV-1 to persist cannot be explained by the model of reduced class I MHC-associated antigen presentation proposed for human adenoviruses.

The rat cim effect: TAP allele-dependent changes in a class I MHC anchor motif and evidence against C-terminal trimming of peptides in the ER

Functional polymorphism in the rat peptide transporter associated with antigen processing (TAP) changes the peptide pool available for binding and presentation by a class I MHC allele, RT1.Aa. The peptide binding motif for RT1.Aa, determined by stabilization with synthetic peptides, included a strong preference for arginine at the peptide C terminus. Analysis of natural peptides bound to RT1.Aa by both pool sequencing and anhydrotrypsin chromatography revealed that TAP polymorphism determined the presence or absence of arginine as the peptide C-terminal residue. This result highlights the in vivo impact of TAP-peptide selectivity, and provides evidence against a high rate of generation of new C termini by protease activity in the endoplasmic reticulum.

Polymorphic peptide transporters in MHC class I monomorphic Syrian hamster

We have already shown that in species with highly polymorphic major histocompatibility complex (MHC) class I molecules (human, mouse) no functional polymorphism of the peptide transporters TAP1 and TAP2 is detectable (Lobigs and Müllbacher 1993). Investigating the antigen-presentation machinery of the class I MHC monomorphic Syrian hamster using mouse MHC class I expression via recombinant vaccinia viruses (VV) we found that six hamster cell lines fall into two phenotypic classes. four cell lines (HaK, FF, MF-2, and HT-1) showed no defect in expressing four different H2 class I molecules (Kk, Kd, Kb, Dd) and the appropriate VV peptide recognized by mouse VV-immune cytotoxic T (Tc) cells on the cell surface. Two cell lines (BHK-21 and NIL-2) expressed Dd and Kb in association with VV peptides as recognized by VV-immune, H2-restricted Tc cells but not Kk and Kd. However, Kd was expressed on the cell surface, as shown by fluorescence-activated cell sorter (FACS) analysis and alloreactive Tc-cell recognition. Kk is only surface-expressed in these two cell lines when superinfected with two VV recombinants encoding rat TAP1 (VV-mtp1) and TAP2 (VV-mtp2). Superinfection with VV-mtp1 and VV-mtp2 rendered both cell lines, after infection with either VV-Kk and VV-Kd, susceptible to lysis by either Kk- or Kd-restricted VV-immune Tc cells. Thus Syrian hamster cell lines express functionally polymorphic peptide transporters. The TAP2 gene from FF cells was cloned and sequenced; comparison with human, mouse, and rat TAP2 sequences show 78%, 88% and 87% similarity, respectively.

Substrate specificity of allelic variants of the TAP peptide transporter

The transporter associated with antigen processing (TAP) translocates peptides from the cytosol into the lumen of the endoplasmic reticulum (ER). An important determinant for the specificity of translocation is the identity of the C-terminal residue of the peptide substrate. In the rat, a suitable C terminus is necessary but not always sufficient for a peptide to be selected for translocation. Here we show that sequence constraints within a peptide of optimal length (9 residues) may interfere with transport; that the transporter selectively translocates shorter derivatives of a 16-mer peptide rather than the 16-mer itself; and that the transporter cimb allele, which is most selective in the C termini it will tolerate, is more relaxed in peptide length preference than is the clma variant.

Susceptibility to alloimmunization to platelet HPA-1a antigen involves TAP1 polymorphism

The alloimmunization against platelet HPA-1a antigen in mothers of thrombocytopenic neonates is strongly associated with HLA class II structures (DR3 and DR13) and especially with HLA-DR52a antigen (98% of the cases reported here). Because new genes have recently been mapped within the MHC class II region, we typed TAP1 and TAP2 gene polymorphisms by ARMS-PCR in order to characterize more effectively MHC genes involved in this alloimmunization. Our results showed that TAP1*0102 allele was significantly associated with NAIT only in the population of HLA-DR 13-DR52a-immunized women (50%) versus HLA-DR 13-DR52a controls (20%) (p < 0.05), and not in HLA-DR3-DR52a-immunized women versus HLA-DR3-DR52a controls. There is no linkage disequilibrium between TAP1*0102 and DRB1*13 alleles (delta = -0.0063) that could account for this result. The higher frequency of TAP1*0102 allele among HLA-DR 13-DR52a-immunized women suggests that HPA-1a antigen presentation and recognition may be influenced by nonclassic HLA class II gene polymorphisms, or that other linked but yet unknown genes could interfere.

Expression and purification of nonglycosylated SIV proteins, and their use in induction and detection of SIV-specific immune responses

Two commercially available expression vectors were modified to generate plasmids pGEXcPk and pQ9cPk. Proteins expressed from pGEXcPk and pQ9cPk had a short oligopeptide tag termed Pk at their carboxy termini and either glutathione S-transferase (GST) or a small histidine (His) tag, respectively, at their N termini. GST fusion proteins can be purified on immobilized glutathione and proteins coupled to the His tag selectively bind to Ni(2+)-NTA columns. The Pk tag is recognized by monoclonal antibody (MAb) SV5-P-k, previously produced in our laboratory. Thus proteins expressed from the pGEXcPk and pQ9cPk vectors can be purified in a two-step procedure, first via the N-terminal tag and second via the C-terminal tag. The combination of two affinity purification steps significantly improves the antigen purity and selects for full-size proteins. Moreover, by using the MAbSV5-P-k in the second purification step, Pk-linked antigens can be assembled directly into solid matrix-antibody-antigen (SMAA) complexes for use as vaccines. The genes for nef, endonuclease, p15, p17, p27, protease, Rev, reverse transcriptase (rt), tat, vif, vpr, and vpx of simian immunodeficiency virus (SIV mac 251) were cloned and expressed as both GST-SIV-Pk and His-SIV-Pk proteins. Multivalent SMAA complexes were made that contained His-p17-Pk, His-p27-Pk, His-rt-Pk, His-vpx-Pk, and His-vpr-Pk. Following two immunizations of mice with this mixture, antibodies could be detected to all five SIV antigens. When compared to single-protein immunizations, the immunogenicity of some of the proteins in this cocktail was either enhanced or decreased. Mice were also immunized with His-p17-Pk or His-p17-Pk-antibody complexes in the presence or absence of alum. The antibody-antigen complexes induced two- to four-fold higher antibody levels than antigen alone but did not appear to be more immunogenic in inducing lymphoproliferative responses. Sera from SIV-infected macaques were tested for the presence of antibodies reacting with the recombinant proteins by Western blot analysis. Antibodies to endonuclease, p15, p17, p27, rt, and vif were readily detected, antibodies against protease and vpx were present at much lower levels, but no antibodies were detected to nef, rev, tat, or vpr. Thus, we have developed a comprehensive range of reagents (available on request) that can be used to examine immune responses to SIV in both mice and monkeys.

T cell allorecognition and endogenous HLA-B27-bound peptides in a cell line with defective HLA-B27-restricted antigen presentation

The B*2702+ lymphoblastoid cell line NW is unable to present at least some HLA-B27-restricted viral antigens to T cells. This defect was genetically inherited, and was suggested to be related to the nature of the HLA-B27 binding peptides reaching the endoplasmic reticulum in these cells (Pazmany et al., J. Exp. Med. 1992. 175: 361). In the present study 17 of 19 HLA-B27-specific alloreactive cytotoxic T lymphocyte clones recognizing the B*2702 subtype on other cells also lysed NW cells. Only two cytotoxic T lymphocyte clones failed to lyse NW while efficiently killing other B*2702+ cell lines. The high-performance liquid chromatography profiles of the B*2702+ bound peptides extracted from NW cells was similar, but not identical, to those from two other cell lines. These results indicate that the HLA-B27-bound peptide repertoire in NW cells is not fundamentally different from those in other B*2702+ cells. Our data argue against gross differences in peptide processing or transport as being responsible for the defective presentation of particular HLA-B27-restricted viral antigens to T cells, but do not rule out distinct presentation of some endogenous peptides. Differences in the capacity to present certain peptides could cause differential susceptibility among HLA-B27+ individuals to ankylosing spondylitis.

Reduction of class I expression in a bovine B-lymphoblastoid cell line is locus specific

A bovine B-lymphoblastoid cell line, BL3.1.2, defective in MHC class I expression was isolated following gamma irradiation and immunoselection of a previously mutated cell, BL3.1. Flow microfluorimetry demonstrated that BL3.1.2 cells expresed reduced amount of class I molecules on the cell surface when compared with the parent cells. 2D gel electrophoresis showed that two less class I gene products were synthesized by BL3.1.2 cells than the parent cells. However, no detectable RFLP difference was revealed between this mutant and the parent cell lines as analyzed by Southern blots using bovine class I cDNA and locus-specific oligonucleotide probes, suggesting no major deletions, insertions, or translocations within class I genes. Northern blot analysis, using class I cDNA probes, revealed a marked reduction of class I mRNA in BL3.1.2 cells. RNA unblots, probed with loci-specific oligonucleotides, and slot blot analysis demonstrated that absence of class I gene transcription was locus specific. This finding indicates there is separate regulation of each class I locus in bovine cells. Furthermore, recombinant IFN-gamma upregulated class I gene expression on the BL3.1.2 cells, as indicated by flow cytometry and slot blot analysis. These findings indicate that the locus-specific MHC class I gene was functionally downregulated in its expression. The silent class I gene could be activated by cytokines known to activate the cis-interferon-responsive element for subsequent transcription and translation of the newly synthesized class I RNA.(ABSTRACT TRUNCATED AT 250 WORDS)

The distribution of Tap2 alleles among laboratory rat RT1 haplotypes

We are reporting the cDNA sequences of Tap2 from two cima and two cimb rat strains. Comparison of the cDNA sequences shows that these alleles fall into two groups, which we refer to as Tap2-A and Tap2-B. We found that alleles from the Tap2-B group are more closely related to the mouse homologue than are Tap2-A alleles, and among the 48 nucleotides which differ between the Tap2-A and Tap2-B cDNAs, three affect restriction sites. We defined pairs of oligonucleotides which allow amplification of the regions bearing these restriction sites from genomic DNA or cDNA, and this technique has been successful for the genotyping of all of the 56 laboratory strains of Rattus norvegicus tested and for five cell lines tested so far. All 14 known RT1 standard haplotypes were tested, and 7 found to belong to the Tap2-B group, and 7 to Tap2-A. We also found that intron sizes among the alleles of the Tap2-B group fall into two subgroups, providing further insight into the phylogeny of these various haplotypes.

Peptide translocation by variants of the transporter associated with antigen processing

Major histocompatibility complex (MHC) class I molecules associate with peptides that are delivered from the cytosol to the lumen of the endoplasmic reticulum by the transporter associated with antigen processing (TAP). Liver microsomes of SHR and Lewis rats, which express different alleles of TAP (cim(b) and cim(a), respectively), accumulate different sets of peptides. Use of MHC congenic rats assigned this difference to the MHC, independent of the class I products expressed. Both the cim(a) and cim(b) TAP complexes translocate peptides with a hydrophobic carboxyl terminus, but translocation of peptides with a carboxyl-terminal His, Lys, or Arg residue is unique to cim(a). Thus, the specificity of the TAP peptide translocator restricts the peptides available for antigen presentation.

An antigen processing polymorphism revealed by HLA-B8-restricted cytotoxic T lymphocytes which does not correlate with TAP gene polymorphism

In previous studies of antigen presentation through HLA-B27, we identified a healthy person whose lymphoblastoid cells do not present three B27-restricted viral epitopes to specific cytotoxic T lymphocytes (CTL), despite adequate cell surface expression of HLA-B2702 of normal sequence. Similar findings were observed in all members of his family sharing the HLA-A3-B2702 haplotype. The original donor, NW, carries HLA-B8 on his other class I haplotype, which his daughter, HW, has inherited. We now report a failure to present an HLA-B8-restricted epitope from influenza nucleoprotein following viral infection of NW cells, although exogenous added peptide is still presented normally. However, cells from HW, which do not carry the A3-B2702 haplotype, present the expected epitope after viral infection. Another B8-restricted epitope, from human immunodeficiency virus-gag, is presented equally well by both cell lines when infected with gag-vaccinia. This antigen processing phenotype does not correlate with any of the known human TAP-1 and TAP-2 polymorphisms.

Sharing of an HLA-B27-restricted H-Y antigen between rat and mouse

The purpose of this work was twofold: 1) to learn whether rats transgenic for HLA-B27 and the human beta 2-microglobulin gene HB2M can mount B27-restricted cytolytic T lymphocyte (CTL) responses to the male H-Y antigen, and 2) to learn whether such CTLs would recognize both rat and mouse H-Y in the context of HLA-B27. Female rats of the B27/HB2M transgenic line 21-4L were primed in vivo with cells from males of the same line. CTL effectors were generated from lymph node cells of these females following culture with irradiated antigen-presenting cells from either male 21-4L rats or male mice of the B27/HB2M transgenic 56-3 line. The CTLs showed male-specific, B27-specific lysis of both rat and mouse targets. Lysis of B27 targets was inhibitable by monoclonal antibodies specific for B27 or rat CD8. Specific lysis of male B27 rat and mouse targets was inhibitable equally by either rat or mouse male B27 cold targets, but not significantly by female or nontransgenic cold targets. The B27-restricted CTLs neither recognized nor were inhibited by B27+ or B27- male or female human targets. These results demonstrate that CD8+, B27-restricted, anti-H-Y CTLs recognize an evolutionarily conserved H-Y peptide antigen in both rats and mice. In addition, they establish the transgenic rat as a model system for examining the T-cell response to antigen presented by class I HLA molecules.

Effects of CD8 depletion on retinal soluble antigen induced experimental autoimmune uveoretinitis

During the later stages of soluble-antigen (sAg)-induced experimental autoimmune uveoretinitis (EAU), an increase in the relative number of CD8+ lymphocytes has been observed at the site of inflammation in the retina. It has been suggested that these late-appearing CD8+ cells might down-regulate this acute disease process. To determine the role of the CD8+ cells in EAU, Lewis rats were depleted of CD8+ cells prior to and during disease and the enucleated eyes examined histologically. The spleen cells from CD8-depleted rats were also examined for their ability to respond to concanavalin A (Con A) and to allogeneic targets as determined by mixed lymphocyte reaction (MLR) and cytotoxicity assays. The results suggest that depleting CD8+ cells had no effect on the course of disease and that CD8+ cells do not play a crucial role in the immunoregulation of EAU.

Defective major histocompatibility complex class I expression on lymphoid cells in autoimmunity

Lymphocytes from patients with insulin-dependent diabetes mellitus (IDDM), a chronic autoimmune disease, have recently been shown to have decreased surface expression of MHC class I antigens. Since IDDM and other autoimmune diseases share a strong genetic association with MHC class II genes, which may in turn be linked to genes that affect MHC class I expression, we studied other autoimmune diseases to determine whether MHC class I expression is abnormal. Fresh PBLs were isolated from patients with IDDM, Hashimoto's thyroiditis, Graves' disease, systemic lupus erythematosis, rheumatoid arthritis, and Sjogren's syndrome. Nondiabetic and non-insulin-dependent diabetes mellitus patients served as controls. MHC class I expression was measured with a conformationally dependent monoclonal antibody, W6/32. Freshly prepared PBLs from the autoimmune diseases studied and the corresponding fresh EBV-transformed B cell lines had decreased MHC class I expression compared with PBLs from normal volunteers and non-insulin-dependent (nonautoimmune) diabetic patients. Only 3 of more than 180 donors without IDDM or other clinically recognized autoimmune disease had persistently decreased MHC class I expression; one patient was treated with immunosuppressive drugs, and subsequent screening of the other two patients revealed high titers of autoantibodies, revealing clinically occult autoimmunity. Patients with nonautoimmune inflammation (osteomyelitis or tuberculosis) had normal MHC class I expression. Autoimmune diseases are characterized by decreased expression of MHC class I on lymphocytes. MHC class I expression may be necessary for self-tolerance, and abnormalities in such expression may lead to autoimmunity.

Molecular basis of genetic polymorphism in major histocompatibility complex-linked proteasome gene (Lmp-2)

Four genes, closely linked to major histocompatibility complex (MHC) class II genes, have been identified in humans, mice, and rats and are thought to be involved in the generation and transport of endogenous immunogenic peptides for the MHC class I antigen-processing pathway. The Tap-1 and Tap-2 genes presumably encode a heterodimeric protein complex responsible for transporting endogenous immunogenic peptides to the lumen of the endoplasmic reticulum. The Lmp-2 and Lmp-7 gene products are two subunits of the large cytosolic proteasome complex possibly involved in generation of endogenous peptides. To study the genetic polymorphism of the Lmp-2 gene, we used a published cDNA sequence as a consensus sequence and PCR-amplified, cloned, and sequenced the Lmp-2 gene from 12 inbred mouse strains. We found three amino acid variants, LMP-2d, LMP-2b, and LMP-2q, which partially correlated with restriction fragment length polymorphism variants identified with Southern blots. Allelic polymorphism of the Lmp-2 gene may be involved in peptide selection, leading to autoimmune disease susceptibility.

Recognition of vaccinia virus-encoded major histocompatibility complex class I antigens by virus immune cytotoxic T cells is independent of the polymorphism of the peptide transporters

In the cytotoxic T-cell response to viruses, peptide antigens of cytoplasmic origin are presented at the cell surface by the highly polymorphic major histocompatibility complex (MHC) class I molecules to CD8+ T-lymphocyte receptors. Peptide transporter molecules and other MHC-linked gene products have been implicated in the generation and import of antigenic peptides into the lumen of the endoplasmic reticulum for assembly with MHC class I glycoproteins. These accessory molecules in the antigen-presentation pathway map to a polymorphic region in the class II MHC, and the possibility of their allele-specific selectivity in antigen presentation has been raised. Here we show that additional, functionally polymorphic components are not apparent in an in vitro mouse MHC class I-restricted cytotoxic T-cell response to vaccinia and influenza viruses. When the mouse H-2Kd molecule was expressed via a recombinant vaccinia virus in target cells of different mouse MHC haplotypes or cells of rat, Syrian hamster, monkey, and human origin, efficient Kd-restricted and vaccinia virus-specific lysis was observed as measured with bulk effectors and at the clonal level. In addition, human transporters efficiently processed peptides originating from influenza virus nucleoprotein and hemagglutinin antigens as recognized by mouse influenza immune cytotoxic T cells.

Cell biology of antigen presentation

MHC class I molecules present degradation products derived from intracellular proteins, whereas MHC class II molecules generally present peptides derived from extracellular or surface proteins. Recent insights into the cell biology of MHC class I and II molecules explain this difference.

Genomic polymorphism, recombination, and linkage disequilibrium in human major histocompatibility complex-encoded antigen-processing genes

Recently, two subunits of a large cytosolic protease and two putative peptide transporter proteins were found to be encoded by genes within the class II region of the major histocompatibility complex (MHC). These genes have been suggested to be involved in the processing of antigenic proteins for presentation by MHC class I molecules. Because of the high degree of polymorphism in MHC genes, and previous evidence for both functional and polypeptide sequence polymorphism in the proteins encoded by the antigen-processing genes, we tested DNA from 27 consanguineous human cell lines for genomic polymorphism by restriction fragment length polymorphism (RFLP) analysis. These studies demonstrate a strong linkage disequilibrium between TAP1 and LMP2 RFLPs. Moreover, RFLPs, as well as a polymorphic stop codon in the telomeric TAP2 gene, appear to be in linkage disequilibrium with HLA-DR alleles and RFLPs in the HLA-DO gene. A high rate of recombination, however, seems to occur in the center of the complex, between the TAP1 and TAP2 genes.

MHC class I and autoimmune diabetes

The cause of failed self tolerance, resulting in autoimmunity is unknown, although genetic linkage to genes within the MHC class II region have been well described. We present evidence that failed self tolerance in autoimmune diabetes appears to be secondary to an antigen presenting cell defect; the diabetic antigen presenting cells fail to deliver fragments of endogenous antigens to the cell surface in the groove of MHC class I. In the diabetic NOD mouse model, this correlates with a rare allele at the Tap-1 locus, a gene that controls proper MHC class I assembly by providing fragments of endogenous peptides into the endoplasmic reticulum. We propose that MHC class I presentation of self peptides may represent a normal pathway for tolerance induction and interruption of this important class I function from any cause, including the MHC class II-linked Tap-1 and Tap-2 genes, which may result in autoreactivity.

Different rates of HLA class I molecule assembly which are determined by amino acid sequence in the alpha 2 domain

Assembly of HLA class I molecules was studied using pulse-chase labeling of B-lymphoblastoid cell lines with 35S-methionine, immunoprecipitation with antibodies detecting free or beta 2-microglobulin-associated heavy chain and isoelectric focusing. Marked differences between the products of different class I alleles were noted. HLA-B51 assembled very inefficiently, with considerable free heavy chain still detected in an unsialated form after a four hour chase. The closely related molecule HLA-B35 was in contrast rapidly assembled, all newly synthesized heavy chain being detected in a beta 2m-associated sialated form within 30 minutes. Analysis of naturally occurring variants related to HLA-B35 and HLA-B51 localized the region determining assembly efficiency to the alpha 2 domain, in which these molecules differ at eight amino acid residues. The effect was not due to a linked dominant gene, as both patterns of assembly were observed in a single cell line.