The MHC class I genes of the rhesus monkey. Different evolutionary histories of MHC class I and II genes in primates

Homologues of the human HLA-A and -B MHC class I loci have been found in great apes and Old World primates suggesting that these two loci have existed for at least 30 million years. The C locus, however, shows some sequence similarity to the B locus and has been found only in gorillas, chimpanzees, and humans. To determine the age of the MHC class I C locus and to examine the evolution of the A and B loci we have cloned, sequenced, and in vitro translated 16 MHC class I cDNAs from two unrelated rhesus monkeys (Macaca mulatta) using both cDNA library screening and PCR amplification. Analyses of these sequences suggest that the C locus is not present in the rhesus monkey, indicating that this locus may be of recent origin in gorillas, chimpanzees, and humans. The rhesus monkey's complement of MHC class I genes includes the products of at least one expressed A locus and at least two expressed B loci, indicating that a duplication of the B locus has taken place in the lineage leading to these Old World primates. Comparison of rhesus monkey MHC class I cDNAs to their primate counterparts reveals fundamental differences between MHC class I and class II evolution in primates. Although MHC class II allelic lineages are shared between humans and Old World primates, no such trans-species sharing of allelic lineages is seen at the MHC class I loci.     

Interpreting MHC class I expression and class I/class II reciprocity in the CNS: reconciling divergent findings

MHC-restricted T cells are thought to contribute to clinical demyelination in MS and other circumstances. The step-by-step mechanisms involved and ways of controlling them are still being defined. Identification of the MHC+ cells in the CNS in situ has been controversial. This chapter reviews MHC expression in neural tissue, including normal, pathological, experimental, and developing tissue in situ and isolated cells in vitro. A basic pattern is defined, in which MHC expression is limited to nonneural cells and strongest class I and II expression are on different cell types. Variations from the basic pattern are reviewed. Ways of reconciling divergent findings are discussed, including the use of "mock tissue" to help choose between technical and biological bases for divergent findings, the potential contribution of internal antigen to the in situ staining patterns, and the possibility that class I upregulation is actively suppressed in situ. Functional implications of the observed patterns of MHC expression and ways of confirming the function of each MHC+ cell type in situ are described. It is suggested that modulating MHC expression in different cell types at different times or in different directions might be desirable.     

De novo expression of MHC class I and class II antigens on endomyocardial biopsies from patients with inflammatory heart disease and rejection following heart transplantation

Inflammation of the heart muscle is caused either by infection (i.e. coxsackie virus) resulting in myocarditis or by rejection following heart transplantation. These processes induce activation of the immune system. We examined endomyocardial biopsies from patients with myocarditis, perimyocarditis and rejection following heart transplantation and compared these to biopsies from patients with coronary artery disease. The biopsies were examined immunohistologically with specific monoclonal antibodies against class I and class II molecules of the major histocompatibility complex (MHC). MHC class I antigens on the normally negative myocytes were evident in myocarditis (38%) and in rejection after heart transplantation (68%). In the interstitium there was an increase of both MHC class I and class II antigens. MHC class II antigens, however, were never seen on myocytes. MHC class I antigens are required for the action of CD 8 positive cytotoxic T cells. Therefore myocytes which express MHC class I antigens are susceptible to cytotoxic effects of the immune system. MHC class II antigens are essential to T helper cells. By cytokine release, activated T helper cells play a central role in the initiation, regulation and mediation of an immune response in myocarditis and rejection following heart transplantation.     

Regulation of MHC class I heterodimer stability and interaction with TAP by tapasin

Major histocompatibility complex (MHC) class I molecules are heterodimers of a class I heavy chain and beta 2-microglobulin that bind peptides supplied by the MHC region-encoded transporters associated with antigen processing (TAP). Peptide binding by class I heterodimers is necessary for their maturation into stable complexes and is dependent on their physical association with TAP. In human mutant 721.220 cells, however, a novel genetic defect causes the failure of class I heterodimers to associate with TAP. This deficiency correlates with lack of expression of a glycoprotein, tapasin (TAP-associated glycoprotein), which has been found in association with class I heterodimers and TAP. Employing a transcomplementation analysis, we obtained evidence co-localizing the genetic defect of mutant 220 cells and the structural or a regulatory gene controlling the expression of tapasin on the short arm of chromosome 6, which includes the MHC. Expression of tapasin and the normal interaction of class I heterodimers with TAP are concomitantly restored, indicating the probable function of tapasin as a physical link between these complexes. In further support of this model, the absence of tapasin in mutant 220 cells correlates with reduced class I heterodimer stability, suggesting that tapasin may stabilize class I heterodimers and thereby enhance their association with TAP. These results further implicate tapasin in a mechanism that promotes peptide binding by class I heterodimers through their interaction with TAP.     

Methylcholanthrene-induced sarcomas in nude mice have short induction times and relatively low levels of surface MHC class I expression

In order to study the role of the T-cell-mediated immune defense in tumor development, a total of 93 sarcomas were induced using different doses (8 micrograms (0.1%), 40 micrograms (0.5%) and 400 micrograms (5%)) of 3-methylcholanthrene in athymic nude Balb/c mice and phenotypically normal immunocompetent Balb/c mice. A shorter tumor induction time and a higher tumor incidence after treatment with low doses of methylcholanthrene were seen in nude mice than in immunocompetent mice, indicating that they have a lower resistance to the carcinogen. Contrary to expectations we found that the MHC class I expression of tumors from nude mice was lower than that of tumors from normal mice. Higher surface expression of MHC class I was demonstrated on high dose tumors from normal mice than on low dose tumors from normal mice. The cellular composition of the individual tumors raised in nude mice was more heterogeneous with respect to MHC class I expression. Since the mice differ genetically only with respect to the nu gene, these results indicate that a lack of T-cell-mediated defense mechanisms may confer upon the bearer a lower resistance to 3-methylcholanthrene and a different MHC profile of the ensuing tumor.     

Neuronal control of MHC class II inducibility in rat astrocytes and microglia

We analysed the inducibility of major histocompatibility complex (MHC) class II molecules of astrocytes and microglia in organotypic hippocampus slice cultures of Lewis rats. Treatment with interferon-gamma (IFN-gamma) resulted in the induction of MHC class II molecules on microglia preferentially in the injured marginal zones of the slice culture, but only sporadically in areas containing intact neuronal architecture. In astrocytes, inducibility of MHC class II molecules was even more strictly controlled. IFN-gamma treatment induced MHC class II expression only in the slice culture zones containing degenerated neurons, and not in the presence of functional neurons. After suppression of spontaneous neuronal activity of the slice culture by the sodium channel blocker tetrodotoxin, MHC class II molecules on astrocytes could be induced by IFN-gamma in areas with intact neuronal architecture, and microglia cells exhibited a higher level of expression. These data suggest that loss of neurons could result in MHC class II inducibility of glial cells, and thus in increased immune reactivity of nervous tissue.     

Chimeric peptides: a new approach to enhancing the immunogenicity of peptides with low MHC class I affinity: application in antiviral vaccination

Recruitment of the CTL repertoire specific for subdominant epitopes that have a low MHC class I-binding affinity could be the way to achieve an efficient protective immunity against spontaneous tumors and viruses with high mutation rate. However, we have reported recently that subdominant peptides of influenza A Puerto Rico/8/34 (flu PR8) nucleoprotein (NP) with low Db affinity are only partially able to protect mice against lethal influenza infection. This seems to be due to their inability to recruit the specific CTL repertoire, and suggests that subdominant peptides could be used for vaccination only if they become highly immunogenic. In this work, we describe an approach that allows enhancement of the immunogenicity of every low affinity peptide presented by the Db molecule. It consists in producing chimeric peptides composed by amino acids from a high Db affinity peptide (NP366) in positions that interact with the MHC, and amino acids from low Db affinity nonimmunogenic influenza NP-derived peptides (NP17, NP97, NP330, and NP469) in positions that are exposed to the TCR. All chimeric peptides tested exhibited a high Db affinity and efficiently recruited the CTL repertoire specific for the corresponding low Db affinity peptide. Furthermore, vaccination with chimeric peptides that corresponded to subdominant NP17 and NP97 peptides induced a very potent anti-flu PR8 protective immunity.     

IFN-gamma treatment increases insulin binding and MHC class I expression in erythroleukemia cells

We have investigated if interferon-gamma (IFN-gamma) treatment of human K562 tumor cells, which upregulates the expression of MHC class I antigens (MHC-I), simultaneously would influence insulin binding. Treatment of K562 cells with recombinant human IFN-gamma for 48 h caused a significant increase of insulin binding at 37 degrees C. Recombinant human tumor necrosis factor-alpha (TNF-alpha) alone had no effect but acted synergistically with IFN-gamma, leading to a two-fold increase of insulin binding. No change in affinity, number of binding sites or cell surface expression of insulin receptors (IR) after IFN-gamma treatment could be detected. The increased insulin binding observed at 37 degrees C was not seen at 4 degrees C, suggesting alteration of insulin internalization. The dose-response curve, as well as the time curve, for the increase in insulin binding after IFN-gamma treatment correlated with enhanced cell surface expression of MHC-I antigens. However, the correlation was not absolute. Our results show that IFN-gamma treatment alone or together with TNF-alpha, can alter the insulin binding to K562 cells without changing the expression or affinity of the IR. This correlates with the effect of IFN-gamma on MHC-I expression. These results support the findings that MHC-I molecules associate and interact with the IR at the cell surface.     

Immunodominance of a single CTL epitope in a primate species with limited MHC class I polymorphism

MHC class I molecules play a crucial role in immunity to viral infections by presenting viral peptides to cytotoxic T lymphocytes. One of the hallmarks of MHC class I genes in outbred populations is their extraordinary polymorphism, yet the significance of this diversity is poorly understood. Certain species with reduced MHC class I diversity, such as the cotton-top tamarin (Saguinus oedipus), are more susceptible to fatal viral infections. To explore the relationship between this primate's limited MHC class I diversity and its susceptibility to viruses, we infected five cotton-top tamarins with influenza virus. Every tamarin recognized the same immunodominant CTL epitope of the influenza nucleoprotein. Surprisingly, this nucleoprotein peptide was bound by Saoe-G*08, an MHC class I molecule expressed by every cotton-top tamarin. Two tamarins also made a subdominant response to an epitope of the matrix (M1) protein. This peptide appeared to be bound by another common MHC class I molecule. With the exception of an additional subdominant response to the polymerase (PB2) protein in one individual, no other influenza-specific CTL responses were detected. In populations or species with limited MHC class I polymorphism like the cotton-top tamarin, a dependence on shared MHC class I molecules may enhance susceptibility to viral infection, since viruses that evade MHC class I-restricted recognition in one individual will likely evade recognition in the majority of individuals.     

Identification, inheritance, and linkage of B-G-like and MHC class I genes in cranes

Trans-4-hydroxy-2-nonenal (HNE) is a potent cytotoxic and genotoxic compound originating from the peroxidation of n-6 polyunsaturated fatty acids. Its metabolism has been previously studied in the rat (Alary et al. 1995. Chem. Res. Toxicol., 8: 35-39). In addition to major urinary mercapturic derivatives, some polar urinary metabolites were isolated and could correspond to hydroxylated compounds. 4-Hydroxynonenoic acid (HNA), resulting from the oxidation of the HNE carbonyl group, is a medium chain fatty acid and its omega-hydroxylation might be hypothesized. Therefore, the involvement of the CYP 4A family isoenzymes in the metabolism of [3H]HNE has been investigated in vivo using inducer treatments (fibrates) in wild-type or in peroxisome proliferator-activated receptor alpha (PPARalpha)-deficient mice. In wild-type mice, but not in PPARalpha (-/-) mice, fibrate treatments resulted in an increase of two urinary metabolites characterized, after HPLC purifications and mass spectrometry analyses, as the omega-hydroxylated metabolite of HNA, i.e., 4,9-dihydroxy-2-nonenoic acid, and its oxidized form, 4-hydroxy-2-nonene-1,9-dicarboxylic acid. The formation of the latter is correlated accurately to laurate hydroxylase activity studied concurrently in microsomes prepared from the liver of these animals. Basal levels of these two metabolites were measured in urine of normal and PPARalpha-deficient mice. These results are in accord with an implication of the P450 4A family in the extended oxidative metabolism of 4-HNE.     

Glucose turnover and insulin sensitivity in rats with pancreatic islet transplants

To study the metabolic effects of insulin derived from islet grafts, oral glucose tolerance (OGT) and glucose turnover were examined in streptozotocin-induced diabetic Lewis rats rendered normoglycemic by syngeneic islet grafts in the renal subcapsular space (REN), in REN with renal vein-to-mesenteric vein anastomosis (REN-RMA), in the liver (intrahepatic [IH]), or in a parahepatic omental pouch (POP) and compared with normal rats. Normal OGT was found at 1 month posttransplant in all animals receiving approximately 3,000 islets, with hyperinsulinemic responses in the REN group compared with the other groups, and with higher C-peptide responses in the IH group than in the other groups (P < 0.05 by one-way analysis of variance). Glucose turnover studies in the insulin-stimulated steady state (INS-SS; infusion of insulin at 10 pmol x kg(-1) x min(-1)) at 2 months posttransplant showed that whole body glucose disappearance rates (Rd) were similar in all groups, but the REN group had higher steady-state insulin levels than the other groups. Glucose infusion rates (GIRs) were lower in the REN and IH groups than in the other groups. Apparent endogenous glucose production (EGP) was not completely inhibited in the REN and IH groups, while complete inhibition was observed in the other groups. When INS-SS insulin levels were matched to the level in REN rats by increasing the insulin infusion rate to 20 pmol x kg(-1) x min(-1) in REN-RMA, IH, and normal rats, GIR and Rd were elevated, exceeding those values in REN rats, but GIR in IH rats was still lower than in REN-RMA and normal rats. Thus, 1) in the REN group, impairment of inhibition of EGP and of stimulation of Rd by exogenous insulin contribute to insulin resistance; 2) in the IH group, incomplete inhibition of EGP is the major determinant of insulin resistance; and 3) with portal delivery of insulin in the REN-RMA and POP groups, normal insulin sensitivity is preserved. The present study confirms that hepatic portal delivery of islet secretions is necessary for physiological regulation of glucose metabolism. The study also suggests the IH grafts do not provide physiological regulation of glucose metabolism, raising the question of whether the liver is an appropriate site for insulin-secreting tissue replacement therapy in diabetes.     

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.     

Inhibition of the ATP-sensitive potassium channel by class I antiarrhythmic agent, cibenzoline, in rat pancreatic beta-cells

1. Cibenzoline, a class I antiarrhythmic agent, was investigated for its effect on the ATP-sensitive K+ channel of pancreatic beta-cells by the patch clamp technique. 2. In perforated patch clamp experiments, cibenzoline depolarized the membrane of single beta-cells and thereafter, caused firing of action potentials in the presence of 2.8 mM glucose. 3. Cibenzoline inhibited the activity of the ATP-sensitive K+ channel in cell-attached recordings in the presence of 2.8 mM glucose and evoked repetitive fluctuations of the baseline current, apparently reflecting the action potentials of the beta-cell. 4. In whole-cell clamp experiments, time-independent outward current was induced by depleting cytoplasmic ATP with 0.1 mM ATP and 0.1 mM ADP in the solution contained in the pipette. The outward current was inhibited by cibenzoline in a dose-dependent manner in the concentration range of 1 microM to 100 microM and half maximum inhibition occurred at 1.5 microM. 5. Cibenzoline blocked substantially the ATP-sensitive K+ channel current when applied at the inner side of the membrane in isolated inside-out membrane patches. 6. It is concluded that cibenzoline blocks the ATP-sensitive K+ channel of pancreatic beta-cells and, thereby, stimulates insulin secretion at sub-stimulatory levels of glucose.     

Alterations in TCR-MHC contacts subsequent to cross-recognition of class I MHC and singly substituted peptide variants

Vesicular stomatitis virus (VSV) elicits H-2Kb-restricted CTLs specific for the immunodominant VSV octapeptide RGYVYQGL. To study the structural features important for interaction between the TCR beta-chain and the peptide/MHC complex, we immunized TCR alpha-chain transgenic mice with the VSV peptide and raised a panel of anti-VSV CTL clones with identical TCR alpha-chains. Consistent with our previous analysis of uncloned populations of primary CTLs, the anti-VSV CTL clones were all Vbeta13+ and expressed TCR beta-chains with highly homologous complementarity-determining region 3 (CDR3) loops. Although the clones expressed similar TCRs, they differed in their ability to cross-react with VSV peptide variants singly substituted at TCR contact positions 4 and 6. These findings allowed us to identify short stretches of amino acids in the C-terminal region of the CDR3beta loop that, when altered, modify the cross-reaction capability of the TCR to position 4 and position 6 variant peptides. To further probe the structural correlates of biologic cross-reactivity, we used cross-reactive CTL clones and cell lines expressing point mutations in H-2Kb to investigate the effect of single amino acid changes in the peptide on the pattern of recognition of the TCR for the peptide/MHC complex. Single conservative substitutions in the peptide were sufficient to alter the recognition contacts between a cross-reactive TCR and the MHC molecule, supporting the idea that the TCR can make overall structural adjustments in MHC contacts to accommodate single amino acid changes in the peptide.     

Comparison of the roles of CD8 alpha alpha and CD8 alpha beta in interaction with MHC class I

The CD8 molecule is expressed either as an alpha/alpha homodimer or an alpha/beta heterodimer on thymocytes and cytotoxic T cells, and functions as a coreceptor in concert with TCR for binding the MHC class I/peptide complex. Although CD8alpha/beta heterodimers have been shown to be more effective coreceptors, the precise role of the beta-chain in TCR-mediated thymic maturation and T cell activation is not understood. To understand the role of CD8beta in mediating CD8/MHC class I interaction, we examined whether cell surface CD8alpha/beta heterodimer promotes better cell-cell adhesion with MHC class I than the CD8alpha/alpha homodimer. The abilities of different forms of CD8 to adhere to MHC class I were measured with a cell-cell binding assay. Using a wild-type CD8beta and -alpha, we found that CD8alphabeta heterodimers did not mediate greater cell-cell adhesion than CD8alphaalpha homodimers. Furthermore, we found that chimeric CD8beta-alpha homodimers afforded no detectable binding. These results do not support the idea that CD8alphabeta binding to MHC class I is greater than that of CD8alphaalpha. Rather, they point to an alternative explanation in which CD8beta may play an role in promoting CD8/TCR interaction and/or in signaling/regulatory pathways.