The detection of conventional class I and class II I-E homologue major histocompatibility complex molecules on feline cells

The presence on feline cells of class I and class II I-E type major histocompatibility complex (MHC) homologues was demonstrated using cross-reacting monoclonal antibodies (mAb). The feline class I antigen homologues were detected with both immunofluorescent and biochemical techniques, using the anti-human class I mAb W6/32. The class I antigens were detected on in vitro cultured feline fibroblasts and lymphoid cells, but not on fresh lymphoid cells, apparently as a result of the association of bovine beta-2 microglobulin with feline class I heavy chains which generated the determinant(s) recognized by mAb W6/32. Class II I-E-like molecules could be detected with immunofluorescent techniques using the species cross-reactive anti-mouse I-E antibody 40D only when peripheral blood mononuclear cells were activated, for example, with the mitogens staphylococcus enterotoxin A or lipopolysaccharide. The predominant expression of I-A-like molecules by resting class II-positive feline cells could explain some of the functional difference we have seen in comparison with those of most other mammalian species.     

Detection of protein binding to a glucocorticoid response element-like sequence in a chicken major histocompatibility complex class II promoter

The glucocorticoid response element in gene promoters mediates regulation of gene expression by glucocorticoids. The major histocompatibility (MHC) class II genes, crucial for immunoresponsiveness, are among those modulated by glucocorticoids. A GRE-like sequence has been located in the promoter of a chicken MHC class II promoter. DNase footprinting revealed protein binding by the GRE-like sequence when nuclear extract from chicken T or B cell lines were used. Gel shift assays detected multiple binding activities in the lymphocyte cell lines, but little binding in the macrophage cell line. Relative band intensity differed among the lymphocyte cell lines. By using a mutant GRE oligonucleotide, most of the binding activities were demonstrated to be specific to the GRE. This study suggests a role of the GRE-like sequence in regulating chicken MHC class II genes and provides further evidence for the previously reported influence of glucocorticoids on chicken MHC class II expression which may be the molecular basis of glucocorticoid immunomodulation.     

Functional expression of a bovine major histocompatibility complex class I gene in transgenic mice

Major histocompatibility complex (MHC) class I restricted cellular immune responses play an important role in immunity to intracellular pathogens. By binding antigenic peptides and presenting them to T cells, class I molecules impose significant selection on the targets of immune responses. Candidate vaccine antigens for cellular immune responses should therefore be analysed in the context of MHC class I antigen presentation. Transgenic mice expressing human MHC (HLA) genes provide a useful model for the identification of potential cytotoxic T lymphocyte (CTL) antigens. To facilitate the analysis of candidate CTL vaccines in cattle, we have produced transgenic mice expressing a common bovine MHC (BoLA) class I allele.The functional BoLA-A11 gene, carried on a 7 kb genomic DNA fragment, was used to make transgenic mice by pronuclear microinjection. Three transgenic mouse lines carrying the BoLA-A11 gene were established. Expression of the BoLA-A11 gene was found in RNA and the A11 product could be detected on the surface of spleen and blood cells. Functional analysis of the A11 transgene product, and its ability to act as an antigen presenting molecules in the mouse host will be discussed.     

Effects of genotype matching of feline major histocompatibility complex (FLA) class II DRB on skin-allograft transplantation in cats.

In order to confirm the effects of matching of expressed feline major histocompatibility complex (FLA) class II DRB genotype on transplantation immunity in cats, skin-allogeneic transplantation was carried out between cats, in which DRB genes expressed were genotyped by the RT-PCR-RFLP method using group-specific primers. Duration until grafts were rejected was 14.63 +/- 1.69 days (mean +/- standard deviation) in the pairs that had the same type of subgroups, 7.25 +/- 0.71 days in the pairs that had one different type of subgroup and 6.88 +/- 0.35 days in the pairs that had two different types of subgroups. The duration of graft survival in the pairs with the same type of subgroups was significantly longer (P<0.01) than those in the pairs with different types. Although FLA components involved in transplantation immunity should not only be DRB genes, it was suggested that the expressed FLA-DRB genotype might associate with feline transplantation immunity, and that typing and matching of expressed FLA-DRB genes might be one of the important factors in the control of feline transplantation immunity.     

Genetic manipulation of the major histocompatibility complex

The genes of the major histocompatibility complex (MHC) are prime candidates for genetic engineering of domestic species because of their importance in many biological phenomena, including disease resistance and reproduction. One MHC-linked gene, the Ped gene in the mouse, has been shown to influence embryo development and survival. The Ped gene has mapped to the Qa-2 subregion of the mouse MHC, the H-2 complex. Future studies are aimed at determining, at the DNA and protein levels, the structure of the Ped gene and its gene product. There is preliminary evidence that there may be MHC-linked Ped-like genes that influence reproduction in other species. The search for Ped-like genes in domestic species has been hampered by the limited data available describing the molecular structure of the MHC of species other than mouse and man. This paper describes the use of restriction fragment length polymorphism analysis to study the MHC of two domestic species, the pig and the chicken. Major histocompatibility complex effects on reproduction have been reported for both the pig and the chicken. The long-range goal is to identify and isolate advantageous alleles that could then be injected into recipient embryos to create more reproductively efficient animals.     

Immunogenetics and the major histocompatibility complex.

The poultry immune system is a complex system involving many different cell types and soluble factors that must act in concert to give rise to an effective response to pathogenic challenge. The complexity of the immune system allows the opportunity for genetic regulation at many different levels. Cellular communication in the immune response, the production of soluble factors, and the rate of development of immune competency are all subject to genetic influences. The genes of the major histocompatibility complex (MHC) encode proteins which have a crucial role in the functioning of the immune system. The MHC antigens of chickens are cell surface glycoproteins of three different classes: Class I (B-F), Class II (B-L) and Class IV (B-G). The MHC antigens serve as essential elements in the regulation of cell-cell interactions. The MHC has been shown to influence immune response and resistance to autoimmune, viral, bacterial and parasitic disease in chickens. The MHC has been the primary set of genes identified with genetic control of immune response and disease resistance, but there are many lesser-characterized genes outside of the MHC that also regulate immunoresponsiveness. Polygenic control has been identified in selection experiments that have produced lines of chickens differing in antibody levels or kinetics of antibody production. These lines also differ in immunoresponsiveness and resistance to a variety of diseases. Understanding the genetic bases for differences in immunoresponsiveness allows the opportunity selectively to breed birds which are more resistant to disease. Indirect markers that can be used for this selection can include the MHC genes and immune response traits that have been associated with specific or general resistance to disease.     

Comparative genomics of the poultry major histocompatibility complex

This review summarizes the latest findings regarding the avian major histocompatibility complex (MHC), focusing particularly on the genomics of MHC in the Japanese quail (Cotrnix japonica) and other birds, as well as haplotype, genomics, function and disease resistance in the chicken (Gallus gallus). This information provides important insight into the breeding of disease resistance in poultry, natural selection of disease resistance in wild birds, and the effects of recombination and hitchhiking on the evolution of multiple MHC gene families.     

Effects of intravenous injection of Salmonella antigen on the distribution of major histocompatibility complex class II positive cells in the ovarian follicles of hens

The goal of this study was to determine whether the distribution of major histocompatibility complex class II positive (MHC class II+) cells was affected by foreign agents in the blood circulation. White Leghorn layers were injected intravenously with or without formalin fixed Salmonella paratyphi , and the area of MHC class II+ cells in the ovarian follicles, which included the largest (F1) and third largest follicles (F3), white follicles (WF) and cortical follicles, was examined by immunocytochemistry. The immunoreaction products for MHC class II were observed in cells of the thecal layer of all follicles in both treated and control birds. Salmonella paratyphi antigen caused a significant increase in the area of MHC class II+ cells in the theca of the F1, F3 and WF, but not in the cortical follicles. The results suggest that the MHC class II+ cells in the theca increase in response to circulating foreign agents, and play a significant role in ovarian local immunity.     

Early cell-mediated immune responses to Marek's disease virus in two chicken lines with defined major histocompatibility complex antigens

N2a and P2a chickens, resistant and susceptible to Marek's disease (MD), respectively, were used to examine relationships between major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) and natural killer (NK)-like cell activity with resistance to infection with Marek's disease virus (MDV). Ten-day-old chickens were infected with MDV and euthanatized at selected times to evaluate for NK cell and MHC-restricted cytotoxicity. The N2a MDV-infected chickens had an early cell-mediated immune response characterized by a sustained NK-like cytotoxicity that coincided with a measurable MHC-cytotoxicity that was lower than controls. Although MHC-restricted and NK cell cytotoxicity was demonstrated in P2a MDV-infected chickens at 8 dpi, both abruptly decreased and remained low for the remainder of the 20-day experiment. The critical time point that may determine the resistance to MD appears to be within the first 2 weeks post-infection. Improvement of the chicken NK cell activity may be a good candidate for both selection and immunomodulation MD control programs.     

3个绵羊种群MHC微卫星标记的遗传多样性

利用微卫星技术对小尾寒羊、道赛特羊、特克赛尔羊3个绵羊种群共218只绵羊的主要组织相容性复合体（MHC）ClassⅡ区DRB1、DRB2、DYMS、MB026基因座的微卫星多态性进行了研究。统计了3个种群的等位基因组成,并计算了微卫星基因座的等位基因频率、杂合度和多态信息含量。结果显示,4个基因座在3个种群中的平均等位基因数分别为14、10.33、12.67、5.33个;平均多态信息含量分别为0.8315、0.8037、0.7946、0.3992;平均杂合度分别为0.8473、0.8229、0.8165、0.4202。研究结果说明,DRB1、DRB2、DYMS基因座为高度多态基因座,MB026基因座为中度多态基因座,在这4个微卫星基因座上,小尾寒羊、道赛特羊及特克赛尔羊均具有丰富的遗传多态性,可作为有效的遗传标记用于各绵羊品种的遗传多样性和系统发生关系分析。     

Class II major histocompatibility complex expression and cell size independently predict survival in canine B-cell lymphoma

Background: Class II major histocompatibility complex (MHC) is an independent predictor of outcome in human B‐cell lymphoma. We assessed class II expression together with other markers for their impact on prognosis in canine B‐cell lymphoma. Hypothesis: Low class II MHC expression, large cell size, and expression of CD34 will predict a poorer outcome in canine B‐cell lymphoma. Expression of CD5 and CD21 on tumor cells also may be associated with outcome. Animals: One hundred and sixty dogs with cytologically confirmed lymphoma. Methods: Patient signalment, treatment type, and flow cytometry characteristics were analyzed for their influence on outcome. A multivariable predictive model of survival was generated using 2/3 of the patients and validated on the remaining 1/3 of the dataset. Results: Class II MHC expression had a negative association with mortality and relapse. Treatment type also influenced relapse and mortality, whereas cell size and patient age was only associated with mortality. CD34, CD21, and CD5 expression was not associated with disease outcome. The constructed model performed variably in predicting the validation group's outcome at the 6‐month time point. Conclusions and Clinical Importance: Low levels of class II MHC expression on B‐cell lymphoma predict a poor outcome, as in human B‐cell lymphoma. This finding has implications for the use of dogs to model human lymphomas. Class II expression, cell size, treatment, and age can be combined to predict mortality with a high level of specificity.     

Influences of major histocompatibility complex class I haplotypes on avian influenza virus disease traits in Thai indigenous chickens

Natural infections with influenza viruses have been reported in a variety of animal species including humans, pigs, horses, sea mammals, mustelids and birds. Occasionally, devastating pandemics occur in domestic chickens (broiler and layers) and in humans. From November 2003 to March 2004 in many countries in Asia, there were outbreaks of H5N1 avian influenza virus, causing death of infected patients, and devastating the poultry industry. Some groups of Thai indigenous chickens survived and were therefore classified as resistant. These traits were related to immunogenetics, in particular, the major histocompatibility complex (MHC) class I and class II molecules. The chicken MHC class I were investigated as candidate genes for avian influenza virus disease resistance. Seven hundred and thirty Thai indigenous chickens from smallholder farms in the rural area of avian influenza virus disease outbreaks in the central part of Thailand were used in the present study. They were separated into two groups, 340 surviving chickens and 390 dead chickens (resistant and susceptible). Genomic DNA were precipitated from blood samples and feathers. The DNA were used to amplify the MHC class I gene. Data were analyzed using χ² analysis to test significant differences of influences of MHC class I haplotypes on avian influenza virus disease traits. The results represented nine MHC class I haplotypes: A1, B12, B13, B15, B19, B21, B2, B6, and BA12, and included 10 of their heterozygotes. The homozygous B21 from these collected samples had a 100% survival rate and they were the major survival group. In addition, the heterozygous B21 also had a high survival rate because of co‐dominant expression of these genes. In contrast, the homozygous B13 had a 100% mortality rate and they were the major mortality group. These results confirmed that MHC class I haplotypes influence avian influenza virus disease‐resistant traits in Thai indigenous chicken. The MHC genes can be used as genetic markers to improve disease‐resistant traits in chicken.     

Chronic active hepatitis in 26 Doberman pinschers

Chronic active hepatitis with increased hepatic copper concentration was diagnosed in 25 female and 1 male Doberman Pinscher dogs. Common clinical signs included polyuria/polydipsia, weight loss, anorexia, icterus, and ascites. Increased liver enzyme activities and abnormal liver function test results were the most consistent clinicopathologic changes. The dogs were assigned to 3 groups on the basis of clinical course of the disease. Group 1 dogs (n = 12) had clinical signs of advanced liver failure and died within one week. Group 2 dogs (n = 7) had less severe clinical signs of liver disease and died within one month. Group 3 dogs (n = 5) did not have clinical signs of illness or had mild clinical signs of liver disease and died 1 to 42 months after initial evaluation. One dog could not be reevaluated and another dog was alive 3 months after initial examination. Treatments consisted of supportive care for dogs in group 1, and dietary manipulations and corticosteroids for dogs in groups 2 and 3. The association of increased liver copper concentration and chronic active hepatitis is not known.     

The evolution and maintenance of polymorphism in the major histocompatibility complex

Lambs with the G2 allele at the ovine major histocompatibility complex (mhc) class II locus DRB1 has previously been shown to have lower faecal nematode egg counts than lambs with the I allele at this locus. This association has been confirmed in separate cohorts from the same farm. Other alleles within the mhc have also shown associations with nematode resistance in other breeds of sheep. Therefore, variation in the mhc is responsible for part of the observed genetic variation in resistance to nematode infection. In addition to the specific effect of particular alleles, heterozygotes are also more resistant than homozygotes. This heterozygote advantage is capable of maintaining the high levels of polymorphism observed within the mhc.     

Structure and function of the major histocompatibility complex in domestic animals

The major histocompatibility complex (MHC) is a genetic region that has been intensively studied for the past 2 decades. Interest in the MHC has been high because of (i) the particular involvement of the MHC in transplantation reactions, including organ allograft rejection in human beings; and (ii) the more general role of MHC gene products in the genetic control of immune responses in all mammals. The MHC has several remarkable properties that include a distinctive genetic structure which has been well-preserved through evolution, and the extreme plasticity of form of the principal MHC genes, which can coexist within a single species in 30 or more allelic forms. The genes of the MHC regulate cell-cell interactions of various types within the lymphoreticular system, and thus function as the so-called "immune response" genes that have been described in mice, rats, and guinea pigs. In human beings, the "disease associations" demonstrated between MHC alleles and various pathologic conditions are probably manifestations of abnormal functions of immune regulation governed by the MHC. Studies of the MHC in domestic species are still in their infancy. However, investigations of the MHC have been carried out in swine, cattle, horses, sheep, goats, dogs, and chickens. Further research on the MHC of domestic animals is merited, both for its contribution to the overall understanding of the biological significance of the MHC and for its practical application in clinical veterinary medicine.     

Gene organization and polymorphism of the swine major histocompatibility complex

The recent availability of the full‐length sequence of one haplotype of the swine leukocyte antigen (SLA) complex, the swine major histocompatibility complex (MHC), and significant progress in the studies on gene expression and polymorphisms led to major advances in deciphering its role in resistance to diseases in animals. The present status of the genomic organization and polymorphism of the SLA complex is presented in this Review. Additionally, a comparative analysis with mammalian MHC has also been provided. The sequenced SLA‐H01 haplotype harbors 152 loci including genuine SLA genes, non‐MHC genes and pseudogenes. Although the numbers of expressed SLA genes could vary across haplotypes, three SLA class Ia, three SLA class Ib, four SLA class IIa and four SLA class IIb genes are currently expressed. Except for the class I genes, which have no clear orthologs, the gene organization of the loci was highly conserved between humans and pigs. Moreover, the human leukocyte antigen (HLA) complex lies on a single chromosomal segment, whereas a centromere at the class II and III junction splits the SLA complex into two segments, without disturbing gene organization or impeding functionality. Over 400 SLA class I and II allele sequences available in databases have been recently clustered and assigned to a specific SLA locus according to a newly defined nomenclature system.