兔膈肌肌纤维亚型和代谢酶活性对不同频率CES的适应性变化

目的:探讨不同频率慢性电刺激对膈肌肌纤维亚型、肌球蛋白重链(MHC)亚型和代谢酶活性的适应性变化的影响.方法:分别用还原型辅酶Ⅰ四唑氮还原法、SDS-PAGE法和酶组织化学染色法观察、测定慢性电刺激后兔膈肌纤维类型、肌球蛋白重链(MHC)和NADHD等九种代谢酶活性变化.结果:①同对照组和慢性高频电刺激50Hz和100 Hz组比较,10 Hz和20 Hz慢性低频电刺激组膈肌Ⅰ型纤维,Ⅰ型MHC显著增加(P＜0.01);ⅡB型纤维和ⅡB型MHC显著减少(P＜0.01);慢性高频电刺激50Hz和100 Hz组则出现完全相反的变化(P＜0.01).②同对照组和慢性高频电刺激50 Hz和100 Hz组比较,慢性低频电刺激10 Hz和20 Hz组LDH和a-GPDHD活性明显降低(P＜0.01),MDH、SDH、GDH、G-6-PD、NADHD和NADPHD活性显著升高(P＜0.01);慢性高频电刺激50Hz和100 Hz组则出现完全相反的变化(P＜0.01).结论:肌纤维与代谢酶模式的适应性变化有明显的频率依赖性.     

白鲢MHC Iα2基因克隆及序列分析

根据人和动物的MHCIα2基因中两个半脱氨酸侧翼的保守序列设计了混合型引物,采用PCR法从白鲢基因组DNA中克隆了MHCIα2（Hymo－BX1）。经氨基酸序列和同源性分析,Hymo－BX1与人和动物的MHCIα2存在26．7％～50．6％同源性,并存在抗原多肽结合位点（T－143、K－146、W－147、Y－159）以及α2微球蛋白结合位点（Q－115、D－119、G－120、D-122）。由此认为：Hymo－BX1属MHCclassIa类可作为白鲢种群分子进化指标之一。     

Intragraft gene expression profile associated with the induction of tolerance by allochimeric MHC I in the rat heart transplantation model

The MHC class I allochimeric protein containing donor‐type epitopes on recipient‐type heavy chains induces indefinite survival of heterotopic cardiac allografts in rats. We analyzed gene expression profile of heart allograft tissue. Mutated peptide [α1h1/u]‐RT1.Aa that contains donor‐type (Wistar Furth, WF; RT1u) immunogenic epitopes displayed on recipient‐type (ACI, RT1a) was delivered into ACI recipients of WF hearts at the time of transplantation in addition to a 3 days course of oral cyclosporine. Microarray analysis was performed using Affymetrix Rat 230 2.0 Microarray. Allochimeric molecule treatment caused upregulation of genes involved in structural integrity of heart muscle, downregulation of IL‐1β a key modulator of the immune response, and downregulation of partitioning defective six homolog gamma PAR6, which is involved in T cell polarity, motility, and ability to scan dendritic cells (DC). These indicate that the immunosuppressive function of allochimeric molecule and/or the establishment of allograft tolerance depend on the induction of genes responsible for the heart tissue integrity, the suppression of cytokine pathway(s), and possibly the impairment of T cells mobility and their DC scanning ability. These novel findings may have important clinical implications for inhibition of chronic rejection in transplant recipients. genesis 48:8–19, 2010. © 2009 Wiley‐Liss, Inc.     

ISAG/IUIS-VIC Comparative MHC Nomenclature Committee report, 2005

Nomenclature for Major Histocompatibility Complex (MHC) genes and alleles in species other than humans and mice has historically been overseen either informally by groups generating sequences, or by formal nomenclature committees set up by the International Society for Animal Genetics (ISAG). The suggestion for a Comparative MHC Nomenclature Committee was made at the ISAG meeting held in Göttingen, Germany (2002), and the committee met for the first time at the Institute for Animal Health, Compton, UK in January 2003. To publicize its activity and extend its scope, the committee organized a workshop at the International Veterinary Immunology Symposium (IVIS) in Quebec (2004) where it was decided to affiliate with the Veterinary Immunology Committee (VIC) of the International Union of Immunological Societies (IUIS). The goals of the committee are to establish a common framework and guidelines for MHC nomenclature in any species; to demonstrate this in the form of a database that will ensure that in the future, researchers can easily access a source of validated MHC sequences for any species; to facilitate discussion on this area between existing groups and nomenclature committees. A further meeting of the committee was held in September 2005 in Glasgow, UK. This was attended by most of the existing committee members with some additional invited participants (Table 1). The aims of this meeting were to facilitate the inclusion of new species onto the database, to discuss extension, improvement and funding of the database, and to address a number of nomenclature issues raised at the previous workshop.     

黑麂MHC - DQA2 基因多态性

利用牛特异性扩增DQA2 第2 外显子的嵌套引物,对黑麂基因组DNA 进行PCR 扩增和克隆测序,基于该
序列设计出黑麂DQA2 基因第2 外显子特异性引物。利用该引物,通过PCR - SSCP 以及克隆测序技术,从40 个
黑麂样品中获得4 个不同的DQA2 等位基因。没有一个个体同时具有2 个以上的等位基因,所有序列均不含插入
或缺失突变,不含终止密码子,因此,本研究所扩增的DQA2 基因可能是表达的单基因座位。抗原结合区(Peptide
binding region,PBR)非同义替换率(dn)显著大于同义替换率(ds) (P <0.05),暗示该座位曾经历过明
显的正选择作用;进一步利用CODEML 程序中的相关模型以及贝叶斯法检测出4 个受选择作用的氨基酸位点
(α11、α58、α62、α66),这4 个位点均位于PBR 区。基于NJ 法构建的部分偶蹄类DQA 外显子2 系统发生关系
显示,黑麂4 个DQA2 等位基因与牛、羊以及梅花鹿的DQA2 等位基因构成独立的进化枝,在该进化枝内,黑麂
DQA2 等位基因优先与牛DQA2 等位基因聚类,暗示黑麂DQA2 基因在进化过程中存在跨物种进化现象。上述结
果表明平衡选择是维持黑麂DQA2 基因多态性的主要机制。然而,本研究从40 个样品中仅检测出2 个杂合子,
黑麂DQA2 等位基因之间的频率存在显著差异,推测可能是所检测的样品来源于不同种群,由于华伦德效应
(The Whalund effect)导致杂合度降低,也不排除本文所设计的引物在PCR 扩增过程中存在无效等位基因。     

A theoretical analysis of HLA-DRbeta1*0301-CLIP complex using the first three multipolar moments of the electrostatic field

Interactions between the HLA-DRbeta1*0301 molecule and several occupying peptides obtained from computational substitutions made to the CLIP peptide are studied. The exploration was carried out using a vector composed of the first three terms of the multipolar expansion of the electrostatic field, namely, charge (q), dipole (d) and quadrupole (C). Comparisons between pocket-peptide interactions established that the binding pockets for this HLA molecule are ordered in terms of their importance for binding peptides, as follows: P1 > P4 > P6 > P7 > P9. A set of electrostatically distinct amino acids that determine interaction stability and specificity were identified for each pocket. The beta74R residue was especially identified as being the key amino acid mediating the occupying peptide binding for pocket 4; this residue has been recently associated with Graves' disease.     

Allele effects in MHC-peptide interactions: a theoretical analysis of HLA-DRbeta1*0101-HA and HLA-DRbeta1*0401-HA complexes

HLA-DRbeta1*0101-HA and HLA-DRbeta1*0401-HA complexes are studied and compared by means of their computationally derived multipolar moments and electrostatic potentials. Changes in electrostatic potential are associated with definite pocket interaction profiles. Thus, Pocket 1 projects itself as an anchoring pocket for both complexes, in accordance with experimental results. While Pocket 4 has an anchoring profile in the HLA-DRbeta1*0101 allele, it presents itself as modulating pocket-peptide interactions in HLA-DRbeta1*0401. Pockets 6 and 7 both strongly contribute to allele specificity, with Pocket 7 being very important for HLA-DRbeta1*0401-HA. Pocket 9 acts as a "double purpose" interaction site for both alleles. It both projects itself as an anchoring pocket as well as modulating pocket-peptide interactions.     

Contrasting patterns of variation in MHC loci in the Alpine newt

Major histocompatibility complex (MHC) genes are essential in pathogen recognition and triggering an adaptive immune response. Although they are the most polymorphic genes in vertebrates, very little information on MHC variation and patterns of evolution are available for amphibians, a group known to be declining rapidly worldwide. As infectious diseases are invoked in the declines, information on MHC variation should contribute to devising appropriate conservation strategies. In this study, we examined MHC variation in 149 Alpine newts ( Mesotriton alpestris ) from three allopatric population groups in Poland at the northeastern margin of the distribution of this species. The genetic distinctiveness of the population groups has previously been shown by studies of skin graft rejection, allozymes and microsatellites. Two putative expressed MHC II loci with contrasting levels of variation and clear evidence of gene conversion/recombination between them were detected. The Meal-DAB locus is highly polymorphic (37 alleles), and shows evidence of historical positive selection for amino acid replacements and substantial geographical differentiation in allelic richness. On the contrary, the Meal-DBB locus exhibits low polymorphism (three alleles differing by up to two synonymous substitutions) and a uniform distribution of three alleles among geographical regions. The uniform frequencies of the presumptively neutral Meal-DBB alleles may be explained by linkage to Meal-DAB . We found differences in allelic richness in Meal-DAB between regions, consistent with the hypothesis that genetic drift prevails with increasing distance from glacial refugia. Pseudogene loci appear to have evolved neutrally. The level of DAB variation correlated with variation in microsatellite loci, implying that selection and drift interplayed to produce the pattern of MHC variation observed in marginal populations of the Alpine newt.     

HLA-DP2 binding prediction by molecular dynamics simulations

Major histocompatibility complex (MHC) II proteins bind peptide fragments derived from pathogen antigens and present them at the cell surface for recognition by T cells. MHC proteins are divided into Class I and Class II. Human MHC Class II alleles are grouped into three loci: HLA-DP, HLA-DQ, and HLA-DR. They are involved in many autoimmune diseases. In contrast to HLA-DR and HLA-DQ proteins, the X-ray structure of the HLA-DP2 protein has been solved quite recently. In this study, we have used structure-based molecular dynamics simulation to derive a tool for rapid and accurate virtual screening for the prediction of HLA-DP2-peptide binding. A combinatorial library of 247 peptides was built using the "single amino acid substitution" approach and docked into the HLA-DP2 binding site. The complexes were simulated for 1 ns and the short range interaction energies (Lennard-Jones and Coulumb) were used as binding scores after normalization. The normalized values were collected into quantitative matrices (QMs) and their predictive abilities were validated on a large external test set. The validation shows that the best performing QM consisted of Lennard-Jones energies normalized over all positions for anchor residues only plus cross terms between anchor-residues.     

Comparative analysis of epitope predictions: proposed library of putative vaccine candidates for HIV

Designing a vaccine for a disease is one of the crucial tasks that involve millions and billions of dollars, several decades and yet there is no guarantee of successful results. Several pharmaceutical companies are investing their money and time in such activities. Computational biology could be of great help in these activities by proving a library of plausible candidates that might actually show some positive responses. MHC binding peptide prediction is one such area where the immense power of computers could be used to get a breakthrough. In this direction several databases and servers have been developed by many labs to predict the MHC binding peptides. These short peptides on the antigen surface are recognized by the MHC molecule and are presented to the receptors of T-cells for further immune response. Peptides that bind to a given MHC molecule share sequence similarity. Here we present a comparative study of servers that can predict the MHC binding peptides in a given protein sequence of the antigen. Based on this comparative analysis on HIV data, we are able to propose a library of putative vaccine candidates for the env GP-160 protein of HIV-1.     

Heterozygote advantage fails to explain the high degree of polymorphism of the MHC

Major histocompatibility (MHC) molecules are encoded by extremely polymorphic genes and play a crucial role in vertebrate immunity. Natural selection favors MHC heterozygous hosts because individuals heterozygous at the MHC can present a larger diversity of peptides from infectious pathogens than homozygous individuals. Whether or not heterozygote advantage is sufficient to account for a high degree of polymorphism is controversial, however. Using mathematical models we studied the degree of MHC polymorphism arising when heterozygote advantage is the only selection pressure. We argue that existing models are misleading in that the fitness of heterozygotes is not related to the MHC alleles they harbor. To correct for this, we have developed novel models in which the genotypic fitness of a host directly reflects the fitness contributions of its MHC alleles. The mathematical analysis suggests that a high degree of polymorphism can only be accounted for if the different MHC alleles confer unrealistically similar fitnesses. This conclusion was confirmed by stochastic simulations, including mutation, genetic drift, and a finite population size. Heterozygote advantage on its own is insufficient to explain the high population diversity of the MHC.Electronic Supplementary Material Supplementary material is available in the online version of this article at     

At least two loci encode polymorphic class I MHC antigens in the horse

Summary. Six monoclonal antibodies and ten alloantisera were used to precipitate cell surface molecules of approximately 44kDa (class I MHC antigens) from radiolabelled equine peripheral blood lymphocytes. All ten antisera were raised against antigens of a single donor horse (horse 0834, ELA-A2,-A2). Four methods of producing antisera were compared: one or two pregnancies, skin allografting, and skin grafting followed by pregnancy. Immunization by pregnancy appeared to produce antibodies against class I products only, while skin grafting raised antibodies to class II antigens as well. Nine of the antisera were raised across an entire MHC haplotype barrier, while one recipient carried the ELA-A2 antigen of the donor. The pregnancy antiserum raised across this barrier probably identifies a second polymorphic class I locus in the horse. Sequential immunoprecipitation using this antiserum in the first stage and an anti-MHC haplotype antiserum or monoclonal antibody reagent in the second stage supported this hypothesis. Gene products of this second ELA class I locus are immunogenic in pregnancy.     

家禽MHC结构研究进展

禽主要组织相容性复合体(Major histocompatibility complex,MHC)的结构与禽病防控、禽免疫学、禽类遗传学研究密切相关。文章对鸡、火鸡、鹌鹑、鸭和鹅的MHC结构方面的研究进展进行了综述,表明其有以下共同特点:都有保守的MHC区域,包括MHC I基因和MHC II基因及一些功能未知基因;基因排列简单而紧凑;MHC I基因内含子的长度都比哺乳动物小;鸡、火鸡、鸭和鹅的MHC I基因组序列都有8个外显子和7个内含子,MHC IIβ基因组序列都有6个外显子和5个内含子;鸡、火鸡和鹌鹑的BG基因结构模式相同;都存在微卫星重复单元。但也存在种属差异:鸡的MHC I基因和MHC II基因是双拷贝,而鸭、鹅和鹌鹑有若干个拷贝;BG基因的拷贝数及其外显子数目不同。对主要家禽MHC结构进行分析比较,将有利于对禽病学及禽免疫遗传学的进究。     

Serological and genetic study of the ELA W21 specificity

Investigations on the W21 specificity showed that this antigen is expressed on lymphocytes and platelets but not on erythrocytes. The molecule carrying the antigen W21 moves in the cell membrane independently from ELA locus A and B encoded antigens, as observed in 'lysostripping'. The W21 specificity occurs with very different gene frequencies in various breeds. In informative families it segregates together with defined gene products of the MHC region. The data suggest strongly that the W21 specificity belongs to the ELA system as a class I gene product, but is governed by a separate locus than the known locus A and locus B allelic series.     

Identification of the major histocompatibility complex in the ring-necked pheasant, Phasianus colchicus

Reciprocal immunization between parents of an Illinois family of ring-necked pheasants, Phasianus colchicus, resulted in antisera detecting two pairs of alloantigens segregating among 13 progeny. The four alloantigens were tentatively designated as 1 and 2, transmitted antithetically by the sire, and 3 and 4, transmitted antithetically by the dam. Genetic segregation occurring in second-generation progeny demonstrated that these two pairs of antigens belonged to a single genetic system. This alloantigen system was shown to correspond serologically to the major histocompatibility complex (MHC) of the chicken by cross-reactivity of the antigens of this system with specific subregional chicken MHC reagents, appropriately absorbed with erythrocytes of individual pheasants. These four haplotypes of the pheasant MHC were subsequently designated as MhcPhco-B1, MhcPhco-B2, MhcPhco-B3 and MhcPhco-B4. Traditional immunogenetic analysis of 30 pheasant families produced in this study disclosed a minimum of 14 pheasant haplotypes of this alloantigen system (MHC) to be segregating in the population under evaluation.     

DNA sequence analysis of serologically detected ELA class II haplotypes at the equine DQP locus

The genetic diversity at the ELA DQβ locus was investigated using polymerase chain reaction and DNA sequencing. Based upon serological methods 16 class II homozygous animals were selected and their genomic DNA was used. A DQβ gene from an equine cDNA library was also sequenced. Our methology and the similarity between the genomic and the cDNA sequences suggest that the studied locus is expressed on equine lymphocytes. In the predicted amino acid sequence the most extensive variation is located at residues 56–60. The pattern of these five amino acids is strongly correlated to the serological ELA class II specificities (W13, W22, W23, Be200). The alleles corresponding to the W23 specificity are the most divergent among the equine DQβ alleles and also from other mammalian DQβ sequences.     

主要组织相容性复合体(MHC)基因的研究概况

主要组织相容性复合体(MHC)因其在免疫方面的重要作用而倍受免疫学家重视．随着研究的不断深入,了解到MHC是一个高度多态的基因群,它广泛分布于各种脊椎动物体内．MHC除了具有免疫功能外,还在其它许多方面起作用．MHC基因的多态性是最受关注的特征,尤其是Ⅱ类基因．根据MHC基因的多态性,可以在遗传、进化、行为、保护及生态等许多方面对其进行研究．就目前的研究情况,在结构、功能及应用等方面对MHC作了介绍．     

Diversification of porcine MHC class II genes: evidence for selective advantage

The major histocompatibility complex (MHC) is an immunological gene-dense region of high diversity in mammalian species. Sus scrofa was domesticated by at least six independent events over Eurasia during the Holocene period. It has been hypothesized that the level and distribution of MHC variation in pig populations reflect genetic selection and environmental influences. In an effort to define the complexity of MHC polymorphisms and the role of selection in the generation of class II gene diversity (DQB, DRB1, and pseudogene ΨDRB3), DNA from globally distributed unrelated domestic pigs of European and Asian origins and a Suidae out-group was analyzed. The number of pseudogene alleles identified (ΨDRB3 33) was greater than those found in the expressed genes (DQB 20 and DRB1 23) but the level of observed heterozygosity (ΨDRB3 0.452, DQB 0.732, and DRB1 0.767) and sequence diversity (ΨDRB3 0.029, DQB 0.062, and DRB1 0.074) were significantly lower in the pseudogene, respectively. The substitution ratios reflected an excess of d _N (DQB 1.476, DRB1 1.724, and ΨDRB3 0.508) and the persistence of expressed gene alleles suggesting the influence of balancing selection, while the pseudogene was undergoing purifying selection. The lack of a clear MHC phylogeographic tree, coupled with close genetic distances observed between the European and Asian populations (DQB 0.047 and DRB1 0.063) suggested that unlike observations using mtDNA, the MHC diversity lacks phylogeographic structure and appears to be globally uniform. Taken together, these results suggest that, despite regional differences in selective breeding and environments, no skewing of MHC diversity has occurred. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

MHC polymorphism under host-pathogen coevolution

The genes encoding major histocompatibility (MHC) molecules are among the most polymorphic genes known for vertebrates. Since MHC molecules play an important role in the induction of immune responses, the evolution of MHC polymorphism is often explained in terms of increased protection of hosts against pathogens. Two selective pressures that are thought to be involved are (1) selection favoring MHC heterozygous hosts, and (2) selection for rare MHC alleles by host-pathogen coevolution. We have developed a computer simulation of coevolving hosts and pathogens to study the relative impact of these two mechanisms on the evolution of MHC polymorphism. We found that heterozygote advantage per se is insufficient to explain the high degree of polymorphism at the MHC, even in very large host populations. Host-pathogen coevolution, on the other hand, can easily account for realistic polymorphisms of more than 50 alleles per MHC locus. Since evolving pathogens mainly evade presentation by the most common MHC alleles in the host population, they provide a selective pressure for a large variety of rare MHC alleles. Provided that the host population is sufficiently large, a large set of MHC alleles can persist over many host generations under host-pathogen coevolution, despite the fact that allele frequencies continuously change.Electronic Supplementary Material Supplementary material is available in the online version of this article at     

Restriction fragment length polymorphism analysis of the chicken B-F and B-L genes and their association with serologically defined B haplotypes

Seven serologically defined chicken haplotypes have been analysed by restriction fragment length polymorphism (RFLP) with chicken cDNA probes specific for MHC class I and II. The results demonstrate an excellent correlation between the observed RFLP banding patterns in the investigated haplotypes and the serological B-typing. In future, RFLP analysis in addition to serological B-typing may sharpen the tools in the search for recombinant chromosomes separating B-F and B-L.