MHC及其在种群遗传学和保护遗传学中的应用

主要组织相容性复合体（major histocompatibility complex,MHC）是脊椎动物体内与免疫应答调节密切相关的一个基因家族,是基因组中多态性最丰富的区域。通过MHC的遗传变异分析可以提供物种的遗传多样性水平、进化历史和种群动态,以及种群遗传结构等信息,并在濒危物种饲养繁殖种群的遗传管理中有重要应用。 MHC and Its Application in the Population and Conservation Genetics YANG Guang,CHEN Xu-yan,REN Wen-hua,YAN Jie Institute of Genetic Resources,Nanjing Normal University,Nanjing 210097,China Abstract:The major histocompatibility complex (MHC),with the highest genetic polymorphism,is a cluster of genes involved in immune response regulation in the vertebrates.MHC can provide information such as population genetic diversity,evolutionary history and population dynamics,and population genetic structure etc.It can also be applied in the captive breeding programme for endangered vertebrate species. Key words：major histocompatibility complex (MHC);genetic diversity,population viability;population genetic structure;captive breeding     

驼鹿的圣地

汗马蕴育着我国独特的寒温带森林湿地动物群.在众多的物种中,以大型有蹄类动物为代表的物种多样性、丰富度和独特性令人惊叹! 有蹄类是动物界的重要组成部分,亦是现存最大群的大型陆生动物,是自然界食物网的主要环节;同时,作为动物界的一部分,有蹄类对生态系统有着重要的影响.有蹄类动物中,驼鹿是鹿科动物中的体型最大者.尽管驼鹿广泛分布于欧洲和北美,但我国驼鹿种群是亚洲最南部的种群.它是国家Ⅱ级保护野生动物,别名:犴、堪达犴.驼鹿这个鹿科动物中的巨人,也是对环境变化非常敏感的物种之一.     

植物边缘种群遗传多样性研究进展

边缘种群指地理分布边缘可检测到的一定数量的同种个体集合, 准确评价其遗传多样性对于理解第四纪冰期后气候变化对物种边缘扩展或收缩、遗传资源保护与利用以及物种形成等有重要意义。该文探讨了维持植物边缘种群遗传多样性的进化机制, 分析交配系统对物种边缘及其遗传多样性的影响, 比较了边缘与中心种群遗传多样性的差异及其形成的生态与进化过程, 并探讨了边缘种群遗传多样性与其所在的群落物种多样性的关系及理论基础。该文提出今后研究的重点是应用全基因组序列或转录组基因序列研究前缘-后缘种群之间或边缘-中心种群之间的适应性差异, 边缘种群与所在群落其他物种之间相互作用的分子机制, 深入解析边缘种群对环境的适应及边缘种群遗传多样性与群落物种多样性关系的生态与进化过程。     

植物边缘种群遗传多样性研究进展

边缘种群指地理分布边缘可检测到的一定数量的同种个体集合,准确评价其遗传多样性对于理解第四纪冰期后气候变化对物种边缘扩展或收缩、遗传资源保护与利用以及物种形成等有重要意义。该文探讨了维持植物边缘种群遗传多样性的进化机制,分析交配系统对物种边缘及其遗传多样性的影响,比较了边缘与中心种群遗传多样性的差异及其形成的生态与进化过程,并探讨了边缘种群遗传多样性与其所在的群落物种多样性的关系及理论基础。该文提出今后研究的重点是应用全基因组序列或转录组基因序列研究前缘-后缘种群之间或边缘-中心种群之间的适应性差异,边缘种群与所在群落其他物种之间相互作用的分子机制,深入解析边缘种群对环境的适应及边缘种群遗传多样性与群落物种多样性关系的生态与进化过程。     

大鸨的现状和研究动态

大鸨(Otistarda)是栖息于广阔草原的重要濒危鸟类,属国家Ⅰ级保护动物。本文根据近年国内外对该物种的研究结果,对其亚种分布、种群数量、生态生物学、种群遗传结构及组织形态学观察等方面作了综述。通过对其生存现状、受胁原因、研究动态的论述,为该物种的保护和管理提供科学的依据。     

鹿科动物线粒体控制区序列分析与系统进化

通过测定鹿科麂亚科中的小麂、赤麂和黑麂的线粒体全基因组,从而定位它们的控制区,并从GenBank获得鹿科另外3个亚科9种动物的线粒体控制区全序列。利用MEGA软件计算了各物种控制区序列的碱基组成、遗传距离和遗传相似度,通过比较序列同源性,以羊线粒体控制区序列为外群,构建NJ分子系统树,探讨了鹿科4个亚科12种动物的系统进化关系。序列分析表明,鹿科12种动物控制区序列的碱基长度在909～1049bp之间,A T含量约占62．06％,其中363个核苷酸位点存在变异(约占34％)。系统进化关系结果表明：(1)以线粒体控制区构建的鹿科12种动物分子系统树基本与NCBI分类一致;(2)美洲鹿亚科驼鹿属驼鹿在鹿科这12种动物中处于最为原始的地位;(3)小麂比赤麂和黑麂更为原始;(4)獐亚科獐属的獐与美洲鹿亚科狍鹿属的狍鹿和美洲狍鹿聚为一支。     

线粒体DNA多态性在海洋动物群体遗传结构研究中的应用

线粒体DNA( mtDNA)分析在揭示物种亲缘关系、遗传比较、系统进化和遗传结构等领域的研究中得到了广泛的应用,尤其是在海洋动物的遗传结构研究中发挥了重要的作用.介绍线粒体DNA的结构特征、多态性研究方法,并对其在海洋动物群体遗传结构研究中的应用进行了综述.     

基于COXI基因的太平洋西岸文昌鱼地理种群分析

文昌鱼是进化发育研究的重要模式动物,目前实验材料均采自野外.因此,对其进行正确的物种鉴定和地理种群的遗传分化分析十分必要.该研究扩增并测定了COX 1基因部分序列,结合NCBI数据库中的COX 1序列信息,对太平洋西岸文昌鱼的种类和地理种群分化情况进行了分析.结果表明,马来文昌鱼(Branchiostoma malayanum)、白氏文昌鱼(B.belcheri)和日本文昌鱼(B.japonicum)这3个种之间的遗传差异很大,再次证实3个物种的有效性,同时提出应当审慎对待NCBI数据库中文昌鱼的种名标注;太平洋西岸文昌鱼属Branchiostoma的3种文昌鱼群体遗传多样性均处于较高水平,同一物种的不同地理种群间没有出现明显的遗传分化,反映了海洋动物的基因交流较容易,不同海域隔离较弱.     

三江源和祁连山国家公园雪豹种群的遗传结构分析

掌握遗传信息对濒危物种的保护和管理具有重要意义。本研究在我国雪豹重要分布区祁连山和三江源国家公园分别采集粪便样品,利用mtDNA的cyt b基因、微卫星多态性位点进行了雪豹的物种鉴定、个体识别和种群遗传结构评估。在采集286份疑似雪豹粪便样品中,成功的对86份雪豹样品进行了扩增鉴定,利用微卫星位点进行个体识别获得41只雪豹个体,其中祁连山国家公园26只,三江源国家公园15只。通过等位基因数、有效等位基因数、观测杂合度、期望杂合度、多态信息含量等指标进行种群遗传多样性评估,认为雪豹种群遗传多样性相对较低,但祁连山国家公园雪豹种群遗传多样性相对较高。STRUCTURE进行群体遗传结构分析表明,4个种群可以划分为3个遗传类群,祁连山国家公园的种群（YCW和QLS）与三江源国家种群(DC和SJ)的遗传差异,可能与种群间的地理隔离存在明显的相似性。     

微卫星标记在种群生物学研究中的应用

微卫星是以几个碱基 (一般为 1～ 6个 )为重复单位组成的简单的串联重复序列 ,具有丰度高、多态性高、共显性标记、选择中性、可自动检测等优点。本文着重介绍了微卫星在种群生物学研究中的应用。微卫星位点可以提供具高分辨率的遗传信息 ,这一特点使微卫星既适合于个体水平上的研究 ,又适合于种群水平上的研究。在个体水平上包括个体识别、交配系统和亲本分析、基因流等研究。微卫星是常用的个体识别手段 ,但在克隆植物遗传结构研究方面的应用还很有限 ;微卫星提高了交配系统和亲本分析、基因流等研究的准确性。在种群水平上微卫星可用于遗传结构、有效种群大小、种群的系统发育重建等研究。微卫星在很多物种 (包括珍稀物种 )的遗传结构研究中得到应用 ;利用微卫星标记确定有效种群大小、检测有效种群大小的波动可以促使我们正确理解种群遗传结构动态和种群进化过程 ;微卫星在种群的系统发育重建研究方面有很大的应用潜力。然而微卫星并不是研究所有问题的唯一选择。文中还讨论了在实际工作中应如何正确利用分子标记等问题     

Genes of the major histocompatibility complex and the evolutionary genetics of lifespan

Mice that presumably differ just in the major histocompatibility complex (MHC) chromosomal region provide the best evidence that MHC genes affect lifespan. Further evidence is that MHC region genes in some cases are known to influence reproduction, growth, and development. Moreover, MHC genetic associations with disease are well documented. This paper summarizes and defines aspects of the molecular biology, cellular function, and evolution of MHC genes (with special emphasis on the polymorphic MHC class I and II genes) which are important in aging, and attempts to integrate these into an evolutionary genetic perspective of senescence. It is suggested that MHC genes provide a mammalian paradigm for the genetics of lifespan because of their intra- and interspecies diversification, evolutionary selection, and age-specific effects.     

Diversity and evolutionary patterns of immune genes in free-ranging Namibian leopards (Panthera pardus pardus)

The genes of the major histocompatibility complex (MHC) are a key component of the mammalian immune system and have become important molecular markers for fitness-related genetic variation in wildlife populations. Currently, no information about the MHC sequence variation and constitution in African leopards exists. In this study, we isolated and characterized genetic variation at the adaptively most important region of MHC class I and MHC class II-DRB genes in 25 free-ranging African leopards from Namibia and investigated the mechanisms that generate and maintain MHC polymorphism in the species. Using single-stranded conformation polymorphism analysis and direct sequencing, we detected 6 MHC class I and 6 MHC class II-DRB sequences, which likely correspond to at least 3 MHC class I and 3 MHC class II-DRB loci. Amino acid sequence variation in both MHC classes was higher or similar in comparison to other reported felids. We found signatures of positive selection shaping the diversity of MHC class I and MHC class II-DRB loci during the evolutionary history of the species. A comparison of MHC class I and MHC class II-DRB sequences of the leopard to those of other felids revealed a trans-species mode of evolution. In addition, the evolutionary relationships of MHC class II-DRB sequences between African and Asian leopard subspecies are discussed.     

Coevolutionary relationship between helminth diversity and MHC class II polymorphism in rodents

Parasite-mediated selection on major histocompatibility complex (MHC) genes has mainly been explored at the intraspecific level, although many molecular studies have revealed trans-species polymorphism. Interspecific patterns of MHC diversity might reveal factors responsible for the long-term evolution of MHC polymorphism. We hypothesize that host taxa harbouring high parasite diversity should exhibit high levels of MHC genetic diversity. We test this assumption using data on rodent species and their helminth parasites compiled from the literature. Controlling for similarity due to common descent, we present evidence indicating that high helminth species richness in rodent species is associated with increased MHC class II polymorphism. Our results are consistent with the idea that parasites sharing a long-term coevolutionary history with their hosts are the agents of selection explaining MHC polymorphism.     

Isolation and characterization of 10 MHC Class I-associated microsatellite loci in tammar wallaby (Macropus eugenii)

The major histocompatibility complex (MHC) contain genes which play a key role in immune response and mate choice, and are therefore of functional importance to molecular ecologists. Here we describe the design of 10 MHC Class I-associated microsatellite loci from the tammar wallaby. All 10 loci are highly polymorphic, with the expected heterozygosity ranging from 0.547 to 0.919. Six loci successfully cross-amplify in other macropodid species. These microsatellites will serve as useful tools for studying the level of MHC diversity, the impact of selection on genetic variation and the unique structure of the tammar wallaby MHC.     

Exchanges of short polymorphic DNA segments predating speciation in feline major histocompatibility complex class I genes

Sequence comparisons of 14 distinct MHC class I cDNA clones isolated from species representing the three major taxonomic lineages of Felidae (domestic cat lineage, ocelot lineage, and pantherine lineage) revealed that feline MHC class I alleles have highly mosaic structures with short polymorphic sequence motifs that are rearranged between alleles of individual MHC loci, between MHC class I genes within cat species, and between homologous MHC loci in different species. The pattern of sequence variation in felids supports the role of the following factors in production and maintenance of MHC variation: (1) gradual spontaneous mutation; (2) selective pressure to conserve certain residues but also to vary in hypervariable regions, notably residues that functionally participate in antigen recognition and presentation; and (3) recombination-mediated gene exchange between alleles and between related genes. The overall amount of genetic variation observed among MHC class I genes in the Felidae family is no greater than the amount of variation within any outbred cat species (i.e., domestic cat, ocelot). The occurrence of equivalent levels of polymorphism plus the simultaneous persistence of the same sequence motifs in divergent feline species suggest that most MHC class I nucleotide site polymorphism predated species divergences. Ancient polymorphisms have been transmitted through the speciation events and modern feline MHC class I alleles were derived by recombinational exchange of polymorphic sequence motifs. Moreover, some of these sequence motifs were found in other mammalian MHC class I genes, such as classical human HLA-B5, nonclassical human HLA-E class I genes, and bovine class I genes. These results raise the prospect of an ancient origin for some motifs, although the possibility of convergence in parallel mammalian radiations cannot be excluded. Correspondence to: N. Yuhki     

Molecular Characterization of the Major Histocompatibility Complex Class Ia Gene in the Black-Spotted Frog, Pelophylax nigromaculata

The genes of the major histocompatibility complex (MHC) are attractive candidates for investigating the link between adaptive variation and individual fitness. We improved rapid amplification of cDNA ends to obtain the whole coding sequence of the MHC class Ia gene of the black-spotted frog (Pelophylax nigromaculata), the most common amphibian in China. We also used genome walking to characterize the partial introns adjacent to exon 3 of the MHC Ia gene. Based on the sequences obtained, we designed locus-specific primers to investigate the molecular polymorphisms of this species in southeast China. The MHC class Ia gene showed a high level of genetic diversity, indicating that this species retains a relatively high potential for survival, despite a population decline among frog species in general and many other amphibians.     

Two patterns of variation among MHC class I loci in Tuatara (Sphenodon punctatus)

The genes of the major histocompatibility complex (MHC) are a central component of the immune system in vertebrates and have become important markers of functional, fitness-related genetic variation. We have investigated the evolutionary processes that generate diversity at MHC class I genes in a large population of an archaic reptile species, the tuatara (Sphenodon punctatus), found on Stephens Island, Cook Strait, New Zealand. We identified at least 2 highly polymorphic (UA type) loci and one locus (UZ) exhibiting low polymorphism. The UZ locus is characterized by low nucleotide diversity and weak balancing selection and may be either a nonclassical class I gene or a pseudogene. In contrast, the UA-type alleles have high nucleotide diversity and show evidence of balancing selection at putative peptide-binding sites. Twenty-one different UA-type genotypes were identified among 26 individuals, suggesting that the Stephens Island population has high levels of MHC class I variation. UA-type allelic diversity is generated by a mixture of point mutation and gene conversion. As has been found in birds and fish, gene conversion obscures the genealogical relationships among alleles and prevents the assignment of alleles to loci. Our results suggest that the molecular mechanisms that underpin MHC evolution in nonmammals make locus-specific amplification impossible in some species.     

The role of the Major Histocompatibility Complex in the spread of contagious cancers

Major Histocompatibility Complex (MHC) genes play a key role in immune response to infectious diseases, immunosurveillance, and self/nonself recognition. Matching MHC alleles is critical for organ transplantation, while changes in the MHC profile of tumour cells allow effective evasion of the immune response. Two unique cancers have exploited these features to become transmissible. In this review I discuss the functional role of MHC molecules in the emergence and evolution of Devil Facial Tumour Disease (DFTD) and Canine Transmissible Venereal Tumour (CTVT). High levels of genetic diversity at MHC genes play a critical role in protecting populations of vertebrate species from contagious cancer. However, species that have undergone genetic bottlenecks and have lost diversity at MHC genes are at risk of transmissible tumours. Moreover, evolution and selection for tumour variants capable of evading the immune response allow contagious cancers to cross MHC barriers. Transmissible cancers are rare but they can provide unique insights into the genetics and immunology of tumours and organ transplants.     

Genetic diversity and differentiation at MHC genes in island populations of tuatara (Sphenodon spp.)

Neutral genetic markers are commonly used to understand the effects of fragmentation and population bottlenecks on genetic variation in threatened species. Although neutral markers are useful for inferring population history, the analysis of functional genes is required to determine the significance of any observed geographical differences in variation. The genes of the major histocompatibility complex (MHC) are well‐known examples of genes of adaptive significance and are particularly relevant to conservation because of their role in pathogen resistance. In this study, we survey diversity at MHC class I loci across a range of tuatara populations. We compare the levels of MHC variation with that observed at neutral microsatellite markers to determine the relative roles of balancing selection, diversifying selection and genetic drift in shaping patterns of MHC variation in isolated populations. In general, levels of MHC variation within tuatara populations are concordant with microsatellite variation. Tuatara populations are highly differentiated at MHC genes, particularly between the northern and Cook Strait regions, and a trend towards diversifying selection across populations was observed. However, overall our results indicate that population bottlenecks and isolation have a larger influence on patterns of MHC variation in tuatara populations than selection.     

Characterisation of class II B MHC genes from a ratite bird,the little spotted kiwi (<Emphasis Type="Italic">Apteryx owenii</Emphasis>)

Major histocompatibility complex (MHC) genes are important for vertebrate immune response and typically display high levels of diversity due to balancing selection from exposure to diverse pathogens. An understanding of the structure of the MHC region and diversity among functional MHC genes is critical to understanding the evolution of the MHC and species resilience to disease exposure. In this study, we characterise the structure and diversity of class II MHC genes in little spotted kiwi Apteryx owenii, a ratite bird representing the basal avian lineage (paleognaths). Results indicate that little spotted kiwi have a more complex MHC structure than that of other non-passerine birds, with at least five class II MHC genes, three of which are expressed and likely to be functional. Levels of MHC variation among little spotted kiwi are extremely low, with 13 birds assayed having nearly identical MHC genotypes (only two genotypes containing four alleles, three of which are fixed). These results suggest that recent genetic drift due to a species-wide bottleneck of at most seven birds has overwhelmed past selection for high MHC diversity in little spotted kiwi, potentially leaving the species highly susceptible to disease.