组织相容性复合体在实验鸡中的应用

鸡主要组织相容性复合体（MHC）基因位于鸡16号染色体上,具有高度的多态性。现已发现,不同MHC-B单倍体对各种疾病的抗性不同。本文主要介绍了鸡MHC的结构特点、鸡MHC与抗病性的关系、鸡MHC检测方法的研究进展以及其在鸡抗病育种中的应用前景。     

犬类MHC复合体Ⅱ类基因研究进展

概述了犬类MHCⅡ类基因的物理结构图谱,对基因的结构、功能及表达、基因分型方法、基因多态性、基因与疾病的关联研究等作了详细的综述,指明了对犬类MHCⅡ类基因的研究利于其抗病育种,对人类自身免疫性疾病和器官移植等方面具有重要现实意义。     

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。     

宠物抗病育种

宠物的抗病育种研究具有重要的意义,本文对开展抗病育种的必要性、宠物免疫抗病系统、疾病抗性遗传机制、免疫反应的遗传控制、宠物抗病常规育种、宠物抗病分子育种以及抗病育种方法的现状、存在的问题、展望进行了介绍。说明了对疾病抗性的选择有一个坚实基础。抗病育种是控制疾病的有效方法,应用前景美好。     

陕北白绒山羊DRB1基因多态性与球虫病的相关性分析

本研究旨在探讨陕北白绒山羊MHC (主要组织相容性复合体)基因与疾病抗性的关系,通过对98只陕北白绒山羊DRB1基因外显子2多态性与球虫病的相关性研究,共获得17条等位基因和29种基因型,其中10条等位基因是首次发现。生物信息学分析表明DRB1位点具有高度多态性,且不同等位基因预测的蛋白质结构存在明显差异,说明这种基因可能通过抗原呈递分子结构的改变影响宿主对病原体的免疫应答。相关性分析发现DRB1*16等位基因频率与球虫感染强度呈显著负相关(p0.05),提示该等位基因可能与相关抗原呈递及抗性的产生有关。本次对陕北白绒山羊DRB1基因多态性及其与球虫病的相关性分析有助于筛选疾病抗性和易感性相关基因,进而可加速绒山羊抗病品系的培育进程。     

水稻抗纹枯病遗传育种研究进展

纹枯病是世界性水稻病害, 在中国南方部分水稻种植区已成为水稻第一大病害. 但对水稻抗纹枯病遗传育种研究却进展缓慢. 抗性鉴定方法、抗病基因定位和抗性资源发掘是抗病遗传育种研究中的最重要内容, 亦是抗病品种选育的基础. 本文综述了近年提出的水稻纹枯病抗性鉴定方法, 对抗病基因QTL进行物理图谱整合, 分析了抗病QTL的定位概况, 同时对抗源发掘和抗病育种方面的新进展进行了归纳与讨论, 最后提出下一步研究方向, 以期为加速水稻抗纹枯病遗传育种进程提供帮助.     

玉米抗甘蔗花叶病毒分子标记开发

由甘蔗花叶病毒引起的玉米矮花叶病是我国黄淮海地区玉米生产的重要病害,开发抗矮花叶病基因分子标记是开展抗病分子标记辅助育种的基础。本文基于玉米6.00-6.01区域的“一致性抗甘蔗花叶病毒QTL区间”寻找抗病基因的功能保守域,依据序列多态性开发出抗病分子标记InDel-130和InDel-110,在已知抗性的102份玉米自交系中进行验证。通过分析标记抗病带型和感病带型中的抗病和感病自交系数目,卡平方测验表明标记InDel-130在供试自交系中与抗病性的表现独立无关,而标记InDel-110与甘蔗花叶病毒抗性高度相关,为共显性标记,可用于玉米抗甘蔗花叶病毒种质筛选和分子标记辅助育种。     

两栖动物MHC基因研究进展

MHC是高度多态的基因群,广泛分布于各种脊椎动物体内。由于MHC基因的多态性,使其在脊椎动物的免疫、遗传、进化、保护等许多方面的研究倍受关注。本文综述了两栖类MHC基因自研究以来国内外有关该基因的研究报道,包括其结构、功能以及在两栖类遗传进化、种群遗传学、免疫遗传学及抗病中的应用,并对研究前景进行了展望。     

IBVS1基因表达载体PG-S1的构建

以含有鸡传染性支气管炎病毒S1基因的载体P^IBV-Z和含有CMV启动子的栽体质粒P^EGFR-C1为材料,构建了可表达IBV S1基因的表达载体P^G-S1,经酶切、电泳和PCR检测结果证实,构建的载体符合目的要求,可以作为表达载体用于鸡的抗病育种。     

玉米抗甘蔗花叶病毒分子标记开发

由甘蔗花叶病毒引起的玉米矮花叶病是我国黄淮海地区玉米生产的重要病害,开发抗矮花叶病基因分子标记是开展抗病分子标记辅助育种的基础。本文基于玉米6．00-6．01区域的“一致性抗甘蔗花叶病毒QTL区间”寻找抗病基因的功能保守域,依据序列多态性开发出抗病分子标记InDel-130和InDel-110,在已知抗性的102份玉米自交系中进行验证。通过分析标记抗病带型和感病带型中的抗病和感病自交系数目,卡平方测验表明标记InDel-130在供试自交系中与抗病性的表现独立无关．而标记InDel-110与甘蔗花叶病毒抗性高度相关,为共显性标记,可用于玉米抗甘蔗花叶病毒种质筛选和分子标记辅助育种。     

Breeding for immune responsiveness and disease resistance

Animal production efficiency, and product volume and quality can be greatly increased by reducing disease losses. Genetic variation, a prerequisite for successful selection, has been found in animals and poultry exposed to a variety of viral, bacterial and parasitic infections. Breeding for disease resistance can play a significant role alone or in combination with other control measures including disease eradication, vaccination and medication. Feasibility of simultaneously improving resistance to specific diseases and production traits has been demonstrated. However, selection for specific resistance to all diseases of animals and poultry is impossible. Development of general disease resistance through indirect selection primarily on immune response traits may be the best long-term strategy but its applicability is presently limited by insufficient understanding of resistance mechanisms. Another hindrance may be negative genetic correlations among various immune response functions: phagocytosis, cell mediated and humoral immunity. To better assess the feasibility of increasing general disease resistance by indirect selection we must obtain estimates of heritability for immune response, disease resistance, and economic production traits, as well as genetic correlations among these traits. The present level of disease resistance in farm animals resulted from natural selection and from correlated responses to selection for production traits while the influence of artificial selection for resistance was minimal. Future research should be directed towards developing and applying breeding techniques that will increase resistance to diseases without compromising production efficiency and product quality. This will require cooperation of immunogeneticists, veterinarians and animal and poultry breeders. Significant progress in the improvement of resistance to diseases may result from the application of new techniques of molecular genetics and cell manipulation.     

Breeding for immune responsiveness and disease resistance1

Animal production efficiency, and product volume and quality can be greatly increased by reducing disease losses. Genetic variation, a prerequisite for successful selection, has been found in animals and poultry exposed to a variety of viral, bacterial and parasitic infections. Breeding for disease resistance can play a significant role alone or in combination with other control measures including disease eradication, vaccination and medication. Feasibility of simultaneously improving resistance to specific diseases and production traits has been demonstrated. However, selection for specific resistance to all diseases of animals and poultry is impossible. Development of general disease resistance through indirect selection primarily on immune response traits may be the best long-term strategy but its applicability is presently limited by insufficient understanding of resistance mechanisms. Another hindrance may be negative genetic correlations among various immune response functions: phagocytosis, cell mediated and humoral immunity. To better assess the feasibility of increasing general disease resistance by indirect selection we must obtain estimates of heritability for immune response, disease resistance, and economic production traits, as well as genetic correlations among these traits. The present level of disease resistance in farm animals resulted from natural selection and from correlated responses to selection for production traits while the influence of artificial selection for resistance was minimal. Future research should be directed towards developing and applying breeding techniques that will increase resistance to diseases without compromising production efficiency and product quailty. This will require cooperation of immunogeneticists, veterinarians and animal and poultry breeders. Significant progress in the improvement of resistance to diseases may result from the application of new techniques of molecular genetics and cell manipulation.     

Production of an MHC class II B molecular probe in the turkey,Meleagris gallopavo

Genetic selection for disease resistance may be facilitated by molecular markers of the major histocompatibility complex (MHC) of poultry. We describe the first sequence variation documented at the MHC Class II B region of turkeys, and provide specific probe optimization conditions for studying RFLP polymorphisms in this species.     

An assessment of opportunities to dissect host genetic variation in resistance to infectious diseases in livestock

This paper reviews the evidence for host genetic variation in resistance to infectious diseases for a wide variety of diseases of economic importance in poultry, cattle, pig, sheep and Atlantic salmon. Further, it develops a method of ranking each disease in terms of its overall impact, and combines this ranking with published evidence for host genetic variation and information on the current state of genomic tools in each host species. The outcome is an overall ranking of the amenability of each disease to genomic studies that dissect host genetic variation in resistance. Six disease-based assessment criteria were defined: industry concern, economic impact, public concern, threat to food safety or zoonotic potential, impact on animal welfare and threat to international trade barriers. For each category, a subjective score was assigned to each disease according to the relative strength of evidence, impact, concern or threat posed by that particular disease, and the scores were summed across categories. Evidence for host genetic variation in resistance was determined from available published data, including breed comparison, heritability studies, quantitative trait loci (QTL) studies, evidence of candidate genes with significant effects, data on pathogen sequence and on host gene expression analyses. In total, 16 poultry diseases, 13 cattle diseases, nine pig diseases, 11 sheep diseases and three Atlantic salmon diseases were assessed. The top-ranking diseases or pathogens, i.e. those most amenable to studies dissecting host genetic variation, were Salmonella in poultry, bovine mastitis, Marek's disease and coccidiosis, both in poultry. The top-ranking diseases or pathogens in pigs, sheep and Atlantic salmon were Escherichia coli, mastitis and infectious pancreatic necrosis, respectively. These rankings summarise the current state of knowledge for each disease and broadly, although not entirely, reflect current international research efforts. They will alter as more information becomes available and as genome tools become more sophisticated for each species. It is suggested that this approach could be used to rank diseases from other perspectives as well, e.g. in terms of disease control strategies.     

Breeding for Improved Disease Resistance in Organic Farming – Possibilities and Constraints

Lowered incidences of disease may be reached in several ways: management and rearing measures, vaccination programmes and preventive medications as well as breeding for improved disease resistance. Here the focus is on breeding for improved resistance to infectious diseases. In comparison to conventional farming, one has to acknowledge that the spectrum of diseases in animals reared under organic conditions is different and that the proportion of the breeding stock of animals in organic farming is considerably smaller. There are at least four different approaches that may be used in breeding towards resistance to infectious diseases. The most obvious is to record disease incidence in the progeny and select those parents that produce the progeny with the lowest incidences of disease. Another approach is to use breeders possessing certain major histo-compatibility complex antigens suggested being associated with resistance to certain infections. A third approach is to analyse the heritability of a set of immune functions or related traits crucial for resistance to infections and then use the traits with high heritability in breeding programmes. Finally, one may genetically select animals for high immune response using an index that combines estimated breeding values for several immunological traits. Examples of these various approaches are given and the feasibility for using these in organic farming are discussed.     

MHC polymorphism and disease resistance to Vibrio anguillarum in 12 selective Japanese flounder (Paralichthys olivaceus) families

Genetic variation in the major histocompatibility complex (MHC) class IIB was tested in Japanese flounder (Paralichthys olivaceus) for survival after challenge with bacterial infection. The material consisted of 6000 Japanese flounder from 60 families challenged with Vibrio anguillarum, which causes significantly different mortality in flounder families. Five individuals from each of six high-resistance (HR) and six low-resistance (LR) families were screened for their MHC class IIB genotypes using sequence analysis. High polymorphism of MHC IIB gene and at least three loci were discovered in Japanese flounder and the rate of d(N) occurred at a significantly higher frequency than that of d(S) in PBR. Among 60 individuals, 76 alleles were discovered and 15 alleles were used to study associations between alleles and resistance to disease. We found highly significant associations between resistance towards infectious disease caused by V. anguillarum and MHC class IIB polymorphism in Japanese flounder. Some alleles appeared in both HR and LR families, while some alleles were only discovered in HR or LR families. One allele, Paol-DAB*4301, was significantly more prevalent in HR families than in LR families (P=0.023). Paol-DAB*0601, Paol-DAB*0801, Paol-DAB*2001, Paol-DAB*3803 were discovered in two HR families with high frequency. One allele, Paol-DAB*1601, was discovered in three LR families. The steady heredity of MHC class IIB alleles was observed, and the family having Paol-DAB*4301 alleles was confirmed with higher resistance to V. anguillarum. This study confirmed the association between alleles of MHC class IIB gene and disease resistance, and also detected some alleles which might be correlated with high bacterial infection resistance. The disease resistance-related MHC markers could be used for molecular marker-assisted selective breeding in the flounder.     

MHC polymorphism and disease resistance in Atlantic salmon (<Emphasis Type="Italic">Salmo salar</Emphasis>); facing pathogens with single expressed major histocompatibility class I and class II loci

Few studies have yet addressed the functional aspects of MHC molecules in fish. To lay the foundation for this, we evaluated the association between disease resistance and MHC class I and class II polymorphism in Atlantic salmon. Standardized disease challenge trials were performed on a semi-wild Atlantic salmon population with subsequent MHC typing and statistical analysis. The pathogens employed were infectious salmon anaemia virus (ISAV) causing infectious salmon anaemia and the Aeromonas salmonicida bacteria causing furunculosis. The material consisted of 1,182 Atlantic salmon from 33 families challenged with A. salmonicida and 1,031 Atlantic salmon from 25 families challenged with ISAV. We found highly significant associations between resistance towards infectious diseases caused by both pathogens and MH class I and class II polymorphism in Atlantic salmon. The observed associations were detected due to independently segregating MH class I and class II single loci, and inclusion of a large number of fish allowing an extensive statistical analysis.     

Polymorphisms in major histocompatibility complex class IIα genes are associated with resistance to infectious hematopoietic necrosis in rainbow trout,Oncorhynchus mykiss (Walbaum, 1792)

Infectious hematopoietic necrosis is a serious viral disease of salmonids, including rainbow trout Oncorhynchus mykiss, and causes tremendous economic losses to the rainbow trout farming industry. Major histocompatibility complex (MHC) genes are crucial elements of adaptive immunity in vertebrate organisms and have been linked with the resistance to numerous pathogenic diseases. In this study, polymerase chain reaction‐single strand conformation polymorphism (PCR‐SSCP) followed by cloning and sequencing were used to examine polymorphisms in the DAA genes (specifically DAA exon 2 of MHC class IIα) of rainbow trout and investigate their association with the infectious hematopoietic necrosis virus (IHNV) resistance in rainbow trout. Seventeen alleles were resolved, including 13 novel alleles. Individuals possessed between two and five alleles, indicating that the genome harbours at least three closely‐related DAA exon 2 loci. The ratio of non‐synonymous to synonymous nucleotide substitutions suggested that DAA exon 2 is under positive selection. A greater variability of amino acids and non‐synonymous nucleotide substitution rate was evident in the peptide‐binding region (PBR) than in the non‐PBR (27.75%). Importantly, the analyses revealed that certain MHC class IIα alleles appear to confer resistance to IHNV in rainbow trout, while others confer susceptibility. The most common alleles in the resistant populations of rainbow trout, Onmy‐DAA*1301 and Onmy‐DAA*0304, confer resistance to IHNV and were not present in the susceptible population. Hence, these alleles may be ideal molecular markers that can assist the breeding of IHNV resistance in rainbow trout.