太平鸡遗传多样性及系统发育研究

受外来选育鸡种冲击,部分地方鸡品种处于濒危状态,甚至灭绝。康县太平鸡是我国优良地方鸡种之一,现存数量和分布区域日趋缩小,曾一度被报道灭绝。为研究太平鸡遗传多样性和系统发育,提供其遗传资源保护和开发理论依据,本研究对甘肃地方鸡种(太平鸡)和选育鸡种(快大型白羽肉鸡)线粒体D环(mitochondrial DNA D-loop)高变区进行了测定,并与Gen Bank中不同母系家鸡(Gallus gallus)相应数据比对分析,结果发现104个个体共检测到17个变异位点,12种单倍型,单倍型多样度(Hd)、核苷酸多样度(Pi)及平均核苷酸差异数(K)均较低。经系统发育分析得知太平鸡是起源于我国西南的地方鸡种,白羽肉鸡与起源于印度次大陆的商业选育鸡种具有相同的选育背景。表明太平鸡遗传多样性较低,是起源于我国西南的地方鸡。     

广西三黄鸡的遗传多样性及保种效果分析

广西三黄鸡肉嫩味美,是中国应用广泛、开发利用最好的著名地方品种。为了准确评价广西三黄鸡的遗传多样性和保种效果,以广西自治区内4个保种场314个样品为研究材料,用18个微卫星标记和线粒体DNA D-loop区(mtDNA)联合分析广西三黄鸡群体的遗传多样性。微卫星标记结果表明:共检测到144个等位基因,平均等位基因数为8个,期望杂合度(HE)为0.679 8,观察杂合度(HO)为0.560 5,多态信息含量(PIC)为0.639 3。线粒体DNA D-loop区结果表明:在检测序列中,共发现31个变异位点,17种单倍型,群体平均核苷酸多态性和单倍型多态性分别为0.0137 9,0.644;网络中介图表明广西三黄鸡具有5个血统来源,主要起源是东亚和云南或云南周边地区地方鸡血统,但在存在少量外来商业鸡种血统。本研究结果表明,广西三黄鸡具有较为丰富的遗传多样性,个别保种场需进一步提纯保种。     

云南地方猪种血液蛋白多态性研究

采用蛋白电泳技术研究了云南地方猪种血液蛋白多态性。共分析了3个云南地方猪种32-36个遗传位点,其中AKP、CAT、DIA、ES、G6PD、PA、6PGD、PHI、TF等9个 位点检测到多态性,多态位点百分比为0.1875-0.2121,平均杂合度为0.0712-0.1027。结果表明,云南地方猪种血液蛋白多态程度较高,反映在蛋白水平上的遗传多样性较为丰富。 Abstract:In this paper,protein electrophoresis was used to analyze the blood protein polymorphism in Yunnan local pig breeds and 32~36 genetic loci in the Yunnan local pig breeds were surveyed,Nine of them,such as AKP、CAT、DIA、ES、G6PD、PA、6PGD、PHI and TF,were found to be polymorphic,the mean heterozygosit(H)was 0.0712~0.1027.The results indicated that the blood protein polymorphism in the Yunnan local pig breeds is high,the Yunnan local pig breeds are wealthy in genetic diversity in point of their protein level.     

中国地方黄牛的遗传多样性*

中国黄牛起源复杂,我国地方黄牛群体不同品种在毛色、形态外貌、细胞遗传学、血液蛋白座位分析均表现出多样性。计算我国黄牛群体6个毛色座位平均杂合度和6个血液蛋白座位平均杂合度分别为0.3144和0.4873,表明我国地方黄牛群体的遗传多样性非常丰富。计算我国黄牛群体的6个毛色座位和6个血液蛋白座位的基因分化系数分别为0.3404和0.095,表明我国黄牛群体毛色差异中有34.04％是由品种间的差异造成的。血液蛋白的多态性有9.5％是由品种间的差异造成的。我国黄牛群体的遗传多样性主要来自品种内的遗传多样性。保存我国黄牛品种资源多样性不仅要从整个中国黄牛群体上考虑,而且要针对每个品种（或类群）进行保种。     

茶花鸡群体遗传多样性

茶花鸡是我国具有独特遗传特性的地方家禽品种,为了进一步阐明其群体遗传变异和遗传结构状况,采用了33个家鸡特异性的微卫星标记对该鸡种自然群体中30个个体进行了多态性电泳检测。33个微卫星座位共检测到105个等位基因,所有座位都呈现出多态性,每个座位的等位基因数在2~5个之间,平均每个座位等位基因数3.20个。群体平均杂合度和平均多态信息含量分别为0.612 9和0.527 6。结果表明,茶花鸡自然群体遗传多样性较丰富。     

鸡年说鸡

20 0 5年是乙酉鸡年 ,在十二生肖中 ,鸡是唯一的鸟类 ,而鸡能够成为十二生肖中的一员 ,不能不说与中国长期饲养家鸡的历史以及丰富的野生雉鸡类资源有关。家鸡是人类最早驯化的动物之一 ,在分类上属于鸟纲鸡形目。古文记载 ,距今 30 0 0多年前我国就有驯养的家鸡了。近年来 ,在河北武安县磁山新石器时代早期文化遗址中发现了类似家鸡的骨骼 ,这个发现表明 ,我国驯养家鸡的历史很可能可以追溯到 70 0 0多年前。家鸡的祖先一般认为是一种称为红原鸡的野生鸡类 ,它在体形、羽色、习性及鸣声等方面都与家鸡最为相似。世界上的野生鸡类共有 2 81…     

利用线粒体COI基因揭示中国乌骨鸡遗传多样性和群体遗传结构

全面了解中国乌骨鸡的遗传背景有利于保护和开发利用其种质资源。本研究测定了中国12个乌骨鸡品种线粒体细胞色素c氧化酶亚基I (cytochrome c oxidase subunit I, COI)基因, 比较分析其遗传多样性和群体遗传结构。255份乌骨鸡样品共检测到22个变异位点, 占分析位点的3.17%; 核苷酸多样性为0.00142-0.00339, 单倍型多样性为0.380-0.757, 其中略阳乌鸡核苷酸多样性最高, 德化黑鸡最低。检测到7个氨基酸变异位点, 来自6个品种共11个个体。定义了24种单倍型, 其中单倍型H1和H3为12个乌骨鸡品种共享, 出现频率分别为115次和64次; 盐津乌骨鸡单倍型数最多, 广西乌鸡最少。中性检验与错配分析显示实验种群未经历显著的群体扩张事件。分子变异分析显示81.06%的变异来自群体内; 品种间遗传距离为0.002-0.004, 品种间遗传分化系数F_st值为-0.035至0.594, 雪峰乌骨鸡与其他种群间的遗传分化程度最高。邻接树显示, 乌骨鸡未能独立形成分支, 不能从家鸡和红原鸡中有效区分开来。中国乌骨鸡中介网络图将24个单倍型分为3条进化主支, 呈现出一定的品种特异性, 由无量山乌骨鸡、云南盐津乌骨鸡和雪峰乌骨鸡组成单倍型H8、H9、H11、H12游离于这3条进化主支之外。增加其他家鸡和红原鸡COI基因的中介网络图主体结构与中国乌骨鸡的相同。结果表明中国乌骨鸡品种遗传多样性较低, 但品种间遗传分化显著, 可能是从当地家鸡中选育而来, 需要加强种质资源的保护。     

中国家鸡的起源探讨

测定了6个家鸡品种30个个体的线粒体D0环区539bp的碱基序列,并与GenBank中的红原鸡、灰原鸡、绿原鸡、黑尾原鸡及鹌鹑的相应序列作比较分析,构建了分析系统树。结果表明,原鸡属4个种间差异较大,其中家鸡与泰国及邻近地区红原鸡关系最近,与印尼红原鸡、黑尾原鸡、灰原鸡、绿原鸡及鹌鹑的关系依次变远。提示中国家鸡可能起源于泰国及邻近地区的红原鸡。结果还显示,该原鸡的两个亚种（G.g.gallus和G.g.spadiceus)间的遗传分化程度显著低于家鸡亚种内的分化程度,这两个亚种似乎可以归为同一亚种。     

尼西鸡遗传多样性微卫星标记分析

尼西鸡抗病力强,产蛋性能高,适应高海拔及寒冷的气候条件,是具有独特群体遗传特性的高原地方鸡种。为了对其有效保护和合理利用提供遗传背景资料,筛选了家鸡基因组24条染色体上的33个微卫星标记,对随机选取的50个尼西鸡个体进行多态性检测,共检测到122个等位基因,每个座位平均等位基因数为3·7个。该群体平均多态信息含量和平均杂合度分别为0·5514和0·6350,大染色体较小染色体的微卫星多态性程度高。表明尼西鸡属多态性较丰富的群体。     

家鸡腺苷琥珀酸裂解酶基因多态性与肌苷酸含量的关联及其与红原鸡的亲缘关系

根据腺苷琥珀酸裂解酶(adenylosuccinate lyase, ADSL)基因外显子2的序列设计引物, 用PCR-SSCP的方法对隐性白羽鸡、丝羽乌骨鸡、白耳鸡、藏鸡以及红色原鸡两个亚种进行了单核苷酸多态性分析, 并检测到了多态性, 表现为3种基因型, 对两种纯合子进行直接测序, 结果发现3484位碱基处发生C→T突变。对3种基因型的肌肉肌苷酸含量的最小二乘分析结果显示TT型(突变型)个体的肌肉肌苷酸含量极显著地高于CT型、显著地高于CC型个体, CT型个体也稍高于CC型, 但差异不显著, 初步推测该位点可能与肌肉肌苷酸含量有关。根据该多态位点的基因频率, 基于Nei氏的遗传距离运用NJ聚类法构建系统发生树, 进行家鸡与原鸡的亲缘关系分析, 结果发现, 丝羽乌骨鸡与白耳鸡的亲缘关系最近, 藏鸡和中国红原鸡亚种的亲缘关系也较近, 中国地方家鸡品种与中国红原鸡亚种的亲缘关系较近,而与泰国红色原鸡的亲缘关系较远,隐性白羽鸡与原鸡亲缘关系最远, 初步得出中国家鸡有自己独自的血缘来源的结论。     

The origin and genetic diversity of Chinese native chicken breeds

The first 539 bases of mitochondrial DNA D-loop region of six Chinese native chicken breeds (Gallus gallus domesticus) were sequenced and compared to those of the red junglefowl (Gallus gallus), the gray junglefowl (Gallus sonneratii), the green junglefowl (Gallus varius) and Lafayette's junglefowl (Gallus lafayettei) reported in GenBank, and the phylogenetic trees for the chickens were constructed based on the D-loop sequences. The results showed that the four species of the genus Gallus had great differences among each other, the G. g. domesticus was closest to the red junglefowl in Thailand and its adjacent regions, suggesting the Chinese domestic fowl probably originated from the red junglefowl in these regions. The two subs pecies of Thailand, G. g. gallus and G. g. spadiceus, should belong to one subspecies because of their resemblance. In the case of native breeds, there existed a great difference between the egg breeds and general purpose breeds, which suggested different maternal origins of the two types.     

Genetic diversity of Guangxi chicken breeds assessed with microsatellites and the mitochondrial DNA D-loop region

The domestic chicken (Gallus gallus domesticus) is an excellent model for genetic studies of phenotypic diversity. The Guangxi Region of China possesses several native chicken breeds displaying a broad range of phenotypes well adapted to the extreme hot-and-wet environments in the region. We thus evaluated the genetic diversity and relationships among six native chicken populations of the Guangxi region and also evaluated two commercial breeds (Arbor Acres and Roman chickens). We analyzed the sequences of the D-loop region of the mitochondrial DNA (mtDNA) and 18 microsatellite loci of 280 blood samples from six Guangxi native chicken breeds and from Arbor Acres and Roman chickens, and used the neighbor-joining method to construct the phylogenetic tree of these eight breeds. Our results showed that the genetic diversity of Guangxi native breeds was relatively rich. The phylogenetic tree using the unweighed pair-group method with arithmetic means (UPGAM) on microsatellite marks revealed two main clusters. Arbor Acres chicken and Roman chicken were in one cluster, while the Guangxi breeds were in the other cluster. Moreover, the UPGAM tree of Guangxi native breeds based on microsatellite loci was more consistent with the genesis, breeding history, differentiation and location than the mtDNA D-loop region. STRUCTURE analysis further confirmed the genetic structure of Guangxi native breeds in the Neighbor-Net dendrogram. The nomenclature of mtDNA sequence polymorphisms suggests that the Guangxi native chickens are distributed across four clades, but most of them are clustered in two main clades (B and E), with the other haplotypes within the clades A and C. The Guangxi native breeds revealed abundant genetic diversity not only on microsatellite loci but also on mtDNA D-loop region, and contained multiple maternal lineages, including one from China and another from Europe or the Middle East.     

Genetic structure of a wide-spectrum chicken gene pool

The genetic structure of 65 chicken populations was studied using 29 simple sequence repeat loci. Six main clusters which corresponded to geographical origins and histories were identified: Brown Egg Layers; predominantly Broilers; native Chinese breeds or breeds with recent Asian origin; predominantly breeds of European derivation; a small cluster containing populations with no common history and populations that had breeding history with White Leghorn. Another group of populations that shared their genome with several clusters was defined as 'Multi-clusters'. Gallus gallus gallus (Multi-clusters), one of the subspecies of the Red Jungle Fowl, which was previously suggested to be one of the ancestors of the domesticated chicken, has almost no shared loci with European and White Egg layer populations. In a further sub-clustering of the populations, discrimination between all the 65 populations was possible, and relationships between each were suggested. The genetic variation between populations was found to account for about 34% of the total genetic variation, 11% of the variation being between clusters and 23% being between populations within clusters. The suggested clusters may assist in future studies of genetic aspects of the chicken gene pool.     

Evaluation of genetic diversity in Chinese indigenous chicken breeds using microsatellite markers

China is rich in chicken genetic resources, and many indigenous breeds can be found throughout the country. Due to poor productive ability, some of them are threatened by the commercial varieties from domestic and foreign breeding companies. In a large-scale investigation into the current status of Chinese poultry genetic resources, 78 indigenous chicken breeds were surveyed and their blood samples collected. The genomes of these chickens were screened using microsatellite analysis. A total of 2740 individuals were genotyped for 27 microsatellite markers on 13 chromosomes. The number of alleles of the 27 markers ranged from 6 to 51 per locus with a mean of 18.74. Heterozygosity (H) values of the 78 chicken breeds were all more than 0.5. The average H value (0.622) and polymorphism information content (PIC, 0.573) of these breeds suggested that the Chinese indigenous chickens possessed more genetic diversity than that reported in many other countries. The fixation coefficients of subpopulations within the total population (F _ST) for the 27 loci varied from 0.065 (LEI0166) to 0.209 (MCW0078), with a mean of 0.106. For all detected microsatellite loci, only one (LEI0194) deviated from Hardy-Weinberg equilibrium (HWE) across all the populations. As genetic drift or non-random mating can occur in small populations, breeds kept on conservation farms such as Langshan chicken generally had lower H values, while those kept on large populations within conservation regions possessed higher polymorphisms. The high genetic diversity in Chinese indigenous breeds is in agreement with great phenotypic variation of these breeds. Using Nei’s genetic distance and the Neighbor-Joining method, the indigenous Chinese chickens were classified into six categories that were generally consistent with their geographic distributions. The molecular information of genetic diversity will play an important role in conservation, supervision, and utilization of the chicken resources.     

Evaluation of genetic diversity in Chinese indigenous chicken breeds using microsatellite markers

China is regarded as one of the domestication cen-ters for chickens and archaeological studies provided evidence of chicken domestication in northern Chinaas early as 6000 BC[1]. At present, China has the larg-est chicken population in the world, represen…     

Evolutionary relationships of Red Jungle Fowl and chicken breeds

Published results were reassessed and original data are provided regarding the origin and relatedness of four postulated chicken breed lineages, egg-type, game, meat-type and Bantam, to each other and to the basic ancestral species of jungle fowls, Gallus gallus. A system approach was employed concerning the planning of the experiments. One element of the system approach is the choice of the breeds to be compared with G. gallus. These breeds were supposed to represent major evolutionary branches of chickens. Four experiments on genetic relationships were conducted using different estimation criteria including morphological discrete characters, body measurements, biochemical markers, and the activity of serum esterase-1. The greatest similarity was found between G. gallus and the egg-type breeds of Mediterranean roots and/or true Bantams. This fact might testify that the indicated chicken groups occupied earlier stages in the evolution from the wild progenitor to the present biodiversity of chickens in the world.     

Sequencing and alignment of mitochondrial genomes of Tibetan chicken and two lowland chicken breeds

Tibetan chicken lives in high-altitude area and has adapted well to hypoxia genetically. Shouguang chicken and Silky chicken are both lowland chicken breeds. In the present study, the complete mitochondrial genome sequences of the three chicken breeds were all sequenced. The results showed that the mitochondrial DNAs (mtDNAs) of Shouguang chicken and Silky chicken consist of 16784 bp and 16785 bp respectively, and Tibetan chicken mitochondrial genome varies from 16784 bp to 16786 bp. After sequence analysis, 120 mutations, including 4 single nucleotide polymorphisms (SNPs) in tRNA genes, 9 SNPs and 1 insertion in rRNA genes, 38 SNPs and 1 deletion in D-LOOP, 66 SNPs in protein-coding genes, were found. This work will provide clues for the future study on the association between mitochondrial genes and the adaptation to hypoxia.     

Sequencing and alignment of mitochondrial genomes of Tibetan chicken and two lowland chicken breeds

Tibetan chicken lives in high-altitude area and has adapted well to hypoxia genetically. Shouguang chicken and Silky chicken are both lowland chicken breeds. In the present study, the complete mito-chondrial genome sequences of the three chicken breeds were all sequenced. The results showed that the mitochondrial DNAs (mtDNAs) of Shouguang chicken and Silky chicken consist of 16784 bp and 16785 bp respectively, and Tibetan chicken mitochondrial genome varies from 16784 bp to 16786 bp. After sequence analysis, 120 mutations, including 4 single nucleotide polymorphisms (SNPs) in tRNA genes, 9 SNPs and 1 insertion in rRNA genes, 38 SNPs and 1 deletion in D-LOOP, 66 SNPs in pro-tein-coding genes, were found. This work will provide clues for the future study on the association between mitochondrial genes and the adaptation to hypoxia.Tibetan chicken, lowland chicken, mitochondrial genome, hypoxia.     

Evaluation of HOXC8 in crested Swiss chicken

The crest in chicken consists of elongated and upraised feathers, as seen in various breeds such as the Silkie chicken. Recently, the still unknown causative mutation for the crest phenotype was assigned to chromosome 33 and an ectopic expression of HOXC8 was shown. The aim this study was to evaluate whether the crest phenotype in a local Swiss chicken breed, the Appenzeller Spitzhaubenhuhn, is associated with HOXC8. Three previously reported crest‐associated flanking markers at the HOXC8 locus were genotyped in cohorts of this breed and two other local breeds without the crest phenotype. For the Appenzeller Spitzhaubenhuhn chicken showing the crest phenotype, no clear association of the reported markers could be revealed. Furthermore, the two exons of HOXC8 were sequenced in crested chicken of the Appenzeller Spitzhaubenhuhn and Silkie breeds and revealed no evidence of polymorphisms within the coding region of HOXC8. Therefore, the molecular genetic etiology for the crest phenotype in the investigated breeds remains unclear.     

Chicken domestication: an updated perspective based on mitochondrial genomes

Domestic chickens (Gallus gallus domesticus) fulfill various roles ranging from food and entertainment to religion and ornamentation. To survey its genetic diversity and trace the history of domestication, we investigated a total of 4938 mitochondrial DNA (mtDNA) fragments including 2843 previously published and 2095 de novo units from 2044 domestic chickens and 51 red junglefowl (Gallus gallus). To obtain the highest possible level of molecular resolution, 50 representative samples were further selected for total mtDNA genome sequencing. A fine-gained mtDNA phylogeny was investigated by defining haplogroups A–I and W–Z. Common haplogroups A–G were shared by domestic chickens and red junglefowl. Rare haplogroups H–I and W–Z were specific to domestic chickens and red junglefowl, respectively. We re-evaluated the global mtDNA profiles of chickens. The geographic distribution for each of major haplogroups was examined. Our results revealed new complexities of history in chicken domestication because in the phylogeny lineages from the red junglefowl were mingled with those of the domestic chickens. Several local domestication events in South Asia, Southwest China and Southeast Asia were identified. The assessment of chicken mtDNA data also facilitated our understanding about the Austronesian settlement in the Pacific.