TYR基因外显子1的序列变异

为了分析家猪与野猪的遗传多样性及起源,测定了来自１２个中国地方家猪品种、３个欧洲引进猪品种以及8个中国野猪和2个越南野猪共36个个体的酪氨酸酶基因（TYR）外显子1的序列,共检出６个单核苷酸多态性位点（SNPs）,且这6个位点的变异均为同义突变,根据这些变异可将酪氨酸酶基因DNA序列归结为４种单倍型。结合已发表的数据,构建了简约中介网络图。 在网络图中,单倍型TYR*2主要为欧洲家猪与欧洲野猪和三条亚洲家猪染色体。大部分亚洲家猪和野猪共享单倍型TYR*1,表明这是一个亚洲类型的单倍型;同时也有部分欧洲家猪与野猪携带这一单倍型。 而单倍型TYR*3和TYR*4为本研究检测到的稀有单倍型,这两种单倍型主要由中国家猪与亚洲野猪组成。这种网络图结构支持家猪的欧洲和亚洲独立起源学说,同时也表明相当部分的欧洲家猪品种受到亚洲猪的基因渗透,而少量中国家猪和日本野猪也受到了欧洲猪的基因渗透。     

广西地区野猪化石古DNA及猪的驯化初探

猪的起源驯化一直是人们关注的问题,古DNA技术可为家猪起源驯化研究提供历史分子证据。为探讨广西地区更新世晚期野猪与当地家猪的关系,我们收集了广西壮族自治区晚更新世三个不同地点的30个猪科动物化石样品,测定了这些样品的线粒体DNA细胞色素b基因的核苷酸序列。结合现代不同品种家猪和野猪DNA同源序列信息,构建Network网络结构图,进一步证实了家猪多地起源学说。研究显示广西古代野猪与现存欧洲猪的基因型最为接近,属于欧洲单倍型H1,从而推测其对该地区现代家猪的遗传贡献可能较低,对考古形态学研究中关于广西地区家猪独立起源的推测提出了质疑。     

贵州三个地方猪种的系统发育分析

采用PCR产物直接测序方法首次测定贵州3个地方猪种(白洗猪、从江香猪、黔北黑猪)共计57个个体线粒体DNA控制区的全序列,将它们与GenBank上已知的25个国内外猪种一起计算遗传距离,并构建系统发育树。结果表明,3个贵州地方猪种mtDNA D-loop区的序列长度为1 254-1 314 bp之间,贵州地方猪种遗传距离在0.002 9-0.007 2之间,白洗猪与黔北黑猪、从江香猪之间的距离最大,均为0.007 2。系统发育分析的结果支持中国家猪分别有南北两个母系起源的观点,且各地方猪种之间可能有基因交流。     

三种小型猪线粒体DNA控制区的比较研究

目的分析五指山小型猪、巴马小型猪和贵州香猪线粒体DNA控制区碱基序列,比较研究不同猪种的遗传标志。方法应用PCR技术分别对这三种小型猪的血液总DNA样品中线粒体DNA D-loop区进行扩增,测序比对。结果猪的线粒体DNA D-loop区分三个区域。I区（靠近5’端区域）704bp,五指山小型猪在此区共有6个变异位点,通过6个变异位点中归纳出3个单倍体,而巴马小型猪在此区有9个变异位点,通过9个变异位点归纳出4个单倍体,贵州香猪在此区共有6个变异位点,通过6个变异位点归纳出3个单倍体。Ⅱ区（串联重复序列区）,五指山小型猪、巴马小型猪和贵州香猪序列相同。Ⅲ区（靠近3’端区域）三种小型猪的序列几乎相同。结论五指山小型猪、巴马小型猪和贵州香猪三种小型猪之间线粒体DNA碱基序列变异位点较少,五指山小型猪和巴马小型猪亲缘关系较近。     

三种小型猪线粒体DNA控制区的比较研究

目的分析五指山小型猪、巴马小型猪和贵州香猪线粒体DNA控制区碱基序列,比较研究不同猪种的遗传标志。方法应用PCR技术分别对这三种小型猪的血液总DNA样品中线粒体DNA D-loop区进行扩增,测序比对。结果猪的线粒体DNA D-loop区分3个区域。Ⅰ区（靠近5′端区域）704 bp,五指山小型猪在此区共有6个变异位点,通过6个变异位点中归纳出3个单倍体,而巴马小型猪在此区有9个变异位点,通过9个变异位点归纳出4个单倍体,贵州香猪在此区共有6个变异位点,通过6个变异位点归纳出3个单倍体。     

猪科的系统发育与系统地理分化

猪科动物是最为昌盛的哺乳动物之一,但它们的分类及系统发育关系却尚待解决。为此,用PCR直接测序法测定了一个红河猪(Potamochoerusporcus)、一个马来西亚野猪(Susbarbatus)以及数头欧亚野猪(Susscorfa)线粒体细胞色素b全序列1140bp。结合从GenBank中获得的其他猪科物种胞色素b序列,用邻接法和最大简约法构建了猪科物种的系统发育关系,其结果显示苏拉威西鹿猪与其他猪科物种为姐妹群的关系。非洲物种疣猪和河猪聚为一枝,而欧亚猪属物种聚为另一支。各物种在系统发育关系中的位置与它们的地理分布对应。猪属物种可以被划分为3个种组:分布于菲律宾群岛、苏拉威西岛及其邻近岛屿的猪属物种形成一个种组,包括苏拉威西岛疣猪、菲律宾疣猪和印度尼西亚疣猪;欧亚野猪种组,包括欧亚野猪和姬猪;须猪和爪哇疣猪形成一个种组。     

猪线粒体控制区微卫星(mtMs)变异及其分布特征

猪线粒体DNA长度因D-loop中mtMs序列重复数变异而不同。为阐明猪mtMs变异及其在不同群体中的分布特征,本研究对4个藏猪群体、八眉猪、烟台黑猪及3个引入猪群体共164个个体mtDNA D-loop全序进行测定,并与GenBank中发表的相关序列进行比对,分析了其中的重复单元核苷酸变异、重复次数及其在各群体间的分布规律。结果表明,因重复单元“5’-TGCGTACACG-3’”第2~4和10位上碱基变异,猪mtMs形成了以其为核心序列的多种重复单元(R^A^R^G)组成的复合结构,重复数介于3~47之间。单一重复(R^A)组成的mtMs结构在各群体中表现出分布优势,而大多数复合结构(R^AR^B)分布在国外选育群体中。藏猪的mtMs复合结构多达8个,R^AR^CR^E为其特有,另有5个与八眉猪共享。中国野猪和韩国地方猪种也有其特有mtMs结构。丰富的mtMs变异和特有结构与长期适应进化有关,本研究为地方猪种遗传资源及适应性研究提供了标记工具和理论基础。     

猪科的系统发育与系统地理分化

猪科动物是最为昌盛的哺乳动物之一，但它们的分类及系统发育关系却尚待解决。为此， 用PCR直接测序法测定了一个红河猪(Potamochoerus porcus)、一个马来西亚野猪(Sus barbatus)以及数头欧亚野猪(Sus scorfa)线粒体细胞色素b全序列1 140 bp。结合从GenBank中获得的其他猪科物种胞色素b序列，用邻接法和最大简约法构建了猪科物种的系统发育关系，其结果显示苏拉威西鹿猪与其他猪科物种为姐妹群的关系。非洲物种疣猪和河猪聚为一枝，而欧亚猪属物种聚为另一支。各物种在系统发育关系中的位置与它们的地理分布对应。猪属物种可以被划分为3个种组：分布于菲律宾群岛、苏拉威西岛及其邻近岛屿的猪属物种形成一个种组，包括苏拉威西岛疣猪、菲律宾疣猪和印度尼西亚疣猪；欧亚野猪种组，包括欧亚野猪和姬猪；须猪和爪哇疣猪形成一个种组。     

西藏小型猪的线粒体DNA控制区分析

目的研究西藏小型猪的遗传标记以及与其他国内地方猪的亲缘关系。方法扩增102头西藏小型猪以及16头巴马小型猪、17头贵州香猪的线粒体DNA控制区,测序并与国内其他猪进行比较。结果西藏小型猪线粒体DNAD-loop区分三个区域。串联重复序列区处于中间位置,包含有15～29个10 bp的重复片段,分为A、B两种类型。D-loop 3′端340 bp,与国内其他猪的序列相同比较保守;5′端704 bp,共有22个变异位点。由22个变异位点中归纳出25个单倍型,其中有两种主要的单倍型,分别占34.4%和36.6%。根据三个转换位点：305、500、691,将西藏小型猪分成了两组,几乎与串联重复序列所分的A、B两组类型相对应。与西藏小型猪相比,巴马小型猪和贵州香猪D-loop 5′端变异位点较少,分别只有4种和2种单倍型,串联重复区也只有一个类型。结论西藏小型猪可能有两个母系祖先并且与我国西南地区的品种猪有较近的亲缘关系;不同的串联重复片段类型和5′端的变异位点可以联合组建西藏小型猪的遗传标记。     

猪TLR4基因外显子1新等位基因的分离及遗传变异分析

文章采用PCR-SSCP方法对亚洲野猪、3个引进的商业化品种和10个中国地方猪品种共893个个体TLR4基因外显子1的遗传变异进行了检测,旨在系统分析国内外猪种TLR4基因的多态性,为探讨该基因在免疫和防御系统中发挥的作用提供依据。结果,在猪TLR4基因外显子1中分离到新的等位基因,共检测到3个等位基因,6种基因型。其中杜洛克检测到AA、BB、CC、AB、AC、BC基因型,有杜洛克血统的苏太猪中检测到BB、CC、BC基因型,长白猪、约克夏中检测到CC、BC基因型,野猪及所有10个中国地方猪品种TLR4基因外显子1高度保守,只检测到CC基因型,中国地方猪品种和引进品种TLR4基因外显子1多态性存在极显著的差异。3种基因型中CC型与GenBank中的序列一致,BB和AA基因型分别存在G93C同义突变位点和G194A无义突变位点,这2个变异位点与抗逆性和一般抗病力的关系值得进一步深入研究。     

A Phylogenetic Study of the Origin of the Domestic Pig Estimated from the Near-Complete mtDNA Genome

The near-complete pig mtDNA genome sequence (15,997 bp) was determined from two domestic pigs (one Chinese Meishan and one Swedish Landrace) and two European wild boars. The sequences were analyzed together with a previously published sequence representing a Swedish domestic pig. The sequences formed three distinct clades, denoted A, E1, and E2, with considerable sequence divergence between them (0.8–1.2%). The results confirm our previous study (based on the sequence of the cytochrome B gene and the control region only) and provide compelling evidence that domestication of pigs must have occurred from both an Asian and a European subspecies of the wild boar. We estimated the time since the divergence of clade A (found in Chinese Meishan pigs) and E1 (found in European domestic pigs) at about 900,000 years before present, long before domestication about 9000 years ago. The pattern of nucleotide substitutions among the sequences was in good agreement with previous interspecific comparisons of mammalian mtDNA; the lowest substitution rates were observed at nonsynonymous sites in protein-coding genes, in the tRNA and rRNA genes, while the highest rates were observed at synonymous sites and in the control region. The presence of Asian clade A in some major European breeds (Large White and Landrace) most likely reflects the documented introgression of Asian germplasm into European stocks during the 18th and 19th centuries. The coexistence of such divergent mtDNA haplotypes for 100+ generations is expected to lead to the presence of recombinant haplotypes if paternal transmission and recombination occur at a low frequency. We found no evidence of such recombination events in the limited sample studied so far. Received: 19 April 2000; Accepted: 15 November 2000     

Genetic relationship amongst the major non-coding regions of mitochondrial DNAs in wild boars and several breeds of domesticated pigs

We completed phylogenetic analysis of the major non-coding region of the mitochondrial DNA (mtDNA) from 159 animals of eight Euro-American and six East Asian domesticated pig breeds and 164 Japanese and five European wild boars. A total of 62 mtDNA haplotypes were detected. Alignment of these regions revealed nucleotide variations (including gaps) at 73 positions, including 58 sites with transition nucleotide substitutions, and two transversion substitutions. Phylogenetic analysis of the sequences could not organize domestic pig breeds into discrete clusters. In addition, many of the haplotypes found in members of diverged clustering groups were found primarily in Euro-American pig breeds, indicating extensive introgression of Asian domestic pigs into European breeds. Furthermore, phylogenetic analysis allocated the DNA sequences of non-coding regions into two different groups, and the deepest branchpoint of this porcine phylogeny corresponded to 86 000-136 000 years before present. This time of divergence would predate the historical period when the pig is thought to have been domesticated from the wild boar.     

Mitochondrial diversity in European and Chinese pigs is consistent with population expansions that occurred prior to domestication

Mitochondrial DNA (mtDNA) diversity in European and Asian pigs was assessed using 1536 samples representing 45 European and 21 Chinese breeds. Diagnostic nucleotide differences in the cytochrome b (Cytb) gene between the European and Asian mtDNA variants were determined by pyrosequencing as a rapid screening method. Subsequently, 637bp of the hypervariable control region was sequenced to further characterize mtDNA diversity. All sequences belonged to the D1 and D2 clusters of pig mtDNA originating from ancestral wild boar populations in Europe and Asia, respectively. The average frequency of Asian mtDNA haplotypes was 29% across European breeds, but varied from 0 to 100% within individual breeds. A neighbour-joining (NJ) tree of control region sequences showed that European and Asian haplotypes form distinct clusters consistent with the independent domestication of pigs in Asia and Europe. The Asian haplotypes found in the European pigs were identical or closely related to those found in domestic pigs from Southeast China. The star-like pattern detected by network analysis for both the European and Asian haplotypes was consistent with a previous demographic expansion. Mismatch analysis supported this notion and suggested that the expansion was initiated before domestication.     

Nucleotide variability of the porcine SERPINA6 gene and the origin of a putative causal mutation associated with meat quality

The serpin peptidase inhibitor, clade A, member 6 gene (SERPINA6), also known as corticosteroid-binding globulin or CBG, is involved in obesity and stress sensitivity. Previous studies have reported putative causal mutations within that gene in the porcine species. To characterize a hypothetical selective footprint, we have resequenced approximately 6 kb of coding and non-coding fragments in 20 pigs comprising domestic breeds and wild boars from Asia and Europe. Nucleotide variability was found to be far greater within Asian pig breeds than European breeds (π = 1% vs. 0.05%, respectively), which is consistent with pig evolutionary history. The putative causal amino acid substitution p.Gly307Arg (SNP c.919G>A) associated with meat quality (drip loss) was only detected in European domestic pig breeds, suggesting a very recent mutation that appeared after domestication in Europe. No support for positive selection was detected, as no reduction in levels of diversity surrounding the mutation was found in lean breeds with respect to wild boar.     

The Balkans and the colonization of Europe: the post‐glacial range expansion of the wild boar,Sus scrofa

Aim We focus on the biogeographical role of the Balkan Peninsula as a glacial refugium and source of northward post‐glacial dispersal for many European taxa. Specifically, we analysed the genetic structure and variation of wild boar (Sus scrofa) samples primarily from Greece, a region that has repeatedly served as a glacial refugium within the Balkan Peninsula. Location Continental Greece, the Aegean island of Samos and Bulgaria. Methods We analysed wild boar samples from 18 localities. Samples from common domestic breeds were also examined to take into account interactions between wild and domesticated animals. Phylogenetic analyses were carried out on a 637‐bp fragment of the mitochondrial DNA control region in 200 wild boar and 27 domestic pigs. The sequences were also compared with 791 Eurasian wild boar and domestic pig D‐loop sequences obtained from GenBank. Results Ninety‐four haplotypes were identified in the European wild boar data set, of which 68 were found in the Balkan samples and assigned to two previously described clades: the E1 European and Near Eastern clades. All of the continental samples clustered in the E1 clade and the samples from Samos fell into the Near Eastern clade, consistent with the island’s proximity to Asia Minor. Intriguingly, 62 novel haplotypes were identified and are found exclusively in the Balkans. Only six haplotypes were shared between wild boar and domestic pigs. Main conclusions Our data reveal numerous novel and geographically restricted haplotypes in wild boar populations, suggesting the presence of separate refugia in the Balkans. Our analyses support the hypothesis of a post‐glacial wild boar expansion consistent with the leading edge model, north and west from modern day Greece, and suggest little maternal introgression of Near Eastern and domestic haplotypes into wild Balkan populations.     

21个野生,培育及地方猪种免疫及生化遗传标记基因位点的遗传分化研究

分析了亚,欧,美,非２１个野生,培育及地方猪种４个免疫遗传标记基因位点（Ｅ,Ｆ,Ｇ,Ｌ系统）和３人生化遗传标记基因位点（Ｃｐ,Ａｍ和Ｔｆ）的遗传多态性,认为Ｅ＾ａｅｇ,Ｆ＾ａ,Ｔｆ＾ｃ基因在亚洲猪种与欧美猪种间存在显著差异,是亚洲猪种３个重要的遗传标记基因,根据Ｆ＾ａ基因频率在亚,欧,美,非猪种的变化规律分析了其基因流向特点,证明欧美猪的育种过程中利用了中国地方猪种的血缘,计算了所测猪种间的Ｎｅｉ     

Mitochondrial Genetic Variation in Chinese Pigs and Wild Boars

The mitochondrial DNAs (mtDNAs) from 30 pig breeds (29 Chinese native breeds and 1 European breed) and wild boars were investigated for restriction fragment length polymorphisms (RFLPs) to determine the phylogenetic relationships and genetic diversity among pig breeds and wild boars. Of the 24 enzymes used, 8 (AvaI, BclI, BglII, EcoRI, EcoRV, ScaI, StuI, and XbaI) detected polymorphisms. By combining the cleavage patterns for each enzyme, 108 individuals were sorted into eight mtDNA mitotypes. There are two haplotype lineages in domestic pigs, i.e., Chinese and European lineages. The pairwise nucleotide sequence divergence was calculated to be 0.56% between Chinese pigs and European pigs, suggesting that they might have diverged from a common ancestor approximately 280,000 years ago. The wild boars showed more extensive genetic variation, four mitotypes were detected in six wild boars. In addition, one of the Zhejiang wild boars was found to share the same mitotype with Chinese native pigs. A UPGMA tree based on genetic distance among mitotypes indicated that mtDNAs of Chinese pigs and European pigs are clearly divided into two clusters, and Chinese wild boars are more closely related to the Chinese pigs. Our results provide molecular evidence to support the previous hypothesis that pigs may be derived from two maternal origins, Asian and European wild boars. Chinese native pig breeds may have a single origin.     

The robust phylogeny of Korean wild boar (<Emphasis Type="Italic">Sus scrofa coreanus</Emphasis>) using partial D-loop sequence of mtDNA

In order to elucidate the precise phylogenetic relationships of Korean wild boar (Sus scrofa coreanus), a partial mtDNA D-loop region (1,274 bp, NC_000845 nucleotide positions 16576-1236) was sequenced among 56 Korean wild boars. In total, 25 haplotypes were identified and classified into four distinct subgroups (K1 to K4) based on Bayesian phylogenetic analysis using Markov chain Monte Carlo methods. An extended analysis, adding 139 wild boars sampled worldwide, confirmed that Korean wild boars clearly belong to the Asian wild boar cluster. Unexpectedly, the Myanmarese/Thai wild boar population was detected on the same branch as Korean wild boar subgroups K3 and K4. A parsimonious median-joining network analysis including all Asian wild boar haplotypes again revealed four maternal lineages of Korean wild boars, which corresponded to the four Korean wild boar subgroups identified previously. In an additional analysis, we supplemented the Asian wild boar network with 34 Korean and Chinese domestic pig haplotypes. We found only one haplotype, C31, that was shared by Chinese wild, Chinese domestic and Korean domestic pigs. In contrast to our expectation that Korean wild boars contributed to the gene pool of Korean native pigs, these data clearly suggest that Korean native pigs would be introduced from China after domestication from Chinese wild boars.     

The origin of the domestic pig: independent domestication and subsequent introgression

The domestic pig originates from the Eurasian wild boar (Sus scrofa). We have sequenced mitochondrial DNA and nuclear genes from wild and domestic pigs from Asia and Europe. Clear evidence was obtained for domestication to have occurred independently from wild boar subspecies in Europe and Asia. The time since divergence of the ancestral forms was estimated at approximately 500,000 years, well before domestication approximately 9,000 years ago. Historical records indicate that Asian pigs were introduced into Europe during the 18th and early 19th centuries. We found molecular evidence for this introgression and the data indicated a hybrid origin of some major "European" pig breeds. The study is an advance in pig genetics and has important implications for the maintenance and utilization of genetic diversity in this livestock species.     

The phylogeny of Chinese indigenous pig breeds inferred from microsatellite markers

A genetic study of 32 local Chinese, three foreign pig breeds [Duroc (DU), Landrace and Yorkshire], and two types of wild boar (Hainan and Dongbei wild boar) based on 34 microsatellite loci was carried out to clarify the phylogeny of Chinese indigenous pig breeds. The allele frequencies, effective numbers of alleles, and the average heterozygosity within populations were calculated. The results showed that the genetic variability of the Lingao pig was the largest, while the Jiaxing pig was the lowest. The greatest distance between domestic pigs was found between Shanggao and DU pig and the shortest was found between Wuzhishan and Lingao pig, respectively. A neighbour-joining tree constructed from Modified Cavalli-Sforza genetic distances divided Chinese pigs into two clusters; four subclusters were also identified. Our results only partly agree with the traditional types of classification and also provide a new relationship among Chinese local pig breeds. Our data also confirmed that Chinese pig breeds have a different origin from European/American breeds and can be utilized in programmes that aim to maintain Chinese indigenous pig breeds.