FSHβ 基因PCR-SSCP多态性及其与济宁青山羊高繁殖力关系的研究

采用PCR-SSCP技术检测促卵泡素b亚基(follicle-stimulating hormone β, FSHβ)基因5′调控区、外显子1和外显子2在高繁殖力山羊品种(济宁青山羊)和低繁殖力山羊品种(辽宁绒山羊、波尔山羊、安哥拉山羊)中的单核苷酸多态性, 同时研究该基因对济宁青山羊高繁殖力的影响。结果表明: 山羊与绵羊的FSHβ 基因该段核苷酸序列同源性为98%。9对引物中, 只有P9的扩增片段存在多态性。P9的扩增片段在济宁青山羊和辽宁绒山羊中检测到AA、AB和AC 3种基因型; 在波尔山羊中检测到AA、CC和AC 3种基因型; 在安哥拉山羊中检测到AA、BB、CC、AB、AC和BC共6种基因型。测序分析发现BB型与AA型相比在外显子2的第94 bp处有G→A突变, 并引起氨基酸改变(丙氨酸→苏氨酸); CC型与AA型相比在外显子2的第174 bp有一处C→T沉默突变。济宁青山羊AA、AB和AC基因型频率分别为0.686、0.137和0.177。AA基因型济宁青山羊产羔数最小二乘均值比AB基因型的多0.78只(P<0.05), 比AC基因型的多0.64只(P<0.05)。     

Polymorphism of bone morphogenetic protein 4 gene and its relationship with litter size of Jining Grey goats

Two pairs of primers (P1 and P2) were designed to detect single nucleotide polymorphisms of exon 2 and intron 2 of bone morphogenetic protein 4 (BMP4) gene in both high fecundity breed (Jining Grey goat) and low fecundity breeds (Boer, Angora and Inner Mongolia Cashmere goats) by single strand conformation polymorphism. Results showed that no polymorphism was detected for exon 2 (primer P1) of BMP4 gene in four goat breeds. For intron 2 (primer P2), three genotypes (AA, AB and BB) were detected in Jining Grey and Inner Mongolia Cashmere goats, two genotypes (AB and BB) in Angora goats, and only one genotype (AA) in Boer goats. Sequencing revealed one mutation (2203G>A) of BMP4 gene in the genotype BB in comparison to the genotype AA. The differences of litter size between AA, AB and BB genotypes were not significant (P > 0.05) in Jining Grey goats. A pair of primer (P3) was designed to detect polymorphism in the 3' flanking region of BMP4 gene that contained dinucleotide repeated sequence (CA) in the four goat breeds by microsatellite analysis. For primer P3, three genotypes (CC, CD and DD) were detected in four goat breeds. Sequencing revealed one more CA dinucleotide in genotype DD than in genotype CC. The Jining Grey does with genotype CC had 0.55 (P < 0.05) or 0.72 (P < 0.05) kids more than those with genotype CD or DD. These results preliminarily indicated that allele C of BMP4 gene is a potential DNA marker for improving litter size in goats.     

Polymorphisms of caprine <Emphasis Type="Italic">GDF</Emphasis>9 gene and their association with litter size in Jining Grey goats

The exons 1, 2 and flanking region of growth differentiation factor 9 (GDF9) gene in five randomly selected does of Jining Grey, Boer and Liaoning Cashmere goats were amplified and analyzed. Thirteen nucleotide differences were identified in GDF9 gene between sheep (AF078545) and goats. Four SNPs (G3288A in intron 1, G423A, A959C [Gln320Pro] and G1189A [Val397Ile] in exon 2) were detected in four goat breeds with different prolificacy, in which G3288A was a new SNP in goats. The results showed that loci 3288, 423 and 1189 in Boer goats, loci 3288 and 423 in Guizhou White goats, loci 423 and 1189 in Liaoning Cashmere goats were all in complete linkage disequilibrium (D′ = 1, r ² = 1), respectively. In moderate (Boer goat) and low prolificacy (Liaoning Cashmere goat) breeds, linkage analysis indicated that there were more fervent linkage disequilibrium among loci 3288, 423 and 1189 than high prolificacy (Jining Grey and Guizhou White goats) breeds. For the 959 locus, the genotype distribution showed obvious difference between high prolificacy breeds and moderate or low prolificacy breeds (P < 0.05 or P < 0.01). The Jining Grey goat does with genotype CC or AC had 0.81 (P < 0.01) or 0.63 (P < 0.01) kids more than those with genotype AA, respectively. The present study preliminarily showed an association between allele C at 959 locus of GDF9 gene and high litter size in Jining Grey goats. These results provide further evidence that the GDF9 gene may be significantly correlated with high prolificacy in goats.     

催乳素受体基因外显子10多态性及其与济宁青山羊高繁殖力关系的研究

设计5对引物, 采用PCR-SSCP技术检测催乳素受体(prolactin receptor, PRLR)基因外显子10及部分3′非翻译区在高繁殖力山羊品种(济宁青山羊)和低繁殖力山羊品种(辽宁绒山羊、波尔山羊和安哥拉山羊)中的单核苷酸多态性, 同时研究该基因对济宁青山羊高繁殖力的影响。结果表明: 首次拼接出的山羊PRLR基因外显子10及部分3′非翻译区的核苷酸序列长度为1,118 bp, 与已公布的绵羊、牛、人PRLR基因mRNA相应序列的同源性分别为98.33%、93.92%、74.52%, 与已公布的羊驼PRLR基因部分序列的同源性为78.29%。引物P1、P2与P4扩增片段具有多态性, 其余2对引物的扩增片段不存在多态性。对于P1扩增片段, 在济宁青山羊和辽宁绒山羊中检测到AA型和AB型, 在安哥拉山羊中检测到AA型和AC型, 在波尔山羊中只检测到AA型; 克隆测序表明AB型与AA型相比有两处突变(186G→A和220T→C), 分别导致氨基酸由天冬氨酸变为天冬酰胺、亮氨酸变为脯氨酸; AC型与AA型相比有1处突变(140A→G), 该突变没有导致氨基酸变化; 济宁青山羊AA和AB基因型之间产羔数的最小二乘均值差异不显著(P>0.05)。对于P2扩增片段, 在济宁青山羊、辽宁绒山羊和波尔山羊中都检测到DD型和DE型, 而在安哥拉山羊中只检测到DD型; 克隆测序表明DE型和DD型相比有两处突变(52G→A和122G→A), 其中122 bp处的突变导致氨基酸由精氨酸变为甘氨酸; 济宁青山羊DD和DE基因型之间产羔数的最小二乘均值差异不显著(P>0.05)。对于P4扩增片段, 在济宁青山羊中检测到FF型和FG型, 在辽宁绒山羊中检测到FF型和GG型, 在波尔山羊中只检测到FF型, 在安哥拉山羊中检测到FF型、FG型和GG型; 克隆测序表明GG型和FF型相比在扩增片段的143 bp处发生1处碱基突变(A→G), 并导致氨基酸由蛋氨酸变为缬氨酸; FG基因型济宁青山羊产羔数最小二乘均值比FF基因型的多0.76只(P<0.05)。研究结果初步表明: PRLR基因可能是控制济宁青山羊多胎性能的一个主效基因或是与之存在紧密遗传连锁的一个标记。     

Association between PCR-SSCP of bone morphogenetic protein 15 gene and prolificacy in Jining Grey goats

The Jining Grey is a prolific local goat breed in P.R. China. Bone morphogenetic protein 15 (BMP15) gene that controls high fecundity of Inverdale, Hanna, Lacaune, Belclare, Cambridge, and Small Tailed Han ewes was studied as a candidate gene for the prolificacy of Jining Grey goats. According to the sequence of ovine BMP15 gene, six pairs of primers were designed to detect single nucleotide polymorphisms in exon 1 and exon 2 of the BMP15 gene in both high fecundity breed (Jining Grey goats) and low fecundity breeds (Boer, Liaoning Cashmere, and Inner Mongolia Cashmere goats) by single strand conformation polymorphism (SSCP). Two pairs of primers (F1/R1 and F2/R2) were used to amplify the exon 1. Four pairs of primers (F3/R3, F4/R4, F5/R5, and F6/R6) were used to amplify the exon 2. Only the products amplified by primer F5/R5 displayed polymorphism. Results indicated that two genotypes (AA and AB) were detected in prolific Jining Grey goats and only one genotype (AA) was detected in low fecundity goat breeds. In Jining Grey goats frequencies of genotypes AA and AB were 0.10 and 0.90, respectively. Sequencing revealed two point mutations (G963A and G1050C) of BMP15 gene in the AB genotype in comparison to the AA genotype. In Jining Grey goats the heterozygous AB does had 1.13 (p < 0.01) kids more than the homozygous AA does. These results preliminarily showed that the BMP15 gene is either a major gene that influences the prolificacy of Jining Grey goats or a molecular genetic marker in close linkage with such a gene.     

Polymorphisms of caprine <Emphasis Type="Italic">POU1F1</Emphasis> gene and their association with litter size in Jining Grey goats

Seven pairs of primers were designed to amplify 5′ promoter region, six exons and partial introns and to detect the polymorphisms of POU1F1 gene in five goat breeds with different prolificacy. The results showed that six mutations were identified in caprine POU1F1 gene including C256T in exon 3, C53T and T123G in intron 3, and G682T (A228S), T723G and C837T in exon 6. The former four mutations were novel SNPs in goat POU1F1 gene. The 53 and 123 loci were in complete linkage disequilibrium in five caprine breeds. Regarding the 256 locus, the Jining Grey goat does with genotype CT had 0.66 kids more than those with genotype CC (P < 0.05), while does with genotype GT had 0.63 (P < 0.05) kids more than those with genotype GG at the 682 locus. The present study preliminarily showed an association between allele T at the 256 and 682 loci of POU1F1 gene and high litter size in Jining Grey goats. Totally 16 haplotypes and 50 genotypes were identified at the above six loci in POU1F1 gene of five goat breeds. Three common haplotypes (hap2, hap3 and hap4) were identified in five goat breeds joined. Four specific haplotypes (hap7, hap9, hap11 and hap13) were detected in Jining Grey goats. The predominant haplotype was hap1 (35.29% and 48.25%) in both Jining Grey and Guizhou White goats, while hap4 (50%) in Boer goats, and hap2 (42.86% and 38.75%) in both Wendeng Dairy and Liaoning Cashmere goats. The most frequent genotypes at six loci in the above five goat breeds were hap1/hap2 (14.38%) and hap1/hap4 (14.38%), hap1/hap2 (38.60%), hap4/hap4 (40.91%), hap2/hap4 (26.53%), hap2/hap5 (20.00%), respectively. The Jining Grey goat does with nine genotypes analyzed of POU1F1 gene showed no obvious difference in litter size.     

Association Between PCR-SSCP of Bone Morphogenetic Protein 15 Gene and Prolificacy in Jining Grey Goats

The Jining Grey is a prolific local goat breed in P.R. China. Bone morphogenetic protein 15 (BMP15) gene that controls high fecundity of Inverdale, Hanna, Lacaune, Belclare, Cambridge, and Small Tailed Han ewes was studied as a candidate gene for the prolificacy of Jining Grey goats. According to the sequence of ovine BMP15 gene, six pairs of primers were designed to detect single nucleotide polymorphisms in exon 1 and exon 2 of the BMP15 gene in both high fecundity breed (Jining Grey goats) and low fecundity breeds (Boer, Liaoning Cashmere, and Inner Mongolia Cashmere goats) by single strand conformation polymorphism (SSCP). Two pairs of primers (F1/R1 and F2/R2) were used to amplify the exon 1. Four pairs of primers (F3/R3, F4/R4, F5/R5, and F6/R6) were used to amplify the exon 2. Only the products amplified by primer F5/R5 displayed polymorphism. Results indicated that two genotypes (AA and AB) were detected in prolific Jining Grey goats and only one genotype (AA) was detected in low fecundity goat breeds. In Jining Grey goats frequencies of genotypes AA and AB were 0.10 and 0.90, respectively. Sequencing revealed two point mutations (G963A and G1050C) of BMP15 gene in the AB genotype in comparison to the AA genotype. In Jining Grey goats the heterozygous AB does had 1.13 (p < 0.01) kids more than the homozygous AA does. These results preliminarily showed that the BMP15 gene is either a major gene that influences the prolificacy of Jining Grey goats or a molecular genetic marker in close linkage with such a gene.     

Analysis on DNA sequence of goat RFRP gene and its possible association with average daily sunshine duration

Goat RFRP gene was cloned and its mutations were detected in thirteen goat breeds whose reproductive seasonality and litter size were different. Then sequence characteristics were analyzed and association analyses were performed to reveal the relationships between mutations of RFRP gene and average daily sunshine duration, reproductive seasonality as well as litter size in goats. A 4,862 bp DNA fragment of goat RFRP gene was obtained and the complete CDS of 591 bp encodes 196 amino acids, having high homology with that of other mammals. The protein was predicted to be a secreted protein with a signal peptide of 21 amino acids. Moreover, two mutations (A712G, T1493C) in 5' regulatory region and one mutation (A3438T) in exon 2 were detected. The test of genotype distribution in six selective goat breeds showed that there was no uniform significant association between the three polymorphisms and seasonal reproduction. The association just existed in some goat breeds for each locus. Interestingly, however, there was a strong positive correlation (r = 0.830, P = 0.003) between the G allele frequency of the A712G locus and average daily sunshine duration in ten local goat breeds, suggesting that RFRP gene has undergone a selective pressure in sunshine duration and may have indirect relationship with reproductive seasonality in goats. Additionally, no significant difference was found in litter size between genotypes in prolific Jining Grey goats.     

Relationship between MTNR1A melatonin receptor gene polymorphism and seasonal reproduction in different goat breeds

The reproductive activity of goats bred in temperate latitude follows a seasonal pattern, influenced by annual variation in day length. Daily variation in pineal melatonin secretion is the neuroendocrine signal recognized by animals through the link between this hormone and melatonin receptor 1a (MTNR1A). A total of 345 goats of different breeds (225 Sarda, 30 Saanen, 30 Chamois Coloured, 30 Maltese and 30 Nubian) with a kidding period in October-December or January-March were analysed to verify if a link exists between the structure of the receptor gene and reproductive activity. The main part of exon II of MTNR1A gene was amplified by PCR and then digested with MnlI and RsaI to prove the presence of restriction sites. Sequencing of 20 cloned samples and 20 purified samples permitted comparison with previously published sequences. No polymorphism was found using MnlI enzyme, as all 345 samples showed the cleavage site in position 605 and all the goats were MM genotype. However, using RsaI enzyme, some Sarda goats, showed a polymorphic site in position 53. Nine Sarda goats were R/r genotype, lacking this cleavage site only in one allele, while the other animals, both Sarda and the other breeds, presented the cleavage site in both the alleles and were thus R/R genotype. No r/r genotype was found in any of the breeds. In Sarda goats the allelic frequency was 0.98 for R allele and 0.02 for r allele; genotypic frequency was 96.00% for R/R genotype and 4.00% for R/r genotype. A strong link emerged from statistical analysis (P<0.001) between R/r genotype and reproductive activity, which was strongly influenced by photoperiod. Sequencing indicated six nucleotide changes that did not induce any amino acid change. Data showed that polymorphism was present and that it influences reproductive activity only in the Sarda breed.     

Polymorphisms of BMPR-IB gene and their relationship with litter size in goats

The bone morphogenetic protein receptor IB (BMPR-IB) gene was studied as a candidate gene for the prolificacy of goats. According to mRNA sequence of ovine BMPR-IB gene, ten pairs of primers were designed to detect single nucleotide polymorphisms (SNPs) of exon 1, exon 2, exon 6 to exon 10 and 3′ untranslated region (UTR) of the BMPR-IB gene in both high prolificacy breed (Jining Grey goat) and low prolificacy breeds (Wendeng Dairy and Inner Mongolia Cashmere goats) by polymerase chain reaction (PCR)-single strand conformation polymorphism (SSCP) method. Only the products amplified by primers P8 and P10 of the 3′UTR displayed polymorphisms. For primer P8, three genotypes (AA, AB and BB) were detected in Jining Grey and Wendeng Dairy goats, two genotypes (AA and AB) were in Inner Mongolia Cashmere goats. Sequencing revealed one mutation (71C→T) of the BMPR-IB gene in genotype BB compared with AA. The differences of least squares mean (LSM) for litter size between genotypes AA, AB and BB were non-significant (P > 0.05) in Jining Grey goats. For primer P10, three genotypes (CC, CD and DD) were detected in Jining Grey and Wendeng Dairy goats and one genotype (CC) in Inner Mongolia Cashmere goats. Sequencing revealed one mutation (130T→C) of the BMPR-IB gene in genotype DD compared with CC. The differences of LSM for litter size between genotypes CC, CD and DD were non-significant (P > 0.05) in Jining Grey goats. These results preliminarily showed that the detected loci of the BMPR-IB gene had no significant effect on prolificacy of Jining Grey goats.     

Analysis on DNA sequence of <Emphasis Type="Italic">GPR54</Emphasis> gene and its association with litter size in goats

The kisspeptin/GPR54 pathway is crucial in the process of puberty onset. Six pairs of primers were designed to clone goat GPR54 and scan polymorphisms and one pair of primers to detect polymorphisms of GPR54 in sexual precocious and sexual late-maturing goat breeds. A DNA fragment of 4258 bp of goat GPR54 was obtained, which contains an open reading frame (ORF) of 1137 bp and encodes 378 amino acids, having a high homology with other mammals. The protein was predicted to have seven transmembrane regions. There were no base pair variation in exons 1–4 and three base changes (G4014A, G4136A and C4152T) in exon 5 by sequencing and the three mutations may have some correlation with sexual precocity in goats. For the 4152 locus, the Jining Grey goat does with genotype TT and CT had 1.02 and 0.84 (P < 0.01) kids more than those with genotype CC, respectively. No significant difference (P > 0.05) was found in litter size between TT and CT genotypes in Jining Grey goat. For the other two loci, no significant difference (P > 0.05) was found in litter size between different genotypes in Jining Grey goats. The present study preliminarily indicated an association between allele T of the 4152 locus in GPR54 and high litter size in Jining Grey goats.     

Genetic diversity and population structure in multiple Chinese goat populations using a SNP panel

Information about genetic diversity and population structure among goat breeds is essential for genetic improvement, understanding of environmental adaptation as well as utilization and conservation of goat breeds. Here, we measured genetic diversity and population structure in multiple Chinese goat populations, namely, Nanjiang, Qinggeda, Arbas Cashmere, Jining Grey, Luoping Yellow and Guangfeng goats. A total of 193 individuals were genotyped for about 47 401 autosomal single nucleotide polymorphisms (SNPs). We found a high proportion of informative SNPs, ranging from 69.5% in the Luoping Yellow to 93.9% in the Jining Grey goat breeds with an average mean of 84.7%. Diversity, as measured by expected heterozygosity, ranged from 0.371 in Luoping Yellow to 0.405 in Jining Grey goat populations. The average estimated pair‐wise genetic differentiation (F_ST) among the populations was 8.6%, ranging from 0.2% to 16% and indicating low to moderate genetic differentiation. Principal component analysis, genetic structure and phylogenetic tree analysis revealed a clustering of six Chinese goat populations according to geographic distribution. The results from this study can contribute valuable genetic information and can properly assist with within‐breed diversity, which provides a good opportunity for sustainable utilization of and maintenance of genetic resource improvements in the Chinese goat populations.     

Analysis on DNA sequence of KiSS-1 gene and its association with litter size in goats

Three pairs of primers were designed to clone the goat KiSS-1 and scan polymorphisms and four pairs to detect polymorphisms in sexual precocious and sexual late-maturing goat breeds. A 4118 bp DNA fragment was obtained, which contains an ORF of 408 bp and encodes 135 amino acids, having a high homology with other mammals. The protein was predicted containing a signal peptide of 17 amino acids. There are two mutations (G3433A [A86T] and C3688A) in exon 3, three mutations (G296C, G454T and T505A) in intron 1 and a 18 bp deletion (?)/insertion (+) (1960–1977) in intron 2 and no mutations in exon 2. The genotype distribution didn’t show obvious difference between sexual precocious and sexual late-maturing goat breeds and no consistency within the sexual late-maturing breeds. For the 296 locus, the Jining Grey goats with genotype CC had 0.80 (P < 0.01) or 0.77 (P < 0.01) kids more than those with genotype GG or GC, respectively. No significant difference (P > 0.05) was found in litter size between GG and GC. For the 1960–1977 locus, the Jining Grey goat does with genotype ?/? had 0.77 (P < 0.01) or 0.73 (P < 0.01) kids more than those with +/+ or +/?, respectively. No significant difference (P > 0.05) was found in litter size between +/+ and +/? genotypes. For the other four loci, no significant difference (P > 0.05) was found in litter size between different genotypes in Jining Grey goats. The present study preliminarily indicated an association between allele C of the 296 locus and allele (?) of the 1960–1977 locus in KiSS-1 and high litter size in Jining Grey goats.     

Characterization of the <Emphasis Type="Italic">GHR</Emphasis> gene genetic variation in Chinese indigenous goat breeds

The aim of the present work was to investigate single nucleotide polymorphism (SNP) of growth hormone receptor (GHR) gene exon 10, characterize the genetic variation in three Chinese indigenous goat breeds, and search for its potential association with cashmere traits. In this study, a polymerase chain reaction-single strand conformation polymorphism (PCR–SSCP) protocol has been developed for rapid genotyping of the GHR gene in goats. One hundred seventy-eight goats from Liaoning Cashmere (96), Inner Mongolia White Cashmere (40), and Chengdu Grey (42) breeds in China were genotyped at GHR locus using the protocol developed. In all goat breeds investigated, a SNP in exon 10 of GHR gene has been identified by analyzing genomic DNA. The polymorphism consists of a single nucleotide substitution A → G, resulting in two alleles named, respectively, A and G based on the nucleotide at the position. The allele A was found to be more common in the animals investigated, and seems to be more consistent with cattle and zebu at this polymorphic site found in goats. The Hardy–Weinberg equilibrium of genotype distributions of GHR locus was verified in Liaoning Cashmere, and Inner Mongolia White Cashmere breeds. According to the classification of polymorphism information content (PIC), Chengdu Grey was less polymorphic than Liaoning Cashmere and Inner Mongolia White Cashmere breeds at this locus. The phylogenetic tree of different species based on the nucleotide sequences of GHR gene exon 10 is generally in agreement with the known species relationship. No significant association was found between the polymorphism revealed and the cashmere traits analyzed in present work.     

Association Between Sexual Precocity and Alleles of KISS-1 and GPR54 Genes in Goats

KISS-1 and GPR54 were regarded as key regulators for the puberty onset and fundamental gatekeepers of sexual maturation in mammals. To explore the possible association between variations in KISS-1 and GPR54 with sexual precocity, mutation screening of exon 1 of KISS-1 and exon 1, exon 3, and partial exon 5 of GPR54 was performed in a sexual precocious breed (Jining Grey goats) and sexual late-maturing breeds (Inner Mongolia Cashmere, Angora, and Boer goats) by PCR-SSCP. The results showed that five novel mutations were identified in exon 1 and partial exon 5 of GPR54 including C96 T, T173C, G176A, G825A, and C981 T. The Jining Grey goats with genotype BB or AB had 1.07 (P < 0.05) or 0.40 (P < 0.05) kids more than those with AA. The Jining Grey goats with genotype DD or CD had 1.80 (P < 0.05) or 0.55 (P < 0.05) kids more than CC, respectively. The present study preliminarily showed an association between alleles B and D of GPR54 with high litter size and sexual precocity in Jining Grey goats.     

Analysis on DNA sequence of <Emphasis Type="Italic">TSHB</Emphasis> gene and its association with reproductive seasonality in goats

Thyroid stimulating hormone beta chain (TSHB) is mainly expressed in pituitary and its expression is closely related to photoperiodic control of seasonal reproduction in animals. In the present study, ten primer pairs have been used to clone the DNA sequence and to detect genetic mutations of goat TSHB gene. Two DNA fragments of goat TSHB gene were obtained, which were 2,614 and 1,031 bp in length, respectively. They comprised about 2.5 kb 5′ regulatory region, all of the three exons and two introns. Goat TSHB gene has a coding region of 417 bp, encoding 138 amino acids which was predicted to be a secretory protein with a signal peptide of 16 amino acids. The sequence of TSHB gene is highly conserved among mammals. In addition, five mutations (C53A, 3 bp Indel at the 287–289 locus, 34 bp Indel at the 584–617 locus, A1819C and E2_72TA) were found in goat TSHB gene and they were shown to be in strong linkage disequilibrium. Interestingly, the genotype distributions for both single locus and haplotype have shown to be significant different between seasonal and nonseasonal goat breeds. And haplotype H2 and diplotype H2/H4 may be related to year-round estrus. We preliminarily presumed that the five closely linked mutations of goat TSHB gene may be part of the causal sources for the diversities of reproductive seasonality in goats. Our study may provide a possible efficient genetic way to decrease seasonality in goats.     

山羊生长激素基因5调控区的多态性分析

以鲁北白山羊、引进波尔山羊、纯繁波尔山羊以及鲁北白山羊与波尔山羊的杂交一代、回交一代共计274个个体为研究材料,用两对引物分别扩增山羊生长激素(GH)基因5^'区的26－239bp以及225－429bp片段,扩增产物经SSCP分析发现均存在多态性。在26－239bp片段上,波尔山羊及杂交后代以 AA型个体占多数,而鲁北白山羊则BB型个体较多;在225－429bp片段上,所有种群均以 CC型个体较多。对两个片段的纯合型（AA,BB;CC,DD）分别克隆测序发现：（1）26－239bp片段上AA型在第60位发生了C→T的突变,第211位发生碱基C的丢失,（2）225－429bp片段上,DD型存在3处突变,分别为264位由T→C,292位由T→A,372位由C→T。上述结果为首次实验证实山羊生长激素5^'调控区存在序列多态性。     

A new transferrin allele in Australian goats

Subdivision of TF B into two variants, B1 (faster) and B2 (slower) in Australian goat breeds was accomplished by high voltage, thin layer polyacrylamide gel electrophoresis at pH 7.9. The genes controlling the caprine transferrins were shown to be autosomal codominant alleles, TFA, TFB1, TFB2 and TFC and in the various breeds of goats, the alleles were in Hardy-Weinberg equilibrium. TFA was the most common allele in the Australian and Texan Angora, Cashmere and Dairy breeds with gene frequencies ranging from 0.652 to 0.977. TFB1 and TFB2 occurred in all four breeds while TFC was only observed in very low frequencies in Australian Angora and Cashmere breeds.     

山东地方山羊BMP15基因多态性与产羔数性状关联分析

利用PCR、克隆测序、序列拼接获得山羊(Capra hircus)BMP15基因全长。利用F-CSGE技术分析两个外显子,发现山羊BMP15编码序列的第901处发生了A→G单碱基突变,该突变使得第301位氨基酸(成熟蛋白质第32位氨基酸)由丝氨酸变为甘氨酸。利用LDR技术对济宁青山羊、鲁北白山羊和沂蒙黑山羊进行突变检测,并进行其与产羔数的关联分析。结果表明,该突变对济宁青山羊产羔数没有显著影响,但对鲁北白山羊及沂蒙黑山羊产羔数均有显著影响(P0.05)。GG型和AG型的鲁北白山羊产羔数分别比AA型多0.34只(P0.01)和0.31只(P0.01)。AG型沂蒙黑山羊的产羔数比AA型多0.13只(P0.01)。初步表明,BMP15是控制鲁北白山羊和沂蒙黑山羊多胎性状的一个主效基因或是与之存在紧密遗传连锁的分子标记。     

Polymorphism of the melatonin receptor MT1 gene and its relationship with seasonal reproductive activity in the Sarda sheep breed

The aim was to study the polymorphisms of the melatonin receptor 1A gene (MTNR1A) and its relationship with seasonal reproduction in the Sarda sheep breed. Four-thousand multiparous ewes reared under natural photoperiod were randomly chosen. Genomic DNA was extracted and subjected to PCR for the amplification of the main part of exon II of the ovine MTNR1A gene (GenBank U14109). PCR products were subjected to restriction enzymes MnlI and RsaI and placed into +/+, +/− or −/− group for MnlI and C/C, C/T or T/T group for RsaI. Samples were cloned and sequenced. The sequences were aligned with the U14109 sequence of GenBank. Data were subjected to allelic frequency analysis and to the χ² test in order to evaluate the link between genotype and reproductive activity. After MnlI digestion, allelic frequency was 0.78 for allele +and 0.22 for allele −; genotype frequency of the +/+ homozygote was 68%, 20.5% for +/− and 11.5% for −/−. After RsaI, allelic frequency was 0.66 for allele C and 0.34 for allele T; genotype frequency of the C/C homozygote was 53.5%, 26% for C/T and 20.5% for T/T. The population was in Hardy-Weinberg disequilibrium both for the MnlI and RsaI. Lambing frequency of +/+ genotype ewes was higher in the period September–December while for −/− genotype in January–April (P < 0.01). Lambing of C/C genotype ewes showed a higher frequency in September–December while for T/T genotype in January–April (P < 0.01). Results confirmed that the polymorphism of the MTNR1A locus was also present in the Sarda with a higher incidence of the +/+ and C/C genotypes. The animals that carried one of these two gene isoforms showed a not seasonal reproductive activity with the lambing period in September–December.