中国荷斯坦牛CVM的基因检测及其与产奶性状的关联分析

脊椎畸形综合征(Complex vertebral malformation, CVM)是由位于牛第3号染色体(BTA3)的SLC35A3基因外显子4的一个单碱基突变(G559T)所致。该致病基因在世界许多国家的荷斯坦牛群中都有一定的比例。文章对北京地区38头优秀种公牛进行分析, 发现了4头携带者, 进而检测了这些携带者公牛的555头女儿的基因型, 其中携带者占检测母牛数的44.0%。此外, 关联分析结果表明, 携带者母牛与非携带者母牛的生产性能之间存在显著差异(P<0.01)。携带者母牛的5个产奶性状育种值均显著高于非携带者, 泌乳持续力和体细胞评分SCS的育种值也比非携带者略高。CVM致病基因可能与BTA3上影响产奶性状的QTL或基因连锁。因此, 建议生产中对CVM携带者进行逐步淘汰     

中国荷斯坦牛白细胞黏附缺陷症PCR-RFLP检测方法的研究

本试验根据已知牛染色体上CD18编码基因序列设计引物,提取牛血液和精液DNA,可扩增出338bp的DNA片段,将PCR产物克隆到pMD18-T载体中,对阳性重组质粒进行测序,确定为牛的CD18基因。由于CD18基因的383位碱基由A变为G,而引起牛白细胞黏附缺陷症(BLAD),通过对济南市11个奶牛场356头奶牛及53头荷斯坦种公牛进行了BLAD的PCR-RFLP检测,共检出3头杂合母牛(携带者),占检测母牛群的0.84%,在荷斯坦公牛中只检测到一种基因型,没有发现隐性突变基因的携带者。     

牛脊柱畸形综合征检测方法的建立与应用

牛脊柱畸形综合征(Complex vertebral malformation, CVM)是近年来新发现的致死性牛常染色体隐性遗传缺陷病。由于编码UDP-N-乙酰葡糖胺载体的SLC35A3基因发生G→T的突变而引起本病的发生, 可引起胎牛死胎、流产、早产。为了解我国正常的荷斯坦牛(黑白花奶牛)的CVM携带和发生情况, 建立、应用创造酶切位点PCR(Created restriction site PCR, CRS-PCR)、等位基因特异性PCR(Allele-specific polymerase chain reaction, AS-PCR)检测方法检测了表型正常的436头荷斯坦母牛和93头荷斯坦公牛, 检测到3头CVM携带者, 其中杂合母牛1头, 杂合公牛2头, 携带率分别为0.60%、2.20%。此方法简便、可靠, 为奶牛CVM有害基因的分型和筛选提供了新的方法和思路, 为我国奶牛的分子选育提供了可靠的理论依据。     

牛FSHR基因第10外显子单核苷酸多态性及其与双胎性状的关系

以秦川牛和荷斯坦奶牛的双胎母牛和单胎母牛为实验材料 ,以牛的FSHR基因的第 10个外显子作为标记牛双胎性状的候选基因 ,用SNP法进行了多态检测 .结果发现 ,在秦川牛的双胎母牛中突变率 6 0 % (6 10 ) ,而在单胎母牛中突变率为 2 0 % (2 10 ) ;在荷斯坦奶牛中 ,双胎母牛突变率为31 2 5 % (5 16 ) ,单胎母牛突变率为 6 6 7% (1 15 ) ;由此可见双胎牛和单胎牛二者之间FSHR基因的第 10个外显子的突变率差异明显 .这表明 ,选择FSHR基因的第 10个外显子有可能作为双胎性状的候选基因 .序列分析发现 ,在FSHR基因的第 15 0 6位碱基发生了突变 (T→C) ,但氨基酸没有发生变化 .     

钝齿棒杆菌的代谢改造：L-鸟氨酸与L-瓜氨酸合成菌株的构建

【目的】对一株产L-精氨酸的钝齿棒杆菌(Corynebacterium crenatum)SYPA5-5进行代谢工程改造,构建L-鸟氨酸和L-瓜氨酸合成菌株,并考察其发酵生产相应氨基酸的性能。【方法】分别敲除菌株SYPA5-5鸟氨酸氨甲酰转移酶(Ornithine carbamoyltransferase,OTC)的编码基因argF和精胺琥珀酸合成酶(Argininosuccinate synthase,ASS)的编码基因argG,构建能够合成L-鸟氨酸及L-瓜氨酸的重组菌株SYPA5-5△argF和SYPA5-5△argG;考察不同营养条件对上述重组菌株生长和相应氨基酸积累的影响。【结果】添加0.3 g/L L-精氨酸可满足SYPA5-5△argF的生长及L-鸟氨酸积累所需,L-鸟氨酸产量可达21.5 g/L;添加L-精氨酸有利于SYPA5-5△argG的生长,但不利于L-瓜氨酸的积累;不添加L-精氨酸时,L-瓜氨酸产量可达15.2 g/L,同时积累6.8 g/L的L-谷氨酸。【结论】分别敲除L-精氨酸生产菌株SYPA5-5的argF及argG基因,可实现L-精氨酸合成途径的中间代谢物L-瓜氨酸和L-鸟氨酸的积累,拓展了该菌株的工业应用范围。     

荷斯坦奶牛脊柱畸形综合征的研究进展

荷斯坦奶牛脊柱畸形综合征是近年新发现的一种常染色体隐性遗传病,该病对纯合子胎儿是致死性的。当荷斯坦牛的育种核心群中携带者达到一定比例,脊柱畸形综合征就会对奶业造成巨大损失。文章综述了脊柱畸形综合征的主要症状和影响、致病基因及检测方法的研究进展以及我国潜在的荷斯坦奶牛脊柱畸形综合征携带者的状况。     

TNF-α基因多态性及其与奶牛乳房炎的相关性分析

以417头中国荷斯坦奶牛为研究对象,根据体细胞评分(Somatic cell score,SCS)的大小将该奶牛群体划分为感染牛群(100头)和健康牛群(317头)。通过PCR-RFLP和CRS-RFLP方法检测了肿瘤坏死因子α(Tumor necrosis factor-alpha,TNF-α)基因在荷斯坦奶牛群体中的多态性,并分析这些多态位点和奶牛乳房炎的相关性。研究发现了3个单核苷酸多态位点(Single-nucleotide polymorphism,SNP):第2外显子39bp处G→A的突变;第4外显子293bp处C→T的突变;5′侧翼区(5′-flanking region,5′UTR)C→G的突变。这3个突变位点分别是DraⅠ、AfaⅠ和DdeⅠ限制性内切酶的酶切多态位点,其中DraⅠ为创造酶切位点。经过基因型分析与χ2检验表明:3个酶切多态位点在荷斯坦奶牛群中均未达到Hardy-Weinberg平衡状态。运用SPSS13.0软件,采用最小二乘拟合线性模型分析3个酶切多态位点与SCS的关系,结果表明:AA基因型个体在DraⅠ酶切位点中的SCS显著大于BB及AB基因型个体(P0.05),BB基因型表现出乳房炎抗性。AfaⅠ酶切位点中BB基因型个体的SCS显著大于AA及AB基因型个体(P0.05),AA基因型表现出乳房炎抗性。DdeⅠ酶切位点中,AB基因型个体的SCS显著低于AA基因型个体(P0.05),AB基因型为优良基因型。因此BB、AA、AB基因型分别为DraⅠ、AfaⅠ、DdeⅠ酶切位点中的优良基因型,可作为分子标记应用于奶牛乳房炎抗性筛选。     

β-LG基因外显子2多态性对荷斯坦牛乳成分的影响

目的:为了研究中国荷斯坦奶牛的β-乳球蛋白(-βlactoglobulin,-βLG)基因外显子2多态现象对乳产量及成分影响。方法:本实验采用单链构象多态(PCR-SSCP)技术对中国荷斯坦奶牛-βLG基因(NCBI登录号:DQ489319)外显子2进行克隆及多态性研究。结果:8种SSCP带型:ab,abc,abcd,abd,abe,abcde,abce和abde型,带型频率分别为:0.14,0.10,0.27,0.23,0.05,0.04,0.11和0.06(P<0.05);6个单核苷酸位点:位点1 C>T,位点2 T>C,位点3 C>T,位点4 C>G,位点5 C>A,位点6 A>T或C,且它们的遗传多态信息含量处于中度或高度多态(PIC>0.25)。结论:中国荷斯坦奶牛-βLG基因外显子2区具有单核苷酸多态,单个核苷酸的改变影响奶牛的生产性能(牛乳产量、乳蛋白和脂肪含量等)。     

牛黑素皮质素受体1(MCIR)基因与毛色表型的研究

牛MC1R基因不仅与毛色有关,而且与牛乳中乳蛋白的含量有关。利用PCR-RFLP和DNA测序技术分析了中国荷斯坦黑白花牛,中国荷斯坦红白花牛,鲁西黄牛和渤海黑牛共4个品种的MC1R基因。共检测出3种等位基因(ED,E ,e)。中国荷斯坦黑白花牛主要是ED和E 等位基因(ED=0.12、E =0.80);渤海黑牛也主要是ED和E 等位基因(ED=0.52、E =0.47);中国荷斯坦红白花牛和鲁西黄牛大多为e等位基因(e=0.95)。中国荷斯坦红白花牛和鲁西黄牛还存在E /e基因型。由此推测ED和E 等位基因导致黑色素合成。另外发现牛MC1R基因编码区725处存在一重要的SNP(单核苷酸多态性)。     

荷斯坦奶牛红毛性状的基因检测及红毛形成机制的探讨

荷斯坦奶牛黑素皮质素受体1(MC1R)基因310G缺失突变产生e等位基因,导致红白花毛色。实验利用PCR-RFLP和DNA测序技术建立了荷斯坦奶牛红毛性状的基因检测方法,并在4个荷斯坦奶牛全同胞家系中得到了证实,可见其可用于鉴定携带e等位基因的种公牛,以指导奶牛育种。通过分析黑素皮质素(MC)受体蛋白家族序列,找到了MC1R蛋白结构与功能的区域(TM3、TM6、TM7和EL3)。利用VHMPT软件预测MC1R突变蛋白的结构,结果显示其丢失了TM3、TM6、TM7和EL3区,也失去了与α-促黑素(α-MSH)结合的区域,最终导致红毛的产生。     

Identification of complex vertebral malformation carriers in Holstein cattle in south China

Complex vertebral malformation (CVM) is a recently described monogenic autosomal recessive hereditary defect of Holstein dairy cattle that causes premature birth, aborted fetuses and stillborn calves. Guanine is substituted by thymine (G>T) in the solute carrier family 35 member A3 gene (SLC35A3). A valine is changed to a phenylalanine at position 180 of uridine 5'-diphosphate-N-acetyl-glucosamine transporter protein. CVM is expected to occur in many countries due to the widespread use of sire semen. We developed a created restriction site PCR (CRS-PCR) method to diagnose CVM in dairy cows. This was tested on 217 cows and 125 bulls selected randomly from a Holstein cattle population in south China. Five Holstein cows and five Holstein bulls were identified to be CVM carriers; the percentages of CVM carriers were estimated to be 2.3, 4.0 and 2.9% in the cows, bulls and entire Holstein cattle sample, respectively.     

Effects of Complex Vertebral Malformation on Fertility in Swedish Holstein Cattle

Complex vertebral malformation (CVM) is an autosomal recessive inherited defect in the Holstein breed. It causes intra-uterine mortality through the entire gestation period leading to repeat breeding and involuntary culling of cows and thereby economic losses. The defect was first reported in Denmark in 1999 and a direct DNA test for the defect has been available since February 2001. The aim of this study was to investigate if Holstein bulls heterozygous for the CVM gene had reduced reproductive performance, measured as non-return rate (NRR) and in a daughter fertility index. All genotyped Swedish Holstein bulls born between 1995 and 1999 were included. Altogether 228 bulls were analysed, of which 53 bulls, i.e. 23%, were confirmed CVM carriers. A statistically significant difference between carriers and non-carriers in the relative breeding value for NRR was observed for 168 days NRR (101.1 ± 0.9 vs. 103.1 ± 0.6, p < 0.05). There was no difference for 28 days NRR whereas the difference approached significance for 56 days NRR. No significant effect of the paternal CVM genotype on the daughter fertility index was shown probably due to the complexity of traits this index is composed of. In conclusion, the study showed that carriers of the CVM defect have an inferior NRR compared with non-carriers.     

Identification of bovine leucocyte adhesion deficiency (BLAD) carriers in Holstein and Brown Swiss AI bulls in Iran

BLAD is a hereditary disease in Holstein dairy cattle. The defective allele of CD18 gene which is responsible for this disease has a recessive inheritance. The recessive homozygous form (BL/BL) is lethal and since carrier animals have viability, BLAD frequency increases by use of carrier bulls in Artificial Insemination (AI). BLAD carriers can be detected easily by means of polymerase chain reaction followed by restriction analysis of the amplicons. In this study DNA samples from Holstein (n = 30) and Brown Swiss (n = 10) bulls from Abbas Abad AI center (Khorasan state of Iran) were analysed. A 101 bp fragment from the polymorphic region of CD18 gene located on chromosome 1 was amplified by PCR. Restriction enzymes TaqI and HaeIII were used to identify genotypes. Digestion products were screened by electrophoresis on 8% non-denaturing polyacrylamide gel and visualized by ethidium bromide staining. Frequencies of BL/TL (carrier) genotypes in Holstein and Brown Swiss bulls were 3.33% and 0%, respectively. Our pedigree studies of the carrier bull in this experiment revealed that the mutation inherited to him from Hawkeye bull (CANM 369995, BL). Although the elimination of BLAD-carrier bulls from the Holstein world would be the most efficient method to control this genetic disorder, many BLAD-carrier bulls are still listed commercially for AI and BLAD is still occurring in Iran. Monitoring the prevalence of BLAD-carriers in random selected herds may be helpful in judging the effectiveness of the BLAD-control program.     

No incidence of DUMPS carriers in Polish dairy cattle

DUMPS (Deficiency of Uridine Monophosphate Synthase) is a hereditary recessive disorder in Holstein cattle causing early embryo mortality during its implantation in the uterus. The only way to avoid the economic losses is early detection of DUMPS carriers. Because American Holstein semen has been intensively imported to Poland since 1970, there was a risk that DUMPS could have spread in Polish dairy cattle. In our study, 2209 dairy cattle of the Polish Holstein breed have been screened by the DNA test. The dominant group was young bulls entering the testing program (1171) and proven bulls (781). They represented all sires entering Polish breeding programs between 1999 and 2003. Also, 257 sire dams were included in the screening program. No DUMPS carrier has been found. Our results then indicate that the population of dairy cattle reared in Poland is free from DUMPS. Because of the economical significance of the DUMPS mutation and its recessive mode of inheritance, attention has to be paid to any case of a bull having in his origin any known DUMPS carrier. Such a bull should be tested and if positive eliminated from the active population. Also, young bulls (testing bulls) should be screened for DUMPS if in their progeny a high incidence of embryo mortality is observed and their genealogy cannot exclude their relatedness to any DUMPS carriers.     

Identification of Bovine Leucocyte Adhesion Deficiency (BLAD) Carriers in Holstein and Brown Swiss AI Bulls in Iran

BLAD is a hereditary disease in Holstein dairy cattle. The defective allele of CD18 gene, which is responsible for this disease, has recessive inheritance. The recessive homozygous form (BL/BL) is lethal and since carrier animals have viability, BLAD frequency increases by use of carrier bulls in Artificial Insemination (AI). BLAD carriers can be detected easily by means of polymerase chain reaction followed by restriction analysis of the amplicons. In this study DNA samples from Holstein (n = 30) and Brown Swiss (n = 10) bulls from Abbas Abad AI center (Khorasan state of Iran) were analysed. A 101-bp fragment from the polymorphic region of CD18 gene located on chromosome 1 was amplified by PCR. Restriction enzymes TaqI and HaeIII were used to identify genotypes. Digestion products were screened by electrophoresis on 8% non-denaturing polyacrylamide gel and visualized by ethidium bromide staining. Frequencies of BL/TL (carrier) genotypes in Holstein and Brown Swiss bulls were 3.33% and 0%, respectively. Our pedigree studies of the carrier bull in this experiment revealed that the mutation was inherited by him from Hawkeye bull (CANM 369995, BL). Although the elimination of BLAD-carrier bulls from the Holstein world would be the most efficient method to control this genetic disorder, many BLAD-carrier bulls are still listed commercially for AI, and BLAD is still occurring in Iran. Monitoring the prevalence of BLAD carriers in random selected herds may be helpful in judging the effectiveness of the BLAD-control program.     

Influence of sire and sire breed (Gyr versus Holstein) on establishment of pregnancy and embryonic loss in lactating Holstein cows during summer heat stress

Heat stress has negative effects on pregnancy rates of lactating dairy cattle. There are genetic differences in tolerance to heat stress; Bos taurus indicus (B. t. indicus) cattle and embryos are more thermotolerant than Bos taurus taurus (B. t. taurus). In the present study, the effects of sire and sire breed on conception and embryonic/fetal loss rates of lactating Holstein cows during the Brazilian summer were determined. In Experiment 1, cows (n=302) were AI after estrus detection or at a fixed-time with semen from one Gyr (B. t. indicus) or one Holstein sire (B. t. taurus). Pregnancy was diagnosed 80 days after AI. In Experiment 2, cows (n=811) were AI with semen from three Gyr and two Holstein sires. Pregnancy was diagnosed at 30-40 and at 60-80 days after AI. Cows diagnosed pregnant at the first examination but non-pregnant at the second were considered as having lost their embryo or fetus. Data were analyzed by logistic regression. The model considered the effect of sire within breed, sire breed, days postpartum, period of lactation, and AI type (AI after estrus versus fixed-time). There was no effect of the AI type, days postpartum or milk production on conception or embryonic loss rates. The use of Gyr bulls increased pregnancy rate when compared to Holstein bulls [9.1% (60/657) versus 5.0% (23/456), respectively, P=0.008; data from Experiments 1 and 2 combined]. Additionally, in Experiment 2, cows inseminated using semen from sire #4 (Gyr) had lower embryonic loss (10%) when compared with other B. t. indicus (35.3% and 40%) or B. t. taurus sires (18.2% and 38.5%, P=0.03). In conclusion, the use of B. t. indicus sires may result in higher conception rates in lactating Holstein cows during summer heat stress. Moreover, sire can affect embryonic loss and selection of bulls according to this criterion may result in higher parturition rates in lactating Holstein cows.     

Identification of a doublet missense substitution in the bovine LRP4 gene as a candidate causal mutation for syndactyly in Holstein cattle

Syndactyly in Holstein cattle is an autosomal recessive abnormality characterized by the fusion of the functional digits. This disorder has been previously mapped to the telomeric part of bovine chromosome 15. Here, we describe the fine-mapping of syndactyly in Holstein cattle to a 3.5-Mb critical interval using a comparative mapping approach and an extended pedigree generated by embryo transfer. We report genetic evidence for the exclusion of two genes previously suggested as candidates (EXT2 and ALX4) and describe the identification of a doublet mutation in complete linkage disequilibrium with syndactyly in one gene of the critical interval: LRP4. Finally, based on recent discoveries concerning the mouse mutants dan and mdig and a mouse knockout for Lrp4, we present solid evidence that the subsequent substitution in LRP4 exon 33 is a strong candidate causal mutation for syndactyly in Holstein cattle.