奶牛热应激的营养和代谢调控及耐热性分子标记的初选
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摘要
热应激对奶牛的生产性能和繁殖性能有极大的负面影响。本研究从营养和代谢调控两方面探索缓解奶牛的热应激的途径,同时利用RAPD技术筛选奶牛的耐热性分子标记。
1.试验一饲喂高能饲料对热应激条件下奶牛的生产性能和生理生化指标的影响及其机理的探究。选择33头处于热应激期泌乳中期的荷斯坦奶牛,随机分为对照组和处理Ⅰ、Ⅱ。处理Ⅰ、Ⅱ饲喂不同的高能饲料,分别为烘烤大豆和油菜籽,对照组为常规饲料。结果表明:处理Ⅰ试验期的产奶量比对照组高3.27%(P<0.05),处理Ⅰ、Ⅱ试验期产奶量比试验前分别提高了2.21%和7.31%,而对照组则略有下降;不同处理间的直肠温度相近,但处理Ⅰ组呼吸频率极显著高于对照组(P<0.01),两处理组的心跳次数显著高于对照组(P<0.05)。与对照组相比,处理组Ⅰ和Ⅱ的过氧化氢酶(CAT)、丙二醛(MDA)和K+的含量显著提高(P<0.05),血清总蛋白(TP)、Cl-含量显著降低(P<0.05)。处理组Ⅰ的血清尿素氮(BUN)含量显著高于对照组(P<0.05);处理组Ⅱ的皮质醇(Cor)显著高于对照组(P<0.05)。处理组Ⅰ和Ⅱ的T3、白细胞介素(IL-2)、免疫球蛋白(IgG)、超氧化物岐化酶(SOD)和胰岛素(INS)的分泌量有增加的趋势(P>0.05),而催乳激素(PRL)、肌酸激酶(CK)和Na+分泌量有下降的趋势(P>0.05)。处理组Ⅰ的T4和乳酸脱氢酶(LDH)的含量有升高的趋势(P>0.05),而处理组Ⅱ呈降低的趋势(P>0.05)。
2.试验二添加复合添加剂对热应激条件下奶牛的生产性能和生理生化指标的影响及其作用机理。选择22头处于泌乳中期的荷斯坦奶牛,随机分为对照组和处理组。处理组添加复合添加剂,对照组为常规日粮。结果表明:使用复合添加剂饲料后,处理组试验期的产奶量比对照组提高1.52%(P<0.05),对照组试验期产奶量比试验前下降16.36%,而试验组提高了1.45%;使用复合添加剂除乳脂率有明显的降低外(P<0.05),对其它乳成分基本没有影响;与对照组比较,试验组的直肠温度显著降低(P<0.05),呼吸频率显著升高(P<0.05)。与对照组比较,处理组的T3、Cor、INS、IL-2、TP、CK、SOD和LgG都有升高的趋势(P>0.05),而T4和Cl-显著升高(P<0.05)。处理组和对照组相比,PRL、LDH、MDA、K+和Na+的含量都有下降的趋势(P>0.05);而CAT显著下降(P<0.05)。BUN的含量两处理组间没有明显变化(P>0.05)。
3.试验三用RAPD技术筛选奶牛的耐热性分子标记。以日均产奶量为标准从处于热应激期的52头奶牛中选出22头奶牛(12头为耐热性优良奶牛,10头为非耐热奶牛)为试验动物,通过RAPD技术进行耐热分子标记的筛选。研究不同酶和反应循环数对RAPD反应的影响,建立了一套适合本试验最佳的反应体系。对170条S系列随机引物进行了PCR-RAPD扩增反应,具有多态性的引物26条,筛选出稳定性好、带型清晰的引物3条。结合奶牛的生理生化指标,发现有两条引物S275和S2011的扩增效果与某些生理生化指标存在显著相关:S275和$2011的差异片段与产奶量(P<0.01)、T4(P<0.05)呈负相关,与乳脂率呈中度的正相关(P<0.05),其中S275的差异片段还与乳蛋白率(P<0.05)、CK(P<0.05)显著正相关,与钾离子含量呈显著负相关(P<0.05),S2011的差异片段与钠离子含量显著负相关(P<0.05)。对两条引物特异性片段测序结果的BLAST分析发现,引物S2011特异性条带在牛第4号染色体上二肽基肽酶Ⅵ下游32Kb处;引物S275测序结果有两个序列,其中序列Ⅰ在MHCⅠ类样基因家族A1基因下游的0.7Kp,ULBP27上游和下游的1.6Kb等基因调控区附近均有分布,而序列Ⅱ位于牛的3号染色体上的NOL1/NOP2/Sun domain family, member 4.通过BLAST结果可以初步推测引物S2011和S275可以作为筛选奶牛耐热性状的分子标记。
本研究通过添加烘烤大豆和油菜籽研究高能饲料对奶牛生产性能和生理生化指标的影响,探讨一种用于缓解奶牛热应激的新型能量饲料的机理:论文还从多种抗热应激添加剂复合效果方面入手,进一步探讨缓解奶牛热应激的新途径;同时利用RAPD技术筛选出与耐热性能有关的分子标记,并结合奶牛的生理生化指标进行分析,确定了其可行性。
Heat-stress has a huge negative effect on production and reproduction performance of dairy cattle. Explore to ease the heat-stress through the aspects of nutrition and metabolism, while RAPD technology was used to select heat resistance molecular markers on dairy cattle.
1.The experiment 1 was conducted to study the effects and mechanism of high energy feed on biochemical physiologic indices and production performance under heat-stress. Thirty three lactating cows were used in the experiment and divided into three groups randomly with 11 cows in each group. The cows in control group were fed with basic diets, the treatmentⅠwas supplemented with roast soybean, and treatmentⅡwas supplemented with rapeseed. The results showed that the milk yield of treatmentⅠhad significant (P<0.05) increase of 3.27% compared with control, milk yield of treatmentⅠandⅡboth increased by 2.21% and 7.31% respectively compared with previous. However, the control group had slight declining. The breath frequency of treatmentfⅠhad significantly (P<0.05) increased compared with that of the control group, and the two treatments had significant higher heartbeat times (P<0.05) compared with control.Both of treatedⅠandⅡhad an significant (P<0.05) increase in the contents of CAT,MDA and K+, but an significant decrease in contents of TP and Cl- compare with the control. TreatedⅠsignificantly(P<0.05)increased the BUN content. Cortical increased significantly (P<0.05) in the treatmentⅡas compared with control.
2.The experiment 2 was conducted to study the effect of complex additive on milk performance and biochemical physiology parameter of cows under heat-stress and its mechanism. Twenty two lactating cows were divided randomly two groups with 11 cows in every group. The cows in control group were fed with basic diets; the treatment was supplemented with complex additive. The results showed that the milk yield of control had decreased 16.36% compare with before experiment, however, that of treatment had increased 1.45%. The complex additive had no effect on the milk composition, except fat content with significant decrease(P<0.05); The recta temperature of treatment had significantly (P<0.05) decreased,and the breath frequency had significantly (P<0.05) increased compare with control. Compared with the control,T3、Cor、INS、IL-2、TP、CK、SOD and LgG trended to increase(P>0.05), however, the content of T4 and cl- had an significant (P<0.05) increase. Compared with the control group, the content of PRL、LDH、MDA、K+ and Na+ trended to decrease (P>0.05), but the content of CAT had an significant (P<0.05) decrease.
3.In this study,22 cows were selected from 52 cows based on average daily milk yield under heat-stress. Then select dairy heat-resistance molecular markers using RAPD. The effects of different enzyme and cycles on RAPD were analyzed. An optimization RAPD system was foud.26 primers with better effect were selected in 170 random primers using PCR-RAPD.Considered the detected result of biochemical and physiology parameters, two molecular markers relative to heat-tolerance in Holstein Cattle were selected finally. There were significantly positive correlations (P<0.05)between milk fat percentage and different fragments of primer S275 and S2011; the content of K+ and milk protein rate (P<0.05)with different fragment of primer S275 was a significantly negative correlations;T3、T4 (P<0.05)and milk yield (P<0.01)with different fragment of primer S275 and S2011 were a significant negative correlations; the content of CK with different fragment of primer S275 was a significantly positive correlations(P<0.05);There were a significantly negative correlations (P<0.05)between Na+ and different fragment of primer S2011.Analysis of sequencing results of specific fragment using BLAST, there were specific bands of primer S2011 at Dipeptidy-peptidase 6 downstream of 32Kb of Bos taurus chromosome 4 genomic. There were two Sequence in sequencing results of primer S275, one sequence was on MHC Class I-like Family Al downstream of 0.7Kb, and ULBP27 upstream of 10Kb; however, another sequence on NOL1/NOP2/Sun Domain Family of Bos taurus chromosome 4 genomic. It was suggested that primers S2011 and S275 could be used as molecular markers in filtration heat-resistant traits of dairy cattle from the result of BLAST.
This study was conducted to study the effects and mechanism of high energy feed and complex additive on biochemical physiologic indices and production performance under heat-stress. It was suggested that two molecular markers were screened in heat-resistant using RAPD technology combined with physiological and biochemical indicators of dairy.
1.试验一饲喂高能饲料对热应激条件下奶牛的生产性能和生理生化指标的影响及其机理的探究。选择33头处于热应激期泌乳中期的荷斯坦奶牛,随机分为对照组和处理Ⅰ、Ⅱ。处理Ⅰ、Ⅱ饲喂不同的高能饲料,分别为烘烤大豆和油菜籽,对照组为常规饲料。结果表明:处理Ⅰ试验期的产奶量比对照组高3.27%(P<0.05),处理Ⅰ、Ⅱ试验期产奶量比试验前分别提高了2.21%和7.31%,而对照组则略有下降;不同处理间的直肠温度相近,但处理Ⅰ组呼吸频率极显著高于对照组(P<0.01),两处理组的心跳次数显著高于对照组(P<0.05)。与对照组相比,处理组Ⅰ和Ⅱ的过氧化氢酶(CAT)、丙二醛(MDA)和K+的含量显著提高(P<0.05),血清总蛋白(TP)、Cl-含量显著降低(P<0.05)。处理组Ⅰ的血清尿素氮(BUN)含量显著高于对照组(P<0.05);处理组Ⅱ的皮质醇(Cor)显著高于对照组(P<0.05)。处理组Ⅰ和Ⅱ的T3、白细胞介素(IL-2)、免疫球蛋白(IgG)、超氧化物岐化酶(SOD)和胰岛素(INS)的分泌量有增加的趋势(P>0.05),而催乳激素(PRL)、肌酸激酶(CK)和Na+分泌量有下降的趋势(P>0.05)。处理组Ⅰ的T4和乳酸脱氢酶(LDH)的含量有升高的趋势(P>0.05),而处理组Ⅱ呈降低的趋势(P>0.05)。
2.试验二添加复合添加剂对热应激条件下奶牛的生产性能和生理生化指标的影响及其作用机理。选择22头处于泌乳中期的荷斯坦奶牛,随机分为对照组和处理组。处理组添加复合添加剂,对照组为常规日粮。结果表明:使用复合添加剂饲料后,处理组试验期的产奶量比对照组提高1.52%(P<0.05),对照组试验期产奶量比试验前下降16.36%,而试验组提高了1.45%;使用复合添加剂除乳脂率有明显的降低外(P<0.05),对其它乳成分基本没有影响;与对照组比较,试验组的直肠温度显著降低(P<0.05),呼吸频率显著升高(P<0.05)。与对照组比较,处理组的T3、Cor、INS、IL-2、TP、CK、SOD和LgG都有升高的趋势(P>0.05),而T4和Cl-显著升高(P<0.05)。处理组和对照组相比,PRL、LDH、MDA、K+和Na+的含量都有下降的趋势(P>0.05);而CAT显著下降(P<0.05)。BUN的含量两处理组间没有明显变化(P>0.05)。
3.试验三用RAPD技术筛选奶牛的耐热性分子标记。以日均产奶量为标准从处于热应激期的52头奶牛中选出22头奶牛(12头为耐热性优良奶牛,10头为非耐热奶牛)为试验动物,通过RAPD技术进行耐热分子标记的筛选。研究不同酶和反应循环数对RAPD反应的影响,建立了一套适合本试验最佳的反应体系。对170条S系列随机引物进行了PCR-RAPD扩增反应,具有多态性的引物26条,筛选出稳定性好、带型清晰的引物3条。结合奶牛的生理生化指标,发现有两条引物S275和S2011的扩增效果与某些生理生化指标存在显著相关:S275和$2011的差异片段与产奶量(P<0.01)、T4(P<0.05)呈负相关,与乳脂率呈中度的正相关(P<0.05),其中S275的差异片段还与乳蛋白率(P<0.05)、CK(P<0.05)显著正相关,与钾离子含量呈显著负相关(P<0.05),S2011的差异片段与钠离子含量显著负相关(P<0.05)。对两条引物特异性片段测序结果的BLAST分析发现,引物S2011特异性条带在牛第4号染色体上二肽基肽酶Ⅵ下游32Kb处;引物S275测序结果有两个序列,其中序列Ⅰ在MHCⅠ类样基因家族A1基因下游的0.7Kp,ULBP27上游和下游的1.6Kb等基因调控区附近均有分布,而序列Ⅱ位于牛的3号染色体上的NOL1/NOP2/Sun domain family, member 4.通过BLAST结果可以初步推测引物S2011和S275可以作为筛选奶牛耐热性状的分子标记。
本研究通过添加烘烤大豆和油菜籽研究高能饲料对奶牛生产性能和生理生化指标的影响,探讨一种用于缓解奶牛热应激的新型能量饲料的机理:论文还从多种抗热应激添加剂复合效果方面入手,进一步探讨缓解奶牛热应激的新途径;同时利用RAPD技术筛选出与耐热性能有关的分子标记,并结合奶牛的生理生化指标进行分析,确定了其可行性。
Heat-stress has a huge negative effect on production and reproduction performance of dairy cattle. Explore to ease the heat-stress through the aspects of nutrition and metabolism, while RAPD technology was used to select heat resistance molecular markers on dairy cattle.
1.The experiment 1 was conducted to study the effects and mechanism of high energy feed on biochemical physiologic indices and production performance under heat-stress. Thirty three lactating cows were used in the experiment and divided into three groups randomly with 11 cows in each group. The cows in control group were fed with basic diets, the treatmentⅠwas supplemented with roast soybean, and treatmentⅡwas supplemented with rapeseed. The results showed that the milk yield of treatmentⅠhad significant (P<0.05) increase of 3.27% compared with control, milk yield of treatmentⅠandⅡboth increased by 2.21% and 7.31% respectively compared with previous. However, the control group had slight declining. The breath frequency of treatmentfⅠhad significantly (P<0.05) increased compared with that of the control group, and the two treatments had significant higher heartbeat times (P<0.05) compared with control.Both of treatedⅠandⅡhad an significant (P<0.05) increase in the contents of CAT,MDA and K+, but an significant decrease in contents of TP and Cl- compare with the control. TreatedⅠsignificantly(P<0.05)increased the BUN content. Cortical increased significantly (P<0.05) in the treatmentⅡas compared with control.
2.The experiment 2 was conducted to study the effect of complex additive on milk performance and biochemical physiology parameter of cows under heat-stress and its mechanism. Twenty two lactating cows were divided randomly two groups with 11 cows in every group. The cows in control group were fed with basic diets; the treatment was supplemented with complex additive. The results showed that the milk yield of control had decreased 16.36% compare with before experiment, however, that of treatment had increased 1.45%. The complex additive had no effect on the milk composition, except fat content with significant decrease(P<0.05); The recta temperature of treatment had significantly (P<0.05) decreased,and the breath frequency had significantly (P<0.05) increased compare with control. Compared with the control,T3、Cor、INS、IL-2、TP、CK、SOD and LgG trended to increase(P>0.05), however, the content of T4 and cl- had an significant (P<0.05) increase. Compared with the control group, the content of PRL、LDH、MDA、K+ and Na+ trended to decrease (P>0.05), but the content of CAT had an significant (P<0.05) decrease.
3.In this study,22 cows were selected from 52 cows based on average daily milk yield under heat-stress. Then select dairy heat-resistance molecular markers using RAPD. The effects of different enzyme and cycles on RAPD were analyzed. An optimization RAPD system was foud.26 primers with better effect were selected in 170 random primers using PCR-RAPD.Considered the detected result of biochemical and physiology parameters, two molecular markers relative to heat-tolerance in Holstein Cattle were selected finally. There were significantly positive correlations (P<0.05)between milk fat percentage and different fragments of primer S275 and S2011; the content of K+ and milk protein rate (P<0.05)with different fragment of primer S275 was a significantly negative correlations;T3、T4 (P<0.05)and milk yield (P<0.01)with different fragment of primer S275 and S2011 were a significant negative correlations; the content of CK with different fragment of primer S275 was a significantly positive correlations(P<0.05);There were a significantly negative correlations (P<0.05)between Na+ and different fragment of primer S2011.Analysis of sequencing results of specific fragment using BLAST, there were specific bands of primer S2011 at Dipeptidy-peptidase 6 downstream of 32Kb of Bos taurus chromosome 4 genomic. There were two Sequence in sequencing results of primer S275, one sequence was on MHC Class I-like Family Al downstream of 0.7Kb, and ULBP27 upstream of 10Kb; however, another sequence on NOL1/NOP2/Sun Domain Family of Bos taurus chromosome 4 genomic. It was suggested that primers S2011 and S275 could be used as molecular markers in filtration heat-resistant traits of dairy cattle from the result of BLAST.
This study was conducted to study the effects and mechanism of high energy feed and complex additive on biochemical physiologic indices and production performance under heat-stress. It was suggested that two molecular markers were screened in heat-resistant using RAPD technology combined with physiological and biochemical indicators of dairy.
引文
[1]Selye.H.Studies on adaption. Endocrinology[M].1937,21:169-188.
[2]Selye.H.The Stress of Life[M].McGraw Hill,New York,1956:205-236.
[3]Bohus.B,KoolhaasJ.M.,Nyakas.C,Stefens A.B,fokkemaD.S.and ScA.J.W. Neuroendocrine states and behavioral and physiological stress responses[J].Progress in brain research,1987,72:57-70.
[4]Ewbank.R.Stress:a general overview.In:Farm Animal and the Environ Clive Phillips, D.Piggins[J].C.A.B.International,1992.pp.255-262.
[5]Siegel H.S.Stress.strain and resistance[J].British Poultry Sci 1995.3.
[6]赖登明,夏冬,李如治.红细胞钾含量对奶牛耐热性的影响[J].中国奶牛,1997,(2):13-14.
[7]West.J W,. Mullinix B G, Bernard J K. Effects of hot, humid weather on milk temperature, dry mater intake, and milk yield of lactating dairy cows[J].J Dairy Sci.2003,86:232-242.
[8]张国高.高温生理与卫生.科学技术出版社,1988.
[9]穆玉云.乳牛耐热性指标的检测.安徽农业大学学报,1993,20(1):66-71.
[10]李建国,桑润滋,张正姗等.热应激对奶牛生理常值、血液生化指标、繁殖及泌乳性[J].河北农业大学学报,1998,21(4):692-673.
[11]Kabayashi K.Thermoregulation during rest and exersice in different postures in a hot humid environment[J].Appl.Physiol.1980,48:999-1007.
[12]McDowell R E.Improvement of live stock production in warm climates[C].A Series of Books in Agricultural Science,1972
[13]Sanchez W K, M A Mcguire,et al.Macromineralnu ration by heat stress interactions in dairy catle:Review and original research[J].J Dairy Sci.,1994,77:2051-2079.
[14]Belay T,C J Wiemusz,et al.Mineral balance and urinary and fecal mineral excretion
profile of broilers housed in the rmoneutral and heat distressed environments [J].Poult. Sci,1992,71:1043.
[15]Collier R J, Beed D K,et al.Influences of environment and its modification no dairy animal health and production[J].J.D airy Sci,1982,65:2213.
[16]Fuquay J W.Heats tred dasit affects animal production[J].J.D airy Sci.,1981,52:164.
[17]Cuningham MD,et al.Effect of drink water temperature upon ruminant digestion, intraruminal temperature and water consumption of nonlacting dairy cows[J].J.Dairy Sci.19 64,47:382-385.
[18]Sevi A,Rotunno T, DiRoberto C, Muscio A.Fatty acid composition of ewe milk as affected by Solar radiation and high ambient temperature[J].J.Dairy Res,2002,69(2):181-94.
[19]Westra H D.Effect of Environmenton Nutrient Requirements of Domestic Animals[J].J.A nim.Sci 1999,85:13-21.
[20]史彬林,闫素梅.奶牛耐热评定指标的研究[J].中国奶牛,1996,(2):20-22.
[21]Alvarez M B,Johnson H D.Environmental heat exposure on cattle plasma catecholamine and Glucocorticoids [J].J.Anim.sci,1973,36:369.
[22]West J W, Mullinix B G,Bernard J K. Effects of hot, humid weather on milk temperature,dry mater intak,and milk yield of lactating dairy cows[J].J Dairy Sci,2003,86:232-242.
[23]DuPreez JH.Parameters for the determination and evaluation of heat stress in dairy cattle in South Africa On derstepoort[J].VetRes.2000.67 (4):263-71.
[24]王前,林玲,林继生等.气候因子与荷斯坦奶牛产奶量的关系研究[J].广州奶牛,2003,(1):1-3.
[25]李如治.奶牛热应激研究现状[J].中国奶牛,1995:38-40.
[26]马胜龙,冯定远.动物热应激机理及其研究进展[J].广东饲料,2000,(4):20-23.
[27]Suchanek B,Gajdvsek S.Compostition of milk form cow herds with high milk efficiency[J].Nas Chov.1989,49(10):454.
[28]KriventsonYu M. et al.Production,chemical composition and technological properties of milk of Black Pied cows of different geno Vestnik sel skokhozyaistvennol nauki(moskva)[J].J Dairy Sci,1991,8:100.
[29]Moore R et al. Feeets of late gestation heats tress on post partum milk production and re production in dairy cattle [J].J Dairy Sci,1992,75:1877.
[30]Wolfenson D, Roth Z, Meidan R A Impaired reproduction in heat-stressed cattle:basic and applied aspects[J].Anim Reprod Sci,2000 60:535-47.
[31]姜礼胜,林映才,蒋宗勇.肉鸡饮服“必补-18”的抗应激效果研究(Ⅱ)[J].畜牧与兽医,1997,29(5):197-200.
[32]Wolfenson D, Roth Z, Meidan R. Ampaired reproduction in heat-stressed cattle:basic and applied aspects[J].Anim Reprod Sci.2000,60-61:535-47.
[33]Tarazon-Herrera M, Huber JT, Santos J. Effects of bovine somatotropin and evaporative cooling pluss hade on lactation performance of cows during summer heat stress [J].J Dairy Sci.1999,82 (11):2352-7.
[34]Siegel R A, Feldman S,Conforti N,Ben-David M,Chowers I. PRL and ACTH secretion fo llowing acute heat exposure, in intact and in hypothalamic deaferentated male rats.Brain [J]. Res.1979.178(2-3):459-466.
[35]May JD, Deaton JW, Reece FN, Branton SL. Effect of acclimation and heat stress on thyroidhormone concentration [J].Poult Sci.1986.65(6):1211.
[36]Bobek S,Sechman A,Wieczorek E.Reverse3,3',5'-triiodothyronine(rT3)enhances hyperglycemic and lipemic effects of heat-stress in chickens[J].Horm Metab Res.19 97.29(5):252-4.
[37]Magdub A, Johnson HD, Belyea RL. Effect of environmental heat and dietary fiber on thyroid physiology of lactating cows[J].JDairy S ci.1982.65(12):2323-31.
[38]Hurley L. Bovine prolactin,TSH,T4 and T3 Concentrations as affected by Tall Fescue Summer Toxicosis and Temperature[J].JA nmi.Sci.1981.55(2):374.
[39]Khurann M L,Madan M L. Thyroxine Secretion Rate in Buffaloes During Hot Dry, Hot Humid and Cold Seasons[M].First World Bufalo Congress, Cairo.1985:1165.
[40]McNabbl Roussel,J D Gomila. Relationships of certain blood serum parameters with enviromental temperatures and milk yield[J].J.Dairy Sci,1974,57:141-156.
[41]Aberle E D, Merkel R A, et al.P htsiological responses of stress susceptible and stress resistant pigs to heat stress[J].J.Anim.Sci,1974,38:954-967.
[42]Olbrich.S E, Martz FA. et al. Semen quality and behabvior of Holstein bulls exposed to estracliol-treated bulls for mounts[J].J.Dairy Sci,1971,54:793-805.
[43]Siegel, H. S.and Lamtimer, J. W. Interaction of high temperature and salmonella pullomm antigen concentration on serum agglutinin and corticoseroid response in WhiteRock chickens[J].Poultry Sci,1984,6 3:2483-2491.
[44]Freeman, B.M.The domestic fowl in biomedical research:physiological effect of environment[J].J World's Poultry Sci,1988,44:41-60.
[45]Cross, W.B.Siegel, P B.Effect of social stress and steroids on antibody production[J].Avian Disease,1973,17:807-815.
[46]Kelley R.V. et al.Effect of environmental temperature on ruminants VTA levels with controlled feed intake[J].J Dairy Sci,1965,50:531-534.
[47]McDowell R. E, Moody E. G, Van Soest P. J,.Lehmann R. P, Ford G. L.Effect of Heat Stress on Energy and Water Utilization of Lactating Cows[J].J Dairy Sci,1969,52 (2): 188-194.
[48]刘艳琴,高洁,高玉红,江富华,李建国.炎热夏季奶牛日粮中添加脂肪酸钙对热应激影响的研究[J].草食家畜,1999,(4):37-39.
[49]陈杰,任明强,孟军.日粮中添加乙酸钠对夏季奶牛生理状况和泌乳性能的影响[J].中国畜牧杂志.1989,25(3):3-4.
[50]韩继福,吴其宏.过瘤胃氨基酸对乳牛瘤胃发酵、产乳量及乳成分的影响[J].安徽农业大学学报,2003,30(2):139-143.
[51]Huber J. T, Higginbotham G, Gomez-Alarcon R. A,Taylor R. B,Chen K. H, Chan S.C, Wu Z.Heat Stress Interactions with Protein Supplemental Fat, and Fungal Cultures [J].J Dairy Sci,1994,77 (7):2080-2090.
[52]LD Muller, AJ Heinrichs, JB Cooper, YH Atkin.Supplemental Niacin for Lactating Cows During Summer Feeding[J].J Dairy Sci,1986,69(5):1416-1420.
[53]黄美音.奶牛的防暑降温[J].畜牧兽医科技,1989(4):45-47.
[54]ArechigaC.F, StaplesC.R, McDowell L. Rand HansenP. J. Effects of Timed Insemination and Supplemental β-Carotene on Reproduction and Milk Yield of Dairy Cows Under Heat Stress[J].J Dairy Sci,1998,81(2):390-402.
[55]唐娇玉,屈孝初.奶牛热应激的研究与应对[J].当代畜禽养殖业,2005(7):47-48.
[56]孙齐英.奶牛不同抗热应激添加剂对奶牛生产性能的影响[J].江西饲料,2003,(5):5-8.
[57]李秋凤,李建国,韩永利.日粮阴阳离子平衡对高温环境中奶牛生产性能和血液指标的影响[J].畜牧兽医学报,2004,35(5),498-504.
[58]李绍钰,魏风仙.有机铬改善高温季节下奶牛生产性能的研究[J].中国奶牛,1999,5:18-19.
[59]张敏红.吡啶羧酸铬对畜禽抗高温、高产生理性应激效果的研究[J].饲料博览2000,12:31-33.
[60]尹召华,杨万玉.酵母培养物在奶牛日粮中的应用效果[J].安徽农业科学,2002,30(3):389-390.
[61]蒋永清,周卫东,黄新.益康“XP”添喂奶牛的效果[J].乳业科学与技术,2001,2:26-27.
[62]张荣飞.半肤胺盐酸盐对高温季节高产奶牛生产性能的影响[D].南京:南京农业大 学,2004,16-17.
[63]张细权,李加琪,杨关福.动物遗传标记[M].北京:中国农业大学出版社,1997:34-45.
[64]伍新尧,罗超权,马洞泉.分子遗传学与基因工程[D].郑州:河南医科大学出版社1997:110-111.
[65]陈丙莺,陈子兴.分子生物学基础与临床[M].南京:东南大学出版社,2002.
[66]孙德斌,鲁成.QTL研究及其在蚕业上的应用前景[J],蚕业科学,2000(1):29-34.
[67]李宁.动物遗传学[M].北京:中国农业出版社,2002:185-186.
[68]赵凯.动物遗传标记概述[J].青海大学学报,2000,18(3):10-13.
[69]魏麟,黎晓英,黄英,史宪伟.遗传标记及其发展概述[J].动物科学与动物医学,2004,21(11):42-45.
[70]曹红鹤.肉牛主要生产性状的生化和分子遗传标记的研究[D].北京:中国农业大学,2000:87-92.
[71]肖天放,苏建家,陈永贵.奶牛育种的遗传进展[J].福建农林大学学报(自然科学版),2002,31(4):500-502.
[72]杨昭庆,洪坤学.单核苷酸多态性的研究进展[J].国外医学遗传分册,2003,23(1):4-8.
[73]赵兴波,储明星,李宁.绵羊线粒体DNA控制区5‘端序列PCR-SSCP与序列分析[J].遗传学报,2001,28(3):225-228.
[74]陈祥,廖正录,李国红等.贵州地方山羊品种的RAPD分析[J].动物学研究,2004,25(2):141-146.
[75]刘德武,杨关福,李加琪等.猪品种与性别区别的RAPD标记研究[C].见:傅衍主编.第十次全国动物遗传育种学术讨论会论文集,北京:中国农业科技出版社,1999,69-72.
[76]孙伟.微卫星的研究与应用[J].黑龙江畜牧兽医,2001,(3):10-12.
[77]张吉清.微卫星标记及其在牛遗传育种中的应用[J].黄牛杂志,2001,26(6):1-5.
[78]曹红鹤,王雅春,陈幼春.探讨微卫星DNA作为南阳杂交牛生长性状的遗传标记[J].遗传学报,1999,26(6):621-626.
[79]Willians J G, Kubelik A R,Livak K J,et al.DNA polymorphisms amplified by arbitrary primer s are useful as genetic markers[J].Nucl Acid Res,1990,18:6531-6535.
[80]Welsh J,Mcclell.Finger printing genomes using PCR with arbitrary prime rs[J].Nucl Acids Res,1990,18:7213-7218.
[81]陈宏,孙维斌,雷初朝等.RAPD标记稳定性的影响因素探索[J].西北农林科技大学学报,2003,31(5):139-142.
[82]雷雪芹,陈宏,徐廷生等.小尾寒羊产羔性状的RAPD标记[J].福建农林大学学报,
2004,33(2):213-214.
[83]徐云碧.分子数量遗传学[M].北京中国农业出版社,1994,34-45.
[84]张恩平,耿社民,张亚妮等.内蒙古绒山羊产绒量和体重性状RAPID标记的初步研究[J].中国农学通报,2004,20(4):1-3.
[85]吴丰春,魏泓,甘世样等.应用100条RAPID引物对中国三种实验用小型猪进行多态性引物的筛选及亲缘关系的初步分析[C].见:傅衍主编.第十次全国动物遗传育种学术讨论会论文集,北京:中国农业科技出版社,1999:74-79.
[86]Orita M et al.Rapid and sensitive detection of point mutations and DNA polymorphisms using the polymerase chain reaction[J].Genomics,1989,5(4):874-9.
[87]Hayashi K.PCR methods and applications [M].NewYork:karger,1991,1:11-34.
[88]戚豫,唐炬,黄丽英.DNA单链构象多态性原理初探[J],基础医学与临,1997,17(2):142-146.
[89]吴珍芳,Habtz,熊远著.邓昌彦等.猪LPL基因多态性其部分DNA片段的顺序[J].华中农业大学学报,1999,18(5):4612-465.
[90]杨阳,姜运良,胡晓湘等.猪激素敏感脂肪酶基因(hs1)外显子的SSCP分析[J].农业生物技术学报,2001,9(2):142-144.
[91]李绍华,李爱云,熊远著,郑嵘等.猪MSTN基因多态性及其SNPs的研究[J].遗传学报,2002,29(4):326-331.
[92]李剑虹,崔卫国,包军.猪Mu阿片受体基因外显子E单核苷酸多态性[J].遗传学报,2003,30(1):30-34.
[93]阮征,凌家瑞,王春芳,韩艳云等.以催乳素受体基因作为母猪产仔数侯选基因的分析[J].中国畜牧杂志,2003,39(1):33-34.
[94]李婧,杨润清,孟和,李长龙等.ES与PRLR基因对民猪产仔数的影响[J].黑龙江畜牧兽医,2003,(4):11-17.
[95]李婧,杨润清,孟和等.民猪产仔数性状四个倏选基因效应分析[J].上海交通大学学报农业科学版,2004,22(1):74-77.
[96]雷雪芹,陈宏,袁志发等.促卵泡生成素受体基因的SNP对牛双胎性状的标记研究[J].云南畜牧兽医,2002(4):28-29.
[97]李国华,张沅,李宁.奶牛乳铁蛋白基因部分序列的PCR-SSCP分析[J].农业生物学报,2001,9(2):139-141.
[98]陈桂芳,谢庄,强巴央宗等.西藏牦牛、荷斯坦牛三个功能基因部分序列多态性的比较研究[J].畜牧兽医学报,2003,34(2):128-131.
[99]咎林森,史明艳,王勇强.秦川牛、南阳牛双肌基因的PCR-SSCP检测[J].中国农业通报,2003,19(5):729.
[100]Botstein. D. R, White. R. L.Construction of a genetic linkage map in man using restrition fragment length polymorphisms[J].Am J Hum Genet,1980,32:314-331.
[101]Donis, Kcllcr H, Grecn P.A genetic linkage map of the human genome [J].1987,51:319-377.
[102]Lagercrantz U,Ellegren H, AnderssonL.The a bundanceo fvarious polymoriphic microsatellites motifs differ between plantsand vertebrates[J].Nucl Acid Res,1993,(21):1111-1115.
[103]Leroy P, Elsen J M and Knot S.Comparison of four statistical methods for detection of a major gene in a progeny test design [J].Genet Sel Evol,1989,21:341-357.
[104]Grobet L,Martin L J,Poncecet D.A deletion in the bovine myostatin gene cause the double-muscled phenotygein cattle[J].Nature Genetics,1997,17(1):71-74.
[105]Keele J. W and Fahrenkrug S.C. Optimum mating systems for the myostatin locus in cattle[J].J Ani Sci,2001,79:2016-2022.
[106]屈军梅,李文平.奶牛热应激及防治对策研究[J].中国奶牛,2005(3):16-2039.
[107]Ren Jun, Yuan Li, HuaXiang-bo.Premary Study on RAPD Markers Associated With Heat Tolerance in TaiHe Silk Chicken[C].Ani Bio Bulletin,2000,7(1):179-182.
[108]Napolitano F et al.Explotation of microsatellites as genetic markers of Beef performance traits in pimontese Xchianina crossbred cattle[J].Breed Genet,1996, 113:157-162.
[109]汤泽桃,肖兵南,燕海峰等.奶牛耐热性状遗传标记研究进展[J].上海畜牧兽医,2005,2:8-11.
[110]史彬林,李如治,黄昌澎等.红细钾作为耐热性选择的遗传可靠性研究[J].南京农业大学学报,1993,16(3):64-67.
[111]赖登明,夏东,李如治等.红细胞钾含量对奶牛耐热性的影响[J].中国奶牛,1997,2:15-16.
[112]Perez-Enciso M and Varona L.Quantitative trait loci mapping in F2 crosses between outbred lines[J].Genetics,2000,155:391-405.
[113]Perez-Enciso M, Fernando R L, Biodanel J. Quantitative trait locus analysis in crosses between out bred lines with dominance and in breeding[J].Genetics,2001,159:413-422.
[114]Hoeschele I, Uimari P, Gringola F E. Advances in statistical methods to map Quantitative trait loci in outbred populations[J].Genetics,1997,147:1445-1457.
[115]徐宁迎.利用微卫星进行奶牛数量性状基因位点定位的研究[J].遗传学报,2000,27(9):772-776.
[116]Zhang gin.Mapping quantitative trait loci for milk production and health of dairy catlle in a large out breed pedigree[J].Genetics,1998,149:40.
[117]曹红鹤,王雅春,陈幼春.五种微卫星标记在肉牛群体中的研究[J].中国农业科学,1999,32(1):78-82.
[118]孙少华.肉牛群体遗传变异的微卫星多态性分析[J].中国农业大学学报,1999,4(增刊):83-87.
[119]Ashwell M.S.Detection of putqtive loci affecting milk, health, and type traits in a united states Holstein populationusing 70 microsatellite markers in agenomescan[J].J Dairy Sci,1999,82:2497-2502.
[120]Kambadur R,Sharma M,Smith T P.mutations in myostatin(GDF-8)in double-muscled Belgian Blue and Piedmontese cattle[J].Genome Research,1997,17(1):71-74.
[121]Martin G B.Rapid ideatification of makers linked to a Pseudomonas resistance gene in tomato by using random primers and near-isogenic lines[J].Proc.Natl.Acad.Sci.USA,1991,88:2336-2440.
[122]Mcihelmore R W.Identification of markers linked to disease resistance genes by Bulked Segregant Analysis:A rapid method to delect markers in specific genomic regions using segregating populations[J].Proc.Natl.Acad.Sci,1991,88(1):9828-9832.
[123]白秀娟,李辉.肉鸡肥度性状RAPD标记的研究[J].东北农业大学学报,2004,35(4):432-436.
[124]姜运良,李宁.猪雌激素受体基因(ESR)点突变的PCR-SSCP检测[J].遗传,2000,22(4):214-216.
[125]Kambadur R,Sharma M,Smith T P.mutations in myostatin(GDF-8)in double-muscled Belgian Blue and Piedmontese cattle[J].Genome Research,1997,17(1):71-74.
[126]Richard J. Spelman.Quantitative trait loci analysis for rive milk production traits on chromosome six in the dutch Holstein Friesian population[J].Genetics,1996,144.1799-1808.
[127]Velmala.R.J.A search for quantitative trait loci for milk production traits on chromosome6 in Finish A yrshire cattle[J].Anim.Gene,1999,30:136.
[1]张卫红.吡啶羧酸铬对奶牛的抗应激作用[A].见:张敏红编.畜禽应激与抗应激新技术[M].北京:中国农业大学出版社,2000:86—89.
[2]梁学武,张龙涛,刘庆华等.热应激期日粮添加酵母铬对奶牛产奶性能及血液生化指标的影响[J].福建农林大学学报,2006,35(2):191-194.
[3]尹召华,邢淑芳.添加高能饲料对乳牛生产性能影响的研究[J].安徽农业科学,2006,34(24):6511-6515.
[4]阎小艳,李新浩,阎晓晖.奶牛热应激[J].动物科学与动物医学,2004,21(9):42-44.
[5]李建国,桑润滋,张正珊等.热应激对奶牛血液生化指标及生产性能的影响[J].中国奶牛,1998(6):19-20.
[6]Malmolf K. Amino acid in farm animal nutrition metabolism, partition and consequences of imbalance[J].Journal of Agricultural Research 1988,18:191-193.
[7]CHANGX,MALLARDBA,MOWATDN.Effects of chromium on health status, blood neutrophil phagocytosis and in vitro lymphocyte blastobenesis of dairy cows[J].Vet Immunol immunopath,1996,52(1):37-52.
[8]H. M. Burrow and K. C.Prayaga.Correlated responses in productive and adaptive traits and temperament following selection for growth and heat resistance in tropical beef cattle[J].Livestock Production Science.2004,86(13):143-161.
[9]L. Avendano-Reyes, F.D.Alvarez-Valenzuela, A. Correa-Calderon, J.S.Saucedo-Quintero, P.H.Robinson and J.G. Fadel,Effect of cooling Holstein cows during the dry period on postpartum performance under heat stress conditions[J].Livestock Science,2006,105(1-3):198-206.
[10]Saiadymy, Shaikhma, Mufarrejsi, et al.Effect of chelated chromium supp lementation on
lactation performance and blood parameters of Holstein cows under heat stress [J].Animal Feed Science and Technology,2004,117:223-233.
[11]王吉峰,王加启.奶牛营养代谢对乳脂合成调控机制的研究进展[J].中国畜牧兽医,2003,30(2):6-10.
[12]夏伦志,蔡东等.半胱胺补饲模式对奶牛生产性能及血清胰岛素水平的影响[J].中国畜牧杂志,2005,41(2):27-29.
[13]樊华,樊丽.热应激对泌乳奶牛血液生化指标的影响[J].中国畜牧兽医,2007,34(4):45-46.
[14]杨笃宝,吕品.热应激对奶牛抗氧化性能的影响[J].动物医学进展,2006,27:99-100.
[15]贾磊,王加启.日粮阴阳离子差对泌乳前期热应激奶牛血液酸碱平衡和生产性能的影响[J].动物营养学报,2007,19(6):663-670.
[16]李新建,高腾云.烟酸和烟酸铬对热应激奶牛产奶性能、血液生理生化指标的影响[J].家畜生态学报,2006,27(5):26-31.
[17]刘强,黄应祥.中草药对奶牛泌乳性能和血液生化指标的影响[J].中国畜牧兽医,2007,40(3):24-27.
[18]魏学良,张家骅.高温环境对奶牛生理活动及生产性能的影响[J].中国农学通报,21(5):13-15.
[19]张龙涛.奶牛日粮添加酵母铬的效应研究.福建农林大学硕士论文,2004.
[20]夏东,杨淑晶,刘铁铮.奶牛血液抗氧化酶活性的季节变化[J].家畜生态学,27(1):57-59.
[21]Jenkins,T.C Palmquist.Effects of fatty acids or calcium soaps on rumen and total nutrient digestibility of dairy rations[J].Dairy Science,1984,67:978-986.
[22]HOFFMAN,P.C.COMBS,D.K.CASLER,M.D.Performance of lactating dairy cows fed alfalfa silage or perennial ryegrass silage[J].Journal of Dairy Science,1998,81 (1):162-168.
[23]李俊杰,桑润滋,田树军,马亚宾,周振明.热应激与牛血液成分的变化[J].家畜生态,2001,22(4):56-59.
[24]唐妓玉,袁自强,屈孝初,李文平.奶牛热应激的检测方法及防治措施[J].湖北畜牧兽医,2005,4:30-32
[25]CURTISS.Environmental management in animal agriculture[M].Ames IA:The Iowa State UnivPress,1983.
[26]刘艳琴,高洁,高玉红,江富华,李建国.炎热夏季奶牛日粮中添加脂肪酸钙对热应激影响的研究[J],草食家畜,1999,(4):37-39.
[27]李士泽,杨玉英,何晶,顾少英.北方寒区环境因素对奶牛生产性能的影响[J].黑龙江八一农垦大学学报,1999,11(3):24-26.
[28]莫放,王光文,范占炼,金遐良,易涛.保护脂肪在奶牛生产申的应用.乳业科学 与技术,2001,24(1):24-27.
[29]王俊锋,王中华,梁国义,谢宝柱.影响奶牛乳蛋白质含量的因素及营养调控技术研究[J].饲料工业,2006,27(15):47-52.
[30]史彬林,闫素梅.奶牛耐热性评定指标的研究[J].中国奶牛,1996,2:20-22.
[31]陈志伟,丁忠锋,陈凯.综合营养措施对热应激奶牛的影响[J].中国畜牧兽医,2005,5:2
[32]张纪芸,黄晓燕,刘道祯,等.肾小球疾病肾功能与甲状腺功能的相关分析.中华内分泌代谢杂志,1996,12(2):116
[33]Rich Verbeck, John F.Smith.奶牛与热应激[J].乳业科学与技术,2004,1:30-33
[1]CHANGX, MALLARDBA,MOWATDN.Effects of chromium on health status, blood neutrophil phagocytosis and in vitro lymphocyte blastogenesis of dairy cows[J].Veterinary immuno pathology,1996,52(1):37-52.
[2]H. M. Burrow and K. C. Prayaga.Correlated responses in productive and adaptive traits and temperament following selection for growth and heat resistance in tropical beef cattle[J].Livestock Production Science.2004,86(13):143-161.
[3]Avendano-Reyes L, Alvarez-Valenzuela F.D, Correa-CalderonA, Saucedo-Quintero J.S, Robinson P.H and Fadel J.G.Effect of cooling Holstein cows during the dry period on postpartum performance under heat stress conditions[J]. Livestock Science.2006,105(1-3):198-206.
[4]SAIADYMY, SHAIKHMA, MUFARREJSI, etal. Effect of chelated chromium supp lementation on lactation performance and blood parameters of Holstein cows under heat stress[J].Animal Feed Science and Technology,2004,117:223-233.
[5]Jenkins,T.C Palmquist Effects of fatty acids or calcium soaps on rumen and total[J].Nutrient digestibility of dairy rations[J].Dairy Science,1984,67:978-986.
[6]HOFFMAN P.C,COMBS D.K, CASLER M.D.Performance of lactating dairy cows fed alfalfa silage or perennial ryegrass silage[J].Journal of Dairy Science 1998,81(1):162-168.
[7]张卫红.吡啶羧酸铬对奶牛的抗应激作用[A].见:张敏红编.畜禽应激与抗应激新技术[M].北京:中国农业大学出版社,2000:86-89.
[8]梁学武,张龙涛等.热应激期日粮添加酵母铬对奶牛产奶性能及血液生化指标的影响[J].福建农林大学学报,2006,35(2):191-194.
[9]李建国,桑润滋,张正珊等.热应激对奶牛血液生化指标及生产性能的影响[J].中国奶牛,1998,(6):19-20.
[10]贾磊,王加启.日粮阴阳离子差对泌乳前期热应激奶牛血液酸碱平衡和生产性能的影响[J].动物营养学报,2007,19(6):663-670.
[11]Erdman A Ricrard.Dietary buffering requirements of the lactating dairy cow.A Review[J].J Dairy Sci,1988,71:246-3266.
[12]West J W, Haydon K D, Mullinix B G, et al.Dietary cation-anion balance and cation source effects on production and acid-base status of heat-stressed cows[J].J Dairy Sci,1992, 75:2776~2786.
[13]Escobosa A,Coppock E C. Effects of dietary sodium bicarbonate and calcium chloride on physiological responses of lactating dairy cows in hot weather [J].J Dairy Sci,1984,67:574-584.
[14]李士泽,杨玉英,何晶,顾少英.北方寒区环境因素对奶牛生产性能的影响[J].黑龙江八一农垦大学学报,1999,11(3):24-26.
[15]王俊锋,王中华,梁国义,谢宝柱影响奶牛乳蛋白质含量的因素及营养调控技术研究[J].饲料工业2006,27(15):47-52
[16]王吉峰,王加启.奶牛营养代谢对乳脂合成调控机制的研究进展[J].中国畜牧兽医2003,30(2):6-10
[17]梁学武,张龙涛,刘庆华,韩国林,陈新华.热应激期日粮添加酵母铬对奶牛产奶性能及血液生化指标的影响[J].福建农林大学学报2006,35(2):191-194
[18]CURTISS.Environmental management in animal agriculture[M].Ames IA:The Iowa State UnivPress,1983.
[19]李士泽,杨玉英,何晶,顾少英.北方寒区环境因素对奶牛生产性能的影响[J].黑龙江八一农垦大学学报,1999,11(3):24-26.
[20]史彬林,闫素梅.奶牛耐热性评定指标的研究[J].中国奶牛,1996,2:20-22.
[21]贾磊,王加启.日粮阴阳离子差对泌乳前期热应激奶牛血液酸碱平衡和生产性能的影响[J].动物营养学报,2007,19(6):663-670.
[22]樊华,樊丽.热应激对泌乳奶牛血液生化指标的影响[J].中国畜牧兽医,2007,34(4):45-46.
[23]夏伦志,蔡东等.半胱胺补饲模式对奶牛生产性能及血清胰岛素水平的影响[J].中国畜牧杂志,2005,41(2):27-29.
[24]李俊杰,桑润滋,田树军,马亚宾,周振明.热应激与牛血液成分的变化[J].家畜生态,2001,22(4):56-59.
[25]杨笃宝,吕品.热应激对奶牛抗氧化性能的影响[J].动物医学进展,2006(27):99-100.
[26]魏学良,张家骅.高温环境对奶牛生理活动及生产性能的影响[J].中国农学通报,21(5):13-15.
[1]万海伟,张传生,杜立新.正交优化法建立奶牛基因组DNA RAPD-PCR最佳反应体系[J].生物技术通报,2004(3):45-47.
[2]魏学良,张家骅.高温环境对奶牛生理活动及生产性能的影响[J].中国农学通报,21(5):13-15.
[3]樊华,樊丽.热应激对泌乳奶牛血液生化指标的影响[J].中国畜牧兽医,2007,34(4):45-46.
[4]李新建,高腾云,常智留,席进华.烟酸和烟酸铬对热应激奶牛产奶性能和血液激素水平的影响[J].华中农业大学学报,2006,25(4):411-415.
[5]沙向阳,张惠斌,周金培.以二肽基肽酶Ⅳ为靶点的抗糖尿病药物[J].药学展,2006,30(6):241-244.
[6]李祎亮,王菊仙,吴香玫,邹美香.二肽基肽酶Ⅳ抑制剂的研究进展[J].中国新药杂志,2008,17(20):1739-1745.
[7]Kazazian H H.mobile elements:driver of genome evolution [J].Science,2004,303(5664):1626-1632.
[8]Sutherland CL, Chalupny N, J Schooley K, VandenBos T, Kubin M, Cosman D.UL16-binding proteins, novel MHC class I-related proteins, bind to NKG2D and activate multiple signaling pathways in primary NK cells [J].J Immunol.2002;168(2):671-9.
[9]KLEIN J, SATIA Y, O'HU IGIN C.The molecular descent of the major histocompatibility complex[J].Annu Rev Immunol,1993,11:269-295.
[10]项伟,马建,王雪峰,赵玉军.SSCP和HMA方法在马MHC-Ⅰ类分子基因多态性研究中的应用[J].遗传,2008,30(12):1635-1639.
[11]刘云芳,剡根强,王新峰.家畜MHC的研究进展及其在遗传育种中的应用[J].黄牛杂志,2004(2):14.
[12]徐卫锋.MHC-Ⅰ类分子对外源蛋白的呈递[J].上海免疫学杂志,1999,19:380.
[13]胡雄贵,肖兵南,邓绪芳,燕海峰.荷斯坦奶牛RAPD反应条件的优化[J].畜禽业,2006,194:8-10.
[14]Ooi GT, Tawadros N, Escalona RM.Pituitary cell lines and their endocrine applications [J].Mol, Cell Endocrinol.2004,228(1-2):1-21.
[15]范少光,丁桂风.神经内分泌与免疫系统之间相互作用的介导物质—共同的生物学语言[J].生理科学进展,26(2):175-183.
[16]张纪芸,黄晓燕,刘道祯等.肾小球疾病肾功能与甲状腺功能的相关分析[J].中华内分泌代谢杂志,1996,12(2):116.
[2]Selye.H.The Stress of Life[M].McGraw Hill,New York,1956:205-236.
[3]Bohus.B,KoolhaasJ.M.,Nyakas.C,Stefens A.B,fokkemaD.S.and ScA.J.W. Neuroendocrine states and behavioral and physiological stress responses[J].Progress in brain research,1987,72:57-70.
[4]Ewbank.R.Stress:a general overview.In:Farm Animal and the Environ Clive Phillips, D.Piggins[J].C.A.B.International,1992.pp.255-262.
[5]Siegel H.S.Stress.strain and resistance[J].British Poultry Sci 1995.3.
[6]赖登明,夏冬,李如治.红细胞钾含量对奶牛耐热性的影响[J].中国奶牛,1997,(2):13-14.
[7]West.J W,. Mullinix B G, Bernard J K. Effects of hot, humid weather on milk temperature, dry mater intake, and milk yield of lactating dairy cows[J].J Dairy Sci.2003,86:232-242.
[8]张国高.高温生理与卫生.科学技术出版社,1988.
[9]穆玉云.乳牛耐热性指标的检测.安徽农业大学学报,1993,20(1):66-71.
[10]李建国,桑润滋,张正姗等.热应激对奶牛生理常值、血液生化指标、繁殖及泌乳性[J].河北农业大学学报,1998,21(4):692-673.
[11]Kabayashi K.Thermoregulation during rest and exersice in different postures in a hot humid environment[J].Appl.Physiol.1980,48:999-1007.
[12]McDowell R E.Improvement of live stock production in warm climates[C].A Series of Books in Agricultural Science,1972
[13]Sanchez W K, M A Mcguire,et al.Macromineralnu ration by heat stress interactions in dairy catle:Review and original research[J].J Dairy Sci.,1994,77:2051-2079.
[14]Belay T,C J Wiemusz,et al.Mineral balance and urinary and fecal mineral excretion
profile of broilers housed in the rmoneutral and heat distressed environments [J].Poult. Sci,1992,71:1043.
[15]Collier R J, Beed D K,et al.Influences of environment and its modification no dairy animal health and production[J].J.D airy Sci,1982,65:2213.
[16]Fuquay J W.Heats tred dasit affects animal production[J].J.D airy Sci.,1981,52:164.
[17]Cuningham MD,et al.Effect of drink water temperature upon ruminant digestion, intraruminal temperature and water consumption of nonlacting dairy cows[J].J.Dairy Sci.19 64,47:382-385.
[18]Sevi A,Rotunno T, DiRoberto C, Muscio A.Fatty acid composition of ewe milk as affected by Solar radiation and high ambient temperature[J].J.Dairy Res,2002,69(2):181-94.
[19]Westra H D.Effect of Environmenton Nutrient Requirements of Domestic Animals[J].J.A nim.Sci 1999,85:13-21.
[20]史彬林,闫素梅.奶牛耐热评定指标的研究[J].中国奶牛,1996,(2):20-22.
[21]Alvarez M B,Johnson H D.Environmental heat exposure on cattle plasma catecholamine and Glucocorticoids [J].J.Anim.sci,1973,36:369.
[22]West J W, Mullinix B G,Bernard J K. Effects of hot, humid weather on milk temperature,dry mater intak,and milk yield of lactating dairy cows[J].J Dairy Sci,2003,86:232-242.
[23]DuPreez JH.Parameters for the determination and evaluation of heat stress in dairy cattle in South Africa On derstepoort[J].VetRes.2000.67 (4):263-71.
[24]王前,林玲,林继生等.气候因子与荷斯坦奶牛产奶量的关系研究[J].广州奶牛,2003,(1):1-3.
[25]李如治.奶牛热应激研究现状[J].中国奶牛,1995:38-40.
[26]马胜龙,冯定远.动物热应激机理及其研究进展[J].广东饲料,2000,(4):20-23.
[27]Suchanek B,Gajdvsek S.Compostition of milk form cow herds with high milk efficiency[J].Nas Chov.1989,49(10):454.
[28]KriventsonYu M. et al.Production,chemical composition and technological properties of milk of Black Pied cows of different geno Vestnik sel skokhozyaistvennol nauki(moskva)[J].J Dairy Sci,1991,8:100.
[29]Moore R et al. Feeets of late gestation heats tress on post partum milk production and re production in dairy cattle [J].J Dairy Sci,1992,75:1877.
[30]Wolfenson D, Roth Z, Meidan R A Impaired reproduction in heat-stressed cattle:basic and applied aspects[J].Anim Reprod Sci,2000 60:535-47.
[31]姜礼胜,林映才,蒋宗勇.肉鸡饮服“必补-18”的抗应激效果研究(Ⅱ)[J].畜牧与兽医,1997,29(5):197-200.
[32]Wolfenson D, Roth Z, Meidan R. Ampaired reproduction in heat-stressed cattle:basic and applied aspects[J].Anim Reprod Sci.2000,60-61:535-47.
[33]Tarazon-Herrera M, Huber JT, Santos J. Effects of bovine somatotropin and evaporative cooling pluss hade on lactation performance of cows during summer heat stress [J].J Dairy Sci.1999,82 (11):2352-7.
[34]Siegel R A, Feldman S,Conforti N,Ben-David M,Chowers I. PRL and ACTH secretion fo llowing acute heat exposure, in intact and in hypothalamic deaferentated male rats.Brain [J]. Res.1979.178(2-3):459-466.
[35]May JD, Deaton JW, Reece FN, Branton SL. Effect of acclimation and heat stress on thyroidhormone concentration [J].Poult Sci.1986.65(6):1211.
[36]Bobek S,Sechman A,Wieczorek E.Reverse3,3',5'-triiodothyronine(rT3)enhances hyperglycemic and lipemic effects of heat-stress in chickens[J].Horm Metab Res.19 97.29(5):252-4.
[37]Magdub A, Johnson HD, Belyea RL. Effect of environmental heat and dietary fiber on thyroid physiology of lactating cows[J].JDairy S ci.1982.65(12):2323-31.
[38]Hurley L. Bovine prolactin,TSH,T4 and T3 Concentrations as affected by Tall Fescue Summer Toxicosis and Temperature[J].JA nmi.Sci.1981.55(2):374.
[39]Khurann M L,Madan M L. Thyroxine Secretion Rate in Buffaloes During Hot Dry, Hot Humid and Cold Seasons[M].First World Bufalo Congress, Cairo.1985:1165.
[40]McNabbl Roussel,J D Gomila. Relationships of certain blood serum parameters with enviromental temperatures and milk yield[J].J.Dairy Sci,1974,57:141-156.
[41]Aberle E D, Merkel R A, et al.P htsiological responses of stress susceptible and stress resistant pigs to heat stress[J].J.Anim.Sci,1974,38:954-967.
[42]Olbrich.S E, Martz FA. et al. Semen quality and behabvior of Holstein bulls exposed to estracliol-treated bulls for mounts[J].J.Dairy Sci,1971,54:793-805.
[43]Siegel, H. S.and Lamtimer, J. W. Interaction of high temperature and salmonella pullomm antigen concentration on serum agglutinin and corticoseroid response in WhiteRock chickens[J].Poultry Sci,1984,6 3:2483-2491.
[44]Freeman, B.M.The domestic fowl in biomedical research:physiological effect of environment[J].J World's Poultry Sci,1988,44:41-60.
[45]Cross, W.B.Siegel, P B.Effect of social stress and steroids on antibody production[J].Avian Disease,1973,17:807-815.
[46]Kelley R.V. et al.Effect of environmental temperature on ruminants VTA levels with controlled feed intake[J].J Dairy Sci,1965,50:531-534.
[47]McDowell R. E, Moody E. G, Van Soest P. J,.Lehmann R. P, Ford G. L.Effect of Heat Stress on Energy and Water Utilization of Lactating Cows[J].J Dairy Sci,1969,52 (2): 188-194.
[48]刘艳琴,高洁,高玉红,江富华,李建国.炎热夏季奶牛日粮中添加脂肪酸钙对热应激影响的研究[J].草食家畜,1999,(4):37-39.
[49]陈杰,任明强,孟军.日粮中添加乙酸钠对夏季奶牛生理状况和泌乳性能的影响[J].中国畜牧杂志.1989,25(3):3-4.
[50]韩继福,吴其宏.过瘤胃氨基酸对乳牛瘤胃发酵、产乳量及乳成分的影响[J].安徽农业大学学报,2003,30(2):139-143.
[51]Huber J. T, Higginbotham G, Gomez-Alarcon R. A,Taylor R. B,Chen K. H, Chan S.C, Wu Z.Heat Stress Interactions with Protein Supplemental Fat, and Fungal Cultures [J].J Dairy Sci,1994,77 (7):2080-2090.
[52]LD Muller, AJ Heinrichs, JB Cooper, YH Atkin.Supplemental Niacin for Lactating Cows During Summer Feeding[J].J Dairy Sci,1986,69(5):1416-1420.
[53]黄美音.奶牛的防暑降温[J].畜牧兽医科技,1989(4):45-47.
[54]ArechigaC.F, StaplesC.R, McDowell L. Rand HansenP. J. Effects of Timed Insemination and Supplemental β-Carotene on Reproduction and Milk Yield of Dairy Cows Under Heat Stress[J].J Dairy Sci,1998,81(2):390-402.
[55]唐娇玉,屈孝初.奶牛热应激的研究与应对[J].当代畜禽养殖业,2005(7):47-48.
[56]孙齐英.奶牛不同抗热应激添加剂对奶牛生产性能的影响[J].江西饲料,2003,(5):5-8.
[57]李秋凤,李建国,韩永利.日粮阴阳离子平衡对高温环境中奶牛生产性能和血液指标的影响[J].畜牧兽医学报,2004,35(5),498-504.
[58]李绍钰,魏风仙.有机铬改善高温季节下奶牛生产性能的研究[J].中国奶牛,1999,5:18-19.
[59]张敏红.吡啶羧酸铬对畜禽抗高温、高产生理性应激效果的研究[J].饲料博览2000,12:31-33.
[60]尹召华,杨万玉.酵母培养物在奶牛日粮中的应用效果[J].安徽农业科学,2002,30(3):389-390.
[61]蒋永清,周卫东,黄新.益康“XP”添喂奶牛的效果[J].乳业科学与技术,2001,2:26-27.
[62]张荣飞.半肤胺盐酸盐对高温季节高产奶牛生产性能的影响[D].南京:南京农业大 学,2004,16-17.
[63]张细权,李加琪,杨关福.动物遗传标记[M].北京:中国农业大学出版社,1997:34-45.
[64]伍新尧,罗超权,马洞泉.分子遗传学与基因工程[D].郑州:河南医科大学出版社1997:110-111.
[65]陈丙莺,陈子兴.分子生物学基础与临床[M].南京:东南大学出版社,2002.
[66]孙德斌,鲁成.QTL研究及其在蚕业上的应用前景[J],蚕业科学,2000(1):29-34.
[67]李宁.动物遗传学[M].北京:中国农业出版社,2002:185-186.
[68]赵凯.动物遗传标记概述[J].青海大学学报,2000,18(3):10-13.
[69]魏麟,黎晓英,黄英,史宪伟.遗传标记及其发展概述[J].动物科学与动物医学,2004,21(11):42-45.
[70]曹红鹤.肉牛主要生产性状的生化和分子遗传标记的研究[D].北京:中国农业大学,2000:87-92.
[71]肖天放,苏建家,陈永贵.奶牛育种的遗传进展[J].福建农林大学学报(自然科学版),2002,31(4):500-502.
[72]杨昭庆,洪坤学.单核苷酸多态性的研究进展[J].国外医学遗传分册,2003,23(1):4-8.
[73]赵兴波,储明星,李宁.绵羊线粒体DNA控制区5‘端序列PCR-SSCP与序列分析[J].遗传学报,2001,28(3):225-228.
[74]陈祥,廖正录,李国红等.贵州地方山羊品种的RAPD分析[J].动物学研究,2004,25(2):141-146.
[75]刘德武,杨关福,李加琪等.猪品种与性别区别的RAPD标记研究[C].见:傅衍主编.第十次全国动物遗传育种学术讨论会论文集,北京:中国农业科技出版社,1999,69-72.
[76]孙伟.微卫星的研究与应用[J].黑龙江畜牧兽医,2001,(3):10-12.
[77]张吉清.微卫星标记及其在牛遗传育种中的应用[J].黄牛杂志,2001,26(6):1-5.
[78]曹红鹤,王雅春,陈幼春.探讨微卫星DNA作为南阳杂交牛生长性状的遗传标记[J].遗传学报,1999,26(6):621-626.
[79]Willians J G, Kubelik A R,Livak K J,et al.DNA polymorphisms amplified by arbitrary primer s are useful as genetic markers[J].Nucl Acid Res,1990,18:6531-6535.
[80]Welsh J,Mcclell.Finger printing genomes using PCR with arbitrary prime rs[J].Nucl Acids Res,1990,18:7213-7218.
[81]陈宏,孙维斌,雷初朝等.RAPD标记稳定性的影响因素探索[J].西北农林科技大学学报,2003,31(5):139-142.
[82]雷雪芹,陈宏,徐廷生等.小尾寒羊产羔性状的RAPD标记[J].福建农林大学学报,
2004,33(2):213-214.
[83]徐云碧.分子数量遗传学[M].北京中国农业出版社,1994,34-45.
[84]张恩平,耿社民,张亚妮等.内蒙古绒山羊产绒量和体重性状RAPID标记的初步研究[J].中国农学通报,2004,20(4):1-3.
[85]吴丰春,魏泓,甘世样等.应用100条RAPID引物对中国三种实验用小型猪进行多态性引物的筛选及亲缘关系的初步分析[C].见:傅衍主编.第十次全国动物遗传育种学术讨论会论文集,北京:中国农业科技出版社,1999:74-79.
[86]Orita M et al.Rapid and sensitive detection of point mutations and DNA polymorphisms using the polymerase chain reaction[J].Genomics,1989,5(4):874-9.
[87]Hayashi K.PCR methods and applications [M].NewYork:karger,1991,1:11-34.
[88]戚豫,唐炬,黄丽英.DNA单链构象多态性原理初探[J],基础医学与临,1997,17(2):142-146.
[89]吴珍芳,Habtz,熊远著.邓昌彦等.猪LPL基因多态性其部分DNA片段的顺序[J].华中农业大学学报,1999,18(5):4612-465.
[90]杨阳,姜运良,胡晓湘等.猪激素敏感脂肪酶基因(hs1)外显子的SSCP分析[J].农业生物技术学报,2001,9(2):142-144.
[91]李绍华,李爱云,熊远著,郑嵘等.猪MSTN基因多态性及其SNPs的研究[J].遗传学报,2002,29(4):326-331.
[92]李剑虹,崔卫国,包军.猪Mu阿片受体基因外显子E单核苷酸多态性[J].遗传学报,2003,30(1):30-34.
[93]阮征,凌家瑞,王春芳,韩艳云等.以催乳素受体基因作为母猪产仔数侯选基因的分析[J].中国畜牧杂志,2003,39(1):33-34.
[94]李婧,杨润清,孟和,李长龙等.ES与PRLR基因对民猪产仔数的影响[J].黑龙江畜牧兽医,2003,(4):11-17.
[95]李婧,杨润清,孟和等.民猪产仔数性状四个倏选基因效应分析[J].上海交通大学学报农业科学版,2004,22(1):74-77.
[96]雷雪芹,陈宏,袁志发等.促卵泡生成素受体基因的SNP对牛双胎性状的标记研究[J].云南畜牧兽医,2002(4):28-29.
[97]李国华,张沅,李宁.奶牛乳铁蛋白基因部分序列的PCR-SSCP分析[J].农业生物学报,2001,9(2):139-141.
[98]陈桂芳,谢庄,强巴央宗等.西藏牦牛、荷斯坦牛三个功能基因部分序列多态性的比较研究[J].畜牧兽医学报,2003,34(2):128-131.
[99]咎林森,史明艳,王勇强.秦川牛、南阳牛双肌基因的PCR-SSCP检测[J].中国农业通报,2003,19(5):729.
[100]Botstein. D. R, White. R. L.Construction of a genetic linkage map in man using restrition fragment length polymorphisms[J].Am J Hum Genet,1980,32:314-331.
[101]Donis, Kcllcr H, Grecn P.A genetic linkage map of the human genome [J].1987,51:319-377.
[102]Lagercrantz U,Ellegren H, AnderssonL.The a bundanceo fvarious polymoriphic microsatellites motifs differ between plantsand vertebrates[J].Nucl Acid Res,1993,(21):1111-1115.
[103]Leroy P, Elsen J M and Knot S.Comparison of four statistical methods for detection of a major gene in a progeny test design [J].Genet Sel Evol,1989,21:341-357.
[104]Grobet L,Martin L J,Poncecet D.A deletion in the bovine myostatin gene cause the double-muscled phenotygein cattle[J].Nature Genetics,1997,17(1):71-74.
[105]Keele J. W and Fahrenkrug S.C. Optimum mating systems for the myostatin locus in cattle[J].J Ani Sci,2001,79:2016-2022.
[106]屈军梅,李文平.奶牛热应激及防治对策研究[J].中国奶牛,2005(3):16-2039.
[107]Ren Jun, Yuan Li, HuaXiang-bo.Premary Study on RAPD Markers Associated With Heat Tolerance in TaiHe Silk Chicken[C].Ani Bio Bulletin,2000,7(1):179-182.
[108]Napolitano F et al.Explotation of microsatellites as genetic markers of Beef performance traits in pimontese Xchianina crossbred cattle[J].Breed Genet,1996, 113:157-162.
[109]汤泽桃,肖兵南,燕海峰等.奶牛耐热性状遗传标记研究进展[J].上海畜牧兽医,2005,2:8-11.
[110]史彬林,李如治,黄昌澎等.红细钾作为耐热性选择的遗传可靠性研究[J].南京农业大学学报,1993,16(3):64-67.
[111]赖登明,夏东,李如治等.红细胞钾含量对奶牛耐热性的影响[J].中国奶牛,1997,2:15-16.
[112]Perez-Enciso M and Varona L.Quantitative trait loci mapping in F2 crosses between outbred lines[J].Genetics,2000,155:391-405.
[113]Perez-Enciso M, Fernando R L, Biodanel J. Quantitative trait locus analysis in crosses between out bred lines with dominance and in breeding[J].Genetics,2001,159:413-422.
[114]Hoeschele I, Uimari P, Gringola F E. Advances in statistical methods to map Quantitative trait loci in outbred populations[J].Genetics,1997,147:1445-1457.
[115]徐宁迎.利用微卫星进行奶牛数量性状基因位点定位的研究[J].遗传学报,2000,27(9):772-776.
[116]Zhang gin.Mapping quantitative trait loci for milk production and health of dairy catlle in a large out breed pedigree[J].Genetics,1998,149:40.
[117]曹红鹤,王雅春,陈幼春.五种微卫星标记在肉牛群体中的研究[J].中国农业科学,1999,32(1):78-82.
[118]孙少华.肉牛群体遗传变异的微卫星多态性分析[J].中国农业大学学报,1999,4(增刊):83-87.
[119]Ashwell M.S.Detection of putqtive loci affecting milk, health, and type traits in a united states Holstein populationusing 70 microsatellite markers in agenomescan[J].J Dairy Sci,1999,82:2497-2502.
[120]Kambadur R,Sharma M,Smith T P.mutations in myostatin(GDF-8)in double-muscled Belgian Blue and Piedmontese cattle[J].Genome Research,1997,17(1):71-74.
[121]Martin G B.Rapid ideatification of makers linked to a Pseudomonas resistance gene in tomato by using random primers and near-isogenic lines[J].Proc.Natl.Acad.Sci.USA,1991,88:2336-2440.
[122]Mcihelmore R W.Identification of markers linked to disease resistance genes by Bulked Segregant Analysis:A rapid method to delect markers in specific genomic regions using segregating populations[J].Proc.Natl.Acad.Sci,1991,88(1):9828-9832.
[123]白秀娟,李辉.肉鸡肥度性状RAPD标记的研究[J].东北农业大学学报,2004,35(4):432-436.
[124]姜运良,李宁.猪雌激素受体基因(ESR)点突变的PCR-SSCP检测[J].遗传,2000,22(4):214-216.
[125]Kambadur R,Sharma M,Smith T P.mutations in myostatin(GDF-8)in double-muscled Belgian Blue and Piedmontese cattle[J].Genome Research,1997,17(1):71-74.
[126]Richard J. Spelman.Quantitative trait loci analysis for rive milk production traits on chromosome six in the dutch Holstein Friesian population[J].Genetics,1996,144.1799-1808.
[127]Velmala.R.J.A search for quantitative trait loci for milk production traits on chromosome6 in Finish A yrshire cattle[J].Anim.Gene,1999,30:136.
[1]张卫红.吡啶羧酸铬对奶牛的抗应激作用[A].见:张敏红编.畜禽应激与抗应激新技术[M].北京:中国农业大学出版社,2000:86—89.
[2]梁学武,张龙涛,刘庆华等.热应激期日粮添加酵母铬对奶牛产奶性能及血液生化指标的影响[J].福建农林大学学报,2006,35(2):191-194.
[3]尹召华,邢淑芳.添加高能饲料对乳牛生产性能影响的研究[J].安徽农业科学,2006,34(24):6511-6515.
[4]阎小艳,李新浩,阎晓晖.奶牛热应激[J].动物科学与动物医学,2004,21(9):42-44.
[5]李建国,桑润滋,张正珊等.热应激对奶牛血液生化指标及生产性能的影响[J].中国奶牛,1998(6):19-20.
[6]Malmolf K. Amino acid in farm animal nutrition metabolism, partition and consequences of imbalance[J].Journal of Agricultural Research 1988,18:191-193.
[7]CHANGX,MALLARDBA,MOWATDN.Effects of chromium on health status, blood neutrophil phagocytosis and in vitro lymphocyte blastobenesis of dairy cows[J].Vet Immunol immunopath,1996,52(1):37-52.
[8]H. M. Burrow and K. C.Prayaga.Correlated responses in productive and adaptive traits and temperament following selection for growth and heat resistance in tropical beef cattle[J].Livestock Production Science.2004,86(13):143-161.
[9]L. Avendano-Reyes, F.D.Alvarez-Valenzuela, A. Correa-Calderon, J.S.Saucedo-Quintero, P.H.Robinson and J.G. Fadel,Effect of cooling Holstein cows during the dry period on postpartum performance under heat stress conditions[J].Livestock Science,2006,105(1-3):198-206.
[10]Saiadymy, Shaikhma, Mufarrejsi, et al.Effect of chelated chromium supp lementation on
lactation performance and blood parameters of Holstein cows under heat stress [J].Animal Feed Science and Technology,2004,117:223-233.
[11]王吉峰,王加启.奶牛营养代谢对乳脂合成调控机制的研究进展[J].中国畜牧兽医,2003,30(2):6-10.
[12]夏伦志,蔡东等.半胱胺补饲模式对奶牛生产性能及血清胰岛素水平的影响[J].中国畜牧杂志,2005,41(2):27-29.
[13]樊华,樊丽.热应激对泌乳奶牛血液生化指标的影响[J].中国畜牧兽医,2007,34(4):45-46.
[14]杨笃宝,吕品.热应激对奶牛抗氧化性能的影响[J].动物医学进展,2006,27:99-100.
[15]贾磊,王加启.日粮阴阳离子差对泌乳前期热应激奶牛血液酸碱平衡和生产性能的影响[J].动物营养学报,2007,19(6):663-670.
[16]李新建,高腾云.烟酸和烟酸铬对热应激奶牛产奶性能、血液生理生化指标的影响[J].家畜生态学报,2006,27(5):26-31.
[17]刘强,黄应祥.中草药对奶牛泌乳性能和血液生化指标的影响[J].中国畜牧兽医,2007,40(3):24-27.
[18]魏学良,张家骅.高温环境对奶牛生理活动及生产性能的影响[J].中国农学通报,21(5):13-15.
[19]张龙涛.奶牛日粮添加酵母铬的效应研究.福建农林大学硕士论文,2004.
[20]夏东,杨淑晶,刘铁铮.奶牛血液抗氧化酶活性的季节变化[J].家畜生态学,27(1):57-59.
[21]Jenkins,T.C Palmquist.Effects of fatty acids or calcium soaps on rumen and total nutrient digestibility of dairy rations[J].Dairy Science,1984,67:978-986.
[22]HOFFMAN,P.C.COMBS,D.K.CASLER,M.D.Performance of lactating dairy cows fed alfalfa silage or perennial ryegrass silage[J].Journal of Dairy Science,1998,81 (1):162-168.
[23]李俊杰,桑润滋,田树军,马亚宾,周振明.热应激与牛血液成分的变化[J].家畜生态,2001,22(4):56-59.
[24]唐妓玉,袁自强,屈孝初,李文平.奶牛热应激的检测方法及防治措施[J].湖北畜牧兽医,2005,4:30-32
[25]CURTISS.Environmental management in animal agriculture[M].Ames IA:The Iowa State UnivPress,1983.
[26]刘艳琴,高洁,高玉红,江富华,李建国.炎热夏季奶牛日粮中添加脂肪酸钙对热应激影响的研究[J],草食家畜,1999,(4):37-39.
[27]李士泽,杨玉英,何晶,顾少英.北方寒区环境因素对奶牛生产性能的影响[J].黑龙江八一农垦大学学报,1999,11(3):24-26.
[28]莫放,王光文,范占炼,金遐良,易涛.保护脂肪在奶牛生产申的应用.乳业科学 与技术,2001,24(1):24-27.
[29]王俊锋,王中华,梁国义,谢宝柱.影响奶牛乳蛋白质含量的因素及营养调控技术研究[J].饲料工业,2006,27(15):47-52.
[30]史彬林,闫素梅.奶牛耐热性评定指标的研究[J].中国奶牛,1996,2:20-22.
[31]陈志伟,丁忠锋,陈凯.综合营养措施对热应激奶牛的影响[J].中国畜牧兽医,2005,5:2
[32]张纪芸,黄晓燕,刘道祯,等.肾小球疾病肾功能与甲状腺功能的相关分析.中华内分泌代谢杂志,1996,12(2):116
[33]Rich Verbeck, John F.Smith.奶牛与热应激[J].乳业科学与技术,2004,1:30-33
[1]CHANGX, MALLARDBA,MOWATDN.Effects of chromium on health status, blood neutrophil phagocytosis and in vitro lymphocyte blastogenesis of dairy cows[J].Veterinary immuno pathology,1996,52(1):37-52.
[2]H. M. Burrow and K. C. Prayaga.Correlated responses in productive and adaptive traits and temperament following selection for growth and heat resistance in tropical beef cattle[J].Livestock Production Science.2004,86(13):143-161.
[3]Avendano-Reyes L, Alvarez-Valenzuela F.D, Correa-CalderonA, Saucedo-Quintero J.S, Robinson P.H and Fadel J.G.Effect of cooling Holstein cows during the dry period on postpartum performance under heat stress conditions[J]. Livestock Science.2006,105(1-3):198-206.
[4]SAIADYMY, SHAIKHMA, MUFARREJSI, etal. Effect of chelated chromium supp lementation on lactation performance and blood parameters of Holstein cows under heat stress[J].Animal Feed Science and Technology,2004,117:223-233.
[5]Jenkins,T.C Palmquist Effects of fatty acids or calcium soaps on rumen and total[J].Nutrient digestibility of dairy rations[J].Dairy Science,1984,67:978-986.
[6]HOFFMAN P.C,COMBS D.K, CASLER M.D.Performance of lactating dairy cows fed alfalfa silage or perennial ryegrass silage[J].Journal of Dairy Science 1998,81(1):162-168.
[7]张卫红.吡啶羧酸铬对奶牛的抗应激作用[A].见:张敏红编.畜禽应激与抗应激新技术[M].北京:中国农业大学出版社,2000:86-89.
[8]梁学武,张龙涛等.热应激期日粮添加酵母铬对奶牛产奶性能及血液生化指标的影响[J].福建农林大学学报,2006,35(2):191-194.
[9]李建国,桑润滋,张正珊等.热应激对奶牛血液生化指标及生产性能的影响[J].中国奶牛,1998,(6):19-20.
[10]贾磊,王加启.日粮阴阳离子差对泌乳前期热应激奶牛血液酸碱平衡和生产性能的影响[J].动物营养学报,2007,19(6):663-670.
[11]Erdman A Ricrard.Dietary buffering requirements of the lactating dairy cow.A Review[J].J Dairy Sci,1988,71:246-3266.
[12]West J W, Haydon K D, Mullinix B G, et al.Dietary cation-anion balance and cation source effects on production and acid-base status of heat-stressed cows[J].J Dairy Sci,1992, 75:2776~2786.
[13]Escobosa A,Coppock E C. Effects of dietary sodium bicarbonate and calcium chloride on physiological responses of lactating dairy cows in hot weather [J].J Dairy Sci,1984,67:574-584.
[14]李士泽,杨玉英,何晶,顾少英.北方寒区环境因素对奶牛生产性能的影响[J].黑龙江八一农垦大学学报,1999,11(3):24-26.
[15]王俊锋,王中华,梁国义,谢宝柱影响奶牛乳蛋白质含量的因素及营养调控技术研究[J].饲料工业2006,27(15):47-52
[16]王吉峰,王加启.奶牛营养代谢对乳脂合成调控机制的研究进展[J].中国畜牧兽医2003,30(2):6-10
[17]梁学武,张龙涛,刘庆华,韩国林,陈新华.热应激期日粮添加酵母铬对奶牛产奶性能及血液生化指标的影响[J].福建农林大学学报2006,35(2):191-194
[18]CURTISS.Environmental management in animal agriculture[M].Ames IA:The Iowa State UnivPress,1983.
[19]李士泽,杨玉英,何晶,顾少英.北方寒区环境因素对奶牛生产性能的影响[J].黑龙江八一农垦大学学报,1999,11(3):24-26.
[20]史彬林,闫素梅.奶牛耐热性评定指标的研究[J].中国奶牛,1996,2:20-22.
[21]贾磊,王加启.日粮阴阳离子差对泌乳前期热应激奶牛血液酸碱平衡和生产性能的影响[J].动物营养学报,2007,19(6):663-670.
[22]樊华,樊丽.热应激对泌乳奶牛血液生化指标的影响[J].中国畜牧兽医,2007,34(4):45-46.
[23]夏伦志,蔡东等.半胱胺补饲模式对奶牛生产性能及血清胰岛素水平的影响[J].中国畜牧杂志,2005,41(2):27-29.
[24]李俊杰,桑润滋,田树军,马亚宾,周振明.热应激与牛血液成分的变化[J].家畜生态,2001,22(4):56-59.
[25]杨笃宝,吕品.热应激对奶牛抗氧化性能的影响[J].动物医学进展,2006(27):99-100.
[26]魏学良,张家骅.高温环境对奶牛生理活动及生产性能的影响[J].中国农学通报,21(5):13-15.
[1]万海伟,张传生,杜立新.正交优化法建立奶牛基因组DNA RAPD-PCR最佳反应体系[J].生物技术通报,2004(3):45-47.
[2]魏学良,张家骅.高温环境对奶牛生理活动及生产性能的影响[J].中国农学通报,21(5):13-15.
[3]樊华,樊丽.热应激对泌乳奶牛血液生化指标的影响[J].中国畜牧兽医,2007,34(4):45-46.
[4]李新建,高腾云,常智留,席进华.烟酸和烟酸铬对热应激奶牛产奶性能和血液激素水平的影响[J].华中农业大学学报,2006,25(4):411-415.
[5]沙向阳,张惠斌,周金培.以二肽基肽酶Ⅳ为靶点的抗糖尿病药物[J].药学展,2006,30(6):241-244.
[6]李祎亮,王菊仙,吴香玫,邹美香.二肽基肽酶Ⅳ抑制剂的研究进展[J].中国新药杂志,2008,17(20):1739-1745.
[7]Kazazian H H.mobile elements:driver of genome evolution [J].Science,2004,303(5664):1626-1632.
[8]Sutherland CL, Chalupny N, J Schooley K, VandenBos T, Kubin M, Cosman D.UL16-binding proteins, novel MHC class I-related proteins, bind to NKG2D and activate multiple signaling pathways in primary NK cells [J].J Immunol.2002;168(2):671-9.
[9]KLEIN J, SATIA Y, O'HU IGIN C.The molecular descent of the major histocompatibility complex[J].Annu Rev Immunol,1993,11:269-295.
[10]项伟,马建,王雪峰,赵玉军.SSCP和HMA方法在马MHC-Ⅰ类分子基因多态性研究中的应用[J].遗传,2008,30(12):1635-1639.
[11]刘云芳,剡根强,王新峰.家畜MHC的研究进展及其在遗传育种中的应用[J].黄牛杂志,2004(2):14.
[12]徐卫锋.MHC-Ⅰ类分子对外源蛋白的呈递[J].上海免疫学杂志,1999,19:380.
[13]胡雄贵,肖兵南,邓绪芳,燕海峰.荷斯坦奶牛RAPD反应条件的优化[J].畜禽业,2006,194:8-10.
[14]Ooi GT, Tawadros N, Escalona RM.Pituitary cell lines and their endocrine applications [J].Mol, Cell Endocrinol.2004,228(1-2):1-21.
[15]范少光,丁桂风.神经内分泌与免疫系统之间相互作用的介导物质—共同的生物学语言[J].生理科学进展,26(2):175-183.
[16]张纪芸,黄晓燕,刘道祯等.肾小球疾病肾功能与甲状腺功能的相关分析[J].中华内分泌代谢杂志,1996,12(2):116.