The effects of heat stress on protein metabolism in lactating Holstein cows

文献类型: 外文期刊

第一作者: Gao, S. T.

作者: Gao, S. T.;Guo, J.;Quan, S. Y.;Nan, X. M.;Fernandez, M. V. Sanz;Baumgard, L. H.;Bu, D. P.;Bu, D. P.

作者机构:

关键词: heat stress;milk protein;restricted intake;milk protein precursor;protein metabolism

期刊名称:JOURNAL OF DAIRY SCIENCE ( 影响因子:4.034; 五年影响因子:4.354 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Heat stress (HS) decreases milk protein synthesis beyond what would be expected based on the concomitant reduction in feed intake. The aim of the present study was to evaluate the direct effects of HS on milk protein production. Four multiparous, lactating Holstein cows (101 +/- 10 d in milk, 574 +/- 36 kg of body weight, 38 +/- 2 kg of milk/d) were individually housed in environmental chambers and randomly allocated to 1 of 2 groups in a crossover design. The study was divided into 2 periods with 2 identical experimental phases (control phase and trial phase) within each period. During phase 1 or control phase (9 d), all cows were housed in thermal neutral conditions (TN; 20 degrees C, 55% humidity) and fed ad libitum. During phase 2 or treatment phase (9 d), group 1 was exposed to cyclical HS conditions (32 to 36 degrees C, 40% humidity) and fed ad libitum, whereas group 2 remained in TN conditions but was pair-fed (PFTN) to their HS counterparts to eliminate the confounding effects of dissimilar feed intake. After a 30-d washout period in TN conditions, the study was repeated (period 2), inverting the environmental treatments of the groups relative to period 1: group 2 was exposed to HS and group 1. to PFTN conditions. Compared with PFTN conditions, HS decreased milk yield (17.0%), milk protein (4.1%), milk protein yield (19%), 4% fat-corrected milk (23%), and fat yield (19%). Apparent digestibility of dry matter, organic matter, neutral detergent fiber, acid detergent fiber, crude protein, and ether extract was increased (11.1-42.9%) in HS cows, as well as rumen liquor ammonia (before feeding 33.2%; after feeding 29.5%) and volatile fatty acid concentration (45.3%) before feeding. In addition, ruminal pH was reduced (9.5 and 6% before and after feeding, respectively) during HS. Heat stress decreased plasma free amino acids (AA; 17.1%) and tended to increase and increased blood, urine, and milk urea nitrogen (17.2, 243, and 24.5%, respectively). Further, HS cows had reduced plasma glucose (8%) and nonesterified fatty acid (39.8%) concentrations compared with PFTN controls. These data suggest that HS increases systemic AA utilization (e.g., decreased plasma AA and increased nitrogen excretion), a scenario that limits the AA supply to the mammary gland for milk protein synthesis. Furthermore, the increase in AA requirements during HS might represent the increased need for gluconeogenic precursors, as HS is thought to prioritize glucose utilization as a fuel at the expense of nonesterified fatty acids.

分类号: TS252

  • 相关文献

[1]Blood amino acids profile responding to heat stress in dairy cows. Guo, Jiang,Bu, Dengpan,Wang, Jiaqi,Guo, Jiang,Gao, Shengtao,Quan, Suyu,Zhang, Yangdong,Bu, Dengpan,Wang, Jiaqi,Bu, Dengpan,Bu, Dengpan. 2018

[2]NPR1-dependent salicylic acid signaling is not involved in elevated CO2-induced heat stress tolerance in Arabidopsis thaliana. Li, Xin,Ahammed, Golam Jalal,Li, Xin,Yu, Jingquan,Shi, Kai. 2015

[3]A Comparison of Milk Protein, Amino Acid and Fatty Acid Profiles of River Buffalo and Their F1 and F2 Hybrids with Swamp Buffalo in China. Ren, Da-xi,Chen, You-liang,Liu, Jian-xin,Zou, Cai-xia,Lin, Bo,Liang, Xian-wei. 2015

[4]Ratio of lysine to methionine alters expression of genes involved in milk protein transcription and translation and mTOR phosphorylation in bovine mammary cells. Nan, Xuemei,Bu, Dengpan,Li, Xiyan,Wang, Jiaqi,Wei, Hongyang,Hu, Han,Zhou, Lingyun,Loor, Juan J.,Loor, Juan J..

[5]Separation and quantification of milk casein from different buffalo breeds. Li, Shanshan,Liu, Jianxin,Ren, Daxi,Li, Ling,Zeng, Qingkun,Li, Ling.

[6]Proteomic analysis of cow, yak, buffalo, goat and camel milk whey proteins: Quantitative differential expression patterns. Yang, Yongxin,Bu, Dengpan,Zhao, Xiaowei,Sun, Peng,Wang, Jiaqi,Zhou, Lingyun,Yang, Yongxin,Zhao, Xiaowei.

[7]D-Glucose and amino acid deficiency inhibits casein synthesis through JAK2/STAT5 and AMPK/mTOR signaling pathways in mammary epithelial cells of dairy cows. Zhang, M. C.,Zhao, S. G.,Wang, S. S.,Luo, C. C.,Gao, H. N.,Zheng, N.,Wang, J. Q.,Zhang, M. C.,Zhao, S. G.,Wang, S. S.,Luo, C. C.,Gao, H. N.,Zheng, N.,Wang, J. Q.,Zhang, M. C.,Zhao, S. G.,Wang, S. S.,Luo, C. C.,Gao, H. N.,Zheng, N.,Wang, J. Q.,Zhang, M. C.,Zhao, S. G.,Wang, S. S.,Luo, C. C.,Gao, H. N.,Zheng, N.,Wang, J. Q.. 2018

[8]Short communication: Effects of replacing part of corn silage and alfalfa hay with Leymus chinensis hay on milk production and composition. Yan, R.,Han, J.,Zhang, Y.,Chen, S.,Undersander, D.,Zhang, Xian.

[9]A rapid analytical method of major milk proteins by reversed-phase high-performance liquid chromatography. Ma, Lu,Yang, Yongxin,Chen, Jingting,Wang, Jiaqi,Bu, Dengpan,Ma, Lu,Bu, Dengpan,Bu, Dengpan. 2017

[10]Genome-wide characterization of differentially expressed genes provides insights into regulatory network of heat stress response in radish (Raphanus sativus L.). Wang, Ronghua,Xu, Liang,Wang, Yan,Liu, Liwang,Wang, Ronghua,Mei, Yi,Guo, Jun,Zhu, Xianwen. 2018

[11]mRNA Expression of Glutathione S-Transferase Pi (GSTP1) under Heat Stress and Association of Genotypes with Heat Tolerance Ability in Holstein. Lai, Song-Jia,Li, Qiu-Ling,Wang, Chang-Fa,Wang, Hong-Mei,Zhong, Ji-Feng. 2011

[12]Genome-Wide Identification and Expression Profile of Dof Transcription Factor Gene Family in Pepper (Capsicum annuum L.). Wu, Zhiming,Bang, Guansheng,Cheng, Jiaowen,Cui, Junjie,Hu, Kailin,Xu, Xiaowan,Luo, Xirong,Chen, Xiaocui,Tang, Xiangqun,Qin, Cheng,Qin, Cheng. 2016

[13]Characterization of HSP70 and its expression in tissue: correlation with physiological and immune indices in goose (Anser cygnoides) serum. Zhang, W. W.,Zhang, X. Q.,Kong, L. N.,Luo, Q. B.,Zhang, W. W.,Xiao, X.,Gan, J. K.,Zhang, X. Q.,Kong, L. N.,Luo, Q. B.. 2015

[14]Heat stress inhibits proliferation, promotes growth, and induces apoptosis in cultured Lantang swine skeletal muscle satellite cells. Gao, Chun-qi,Zhao, Yin-ling,Sui, Wei-guo,Yan, Hui-chao,Wang, Xiu-qi,Li, Hai-chang. 2015

[15]Effect of Heat Stress on the Photosynthetic Characteristics in Flag Leaves at the Grain-Filling Stage of Different Heat-Resistant Winter Wheat Varieties. Feng, B.,Liu, P.,Li, G.,Dong, S. T.,Zhang, J. W.,Feng, B.,Wang, F. H.,Kong, L. A.. 2014

[16]Effects of heat stress on gene expression in eggplant (Solanum melongema L.) seedlings. Li, Yanyan,Li, Zhiliang,Li, Zhenxing,Luo, Shaobo,Sun, Baojuan,Li, Yanyan. 2011

[17]The newly identified heat-stress sensitive albino 1 gene affects chloroplast development in rice. Qiu, Zhennan,Kang, Shujing,He, Lei,Zhao, Juan,Zhang, Sen,Hu, Jiang,Zeng, Dali,Zhang, Guangheng,Dong, Guojun,Gao, Zhenyu,Ren, Deyong,Chen, Guang,Guo, Longbiao,Qian, Qian,Zhu, Li. 2018

[18]Heat stress impairs the nutritional metabolism and reduces the productivity of egg-laying ducks. Ma, Xianyong,Lin, Yingcai,Zhang, Hanxing,Chen, Wei,Wang, Shang,Ruan, Dong,Jiang, Zongyong,Ma, Xianyong,Lin, Yingcai,Zhang, Hanxing,Chen, Wei,Wang, Shang,Ruan, Dong,Jiang, Zongyong,Ma, Xianyong,Lin, Yingcai,Zhang, Hanxing,Chen, Wei,Wang, Shang,Ruan, Dong,Jiang, Zongyong. 2014

[19]Dwarfing apple rootstock responses to elevated temperatures: A study on plant physiological features and transcription level of related genes. Zhou Bei-bei,Sun Jian,Liu Song-zhong,Jin Wan-mei,Zhang Qiang,Wei Qin-ping. 2016

[20]Overexpression of heat shock protein 70 and its relationship to intestine under acute heat stress in broilers: 2. Intestinal oxidative stress. Gu, X. H.,Hao, Y.,Wang, X. L.. 2012

作者其他论文 更多>>

微信小程序