自然生产条件下热应激周期变化揭示泌乳中期奶牛出现“热应激乳蛋白降低征”

›› 2014, Vol. 41 ›› Issue (10): 73-84.

自然生产条件下热应激周期变化揭示泌乳中期奶牛出现“热应激乳蛋白降低征”

程建波^1,3, 王伟宇², 郑楠¹, 李松励¹, 张养东¹, 张幸开⁴, 袁耀明⁴, 王加启¹

1. 中国农业科学院北京畜牧兽医研究所, 北京 100193;
2. 中国人民大学附属中学, 北京 100080;
3. 安徽农业大学动物科技学院, 安徽合肥 230036;
4. 上海光明荷斯坦牧业有限公司, 上海 200436

收稿日期:2014-08-13 出版日期:2014-10-20 发布日期:2014-10-29
通讯作者: 王加启 E-mail:wang-jia-qi@263.net
作者简介:程建波(1975-),男,副教授,硕士生导师,主要从事奶牛营养与牛奶质量安全研究。E-mail: chengjianbofcy@163.com
基金资助:
现代农业产业技术体系专项资金(nycytx-04-01);国家重点基础研究发展计划(2011CB100805)

Natural Period Change of Heat Stress Reveals Unique “Heat-stressed Milk Protein Decrease Syndrome” in Mid-lactation Dairy Cows

CHENG Jian-bo^1,3, WANG Wei-yu², ZHENG Nan¹, LI Song-li¹, ZHANG Yang-dong¹, ZHANG Xing-kai⁴, YUAN Yao-ming⁴, WANG Jia-qi¹

1. Institute of Animal Sciences, Chinese Academy of Agricultural Sciences, Beijing 100193, China;
2. The High School Affiliated to Renmin University of China, Beijing 100080, China;
3. College of Animal Science and Technology, Anhui Agricultural University, Hefei 230036, China;
4. Shanghai Bright Holstein Co., Ltd., Shanghai 200436, China

Received:2014-08-13 Online:2014-10-20 Published:2014-10-29

摘要/Abstract

摘要： 本试验在连续3年时间里测定了上海地区热应激周期变化对泌乳中期奶牛生产性能和牛奶品质的影响。通过实地测定并计算分析,绘制了上海地区热应激周期变化图谱,揭示了整个热应激周期中不同热应激程度的分布状况。研究对比了自然生产环境下无热应激与中度热应激对奶牛生产性能和牛奶品质的影响,发现中度热应激极显著降低了奶牛采食量、产奶量、乳脂校正乳产量、能量校正乳产量、乳脂率、乳蛋白含量、总固体含量(P<0.01),而且显著增加了乳中尿素氮含量(P<0.05)。在热应激周期变化研究中发现,中度热应激显著升高泌乳奶牛的直肠温度和呼吸频率(P<0.05),而且呼吸频率比直肠温度对热应激变化的反应更快、更敏感。热应激周期变化对奶牛干物质采食量、产奶量的影响取决于热应激程度,2012年整个热应激周期的热应激程度比较低,热应激周期变化对奶牛干物质采食量、产奶量无显著影响(P>0.05),但是2013年热应激程度更加严重,热应激周期变化对奶牛干物质采食量、产奶量产生了极显著影响(P<0.01)。在牛奶品质中,受热应激影响最大的是乳蛋白合成量(P<0.01)。2012年和2013年2个热应激周期变化对其他乳成分含量没有显著影响(P>0.05),但是两年的热应激周期变化都导致乳蛋白含量显著下降(P<0.05)和乳中尿素氮含量显著升高(P<0.05)。尤其值得注意的是,2012年热应激周期变化并没有导致奶牛采食量下降(P>0.05),而且产奶量也没有显著性差异(P>0.05),但是仍然出现了乳蛋白含量下降和乳中尿素氮含量升高(P<0.05)。这表明热应激周期变化改变了泌乳中期奶牛氮代谢的途径,发生了氮营养重分配(repartitioning)现象,而且这种现象不依赖于采食量和产奶量,可以称之为“热应激乳蛋白降低征”(heat-stressed milk protein decrease syndrome,HS-MPD)。

关键词: 泌乳奶牛; 热应激周期; 生产性能; 乳蛋白降低征

Abstract: More than fifteen provinces in Southern China are characterized as humid tropical and subtropical regions with long period of summer. Heat stress from high ambient temperature and relative humidity is detrimental to dairy production and usually renders dairy farms in the affected regions almost profitless. But so far little information is available on annual heat stress dynamic variation and its interaction with lactating dairy cow performance. Thus,our study objectives were to record the natural period change of heat stress on practical dairy farms from 2012 to 2014,and analyze its impact on the productive performance and milk quality of mid-lactation dairy cows. Temperature and relative humidity on the dairy farm were recorded from July 12 to September 19 of 2012,July 15 to October 12 of 2013 and April 5 to 7 in 2014,respectively. Temperature-humidity index (THI) was calculated using following equation: THI=0.81xT+(0.99xT-14.3)xR+46.3,where T is temperature degree(℃),R is relative humidity(%)(NOAA,1976). According to THI,degree of heat stress can be classified into severe heat stress (THI>88),moderate heat stress (88≥THI>78),Mild heat stress (78≥THI>72) and no heat stress (THI≤72) (Armstrong,1994). During the study period,diet formula and cow management for the experimental cows kept the same as the other cows. Feed samples and milk samples were collected weekly. Rectal temperature and respiration rate were recorded in each heat stress change phase.
The experimental design was to analyze the natural period change of heat stress on the productive performance and milk quality of mid-lactation dairy cows with the data of 2012 (n=10) and 2013 (n=12). The results showed that from July to September of 2012 and July to October of 2013,the degree of heat stress can be marked off into moderate heat stress,mild heat stress and no heat stress. Dairy cows had different reaction to the heat stress cycles. Rectal temperatures and respiration rates increased during moderate heat stress (P<0.05). We found that respiration rate was more sensitive to heat stress than rectal temperature. Long term moderate heat stress significantly reduced milk yield (P<0.05).
We also found that milk protein synthesis was most susceptive to heat stress compared to other milk compositions. In 2012,milk protein content was 2.99% for no heat stress cows,but heat stress decreased it to 2.62% (P<0.05). In 2013,milk protein content was 3.41% for no heat stress cows,but only 2.90% during moderate heat stress (P<0.05). At the same time,urea nitrogen content in milk increased significantly (P<0.05). There was no significant difference for other milk compositions in 2012 and 2013 (P>0.05). A very special phenomenon was that natural period change of heat stress did not reduce dry matter intake and milk yield of the mid-lactation dairy cows in 2012 (P>0.05),but milk protein content decreased and milk urea nitrogen content increased dramatically (P<0.05). These results indicated that natural period change of heat stress may interfere with nitrogen metabolism and cause nutrition repartitioning in mid-lactation dairy cows. Such interference was independent of dry matter intake and milk yield. This unique phenomenon can be defined as "heat-stressed milk protein decrease syndrome" (HS-MPD). Heat-stressed milk protein decrease syndrome can only be revealed through the study of the long-term natural period change of heat stress.
In summary,we successfully delineated the annual natural period dynamic pattern of heat stress in southern China. The main impact of heat stress period change on productive performance and milk quality of mid-lactation Holstein cows was elucidated. Milk protein synthesis was most affected compared to other milk compositions. The synchronous decrease of milk protein content and increase of milk urea nitrogen content implies nutrition repartitioning for heat-stressed lactating dairy cows. This unique phenomenon can be denominated as "heat-stressed milk protein decrease syndrome" (HS-MPD).

Key words: dairy cow; heat stress; natural period; milk protein decrease syndrome

中图分类号:

S823

程建波, 王伟宇, 郑楠, 李松励, 张养东, 张幸开, 袁耀明, 王加启. 自然生产条件下热应激周期变化揭示泌乳中期奶牛出现“热应激乳蛋白降低征”[J]. , 2014, 41(10): 73-84.

CHENG Jian-bo, WANG Wei-yu, ZHENG Nan, LI Song-li, ZHANG Yang-dong, ZHANG Xing-kai, YUAN Yao-ming, WANG Jia-qi. Natural Period Change of Heat Stress Reveals Unique “Heat-stressed Milk Protein Decrease Syndrome” in Mid-lactation Dairy Cows[J]. , 2014, 41(10): 73-84.

参考文献

1 Armstrong D V. Heat stress interaction with shade and cooling[J]. Journal of Dairy Science,1994,77:2044~2050.
2 Baumgard L H,Wheelock J B,Sanders S R,et al. Postabsorptive carbohydrate adaptations to heat stress and monensin supplementation in lactating Holstein cows[J]. Journal of Dairy Science,2011,94:5620~5633.
3 Baumgard Lance H,Rhoads Robert P Jr. Effects of heat stress on postabsorptive metabolism and energetics[J]. Annual Review of Animal Bioscience,2013,1:311~337.
4 Beede D K,Collier R J. Potential nutritional strategies for intensively managed cattle during thermal stress[J]. Journal of Animal Science,1986,62:543~554.
5 California Department Food Agriculture. Hot topics affecting California Agriculture. 2008.Http://www.cdfa.ca.gov/exec/Public_Affairs/pdf/AGOnAg080306.pdf.
6 Cheng J B,Bu D P,Wang J Q,et al. Effects of rumen-protected γ-aminobutyric acid on performance and nutrient digestibility in heat-stressed dairy cows[J]. Journal of Dairy Science,2014,97:5599~5607.
7 Knapp D M,Grummer R R. Response of lactating dairy cows to fat supplementation during heat stress[J]. Journal of Dairy Science,1991,74:2573~2579.
8 NOAA(National Oceanic and Atmospheric Administration). Livestock hot weather stress. Regional Operations Manual Letter C-31-76. US Department of Commerce,National Weather Service Central Region,Kansas City,MO. 1976.
9 Pan L,Bu D P,Wang J Q,et al. Effects of Radix Bupleuri extract supplementation on lactation performance and rumen fermentation in heat-stressed lactating Holstein cows[J]. Animal Feed Science and Technology,2014,187:1~8.
10 Ryan D P,Bloand M P,Kopel E,et al. Evaluating two different evaporative cooling management systems for dairy cows in a hot,dry climate[J]. Journal of Dairy Science,1992,75:1052~1059.
11 Shwartz G,Rhoads M L,VanBaale M J,et al. Effects of a supplemental yeast culture on heat-stressed lactating Holstein cows[J]. Journal of Dairy Science,2009,92:935~942.
12 St-Pierre N R,Cobanov B,Schnitkey G. Economic Losses from heat stress by US livestock industries[J]. Journal of Dairy Science,2003,86(E Suppl.):E52~E77.
13 Wang J P,Bu D P,Wang J Q,et al. Effect of saturated fatty acid supplementation on production and metabolism indices in heat-stressed mid-lactation dairy cows[J]. Journal of Dairy Science,2010,93:4121~4127.
14 Wheelock J B,Rhoads R P,VanBaale M J. Effects of heat stress on energetic metabolism in lactating Holstein cows[J]. Journal of Dairy Science,2010,93:644~655.

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