我国主要肉牛品种生长曲线拟合分析

doi:10.19788/j.issn.2096-6369.200408

农业大数据学报 ›› 2020, Vol. 2 ›› Issue (4): 63-69.doi: 10.19788/j.issn.2096-6369.200408

• 专题——农业基础性长期性科技工作 • 上一篇下一篇

我国主要肉牛品种生长曲线拟合分析

安炳星^1,^2,³(), 张路培^1,^2,³, 段星海¹, 张家春¹, 赵屿姗¹, 熊兰玲¹, 朱波¹, 李岩⁴, 徐凌洋¹, 袁维峰¹, 张军民¹, 李俊雅¹(), 高会江¹

^1.中国农业科学院北京畜牧兽医研究所，北京 100193
^2.国家肉牛遗传评估中心，北京 100193
^3.农业农村部动物遗传育种与繁殖重点实验室，北京 100193
^4.锡林郭勒盟乌拉盖管理区兽医局，乌拉盖 026321

收稿日期:2021-01-04 出版日期:2020-12-26 发布日期:2021-03-11
通讯作者: 李俊雅 E-mail:ABX2HF@126.com;lijunya@caas.cn
作者简介:安炳星，男，博士研究生，研究方向：肉牛遗传育种; E-mail: ABX2HF@126.com
基金资助:
农业科技创新联盟建设-农业基础性长期性科研工作(Y2017LM05);国家肉牛牦牛产业技术体系岗位科学家经费(CARS-37);中央级公益性科研院所基本科研业务费专项资金项目“长期监测畜禽种质资源与育种群体性能”(2020-YWF-ZX-05)

Growth Curve Fitting Analysis of Main Beef Cattle Breeds in China

Bingxing An^1,^2,³(), Lupei Zhang^1,^2,³, Xinghai Duan¹, Jiachun Zhang¹, Yushan Zhao¹, Lanling Xiong¹, Bo Zhu¹, Yan Li⁴, Lingyang Xu¹, Weifeng Yuan¹, Junmin Zhang¹, Junya Li¹(), Huijiang Gao¹

^1.Institute of Animal Sciences, Chinese Academy of Agriculture Sciences, Beijing 100193, China
^2.National Center of Beef Cattle Genetic Evalution, Beijing 100193, China
^3.Key Laboratory of Animal Genetics Breeding and Reproduction, Ministry of Agriculture and Rural Affairs, Beijing 100193, China
^4.Veterinary Bureau of Wulagai Precinct in Xilin Gol League, Wulagai 026321, China

Received:2021-01-04 Online:2020-12-26 Published:2021-03-11
Contact: Junya Li E-mail:ABX2HF@126.com;lijunya@caas.cn

摘要/Abstract

摘要： 目的

本文旨在拟合我国主要品种肉牛的生长曲线，优化体重预测模型。

方法

基于国家畜禽养殖数据中心和国家肉牛遗传评估中心收集的22个肉牛品种近6万条体重记录，本研究利用Gompertz、Logistic、Bertalanffy和Brody等四种非线性模型拟合生长发育曲线，估计模型中相应的参数，并分析了11个肉牛品种间24月龄背膘厚和眼肌面积的差异，挖掘品种特性，为后期育种选种工作提供正确的理论依据。

结果

根据模型拟合度及实际生长发育规律，为主要肉牛品种的公畜和母畜拟合了体重预测模型并估计相应参数。总的来说，各品种从初生到成熟体重呈逐增态势，整体上趋近“S”型曲线，12月龄之前增速较快，18月龄后增速减缓；公畜与母畜的发育趋势基本一致，但品种间存在一定差异，如和牛公畜前期发育速度高于安格斯牛，和牛母畜前期发育速度低于安格斯牛。结合24月龄背膘厚和眼肌面积比较，肉用型品种相较于兼用和地方黄牛品种在成熟体重和发育速度上有优势，而一些地方黄牛品种，如文山牛、渤海黑牛和南阳牛有不错的脂肪沉积能力，郏县红牛、晋南牛和三河牛表现出优良的高价值牛肉产率。

结论

本研究为我国主要肉牛品种的公畜和母畜提供了较为准确的体重预测模型，并且发现我国一些地方黄牛品种体型较小，但有较高的高价值牛肉产率。

关键词: 肉牛, 生长曲线, 背膘厚, 眼肌面积, 科学数据

Abstract: Objective

This research was conducted to fit growth curves for, and optimize body weight prediction models of, the main beef cattle breeds in China.

Methods

Based on more than 60,000 records of 22 cattle breeds collected by the National Center of Beef Cattle Genetic Evaluation, four non-linear models, namely Gompertz, logistic, von Bertalanffy and Brody, were used to fit growth curves, estimate the corresponding parameters and analyze the difference in back fat thickness and loin eye area among 11 beef cattle breeds at the age of 24 months. These models were used to determine breed characteristics and provide an accurate theoretical basis for future breeding programs.

Results

According to the R^2 and actual growth laws, the optimal weight prediction models were selected for male and female cattle and the corresponding parameters were estimated. Overall, the body weight of each breed gradually increased from birth to maturity, approaching the “S” curve. The growth rate was faster before 12 months of age, and then gradually decreased after 18 months of age. The growth trend of male and female cattle was essentially the same, but there were certain differences between breeds; for example, Wagyu bulls showed higher growth rates in early stages than Angus, and Wagyu cows showed lower growth rates in early stages than Angus. Meat-type breeds had advantages in mature weight and growth speed compared with dual purpose and local cattle breeds. When compared for back fat thickness and loin eye area at the age of 24 months, some local breeds such as Wenshan cattle, Bohai Black cattle and Nanyang cattle had greater fat deposition, and Jiaxian Red cattle, Jinnan cattle and Sanhe cattle were superior in meat production.

Conclusion

This study provides more accurate weight prediction models than were previously available for bulls and cows of the major beef cattle breeds in China. Although some local cattle breeds are small in body size, they have the potential to produce high-quality beef products.

Key words: beef cattle, growth curves, back fat thickness, loin eye area, scientific data

中图分类号:

S823

安炳星, 张路培, 段星海, 张家春, 赵屿姗, 熊兰玲, 朱波, 李岩, 徐凌洋, 袁维峰, 张军民, 李俊雅, 高会江. 我国主要肉牛品种生长曲线拟合分析[J]. 农业大数据学报, 2020, 2(4): 63-69.

Bingxing An, Lupei Zhang, Xinghai Duan, Jiachun Zhang, Yushan Zhao, Lanling Xiong, Bo Zhu, Yan Li, Lingyang Xu, Weifeng Yuan, Junmin Zhang, Junya Li, Huijiang Gao. Growth Curve Fitting Analysis of Main Beef Cattle Breeds in China[J]. Journal of Agricultural Big Data, 2020, 2(4): 63-69.

图/表 6

表1

表2

生长曲线模型"

模型 Model	函数表达式 Function
Gompertz	$w i = A e x p (- b e x p - k t)$
Logistic	$w i = A (1 + b e x p - k t) - 1$
Bertalanffy	$w i = A (1 - b e x p - k t) 3$
Brody	$w i = A (1 - b e x p - k t)$

表2

表3

图1

图2

图3

参考文献 16

1	Fitzhugh H A. Analysis of growth curves and strategies for altering their shape.[J]. Journal of animal science, 1976, 42(4).
2	梁永虎,朱波,金生云,等. 肉用西门塔尔牛群体生长曲线拟合及体重与体尺相关性分析的研究[J]. 畜牧兽医学报,2018, 49(03): 497-506.
	Liang Y H, Zhu B, Jin Y S, et al. The Growth Curve Fitting and the Correlation Analysis between Body Weight and Body Measurements in Chinese Simmental Beef Cattle Population[J]. Acta Veterinaria Et Zootechnica Sinica,2018,49(03): 497-506.
3	刘丽元,周靖航,李金芝,等. 新疆褐牛母牛早期生长曲线拟合研究[J]. 中国畜牧杂志, 2015, 51(19): 4-8.
	Liu L Y, Zhou J H, Li J Z, et al. Fitting of the Early Growth Curve for Growing Xinjiang Brown Cattle[J]. Chinese Journal of Animal Science, 2015, 51(19): 4-8.
4	杨运清,杨玉林. 动物生长模型参数的常规估计法[J]. 东北农业大学学报, 1994(02): 132-137.
	Yang Y Q, Yang Y L. Routine Parameter Estimation Methods for Animal Growth Models[J]. Journal of Northeast Agricultural University, 1994(02): 132-137.
5	Bullock K D, Bertrand J K, Benyshek L L. Genetic and environmental parameters for mature weight and other growth measures in Polled Hereford cattle[J]. Journal of animal science, 1993, 71(7):1737-1741.
6	Beltrán J J, Butts W T, Olson T A, et al. Growth patterns of two lines of Angus cattle selected using predicted growth parameters[J]. Journal of animal science, 1992, 70(3): 734-741.
7	Aline C C, Matthew J K, Simone E F G E, et al. Multi-Trait GWAS and New Candidate Genes Annotation for Growth Curve Parameters in Brahman Cattle[J/OL]. PLoS ONE, 2017,10(10):e0139906. [2015-10-7] doi:10.1371/journal.pone.0139906.. doi: 10.1371/journal.pone.0139906
8	杨晓冰,陈宏,滑留帅,等. 固原地区秦川牛利杂群体生长曲线拟合分析[J]. 中国牛业科学, 2011, 37(06): 4-7.
	Yang X B, Chen H, Hua L S, et al. Growth Curve Analysis of Limousin×Qinchuan Cattle in Guyuan Region[J]. China Cattle Science, 2011, 37(06): 4-7.
9	张丽,张良志,张爱玲,等. 南阳黄牛体重曲线拟合的比较分析[J]. 广东海洋大学学报, 2008(01): 98-100.
	Zhang L, Zhang L Z, Zhang A L, et al. Growth Curve Analysis of Body Weight of Nanyang Cattle[J]. Journal of Zhanjiang Ocean University, 2008(01): 98-100.
10	蒋昊,吴宏军,刘爱荣,等. 三河牛种公牛生长曲线拟合研究[J]. 黑龙江畜牧兽医, 2017(02): 58-60.
	Jiang H, Wu H J, Liu A R, et al. Study on the Fitting of the Growth Curves for Sanhe cattle[J]. Heilongjiang Animal Science and Veterinary Medicine, 2017(02): 58-60.
11	Tony J, K. A S W. An Introduction to Latent Class Growth Analysis and Growth Mixture Modeling[J]. Social and Personality Psychology Compass, 2008, 2(1):302-317.
12	U. J S D, R. S. Invited Review: Methods to Determine Body Fat Reserves in the Dairy Cow with Special Regard to Ultrasonographic Measurement of Backfat Thickness[J]. Journal of Dairy Science, 2006, 89(1):1-14.
13	杨运清. 动物生长模型的优化拟合方法[J]. 数理统计与管理, 1991(05): 43-48.
	Yang Y Q. Optimal Fitting Methods for Animal Growth Model[J]. Journal of Applied Statistics and Management,1991(05): 43-48.
14	于志,高艳霞,曹玉凤,等. 中国荷斯坦犊牛和育成牛生长发育规律的研究[J]. 中国畜牧兽医, 2014, 41(06): 121-125.
	Yu Z, Gao Y X, Cao Y F, et al. Study on Growth and Development Pattern of Chinese Holstein Calf and Heifer[J]. China Animal Husbandry & Veterinary Medicine, 2014, 41(06): 121-125.
15	陈江凌,汪聪勇,耿繁军. 种公牛早期生长曲线分析[J]. 安徽农业科学, 2014, 42(14): 4352-4353.
	Chen J L, Wang C Y, Geng F J. Analysis of Growth Curve of Growing Bulls[J]. Journal of Anhui Agricultural Sciences, 2014, 42(14): 4352-4353.
16	王玲,左福元,周沛. 安格斯杂种后代生长曲线拟合分析[J]. 黑龙江畜牧兽医, 2007(09): 37-38.
	Wang L, Zuo F Y, Zhou P. Analysis of Growth Curve Fitting of Angus Hybrid Offspring[J]. Heilongjiang Animal Science and Veterinary Medicine, 2007(09): 37-38.

品种 Breed	公牛数 Bulls	母牛数 Cows	品种 Breed	公牛数 Bulls	母牛数 Cows
安格斯牛* Angus	587	1 457	郏县红牛* Jiaxian Red cattle	230	278
和牛 Wagyu	346	990	锦江牛 Jinjiang cattle	29	71
云岭牛 Yunling cattle	386	539	晋南牛* Jinnan cattle	271	298
西门塔尔牛(兼用型)* Simmental (dual-type)	334	1 122	鲁西牛 Luxi cattle	284	421
短角牛* Shorthorn	106	214	南阳牛* Nanyang cattle	207	351
黑西门塔尔牛 Black Simmental	20	25	皖东牛 Wandong cattle	19	70
西门塔尔牛(肉用型)* Simmental (meat-type)	2 007	3 712	文山牛* Wenshan cattle	824	1 088
夏洛来牛 Charolais	9	19	延边牛 Yanbian cattle	0	281
新疆褐牛* Xinjiang Brown cattle	0	309	延黄牛 Yanhuang cattle	0	261
渤海黑牛* Bohai Black cattle	212	130	三河牛* Sanhe cattle	0	361

品种 Breed	性别 Sex	模型 Model	A	b	k
安格斯牛 Angus	公 Bulls	Bertalanffy	927	0.6186	0.056
安格斯牛 Angus	母 Cows	Brody	700.7	0.9526	0.0422
和牛 Wagyu	公 Bulls	Bertalanffy	616.2	0.6449	0.1115
和牛 Wagyu	母 Cows	Logistic	477.7	7.6539	0.1759
西门塔尔牛（兼用） Simmental (dual-type)	公 Bulls	Bertalanffy	736.1	2.635	0.1228
西门塔尔牛（兼用） Simmental (dual-type)	母 Cows	Bertalanffy	565.7	0.9327	0.0716
短角牛 Shorthorn	公 Bulls	Brody	762.8	0.9486	0.0556
短角牛 Shorthorn	母 Cows	Brody	725.4	0.9465	0.0475
黑西门塔尔牛 Black Simmental	公 Bulls	Gomportz	941.5	2.8298	0.1057
黑西门塔尔牛 Black Simmental	母 Cows	Gomportz	769.4	2.6952	0.1128
夏洛来 Charolais	母 Cows	Brody	837.9	0.942	0.0394
云岭牛 Yunling cattle	公 Bulls	Brody	667.3	0.9562	0.0449
云岭牛 Yunling cattle	母 Cows	Brody	552.4	0.9506	0.0573
西门塔尔牛（肉用） Simmental (meat-type)	公 Bulls	Gomportz	879.4	0.6207	0.0914
西门塔尔牛（肉用） Simmental (meat-type)	母 Cows	Brody	679.1	0.5851	0.096
新疆褐牛 Xinjiang Brown cattle	母 Cows	Bertalanffy	552.7	0.5925	0.0779
延黄牛 Yanhuang cattle	母 Cows	Gomportz	522.4	2.6044	0.124
三河牛 Sanhe cattle	母 Cows	Gomportz	672.2	2.5658	0.0943
渤海黑牛 Bohai Black cattle	公 Bulls	Gomportz	824.4	3.1165	0.0766
渤海黑牛 Bohai Black cattle	母 Cows	Bertalanffy	525.5	0.5716	0.0643
郏县红牛 Jiaxian Red cattle	公 Bulls	Logistic	688.1	9.4409	0.1215
郏县红牛 Jiaxian Red cattle	母 Cows	Bertalanffy	528	0.5827	0.0699
锦江牛 Jinjiang cattle	母 Cows	gomportz	289.7	3.6135	0.1422
晋南牛 Jinnan cattle	公 Bulls	Bertalanffy	499.4	0.5901	0.0865
晋南牛 Jinnan cattle	母 Cows	Bertalanffy	435.4	0.5728	0.089
鲁西牛 Luxi cattle	公 Bulls	Gomportz	705.3	2.6365	0.0772
鲁西牛 Luxi cattle	母 Cows	Brody	585.2	0.9523	0.0373
南阳牛 Nanyang cattle	公 Bulls	Bertalanffy	542.9	0.5932	0.089
南阳牛 Nanyang cattle	母 Cows	Bertalanffy	478.5	0.5632	0.0838
皖东牛 Wandong cattle	母 Cows	Gomportz	346.7	2.6538	0.1334
文山牛 Wenshan cattle	公 Bulls	Bertalanffy	586.5	0.6619	0.0689
文山牛 Wenshan cattle	母 Cows	Bertalanffy	335.8	0.5796	0.0821
延边牛 Yanbian cattle	母 Cows	Bertalanffy	508.4	0.6087	0.1032

[1]	段博文, 王卷乐, 石蕾, 高孟绪. 前沿领域国内外典型数据库调研与启示[J]. 农业大数据学报, 2023, 5(1): 46-54.
[2]	孙雨潇, 李艳丽, 李峰, 陈谦. 国内外科学数据共享现状研究与发展建议[J]. 农业大数据学报, 2022, 4(2): 88-98.
[3]	薛沐涵, 徐硕, 刘慧媛, 鲁峰, 王宇, 李奥. 远洋渔业科学数据治理与应用服务研究[J]. 农业大数据学报, 2022, 4(2): 99-107.
[4]	王亚鹏, 张文革, 胡林, 刘婷婷, 曹姗姗, 王蕾, 孙伟. 2019年天山云杉背包式激光雷达三维参数测量数据集[J]. 农业大数据学报, 2022, 4(1): 119-124.
[5]	范亚慧, 朱亮, 赵华, 郑建华. 科学数据共享的知识产权保护研究[J]. 农业大数据学报, 2021, 3(4): 3-9.
[6]	冯小鼎, 王晓冬, 罗斌, 王成. 基于LabVIEW的植物离子吸收多参数检测系统软件研发[J]. 农业大数据学报, 2021, 3(2): 16-23.
[7]	李强, 高懋芳, 方莹. 农业大数据信息平台构建方法初探[J]. 农业大数据学报, 2021, 3(2): 24-30.
[8]	颜瑞, 王震, 李言浩, 李哲敏, 李娴. 中国农业智能传感器的应用、问题与发展[J]. 农业大数据学报, 2021, 3(2): 3-15.
[9]	王慧, 王海江, 高攀, 张泽, 侯彤瑜, 吕新. 新疆生产建设兵团农业资源数据采集与整合方法研究[J]. 农业大数据学报, 2021, 3(2): 31-41.
[10]	王晓丽, 胡乾浩, 满芮, 刘婷婷. 中国果树花期2016年近红外光谱和图像数据集[J]. 农业大数据学报, 2021, 3(1): 88-93.
[11]	庄严, 杨帅, 刘照坤, 樊景超, 周舒雅. 农业科学观测数据权属与保护路径研究[J]. 农业大数据学报, 2020, 2(4): 107-112.
[12]	王晓丽, 胡乾浩, 樊景超, 李壮. 辽北苹果叶片氮含量、近红外光谱与图像数据集[J]. 农业大数据学报, 2020, 2(4): 113-119.
[13]	高飞, 王晓丽, 刘婷婷, 李壮, 满芮. 中国苹果叶片病虫害2015年光谱和图像数据集[J]. 农业大数据学报, 2020, 2(4): 120-124.
[14]	樊景超, 满芮, 张翔鹤, 周国民. 国家农业观测数据共享元数据标准研究[J]. 农业大数据学报, 2020, 2(4): 14-19.
[15]	陈彦清, 曹永生, 林雨楠, 方沩. 国家作物种质资源观测鉴定站点体系布局方法研究[J]. 农业大数据学报, 2020, 2(4): 20-28.

我国主要肉牛品种生长曲线拟合分析

Growth Curve Fitting Analysis of Main Beef Cattle Breeds in China

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

图/表 6

参考文献 16

相关文章 15

Metrics

本文评价

推荐阅读 0