Holstein white coat color and performance: phenotypic, genetic and environmental correlations

Becerril, Carlos M.; Wilcox, Charles J.; Guerrero, Victor M.

doi:10.1590/S0100-84551996000400009

Abstract

Correlations of measures of percentages of white coat color, five measures of production and two measures of reproduction were obtained from 4293 first lactation Holsteins from eight Florida dairy farms. Percentages of white coat color were analyzed as recorded and transformed by an extension of Box-Cox procedures. Statistical analyses were by derivative-free restricted maximum likelihood (DFREML) with an animal model. Phenotypic and genetic correlations of white percentage (not transformed) were with milk yield, 0.047 and 0.097; fat yield, 0.002 and 0.004; fat percentage, -0.047 and -0.090; protein yield, 0.024 and 0.048; protein percentage, -0.070 and -0.116; days open, -0.012 and -0.065; and calving interval, -0.007 and -0.029. Changes in magnitude of correlations were very small for all variables except days open. Genetic and phenotypic correlations of transformed values with days open were -0.027 and -0.140. Modest positive correlated responses would be expected for white coat color percentage following direct selection for milk, fat, and protein yields, but selection for fat and protein percentages, days open, or calving interval would lead to small decreases.

Holstein; phenotypic; genetic; environmental

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Holstein white coat color and performance: phenotypic, genetic and environmental correlations^* * Florida Agricultural Experiment Journal Series Number R03188.

Carlos M. Becerril^I; Charles J. Wilcox^II; Victor M. Guerrero^III

^IPrograma de Ganaderia, Colegio de Postgraduados, Chapingo, Edo. de Mexico, CP 56230, Mexico

^IIDepartment of Dairy and Poultry Sciences, University of Florida, P.O. Box 110920, Gainesville, FL 32611-0920, USA. Send correspondence to C.J.W.

^IIIDepartamento de Estadistica, Instituto Tecnologio Autonomo de Mexico, Mexico City, 01000, Mexico

ABSTRACT

Correlations of measures of percentages of white coat color, five measures of production and two measures of reproduction were obtained from 4293 first lactation Holsteins from eight Florida dairy farms. Percentages of white coat color were analyzed as recorded and transformed by an extension of Box-Cox procedures. Statistical analyses were by derivative-free restricted maximum likelihood (DFREML) with an animal model. Phenotypic and genetic correlations of white percentage (not transformed) were with milk yield, 0.047 and 0.097; fat yield, 0.002 and 0.004; fat percentage, -0.047 and -0.090; protein yield, 0.024 and 0.048; protein percentage, -0.070 and -0.116; days open, -0.012 and -0.065; and calving interval, -0.007 and -0.029. Changes in magnitude of correlations were very small for all variables except days open. Genetic and phenotypic correlations of transformed values with days open were -0.027 and -0.140. Modest positive correlated responses would be expected for white coat color percentage following direct selection for milk, fat, and protein yields, but selection for fat and protein percentages, days open, or calving interval would lead to small decreases.

Keywords: Holstein; phenotypic; genetic; environmental.

Becerril, C.M. and Wilcox, C.J. (1992). Determination of percentage of white coat color from registry certificates in Holsteins. J. Dairy Sci. 75: 3582-3586.
Becerril, C.M., Wilcox, C.J., Lawlor, T.J., Wiggans, G.R. and Webb, D.W. (1993). Effects of percentage of white coat color on Holstein production and reproduction in a subtropical environment. J. Dairy Sci. 76: 2286-2291.
Becerril, C.M., Wilcox, C.J., Wiggans, G.R. and Sigmon, K.N. (1994a). Transformation of measurements of Holstein white coat color percentages and estimation of heritability. J. Dairy Sci. 77: 2651-2657.
Becerril, C.M., Wilcox, C.J., Campos, M.S. and Hansen, P.J. (1994b). Genetic effects and relationship of milk production and percentage of white coat in a subtropical Holstein herd. Braz. J. Genet. 17: 65-68.
Bray, D.R. and Shearer, J.K. (1988). Environmental modifications on Florida dairies. In: Proceedings of 5th Florida Dairy Production Conference. Gainesville, FL, pp. 52.
Briquet, R. and Lush, J.L. (1947). Heritability of amount of spotting in Holstein-Friesian cattle. J. Hered. 38: 99-105.
Dunn, L.C., Webb, H.F. and Schneider, M. (1923). The inheritance of degrees of spotting in Holstein cattle. J. Hered. 14: 229-240.
Finch, V.A. (1983). Heat as a stress factor in herbivores under tropical conditions. In: Herbivore Nutrition in the Subtropics and Tropics (Gilchrist, F.M.C. and Mackie, R.I., eds.). The Science Press (PYT), Craighill, South Africa, pp. 88.
Finch, V.A. (1986). Body temperature in beef cattle: Its control and relevance to production in the tropics. J. Anim. Sci. 62: 531-542.
Guerrero, V.M. and Johnson, R.A. (1984). Transformation of grouped data to near normality. Ins. Math. Econ. 3: 257-362.
Hansen, P.J. (1990a). Effects of coat colour on physiological responses to solar radiation in Holsteins. Vet. Rec. 127: 333-334.
Hansen, P.J. (1990b). Can cattle be made resistant to heat stress? In: Proceedings of International Conference on Livestock in the Tropics. Gainesville, FL, pp. C-18.
King, V.L., Denise, S.K., Armstrong, D.V. and Torabi, M. (1988). Effects of a hot climate on the performance of first lactation Holstein cows grouped by coat color. J. Dairy Sci. 71: 1093-1096.
Koger, M. and Mankin, J.D. (1952). Heritability of intensity of red color in Hereford cattle. J. Hered. 43: 15-17.
Meyer, K. (1991a). Estimating variances and covariances for multivariate animal models by restricted maximum likelihood. Genet. Sel. Evol. 23: 67-83.
Meyer, K. (1991b). DFREML v2.0. User Notes. Univ. New England. Armidale, New South Wales, Australia.

*

Florida Agricultural Experiment Journal Series Number R03188.

Publication Dates

Publication in this collection
27 Oct 2006
Date of issue
1996

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Becerril, C.M. and Wilcox, C.J. (1992). Determination of percentage of white coat color from registry certificates in Holsteins. J. Dairy Sci. 75: 3582-3586.

[2] Becerril, C.M., Wilcox, C.J., Lawlor, T.J., Wiggans, G.R. and Webb, D.W. (1993). Effects of percentage of white coat color on Holstein production and reproduction in a subtropical environment. J. Dairy Sci. 76: 2286-2291.

[3] Becerril, C.M., Wilcox, C.J., Wiggans, G.R. and Sigmon, K.N. (1994a). Transformation of measurements of Holstein white coat color percentages and estimation of heritability. J. Dairy Sci. 77: 2651-2657.

[4] Becerril, C.M., Wilcox, C.J., Campos, M.S. and Hansen, P.J. (1994b). Genetic effects and relationship of milk production and percentage of white coat in a subtropical Holstein herd. Braz. J. Genet. 17: 65-68.

[5] Bray, D.R. and Shearer, J.K. (1988). Environmental modifications on Florida dairies. In: Proceedings of 5th Florida Dairy Production Conference. Gainesville, FL, pp. 52.

[6] Briquet, R. and Lush, J.L. (1947). Heritability of amount of spotting in Holstein-Friesian cattle. J. Hered. 38: 99-105.

[7] Dunn, L.C., Webb, H.F. and Schneider, M. (1923). The inheritance of degrees of spotting in Holstein cattle. J. Hered. 14: 229-240.

[8] Finch, V.A. (1983). Heat as a stress factor in herbivores under tropical conditions. In: Herbivore Nutrition in the Subtropics and Tropics (Gilchrist, F.M.C. and Mackie, R.I., eds.). The Science Press (PYT), Craighill, South Africa, pp. 88.

[9] Finch, V.A. (1986). Body temperature in beef cattle: Its control and relevance to production in the tropics. J. Anim. Sci. 62: 531-542.

[10] Guerrero, V.M. and Johnson, R.A. (1984). Transformation of grouped data to near normality. Ins. Math. Econ. 3: 257-362.

[11] Hansen, P.J. (1990a). Effects of coat colour on physiological responses to solar radiation in Holsteins. Vet. Rec. 127: 333-334.

[12] Hansen, P.J. (1990b). Can cattle be made resistant to heat stress? In: Proceedings of International Conference on Livestock in the Tropics. Gainesville, FL, pp. C-18.

[13] King, V.L., Denise, S.K., Armstrong, D.V. and Torabi, M. (1988). Effects of a hot climate on the performance of first lactation Holstein cows grouped by coat color. J. Dairy Sci. 71: 1093-1096.

[14] Koger, M. and Mankin, J.D. (1952). Heritability of intensity of red color in Hereford cattle. J. Hered. 43: 15-17.

[15] Meyer, K. (1991a). Estimating variances and covariances for multivariate animal models by restricted maximum likelihood. Genet. Sel. Evol. 23: 67-83.

[16] Meyer, K. (1991b). DFREML v2.0. User Notes. Univ. New England. Armidale, New South Wales, Australia.

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Holstein white coat color and performance: phenotypic, genetic and environmental correlations

Abstract

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