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Genetic relationship between weaning weight and milk yield in Nguni cattle

Published online by Cambridge University Press:  11 July 2017

L. T. Nesengani*
Affiliation:
Animal Production Institute (ARC), Animal Breeding and Genetics Programme, Private Bag X2, Irene, 0062, South Africa
K. A. Nephawe
Affiliation:
Tshwane University of Technology (TUT), Private Bag X680, Pretoria, 0001, South Africa
J. Sebei
Affiliation:
Limpopo Department of Agriculture, 69 Biccard Street, Private Bag X9487, Polokwane, 0700, South Africa
D. Norris
Affiliation:
University of Limpopo, Turfloop Campus, Private Bag X1106, Sovenga, 0727, South Africa
A. Maiwashe
Affiliation:
Animal Production Institute (ARC), Animal Breeding and Genetics Programme, Private Bag X2, Irene, 0062, South Africa
*
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Abstract

A study was conducted to estimate the genetic relationship between weaning weight and milk yield in Nguni cattle. Milk yield data (n=125) were collected from 116 Nguni cows from Mara Research Station located in Limpopo Province and Loskop South Farm located in Mpumalanga Province using the weigh-suckle-weigh technique. Weaning weight data (n=19 065) were obtained from stud Nguni cattle from 146 herds distributed throughout South Africa. Estimates of (co)variance components for milk yield and weaning weight were calculated using PEST and VCE softwares. The average weaning weight, age of the calf at weaning and 24-h milk yield was 158.94 kg, 210 days and 5.25 kg/day, respectively. Heritability estimates for milk yield, direct and maternal weaning weight were 0.22±0.238, 0.47±0.039 and 0.25±0.029, respectively. Estimates of genetic correlations for milk yield and maternal weaning weight, milk yield and direct weaning weight, direct and maternal weaning weight were 0.97±0.063, −0.71±0.416 and −0.56±0.247, respectively. The results indicate that maternal weaning weight is genetically highly predictive of milk yield in Nguni cattle. Maternal breeding values for weaning weight could therefore be used as a selection criterion to improve milk yield in Nguni cattle.

Type
Research Article
Copyright
© The Animal Consortium 2017 

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Footnotes

a

These two authors contributed equally to this work.

References

Beal, WE, Notter, DR and Akers, RM 1990. Techniques for estimation of milk yield in beef cows and relationships of milk yield to calf weight gain and postpartum reproduction. Journal of Animal Science 68, 937943.Google Scholar
Carvalheira, JG, Blake, RW, Pollak, EJ and Van soest, PJ 1995. Comparison of Landim and Afrikaner cattle in Southern Mozambique: I. Body weights and growth. Journal of Animal Science 73, 35193526.Google Scholar
Clutter, AC and Nielsen, MK 1987. Effect of level of beef cow milk production on pre- and post-weaning calf growth. Journal of Animal Science 64, 13131322.Google Scholar
Collins-Lusweti, E 2000. The performance of the Nguni, Afrikaner and Bonsmara cattle breeds in developing areas of Southern Africa. South African Journal of Animal Science 30, 2828.Google Scholar
Eler, JP, Van vleck, LD, Ferraz, JB and Lôbo, RB 1995. Estimation of variances due to direct and maternal effects for growth traits of Nelore cattle. Journal of Animal Science 73, 32533258.CrossRefGoogle ScholarPubMed
Gregory, KE and Cundiff, LV 1980. Crossbreeding in beef cattle: evaluations of systems. Journal of Animal Science 51, 12241242.Google Scholar
Gregory, KE, Cundiff, LV and Koch, RM 1992. Effects of breed and retained heterosis on milk yield and 200-day weight in advanced generations of composite generations of beef cattle. Journal of Animal Science 70, 23662372.Google Scholar
Groeneveld, E 1998. VCE4 Version 4.3.0 user’s guide and reference manual. Mariensee, Germany. Google Scholar
Kars, AA, Erasmus, GJ and Van der westhuizen, J 1994. Factors influencing growth traits in the Nguni cattle stud at Bartlow Combine. South African Journal of Animal Science 24, 1821.Google Scholar
Lee, C and Pollak, EJ 2002. Genetic antagonism between body weight and milk production in beef cattle. Journal of Animal Science 80, 316321.CrossRefGoogle ScholarPubMed
Macneil, MD and Mott, TB 2006. Genetic analysis of gain from birth to weaning, milk production, and udder conformation in Line 1 Hereford cattle. Journal of Animal Science 84, 16391645.Google Scholar
Maiwashe, A, Nengovhela, NB, Nephawe, KA, Sebei, J, Netshilema, T, Mashaba, HD, Nesengani, L and Norris, D 2013. Estimates of lactation curve parameters for Bonsmara and Nguni cattle using the weigh-suckle-weigh technique. South African Journal of Animal Science 43, 1216.Google Scholar
Mallinckrodt, CH, Bourdon, RM, Golden, BL, Schalles, RR and Odde, KG 1993. Relationship of maternal milk expected progeny differences to actual milk yield and calf weaning weight. Journal of Animal Science 71, 355362.Google Scholar
Melton, AA, Riggs, JK, Nelson, LA and Cartwright, TC 1967. Milk production, composition and calf gains of Angus, Charolais and Hereford cows. Journal of Animal Science 26, 804809.Google Scholar
Meyer, K, Carrick, MJ and Donnelly, BJ 1994. Genetic parameters for milk production of Australian beef cows and weaning weight of their calves. Journal of Animal Science 72, 11551165.CrossRefGoogle ScholarPubMed
Miller, SP and Wilton, JM 1999. Genetic relationship among direct and maternal components of milk yield and maternal weaning gain in a multibreed beef herd. Journal of Animal Science 77, 11551161.CrossRefGoogle Scholar
Ndofor-foleng, HM, Ebangi, AL, Agu, CI and Okenyi, N 2012. Estimation of genetic parameters for pre-weaning and post-weaning growth traits in the Gudali beef cattle using multiple traits Derivative-Free Restricted Maximum Likelihood. African Journal of Biotechnology 11, 1441014416.Google Scholar
Neser, FWC, Van wyk, JB, Fair, MD, Lubout, P and Crook, B.J 2012. Estimation of genetic parameters for growth traits in Brangus cattle. South African Journal of Animal Science 42, 469473.Google Scholar
Norris, D, Banga, C, Benyi, K and Sithole, BC 2004. Estimation of genetic parameters and variance components for growth traits of Nguni Cattle in Limpopo Province, South Africa. Tropical Animal Health and Production 36, 801806.Google Scholar
Statistical Analysis Systems 2012. SAS Release 9.3. Statistical Analysis System Institute, Inc., Cary, NC, USA.Google Scholar
Scholtz, MM and Theunissen, A 2010. The use of indigenous cattle interminal cross-breeding to improve beef cattle production in Sub-Saharan Africa. Animal Genetic Resources 46, 3339.Google Scholar
Splan, RK, Cundiff, LV, Dikeman, ME and Van vleck, LD 2002. Estimates of parameters between direct and maternal genetic effects for weaning weight and direct genetic effects for carcass traits in crossbred cattle. Journal of Animal Science 80, 31073111.CrossRefGoogle ScholarPubMed
Van Niekerk, M and Neser, FWC 2006. Genetic parameters for growth traits in South African Limousin cattle. South African Journal of Animal Science 36, 69.Google Scholar
Van niekerk, M, Neser, fwc and Van wyk, JB 2004. (Co) variance components for growth traits in the Nguni cattle breed. South African Journal of Animal Science 34, 113115.Google Scholar
Wasike, CB, Indetie, D, Ojango, JMK and Kahi, AK 2009. Direct and maternal (co)variance components and genetic parameters for growth and reproductive traits in the Boran cattle in Kenya. Tropical Animal Health Production 41, 741748.Google Scholar