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RESEARCH ARTICLE

The genetics of cow growth and body composition at first calving in two tropical beef genotypes

M. L. Wolcott A B D , D. J. Johnston A B , S. A. Barwick A , N. J. Corbet A C and P. J. Williams A C
+ Author Affiliations
- Author Affiliations

A Cooperative Research Centre for Beef Genetic Technologies, Armidale, NSW 2351, Australia.

B Animal Genetics and Breeding Unit1

1AGBU is a joint venture of NSW Department of Primary Industries and the University of New England.

, University of New England, Armidale, NSW 2351, Australia.

C CSIRO Livestock Industries, Rockhampton, Qld 4702, Australia.

D Corresponding author. Email: mwolcott@une.edu.au

Animal Production Science 54(1) 37-49 https://doi.org/10.1071/AN12427
Submitted: 14 December 2012  Accepted: 23 May 2013   Published: 20 August 2013

Abstract

The genetics of cow growth and body composition traits, measured before first calving (pre-calving: in females before calving following their first 3-month annual mating period, at an average age of 34 months) and at the start of the subsequent mating period (Mating 2: on average 109 days later), were evaluated in 1016 Brahman (BRAH) and 1094 Tropical Composite (TCOMP) cows. Measurements analysed were liveweight, ultrasound-scanned measurements of P8 and 12/13th rib fat depth and eye muscle area, body condition score and hip height. Traits describing the change in these from pre-calving to Mating 2 were also included in the analysis. The maternal genetic component of weaning weight was estimated from weaning-weight records on these cows, their steer half-sibs and their progeny generated from up to six matings (n = 12 528). Within pregnant cows at pre-calving, BRAH were significantly lighter, leaner at the P8 site and taller than their TCOMP contemporaries, and these differences were also significant at Mating 2. There was a genetic basis for variation in growth and body composition traits measured at pre-calving and Mating 2 in BRAH (h2 = 0.27–0.67) and TCOMP (h2 = 0.25–0.87). Traits describing the change from pre- calving to Mating 2 were also moderately heritable for both genotypes (h2 = 0.17–0.54), except for change in hip height (h2 = 0.00 and 0.10 for BRAH and TCOMP, respectively). Genetic correlations between measurements of the same trait at pre-calving and Mating 2 were consistently positive and strong (rg = 0.75–0.98) and similar for both genotypes. In lactating cows, genetic correlations of growth and body composition traits with their change from pre-calving to Mating 2 showed that when animals had low levels of P8 and rib fat at Mating 2, change in eye muscle area was an important descriptor of genetic body condition score (rg = 0.63). This was supported by moderate genetic relationships, which suggested that lactating cows that were genetically predisposed to lose less eye muscle area were those that ended the period with higher P8 fat (rg = 0.66), rib fat (rg = 0.72) and body condition score (rg = 0.61). Change in liveweight, body condition score and, in particular, eye muscle area was significantly related to the maternal genetic component of weaning weight (rg = from –0.40 to –0.85) in both genotypes, suggesting that cows with higher genetic milk-production potential were those with the propensity for greater loss of these traits over the period from pre-calving to Mating 2. These results showed that for tropically adapted cows, the change in eye muscle area from pre-calving to Mating 2 was a more important descriptor of body condition at Mating 2 than was change in fat depth, and that higher genetic milk-production potential, measured as maternal weaning weight, was genetically related to higher mobilisation of muscle, and therefore body condition, over this period.

Additional keywords: lactation, maternal weaning weight, pregnancy, weight loss.


References

Arango JA, Cundiff LV, Van Vleck LD (2002) Genetic parameters for weight, weight adjusted for body condition score, height, and body condition score in beef cows. Journal of Animal Science 80, 3112–3122.

Arthur PF, Hearnshaw H, Kohun PJ, Barlow R (1994) Evaluation of Bos indicus and Bos taurus straightbreds and crosses. I. Post-weaning growth of steers in different environments. Australian Journal of Agricultural Research 45, 783–794.
Evaluation of Bos indicus and Bos taurus straightbreds and crosses. I. Post-weaning growth of steers in different environments.Crossref | GoogleScholarGoogle Scholar |

Bartle SJ, Males JR, Preston RL (1984) Effect of energy intake on the postpartum interval in beef cows and the adequacy of the cow’s milk production for calf growth. Journal of Animal Science 58, 1068–1074.

Barwick SA, Johnston DJ, Burrow HM, Holroyd RG, Fordyce G, Wolcott ML, Sim WD, Sullivan MT (2009a) Genetics of heifer performance in ‘wet’ and ‘dry’ seasons and their relationships with steer performance in two tropical beef genotypes. Animal Production Science 49, 367–382.
Genetics of heifer performance in ‘wet’ and ‘dry’ seasons and their relationships with steer performance in two tropical beef genotypes.Crossref | GoogleScholarGoogle Scholar |

Barwick SA, Wolcott ML, Johnston DJ, Burrow HM, Sullivan MT (2009b) Genetics of steer daily feed intake and residual feed intake in tropical beef genotypes and relations among intake, body composition, growth and other post weaning measures. Animal Production Science 49, 351–366.
Genetics of steer daily feed intake and residual feed intake in tropical beef genotypes and relations among intake, body composition, growth and other post weaning measures.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXotFOgtrc%3D&md5=d8bc7838d05e31202598bec42ed148d7CAS |

Berry DP, Buckley F, Dillion P, Evans RD, Rath M, Veerkamp RF (2002) Genetic parameters of body condition score and body weight in dairy cows. Journal of Dairy Science 85, 2030–2039.
Genetic parameters of body condition score and body weight in dairy cows.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38Xmtl2rtLs%3D&md5=6983f84a33107f196c614436589efdf0CAS | 12214996PubMed |

Blöttner S, Heins BJ, Wensch-Dorendorf M, Hansen LB, Swalve HH (2011) Brown Swiss × Holstein crossbreds compared with pure Holsteins for calving traits, body weight, backfat thickness, fertility, and body measurements. Journal of Dairy Science 94, 1058–1068.
Brown Swiss × Holstein crossbreds compared with pure Holsteins for calving traits, body weight, backfat thickness, fertility, and body measurements.Crossref | GoogleScholarGoogle Scholar | 21257076PubMed |

Brown WF, Holloway JW, Butts WT (1980) Patterns of change in mature Angus cow weight and fatness during the year. Journal of Animal Science 51, 43–50.

Bruckmaier RM, Gregoretti L, Jans F, Faissler D, Blum JW (1998) Longissimus dorsi muscle diameter, backfat thickness, body condition score and shin fold values related to metabolic and endocrine traits in lactating dairy cows fed crystalline fat or free fatty acids. Journal of Veterinary Medicine A 45, 379–410.

Bullock KD, Bertrand LL, Benysheck SE, Williams SE, Lust DG (1991) Comparison of real time ultrasound and other live measures to carcass measures as predictors of beef cow energy stores. Journal of Animal Science 69, 3908–3916.

Burrow HM (2001) Variances and covariances between productive and adaptive traits and temperament in a composite breed of tropical beef cattle. Livestock Production Science 70, 213–233.
Variances and covariances between productive and adaptive traits and temperament in a composite breed of tropical beef cattle.Crossref | GoogleScholarGoogle Scholar |

Burrow HM, Johnston DJ, Barwick SA, Holroyd RG, Barendse W, Thompson JM, Griffith GR, Sullivan M (2003) Genetics relationships between carcass and beef quality and components of herd profitability in northern Australia. Proceedings of the Association for the Advancement of Animal Breeding and Genetics 15, 359–362.

Chase CC, Riley DG, Olson TA, Coleman SW (2005) Evaluation of Brahman and tropically adapted Bos taurus breeds in the humid subtropics. In ‘A compilation of research results involving tropically adapted beef cattle breeds’. Southern Cooperative Series Bulletin 405. pp. 108–117. Available at http://www.lsuagcenter.com [Verified 20 June 2012]

Davis GP (1993) Genetic parameters for tropical beef cattle in northern Australia: a review. Australian Journal of Agricultural Research 44, 179–198.
Genetic parameters for tropical beef cattle in northern Australia: a review.Crossref | GoogleScholarGoogle Scholar |

Ferrel CL, Jenkins TG (1984) Energy utilization by mature, non-pregnant, non-lactating cows of different types. Journal of Animal Science 58, 234–243.

Fuguitt GV, Lieberson S (1974) Correlation of ratios or difference scores having common terms. In ‘Sociological methodology 1973–1974’. (Ed. HL Costner) pp. 128–144. (Jossey-Bass: San Francisco)

Gilmour A, Cullis B, Welham S, Gogel B, Thompson R (2004) An efficient computing strategy for prediction in mixed linear models. Computational Statistics & Data Analysis 44, 571–586.
An efficient computing strategy for prediction in mixed linear models.Crossref | GoogleScholarGoogle Scholar |

Gilmour AR, Gogel BJ, Cullis BR, Thompson R (2009) ‘ASREML users guide release 3.’ (VSN International: Hemel Hempstead, UK)

Houghton PL, Lemenager RP, Horstman LA, Hendrix KS, Moss GE (1990) Effects of body composition, pre- and postpartum energy level and early weaning on reproductive performance of beef cows and preweaning calf gain. Journal of Animal Science 68, 1438–1446.

Johnson MZ, Schalles RR, Dikeman MW, Golden BL (1993) Genetic parameter estimates of ultrasound-measured longissimus muscle area and 12th rib fat thickness in Brangus cattle. Journal of Animal Science 71, 2623–2630.

Johnston DJ, Barwick SA, Holroyd RG, Fordyce G, Wolcott ML, Burrow HM (2009) Genetics of heifer puberty in two tropical beef genotypes in northern Australia and associations with heifer and steer production traits. Animal Production Science 49, 399–412.
Genetics of heifer puberty in two tropical beef genotypes in northern Australia and associations with heifer and steer production traits.Crossref | GoogleScholarGoogle Scholar |

Johnston DJ, Barwick SA, Fordyce G, Holroyd RG, Williams PJ, Corbet NJ, Grant T (2014) Genetics of early and lifetime annual reproductive performance in cows of two tropical beef genotypes in northern Australia. Animal Production Science 54, 1–15.
Genetics of early and lifetime annual reproductive performance in cows of two tropical beef genotypes in northern Australia.Crossref | GoogleScholarGoogle Scholar |

Kadarmideen HN (2004) Genetic correlations among body condition score, somatic cell score, milk production, fertility and conformation traits in dairy cows. Animal Science 79, 191–201.

Koenen EPC, Groen AF, Gengler N (1999) Phenotypic variation in liveweight and liveweight changes of lactating Holstein–Friesian cows. Animal Science 68, 109–114.

Lin CY, McAllister AJ, Lee AJ (1985) Multitrait estimation of relationships of first-lactation yields to body weight changes in Holstein heifers. Journal of Dairy Science 68, 2954–2963.
Multitrait estimation of relationships of first-lactation yields to body weight changes in Holstein heifers.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DyaL28%2Fos1KksA%3D%3D&md5=1d226377b73e0eecd98ab4de52840c72CAS | 4078123PubMed |

Meyer K (1995) Estimates of genetic parameters for mature weight of Australian beef cows and its relationship to early growth and skeletal measures. Livestock Production Science 44, 125–137.
Estimates of genetic parameters for mature weight of Australian beef cows and its relationship to early growth and skeletal measures.Crossref | GoogleScholarGoogle Scholar |

Miller RH, Hooven NW, Creegan ME (1969) Weight changes in lactating Holstein cows. Journal of Dairy Science 52, 90–94.
Weight changes in lactating Holstein cows.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DyaF1M%2FotVWlsA%3D%3D&md5=fcc39c0868c4c741f3fbc28edc4eef7bCAS | 5762155PubMed |

Newman S, Reverter A, Johnston DJ (2002) Purebred-crossbred performance and genetic evaluation of postweaning growth and carcass traits in Bos indicus × Bos taurus crosses in Australia. Journal of Animal Science 80, 1801–1808.

Petit M, Micol N (1981) Evaluation of energy requirements of beef cows during early lactation. Livestock Production Science 8, 139–153.
Evaluation of energy requirements of beef cows during early lactation.Crossref | GoogleScholarGoogle Scholar |

Pryce JE, Coffey MP, Simm G (2001) The relationship between body condition score and reproductive performance. Journal of Dairy Science 84, 1508–1515.
The relationship between body condition score and reproductive performance.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXktlKgsLo%3D&md5=3c965496f8fce8acb463d0032f086437CAS | 11417711PubMed |

Riley DG, Chase CC, Hammond AC, West RL, Johnson DD, Olson TA, Coleman SW (2002) Estimated genetic parameters for carcass traits of Brahman cattle. Journal of Animal Science 80, 955–962.

Robinson DL, O’Rourke PK (1992) Genetic parameters for liveweights of beef cattle in the tropics. Australian Journal of Agricultural Research 43, 1297–1305.

Rydhmer L, Johansson K, Stern S, Eliasson-Selling L (1992) A genetic study of pubertal age, litter traits, weight loss during lactation and relations to growth and leanness in gilts. Acta Agriculturae Scandinavica, Section A. Animal Science 42, 211–219.

Slack-Smith A, Griffith G, Thompson JM (2009) The cost of non-compliance to beef market specifications. Australasian Agribusiness Review 17, 178–190.

Tamminga S, Luteijn PA, Meijer RGM (1997) Changes in composition and energy content of liveweight loss in dairy cows with time after parturition. Livestock Production Science 52, 31–38.
Changes in composition and energy content of liveweight loss in dairy cows with time after parturition.Crossref | GoogleScholarGoogle Scholar |

Thompson WR, Thumick DH, Meiike JC, Goodrich RD, Rust JR, Byers FM (1983) Linear measurements and visual appraisal as estimators of percentage empty body fat of beef cows. Journal of Animal Science 56, 755–760.

Vankan DM, Burns BM (1997) DNA fingerprinting: how it works and applications for the beef industry. Proceedings of the Association for the Advancement of Animal Breeding and Genetics 12, 433–437.

Veerkamp RF, Oldenbroek JK, Van Der Gaast HJ, Van Der Werf JHJ (2000) Genetic correlation between days until start of luteal activity and milk yield, energy balance, and live weights. Journal of Dairy Science 83, 577–583.
Genetic correlation between days until start of luteal activity and milk yield, energy balance, and live weights.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3cXit1ymsbw%3D&md5=9d3b6717aab5fecf062b8563cd3d3100CAS | 10750116PubMed |

Veerkamp RF, Koenen EPC, De Jong G (2001) Genetic correlations among body condition score, yield, and fertility in first-parity cows estimated by random regression models. Journal of Dairy Science 84, 2327–2335.
Genetic correlations among body condition score, yield, and fertility in first-parity cows estimated by random regression models.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXnvV2ksbo%3D&md5=604f8a77a046e0fddf7c71a2a237bbd4CAS | 11699466PubMed |

Wall E, Brotherstone S, Woolliams JA, Banos G, Coffey MP (2003) Genetic evaluation of fertility using direct and correlated traits. Journal of Dairy Science 86, 4093–4102.
Genetic evaluation of fertility using direct and correlated traits.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXhtVWgsL7J&md5=0a275dd705dce3ef1d5f8d8d1a30651dCAS | 14740850PubMed |

Wolcott ML, Johnston DJ, Barwick SA, Iker CL, Thompson JM, Burrow HM (2009) Genetics of meat quality and carcass traits and the impact of tenderstretching in two tropical beef genotypes. Animal Production Science 49, 383–398.
Genetics of meat quality and carcass traits and the impact of tenderstretching in two tropical beef genotypes.Crossref | GoogleScholarGoogle Scholar |

Yamazaki T, Takeda H, Nishiura A, Sasai Y, Sugawara N, Togashi K (2011) Phenotypic relationships between lactating persistency and change in body condition score in first-lactation Holstein cows. Asian-Australasian Journal of Animal Sciences 24, 610–615.
Phenotypic relationships between lactating persistency and change in body condition score in first-lactation Holstein cows.Crossref | GoogleScholarGoogle Scholar |