Brahman and Brahman crossbred cattle grown on pasture and in feedlots in subtropical and temperate Australia. 1. Carcass quality
K. M. Schutt A B D E , H. M. Burrow A , J. M. Thompson A C and B. M. Bindon AA Cooperative Research Centre for Beef Genetic Technologies, C.J. Hawkins Homestead, University of New England, Armidale, NSW 2351, Australia.
B CSIRO Livestock Industries, PO Box 5545, Rockhampton Mail Centre, Qld 4702, Australia.
C Division of Animal Science, University of New England, Armidale, NSW 2351, Australia.
D Present address: ‘Ingaby Station’, St George, Qld 4487, Australia.
E Corresponding author. Email: sk_prewett@activ8.net.au
Animal Production Science 49(6) 426-438 https://doi.org/10.1071/EA08081
Submitted: 3 March 2008 Accepted: 12 February 2009 Published: 13 May 2009
Abstract
Brahmans are known to have poorer carcass quality relative to Bos taurus breeds and crossbreds under temperate environments; however, little is known of their performance in subtropical environments. The Cooperative Research Centre for Cattle and Beef Industry (Meat Quality) initiated a crossbred progeny test experiment to compare straightbred Brahmans with Brahman crossbreds finished on pasture and grain, in subtropical and temperate environments, to carcass quality specifications of Australian domestic and export markets. Brahman, Belmont Red, Santa Gertrudis, Angus, Hereford, Shorthorn, Charolais and Limousin sires were mated to Brahman females in subtropical Queensland over 3 years to produce 1750 progeny. At a common age at slaughter, Charolais crossbreds had the highest hot carcass weight (CWT) but were not significantly heavier than Limousin or British crossbred progeny. At common carcass weights, breeds within breed type (British, Continental, tropically adapted) performed similarly. British and Santa Gertrudis crossbreds had the fattest carcasses and lowest yields. British and Belmont Red crossbreds had the highest intramuscular fat percentage (IMF). Continental crossbreds had the highest retail beef yield (RBY), kilograms of retail primals (RTPM) and percent retail primals (pcRTPM) and leanest carcasses. Brahmans had the lowest CWT, intermediate subcutaneous fat cover, high yields and low IMF. Animals finished in the subtropics on pasture were significantly older, leaner and had higher RBY, RTPM and pcRTPM than subtropical feedlot-finished contemporaries. Temperate feedlot animals had significantly more IMF, less subcutaneous fat at the P8 site and slightly lower yields than subtropical feedlot contemporaries, indicating possible effects of postweaning growth path on fat distribution. Belmont Red crossbreds demonstrated the advantages of adaptation with the highest IMF in both subtropical finishing regimes, while Angus progeny had the highest IMF in the temperate feedlot environment and highest IMF overall when analysed across finishing regimes. Significant interactions were mainly the result of scale effects rather than breed re-ranking for carcass traits across markets and finishing regimes. Therefore, breeds that performed well for certain carcass traits in subtropical environments performed consistently for those traits in temperate environments relative to other sire breeds, regardless of market endpoint or finishing nutrition.
Acknowledgements
The authors gratefully acknowledge the significant efforts of all Beef CRC staff involved in breeding and managing the experimental animals, field data collection at ‘Duckponds’, ‘Goonoo’, ‘Tullimba’ and ‘McMaster’, abattoir data collection, laboratory meat quality analyses, collation of project data and maintenance of the CRC database. The following donors of Brahman breeding cows for use in the project are also gratefully acknowledged: Hillgrove Pastoral Co., Australian Agricultural Co., North Australian Pastoral Co., Stanbroke Pastoral Co., Queensland and Northern Territory Pastoral Co., Consolidated Pastoral Co., Heytesbury Pastoral Co., Peter Hughes and Acton Land and Cattle Co. Generous funding for the project was provided by Meat and Livestock Australia through Project NAP.3.104.
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