Effect of postweaning growth and bulls selected for extremes in retail beef yield and intramuscular fat on progeny liveweight and carcass traits
J. F. Graham A B D , J. Byron A B , A. J. Clark A B , G. Kearney A B and B. Orchard A CA Cooperative Research Centre for Beef Genetic Technologies, University of New England, Armidale, NSW 2351, Australia.
B Department of Primary Industries, Primary Industries Research Victoria – Hamilton, Mt Napier Road, Hamilton, Vic. 3300, Australia.
C NSW Department of Primary Industries, Agricultural Institute, Private Bag Wagga Wagga, NSW 2650, Australia.
D Corresponding author. Email: john.graham@dpi.vic.gov.au
Animal Production Science 49(6) 493-503 https://doi.org/10.1071/EA08181
Submitted: 6 June 2008 Accepted: 14 November 2008 Published: 13 May 2009
Abstract
The present study is a component of a multi-site experiment, using Bos taurus cattle generated at four locations across southern Australia, designed to examine postweaning growth pathways for progeny whose sires were extreme in retail beef yield and intramuscular fat. Treatment and interaction effects on beef production and meat quality were examined within and across sites. The present paper describes the effect of postweaning growth and sire carcass type on liveweight and carcass traits at the Hamilton site. Angus sires selected on estimated breeding values for extremes in retail beef yield (RBY%), intramuscular fat (IMF%) (estimated breeding values for IMF% are derived by using live-animal ultrasound scanning) or both and sire breed types considered to be more extreme in those traits (Limousin, and Belgian Blue for yield, and Wagyu for intramuscular fat) were joined to crossbred and straight-bred cows. After weaning, the resultant 645 steer and heifer progeny were grown on a fast and slow growth path to ~550 kg and slaughtered, averaging 0.68 kg/day and 22.2 months, and 0.49 kg/day and 27.8 months for growth rate and age at slaughter, respectively. Growth path, sire carcass type and sex affected carcass traits; however, there were no sire carcass type by growth treatment interactions. The fast growth-path cattle were fatter, had more intramuscular fat (measured chemically), a higher Meat Standards of Australia (MSA) USA and AUS marble score, and a higher predicted MSA eating-quality score. Progeny of Wagyu sires were lighter at weaning and slaughter and had a lower hot standard carcass weight than the other sire carcass types. The Belgian Blue and Limousin progeny had a higher dressing percentage, a higher RBY% and a lower P8 and rib-fat depth and lower IMF% than the other sire breed types. Progeny of the high RBY% Angus had a lower rib-fat depth, a lower IMF% and higher RBY% than those selected for high IMF%. There was no difference in IMF% between the Wagyu or the high IMF% Angus. Progeny from the Belgian Blue, Limousin and Wagyu had a larger eye muscle area than the other sire breeds. The results indicate that simultaneous selection for supposedly antagonistic traits of IMF% and RBY% would result in carcass having high values of both measurements. Females were lighter than steers at slaughter, had a lower hot standard carcass weight, were fatter at the P8 and rib, and had a higher marble score and IMF%, a lower yield and a lower MSA-predicted eating-quality score than did steers. There was no interaction between postweaning growth and sire carcass type. These results indicate that with the use of appropriate sire carcass types and BREEDPLAN, and post-weaning nutrition, beef producers can confidently change carcass parameters to suit market specifications.
Additional keywords: sire breed type.
Acknowledgements
We are grateful for the cooperation and assistance of Cargill Beef for the processing stages of the experiments – thanks go to the many staff and management at the abattoir works at Wagga Wagga (Harry Waddington and Grant Garey, in particular) who provided enthusiastic assistance and access to data. Thanks also go to Don Robertson, ‘Skene’, Hamilton, for the use of his breeding herd and his keen assistance. This project was heavily supported by funding from Meat and Livestock Australia within the Beef CRC 2 (Cooperative Research Centre for Cattle and Beef Quality Australia). We are most grateful for the assistance of the staff of the Meat Science Laboratory at Armidale and the staff of MSA. Staff of the NSW State Department of Primary Industry assisted in abattoir data collection. Thanks go to Brian Clark for management support. Finally, we gratefully acknowledge the inputs of Mr Jim Walkley for his helpful advice in the drafting and revision of this paper.
Afolayan RA,
Pitchford WS,
Deland MPB, McKiernan WA
(2007) Breed variation and genetic parameters for growth and body development in diverse beef cattle genotypes. Animal 1, 13–20.
| Crossref | GoogleScholarGoogle Scholar |
[Verified 18 March 2009]
Graham JF,
Clark AJ,
Hayes GJ,
Kearney GA, Deland MPB
(2000) The effect of genotype on growth and fatness when Angus, Hereford, Limousin and Simmental sires are mated to Angus and Hereford cows. Asian–Australasian Journal of Animal Sciences 13, 325–328.
Graser HU,
Tier B,
Johnston DJ, Barwick SA
(2005) Genetic evaluation for the beef industry in Australia. Australian Journal of Experimental Agriculture 45, 913–921.
| Crossref | GoogleScholarGoogle Scholar |
Gregory KE,
Cundiff LV,
Koch RM,
Dikeman ME, Koohmaraie M
(1994a) Breed effects, retained heterosis, and estimates of genetic and phenotypic parameters for carcase and meat traits of beef cattle. Journal of Animal Science 72, 1174–1183.
Gregory KE,
Cundiff LV,
Koch RM,
Dikeman ME, Koohmaraie M
(1994b) Breed effects and retained heterosis for growth, carcase and meat traits in advanced generations of composite populations of beef cattle. Journal of Animal Science 72, 833–850.
Hersom MJ,
Horn GW,
Krehbiel CR, Phillips WA
(2004) Effect of live weight gain of steers during winter grazing. I. Feedlot performance, carcase characteristics, and body composition of beef steers. Journal of Animal Science 82, 262–272.
Irwin J,
Wilkins JF, McKiernan WA
(2006) Effects of sire genotype and growth rate on the variation in weaning and feedlot entry weights of beef feeder steers. Animal Production in Australia 25, 267.
Jesse GW,
Thompson GB,
Clark JL,
Hedrick HB, Weimer KG
(1976) Effects of ration energy and slaughter weight on composition of empty body and carcase gain of beef cattle. Journal of Animal Science 43, 418–425.
Jones DK,
Savel JW, Cross HR
(1990) The influence of sex-class, USDA yield grade and USDA quality grade on seam fat trim from the primals of beef carcases. Journal of Animal Science 68, 1987–1991.
Koch RM,
Dikeman ME,
Allen DM,
May M,
Crouse JD, Campion DR
(1976) Characterization of biological types of cattle III carcase composition, quality and palatability. Journal of Animal Science 43, 48–62.
Koots KR,
Gibson JP,
Smith C, Wilton JW
(1994) Analyses of published genetic parameter estimates for beef production traits. 1. Heritability. Animal Breeding Abstracts 62, 309–338.
Lunstra DD, Cundiff LV
(2003) Growth and pubertal development in Brahman, Boran, Tuli, Belgian Blue, Hereford and Angus sired F1 bulls. Journal of Animal Science 81, 1414–1426.
Lunt DK,
Riley RR, Smith SB
(1993) Growth and carcase characteristics of Angus and American Wagyu steers. Meat Science 34, 327–334.
| Crossref | GoogleScholarGoogle Scholar |
Marshall DM
(1994) Breed differences and genetic parameters for body composition traits in beef cattle. Journal of Animal Science 72, 2745–2755.
McKiernan WA,
Wilkin JF,
Barwick SA,
Tudor GD,
McIntyre BL,
Graham JF,
Deland MPD, Davies L
(2005) CRC ‘Regional Combinations’ Project – Effects of genetics and growth paths on beef production and meat quality: experimental design, methods and measurements. Australian Journal of Experimental Agriculture 45, 959–969.
| Crossref | GoogleScholarGoogle Scholar |
Mir PS,
Mir Z,
Kuber PS,
Gaskins CT,
Martin EL,
Dodson MV,
Elias Calles JA,
Johnson KA,
Busboom JR,
Wood AJ,
Pittenger GJ, Reeves JJ
(2002) Growth, carcase characteristics, muscle conjugated linoleic acid (CLA) content, and response to intravenous glucose challenge in high percentage Wagyu, Wagyu x Limousin, and Limousin steers fed sunflower oil-containing diets. Journal of Animal Science 80, 2996–3004.
Murphey CE,
Johnson D,
Smith GC,
Abraham HC, Cross HR
(1985) Effects of sex related differences in external fat deposition on subjective carcase fatness evaluations-steer versus heifer. Journal of Animal Science 68, 1987–1991.
Murphy TA, Loerch SC
(1994) Effects of restricted feeding of growing steers on performance, carcase characteristics and composition. Journal of Animal Science 72, 2497–2507.
Murray DM,
Tulloh NM, Winter WH
(1974) Effects of three different growth rates on empty body weight, carcase weight and dissected carcase composition of cattle. Journal of Agricultural Science 82, 535–547.
Owens FN, Gardner BA
(1999) A review of the impact of feedlot management and nutrition on carcase measurements of feedlot cattle. Journal of Animal Science 77, 1–18.
Owens FN,
Gill DR,
Secrist DS, Coleman SW
(1995) Review of some aspects of growth and development of feedlot cattle. Journal of Animal Science 73, 3152–3172.
Perry D, Thompson JM
(2005) The effect of growth rate during backgrounding and finishing on meat quality traits in beef cattle. Meat Science 69, 691–702.
| Crossref | GoogleScholarGoogle Scholar |
Perry D,
Shorthose WR,
Ferguson DM, Thompson JM
(2001) Methods used in the CRC program for the determination of carcase yield and beef quality. Australian Journal of Experimental Agriculture 41, 953–957.
| Crossref | GoogleScholarGoogle Scholar |
Pethick DW,
Harper GS, Oddy VH
(2004) Growth, development and nutritional manipulation of marbling in cattle, a review. Australian Journal of Experimental Agriculture 44(7), 705–715.
| Crossref | GoogleScholarGoogle Scholar |
Pitchford WS,
Deland MPB,
Siebert BD,
Malau-Aduli AEO, Bottema CDK
(2002) Genetic variation in fatness and fatty acid composition of crossbred cattle. Journal of Animal Science 80, 2825–2832.
Pitchford WS,
Mirzaei HM,
Deland MPB,
Afolayan RA,
Rutley DL, Verbyla AR
(2006) Variance components for birth and carcase traits of crossbred cattle. Australian Journal of Experimental Agriculture 46, 225–231.
| Crossref | GoogleScholarGoogle Scholar |
Reverter A,
Johnston DJ,
Perry D,
Goddard ME, Burrow HM
(2003) Genetic and phenotypic characterization of animal, carcase, and meat quality traits from temperate and tropically adapted beef breeds. 2. Abattoir carcase traits. Australian Journal of Agricultural Research 54, 119–134.
| Crossref | GoogleScholarGoogle Scholar |
Ridenour KW,
Kiesling HE,
Lofgreen GP, Stiffier DM
(1982) Feedlot performance and carcase characteristics of beef steers grown and finished under different nutrition and management programs. Journal of Animal Science 54, 1115–1119.
Ríos-Utrera A,
Cundiff LV,
Gregory KE,
Koch RM,
Dikeman ME,
Koohmaraie M, Van Vleck LD
(2006) Effects of age, weight and fat slaughter end points on estimates of breed and retained heterosis effects for carcase traits. Journal of Animal Science 84, 63–87.
Robinson DL,
Oddy VH,
Dicker RW, McPhee M
(2001) Post-weaning growth in northern New South Wales. 3. Carry-over effects on finishing, carcase characteristics and intramuscular fat. Australian Journal of Experimental Agriculture 41, 1041–1049.
| Crossref | GoogleScholarGoogle Scholar |
Ross JW,
Smith TK,
Krehbiel CR,
Malayer JR,
DeSilva U,
Morgan JB,
White FJ,
Hersom MJ,
Horn GW, Geisert RD
(2005) Effects of grazing program and subsequent finishing on gene expression in different adipose tissue depots in beef steers. Journal of Animal Science 83, 1914–1923.
Sainz RD, Vernazza Paganini RF
(2004) Effects of different grazing and feeding periods on performance and carcase traits of beef steers. Journal of Animal Science 82, 292–297.
Saul GR
(1983) The composition, fat distribution and yield of carcase beef from steers and heifers when entired, spayed, pregnant, or fitted with an intravaginal device. Australian Journal of Experimental Agriculture and Animal Husbandry 23, 354–357.
| Crossref | GoogleScholarGoogle Scholar |
Slabbert N,
Campher JP,
Shelby T,
Leeuw KJ,
Kuhn GP, Meissner HH
(1992) The influence of dietary energy concentration and feed intake level on feedlot steers. 3. Carcase composition and tissue growth as influenced by rate of gain. South African Journal of Animal Science 22, 115–121.
Thompson JM
(2002) Managing meat tenderness. Meat Science 62, 295–308.
| Crossref | GoogleScholarGoogle Scholar |
Tong AKW,
Robinson DJ,
Robertson WR,
Zawadski SM, Liu T
(1999) Evaluation of the Canadian vision system for beef carcase grading. Proceedings of the 45th International Congress of Meat Science and Technology 45, 374–375.
Trenkle A,
DeWitt DL, Topel DG
(1978) Influence of age, nutrition and genotype on carcase traits and cellular development of the M. longissimus of cattle. Journal of Animal Science 46, 1597–1603.
Tudor GD,
Utting DW, O’Rourke PK
(1980) The effect of pre- and post-natal nutrition on the growth of beef cattle. III. The effect of severe restriction in early post-natal life on the development of the body components and chemical composition. Australian Journal of Agricultural Research 31, 191–204.
| Crossref | GoogleScholarGoogle Scholar |
Upton W,
Burrow HM,
Dundon A,
Robinson DL, Farrell EB
(2001) CRC breeding program design, measurements and database, methods that underpin CRC research results. Australian Journal of Experimental Agriculture 41, 943–952.
| Crossref | GoogleScholarGoogle Scholar |
Vieselmeyer BA,
Rasby RJ,
Gwartney BL,
Calkins CR,
Stock RA, Gosey JA
(1996) Use of expected progeny differences for marbling in beef. I. Production traits. Journal of Animal Science 74, 1009–1013.
Wertz AE,
Berger LL,
Walker PM,
Faulkner DB,
McKeith FK, Rodriguez-Zas SL
(2002) Early-weaning and post weaning nutritional management effect feedlot performance, carcase merit, and the relationship of 12th-rib fat, marbling score, and feed efficiency among Angus and Wagyu heifers. Journal of Animal Science 80, 28–37.
Wheeler TL,
Cundiff LV,
Koch RM, Crouse D
(1996) Characterization of biological types of cattle (Cycle IV), carcass traits and longissimus palatability. Journal of Animal Science 74, 1023–1035.
Wheeler TL,
Cundiff LV,
Shackelford SD, Koohmaraie M
(2001) Characterization of biological types of cattle (Cycle V), carcase traits and longissimus palatability. Journal of Animal Science 79, 1209–1222.
Wheeler TL,
Cundiff LV,
Shackelford SD, Koohmaraie M
(2004) Characterization of biological types of cattle (Cycle VI), carcase, yield, and longissimus palatability traits. Journal of Animal Science 82, 1177–1189.
Wheeler L,
Cundiff LV,
Shackelford SD, Koohmaraie M
(2005) Characterization of biological types of cattle (Cycle VII), carcase, yield, and longissimus palatability traits. Journal of Animal Science 83, 196–207.
Williams CB,
Bennett GL, Keele JW
(1995) Simulated influence of post weaning production system on performance of different biological types of cattle. I. Estimation of model parameters. Journal of Animal Science 73, 665–673.
Wood JD,
Enser M,
Fisher AV,
Nute GR,
Richardson RI, Sheard PR
(1999) Manipulating meat quality and composition. Proceedings of the Nutrition Society 58, 363–370.
Young LD,
Cundiff LV,
Crouse JD,
Smith GM, Gregory KE
(1978) Characterization of biological types of cattle. VIII. Post weaning growth and carcase traits of three-way cross steers. Journal of Animal Science 46, 1178–1191.
Zembayashi M
(1994) Effects of nutritional planes and breeds on intramuscular-lipid deposition in M. longissimus dorsi of steers. Meat Science 38, 367–374.
| Crossref | GoogleScholarGoogle Scholar |
