Effects of genetic merit for carcass weight, breed type and slaughter weight on performance and carcass traits of beef × dairy steers

Keane, M. G.; Dunne, Padraig; Kenny, David A.; Berry, D.P.

doi:10.1017/s1751731110001758

Cited by 8 publications

(6 citation statements)

References 29 publications

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“…The lack of difference in intramuscular fat concentration between feeding treatments supports the findings of Moloney et al (2008) and likely reflects the duration of the re-alimentation period. The higher intramuscular fat concentration in muscle from AN in the present study supports the findings of other studies for the same genotypes (Keane et al, 2011) and reflects the maturity of the AN breed compared to the BB breed.…”

Section: Chemical Composition Of Ltlsupporting

confidence: 91%

“…The difference in redness between genotypes supports the findings of Keane et al (2011) and Cuvelier et al (2006a, b). However, Campion et al (2009) found no difference in redness between AN and BB genotypes Carotenoid consumption by cattle results in accumulation in adipose tissue and more yellow colour (for review, see Dunne et al, 2009).…”

Section: Double Muscled Animals Have a Greater Percentage Of White Musupporting

confidence: 89%

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Compensatory growth in crossbred Aberdeen Angus and Belgian Blue steers: Effects on the colour, shear force and sensory characteristics of longissimus muscle

et al. 2017

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General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. The effect of feed restriction (99 days) followed by compensatory growth during a 27 200 day re-alimentation period on the colour and sensory characteristics of meat from 28Aberdeen Angus × Holstein-Friesian (AN) and Belgian Blue × Holstein-Friesian (BB) 29 steers was examined. Compensatory growth had no effect on muscle pH and 30 temperature decline, chemical composition, drip loss, fat colour, or juiciness, but 31 increased (p = 0.009) Warner-Bratzler shear force and decreased tenderness (P = 0.08) 32and overall flavour (P = 0.03). Compared to meat from BB steers, meat from AN 33 steers had a higher intramuscular fat concentration and was rated similarly for 34 tenderness, but higher for many of the flavour characteristics examined. While 35 adjustment for intramuscular fat concentration removed some of these differences, 36 genotype-specific flavour differences remained. It is concluded that genotype had 37 greater effects of meat quality that the compensatory growth feeding regime imposed 38 in this study. 39 40 41

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Section: Chemical Composition Of Ltlsupporting

confidence: 91%

Section: Double Muscled Animals Have a Greater Percentage Of White Musupporting

confidence: 89%

Compensatory growth in crossbred Aberdeen Angus and Belgian Blue steers: Effects on the colour, shear force and sensory characteristics of longissimus muscle

et al. 2017

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“…A number of studies to date have investigated the physical and physiological differences in animals varying in EPD cwt (Crews et al, 2004;Keane et al, 2011). In addition, Bernard et al (2009) examined the effects of genetic selection in favor of high muscle growth on global gene expression in muscle tissue of young Charolais bulls.…”

Section: Introductionmentioning

confidence: 99%

Proteomic profiling of bovine M. longissimus lumborum from Crossbred Aberdeen Angus and Belgian Blue sired steers varying in genetic merit for carcass weight1

Keady

Kenny

Ohlendieck

et al. 2013

Journal of Animal Science

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Bovine skeletal muscle is a tissue of signifi cant value to the beef industry and global economy. Proteomic analyses offer the opportunity to detect molecular mechanisms regulating muscle growth and intramuscular fat accumulation. The current study aimed to investigate differences in protein abundance in skeletal muscle tissue of cattle from two breeds of contrasting maturity (early vs. late maturing), adiposity, and muscle growth potential, namely, Belgian Blue (BB) × Holstein Friesian and Aberdeen Angus (AA) × Holstein Friesian. Twenty AA (n = 10) and BB (n = 10) sired steers, the progeny of sires of either high or low genetic merit, expressed as expected progeny difference for carcass weight (EPD cwt ), and bred through AI, were evaluated as 4 genetic groups, BB-High, BB-Low, AA-High, and AA-Low (n = 5 per treatment). Chemical composition analysis of M. longissimus lumborum showed greater protein and moisture and decreased lipid concentrations for BB-sired compared with AA-sired steers. To investigate the effects of both sire breed and EPD cwt on M. longissimus lumborum, proteomic analysis was performed using 2-dimensional difference gel electrophoresis followed by mass spectrometry. Proteins were identifi ed from their peptide sequences, using the National Center for Biotechnology Information (NCBI) and Swiss-prot databases. Metabolic enzymes involved in glycolysis (glycogen phosphorylase, phosphoglycerate mutase) and the citric acid cycle (aconitase 2, oxoglutarate dehydrogenase) were increased in AA-vs. BB-sired steers. Expression of proteins involved in cell structure, such as myosin light chain isoforms and troponins I and T, were also altered due to sire breed. Furthermore, heat shock protein β-1 and peroxiredoxin 6, involved in cell defense, had increased abundance in muscle of AA-sired relative to BB-sired steers. Protein abundance of glucose-6-phosphate isomerase, enolase-3, and pyruvate kinase was greater in AA-sired animals of High compared with Low EPD cwt . Changes in the expression of these proteins were supported by gene expression analysis using quantitative real-time PCR. This information will aid in our understanding of genetic infl uences controlling muscle growth and fat accumulation and could contribute to future breeding programs to increase lean tissue gain of beef cattle.

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“…Numerous studies have demonstrated that intramuscular fat content of cattle and beef quality are influenced by factors of the production or processing system including the breed, sex, age, housing system, feeding, and pre-slaughter handling, but also the individual genetic background of an animal [18,19] (Figure 1). The impact of breed on suitability for meat production was reported by many authors, but it is difficult to pinpoint the best breed for beef production and it is unlikely that one breed will have all the desirable traits for survival, growth, and quality meat production [20,21,22]. Breeds differ in many aspects including degree of muscling, intramuscular fat content, meat aroma, juiciness, and tenderness.…”

Section: Effect Of Some Slaughter Value Factors On Meat Qualitymentioning

confidence: 99%

Advances of Molecular Markers and Their Application for Body Variables and Carcass Traits in Qinchuan Cattle

Raza

Khan

Abdelnour

et al. 2019

Genes

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This review considers the unique characteristics of Chinese cattle and intramuscular fat content (IMF) as factors influencing meat quality, including tenderness, flavor, and juiciness of meat. Due to its nutritional qualities, meat contributes to a healthy and balanced diet. The intramuscular fat content and eating quality of beef are influenced by many factors, which can generally be divided into on-farm and pre-slaughter factors (breed, sex of cattle, age at slaughter, housing system, diet, and pre-slaughter handling) and postmortem factors (post-slaughter processing, chilling temperature, and packaging). Meat quality traits can also be influenced by the individual genetic background of the animal. Worldwide, the function of genes and genetic polymorphisms that have potential effects on fattening of cattle and beef quality have been investigated. The use of DNA markers is recognized as a powerful and efficient approach to achieve genetic gain for desirable phenotypic characteristics, which is helpful for economic growth. The polymorphisms of the SIRT4, SIRT6, SIRT7, CRTC3, ABHD5, KLF6, H-FABP, and ELOVL6 genes for body and growth characteristics of cattle, and also for beef quality, are considered with the aim of highlighting the significance of beef intramuscular fat content, and that growth, body, and meat quality characteristics are polygenically regulated.

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Effects of genetic merit for carcass weight, breed type and slaughter weight on performance and carcass traits of beef × dairy steers

Cited by 8 publications

References 29 publications

Compensatory growth in crossbred Aberdeen Angus and Belgian Blue steers: Effects on the colour, shear force and sensory characteristics of longissimus muscle

Compensatory growth in crossbred Aberdeen Angus and Belgian Blue steers: Effects on the colour, shear force and sensory characteristics of longissimus muscle

Proteomic profiling of bovine M. longissimus lumborum from Crossbred Aberdeen Angus and Belgian Blue sired steers varying in genetic merit for carcass weight1

Advances of Molecular Markers and Their Application for Body Variables and Carcass Traits in Qinchuan Cattle

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