Effect of dietary energy source on in vitro substrate utilization and insulin sensitivity of muscle and adipose tissues of Angus and Wagyu steers

Rhoades, Ryan; Sawyer, J. E.; Chung, Ki Yong; Schell, Mareike; Lunt, D. K.; Smith, Stephen B.

doi:10.2527/jas.2006-498

Cited by 57 publications

(61 citation statements)

References 31 publications

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“…It has been suggested that different fat depots have preferences for different substrates to support lipogenesis and/ or adipogenesis, although empirical evidence for effects on carcass characteristics independent of the amount of NE supplied is lacking (Pethick et al, 2004;Hocquette et al, 2010). Acetate is the major carbon source for fatty acid synthesis in ruminants' fat depots (Bauman, 1976); however, it has been suggested that IMF (as opposed to other depots) preferentially utilizes glucose/lactate for fatty acid synthesis (Smith and Crouse, 1984;Rhoades et al, 2007;Smith et al, 2009;Hocquette et al, 2010). Diets based on cereal grain would potentially generate additional glucose either via gluconeogenesis from propionate or via direct absorption of glucose from the small intestine (Rowe et al, 1999).…”

Section: Discussionmentioning

confidence: 99%

Postweaning substitution of grazed forage with a high-energy concentrate has variable long-term effects on subcutaneous fat and marbling in Bos taurus genotypes1

Greenwood

Siddell

Walmsley

et al. 2015

Journal of Animal Science

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ABSTRACT:The objective of this study was to quantify the effects and interactions of stage of growth and genotype on commercial carcass traits and intramuscular fat (IMF) content in 5 muscles of Bos taurus steers (n = 165) and to test the hypothesis that substituting pasture with a high-energy concentrate during the immediate postweaning period increases IMF. Cattle of 3 genotypes (Angus, Hereford, and Wagyu × Angus; n = 55/genotype) were selected at weaning from commercial herds, targeting genotypic differences in marbling and subcutaneous fatness. Following weaning, steers were fed for 168 d within 2 different improved, temperate pasture-based nutritional systems: a forage-only system (FS) and forage with high-energy supplemented system (SS), with 2 replicates per system. The supplement was fed at a level of 1% of average BW adjusted every 2 wk to provide an estimated 50% of energy requirements for 168 d from weaning. Pasture on offer in both systems was managed to match the BW of the FS and SS steers during the postweaning treatment period to avoid confounding due to differences in growth rate during this period. Steers were then regrouped into 2 replicates and backgrounded on improved, temperate pasture for 158 d and then grain fed within 1 group for 105 d (short fed) or 259 d (long fed). Groups were slaughtered at commencement (d 0) and end of postweaning nutritional treatments (d 168), end of backgrounding (d 326), and after short (d 431) or long feedlotting (d 585). Serial slaughter stage had an effect on all traits assessed (P < 0.01). The FS steers had more rib fat (P < 0.01) and higher Meat Standards Australia marbling score (P < 0.05) and a tendency (P < 0.10) to have greater eye muscle area than the SS steers throughout the study. Genotypic differences were evident (P < 0.05) for all traits assessed except HCW, dressing percentage, rib fat depth, ossification score, ultimate pH, and IMF in the semitendinosus muscle. The results for marbling and IMF do not support the use of a high-energy feed as a substitute for an equivalent amount of energy from pasture during the immediate postweaning period to enhance development of marbling.

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Section: Discussionmentioning

confidence: 99%

Postweaning substitution of grazed forage with a high-energy concentrate has variable long-term effects on subcutaneous fat and marbling in Bos taurus genotypes1

Greenwood

Siddell

Walmsley

et al. 2015

Journal of Animal Science

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“…Then, a higher level of GLUT4 expression and higher activities of metabolic enzymes involved in the conversion of glucose into long-chain fatty acids (namely phosphofructokinase and ATP-citrate lyase) were detected in intramuscular adipose tissue compared to subcutaneous fat in these species . More recently, it was shown that the rate of glucose incorporation into fatty acid was more than twice as high as the rate of acetate incorporation in IMF adipocytes, whereas they are similar in subcutaneous adipose tissue (Rhoades et al, 2007). Thus, when fat synthesis is limited (such as within IMF adipocytes), glucose provides a greater proportion of acetyl units for lipogenesis than acetate (for review, see Smith et al, 2009).…”

Section: Nutritional Regulation Of Imf Level and Potential Outputsmentioning

confidence: 99%

“…For instance, it should be proposed that feeding a hay-based diet (providing mainly acetate) may alter intramuscular adipose tissue metabolism with less effect on subcutaneous adipose tissue accretion in ruminants. A recent experiment indicated that feeding a corn-based diet (providing a great amount of propionate, a glucogenic precursor) enhances glucose uptake in IMF depot, whereas feeding a hay-based diet reduces insulin action without altering acetate incorporation in fatty acids (Rhoades et al, 2007). Because subcutaneous fat used acetate more effectively than intramuscular adipose tissue, feeding a hay-based diet would then promote subcutaneous fat deposition over intramuscular adipose tissue accretion.…”

Section: Nutritional Regulation Of Imf Level and Potential Outputsmentioning

confidence: 99%

Intramuscular fat content in meat-producing animals: development, genetic and nutritional control, and identification of putative markers

Hocquette

Gondret

Baéza³

et al. 2010

Animal

632

447

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Intramuscular fat (IMF) content plays a key role in various quality traits of meat. IMF content varies between species, between breeds and between muscle types in the same breed. Other factors are involved in the variation of IMF content in animals, including gender, age and feeding. Variability in IMF content is mainly linked to the number and size of intramuscular adipocytes. The accretion rate of IMF depends on the muscle growth rate. For instance, animals having a high muscularity with a high glycolytic activity display a reduced development of IMF. This suggests that muscle cells and adipocytes interplay during growth. In addition, early events that influence adipogenesis inside the muscle (i.e proliferation and differentiation of adipose cells, the connective structure embedding adipocytes) might be involved in interindividual differences in IMF content. Increasing muscularity will also dilute the final fat content of muscle. At the metabolic level, IMF content results from the balance between uptake, synthesis and degradation of triacylglycerols, which involve many metabolic pathways in both adipocytes and myofibres. Various experiments revealed an association between IMF level and the muscle content in adipocyte-type fatty acid-binding protein, the activities of oxidative enzymes, or the delta-6-desaturase level; however, other studies failed to confirm such relationships. This might be due to the importance of fatty acid fluxes that is likely to be responsible for variability in IMF content during the postnatal period rather than the control of one single pathway. This is evident in the muscle of most fish species in which triacylglycerol synthesis is almost zero. Genetic approaches for increasing IMF have been focused on live animal ultrasound to derive estimated breeding values. More recently, efforts have concentrated on discovering DNA markers that change the distribution of fat in the body (i.e. towards IMF at the expense of the carcass fatness). Thanks to the exhaustive nature of genomics (transcriptomics and proteomics), our knowledge on fat accumulation in muscles is now being underpinned. Metabolic specificities of intramuscular adipocytes have also been demonstrated, as compared to other depots. Nutritional manipulation of IMF independently from body fat depots has proved to be more difficult to achieve than genetic strategies to have lipid deposition dependent of adipose tissue location. In addition, the biological mechanisms that explain the variability of IMF content differ between genetic and nutritional factors. The nutritional regulation of IMF also differs between ruminants, monogastrics and fish due to their digestive and nutritional particularities.

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“…May et al (1994) showed that pre-adipocytes of Wagyu steer proliferate more actively than the cells of Angus steer. It has been demonstrated that IM adipocytes prefer to use glucose, while SC adipocytes prefer to use acetate as primary substrates for fatty acid synthesis in bovine in vitro (Smith and Crouse 1984;Rhoades et al 2007), and triacylglycerol biosynthesis is less sensitive to starvation in IM than in SC adipose tissue (Smith et al 1998). Diets greater in starch promote IM fat deposition relative to SC deposition (Choat et al 2003).…”

Section: Introductionmentioning

confidence: 98%

Comparison of the adipogenesis in intramuscular and subcutaneous adipocytes from Bamei and Landrace pigs

Hua

Xiong

ChenYan

et al. 2014

Biochem. Cell Biol.

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Fat deposition is a complex process involving proliferation, differentiation, and lipogenesis of adipocytes. Bamei and Landrace are considered to represent fat- and lean-type pig breeds. Subcutaneous (SC) and intramuscular (IM) pre-adipocytes were cultured to compare the proliferation and lipogenesis in these breeds. The differentiated adipocytes were exposed to glucose or insulin to evaluate their effects on lipogenesis and lipogenic gene expression. Pre-adipocytes proliferated dramatically faster in SC vs. IM cells, and in Bamei vs. Landrace breeds. Lipogenesis and lipogenic gene expression had a greater increase in Bamei than in Landrace, and in SC vs. IM in the process of differentiation. Glucose markedly promoted lipogenesis and lipogenic gene expression in differentiated adipocytes. The stimulation of high-glucose levels on lipogenesis and ChREBP and lipogenic gene expression was higher in SC than IM adipocytes, and in Bamei vs. Landrace. Insulin largely increased SREBP-1c expression, however it modestly stimulated lipogenesis and lipogenic gene expression, and there was no difference between cell populationsor between breeds. These data demonstrated that regional and varietal differences obviously existed in the development of porcine adipocytes. The proliferation and differentiation capacity of pre-adipocytes, and the adipocyte lipogenesis stimulated by glucose, are stronger in Bamei than Landrace, and in SC vs. IM adipocytes independent of breed.

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Effect of dietary energy source on in vitro substrate utilization and insulin sensitivity of muscle and adipose tissues of Angus and Wagyu steers

Cited by 57 publications

References 31 publications

Postweaning substitution of grazed forage with a high-energy concentrate has variable long-term effects on subcutaneous fat and marbling in Bos taurus genotypes1

Postweaning substitution of grazed forage with a high-energy concentrate has variable long-term effects on subcutaneous fat and marbling in Bos taurus genotypes1

Intramuscular fat content in meat-producing animals: development, genetic and nutritional control, and identification of putative markers

Comparison of the adipogenesis in intramuscular and subcutaneous adipocytes from Bamei and Landrace pigs

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