Prenatal and pre-weaning growth and nutrition of cattle: long-term consequences for beef production

633

447

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.

Section: How Might Marbling Begin?mentioning

confidence: 88%

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

Hocquette

Gondret

Baéza³

et al. 2010

633

447

“…Papstein et al (1999) have previously shown that the total number of fibres in M. longissimus was lower in twin compared with single-born beef cattle that were heavier at birth. Greenwood and Cafe (2007) reported smaller weight and cross-sectional area of longissimus muscle in response to retarded intrauterine growth, but apparent fibre number at 30 months of age was not different. Similarly, no differences in beef quality were apparent.…”

Section: Regulation Of Myogenesis and Environmental Impactmentioning

confidence: 86%

“…Taken together, these sheep and cattle studies suggest that restricted foetal growth resulting in low birth weight has similar consequences for postnatal growth rate and carcass composition as described in the pig and that this is related to myofibre number and/or muscular DNA content, whereas the effects on meat quality seem to be marginal. Species specificities in the nutritional foetal programming have been observed between ovine and bovine, due to differences in the timing of placental and foetal growth (Greenwood and Cafe, 2007) In conclusion, impaired myogenesis resulting in low skeletal myofibre and myonuclear numbers is considered one of the main reasons for the negative long-term consequences of IUGR on muscle growth.…”

Section: Regulation Of Myogenesis and Environmental Impactmentioning

confidence: 98%

“…Environmental impact on skeletal muscle development and consequences for animal growth, carcass and meat quality Prenatal and early postnatal nutrition There is evidence for prenatal effects of nutrition on postnatal development of skeletal muscle in a variety of species, but mainly in young offspring of sheep, pigs, cattle and laboratory animals (Greenwood and Cafe, 2007;Brameld and Daniel, 2008;Funston et al, 2010). To investigate the effects of in utero nutrition in mammals, two experimental models have been considered in this respect: first, the natural variation in birth weight of litter-or twin-bearing animals, which is most probably a result of different levels of nutrition in utero, and second, changes in maternal nutrition at different stages of pregnancy.…”

Section: Regulation Of Myogenesis and Environmental Impactmentioning

confidence: 99%

See 1 more Smart Citation

Advances in research on the prenatal development of skeletal muscle in animals in relation to the quality of muscle-based food. I. Regulation of myogenesis and environmental impact

Rehfeldt

Pas

Wimmers

et al. 2011

Skeletal muscle development in vertebrates – also termed myogenesis – is a highly integrated process. Evidence to date indicates that the processes are very similar across mammals, poultry and fish, although the timings of the various steps differ considerably. Myogenesis is regulated by the myogenic regulatory factors and consists of two to three distinct phases when different fibre populations appear. The critical times when myogenesis is prone to hormonal or environmental influences depend largely on the developmental stage. One of the main mechanisms for both genetic and environmental effects on muscle fibre development is via the direct action of the growth hormone–insulin-like growth factor (GH–IGF) axis. In mammals and poultry, postnatal growth and function of muscles relate mainly to the hypertrophy of the fibres formed during myogenesis and to their fibre-type composition in terms of metabolic and contractile properties, whereas in fish hyperplasia still plays a major role. Candidate genes that are important in skeletal muscle development, for instance, encode for IGFs and IGF-binding proteins, myosin heavy chain isoforms, troponin T, myosin light chain and others have been identified. In mammals, nutritional supply in utero affects myogenesis and the GH–IGF axis may have an indirect action through the partitioning of nutrients towards the gravid uterus. Impaired myogenesis resulting in low skeletal myofibre numbers is considered one of the main reasons for negative long-term consequences of intrauterine growth retardation. Severe undernutrition in utero due to natural variation in litter or twin-bearing species or insufficient maternal nutrient supply may impair myogenesis and adversely affect carcass quality later in terms of reduced lean and increased fat deposition in the progeny. On the other hand, increases in maternal feed intake above standard requirement seem to have no beneficial effects on the growth of the progeny with myogenesis not or only slightly affected. Initial studies on low and high maternal protein feeding are published. Although there are only a few studies, first results also reveal an influence of nutrition on skeletal muscle development in fish and poultry. Finally, environmental temperature has been identified as a critical factor for growth and development of skeletal muscle in both fish and poultry.

“…Moreover, foetal growth of AT is thought to be a critical factor contributing to adult AT mass and thus to the lifelong productivity of the offspring based on (1) a strong postnatal hypertrophy of adipocytes, which mainly increase in number during the foetal growth (Vernon, 1986) and (2) evidence for foetal programming of postnatal AT growth in bovines (Greenwood and Cafe, 2007).…”

Section: Introductionmentioning

confidence: 99%

Foetal bovine intermuscular adipose tissue exhibits histological and metabolic features of brown and white adipocytes during the last third of pregnancy

Taga

Chilliard

Picard

et al. 2012

This study reports the metabolic and morphological characteristics of bovine intermuscular adipose tissue (AT) throughout foetal growth. Our hypothesis was that the histological and molecular features of intermuscular AT would be different from those previously reported for foetal perirenal AT, based on its anatomical location near the muscle and the recent identification of two distinct adipocyte precursors in mouse AT depending on their locations. To address this question, intermuscular AT was sampled from Charolais and Blond d'Aquitaine foetuses at 180, 210 and 260 days post conception (dpc). The two bovine breeds were chosen because of the higher adiposity of Charolais than Blond d'Aquitaine cattle during the postnatal life. Regardless of the breed, adipocyte volume increased slightly (138%, P , 0.01) with increasing foetal age. This was concomitant with a decrease ( P , 0.05) in the activity of enzymes involved in de novo fatty acid (FA) synthesis (FA synthase and glucose-6-phosphate dehydrogenase) and FA esterification (glycerol-3-phosphate dehydrogenase) when expressed per million adipocytes, and with an increase ( P < 0.01) in mRNA abundances for uncoupling protein 1, adiponectin and leptin (LEP) between 180 and 260 dpc. No difference was observed in the adipocyte volume between breeds, which was consistent with the lack of major between-breed differences in mRNA abundances or activities of enzymes involved in lipid metabolism. The mRNA abundance of lipoprotein lipase was maintained across ages, suggesting a storage of circulating FA rather than of FA synthesized de novo. Plasma LEP increased with foetal age, but only in the Charolais breed (171%, P < 0.01), and was two-to threefold higher in Charolais than Blond d'Aquitaine foetuses. Regardless of the breed, bovine intermuscular AT contained predominantly unilocular adipocytes believed to be white adipocytes that were larger at 260 dpc than at 180 dpc. These data thus challenge current concepts of the largely brown nature of bovine foetal AT (based on histological and metabolic features of perirenal AT as previously reported a few days before or after birth).