Effects of feeding diets rich in α-linolenic acid and copper on performance, carcass characteristics, and fatty acid profiles of feedlot heifers1

Alvarado-Gilis, C. A.; Aperce, C. C.; Miller, K. A.; Bibber-Krueger, C. L. Van; Uwituze, S.; Drouillard, James S.; Higgins, James J.

doi:10.2527/jas.2014-8011

Cited by 3 publications

(3 citation statements)

References 32 publications

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“…The above‐mentioned changes in lipid metabolism by copper supplementation (20–40 mg/kg DM) are published mainly by one research group (Engle and Spears, ; Engle et al., ,b,c); some recent studies in bulls found a decrease in cholesterol and an increase in the proportion of UFA in meat after supplementation of copper (30–40 mg/kg DM, background 4.7–7) (Correa et al., , ; Fagari‐Nobijari et al., ). On the other hand, these effects were not confirmed in Simmental steers (10 or 40 mg Cu/kg DM, background 5.1) (Engle and Spears, ), in feedlot Brangus bulls (40 mg Cu/kg DM, background 5.8) (Netto et al., ) and in beef heifers (16.8 and 98 mg Cu/kg DM complete diet) (Alvarado‐Gilis et al., ).…”

Section: Assessmentmentioning

confidence: 99%

Revision of the currently authorised maximum copper content in complete feed

2016

EFS2

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The Panel on Additives and Products or Substances used in Animal Feed (FEEDAP) reviewed (i) the copper requirements of food-producing and pet animals, (ii) the copper concentration in feed materials and complete feed, (iii) the copper bioavailability, and (iv) the calculated background copper concentration of complete feed. Also considered were (i) the influence of dietary copper on gut microbiota profile and on the bacterial antibiotic resistance in target animals and (ii) the environmental occurrence of bacterial heavy metal tolerance (copper resistance) and resistance to certain antibiotics. The data collected supported the possibility of a reduction in some of the currently authorised maximum contents (CAMC) for total copper in feed. The EFSA Panel developed an algorithm to derive newly proposed maximum contents (NPMC) from the requirement and the native dietary copper content. The NPMC (mg Cu/kg complete feed) comprised of maintained (m), decreased (d) and increased (i) values: 15 for bovine before the start of rumination (m), 30 for other bovine (d), 35 for caprine (i), 15 for ovine (m), 50 for crustacean (m) and 25 for other animal species ((d) for piglets up to 12 weeks, (m) for all other species). The NMPC support health, welfare and economic productivity of target animals, except piglets; performance of weaned piglets would be impacted. The NPMC values would not likely have any consequences on the consumers' intake of copper and are of no concern for the safety of the consumer. The reduction from 170 mg to 25 mg Cu/kg feed piglets would have the capacity to save 1,200 tonnes copper/year being spread in the field and thus, to reduce total copper emissions from farm animal production by about 20%. Thus, the reduction of the CAMC to the NPMC would have a significant impact on the concentrations of copper in the environment of piggeries.

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Section: Assessmentmentioning

confidence: 99%

Revision of the currently authorised maximum copper content in complete feed

2016

EFS2

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“…Lipidomics analysis has revealed that palmitic acid impaired the development of hepatocellular carcinoma by regulating cell membrane fluidity and glucose metabolism [ 44 ]. Furthermore, research has demonstrated that adding Cu to the diet leads to higher concentrations of fatty acids in calf plasma [ 46 ]. This effect may be due to the crucial role of Cu in the activity of enzymes involved in fatty acid synthesis and metabolism.…”

Section: Discussionmentioning

confidence: 99%

Transcriptomics and metabolomics analysis reveal the dietary copper deficiency and supplementation effects of liver gene expression and metabolite change in grazing sheep

Jin,

Meng,

et al. 2024

BMC Genomics

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Background The appropriate mineral nutrients are essential for sheep growth and reproduction. However, traditional grazing sheep often experience mineral nutrient deficiencies, especially copper (Cu), due to inadequate mineral nutrients from natural pastures. Results The results indicated that dietary Cu deficiency and supplementation significantly reduced and elevated liver concentration of Cu, respectively (p < 0.05). FOXO3, PLIN1, ACTN2, and GHRHR were identified as critical genes using the weighted gene co-expression network analysis (WGCNA), quantitative real-time polymerase chain reaction (qRT-PCR), and receiver operating characteristic curve (ROC) validation as potential biomarkers for evaluating Cu status in grazing sheep. Combining these critical genes with gene functional enrichment analysis, it was observed that dietary Cu deficiency may impair liver regeneration and compromise ribosomal function. Conversely, dietary Cu supplementation may enhance ribosomal function, promote lipid accumulation, and stimulate growth and metabolism in grazing sheep. Metabolomics analysis indicated that dietary Cu deficiency significantly decreased the abundance of metabolites such as cholic acid (p < 0.05). On the other hand, dietary Cu supplementation significantly increased the abundance of metabolites such as palmitic acid (p < 0.05). Integrative analysis of the transcriptome and metabolome revealed that dietary Cu deficiency may reduce liver lipid metabolism while Cu supplementation may elevate it in grazing sheep. Conclusions The Cu content in diets may have an impact on hepatic lipid metabolism in grazing sheep. These findings provide new insights into the consequences of dietary Cu deficiency and supplementation on sheep liver and can provide valuable guidance for herders to rationalize the use of mineral supplements.

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“…36 Efforts have been made to improve meat FA profile according to health recommendations leading to meat products with reduced SFA and cholesterol and improved contents of MUFA, n-3 or CLA. For example, feeding beef cattle with rumen-protected fish oil supplements 37 or oil seeds 38 can be used to increase C20:5n-3 and C22:6n-3 concentrations. Also, there have been efforts to modulate the genetics of bovines to increase total n-3 FA: Cheng et al 39 demonstrated that the codon-optimized C. elegans mfat1 gene can be functionally expressed in beef cattle and converts n-6 PUFAs to n-3 PUFAs.…”

Section: Ruminant Meat and Human Healthmentioning

confidence: 99%

Impacts of fat from ruminants' meat on cardiovascular health and possible strategies to alter its lipid composition

Vargas‐Bello‐Pérez

Larraín

2017

J Sci Food Agric

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In the last few decades there has been increased consumer interest in the fatty acid (FA) composition of ruminant meat due to its content of saturated FAs, which have been implicated in diseases associated with modern life. However, recent studies have questioned the recommendations to reduce intake of fat, saturated FAs and cholesterol as a means of reducing the risk of cardiovascular disease. Interestingly, ruminant meat has some bioactive lipids such as C18:1t11 and C18:2 c9, t11 which have been reported to have positive effects on human health. In order to improve muscle fat composition from a human health standpoint, oilseeds, plant oils and marine oils can be used in ruminant diets. On the other hand, molecular mechanisms play an important role in the alteration of the FA composition of muscle fat. Genetics offer a wide range of possibilities for improvement of muscle fat composition by identifying different loci underlying the expression of quantitative traits. While significant progress has been made in characterizing the influence of diet on the FA composition of ruminant meat, the use of genetic tools can favor genotypes that could maximize their genetic potential through the diet. © 2016 Society of Chemical Industry.

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Effects of feeding diets rich in α-linolenic acid and copper on performance, carcass characteristics, and fatty acid profiles of feedlot heifers1

Cited by 3 publications

References 32 publications

Revision of the currently authorised maximum copper content in complete feed

Revision of the currently authorised maximum copper content in complete feed

Transcriptomics and metabolomics analysis reveal the dietary copper deficiency and supplementation effects of liver gene expression and metabolite change in grazing sheep

Impacts of fat from ruminants' meat on cardiovascular health and possible strategies to alter its lipid composition

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