Effects of fish oil and additional starch on tissue fatty acid profile and lipogenic gene mRNA abundance in lactating goats fed a diet containing sunflower-seed oil

Toral, Pablo G.; Bernard, L.; Delavaud, Carole; Gruffat, Dominique; Leroux, Christine; Chilliard, Yves

doi:10.1017/s1751731113000049

Cited by 32 publications

(26 citation statements)

References 36 publications

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“…Furthermore, Yang et al (2007) showed that FAs with a chain length longer than eight carbons could effectively inhibit FAT/CD36 expression in adipocytes, but unsaturated LCFAS had no effect. Dietary oil sources, such as lard oil, FO or sunflower-seed oil, differently influenced FAT/CD36 expression in the liver and muscle of rats (Feillet-Coudray et al 2013) and in the mammary secretory tissue and mental adipose tissue of goats (Toral et al 2013), whereas FAT/CD36 expression in the hepatopancreas was not affected by diets containing lard oil diet or FO in grass carp (Tian et al 2015). These previous studies give scarcely identical information on different longchain unsaturated FAs affecting FAT/CD36 expression.…”

Section: Fat/cd36 Mrna Expression Responses To Different Dietary Oil mentioning

confidence: 94%

LCFA Uptake and FAT/CD36: molecular cloning, tissue expression and mRNA expression responses to dietary oil sources in grass carp (Ctenopharyngodon idellus)

Zhou

Lin

et al. 2017

Journal of Applied Animal Research

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Section: Fat/cd36 Mrna Expression Responses To Different Dietary Oil mentioning

confidence: 94%

LCFA Uptake and FAT/CD36: molecular cloning, tissue expression and mRNA expression responses to dietary oil sources in grass carp (Ctenopharyngodon idellus)

Zhou

Lin

et al. 2017

Journal of Applied Animal Research

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“…For example, Hussein et al (2013) reported that trans-10 cis-12 CLA-induced MFD in lactating ewes involves the SREBF family and a coordinated downregulation of genes related to mammary lipid synthesis (e.g., ACACA, FASN, SCD1, AGPAT6, SREBF1 or INSIG1). In contrast, several studies in dairy sheep (Dervishi et al, 2012;Bichi et al, 2013a;Castro-Carrera et al, 2015) or dairy goats (Bernard et al, 2008;Tsiplakou et al, 2009;Toral et al, 2013) observed a weak relationship between changes in milk FA production and mammary mRNA abundance of key candidate genes and transcription factors involved in lipid metabolism. Yet, Bichi et al (2013a), who studied that relationship after 54 days on marine lipids, suggested that transcriptional regulation in dairy ewes might have been established earlier during the feeding period.…”

Section: Introductionmentioning

confidence: 94%

Fish oil-induced milk fat depression and associated downregulation of mammary lipogenic genes in dairy ewes

Carreño

Hervás

Toral

et al. 2016

Journal of Dairy Science

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A number of studies in dairy cows have shown a relationship between milk fat depression (MFD) and alterations caused in lipogenic gene expression by dietary nutrients.However, information in small ruminants is not only scarce but also inconsistent. Therefore, this experiment was conducted in dairy ewes to study the effect of a diet known to induce MFD on milk fatty acid (FA) composition and mRNA abundance of key candidate genes involved in mammary lipogenesis. Twelve lactating Assaf ewes (63 days in milk; SD = 7.8) were randomly assigned to 2 treatments consisting of a total mixed ration based on alfalfa hay and concentrates (50:50), supplemented with 0 (control) or 17 g of fish oil/kg of diet DM (FO). Profiles of milk FA and mRNA abundance of candidate genes in biopsied mammary tissue were examined before starting the treatments and after 1 and 4.5 weeks on the diets. As expected, FO induced MFD and modified milk FA composition. Compared with the control, 3 reductions in milk fat concentration and yield were not detected on day 7, but reached up to 25 and 22%, respectively, on day 30. However, increases in confirmed or putative antilipogenic FA (trans-10 cis-12 and trans-9 cis-11 18:2, cis-9 16:1, cis-11 18:1 and oxo-FA) were already established on the early stage of the treatment and lasted until the end of the feeding period. These changes were accompanied by decreases in the mRNA abundance of genes encoding lipogenic enzymes. The coordinated nature of the downregulation, which tended to affect most studied metabolic pathways, including FA activation (ACSS2), de novo synthesis (ACACA and FASN), uptake and transport (LPL and FABP3), desaturation (SCD1) and esterification (AGAPT6), supports the involvement of a central regulator of milk fat synthesis. In this regard, without ruling out the potential contribution of PPARG, our results suggest that SREBF1 would have a relevant role in the MFD syndrome in sheep fed FO.Among the other studied transcription factors, the tendency to a downregulation of INSIG1 was associated with that of SREBF1, whereas no variation was detected for SCAP or THRSP.Fish oil had no significant effects on the transcript abundance of CD36, GPAM, DGAT1, LPIN1 and XDH. Overall, changes in potential antilipogenic FA and mRNA abundance of candidate lipogenic genes support a relationship between them and suggest that FO-induced MFD in dairy ewes would be mediated by transcriptional mechanisms.

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“…Concerning the FA profile of the mammary tissue, there is very little literature reporting this data in ruminants (Christie, 1981;Toral et al, 2013) and no information is available in lactating ewes. In the present study, the virtual absence of shorter-chain FA (4 to 9 carbons, which are present in the milk) would suggest not only that residual milk was well removed but also a minor contribution of unsecreted cytosolic lipid droplets to extracted lipids.…”

Section: Mammary Lipid Metabolismmentioning

confidence: 99%

Dietary sunflower oil modulates milk fatty acid composition without major changes in adipose and mammary tissue fatty acid profile or related gene mRNA abundance in sheep

Castro-Carrera

Frutos

Leroux

et al. 2015

Animal

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There are very few studies in ruminants characterizing mammary and adipose tissue (AT) expression of genes and gene networks for diets causing variations in milk fatty acid (FA) composition without altering milk fat secretion, and even less complementing this information with data on tissue FA profiles. This work was conducted in sheep in order to investigate the response of the mammary gland and the subcutaneous and perirenal AT, in terms of FA profile and mRNA abundance of genes involved in lipid metabolism, to a diet known to modify milk FA composition. Ten lactating Assaf ewes were randomly assigned to two treatments consisting of a total mixed ration based on alfalfa hay and a concentrate (60 : 40) supplemented with 0 (control diet) or 25 (SO diet) g of sunflower oil/kg of diet dry matter for 7 weeks. Milk composition, including FA profile, was analysed after 48 days on treatments. On day 49, the animals were euthanized and tissue samples were collected to analyse FA and mRNA abundance of 16 candidate genes. Feeding SO did not affect animal performance but modified milk FA composition. Major changes included decreases in the concentration of FA derived from de novo synthesis (e.g. 12:0, 14:0 and 16:0) and increases in that of long-chain FA (e.g. 18:0, c9-18:1, trans-18:1 isomers and c9,t11-CLA); however, they were not accompanied by significant variations in the mRNA abundance of the studied lipogenic genes (i.e. ACACA, FASN, LPL, CD36, FABP3, SCD1 and SCD5) and transcription factors (SREBF1 and PPARG), or in the constituent FA of mammary tissue. Regarding the FA composition of AT, the little influence of SO did not appear to be linked to changes in gene mRNA abundance (decreases of GPAM and SREBF1 in both tissues, and of PPARG in the subcutaneous depot). Similarly, the great variation between AT (higher contents of saturated FA and trans-18:1 isomers in the perirenal, and of cis-18:1, c9,t11-CLA and n-3 PUFA in the subcutaneous AT) could not be related to differences in gene mRNA abundance due to tissue site (higher LPL and CD36, and lower SREBF1 in perirenal than in subcutaneous AT). Overall, these results suggest a marginal contribution of gene expression to the nutritional regulation of lipid metabolism in these tissues, at least with the examined diets and after 7 weeks on treatments. It cannot be ruled out, however, that the response to SO is mediated by other genes or post-transcriptional mechanisms.

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Effects of fish oil and additional starch on tissue fatty acid profile and lipogenic gene mRNA abundance in lactating goats fed a diet containing sunflower-seed oil

Cited by 32 publications

References 36 publications

LCFA Uptake and FAT/CD36: molecular cloning, tissue expression and mRNA expression responses to dietary oil sources in grass carp (Ctenopharyngodon idellus)

LCFA Uptake and FAT/CD36: molecular cloning, tissue expression and mRNA expression responses to dietary oil sources in grass carp (Ctenopharyngodon idellus)

Fish oil-induced milk fat depression and associated downregulation of mammary lipogenic genes in dairy ewes

Dietary sunflower oil modulates milk fatty acid composition without major changes in adipose and mammary tissue fatty acid profile or related gene mRNA abundance in sheep

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