Hostname: page-component-8448b6f56d-cfpbc Total loading time: 0 Render date: 2024-04-19T03:46:34.164Z Has data issue: false hasContentIssue false
  • English
  • Français

Dietary n-3 PUFA affect lipid metabolism and tissue function-related genes in bovine muscle

Published online by Cambridge University Press:  18 November 2011

Beate Hiller ,
Jean-Francois Hocquette ,
Isabelle Cassar-Malek ,
Gerd Nuernberg  and
Karin Nuernberg
Beate Hiller*
Affiliation:
Research Unit Muscle Biology and Growth, Leibniz Institute for Farm Animal Biology, Wilhelm-Stahl-Allee 2, 18196Dummerstorf, Germany
Jean-Francois Hocquette
Affiliation:
INRA, UR1213, Unité de Recherches sur les Herbivores, Centre Clermont-Ferrand/Theix, 63122Saint-Genès-Champanelle, France
Isabelle Cassar-Malek
Affiliation:
INRA, UR1213, Unité de Recherches sur les Herbivores, Centre Clermont-Ferrand/Theix, 63122Saint-Genès-Champanelle, France
Gerd Nuernberg
Affiliation:
Research Unit Genetics and Biometry, Leibniz Institute for Farm Animal Biology, Wilhelm-Stahl-Allee 2, 18196Dummerstorf, Germany
Karin Nuernberg
Affiliation:
Research Unit Muscle Biology and Growth, Leibniz Institute for Farm Animal Biology, Wilhelm-Stahl-Allee 2, 18196Dummerstorf, Germany
*
*Corresponding author: Dr B. Hiller, fax +49 3820868852, email hiller@fbn-dummerstorf.de
Rights & Permissions [Opens in a new window]

Abstract

Gene expression profiles of bovine longissimus muscle as affected by dietary n-3 v.n-6 fatty acid (FA) intervention were analysed by microarray pre-screening of >3000 muscle biology/meat quality-related genes as well as subsequent quantitative RT-PCR gene expression validation of genes encoding lipogenesis-related transcription factors (CCAAT/enhancer-binding protein β, sterol regulatory element-binding transcription factor 1), key-lipogenic enzymes (acetyl-CoA carboxylase α (ACACA), fatty acid synthase (FASN), stearoyl-CoA desaturase (SCD)), lipid storage-associated proteins (adipose differentiation-related protein (ADFP)) and muscle biology-related proteins (cholinergic receptor, nicotinic, α1, farnesyl diphosphate farnesyl transferase 1, sema domain 3C (SEMA3C)). Down-regulation of ACACA (P = 0·00), FASN (P = 0·09) and SCD (P = 0·02) gene expression upon an n-3 FA intervention directly corresponded to reduced SFA, MUFA and total FA concentrations in longissimus muscle, whereas changes in ADFP (P = 0·00) and SEMA3C (P = 0·05) gene expression indicated improved muscle function via enhanced energy metabolism, vasculogenesis, innervation and mediator synthesis. The present study highlights the significance of dietary n-3 FA intervention on muscle development, maintenance and function, which are relevant for meat quality tailoring of bovine tissues and modulating animal production-relevant physiological processes.

Keywords

Gene expressionMicroarray/quantitative RT-PCR methodologyLipogenesisMuscle function
Type
Short Communication
Information
British Journal of Nutrition , Volume 108 , Issue 5 , 14 September 2012 , pp. 858 - 863
Copyright
Copyright © The Authors 2011

Continuously rising requirements of consumers, producers and nutritionists towards the sensory, techno-functional and tropho-functional attributes of animal origin foodstuffs have paved the way for novel meat quality tailoring strategies. Within the broad spectrum of methods to optimise meat quality traits, nutritional intervention of farm animals has been successfully exploited to modulate muscle tissue development, composition and characteristics(Reference Dunshea, D'Souza and Pethick1, Reference Wood, Enser and Fisher2).

Dietary intervention of ruminant and non-ruminant farm animals with exogenous fatty acid (FA) sources – such as linseed/linseed oil, rapeseed cake/oil, algae(Reference Raes, De Smet and Demeyer3) as well as pasture v. concentrate(Reference Nuernberg, Fischer and Nuernberg4) or grass-silage- v. maize-silage-based feeding regimens(Reference Herdmann, Nuernberg and Martin5) – has been demonstrated to improve meat quality traits by affecting intramuscular fat development quantitatively in regard to meat tenderness, juiciness and flavour(Reference Hocquette, Gondret and Baéza6) and qualitatively with respect to FA composition and n-6:n-3 FA ratio(Reference Nuernberg, Fischer and Nuernberg4, Reference Scollan, Hocquette and Nuernberg7). As the underlying mechanisms, genetically(Reference Zhang, Knight and Reecy8, Reference Orrù, Cifuni and Piasentier9) and physiologically(Reference Scollan, Hocquette and Nuernberg7) determined shifts in lipogenic gene expression, protein expression and enzyme activities were identified(Reference Bernard, Leroux and Chilliard10Reference Waters, Kelly and O'Boyle12).

Concerning the dietary intervention of farm animals with n-3 FA sources, previous investigations of our research group obtained beneficially reduced n-6:n-3 FA ratios in longissimus muscle of German Holstein bulls via diminished sterol regulatory element-binding transcription factor 1 (SREBF1), acetyl-CoA carboxylase α (ACACA), fatty acid synthase (FASN) and stearoyl-CoA desaturase (SCD) gene expression, Δ6D and SCD protein expression as well as SCD enzyme activity(Reference Herdmann, Nuernberg and Martin5, Reference Hiller, Herdmann and Nuernberg13, Reference Herdmann, Martin and Nuernberg14). Taking into account that an n-3 FA intervention affects in a complex manner the various metabolic pathways in tissues(Reference Sampath and Ntambi15), the present study aimed at a characterisation of the impact of n-3 v. n-6 FA-based feeding regimens on the expression levels of several muscle biology and meat quality-related genes. In this context, bovine longissimus muscle samples were pre-screened for overall gene expression profiles via microarray analysis (regarding a limited number of ten animals) and subjected to quantitative RT-PCR gene expression validation (regarding the total population of twenty-seven animals), addressing selected genes for which either certain expression differences had been obtained via microarray analysis or distinct dietary n-3 FA intervention effects had been hypothesised.

Methods and materials

Animals, study design and tissue sampling

German Holstein bulls were assigned to a maize-silage/n-6 FA-based control diet (control group (CG); n 14) or a grass-silage/n-3 FA-based intervention diet (intervention group (IG); n 13) during a fattening period of 245 (sd 40) d until a live weight of 623 (sd 26) kg (CG) or 626 (sd 20) kg (IG) at an age of 475 (sd 39) d (CG) or 513 (sd 33) d (IG) was reached.

Experimental diets were isoenergetically formulated; actual energy intake ranged between mean values of 112·5 MJ (CG) and 108·5 MJ (IG) metabolisable energy per d. The control diet consisted of 0·153 g crude protein, 0·03 g crude fat (22·9 % SFA, 26·0 % MUFA, 51·1 % PUFA; 46·3 % n-6 FA, 4·8 % n-3 FA; n-6:n-3 FA ratio = 9·6) and 0·07 g crude ash/g DM. The intervention diet consisted of 0·149 g crude protein, 0·04 g crude fat (23·6 % SFA, 17·6 % MUFA, 58·8 % PUFA; 22·3 % n-6 FA, 36·5 % n-3 FA; n-6:n-3 FA ratio = 0·6) and 0·12 g crude ash. The FA composition of the control and intervention diets is given in Table 1.

Table 1 Fatty acid (FA) composition (% of the total FA) of the control and intervention diets

* Determined by GC-flame ionisation detection analysis of fatty acid methyl esters; see Hiller et al. (Reference Hiller, Herdmann and Nuernberg13)

SFA = 10 : 0+11 : 0+12 : 0+13 : 0+14 : 0+15 : 0+16 : 0+17 : 0+18 : 0+20 : 0+21 : 0+22 : 0+23 : 0+24 : 0.

MUFA = 14 : 1+15 : 1+16 : 1+17 : 1+18 : 1n-9+18 : 1cis-11+18 : 1trans-9+18 : 1trans-10+18 : 1trans-11+22 : 1+24 : 1.

§ PUFA = n-3 PUFA+n-6 PUFA.

n-3 PUFA = 18 : 3n-3+18 : 4n-3+20 : 3n-3+20 : 5n-3+22 : 5n-3+22 : 6n-3.

n-6 PUFA = 18 : 2n-6+18 : 3n-6+20 : 2n-6+20 : 3n-6+20 : 4n-6+22 : 2n-6+22 : 4n-6.

Experimental animals were managed and slaughtered according to the national guidelines for animal welfare. Immediately after slaughter and exsanguination, longissimus muscle samples were taken from the right side of the carcass (between the thirteenth and fourteenth rib), snap-frozen in liquid N2 and stored at − 80°C until further analysis.

Gene expression analysis

Gene expression profile pre-screening was performed by microarray gene expression analysis of longissimus muscle samples of a randomly selected subpopulation of ten animals (n 5 (CG), n 5 (IG)). Tissue samples of the total population of twenty-seven animals (n 14 (CG), n 13 (IG)) were subjected to quantitative RT-PCR gene expression validation, addressing genes (adipose differentiation-related protein (ADFP), CCAAT/enhancer-binding protein β (CEBPB), cholinergic receptor, nicotinic, α1 (CHRNA1), farnesyl diphosphate farnesyl transferase 1 (FDFT1), sema domain 3C (SEMA3C)) for which certain expression differences had been obtained via microarray analysis, or genes (ACACA, FASN, SCD, SREBP) for which distinct dietary n-3 FA intervention effects had been hypothesised.

Gene expression analysis via microarray experiment

Expression of >3000 genes involved in muscle biology or meat quality of beef cattle was assessed with a custom-designed Agilent GENOTEND chip with several specific probes for each gene. The total number of probes was 10 257 of which 1614 were control probes for gene expression normalisation(Reference Hocquette, Bernard-Capel and Vuillaume16).

Total RNA was extracted from muscle samples and analysed for quantity and integrity (Agilent 2100 Bioanalyser; Agilent Technologies, Massy, France). RNA was amplified, labelled with Cy3 and purified(Reference Hocquette, Bernard-Capel and Vuillaume16). Labelled complementary RNA was fragmented and hybridised to an Agilent 8 × 15K custom Oligo Microarray. After washing, microarrays were scanned and data extracted with Feature Extraction 9.1 Software (Agilent Technologies)(Reference Hocquette, Bernard-Capel and Vuillaume16). Data of each array were normalised via the median of all 1614 control probes. Subsequently, data per probe were normalised via the median probe values of replicate arrays and log 2-transformed. Expression differences between the control and intervention groups were analysed by two-way ANOVA with fixed-factor diet and repeated-factor probes per gene, using proc MIXED of SAS (SAS Institute Inc., Cary, NC, USA)(17).

Gene expression analysis via quantitative RT-PCR

RNA was extracted from the muscle samples and analysed for RNA quantity, purity and integrity(Reference Hiller, Herdmann and Nuernberg13). RNA was reverse-transcribed with the iScriptTM complementary DNA Synthesis Kit (Bio-Rad Laboratories GmbH, Munich, Germany)(Reference Hiller, Herdmann and Nuernberg13). Quantitative RT-PCR (qRT-PCR) analysis was performed by subjecting reaction mixes of 5 μl iQ SYBR® Green Supermix (Bio-Rad Laboratories GmbH), 4 μl forward/reverse primer solution (0·2 μmol/l) and 1 μl complementary DNA template (10 ng/μl) to a thermocycling program of 10 s at 94°C, 30 s at 60°C and 45 s at 70°C (forty-five cycles)(Reference Hiller, Herdmann and Nuernberg13). Gene-specific oligonucleotides (Table 2) were designed with Primer3 (version 0.4.0; whitehead Institute for Biomedical Research, Cambridge, MA, USA). PCR analysis was performed in triplicate. Amplification specificity was confirmed by melt curve analysis, agarose gel electrophoresis and sequencing of PCR products(Reference Hiller, Herdmann and Nuernberg13).

Table 2 Specifications of gene-specific oligonucleotides

ACACA, acetyl-CoA carboxylase α; Fwd, forward; Rev, reverse; ADFP, adipose differentiation-related protein; CEBPB, CCAAT/enhancer-binding protein β; CHRNA1, cholinergic receptor, nicotinic, α1; FASN, fatty acid synthase; FDFT1, farnesyl diphosphate farnesyl transferase 1; SCD, stearoyl-CoA desaturase; SEMA3C, sema domain 3C; SREBF1, sterol regulatory element-binding transcription factor 1; RPS18, ribosomal protein S18; B2M, β2-microglobulin; SF3A1, splicing factor 3a, subunit 1; EEF1A2, eukaryotic translation elongation factor 1, α2

* Determined by plotting the C t values of 10·0, 1·0, 0·5, 0·1 and 0·01 ng complementary DNA v. the logarithm of the corresponding complementary DNA amount.

Relative gene expression was calculated with the comparative, efficiency-corrected ΔΔC t method, using splicing factor 3a, subunit 1, eukaryotic translation elongation factor 1, α2, ribosomal protein S18 and β2-microglobulin for gene expression normalisation. Differences in gene expression profiles between the control and intervention groups were tested for significance using REST© algorithm (REST© 2009, version 2.0.13; TUM, Munich, Germany)(Reference Pfaffl, Horgan and Dempfle18).

Results

Expression of muscle biology and meat quality-related genes as affected by n-3 v. n-6 FA intervention was assessed via microarray gene expression pre-screening (regarding a limited number of ten animals) and qRT-PCR gene expression validation (regarding the total population of twenty-seven animals). Of an initial set of >3000 pre-screened genes, Tables 3 and 4 summarise the gene expression results derived for selected genes encoding lipogenesis-related transcription factors (CEBPB, SREBF1), key-lipogenic enzymes (ACACA, FASN, SCD), lipid storage-associated proteins (ADFP) and muscle biology-related proteins (CHRNA1, FDFT1, SEMA3C).

Table 3 Microarray gene expression analysis (n 10) results

(Fold changes and 95 % confidence intervals)

FC, fold change; ACACA, acetyl-CoA carboxylase α; ADFP, adipose differentiation-related protein; CEBPB, CCAAT/enhancer-binding protein β; CHRNA1, cholinergic receptor, nicotinic, α1; FASN, fatty acid synthase; FDFT1, farnesyl diphosphate farnesyl transferase 1; SCD, stearoyl-CoA desaturase; SEMA3C, sema domain 3C; SREBF1, sterol regulatory element-binding transcription factor 1.

Table 4 Quantitative RT-PCR gene expression validation (n 27) results

(Fold changes and 95 % confidence intervals)

FC, fold change; ACACA, acetyl-CoA carboxylase α; ADFP, adipose differentiation-related protein; CEBPB, CCAAT/enhancer-binding protein β; CHRNA1, cholinergic receptor, nicotinic, α1; FASN, fatty acid synthase; FDFT1, farnesyl diphosphate farnesyl transferase 1; SCD, stearoyl-CoA desaturase; SEMA3C, sema domain 3C; SREBF1, sterol regulatory element-binding transcription factor 1.

Microarray pre-screening of a limited number of ten animals indicated down-regulation of ACACA (fold change (FC) = 0·80), ADFP (FC = 0·69), FASN (FC = 0·82) and SCD (FC = 0·88) gene expression upon dietary n-3 FA intervention (Table 3), which was confirmed to be significant in the case of ACACA (P = 0·00; FC = 0·78), ADFP (P = 0·00; FC = 0·80) and SCD gene (P = 0·02; FC = 0·83) by qRT-PCR analysis of the total population of twenty-seven animals (Table 4). Up-regulated CEBPB (FC = 1·41), CHRNA1 (FC = 1·75), FDFT1 (FC = 1·57) and SEMA3C (FC = 1·54) gene expression in the intervention than control group muscle samples such as that obtained by microarray pre-screening (Table 3) was confirmed to be significant in the case of SEMA3C gene (P = 0·05; FC = 1·10) by qRT-PCR analysis (Table 4). SREBF1 gene expression was not found to be affected by dietary intervention, via either microarray or qRT-PCR gene expression analysis (Tables 3 and 4).

Discussion

Dietary FA intervention of farm animals has been successfully exploited to improve carcass quality attributes via diet-induced shifts in meat quality-related transcriptome, proteome and metabolome(Reference Bernard, Leroux and Chilliard10Reference Waters, Kelly and O'Boyle12, Reference te Pas, Keuning and Hulsegge19). Preliminary investigations revealed that a dietary n-3 FA intervention of German Holstein bulls beneficially affected n-6:n-3 FA ratios and reduced SFA concentrations in longissimus muscle via diminished SREBF1, ACACA, FASN and SCD gene expression, Δ6D and SCD protein expression as well as SCD enzyme activity(Reference Herdmann, Nuernberg and Martin5, Reference Hiller, Herdmann and Nuernberg13, Reference Herdmann, Martin and Nuernberg14).

In addition to beneficial improvements of the FA composition of beef (see Hiller et al.(Reference Hiller, Herdmann and Nuernberg13); Table 5), the present study indicated that an n-3 FA supplementation affects in a complex manner the expression of various muscle biology and meat quality-related genes in bovine longissimus muscle. Of an initial set of more than 3000 individual genes analysed by microarray gene expression pre-screening, three major classes of genes were confirmed to be modulated by dietary n-3 FA intervention via qRT-PCR gene expression validation: genes encoding (a) lipogenesis-related enzymes, (b) intracellular lipid storage-associated proteins and (c) cell function and signalling-associated proteins.

Table 5 Fatty acids (FA, mg/100 g tissue) in longissimus muscle of experimental animals

(Mean values and standard deviations)

ACACA, acetyl-CoA carboxylase α; FASN, FA synthase; TFA, total fatty acids; SCD, stearoyl-CoA desaturase.

* Determined by GC-flame ionisation detection analysis of fatty acid methyl esters; see Hiller et al.(Reference Hiller, Herdmann and Nuernberg13).

SFA = 10 : 0+11 : 0+12 : 0+13 : 0+14 : 0+15 : 0+16 : 0+17 : 0+18 : 0+20 : 0+21 : 0+22 : 0+23 : 0+24 : 0.

MUFA = 14 : 1+15 : 1+16 : 1+17 : 1+18 : 1n-9+18 : 1cis-11+18 : 1trans-9+18 : 1trans-10+18 : 1trans-11+22 : 1+24 : 1.

§ PUFA = n-3 FA+n-6 FA.

n-3 FA = 18 : 3n-3+18 : 4n-3+20 : 3n-3+20 : 5n-3+22 : 5n-3+22 : 6n-3.

n-6 FA = 18 : 2n-6+18 : 3n-6+20 : 2n-6+20 : 3n-6+20 : 4n-6+22 : 2n-6+22 : 4n-6.

Concerning (a) lipogenesis-related genes, diminished expression of genes encoding enzymes involved in FA de novo synthesis (acetyl-CoA carboxylase α, FA synthase) and monodesaturation (stearoyl-CoA desaturase) was obtained upon n-3 FA intervention, which was confirmed to be significant in the case of ACACA and SCD genes by qRT-PCR analysis.

These findings correspond to FA composition analyses of the control and intervention group muscle samples, indicating significantly lower amounts of ACACA and FASN gene products 12 : 0 (1·5 mg (CG) v. 1·1 mg (IG)/100 g), 14 : 0 (64·9 mg (CG) v. 43·8 mg (IG)/100 g), 16 : 0 (635·7 mg v. 460·2 mg (IG)/100 g) and total FA (2397·9 mg (CG) v. 1805·7 mg (IG)/100 g) as well as SCD gene products 16 : 1 (91·9 mg (CG) v. 59·4 mg (IG)/100 g) and 18 : 1n-9 (907·8 mg (CG) v. 629·6 mg (IG)/100 g) in the intervention group muscle samples (see Hiller et al.(Reference Hiller, Herdmann and Nuernberg13); Table 5).

Although unsaturated FA intervention was already reported to cause tissue-, sex-(Reference Dridi, Taouis and Gertler20), breed-(Reference Dridi, Taouis and Gertler20) and developmental stage(Reference Wang, Bower and Reverter22)-dependent decreases in ACACA, FASN and SCD gene expression(Reference Joseph, Robbins and Pavan23), protein expression(Reference Herdmann, Nuernberg and Martin5) and enzyme activities(Reference Herdmann, Martin and Nuernberg14), the present results outline that – despite an extensive hydrogenation of exogenous unsaturated FA by ruminal microbiota(Reference Scollan, Hocquette and Nuernberg7)n-3 FA-based diets exert significantly more restrictive effects on tissue-specific, lipogenesis-related transcriptome associated with SFA, MUFA and total FA synthesis than n-6 FA-based diets. The aspect that the gene expression levels of transcription factors CEBPB and SREBF1 controlling ACACA, FASN and SCD gene expression did not significantly differ between the control and intervention groups in the present study implies that either the diet-induced shifts in CEBPB and SREBF1 gene expression preceded the chosen biological endpoints or the CEBPB and SREBF1 expression levels were post-transcriptionally affected by an n-3 FA intervention. An involvement of further lipogenic transcription factors (e.g. PPAR) in the mediation of exogenous n-3 FA-induced effects may also be considered in this regard.

Concerning (b) genes encoding lipid storage-associated proteins, significantly reduced expression of the ADFP gene was obtained in the intervention than control group tissue samples. Considering adipophilin as an essential lipid droplet coating protein(Reference Bickel, Tansey and Welte24, Reference McManaman, Zabaronick and Schaack25), it remains unclear whether reduced adipophilin gene expression results from an overall lower total FA amount in the intervention (1805·7 (sd 369·4) mg/100 g) than control (2397·9 (sd 932·0) mg/100 g) group muscle samples (see Hiller et al.(Reference Hiller, Herdmann and Nuernberg13); Table 5) or whether an n-3 FA-based diet induces specific, restrictive transcriptomic control mechanisms towards adipophilin expression mediated via e.g. PPAR and peroxisome proliferator response elements (PPRE)(Reference Bickel, Tansey and Welte24). Taking into account that adipophilin molecules associated with lipid droplet membranes sterically retard an enzymatic breakdown of intracellularly stored TAG by hormone-sensitive lipase (HSL) and adipose TAG lipase (ATGL)(Reference Listenberger, Ostermeyer-Fay and Goldberg26), the present findings may indicate that n-3 FA-based diets significantly improve muscle function by facilitating more rapid re-mobilisation and re-utilisation of stored lipids for energy homeostasis, organic syntheses and cell signalling processes than n-6 FA-based diets.

Regarding (c) genes encoding cell function and signalling-associated proteins, significant up-regulation of the SEMA3C gene was obtained by qRT-PCR analysis. In addition to acknowledged improvements of muscle function via increased cell membrane fluidity upon an n-3 FA supplementation(Reference Ayre and Hulbert27), the present findings may indicate enhanced muscle function via accelerated vasculogenesis/angiogenesis, innervation, mediator synthesis and immune response(Reference Banu, Teichman and Dunlap-Brown28). These findings as well as literature data concerning the induction of genes/pathways related to cell signalling (arylalkylamine N-acetyltransferase; AANAT), thermogenesis and oxidative control (uncoupling protein 2; UCP2), energy homeostasis (activator of Hsp90 ATPase-1; AHA1)(Reference Perez, Canon and Dunner29), insulin-mediated glucose utilisation(Reference Gingras, White and Chouinard30, Reference Hessvik, Bakke and Fredriksson31), metabolic switching(Reference Hessvik, Bakke and Fredriksson31) and muscle protein synthesis(Reference Smith, Atherton and Reeds32) strongly outline the significance of n-3 FA supplementation on muscle development, maintenance and function.

Altogether, the present study indicates the superiority of n-3 over n-6 FA-based diets by beneficially affecting meat quality and muscle biology-related transcriptome, which may be relevant in regard to meat quality tailoring of animal tissues via dietary FA intervention, as also with respect to human primary and secondary nutritional intervention against insulin resistance, hyperglycaemia, type 2 diabetes(Reference Gingras, White and Chouinard30) and muscle protein degradation syndromes(Reference Smith, Atherton and Reeds32).

Conclusions

Of an initial set of >3000 genes pre-screened by microarray methodology, qRT-PCR expression validation of genes encoding lipogenesis-related transcription factors (CEBPB, SREBF1), key-lipogenic enzymes (ACACA, FASN, SCD), lipid storage-associated proteins (ADFP) and muscle biology-related proteins (CHRNA1, FDFT1, SEMA3C) revealed significant down-regulation of ACACA, ADFP and SCD gene as well as up-regulation of SEMA3C gene upon n-3 v. n-6 FA intervention. Reduced levels of ACACA, FASN and SCD gene expression directly corresponded to reduced SFA, MUFA and total FA concentrations in longissimus muscle, whereas changes in ADFP and SEMA3C gene expression indicated improved muscle function via enhanced energy metabolism, vasculogenesis, innervation and mediator synthesis.

This study highlights the significance of alimentary n-3 FA intervention on muscle development, maintenance and function, which are relevant for tailoring meat quality traits and modulating animal production-relevant physiological processes.

Acknowledgements

The present study was conducted and financially supported within the framework of the EU Project ProSafeBeef (Project no. FOOD-CT-2006-36241). The GENOTEND project was funded by APIS-GENE, INTERBEV, FranceAgriMer, the Auvergne Regional Council and the private company IMAXIO. The GENOTEND chip has been protected under the number IDDN.FR.001.260011.000.R.C.2010.000.10300. Hybridisation and data analyses were performed by IMAXIO. The authors thank Carine Bernard-Capel for her help in the conception of the GENOTEND chip. The authors’ contributions are as follows: B. H. and K. N. designed the research, performed the qRT-PCR experiment and wrote the paper; J.-F. H. and I. C.-M. conducted the microarray experiment; and G. N. performed the statistical analyses. The authors declare that there are no conflicts of interest.

References

1Dunshea, FR, D'Souza, DN, Pethick, DW, et al. (2005) Effects of dietary factors and other metabolic modifiers on quality and nutritional value of meat. Meat Sci 71, 838.Google Scholar
2Wood, JD, Enser, M, Fisher, AV, et al. (1999) Manipulating meat quality and composition. Proc Nutr Soc 58, 363370.Google Scholar
3Raes, K, De Smet, S & Demeyer, D (2004) Effect of dietary fatty acids on incorporation of long chain polyunsaturated fatty acids and conjugated linoleic acid in lamb, beef and pork meat: a review. Anim Feed Sci Technol 113, 199221.CrossRefGoogle Scholar
4Nuernberg, K, Fischer, A, Nuernberg, G, et al. (2008) Meat quality and fatty acid composition of lipids in muscle and fatty tissue of Skudde lambs fed grass versus concentrate. Small Ruminant Res 74, 279283.Google Scholar
5Herdmann, A, Nuernberg, K, Martin, J, et al. (2010) Effect of dietary fatty acids on expression of lipogenic enzymes and fatty acid profile in tissues of bulls. Animal 4, 755762.Google Scholar
6Hocquette, JF, Gondret, F, Baéza, E, et al. (2010) Intramuscular fat content in meat-producing animals: development, genetic and nutritional control, identification of putative markers. Animal 4, 303319.Google Scholar
7Scollan, N, Hocquette, J-F, Nuernberg, K, et al. (2006) Innovations in beef production systems that enhance the nutritional and health value of beef lipids and their relationship with meat quality. Meat Sci 74, 1733.Google Scholar
8Zhang, S, Knight, TJ, Reecy, JM, et al. (2010) Associations of polymorphisms in the promoter I of bovine acetyl-CoA carboxylase-alpha gene with beef fatty acid composition. Anim Genet 41, 417420.Google Scholar
9Orrù, L, Cifuni, GF, Piasentier, E, et al. (2011) Association analyses of single nucleotide polymorphisms in the LEP and SCD1 genes on the fatty acid profile of muscle fat in Simmental bulls. Meat Sci 87, 344348.Google Scholar
10Bernard, L, Leroux, C & Chilliard, Y (2008) Expression and nutritional regulation of lipogenic genes in the ruminant lactating mammary gland. Adv Exp Med Biol 606, 67108.Google Scholar
11Ward, RE, Woodward, B, Otter, N, et al. (2010) Relationship between the expression of key lipogenic enzymes, fatty acid composition, and intramuscular fat content of Limousin and Aberdeen Angus cattle. Livestock Sci 127, 2229.Google Scholar
12Waters, SM, Kelly, JP, O'Boyle, P, et al. (2009) Effect of level and duration of dietary n-3 polyunsaturated fatty acid supplementation on the transcriptional regulation of {Delta}9-desaturase in muscle of beef cattle. J Anim Sci 87, 244252.Google Scholar
13Hiller, B, Herdmann, A & Nuernberg, K (2011) Dietary n-3 fatty acids significantly suppress lipogenesis in bovine muscle and adipose tissue: a functional genomics approach. Lipids 46, 557567.Google Scholar
14Herdmann, A, Martin, J, Nuernberg, G, et al. (2010) Effect of dietary n-3 and n-6 PUFA on lipid composition of different tissues of German Holstein bulls and the fate of bioactive fatty acids during processing. J Agric Food Chem 58, 83148321.Google Scholar
15Sampath, H & Ntambi, JM (2006) Regulation of gene expression by polyunsaturated fatty acids. Heart Metab 32, 3235.Google Scholar
16Hocquette, J-F, Bernard-Capel, C & Vuillaume, ML, et al. (2009) The GENOTEND chip: a tool to analyse gene expression in muscle of beef cattle BIT's 2nd Ann. Congress Expo of Molecular Diagnostics 2009; Beijing, China.Google Scholar
17SAS Institute Inc. (2009) SAS/STAT® 9.2, User's Guide, 2nd ed.Cary, NC: SAS Institute Inc.Google Scholar
18Pfaffl, MW, Horgan, GW & Dempfle, L (2002) Relative expression software tool for group-wise comparison and statistical analysis of relative expression results in real-time PCR. Nucleic Acids Res 30, 110.Google Scholar
19te Pas, MFW, Keuning, E, Hulsegge, B, et al. (2010) Longissimus muscle transcriptome profiles related to carcass and meat quality traits in fresh meat Piétrain carcasses. J Anim Sci 88, 40444055.Google Scholar
20Dridi, S, Taouis, M, Gertler, A, et al. (2007) The regulation of stearoyl-CoA desaturase gene expression is tissue specific in chickens. J Endocrinol 192, 229236.CrossRefGoogle Scholar
21Matsuhashi, T, Maruyama, S, Uemoto, Y, et al. (2011) Effects of bovine fatty acid synthase, stearoyl-coenzyme A desaturase, sterol regulatory element-binding protein 1, and growth hormone gene polymorphisms on fatty acid composition and carcass traits in Japanese Black cattle. J Anim Sci 89, 1222.Google Scholar
22Wang, YH, Bower, NI, Reverter, A, et al. (2009) Gene expression patterns during intramuscular fat development in cattle. J Anim Sci 87, 119130.Google Scholar
23Joseph, SJ, Robbins, KR, Pavan, E, et al. (2010) Effect of diet supplementation on the expression of bovine genes associated with fatty acid synthesis and metabolism. Bioinform Biol Insights 4, 1931.Google Scholar
24Bickel, PE, Tansey, JT & Welte, MA (2009) PAT proteins, an ancient family of lipid droplet proteins that regulate cellular lipid stores. Biochim Biophys Acta 1791, 419440.Google Scholar
25McManaman, JL, Zabaronick, W, Schaack, J, et al. (2003) Lipid droplet targeting domains of adipophilin. J Lipid Res 44, 668673.Google Scholar
26Listenberger, LL, Ostermeyer-Fay, AG, Goldberg, EB, et al. (2007) Adipocyte differentiation-related protein reduces the lipid droplet association of adipose triglyceride lipase and slows triacylglycerol turnover. J Lipid Res 48, 27512761.Google Scholar
27Ayre, KJ & Hulbert, AJ (1996) Dietary fatty acid profile influences the composition of skeletal muscle phospholipids in rats. J Nutr 126, 653662.Google Scholar
28Banu, N, Teichman, J, Dunlap-Brown, M, et al. (2006) Semaphorin 3C regulates endothelial cell function by increasing integrin activity. FASEB J 20, E1520E1527.Google Scholar
29Perez, R, Canon, J & Dunner, S (2010) Genes associated with long-chain omega-3 fatty acids in bovine skeletal muscle. J Appl Genet 51, 479487.CrossRefGoogle Scholar
30Gingras, A-A, White, PJ, Chouinard, PY, et al. (2007) Long-chain omega-3 fatty acids regulate bovine whole-body protein metabolism by promoting muscle insulin signalling to the Akt-mTOR-S6K1 pathway and insulin sensitivity. J Physiol 579.1, 269284.Google Scholar
31Hessvik, NP, Bakke, SS, Fredriksson, K, et al. (2010) Metabolic switching of human myotubes is improved by n-3 fatty acids. J Lipid Res 51, 20902104.Google Scholar
32Smith, GI, Atherton, P, Reeds, DN, et al. (2011) Dietary omega-3 fatty acid supplementation increases the rate of muscle protein synthesis in older adults: a randomized controlled trial. Am J Clin Nutr 93, 402412.Google Scholar
Figure 0

Table 1 Fatty acid (FA) composition (% of the total FA) of the control and intervention diets

Figure 1

Table 2 Specifications of gene-specific oligonucleotides

Figure 2

Table 3 Microarray gene expression analysis (n 10) results(Fold changes and 95 % confidence intervals)

Figure 3

Table 4 Quantitative RT-PCR gene expression validation (n 27) results(Fold changes and 95 % confidence intervals)

Figure 4

Table 5 Fatty acids (FA, mg/100 g tissue) in longissimus muscle of experimental animals(Mean values and standard deviations)