A mathematical model for mammary fatty acid synthesis and triglyceride assembly: the role of stearoyl CoA desaturase (SCD)

Paul R Shorten; Tony B Pleasants; Girish C Upreti

doi:10.1017/S0022029904000354

Abstract

An increase in the proportion of unsaturated fatty acids in milk is considered desirable for human health. A prerequisite for the manipulation of milk fat composition is a co-ordinated understanding of the complex interactions in its biosynthesis. It has been suggested that an increase in the expression of mammary stearoyl-CoA-desaturase (SCD) would enrich mono-unsaturated fatty acids in milk, and therefore improve its nutritional properties. To investigate the potential effects of changes in expression of mammary enzymes and substrate availability on milk fat composition, we constructed, parameterized and evaluated a mechanistic mathematical model of fatty acid biosynthesis and milk-fat triglyceride assembly. The objective was to describe changes in the amount and composition of milk fat produced by bovine mammary cells due to changes in nutrition. Using the model we found that a 50% up-regulation in SCD activity increased the molar fraction of milk triglyceride 18[ratio ]1 from 0·30 to 0·33 and 16[ratio ]1 from 0·04 to 0·06. Up-regulation of SCD therefore did not appear to be the optimal method for increasing the content of unsaturated fatty acids in milk fat. The model was also used to determine the likely rate-limiting processes for the incorporation of unsaturated fatty acids into milk fat. Halving the concentration of glycerol 3-phosphate increased the molar fraction of milk triglyceride 18[ratio ]1 from 0·30 to 0·35 and decreased the molar fraction of milk triglyceride 16[ratio ]0 from 0·30 to 0·22. This achieved the desirable outcome of producing more unsaturated low-fat milk. Our model also predicted that a K232A mutation in the bovine mammary DGAT1 gene that is linked with an increase in milk fat yield would be consistent with a 120% increase in the DGAT acylation rate and also would be associated with a decrease in milk mono-unsaturated fatty acids.

Crossref Citations

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Shorten, P.R. and Upreti, G.C. 2005. A mathematical model of fatty acid metabolism and VLDL assembly in human liver. Biochimica et Biophysica Acta (BBA) - Molecular and Cell Biology of Lipids, Vol. 1736, Issue. 2, p. 94.

Carroll, S.M. DePeters, E.J. Taylor, S.J. Rosenberg, M. Perez-Monti, H. and Capps, V.A. 2006. Milk composition of Holstein, Jersey, and Brown Swiss cows in response to increasing levels of dietary fat. Animal Feed Science and Technology, Vol. 131, Issue. 3-4, p. 451.

Schennink, A. Stoop, W. M. Visker, M. H. P. W. Heck, J. M. L. Bovenhuis, H. Van Der Poel, J. J. Van Valenberg, H. J. F. and Van Arendonk, J. A. M. 2007. DGAT1 underlies large genetic variation in milk‐fat composition of dairy cows. Animal Genetics, Vol. 38, Issue. 5, p. 467.

Moate, P.J. Chalupa, W. Boston, R.C. and Lean, I.J. 2008. Milk Fatty Acids II: Prediction of the Production of Individual Fatty Acids in Bovine Milk. Journal of Dairy Science, Vol. 91, Issue. 3, p. 1175.

Taugbøl, O. Karlengen, I. J. Bolstad, T. Aastveit, A. H. and Harstad, O. M. 2008. Cobalt supplied per os reduces the mammary Δ9-desaturase index of bovine milk1. Journal of Animal Science, Vol. 86, Issue. 11, p. 3062.

Cabrita, A.R.J. Vale, J.M.P. Bessa, R.J.B. Dewhurst, R.J. and Fonseca, A.J.M. 2009. Effects of dietary starch source and buffers on milk responses and rumen fatty acid biohydrogenation in dairy cows fed maize silage-based diets. Animal Feed Science and Technology, Vol. 152, Issue. 3-4, p. 267.

van Arendonk, J.A.M. van Valenberg, H.J.F. and Bovenhuis, H. 2010. Improving the Safety and Quality of Milk. p. 197.

Bannink, André France, James and Dijkstra, Jan 2011. Systems Biology and Livestock Science. p. 191.

Woelders, H. Te Pas, M.F.W. Bannink, A. Veerkamp, R.F. and Smits, M.A. 2011. Systems biology in animal sciences. Animal, Vol. 5, Issue. 7, p. 1036.

Communod, Ricardo Guida, Silvia Vigo, Daniele Beretti, Valentino Munari, Eleonora Colombani, Carla Superchi, Paola and Sabbioni, Alberto 2013. Body Measures and Milk Production, Milk Fat Globules Granulometry and Milk Fatty Acid Content in Cabannina Cattle Breed. Italian Journal of Animal Science, Vol. 12, Issue. 1, p. e18.

Lin, Xian-zi Luo, Jun Zhang, Li-ping Wang, Wei Shi, Heng-bo and Zhu, Jiang-jiang 2013. miR-27a suppresses triglyceride accumulation and affects gene mRNA expression associated with fat metabolism in dairy goat mammary gland epithelial cells. Gene, Vol. 521, Issue. 1, p. 15.

Abdou-Arbi, Oumarou Lemosquet, Sophie Milgen, Jaap Van Siegel, Anne and Bourdon, Jérémie 2014. Exploring metabolism flexibility in complex organisms through quantitative study of precursor sets for system outputs. BMC Systems Biology, Vol. 8, Issue. 1,

Nafikov, Rafael A. Schoonmaker, Jon P. Korn, Kathleen T. Noack, Kristin Garrick, Dorian J. Koehler, Kenneth J. Minick-Bormann, Jennifer Reecy, James M. Spurlock, Diane E. and Beitz, Donald C. 2014. Polymorphisms in lipogenic genes and milk fatty acid composition in Holstein dairy cattle. Genomics, Vol. 104, Issue. 6, p. 572.

Tăbăran, A. Balteanu, V. A. Gal, E. Pusta, D. Mihaiu, R. Dan, S. D. Tăbăran, A. F. and Mihaiu, M. 2015. Influence of DGAT1 K232A Polymorphism on Milk Fat Percentage and Fatty Acid Profiles in Romanian Holstein Cattle. Animal Biotechnology, Vol. 26, Issue. 2, p. 105.

Sun, Yuting Luo, Jun Zhu, Jiangjiang Shi, Hengbo Li, Jun Qiu, Siyuan Wang, Ping and Loor, Juan J. 2016. Effect of short‐chain fatty acids on triacylglycerol accumulation, lipid droplet formation and lipogenic gene expression in goat mammary epithelial cells. Animal Science Journal, Vol. 87, Issue. 2, p. 242.

Pruett, William A. and Hester, Robert L. 2016. The Digital Patient. p. 127.

Hue-Beauvais, Cathy Aujean, Etienne Miranda, Guy Ralliard-Rousseau, Delphine Valentino, Sarah Brun, Nicolas Ladebese, Stessy Péchoux, Christine Chavatte-Palmer, Pascale Charlier, Madia and Larcombe, Alexander 2019. Impact of exposure to diesel exhaust during pregnancy on mammary gland development and milk composition in the rabbit. PLOS ONE, Vol. 14, Issue. 2, p. e0212132.

Requena, Francisco Peña, Francisco Agüera, Estrella and Marín, Andrés Martínez 2020. A Meta-Analytic Approach to Predict Methane Emissions from Dairy Goats Using Milk Fatty Acid Profile. Sustainability, Vol. 12, Issue. 12, p. 4834.

Chen, Guanqun Harwood, John L. Lemieux, M. Joanne Stone, Scot J. and Weselake, Randall J. 2022. Acyl-CoA:diacylglycerol acyltransferase: Properties, physiological roles, metabolic engineering and intentional control. Progress in Lipid Research, Vol. 88, Issue. , p. 101181.

Pathak, Upasana Das, Abhichandan Kumar Bora, Pranjal and Rajkhowa, Sanchaita 2023. Systems Biology, Bioinformatics and Livestock Science. p. 279.

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A mathematical model for mammary fatty acid synthesis and triglyceride assembly: the role of stearoyl CoA desaturase (SCD)

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A mathematical model for mammary fatty acid synthesis and triglyceride assembly: the role of stearoyl CoA desaturase (SCD)

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