Gene expression of hepatic gluconeogenic and fatty acid metabolism in early-lactation dairy cows as affected by dietary starch and monensin supplementation

M M McCarthy; G D Mechor; A W Holloway; T R Overton; E A Horst

doi:10.3168/jdsc.2023-0430

Gene expression of hepatic gluconeogenic and fatty acid metabolism in early-lactation dairy cows as affected by dietary starch and monensin supplementation

JDS Commun. 2023 Nov 4;5(2):161-166. doi: 10.3168/jdsc.2023-0430. eCollection 2024 Mar.

Authors

M M McCarthy¹, G D Mechor², A W Holloway², T R Overton¹, E A Horst²

Affiliations

¹ Department of Animal Science, Cornell University, Ithaca, NY 14853.
² Elanco Animal Health, Greenfield, IN 46140.

Abstract

Our previously published companion papers demonstrated improved production performance and energetic metabolism in cows fed diets with increased propiogenic potential in early lactation. Study objectives were to further explore effects of dietary starch content and monensin on hepatic gene expression of key enzymes related to gluconeogenesis and fatty acid metabolism in early lactation. From d 1 to 21 postpartum, primiparous (n = 16) and multiparous (n = 33) Holstein cows were fed a high (HS; 26.2% starch, 34.3% neutral detergent fiber, 22.7% acid detergent fiber, 15.5% crude protein) or low (LS; 21.5% starch, 36.9% neutral detergent fiber, 25.2% acid detergent fiber, 15.4% crude protein) starch diet with a daily topdress containing either 0 (Con) or 450 mg/d monensin (Mon). Cows were randomly assigned to treatment. Liver biopsies were obtained from cows on d 7 postpartum for DNA and RNA quantification and mRNA expression analysis. In primiparous cows, Mon supplementation decreased CPT1A expression relative to controls, whereas in multiparous cows Mon increased its expression. Cows fed HS and Mon tended to have decreased HMGCS2 expression relative to cows fed HS and Con. In multiparous cows, Mon supplementation tended to increase PC and PCK1 expression relative to controls. Correlation analysis was performed for all gene expression variables. Overall, relationships were similar in directionality and magnitude between cows fed HS and LS and Con and Mon. However, for cows fed Con there was a positive relationship between HMGCS2 and PC and HMGCS2 and PCK1, whereas for cows fed Mon there was no relationship. There was a similar lack of relationship between HMGCS2 and PC for cows fed HS. Overall, results support changes in performance and energetic metabolism reported in our companion papers, indicating that cows fed diets of different starch content in early lactation with Mon supplementation throughout the transition period had alterations in hepatic gene expression consistent with increased hepatic propionate supply.