Short communication: Hepatic progesterone-metabolizing enzymes cytochrome P450 2C and 3A in lactating cows during thermoneutral and heat stress conditions

Abstract

Two experiments were performed to determine the effects of heat stress (HS) and insulin on hepatic mRNA abundance of enzymes responsible for metabolizing progesterone [cytochrome P450 2C and 3A (CYP2C and CYP3A)]. To distinguish the direct effects of HS from decreased dry matter intake, cohorts were pair fed (PF) in thermoneutral conditions to match the intake of the HS cows during both experiments. In the first experiment, multiparous late-lactation Holstein cows (n=12, 305±33 d in milk) housed in climate-controlled chambers were subjected to 2 experimental periods: (1) thermoneutral (TN) conditions (18°C, 20% humidity) with ad libitum intake (TN and well fed) for 9 d; and (2) either HS conditions (cyclical temperature 31–40°C, 20% humidity) fed for ad libitum intake (n=6), or TN conditions and PF to match the HS animal (n=6) for 9 d. To evaluate hepatic gene expression during experiment 1, biopsies were obtained at the end of each period. In the second experiment, multiparous mid-lactation Holstein cows (n=12, 136±8 DIM) were housed and fed in conditions similar to those described for the first experiment. Liver biopsies were obtained immediately before and after an insulin tolerance test administered on d 6 of each period. No effects of exogenous insulin were observed on any of the tested variables, nor were there interactions between environment (TN/HS or well fed/PF) and insulin administration. Heat stress decreased hepatic CYP2C expression during both experiments. The relative abundance of CYP3A was not affected by environmental conditions in the late-lactation cows (first experiment), but was reduced by HS in the mid-lactation cows (second experiment). Interestingly, during experiment 2, hepatic CYP3A expression also decreased during PF. These results suggest that HS reduces the capacity of the liver to metabolize progesterone through distinct effects on CYP2C and CYP3A, and that the effects appear to vary based upon stage of lactation. Ultimately, HS may affect reproductive outcomes by reducing the abundance of the enzymes responsible for the breakdown of progesterone. This reduction could serve as a beneficial adaptation for rescuing early embryos or may be detrimental, as it affects feedback mechanisms necessary for proper cyclicity.