RESUMO
In dairy cows, the lactating mammary glands synthesize serotonin, which acts in an autocrine-paracrine manner in the glands and is secreted into the periphery. Serotonin signaling during lactation modulates nutrient metabolism in peripheral tissues such as adipose and liver. We hypothesized that the elevation of circulating serotonin during lactation would increase nutrient partitioning to the mammary glands, thereby promoting milk production. Our objective was to elevate circulating serotonin via intravenous infusion of the serotonin precursor 5-hydroxytryptophan (5-HTP) to determine its effects on mammary supply and extraction efficiency of AA, and milk components production. Twenty-two multiparous mid-lactation Holstein cows were intravenously infused with 5-HTP (1 mg/kg body weight) or saline, in a crossover design with two 21-d periods. Treatments were infused via jugular catheters for 1 h/d, on d 1 to 3, 8 to 10, and 15 to 17 of each period, to maintain consistent elevation of peripheral serotonin throughout the period. Milk and blood samples were collected in the last 96 h of each period. Whole-blood serotonin concentration was elevated above saline control for 96 h after the last 5-HTP infusion. Dry matter intake was decreased for cows receiving 5-HTP, and on average they lost body weight over the 21-d period, in contrast to saline cows who gained body weight. Milk production and milk protein yield were lower in cows receiving 5-HTP during the 3 infusion days, but both recovered to saline cow yields in the days after. Although milk fat yield exhibited a day-by-treatment interaction, no significant difference occurred on any given day. Milk urea nitrogen concentration was lower in 5-HTP cows on the days following the end of infusions, but not different from saline cows on infusion days. Meanwhile, plasma urea nitrogen was not affected by 5-HTP infusion. Circulating concentrations of AA were overall transiently decreased by 5-HTP, with concentrations mostly returning to baseline within 7 h after the end of 5-HTP infusion. Mammary extraction efficiency of AA was unaffected by 5-HTP infusion. Overall, both lactation performance and circulating AA were transiently reduced in cows infused with 5-HTP, despite sustained elevation of circulating serotonin concentration.
Assuntos
5-Hidroxitriptofano , Lactação , Animais , Bovinos , Feminino , Aminoácidos/metabolismo , Peso Corporal , Dieta/veterinária , Infusões Intravenosas/veterinária , Proteínas do Leite , Serotonina , Ureia/análiseRESUMO
Energy partitioning in lactating cows affects milk production, feed efficiency, and body reserves, with the latter having health implications for the transition into the following lactation. One molecule likely involved in the regulation of energy partitioning is serotonin. The objective of this experiment was to explore how increasing circulating serotonin, by intravenous infusion of the serotonin precursor 5-hydroxytryptophan (5-HTP), affects metabolic responses to a glucose challenge in midlactation cows as a means to manipulate energy partitioning. We intravenously infused Holstein cows with 5-HTP (1 mg/kg bodyweight dissolved in saline, n = 11) or saline alone as control (n = 9) over 1 h/day for 3 days. Cows were fasted overnight on day 2. On day 3, fasted cows were given an intravenous bolus of glucose (0.092 g/kg bodyweight). Blood samples were collected for the following 120 min for metabolic and hormonal analysis. Infusion of 5-HTP elevated circulating concentrations of serotonin and free fatty acids, reduced the concentration of insulin and amino acids, and did not affect the concentration of glucose and glucagon before the glucose challenge. Surrogate insulin sensitivity indices indicated improved insulin sensitivity in 5-HTP cows, but due to the unique metabolism of lactating ruminants, these index changes may instead reflect effects in insulin-independent glucose disposal, like milk synthesis. Challenging 5-HTP-treated cows with a glucose bolus reduced the insulin spike and blunted the decrease in free fatty acids, compared to saline cows, without changing glucose dynamics. Overall, these results suggest that serotonin stimulates insulin-independent glucose disposal, requiring less insulin to maintain normoglycemia.