Effects of isoleucine, lysine, valine, and a group of non-essential amino acids on mammary amino acid metabolism in lactating dairy cows.

Abstract

Intracellular amino acids (AA) regulate milk protein synthesis within the mammary glands by modifying mammary plasma flow (MPF) and AA transporter activity. Amino acid transporters catalyze translocation using Na+-gradient, substrate gradient (uniporters), and exchange mechanisms; further, they exhibit specificity for individual AA or groups of AA with similar side-chain properties within each transport system. Non-essential AA are actively transported through Na+-dependent transporters and, thus, are often utilized as intracellular currencies for EAA transport through exchange transporters. Therefore, it was hypothesized that individual EAA supplementation would compete with other EAA for shared transporters, and supplementation with Ala, Gln, and Gly would stimulate EAA transport through exchange transporters. Ten primiparous lactating dairy cows were divided into 2 groups based on milk production and were randomly assigned to treatment sequences within 2 balanced 5 × 5 Latin Squares by group. Period length was 14 d. Treatments were 9-d jugular infusions of 1) saline; 2) 34.5 g Val/d; 3) 32.7 g Ala/d: 40 g Gln/d: 26.7 g Gly/d (AQG); 4) 43 g Lys/d; or 5) 33.5 g Ile/d. All cows were fed a common base diet formulated to contain 15.0% CP. Ile, Lys, or AQG infusions did not affect milk protein or milk production; however, Val infusion decreased both. The effects of Val infusion on milk protein production appeared to be partially driven by decreased DMI. The decline in milk protein percentage indicated that milk lactose production was also affected. Additionally, Val infusion increased MPF efficiency (MPF/Milk; L/L) by approximately 44%. Val infusion tended to decrease or decreased mammary net uptakes of Lys, Leu, Met, and total AA. Ile infusion tended to increase its mammary net uptakes but did not affect any other AA. Lys and AQG infusions did not affect any mammary net uptakes. Val infusion tended to decrease Phe and total NEAA mammary clearance rates. AQG infusion stimulated Tyr clearance rates and tended to decline System N mammary clearance rates. Mammary uptake to milk protein output ratios (U:O) of BCAA did not differ from 1 for Val-infused cows, which indicated that little intramammary catabolism was occurring. Additionally, the average NEAA U:O in response to all treatments except Val was 0.70, but Val-infused cows had NEAA U:O that averaged 0.09 indicating increased synthesis within the glands. The effects of Val on mammary net clearance rates of multiple EAA support the incorporation of AA limitations in ration optimizers to prevent AA imbalances. It is possible that over-supplementation of EAA other than Val may also decrease DMI and mammary activity. Identifying efficiency apexes for each of the EAA will allow more precise diet formulation and supplementation, leading to improved production efficiency.