Late-Breaking: Maternal nutrient restriction and re-alimentation influences liver protein expression in fetal sheep

Abstract To determine the effects of maternal nutrient restriction and re-alimentation on the fetal liver proteome, 48 pregnant ewes with singletons were fed a control diet [100% National Research Council (NRC) requirements (CON)] starting at the beginning of gestation. On day 50 of gestation, a subset of ewes were fed either CON or 60% NRC requirements (RES). A subset of ewes were euthanized at day 90 of gestation (n = 7/treatment), and fetal liver samples collected. Remaining ewes were maintained on the current diet (CON-CON, n=6; RES-RES, n = 7) or switched to alternative diet (CON-RES, RES-CON; n=7/treatment). On day 130 of gestation, remaining ewes were euthanized, and fetal samples collected. Fetal liver proteins were extracted, digested by trypsin and subjected to multiplexed, label-based quantitative mass spectrometry analysis integrating Tandem Mass Tags. Proteins were identified and quantified using Proteome Discoverer (v2.5, Thermo Scientific) and differential abundance analysis was performed using ANOVA and post hoc Tukey’s HSD test. Hierarchal clustering analysis showed clustering of treatments by day of gestation. However, differences were also observed between treatments. At day 90 of gestation, 23 proteins were differentially expressed in RES compared with CON among which glycyl tRNA synthetase and pyruvate carboxylase were increased 12% and 10%, respectively (P < 0.03). At day 130 of gestation, 24, 5, and 71 proteins were differentially expressed in CON-RES, RES-CON, and RES-RES, respectively, compared with CON-CON. Carnosine dipeptidase 2 was decreased 7% in CON-RES and rho associated protein kinase and glycogen synthase 2 were increased 20% and 26% in RES-CON and RES-RES, respectively, compared with CON-CON (P < 0.04). These results indicate that nutrient restriction during mid- and late-gestation impacts expression of proteins involved in gluconeogenesis, glycogenesis, and the formation of carnosine, an integral molecule in beta-oxidation, and that re-alimentation alters proteins involved in cell migration pathways. Supported by USDA-AFRI grants 2016-67016-24884 and 2017-67016-26568.