The threonyl-tRNA synthetase gene (thrS) is a member of the T-box family of approximately 250 genes, found essentially in Gram-positive bacteria, regulated by a tRNA-dependent antitermination mechanism in response to starvation for the cognate amino acid. While interaction between uncharged tRNA and the untranslated leader region of these genes has been firmly established by genetic means, attempts to show this interaction or to reconstitute the antitermination mechanism in vitro using purified tRNAs have so far failed. In addition, a number of conserved sequences have been identified in the T-box leaders, for which no function has yet been assigned. This suggests that factors other than the tRNA are important for this type of control. Here we demonstrate tRNA-mediated antitermination for the first time in vitro, using the regulatory tRNA(Thr) isoacceptor isolated from Bacillus subtilis and a partially purified protein fraction. As predicted by the model, aminoacylation of tRNA(Thr(GGU)) with threonine completely abolishes its ability to act as an effector. The role of the partially purified protein fraction can be functionally substituted by high concentrations of spermidine. However, this polyamine does not play a significant role in the induction of thrS expression in vivo, suggesting that it is specific protein co-factors that promote T-box gene regulation in conjunction with uncharged tRNA.
The effect of feed restriction on gene expression of regulatory enzymes of intermediary metabolism was studied in two sheep breeds (Australian Merino and Dorper) subjected to two nutritional treatments: feed restriction (85% of daily maintenance requirements) and control (ad libitum feeding), during 42 days. The experimental animals (ram lambs) were divided into four groups, n 5 5 (Australian Merino control (MC), Australian Merino Restriction (MR), Dorper control (DC) and Dorper Restriction (DR)). After the trial, animals were sacrificed and samples were taken from liver tissue to quantify glucose levels and gene expression of relevant intermediary metabolism enzymes (phosphofructokinase (PFK), pyruvate kinase (PK), phosphoenolpyruvate carboxykinase, fructose 1,6-bisphosphatase, glucose-6-phosphatase, glycogen synthase (GS), fatty acid synthase (FAS), glutamate dehydrogenase (GDH) and carbamoyl phosphate synthase (CPS)) through real-time PCR. During the experimental period, the MR animals lost 12.6% in BW compared with 5.3% lost by the Dorper lambs. MC and DC rams gained, respectively, 8.8% and 14% during the same period. Within the Dorper breed, restricted feed animals revealed a significant decrease over controls in the transcription of PFK (1.95-fold) and PK (2.26-fold), both glycolytic enzymes. The gluconeogenesis showed no change in the feed restricted animals of both breeds. DR feed group presented a significant decrease over the homologous Merino sheep group on GS. In both experimental breeds, FAS mRNA expression was decreased in restricted feed groups. GDH expression was decreased only in the DR animals (1.84-fold) indicating a reduced catabolism of amino acids in these animals. Finally, CPS was significantly (P , 0.05) higher in the Dorper sheep, indicating a facilitated urea synthesis in this breed. These results indicate a better adaptation of metabolic intermediate regulatory enzymes and hepatic glucose production of Dorper sheep to feed restriction concurring with the BW results in the experimental groups. ImplicationsThe relevant negative impact in livestock production due to seasonal dry periods within tropical and arid climate regions highlights the need to understand genetic and metabolic adaptation mechanisms to periodical feed restriction. Our results concerning changes in BW and genomic expressions of intermediary metabolism regulatory enzymes of ram lambs of Dorper and Australian Merino breeds subjected to ad libitum and to 85% maintenance energy requirements show that Dorper have a better adaptation to feed restriction than the Merino sheep. Our findings can contribute to future research guidelines leading to improved genetic selection toward livestock adaptation to harsh environments.
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