Abstract P2007: Novel Regulatory Axis In Heart-adrenal Cross Talk Mediated By Mtor-eprs

Abstract

Adrenal catecholamines, including norepinephrine and epinephrine play an important role in cardiovascular physiology. Serum catecholamine level is tightly regulated in response to metabolic and cardiac stress. The biosynthesis of catecholamine is driven by a series of enzymatic reaction carried out by the key rate-limiting enzymes, including tyrosine hydroxylase (TH), DOPA decarboxylase (DDC) and phenylethanolamine-N-methyltransferase (PNMT). Although the transcription regulation of these enzymes has been described before, the regulatory mechanism at post-transcription or protein translation level has never been explored. Using a system genetics approach, we explored genes associated with the adrenal gland traits in HMDP at basal and post isoproterenol treatment. We have identified EPRS (Glutamyl-Prolyl-tRNA synthetase) to be significantly associated with adrenal gland mass post ISO treatment. EPRS is a tRNA synthetase responsible for charging tRNA during protein translation, EPRS also regulates mRNA translation as an RNA binding protein. To explore the functional impact of EPRS in adrenal gland physiology, we generated an EPRS adrenal gland specific knockout mouse model (EPRS-aKO). Inactivation of EPRS in adrenal gland led to a decrease of adrenal gland mass associated with reduced systemic catecholamine level. Interestingly, we further observed a moderate yet significantly decreased heart rate and ejection fraction in EPRS-aKO mice. Through both in vivo and in vitro analysis, we confirmed inactivation of EPRS led to a reduced protein, but not mRNA expression for both TH and DDC. In adipose tissue, activation of EPRS through mTOR signaling pathway is critical for its function as RNA binding protein. To further explore the mechanism through EPRS mediated catecholamine synthesis, we treated PC12 cells with rapamycin to inhibit mTOR activity. Treatment with Rapamycin diminished EPRS activity and expression, reduced TH protein expression along with a decrease of catecholamine level. Our results identified a novel regulatory scheme of catecholamine synthesis through mTOR-EPRS axis, adding a novel layer of gene regulation in catecholamine production and providing new mechanistic insights for heart-adrenal cross talk.