PROJECT SUMMARY The epidemic of cardiometabolic disease occurring throughout the world is taking a heavy toll on individuals’ quality of life, along with a huge economic impact Excess caloric intake leading to obesity is a major driver of the cardiometabolic syndrome. Brown adipose tissue (BAT) evolved in homeotherms as a mean to maintain body temperature by generating heat from stored calories. Brown adipocytes are highly enriched in mitochondria and express a unique protein called uncoupling protein-1 (UCP1). UCP1 ‘uncouples’ the mitochondrial proton gradient from ATP production, thus avidly consuming glucose and fatty acids with the result being net energy expenditure. Active brown fat is present in adult humans and its amount is significantly correlated with reduced body fat and circulating triglycerides, greater insulin sensitivity, and lowered incidence of Type II diabetes. Increasing brown adipocyte amount and activity could reduce the risk of cardiometabolic disease. The sympathetic nervous system (SNS)-derived catecholamine norepinephrine, which act through β-adrenergic receptors and cAMP, is a well-established activator of BAT and the recruitment of UCP1-positive cells in white adipose tissue (WAT) depots (a process termed ‘browning’ or ‘beiging’). We have shown in prior work that the cardiac hormones atrial natriuretic peptide (ANP) and B-type natriuretic peptide (BNP) also stimulate a similar ‘browning’ program in mouse and human adipocytes, and protect against obesity-associated insulin resistance, hepatic steatosis and inflammation. This suggests that increasing NP signaling in adipose tissues is metabolically beneficial. NP activation of NP receptor A (NPRA) leads to cGMP production, while the NP ‘clearance receptor’ NPRC removes NPs from circulation, and the ratio of NPRA to NPRC determines NP signaling capacity. Clinical studies show that compared to lean individuals, obese individuals have lower circulating NP level, increased NPRC level in adipose tissue, and blunted lipolytic responses to NPs. We observed similar patterns of receptor expression and physiological responses in mice. It has been postulated that higher adipose NPRC levels increases NP clearance, thus reducing NP availability in the circulation and efficacy in target tissues, resulting in a so-called ‘natriuretic handicap’. On the other hand, conditions such as fasting and cold temperature exposure reduce the level of NPRC expression, resulting in an increased NPRA/NPRC ratio and thus NP/cGMP signaling. Our studies with mouse models further support these observations. We also find that the expression of other components of the NP signaling system, such as phosphodiesterase-9 and the peptidase neprilysin are also decreased in response to cold and βAR agonists The overall objective of this project is to: define the transcriptional regulatory mechanisms of the Nprc, Pde9 and Mme genes in human and mouse adipocytes; determine whether increased levels of NPRC in obesity...