In vivo actions of SCTR/AT1aR heteromer in controlling Vp expression and release via cFos/cAMP/CREB pathway in magnocellular neurons of PVN.

With an increasing body of evidence regarding GPCR oligomerization and its clinical implications over the last decade, the modulation and dynamics of GPCR homo- and hetero-oligomers has more recently become an area of intense research focus. Previously, our lab showed in vitro heteromer formation between angiotensin II receptor type 1 subtype a (AT1aR) and secretin receptor (SCTR), which is involved in in vivo control of hyperosmolality-induced water drinking behavior. Because the secretin (SCT)/SCTR axis is crucial to the central actions of angiotensin II (ANGII) and both SCT and ANGII are capable of triggering vasopressin (Vp) release from hypothalamus, we investigated here the in vivo role of SCTR-AT1aR heteromer in regulating Vp release in hypothalamus using transmembrane peptides as tools. We showed that SCTR-AT1aR heteromer mediates stimulatory actions of both SCT and ANGII in hypothalamic Vp expression and release as well as neuronal activities via the immediate early gene cFos. The results from this study not only are consistent with our hypothesis that SCT and ANGII interact at the receptor level to mediate their water homeostatic activities but also provide evidence for in vivo functions of cross-class GPCR heteromers.-Mak, S. O. K., Zhang, L., Chow, B. K. C. In vivo actions of SCTR/AT1aR heteromer in controlling Vp expression and release via cFos/cAMP/CREB pathway in magnocellular neurons of PVN.

Secretin receptor deletion in the subfornical organ attenuates the activation of excitatory neurons under dehydration.

In mammals, thirst is strongly influenced by the subfornical organ (SFO), a forebrain structure that integrates circulating signals including osmotic pressure and sodium contents. Secretin (SCT), a classical gastrointestinal hormone, has been implicated as a humoral factor regulating body-fluid homeostasis. However, the neural mechanism of secretin in the central nervous system in managing thirst remains unclear. In this study, we report that the local ablation of SCT receptor (SCTR) in the SFO reduces water but not salt intake in dehydrated mice and this effect could not be rescued by exogenous SCT administration. Electrophysiology with single-cell RT-PCR indicates that SCT elicits inward currents in the SFO neuronal nitric oxide synthase (SFOnNOS) neurons via SCTR in the presence of glutamate receptor antagonists. We further show that the SCTR in the SFO permits the activation of SFOnNOS neurons under distinct thirst types. Projection-specific gene deletion of SCTR in SFO to the median preoptic nucleus (MnPO) pathway also reduces water intake in dehydrated animals. SCT signaling thus plays an indispensable role in driving thirst. These data not only expand the functional boundaries of SCTR but also provide insights into the central mechanisms of homeostatic regulation.

Loss of secretin results in systemic and pulmonary hypertension with cardiopulmonary pathologies in mice.

More than 1 billion people globally are suffering from hypertension, which is a long-term incurable medical condition that can further lead to dangerous complications and death if left untreated. In earlier studies, the brain-gut peptide secretin (SCT) was found to be able to control blood pressure by its cardiovascular and pulmonary effects. For example, serum SCT in patients with congestive heart failure was one-third of the normal level. These observations strongly suggest that SCT has a causal role in blood pressure control, and in this report, we used constitutive SCT knockout (SCT-/-) mice and control C57BL/6N mice to investigate differences in the morphology, function, underlying mechanisms and response to SCT treatment. We found that SCT-/- mice suffer from systemic and pulmonary hypertension with increased fibrosis in the lungs and heart. Small airway remodelling and pulmonary inflammation were also found in SCT-/- mice. Serum NO and VEGF levels were reduced and plasma aldosterone levels were increased in SCT-/- mice. Elevated cardiac aldosterone and decreased VEGF in the lungs were observed in the SCT-/- mice. More interestingly, SCT replacement in SCT-/- mice could prevent the development of heart and lung pathologies compared to the untreated group. Taken together, we comprehensively demonstrated the critical role of SCT in the cardiovascular and pulmonary systems and provide new insight into the potential role of SCT in the pathological development of cardiopulmonary and cardiovascular diseases.

Role of SCTR/AT1aR heteromer in mediating ANGII-induced aldosterone secretion.

The involvement of secretin (SCT) and its receptor (SCTR) in angiotensin II (ANGII)-mediated osmoregulation by forming SCTR/ angiotensin II type 1 receptor (AT1R) heteromer is well established. In this study, we demonstrated that SCTR/AT1R complex can mediate ANGII-induced aldosterone secretion/release through potentiating calcium mobilization. Through IHC and cAMP studies, we showed the presence of functional SCTR and AT1R in the primary zona glomerulosa (ZG) cells of C57BL/6N (C57), and functional AT1R and non-functional SCTR in SCTR knockout (SCTR-/-) mice. Calcium mobilization studies revealed the important role of SCTR on ANGII-mediated calcium mobilization in adrenal gland. The fluo4-AM loaded primary adrenal ZG cells from the C57 mice displayed a dose-dependent increase in intracellular calcium influx ([Ca2+]i) when exposed to ANGII but not from the SCTR-/- ZG cells. Synthetic SCTR transmembrane (TM) peptides STM-II/-IV were able to alter [Ca2+]i in C57 mice, but not the mice with mutated STM-II/-IV (STM-IIm/IVm) peptides. Through enzyme immunoassay (EIA), we measured the aldosterone release from primary ZG cells of both C57 and SCTR-/- mice by exposing them to ANGII (10nM). SCTR-/- ZG cells showed impaired ANGII-induced aldosterone secretion compared to the C57 mice. TM peptide, STM-II hindered the aldosterone secretion in ZG cells of C57 mice. These findings support the involvement of SCTR/AT1R heterodimer complex in aldosterone secretion/release through [Ca2+]i.