Signaling of Phoenixin via GPR173 and the Paradox of Increased Vasopressin Secretion in Preeclampsia

Abstract

Preterm birth affects over 15 million pregnancies annually worldwide, and is associated with severe health risks for both mother and child. The leading cause of clinically indicated, non-spontaneous preterm delivery is preeclampsia, which can lead to maternal and fetal morbidity and mortality if not appropriately and promptly managed. At this time, the only “cure” for preeclampsia is delivery of the fetus and associated products of conception, which presents the clinical challenge of weighing the risks versus benefits of delivery if the pregnancy is preterm. The etiology of preeclampsia is multifactorial and incompletely understood. However, several carefully conducted studies have implicated the paradoxical secretion of the posterior pituitary hormone, arginine vasopressin (AVP) as a potential causative factor. Women with preeclampsia exhibit elevated plasma levels of AVP even in the face of the ongoing hypertension and hyponatremia, and infusion of AVP into pregnant rodents recapitulated multiple features of preeclampsia. The reason for the inappropriately elevated AVP in preeclampsia is unknown. Using a bioinformatic algorithm, our group identified a novel peptide that is conserved across multiple species, and named it phoenixin (PNX) (PMID 22963497). Our published data demonstrate a reproductive role of the peptide, and indicate that hypothalamic and pituitary PNX expression is modulated by sex hormones (PMID 27440717). Likewise, we recently have demonstrated that cerebroventrcular administration of PNX elevated plasma AVP levels in rats (PMID 29364701). Using the RNAscope approach we have now demonstrated that the receptor for PNX, identified by our group as GPR173 (PMID 27440717), is expressed by AVP neurons. Importantly expression of GPR173 increased across pregnancy in the rat hypothalamus coincident with increased AVP production and release (PMID 27330717). These data strongly suggest that PNX, acting through GPR173, could act as a molecular link between sex hormones and AVP secretion. In addition, we now demonstrate that central injection of PNX increases blood pressure, likely through PNX-induced elevation in AVP secretion. We hypothesize that the paradox of increased AVP secretion in the hyponatremic and hypervolemic state of preeclampsia is due to exaggerated PNX signaling in hypothalamus via GPR173 on AVP neurons and possibly on GPR173 expressing neurons in autonomic centers in hindbrain.