Adrenomedullin-mediated depressor response with visceral afferent-specific membrane depolarization in isolated nodose ganglion neurons from adult female rat

Abstract

Adrenomedullin (ADM) is an endogenous and vasoactive neuropeptide that possesses potent central/peripheral regulations on blood pressure (BP) and sex-related vasodilation under physiological conditions. However, the role of ADM on baroreflex afferent function is largely unknown. Here, BP was monitored in adult female rats while ADM was microinjected into the nodose ganglion (NG); Fluorescent intensity against ADM was analyzed in the tissue level and membrane responses elicited by ADM were tested in identified NG neurons isolated from adult female rats with gap-free protocol under current-clamp mode with or without ADM antagonist. The results showed that BP was reduced by ADM (30–300 nM) concentration-dependently; myelinated (HCN1-positive) neurons showed significantly higher fluorescent intensity against ADM antibody vs. unmyelinated (HCN1-negative) neurons. Interestingly, patch-clamp data indicated that membrane potential was not changed in 50 % (6/12) of identified A-types, only 4/12 was hyperpolarized by 30 nM ADM, while 100 nM ADM induced brief hyperpolarization followed by depolarization in 2/12 of recordings; Robustly, ADM depolarized 100 % tested myelinated Ah-type neurons with dramatic and concentration-dependent repetitive discharges; While, a majority (8/9) of unmyelinated C-types were depolarized and few with repetitive dischargers. By application of ADM (22–52), the depolarization elicited by ADM 100 nM was partially or completely abolished in Ah-types or C-types, respectively. These datasets demonstrated for the first time that baroreflex afferents especially female-distributed subpopulation of Ah-types would be a key player in ADM-mediated depressor response unveiling the dominate role of peripheral ADM in neurocontrol of hypotension via baroreflex afferent function and gender-dependent vasodilation promoted by female sex steroid.