CONICET | Buscador de Institutos y Recursos Humanos

The mechanisms by which ghrelin controls electrical activity in the hypothalamus are not fully understood. One unexplored target of ghrelin is CaV3, responsible for transient calcium currents (T-currents) that control neuronal firing. We investigated the effect of ghrelin on CaV3 subtypes and how this modulation impacts on neuronal activity. We performed whole-cell patch-clamp recordings in primary mouse hypothalamic cultures to explore the effect of ghrelin on T-currents. We also recorded calcium currents from transiently-transfected tsA201 cells to study the sensitivity of each CaV3 subtype to GHSR (growth hormone secretagogue receptor) activation. Finally, we ran a computational model combining the well-known reduction of potassium current by ghrelin with the CaV3 biophysical parameter modifications induced by ghrelin to predict the impact on neuronal electrical behavior. We found that ghrelin inhibits native T-currents in hypothalamic neurons. We determined that CaV3.3 is the only CaV3 subtype sensitive to ghrelin. The modulation of CaV3.3 by ghrelin comprises a reduction in maximum conductance, a shift to hyperpolarized voltages of the current-voltage (I-V) and steady-state inactivation curves, and an acceleration of activation and inactivation kinetics. Our model-based prediction indicates that the inhibition of CaV3.3 would attenuate the stimulation of firing originating from the inhibition of potassium currents by ghrelin. In summary, we discovered a new target of ghrelin in neurons: the CaV3.3. This mechanism would imply a negative feed-forward regulation of the neuronal activation exerted by ghrelin. Our work expands the knowledge of the wide range of actions of GHSR, a receptor potentially targeted by therapeutics for several diseases.