Parvalbumin expression does not account for discrete electrophysiological profiles of glutamatergic ventral pallidal subpopulations

Abstract

The ventral pallidum (VP) has emerged as a critical node in the mesolimbic reward system. Modulating the VP can impact the subjective valuation of rewards, reward motivation, and reward seeking under conflict, making it an attractive target for clinical neuromodulation therapies that manage substance use disorders. To understand how to rationally modulate the VP, we need a better understanding of the electrophysiological properties of VP neurons and the molecular and biophysical determinants of these properties. Here, we used patch-clamp electrophysiology to characterize the intrinsic properties of glutamatergic VP (VP_Glu) neurons and observed two distinct electrophysiological profiles: VP_Glu neurons that undergo depolarization block in response to progressively increasing current injection amplitudes and those that were resistant to depolarization block. To explore the mechanisms that could contribute to these distinct profiles, we used targeted ribosome affinity purification to identify ion channel subunits and regulatory proteins by isolating actively transcribed mRNA selectively from VP_Glu neurons. We then used this transcriptomic information to implement a Markov Chain Monte Carlo method to parameterize a large population of biophysically distinct multicompartment models of VP_Glu neurons conforming to either subpopulation. Based on prior literature suggesting parvalbumin (PV) is expressed in a subset of VP_Glu neurons, and that PV expression governs the firing properties of those neurons, we tested the hypothesis that PV expression accounted for differences in subgroups, by increasing the maximal firing frequency and conferring resistance to depolarization block. In contrast, our model determined that PV expression at physiological levels had no effect on maximum firing rate. However, supraphysiological expression levels of PV appeared to induce a depolarization block in previously depolarization block-resistant neuron models, suggesting that other intracellular calcium-binding proteins could play a role in determining the firing phenotype of VP_Glu neurons. We corroborated this result with single-cell patch-clamp RT-PCR, which confirmed that PV expression did not distinguish the two electrophysiologically distinct subpopulations. Together, these findings establish that VP_Glu neurons are composed of biophysically distinct subpopulations that have not been appreciated in prior studies interrogating the function of this population. With the advent of novel tools for cell-type specific pharmacology and targeted neurostimulation, this understanding will be critical for developing strategies to rationally modulate VP_Glu cells to treat disorders characterized by maladaptive reward seeking.