Summary: | Indiana University-Purdue University Indianapolis (IUPUI) === Increased electrical activity in peripheral sensory neurons contributes to pain. A unique type of sodium current, fast resurgent current, is proposed to increase nerve activity and has been associated with pain pathologies. While sodium channel isoform Nav1.6 has been identified as the main carrier of fast resurgent currents, our understanding of how resurgent currents are modulated in sensory neurons is fairly limited. Thus the goal of this dissertation was to identify resurgent current modulators. In particular, we focused on sodium channel beta subunits (Navβs) and fibroblast growth factor homologous factors (FHFs) in dorsal root ganglion (DRG) neurons. We hypothesized that Navβ4 and FHF2B act as positive regulators by mediating resurgent currents and modulating Nav1.6 inactivation, respectively. In contrast, we hypothesized FHF2A negatively regulates resurgent current by increasing the probability of channels in inactivated states. Thus, the aims of this dissertation were to 1) determine if Navβ4 regulates fast resurgent currents in DRG neurons, 2) examine the effects of Navβ4 knockdown on resurgent currents, firing frequency and pain associated behavior in an inflammatory pain model and 3) determine if FHF2A and FHF2B functionally regulate Nav1.6 currents, including resurgent currents in DRG neurons. To examine the aims, we used biochemical, electrophysiological and behavioral assays. Our results suggest that Navβ4 is a positive regulator of resurgent currents: in particular, the C-terminus likely mediates these currents. Localized knockdown of Navβ4 decreased inflammation-induced enhancement of resurgent currents and neuronal excitability, and prevented the development of persistent pain associated behavior in an inflammatory pain model. FHF2B increased resurgent currents and delayed inactivation. In contrast, FHF2A limited resurgent currents; an effect that is mainly contributed by FHF2A's N-terminus activity that increased accumulation of channels in inactivated states. Interestingly, in an inflammatory pain model FHF2B was upregulated and FHFA isoforms were downregulated. Together these results suggest that FHF2A/B modulation might contribute to enhanced resurgent currents and increased neuronal excitability observed in the inflammatory pain model. Overall, our work has identified three resurgent current modulators FHF2A, FHF2B and Navβ4. Manipulation of these proteins or their activity might result in novel strategies for the study and treatment of pain.
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