∼18-26 ms), closely matching that of native I SA and significantly faster than the recovery of Kv4.2 + KChIP3 or Kv4.2 + DPP10 channels. For comparison, identical triple coexpression experiments were performed using DPP6 variants. While most results are similar, the Kv4.2 + KChIP3 + DPP6 channels exhibit inactivation that slows with increasing membrane potential, resulting in inactivation slower than that of Kv4.2 + KChIP3 + DPP10 channels at positive voltages. In conclusion, the native neuronal subthreshold A-type channel is probably a macromolecular complex formed from Kv4 and a combination of both KChIP and DPL proteins, with the precise composition of channel α and auxiliary subunits underlying tissue and regional variability in I SA properties.
We have examined the molecular mechanism of rapid inactivation gating in a mouse Shal K+ channel (mKv4.1). The results showed that inactivation of these channels follows a complex time course that is well approximated by the sum of three exponential terms. Truncation of an amphipathic region at the N-terminus (residues 2-71) abolished the rapid phase of inactivation (r = 16 ms) and altered voltage-dependent gating. Surprisingly, these effects could be mimicked by deletions affecting the hydrophilic C-terminus. The sum of two exponential terms was sufficient to describe the inactivation of deletion mutants. In fact, the time constants corresponded closely to those of the intermediate and slow phases of inactivation observed with wild-type channels. Further analysis revealed that several basic amino acids at the N-terminus do not influence inactivation, but a positively charged domain at the C-terminus (amino acids 420-550) is necessary to support rapid inactivation. Thus, the amphipathic N-terminus and the hydrophilic C-terminus of mKv4.1 are essential determinants of inactivation gating and may interact with each other to maintain the N-terminal inactivation gate near the inner mouth of the channel. Furthermore, this inactivation gate may not behave like a simple open-channel blocker because channel blockade by internal tetraethylammonium was not associated with slower current decay and an elevated external K+ concentration retarded recovery from inactivation.
The dipeptidyl aminopeptidase-like protein DPPX (DPP6) associates with Kv4 potassium channels, increasing surface trafficking and reconstituting native neuronal ISA-like properties. Dipeptidyl peptidase 10 (DPP10) shares with DPP6 a high amino acid identity, lack of enzymatic activity, and expression predominantly in the brain. We used a two-electrode voltage-clamp and oocyte expression system to determine if DPP10 also interacts with Kv4 channels and modulates their expression and function. Kv4.2 coimmunoprecipitated with HA/DPP10 from extracts of oocytes heterologously expressing both proteins. Coexpression with DPP10 and HA/DPP10 enhanced Kv4.2 current by approximately fivefold without increasing protein level. DPP10 also remodeled Kv4.2 kinetic and steady-state properties by accelerating time courses of inactivation and recovery (taurec: WT = 200 ms, +DPP10 = 78 ms). Furthermore, DPP10 introduced hyperpolarizing shifts in the conductance-voltage relationship (approximately 19 mV) as well as steady-state inactivation (approximately 7 mV). The effects of DPP10 on Kv4.1 were similar to Kv4.2; however, distinct biophysical differences were observed. Additional experiments suggested that the cytoplasmic N-terminal domain of DPP10 determines the acceleration of inactivation. In summary, DPP10 is a potent modulator of Kv4 expression and biophysical properties and may be a critical component of somatodendritic ISA channels in the brain.
Auxiliary subunits are non-conducting, modulatory components of the multi-protein ion channel complexes that underlie normal neuronal signaling. They interact with the pore-forming α-subunits to modulate surface distribution, ion conductance, and channel gating properties. For the somatodendritic subthreshold A-type potassium (ISA) channel based on Kv4 α-subunits, two types of auxiliary subunits have been extensively studied: Kv channel-interacting proteins (KChIPs) and dipeptidyl peptidase-like proteins (DPLPs). KChIPs are cytoplasmic calcium-binding proteins that interact with intracellular portions of the Kv4 subunits, whereas DPLPs are type II transmembrane proteins that associate with the Kv4 channel core. Both KChIPs and DPLPs genes contain multiple start sites that are used by various neuronal populations to drive the differential expression of functionally distinct N-terminal variants. In turn, these N-terminal variants generate tremendous functional diversity across the nervous system. Here, we focus our review on (1) the molecular mechanism underlying the unique properties of different N-terminal variants, (2) the shaping of native ISA properties by the concerted actions of KChIPs and DPLP variants, and (3) the surprising ways that KChIPs and DPLPs coordinate the activity of multiple channels to fine-tune neuronal excitability. Unlocking the unique contributions of different auxiliary subunit N-terminal variants may provide an important opportunity to develop novel targeted therapeutics to treat numerous neurological disorders.
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