Abstract
Cx43 hemichannels (HCs) are electrically and chemically gated transmembrane pores with low open probability and multiple conductance states, which makes kinetic studies of channel gating in large datasets challenging. Here, we developed open access software, named HemiGUI, to analyze HC gating transitions and investigated voltage-induced HC opening based on up to ≈4000 events recorded in HeLa-Cx43-overexpressing cells. We performed a detailed characterization of Cx43 HC gating profiles and specifically focused on the role of the C-terminal tail (CT) domain by recording the impact of adding an EGFP tag to the Cx43 CT end (Cx43-EGFP) or by supplying the Cx43 HC-inhibiting peptide Gap19 that interferes with CT interaction with the cytoplasmic loop (CL). We found that Gap19 not only decreased HC opening activity to the open state (≈217 pS) but also increased the propensity of subconductance (≈80 pS) transitions that additionally became slower as compared to the control. The work demonstrates that large sample transition analysis allows detailed investigations on Cx43 HC gating and shows that Gap19 acts as a HC gating modifier by interacting with the CT that forms a crucial gating element.
Highlights
Communication between adjacent cells is in large part coordinated by gap junctions (GJs) [1]
On the basis of this analysis, applied to a large dataset of whole-cell current recordings in HeLa cells overexpressing Cx43, we found that Gap19 inhibition of Cx43 HCs involves a 3.6-fold decrease in main state opening but was accompanied by a 2.5-fold increase of transitions to the subconductance state that displayed significantly slowed kinetics
This is followed by total variation denoising and extraction of exact event time positions, amplitudes, and transition kinetics
Summary
Communication between adjacent cells is in large part coordinated by gap junctions (GJs) [1]. Biophysical studies further suggest that voltage-dependent Cx43 HC gating involves three distinct states: closed, fully open, and a subconductance state [5,10], with a slow gate (> 5 ms transition time) being involved in transitions between closed and fully open states, and a fast gate (< 1 ms transition time) mediating transitions to the subconductance state These slow and fast gating events resemble those found in junctional voltage gating of GJs [11]. On the basis of this analysis, applied to a large dataset of whole-cell current recordings in HeLa cells overexpressing Cx43, we found that Gap inhibition of Cx43 HCs involves a 3.6-fold decrease in main state opening but was accompanied by a 2.5-fold increase of transitions to the subconductance state that displayed significantly slowed kinetics. The data support the notion that preventing CT–CL interaction with Gap hinders the movement of all six HC subunits to the fully open conformation
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