Abstract

The L-type calcium channel (LCC) plays a crucial role in the electrical remodeling of atrial fibrillation (AF). AF is associated with reduction of L-type calcium current density, due to a transcriptional downregulation of the pore forming alpha(1c)-subunit of LCC. However, it is unclear, whether this current reduction is related to a decrease in channel number or to alterations in channel function. Hence, we performed a single LCC analysis to assess channel gating and function in human AF. We used the cell-attached patch-clamp technique in isolated atrial human cardiomyocytes of 25 patients with sinus rhythm (SR) and 15 patients with chronic AF. Protein expression of the pore-forming alpha(1c)-subunit of LCC was reduced by 40% in AF. Single channel peak average current was 1.7-fold higher in AF than in SR, due to a 3.1-fold higher open probability of LCC. Since phosphatase 2A (PP2A) is known to preferentially reduce LCC open probability via channel dephosphorylation, we assessed whether PP2A expression or activity is reduced in AF. Okadaic acid, an inhibitor of phosphatases, increased channel open probability in SR, but not in AF. However, Western blot analysis of atrial homogenates of the same patient population revealed unchanged expression of PP2A. Human AF is characterized by increased single LCC activity, due to an increase of channel open probability. The blunted effect of PP2A on LCC as shown by single channel analysis may be related to a reduction of cytosolic PP2A activity or impaired local interaction between PP2A and LCC in AF.

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