Oxidative stress creates a unique, CaMKII-mediated substrate for atrial fibrillation in heart failure
Shin Yoo, Gary Aistrup, Yohannes Shiferaw, Jason Ng, Peter J. Mohler, Thomas J. Hund, Trent Waugh, Suzanne Browne, Georg Gussak, Mehul Gilani, Bradley P. Knight, Rod Passman, Jeffrey J. Goldberger, J. Andrew Wasserstrom, Rishi Arora
Shin Yoo, Gary Aistrup, Yohannes Shiferaw, Jason Ng, Peter J. Mohler, Thomas J. Hund, Trent Waugh, Suzanne Browne, Georg Gussak, Mehul Gilani, Bradley P. Knight, Rod Passman, Jeffrey J. Goldberger, J. Andrew Wasserstrom, Rishi Arora
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Research Article Cardiology

Oxidative stress creates a unique, CaMKII-mediated substrate for atrial fibrillation in heart failure

Abstract

The precise mechanisms by which oxidative stress (OS) causes atrial fibrillation (AF) are not known. Since AF frequently originates in the posterior left atrium (PLA), we hypothesized that OS, via calmodulin-dependent protein kinase II (CaMKII) signaling, creates a fertile substrate in the PLA for triggered activity and reentry. In a canine heart failure (HF) model, OS generation and oxidized-CaMKII–induced (Ox-CaMKII–induced) RyR2 and Nav1.5 signaling were increased preferentially in the PLA (compared with left atrial appendage). Triggered Ca2+ waves (TCWs) in HF PLA myocytes were particularly sensitive to acute ROS inhibition. Computational modeling confirmed a direct relationship between OS/CaMKII signaling and TCW generation. CaMKII phosphorylated Nav1.5 (CaMKII-p-Nav1.5 [S571]) was located preferentially at the intercalated disc (ID), being nearly absent at the lateral membrane. Furthermore, a decrease in ankyrin-G (AnkG) in HF led to patchy dropout of CaMKII-p-Nav1.5 at the ID, causing its distribution to become spatially heterogeneous; this corresponded to preferential slowing and inhomogeneity of conduction noted in the HF PLA. Computational modeling illustrated how conduction slowing (e.g., due to increase in CaMKII-p-Nav1.5) interacts with fibrosis to cause reentry in the PLA. We conclude that OS via CaMKII leads to substrate for triggered activity and reentry in HF PLA by mechanisms independent of but complementary to fibrosis.

Authors

Shin Yoo, Gary Aistrup, Yohannes Shiferaw, Jason Ng, Peter J. Mohler, Thomas J. Hund, Trent Waugh, Suzanne Browne, Georg Gussak, Mehul Gilani, Bradley P. Knight, Rod Passman, Jeffrey J. Goldberger, J. Andrew Wasserstrom, Rishi Arora

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Figure 3

Increased expression of CaMKII-p-RyR2 (S2814) in HF PLA and sensitivity of triggered Ca2+ waves in PLA myocytes to acute ROS inhibition.

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Increased expression of CaMKII-p-RyR2 (S2814) in HF PLA and sensitivity ...
(A) Representative immunoblot and densitometric measurements of CaMKII-p-RyR2 (S2814) (normalized to native RyR2) from control and HF in PLA (left) and LAA (right). (B) HF atrial myocytes showed higher incidence of triggered Ca2+ waves, compared with control. (C) Higher incidence of triggered Ca2+ waves in HF PLA myocytes, compared with HF LAA myocytes at 300 ms BCL. (D) Ca2+ imaging showed attenuation of incidence of triggered Ca2+ waves at 500 ms and 300 ms BCL in the presence of mito-TEMPO and apocynin in HF PLA myocytes, but not in HF LAA myocytes. Time bar: 1 second. The myocytes for these experiments were obtained from 4 HF dogs, and the number of myocytes for each experimental condition is given in each figure panel. Data are represented as mean ± SEM. *P < 0.05, ***P < 0.001. (A and B) Independent t test. (C) Paired t test. (D) Main effect of ANOVA (P = 0.017 at 300 ms, 0.053 at 500ms), post hoc t tests with each cycle with Bonferroni correction. HF, heart failure; PLA, posterior left atrium; LAA, left atrial appendage. See complete unedited blots in the supplemental material.