Ca2+ spark latency and control of intrinsic Ca2+ release dyssynchrony in rat cardiac ventricular muscle cells

Cherrie H.T. Kong; Mark B Cannell

doi:10.1016/j.yjmcc.2023.07.005

Ca2+ spark latency and control of intrinsic Ca2+ release dyssynchrony in rat cardiac ventricular muscle cells

Cherrie H.T. Kong^*, Mark B Cannell^*

^*Corresponding author for this work

School of Physiology, Pharmacology & Neuroscience

Research output: Contribution to journal › Article (Academic Journal) › peer-review

1 Citation (Scopus)

Abstract

Cardiac excitation-contraction coupling (ECC) depends on Ca2+ release from intracellular stores via ryanodine receptors (RyRs) triggered by L-type Ca2+ channels (LCCs). Uncertain numbers of RyRs and LCCs form ‘couplons’ whose activation produces Ca2+ sparks, which summate to form a cell-wide Ca2+ transient that switches on contraction. Voltage (Vm) changes during the action potential (AP) and stochasticity in channel gating should create variability in Ca2+ spark timing, but Ca2+ transient wavefronts have remarkable uniformity. To examine how this is achieved, we measured the Vm-dependence of evoked Ca2+ spark probability (Pspark) and latency over a wide voltage range in rat ventricular cells. With depolarising steps, Ca2+ spark latency showed a U-shaped Vm-dependence, while repolarising steps from 50 mV produced Ca2+ spark latencies that increased monotonically with Vm. A computer model based on reported channel gating and geometry reproduced our experimental data and revealed a likely RyR:LCC stoichiometry of ∼ 5:1 for the Ca2+ spark initiating complex (IC). Using the experimental AP waveform, the model revealed a high coupling fidelity (Pcpl ∼ 0.5) between each LCC opening and IC activation. The presence of ∼ 4 ICs per couplon reduced Ca2+ spark latency and increased Pspark to match experimental data. Variability in AP release timing is less than that seen with voltage steps because the AP overshoot and later repolarization decrease Pspark due to effects on LCC flux and LCC deactivation respectively. This work provides a framework for explaining the Vm- and time-dependence of Pspark, and indicates how ion channel dispersion in disease can contribute to dyssynchrony in Ca2+ release.

Original language	English
Pages (from-to)	44-53
Number of pages	10
Journal	Journal of Molecular and Cellular Cardiology
Volume	182
DOIs	https://doi.org/10.1016/j.yjmcc.2023.07.005
Publication status	Published - 14 Jul 2023

Bibliographical note

Funding Information:
We would like to thank Dr. M. Stern (NIA NIH, Baltimore) for critical reading of the manuscript and Drs. A.F. James and L. Pannell for supplying some of the cells used in this study (the latter supported by British Heart Foundation FS/CRTF/21/24122 ).

Funding Information:
The work was supported by the Auckland Medical Research Foundation ( 81,216 to C.H.T.K.), Health Research Council of New Zealand ( 08/049 to M.B.C.), British Heart Foundation ( PG/20/5/34801 to C.H.T.K. and M.B.C.; IG/13/3/30212 to M.B.C.), Medical Research Council ( MR/N002903/1 to M.B.C.), Royal Society (U.K.) Wolfson Merit Award (to M.B.C.) and facilities provided by the Advanced Computing Research Centre at the University of Bristol ( http://www.bristol.ac.uk/acrc/ ).

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© 2023

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@article{8394b4455e0a4a56a55028f731ea7b97,

title = "Ca2+ spark latency and control of intrinsic Ca2+ release dyssynchrony in rat cardiac ventricular muscle cells",

abstract = "Cardiac excitation-contraction coupling (ECC) depends on Ca2+ release from intracellular stores via ryanodine receptors (RyRs) triggered by L-type Ca2+ channels (LCCs). Uncertain numbers of RyRs and LCCs form {\textquoteleft}couplons{\textquoteright} whose activation produces Ca2+ sparks, which summate to form a cell-wide Ca2+ transient that switches on contraction. Voltage (Vm) changes during the action potential (AP) and stochasticity in channel gating should create variability in Ca2+ spark timing, but Ca2+ transient wavefronts have remarkable uniformity. To examine how this is achieved, we measured the Vm-dependence of evoked Ca2+ spark probability (Pspark) and latency over a wide voltage range in rat ventricular cells. With depolarising steps, Ca2+ spark latency showed a U-shaped Vm-dependence, while repolarising steps from 50 mV produced Ca2+ spark latencies that increased monotonically with Vm. A computer model based on reported channel gating and geometry reproduced our experimental data and revealed a likely RyR:LCC stoichiometry of ∼ 5:1 for the Ca2+ spark initiating complex (IC). Using the experimental AP waveform, the model revealed a high coupling fidelity (Pcpl ∼ 0.5) between each LCC opening and IC activation. The presence of ∼ 4 ICs per couplon reduced Ca2+ spark latency and increased Pspark to match experimental data. Variability in AP release timing is less than that seen with voltage steps because the AP overshoot and later repolarization decrease Pspark due to effects on LCC flux and LCC deactivation respectively. This work provides a framework for explaining the Vm- and time-dependence of Pspark, and indicates how ion channel dispersion in disease can contribute to dyssynchrony in Ca2+ release.",

author = "Kong, {Cherrie H.T.} and Cannell, {Mark B}",

note = "Funding Information: We would like to thank Dr. M. Stern (NIA NIH, Baltimore) for critical reading of the manuscript and Drs. A.F. James and L. Pannell for supplying some of the cells used in this study (the latter supported by British Heart Foundation FS/CRTF/21/24122 ). Funding Information: The work was supported by the Auckland Medical Research Foundation ( 81,216 to C.H.T.K.), Health Research Council of New Zealand ( 08/049 to M.B.C.), British Heart Foundation ( PG/20/5/34801 to C.H.T.K. and M.B.C.; IG/13/3/30212 to M.B.C.), Medical Research Council ( MR/N002903/1 to M.B.C.), Royal Society (U.K.) Wolfson Merit Award (to M.B.C.) and facilities provided by the Advanced Computing Research Centre at the University of Bristol ( http://www.bristol.ac.uk/acrc/ ). Publisher Copyright: {\textcopyright} 2023",

year = "2023",

month = jul,

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doi = "10.1016/j.yjmcc.2023.07.005",

language = "English",

volume = "182",

pages = "44--53",

journal = "Journal of Molecular and Cellular Cardiology",

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TY - JOUR

T1 - Ca2+ spark latency and control of intrinsic Ca2+ release dyssynchrony in rat cardiac ventricular muscle cells

AU - Kong, Cherrie H.T.

AU - Cannell, Mark B

N1 - Funding Information: We would like to thank Dr. M. Stern (NIA NIH, Baltimore) for critical reading of the manuscript and Drs. A.F. James and L. Pannell for supplying some of the cells used in this study (the latter supported by British Heart Foundation FS/CRTF/21/24122 ). Funding Information: The work was supported by the Auckland Medical Research Foundation ( 81,216 to C.H.T.K.), Health Research Council of New Zealand ( 08/049 to M.B.C.), British Heart Foundation ( PG/20/5/34801 to C.H.T.K. and M.B.C.; IG/13/3/30212 to M.B.C.), Medical Research Council ( MR/N002903/1 to M.B.C.), Royal Society (U.K.) Wolfson Merit Award (to M.B.C.) and facilities provided by the Advanced Computing Research Centre at the University of Bristol ( http://www.bristol.ac.uk/acrc/ ). Publisher Copyright: © 2023

PY - 2023/7/14

Y1 - 2023/7/14

N2 - Cardiac excitation-contraction coupling (ECC) depends on Ca2+ release from intracellular stores via ryanodine receptors (RyRs) triggered by L-type Ca2+ channels (LCCs). Uncertain numbers of RyRs and LCCs form ‘couplons’ whose activation produces Ca2+ sparks, which summate to form a cell-wide Ca2+ transient that switches on contraction. Voltage (Vm) changes during the action potential (AP) and stochasticity in channel gating should create variability in Ca2+ spark timing, but Ca2+ transient wavefronts have remarkable uniformity. To examine how this is achieved, we measured the Vm-dependence of evoked Ca2+ spark probability (Pspark) and latency over a wide voltage range in rat ventricular cells. With depolarising steps, Ca2+ spark latency showed a U-shaped Vm-dependence, while repolarising steps from 50 mV produced Ca2+ spark latencies that increased monotonically with Vm. A computer model based on reported channel gating and geometry reproduced our experimental data and revealed a likely RyR:LCC stoichiometry of ∼ 5:1 for the Ca2+ spark initiating complex (IC). Using the experimental AP waveform, the model revealed a high coupling fidelity (Pcpl ∼ 0.5) between each LCC opening and IC activation. The presence of ∼ 4 ICs per couplon reduced Ca2+ spark latency and increased Pspark to match experimental data. Variability in AP release timing is less than that seen with voltage steps because the AP overshoot and later repolarization decrease Pspark due to effects on LCC flux and LCC deactivation respectively. This work provides a framework for explaining the Vm- and time-dependence of Pspark, and indicates how ion channel dispersion in disease can contribute to dyssynchrony in Ca2+ release.

AB - Cardiac excitation-contraction coupling (ECC) depends on Ca2+ release from intracellular stores via ryanodine receptors (RyRs) triggered by L-type Ca2+ channels (LCCs). Uncertain numbers of RyRs and LCCs form ‘couplons’ whose activation produces Ca2+ sparks, which summate to form a cell-wide Ca2+ transient that switches on contraction. Voltage (Vm) changes during the action potential (AP) and stochasticity in channel gating should create variability in Ca2+ spark timing, but Ca2+ transient wavefronts have remarkable uniformity. To examine how this is achieved, we measured the Vm-dependence of evoked Ca2+ spark probability (Pspark) and latency over a wide voltage range in rat ventricular cells. With depolarising steps, Ca2+ spark latency showed a U-shaped Vm-dependence, while repolarising steps from 50 mV produced Ca2+ spark latencies that increased monotonically with Vm. A computer model based on reported channel gating and geometry reproduced our experimental data and revealed a likely RyR:LCC stoichiometry of ∼ 5:1 for the Ca2+ spark initiating complex (IC). Using the experimental AP waveform, the model revealed a high coupling fidelity (Pcpl ∼ 0.5) between each LCC opening and IC activation. The presence of ∼ 4 ICs per couplon reduced Ca2+ spark latency and increased Pspark to match experimental data. Variability in AP release timing is less than that seen with voltage steps because the AP overshoot and later repolarization decrease Pspark due to effects on LCC flux and LCC deactivation respectively. This work provides a framework for explaining the Vm- and time-dependence of Pspark, and indicates how ion channel dispersion in disease can contribute to dyssynchrony in Ca2+ release.

U2 - 10.1016/j.yjmcc.2023.07.005

DO - 10.1016/j.yjmcc.2023.07.005

M3 - Article (Academic Journal)

C2 - 37433391

SN - 0022-2828

VL - 182

SP - 44

EP - 53

JO - Journal of Molecular and Cellular Cardiology

JF - Journal of Molecular and Cellular Cardiology

ER -

Ca2+ spark latency and control of intrinsic Ca2+ release dyssynchrony in rat cardiac ventricular muscle cells

Abstract

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