Spontaneous Ca<sup>2+</sup> sparks and Ca<sup>2+</sup> homeostasis in a minimal model of permeabilized ventricular myocytes

Hartman, Jana M.; Sobie, Eric A.; Smith, Gregory D.

doi:10.1152/ajpheart.00293.2010

Cited by 15 publications

(9 citation statements)

References 52 publications

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“…Williams et al demonstrated that a population of subspace domains can be represented by a probability density approach and can be utilized to simulate global calcium dynamics [45]. Hartman et al utilized a model of a small number of coupled calcium activated channels to predict the global calcium release dynamics in response to pharmacological modification of single channel kinetics [46]. However, this study is the first to compare a model of calcium channel regulation accounting for the finite subspace volume (and using a discrete representation of the number of subspace calcium ions) with the corresponding ODE formulation that assumes a large system size (and uses a continuous representation of calcium concentration).…”

Section: Discussionmentioning

confidence: 99%

Discrete-State Stochastic Models of Calcium-Regulated Calcium Influx and Subspace Dynamics Are Not Well-Approximated by ODEs That Neglect Concentration Fluctuations

Weinberg

Smith

2012

Computational and Mathematical Methods in Medicine

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Cardiac myocyte calcium signaling is often modeled using deterministic ordinary differential equations (ODEs) and mass-action kinetics. However, spatially restricted “domains” associated with calcium influx are small enough (e.g., 10−17 liters) that local signaling may involve 1–100 calcium ions. Is it appropriate to model the dynamics of subspace calcium using deterministic ODEs or, alternatively, do we require stochastic descriptions that account for the fundamentally discrete nature of these local calcium signals? To address this question, we constructed a minimal Markov model of a calcium-regulated calcium channel and associated subspace. We compared the expected value of fluctuating subspace calcium concentration (a result that accounts for the small subspace volume) with the corresponding deterministic model (an approximation that assumes large system size). When subspace calcium did not regulate calcium influx, the deterministic and stochastic descriptions agreed. However, when calcium binding altered channel activity in the model, the continuous deterministic description often deviated significantly from the discrete stochastic model, unless the subspace volume is unrealistically large and/or the kinetics of the calcium binding are sufficiently fast. This principle was also demonstrated using a physiologically realistic model of calmodulin regulation of L-type calcium channels introduced by Yue and coworkers.

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Section: Discussionmentioning

confidence: 99%

Discrete-State Stochastic Models of Calcium-Regulated Calcium Influx and Subspace Dynamics Are Not Well-Approximated by ODEs That Neglect Concentration Fluctuations

Weinberg

Smith

2012

Computational and Mathematical Methods in Medicine

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“…S3 qualified as Ca sparks). As the detection threshold increases, nonspark leak is increased (25). If we reduce our detection threshold to D[Ca] I ¼ 0.05 mM, more Ca sparks are seen ( Fig.…”

Section: Methodsmentioning

confidence: 95%

How Does Stochastic Ryanodine Receptor-Mediated Ca Leak Fail to Initiate a Ca Spark?

Sato

Bers

2011

Biophysical Journal

111

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Spontaneous calcium (Ca) sparks are initiated by single ryanodine receptor (RyR) opening. Once one RyR channel opens, it elevates local [Ca] in the cleft space ([Ca](Cleft)), which opens other RyR channels in the same Ca release unit (CaRU) via Ca-induced Ca-release. Experiments by Zima et al. (J. Physiol. 588:4743-4757, 2010) demonstrate that spontaneous Ca sparks occur only when intrasarcoplasmic-reticulum (SR) [Ca] ([Ca](SR)) is above a threshold level, but that RyR-mediated SR Ca leak exists without Ca sparks well below this threshold [Ca](SR). We examine here how single RyR opening at lower [Ca](SR) can fail to recruit Ca sparks at a CaRU, while still contributing to SR Ca leak. We assess this using a physiologically detailed mathematical model of junctional SR Ca release in which RyR gating is regulated by [Ca](SR) and [Ca](Cleft). We find that several factors contribute to the failure of Ca sparks as [Ca](SR) declines: 1), lower [Ca](SR) reduces driving force and thus limits local [Ca](Cleft) achieved and the rate of rise during RyR opening; 2), low [Ca](SR) limits RyR open time (τ(O)), which further reduces local [Ca](Cleft) attained; 3), low τ(O) and fast [Ca](Cleft) dissipation after RyR closure shorten the opportunity for neighboring RyR activation; 4), at low [Ca](SR), the RyR exhibits reduced [Ca](Cleft) sensitivity. We conclude that all of these factors conspire to reduce the probability of Ca sparks as [Ca](SR) declines, despite continued RyR-mediated Ca leak. In addition, these same factors explain the much lower efficacy of L-type Ca channel opening to trigger local SR Ca release at low [Ca](SR) during excitation-contraction coupling. Conversely, all of these factors are fundamentally important for increasing the propensity for pro-arrhythmic Ca sparks and waves in cardiac myocytes at high [Ca](SR).

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“…The first study to simulate both stochastic spark triggering and cellular action potentials (APs) was published by Greenstein and Winslow in 2002 [62]. Several studies published more recently have used either elegant algorithms [63-68], or improvements in computational power [69-74], to develop new models. The biological questions that can be asked with these models, however, are somewhat different from those that can be addressed with the lumped models.…”

Section: A Review Of Recent and Historically-important Studiesmentioning

confidence: 99%

“…In these newer models, however, SR Ca 2+ leak via stochastic gating of RyRs is simulated explicitly. Several studies published in the past few years have computed leak in a resting myocyte as a function of SR [Ca 2+ ] and have used the simulations to quantify the relative importance of visible leak in the form of Ca 2+ sparks, versus “invisible” leak that would be difficult to detect with standard recording techniques [68, 70, 73, 74]. Sensitivity analyses with these newer models can therefore consider additional model outputs, such as the resting spark rate or the number of Ca 2+ sparks triggered by specific voltage-clamp depolarizations.…”

Section: A Review Of Recent and Historically-important Studiesmentioning

confidence: 99%

Decoding myocardial Ca2+ signals across multiple spatial scales: A role for sensitivity analysis

Lee

Liu

Sobie

2013

Journal of Molecular and Cellular Cardiology

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Numerous studies have employed mathematical modeling to quantitatively understand release of Ca2+ from the sarcoplasmic reticulum (SR) in heart. Models have been used to investigate physiologically important phenomena such as triggering of SR Ca2+ release by Ca2+ entry across the cell membrane and spontaneous leak of Ca2+ from the SR in quiescent heart cells. In this review we summarize studies that have modeled myocardial Ca2+ at different spatial scales: the sub-cellular level, the cellular level, and the multicellular level. We discuss each category of models from the standpoint of parameter sensitivity analysis, a common simulation procedure that can generate quantitative, comprehensive predictions about how changes in conditions influence model output. We propose that this is a useful perspective for conceptualizing models, in part because a sensitivity analysis requires the investigator to define the relevant parameters and model outputs. This procedure therefore helps to illustrate the capabilities and limitations of each model. We further suggest that in future studies, sensitivity analyses will aid in simplifying complex models and in suggesting experiments to differentiate between competing models built with different assumptions. We conclude with a discussion of unresolved questions that are likely to be addressed over the next several years.

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Spontaneous Ca²⁺ sparks and Ca²⁺ homeostasis in a minimal model of permeabilized ventricular myocytes

Cited by 15 publications

References 52 publications

Discrete-State Stochastic Models of Calcium-Regulated Calcium Influx and Subspace Dynamics Are Not Well-Approximated by ODEs That Neglect Concentration Fluctuations

Discrete-State Stochastic Models of Calcium-Regulated Calcium Influx and Subspace Dynamics Are Not Well-Approximated by ODEs That Neglect Concentration Fluctuations

How Does Stochastic Ryanodine Receptor-Mediated Ca Leak Fail to Initiate a Ca Spark?

Decoding myocardial Ca2+ signals across multiple spatial scales: A role for sensitivity analysis

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Spontaneous Ca2+ sparks and Ca2+ homeostasis in a minimal model of permeabilized ventricular myocytes

Cited by 15 publications

References 52 publications

Discrete-State Stochastic Models of Calcium-Regulated Calcium Influx and Subspace Dynamics Are Not Well-Approximated by ODEs That Neglect Concentration Fluctuations

Discrete-State Stochastic Models of Calcium-Regulated Calcium Influx and Subspace Dynamics Are Not Well-Approximated by ODEs That Neglect Concentration Fluctuations

How Does Stochastic Ryanodine Receptor-Mediated Ca Leak Fail to Initiate a Ca Spark?

Decoding myocardial Ca2+ signals across multiple spatial scales: A role for sensitivity analysis

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Spontaneous Ca²⁺ sparks and Ca²⁺ homeostasis in a minimal model of permeabilized ventricular myocytes