Computer modeling of whole-cell voltage-clamp analyses to delineate guidelines for good practice of manual and automated patch-clamp

Montnach, Jérôme; Lorenzini, Maxime; Lesage, Adrien; Simon, Isabelle; Nicolas, Sébastien; Moreau, Eléonore; Marionneau, Céline; Baró, Isabelle; Waard, Michel De; Loussouarn, Gildas

doi:10.1038/s41598-021-82077-8

Cited by 21 publications

(30 citation statements)

References 15 publications

(14 reference statements)

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“…While the effects of experimental artefacts in single-cell studies are well-established, consideration of them while building ion channel and action potential models has been limited (Whittaker et al, 2020). In silico studies investigating series resistance effects on voltage clamp recordings have been done in fast-activating currents, such as I Na and I to (Ebihara and Johnson, 1980; Montnach et al, 2021), but to our knowledge artefact equations have not been included in the calibration process for widely-used models of these currents — although the I Na model by Ebihara and Johnson was incorporated directly into the widely copied INa model by Luo and Rudy (1994). Recently, Lei et al (2020) demonstrated that coupling experimental artefact equations with an I Kr mechanistic model improved predictions.…”

Section: Discussionmentioning

confidence: 99%

Leak current, even with gigaohm seals, can cause misinterpretation of stem-cell derived cardiomyocyte action potential recordings

Clark

Clerx

Wei

et al. 2022

Preprint

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Human induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs) have become an essential tool to study arrhythmia mechanisms. Much of the foundational work on these cells, and the computational models built from the resultant data, has overlooked the contribution of seal-leak current on the immature and heterogeneous phenotype that has come to define these cells. Here, we usein silicoandin vitrostudies to demonstrate how seal-leak current depolarises action potentials (APs), substantially affecting their morphology, even with seal resistances (Rseal) above 1GΩ. We show that compensation of this leak current is difficult due to challenges with recording accurate measures of Rseal during an experiment. Using simulation, we show that Rsealmeasures: 1) change during an experiment, invalidating the use of pre-rupture values, and 2) are polluted by the presence of transmembrane currents at every voltage. Finally, we posit the background sodium current in baseline iPSC-CM models imitates the effects of seal-leak current and is increased to a level that masks the effects of seal-leak current on iPSC-CMs. Based on these findings, we make three recommendations to improve iPSC-CM AP data acquisition, interpretation, and model-building. Taking these recommendations into account will improve our understanding of iPSC-CM physiology and the descriptive ability of models built from such data.

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Section: Discussionmentioning

confidence: 99%

Leak current, even with gigaohm seals, can cause misinterpretation of stem-cell derived cardiomyocyte action potential recordings

Clark

Clerx

Wei

et al. 2022

Preprint

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“…This flexibility enables neural networks to approximate (almost) any function, making them a powerful universal approximator. However, experimental data are generally imperfect; there are experimental artefacts in the data, for example imperfect series resistance and membrane capacitance compensations, imperfect leak correction, etc., as discussed in Marty and Neher (1995), Sherman et al (1999), Raba et al (2013), Lei et al (2020a,b), and Montnach et al (2021). Unlike (smaller) biophysical models, with limited flexibility, neural networks might easily absorb such undesired, non-biophysical artefacts into the model, hence making non-physiologicallyrelevant predictions.…”

Section: Discussionmentioning

confidence: 99%

Neural Network Differential Equations For Ion Channel Modelling

Lei

Mirams

2021

Front. Physiol.

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Mathematical models of cardiac ion channels have been widely used to study and predict the behaviour of ion currents. Typically models are built using biophysically-based mechanistic principles such as Hodgkin-Huxley or Markov state transitions. These models provide an abstract description of the underlying conformational changes of the ion channels. However, due to the abstracted conformation states and assumptions for the rates of transition between them, there are differences between the models and reality—termed model discrepancy or misspecification. In this paper, we demonstrate the feasibility of using a mechanistically-inspired neural network differential equation model, a hybrid non-parametric model, to model ion channel kinetics. We apply it to the hERG potassium ion channel as an example, with the aim of providing an alternative modelling approach that could alleviate certain limitations of the traditional approach. We compare and discuss multiple ways of using a neural network to approximate extra hidden states or alternative transition rates. In particular we assess their ability to learn the missing dynamics, and ask whether we can use these models to handle model discrepancy. Finally, we discuss the practicality and limitations of using neural networks and their potential applications.

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“…To control this large variability, a moderate correlation was identified between activation V 1/2 and peak current amplitude in all conditions where peak amplitude ranged beyond 10 nA, such that larger amplitude currents tended to be associated with more hyperpolarized activation V 1/2 values. To ensure that the reported shifts were real and not an artifact of skewed amplitude distributions ( Montnach et al, 2021 ), scatter plots in which V 1/2 values were plotted as a function of their corresponding peak current amplitude were reported. The resulting scatter distribution was then fitted with a line of regression:

where V x is the predicted V 1/2 , m is the line slope, A is the maximum current amplitude, and b is the line y-intercept.…”

Section: Methodsmentioning

confidence: 99%

Spliced isoforms of the cardiac Nav1.5 channel modify channel activation by distinct structural mechanisms

Mancino

Glass

Yan

et al. 2022

Journal of General Physiology

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Alternative splicing is an important cellular mechanism that fine tunes the gating properties of both voltage- and ligand-gated ion-channels. The cardiac voltage-gated sodium channel, Nav1.5, is subject to alternative splicing of the DI S3–S4 linker, which generates two types of channels with different activation properties. Here, we show that the gating differences between the adult (mH1) and neonatal (Nav1.5e) isoforms of Nav1.5 are mediated by two amino acid residues: Thr/Ser at position 207 and Asp/Lys at position 211. Electrophysiological experiments, in conjunction with molecular dynamics simulations, revealed that each residue contributes equally to the overall gating shifts in activation, but that the underlying structural mechanisms are different. Asp/Lys at position 211 acts through electrostatic interactions, whereas Thr/Ser at position 207 is predicted to alter the hydrogen bond network at the top of the S3 helix. These distinct structural mechanisms work together to modify movement of the voltage-sensitive S4 helix to bring about channel activation. Interestingly, mutation of the homologous Asp and Thr residues of the skeletal muscle isoform, Nav1.4, to Lys and Ser, respectively, confers a similar gating shift in channel activation, suggesting that these residues may fulfill a conserved role across other Nav channel family members.

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Computer modeling of whole-cell voltage-clamp analyses to delineate guidelines for good practice of manual and automated patch-clamp

Cited by 21 publications

References 15 publications

Leak current, even with gigaohm seals, can cause misinterpretation of stem-cell derived cardiomyocyte action potential recordings

Leak current, even with gigaohm seals, can cause misinterpretation of stem-cell derived cardiomyocyte action potential recordings

Neural Network Differential Equations For Ion Channel Modelling

Spliced isoforms of the cardiac Nav1.5 channel modify channel activation by distinct structural mechanisms

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