Machine Learning Methods for the Analysis of the Patch-Clamp Signals

Overview

Journal Methods Mol Biol

Specialty Molecular Biology

Date 2024 Jun 10

PMID 38856906

Authors

Monika Richter-Laskowska

Agata Wawrzkiewicz-Jalowiecka

Aleksander Bies

Paulina Trybek

Affiliations

Soon will be listed here.

Abstract

Patch-clamp technique provides a unique possibility to record the ion channels' activity. This method enables tracking the changes in their functional states at controlled conditions on a real-time scale. Kinetic parameters evaluated for the patch-clamp signals form the fundamentals of electrophysiological characteristics of the channel functioning. Nevertheless, the noisy series of ionic currents flowing through the channel protein(s) seem to be bountiful of information, and the standard data processing techniques likely unravel only its part. Rapid development of artificial intelligence (AI) techniques, especially machine learning (ML), gives new prospects for whole channelology. Here we consider the question of the AI applications in the patch-clamp signal analysis. It turns out that the AI methods may not only enable for automatizing of signal analysis, but also they can be used in finding inherent patterns of channel gating and allow the researchers to uncover the details of gating machinery, which had been never considered before. In this work, we outline the currently known AI methods that turned out to be utilizable and useful in the analysis of patch-clamp signals. This chapter can be considered an introductory guide to the application of AI methods in the analysis of the time series of channel currents (together with its advantages, disadvantages, and limitations), but we also propose new possible directions in this field.

References

Hille B . Ionic channels in excitable membranes. Current problems and biophysical approaches. Biophys J. 1978; 22(2):283-94. PMC: 1473440. DOI: 10.1016/S0006-3495(78)85489-7. View

Santos R, Ursu O, Gaulton A, Bento A, Donadi R, Bologa C . A comprehensive map of molecular drug targets. Nat Rev Drug Discov. 2016; 16(1):19-34. PMC: 6314433. DOI: 10.1038/nrd.2016.230. View

Hutchings C, Colussi P, Clark T . Ion channels as therapeutic antibody targets. MAbs. 2018; 11(2):265-296. PMC: 6380435. DOI: 10.1080/19420862.2018.1548232. View

Zhang Y, Wang K, Yu Z . Drug Development in Channelopathies: Allosteric Modulation of Ligand-Gated and Voltage-Gated Ion Channels. J Med Chem. 2020; 63(24):15258-15278. DOI: 10.1021/acs.jmedchem.0c01304. View

Qin F, Auerbach A, Sachs F . Estimating single-channel kinetic parameters from idealized patch-clamp data containing missed events. Biophys J. 1996; 70(1):264-80. PMC: 1224925. DOI: 10.1016/S0006-3495(96)79568-1. View

Sivilotti L, Colquhoun D . In praise of single channel kinetics. J Gen Physiol. 2016; 148(2):79-88. PMC: 4969800. DOI: 10.1085/jgp.201611649. View

Menke J, Maskri S, Koch O . Computational Ion Channel Research: from the Application of Artificial Intelligence to Molecular Dynamics Simulations. Cell Physiol Biochem. 2021; 55(S3):14-45. DOI: 10.33594/000000336. View

Zhu Z, Deng Z, Wang Q, Wang Y, Zhang D, Xu R . Simulation and Machine Learning Methods for Ion-Channel Structure Determination, Mechanistic Studies and Drug Design. Front Pharmacol. 2022; 13:939555. PMC: 9275593. DOI: 10.3389/fphar.2022.939555. View

Han K, Wang M, Zhang L, Wang Y, Guo M, Zhao M . Predicting Ion Channels Genes and Their Types With Machine Learning Techniques. Front Genet. 2019; 10:399. PMC: 6510169. DOI: 10.3389/fgene.2019.00399. View

10.

Ashrafuzzaman M . Artificial Intelligence, Machine Learning and Deep Learning in Ion Channel Bioinformatics. Membranes (Basel). 2021; 11(9). PMC: 8467682. DOI: 10.3390/membranes11090672. View

11.

Singh A, Tiwari A . Machine learning-based approach for prediction of ion channels and their subclasses. J Cell Biochem. 2022; 124(1):72-88. DOI: 10.1002/jcb.30343. View

13.

Richter-Laskowska M, Trybek P, Bednarczyk P, Wawrzkiewicz-Jalowiecka A . To what extent naringenin binding and membrane depolarization shape mitoBK channel gating-A machine learning approach. PLoS Comput Biol. 2022; 18(7):e1010315. PMC: 9342765. DOI: 10.1371/journal.pcbi.1010315. View

14.

Kicinska A, Augustynek B, Kulawiak B, Jarmuszkiewicz W, Szewczyk A, Bednarczyk P . A large-conductance calcium-regulated K+ channel in human dermal fibroblast mitochondria. Biochem J. 2016; 473(23):4457-4471. DOI: 10.1042/BCJ20160732. View

15.

Richter-Laskowska M, Trybek P, Bednarczyk P, Wawrzkiewicz-Jalowiecka A . Application of Machine-Learning Methods to Recognize mitoBK Channels from Different Cell Types Based on the Experimental Patch-Clamp Results. Int J Mol Sci. 2021; 22(2). PMC: 7831025. DOI: 10.3390/ijms22020840. View

16.

Zorko A, Fruhwirth M, Goswami N, Moser M, Levnajic Z . Heart Rhythm Analyzed via Shapelets Distinguishes Sleep From Awake. Front Physiol. 2020; 10:1554. PMC: 6978775. DOI: 10.3389/fphys.2019.01554. View

17.

Celik N, OBrien F, Brennan S, Rainbow R, Dart C, Zheng Y . Deep-Channel uses deep neural networks to detect single-molecule events from patch-clamp data. Commun Biol. 2020; 3(1):3. PMC: 6946689. DOI: 10.1038/s42003-019-0729-3. View

18.

Gnanasambandam R, Nielsen M, Nicolai C, Sachs F, Hofgaard J, Dreyer J . Unsupervised Idealization of Ion Channel Recordings by Minimum Description Length: Application to Human PIEZO1-Channels. Front Neuroinform. 2017; 11:31. PMC: 5406404. DOI: 10.3389/fninf.2017.00031. View