Elucidation of molecular kinetic schemes from macroscopic traces using system identification.

Overall cellular responses to biologically-relevant stimuli are mediated by networks of simpler lower-level processes. Although information about some of these processes can now be obtained by visualizing and recording events at the molecular level, this is still possible only in especially favorabl...

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Main Authors: Miguel Fribourg, Diomedes E Logothetis, Javier González-Maeso, Stuart C Sealfon, Belén Galocha-Iragüen, Fernando Las-Heras Andrés, Vladimir Brezina
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2017-02-01
Series:PLoS Computational Biology
Online Access:https://doi.org/10.1371/journal.pcbi.1005376
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spelling doaj-0dbc498a0781429285cc7ee510a2e7052021-04-21T15:02:46ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582017-02-01132e100537610.1371/journal.pcbi.1005376Elucidation of molecular kinetic schemes from macroscopic traces using system identification.Miguel FribourgDiomedes E LogothetisJavier González-MaesoStuart C SealfonBelén Galocha-IragüenFernando Las-Heras AndrésVladimir BrezinaOverall cellular responses to biologically-relevant stimuli are mediated by networks of simpler lower-level processes. Although information about some of these processes can now be obtained by visualizing and recording events at the molecular level, this is still possible only in especially favorable cases. Therefore the development of methods to extract the dynamics and relationships between the different lower-level (microscopic) processes from the overall (macroscopic) response remains a crucial challenge in the understanding of many aspects of physiology. Here we have devised a hybrid computational-analytical method to accomplish this task, the SYStems-based MOLecular kinetic scheme Extractor (SYSMOLE). SYSMOLE utilizes system-identification input-output analysis to obtain a transfer function between the stimulus and the overall cellular response in the Laplace-transformed domain. It then derives a Markov-chain state molecular kinetic scheme uniquely associated with the transfer function by means of a classification procedure and an analytical step that imposes general biological constraints. We first tested SYSMOLE with synthetic data and evaluated its performance in terms of its rate of convergence to the correct molecular kinetic scheme and its robustness to noise. We then examined its performance on real experimental traces by analyzing macroscopic calcium-current traces elicited by membrane depolarization. SYSMOLE derived the correct, previously known molecular kinetic scheme describing the activation and inactivation of the underlying calcium channels and correctly identified the accepted mechanism of action of nifedipine, a calcium-channel blocker clinically used in patients with cardiovascular disease. Finally, we applied SYSMOLE to study the pharmacology of a new class of glutamate antipsychotic drugs and their crosstalk mechanism through a heteromeric complex of G protein-coupled receptors. Our results indicate that our methodology can be successfully applied to accurately derive molecular kinetic schemes from experimental macroscopic traces, and we anticipate that it may be useful in the study of a wide variety of biological systems.https://doi.org/10.1371/journal.pcbi.1005376
collection DOAJ
language English
format Article
sources DOAJ
author Miguel Fribourg
Diomedes E Logothetis
Javier González-Maeso
Stuart C Sealfon
Belén Galocha-Iragüen
Fernando Las-Heras Andrés
Vladimir Brezina
spellingShingle Miguel Fribourg
Diomedes E Logothetis
Javier González-Maeso
Stuart C Sealfon
Belén Galocha-Iragüen
Fernando Las-Heras Andrés
Vladimir Brezina
Elucidation of molecular kinetic schemes from macroscopic traces using system identification.
PLoS Computational Biology
author_facet Miguel Fribourg
Diomedes E Logothetis
Javier González-Maeso
Stuart C Sealfon
Belén Galocha-Iragüen
Fernando Las-Heras Andrés
Vladimir Brezina
author_sort Miguel Fribourg
title Elucidation of molecular kinetic schemes from macroscopic traces using system identification.
title_short Elucidation of molecular kinetic schemes from macroscopic traces using system identification.
title_full Elucidation of molecular kinetic schemes from macroscopic traces using system identification.
title_fullStr Elucidation of molecular kinetic schemes from macroscopic traces using system identification.
title_full_unstemmed Elucidation of molecular kinetic schemes from macroscopic traces using system identification.
title_sort elucidation of molecular kinetic schemes from macroscopic traces using system identification.
publisher Public Library of Science (PLoS)
series PLoS Computational Biology
issn 1553-734X
1553-7358
publishDate 2017-02-01
description Overall cellular responses to biologically-relevant stimuli are mediated by networks of simpler lower-level processes. Although information about some of these processes can now be obtained by visualizing and recording events at the molecular level, this is still possible only in especially favorable cases. Therefore the development of methods to extract the dynamics and relationships between the different lower-level (microscopic) processes from the overall (macroscopic) response remains a crucial challenge in the understanding of many aspects of physiology. Here we have devised a hybrid computational-analytical method to accomplish this task, the SYStems-based MOLecular kinetic scheme Extractor (SYSMOLE). SYSMOLE utilizes system-identification input-output analysis to obtain a transfer function between the stimulus and the overall cellular response in the Laplace-transformed domain. It then derives a Markov-chain state molecular kinetic scheme uniquely associated with the transfer function by means of a classification procedure and an analytical step that imposes general biological constraints. We first tested SYSMOLE with synthetic data and evaluated its performance in terms of its rate of convergence to the correct molecular kinetic scheme and its robustness to noise. We then examined its performance on real experimental traces by analyzing macroscopic calcium-current traces elicited by membrane depolarization. SYSMOLE derived the correct, previously known molecular kinetic scheme describing the activation and inactivation of the underlying calcium channels and correctly identified the accepted mechanism of action of nifedipine, a calcium-channel blocker clinically used in patients with cardiovascular disease. Finally, we applied SYSMOLE to study the pharmacology of a new class of glutamate antipsychotic drugs and their crosstalk mechanism through a heteromeric complex of G protein-coupled receptors. Our results indicate that our methodology can be successfully applied to accurately derive molecular kinetic schemes from experimental macroscopic traces, and we anticipate that it may be useful in the study of a wide variety of biological systems.
url https://doi.org/10.1371/journal.pcbi.1005376
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