Computational modeling reveals key contributions of KCNQ and hERG currents to the malleability of uterine action potentials underpinning labor

The electrical excitability of uterine smooth muscle cells is a key determinant of the contraction of the organ during labor and is manifested by spontaneous, periodic action potentials (APs). Near the end of term, APs vary in shape and size reflecting an ability to change the frequency, duration an...

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Veröffentlicht in:	PloS one 2014-12, Vol.9 (12), p.e114034
Hauptverfasser:	Tong, Wing-Chiu, Tribe, Rachel M, Smith, Roger, Taggart, Michael J
Format:	Artikel
Sprache:	eng
Schlagworte:	Action Potentials Analysis Biology and Life Sciences Bursting Channels Computation Computer applications Computer Simulation Contraction Electric properties Ether-A-Go-Go Potassium Channels - metabolism Excitability Female Humans KCNQ Potassium Channels - metabolism Kinetics Labor Labor, Obstetric - metabolism Labor, Obstetric - physiology Mathematical models Medical research Medicine and Health Sciences Models, Biological Muscle contraction Muscles Myocytes, Smooth Muscle - cytology Parturition Potassium Potassium channels (voltage-gated) Potassium currents Pregnancy Rodents Sensitivity analysis Smooth muscle Uterus Uterus - cytology Uterus - physiology Womens health
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description	The electrical excitability of uterine smooth muscle cells is a key determinant of the contraction of the organ during labor and is manifested by spontaneous, periodic action potentials (APs). Near the end of term, APs vary in shape and size reflecting an ability to change the frequency, duration and amplitude of uterine contractions. A recent mathematical model quantified several ionic features of the electrical excitability in uterine smooth muscle cells. It replicated many of the experimentally recorded uterine AP configurations but its limitations were evident when trying to simulate the long-duration bursting APs characteristic of labor. A computational parameter search suggested that delayed rectifying K(+) currents could be a key model component requiring improvement to produce the longer-lasting bursting APs. Of the delayed rectifying K(+) currents family it is of interest that KCNQ and hERG channels have been reported to be gestationally regulated in the uterus. These currents exhibit features similar to the broadly defined uterine IK1 of the original mathematical model. We thus formulated new quantitative descriptions for several I(KCNQ) and I(hERG). Incorporation of these currents into the uterine cell model enabled simulations of the long-lasting bursting APs. Moreover, we used this modified model to simulate the effects of different contributions of I(KCNQ) and I(hERG) on AP form. Our findings suggest that the alterations in expression of hERG and KCNQ channels can potentially provide a mechanism for fine tuning of AP forms that lends a malleability for changing between plateau-like and long-lasting bursting-type APs as uterine cells prepare for parturition.
doi_str_mv	10.1371/journal.pone.0114034
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Near the end of term, APs vary in shape and size reflecting an ability to change the frequency, duration and amplitude of uterine contractions. A recent mathematical model quantified several ionic features of the electrical excitability in uterine smooth muscle cells. It replicated many of the experimentally recorded uterine AP configurations but its limitations were evident when trying to simulate the long-duration bursting APs characteristic of labor. A computational parameter search suggested that delayed rectifying K(+) currents could be a key model component requiring improvement to produce the longer-lasting bursting APs. Of the delayed rectifying K(+) currents family it is of interest that KCNQ and hERG channels have been reported to be gestationally regulated in the uterus. These currents exhibit features similar to the broadly defined uterine IK1 of the original mathematical model. We thus formulated new quantitative descriptions for several I(KCNQ) and I(hERG). Incorporation of these currents into the uterine cell model enabled simulations of the long-lasting bursting APs. Moreover, we used this modified model to simulate the effects of different contributions of I(KCNQ) and I(hERG) on AP form. 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Near the end of term, APs vary in shape and size reflecting an ability to change the frequency, duration and amplitude of uterine contractions. A recent mathematical model quantified several ionic features of the electrical excitability in uterine smooth muscle cells. It replicated many of the experimentally recorded uterine AP configurations but its limitations were evident when trying to simulate the long-duration bursting APs characteristic of labor. A computational parameter search suggested that delayed rectifying K(+) currents could be a key model component requiring improvement to produce the longer-lasting bursting APs. Of the delayed rectifying K(+) currents family it is of interest that KCNQ and hERG channels have been reported to be gestationally regulated in the uterus. These currents exhibit features similar to the broadly defined uterine IK1 of the original mathematical model. We thus formulated new quantitative descriptions for several I(KCNQ) and I(hERG). Incorporation of these currents into the uterine cell model enabled simulations of the long-lasting bursting APs. Moreover, we used this modified model to simulate the effects of different contributions of I(KCNQ) and I(hERG) on AP form. 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Incorporation of these currents into the uterine cell model enabled simulations of the long-lasting bursting APs. Moreover, we used this modified model to simulate the effects of different contributions of I(KCNQ) and I(hERG) on AP form. Our findings suggest that the alterations in expression of hERG and KCNQ channels can potentially provide a mechanism for fine tuning of AP forms that lends a malleability for changing between plateau-like and long-lasting bursting-type APs as uterine cells prepare for parturition.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>25474527</pmid><doi>10.1371/journal.pone.0114034</doi><oa>free_for_read</oa></addata></record>
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subjects	Action Potentials Analysis Biology and Life Sciences Bursting Channels Computation Computer applications Computer Simulation Contraction Electric properties Ether-A-Go-Go Potassium Channels - metabolism Excitability Female Humans KCNQ Potassium Channels - metabolism Kinetics Labor Labor, Obstetric - metabolism Labor, Obstetric - physiology Mathematical models Medical research Medicine and Health Sciences Models, Biological Muscle contraction Muscles Myocytes, Smooth Muscle - cytology Parturition Potassium Potassium channels (voltage-gated) Potassium currents Pregnancy Rodents Sensitivity analysis Smooth muscle Uterus Uterus - cytology Uterus - physiology Womens health
title	Computational modeling reveals key contributions of KCNQ and hERG currents to the malleability of uterine action potentials underpinning labor
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