<HashMap><database>biostudies-literature</database><scores/><additional><submitter>Nowak MB</submitter><funding>NHLBI NIH HHS</funding><funding>National Institutes of Health</funding><pagination>60-71</pagination><full_dataset_link>https://www.ebi.ac.uk/biostudies/studies/S-EPMC8026540</full_dataset_link><repository>biostudies-literature</repository><omics_type>Unknown</omics_type><volume>153</volume><pubmed_abstract>Cardiac action potentials are initiated by sodium ion (Na&lt;sup>+&lt;/sup>) influx through voltage-gated Na&lt;sup>+&lt;/sup> channels. Na&lt;sup>+&lt;/sup> channel gain-of-function (GOF) can arise in inherited conditions due to mutations in the gene encoding the cardiac Na&lt;sup>+&lt;/sup> channel, such as Long QT syndrome type 3 (LQT3). LQT3 can be a "concealed" disease, as patients with LQT3-associated mutations can remain asymptomatic until later in life; however, arrhythmias can also arise early in life in LQT3 patients, demonstrating a complex age-associated manifestation. We and others recently demonstrated that cardiac Na&lt;sup>+&lt;/sup> channels preferentially localize at the intercalated disc (ID) in adult cardiac tissue, which facilitates ephaptic coupling and formation of intercellular Na&lt;sup>+&lt;/sup> nanodomains that regulate pro-arrhythmic early afterdepolarization (EAD) formation in tissue with Na&lt;sup>+&lt;/sup> channel GOF. Several properties related to ephaptic coupling vary with age, such as cell size and Na&lt;sup>+&lt;/sup> channel and gap junction (GJ) expression and distribution: neonatal cells have immature IDs, with Na&lt;sup>+&lt;/sup> channels and GJs primarily diffusively distributed, while adult myocytes have mature IDs with preferentially localized Na&lt;sup>+&lt;/sup> channels and GJs. Here, we perform an in silico study varying critical age-dependent parameters to investigate mechanisms underlying age-associated manifestation of Na&lt;sup>+&lt;/sup> channel GOF in a model of guinea pig cardiac tissue. Simulations predict that total Na&lt;sup>+&lt;/sup> current conductance is a critical factor in action potential duration (APD) prolongation. We find a complex cell size/ Na&lt;sup>+&lt;/sup> channel expression relationship: increases in cell size (without concurrent increases in Na&lt;sup>+&lt;/sup> channel expression) suppress EAD formation, while increases in Na&lt;sup>+&lt;/sup> channel expression (without concurrent increases in cell size) promotes EAD formation. Finally, simulations with neonatal and early age-associated parameters predict normal APD with minimal dependence on intercellular cleft width; however, variability in cellular properties can lead to EADs presenting in early developmental stages. In contrast, for adult-associated parameters, EAD formation is highly dependent on cleft width, consistent with a mechanism underlying the age-associated manifestation of the Na&lt;sup>+&lt;/sup> channel GOF.</pubmed_abstract><journal>Journal of molecular and cellular cardiology</journal><pubmed_title>Mechanisms underlying age-associated manifestation of cardiac sodium channel gain-of-function.</pubmed_title><pmcid>PMC8026540</pmcid><funding_grant_id>R01 HL102298</funding_grant_id><funding_grant_id>R01 HL138003</funding_grant_id><pubmed_authors>Poelzing S</pubmed_authors><pubmed_authors>Nowak MB</pubmed_authors><pubmed_authors>Weinberg SH</pubmed_authors></additional><is_claimable>false</is_claimable><name>Mechanisms underlying age-associated manifestation of cardiac sodium channel gain-of-function.</name><description>Cardiac action potentials are initiated by sodium ion (Na&lt;sup>+&lt;/sup>) influx through voltage-gated Na&lt;sup>+&lt;/sup> channels. Na&lt;sup>+&lt;/sup> channel gain-of-function (GOF) can arise in inherited conditions due to mutations in the gene encoding the cardiac Na&lt;sup>+&lt;/sup> channel, such as Long QT syndrome type 3 (LQT3). LQT3 can be a "concealed" disease, as patients with LQT3-associated mutations can remain asymptomatic until later in life; however, arrhythmias can also arise early in life in LQT3 patients, demonstrating a complex age-associated manifestation. We and others recently demonstrated that cardiac Na&lt;sup>+&lt;/sup> channels preferentially localize at the intercalated disc (ID) in adult cardiac tissue, which facilitates ephaptic coupling and formation of intercellular Na&lt;sup>+&lt;/sup> nanodomains that regulate pro-arrhythmic early afterdepolarization (EAD) formation in tissue with Na&lt;sup>+&lt;/sup> channel GOF. Several properties related to ephaptic coupling vary with age, such as cell size and Na&lt;sup>+&lt;/sup> channel and gap junction (GJ) expression and distribution: neonatal cells have immature IDs, with Na&lt;sup>+&lt;/sup> channels and GJs primarily diffusively distributed, while adult myocytes have mature IDs with preferentially localized Na&lt;sup>+&lt;/sup> channels and GJs. Here, we perform an in silico study varying critical age-dependent parameters to investigate mechanisms underlying age-associated manifestation of Na&lt;sup>+&lt;/sup> channel GOF in a model of guinea pig cardiac tissue. Simulations predict that total Na&lt;sup>+&lt;/sup> current conductance is a critical factor in action potential duration (APD) prolongation. We find a complex cell size/ Na&lt;sup>+&lt;/sup> channel expression relationship: increases in cell size (without concurrent increases in Na&lt;sup>+&lt;/sup> channel expression) suppress EAD formation, while increases in Na&lt;sup>+&lt;/sup> channel expression (without concurrent increases in cell size) promotes EAD formation. Finally, simulations with neonatal and early age-associated parameters predict normal APD with minimal dependence on intercellular cleft width; however, variability in cellular properties can lead to EADs presenting in early developmental stages. In contrast, for adult-associated parameters, EAD formation is highly dependent on cleft width, consistent with a mechanism underlying the age-associated manifestation of the Na&lt;sup>+&lt;/sup> channel GOF.</description><dates><release>2021-01-01T00:00:00Z</release><publication>2021 Apr</publication><modification>2025-04-29T11:28:13.912Z</modification><creation>2025-04-29T11:28:13.912Z</creation></dates><accession>S-EPMC8026540</accession><cross_references><pubmed>33373643</pubmed><doi>10.1016/j.yjmcc.2020.12.008</doi></cross_references></HashMap>