Kinetic and thermodynamic modeling of a voltage-gated sodium channel

Like all biological and chemical reactions, ion channel kinetics are highly sensitive to changes in temperature. Therefore, it is prudent to investigate channel dynamics at physiological temperatures. However, most ion channel investigations are performed at room temperature due to practical considerations, such as recording stability and technical limitations. This problem is especially severe for the fast voltage-gated sodium channel, whose activation kinetics are faster than the time constant of the standard patch-clamp amplifier at physiological temperatures. Thus, biologically detailed simulations of the action potential generation evenly scale the kinetic models of voltage-gated channels acquired at room temperature. To quantitatively study voltage-gated sodium channels' temperature sensitivity, we recorded sodium currents from nucleated patches extracted from the rat's layer five neocortical pyramidal neurons at several temperatures from 13.5 to 30°C. We use these recordings to model the kinetics of the voltage-gated sodium channel as a function of temperature. We show that the temperature dependence of activation differs from that of inactivation. Furthermore, we show that the sustained current has a different temperature dependence than the fast current. Our kinetic and thermodynamic analysis of the current provided a numerical model spanning the entire temperature range. This model reproduced vital features of channel activation and inactivation. Furthermore, the model also reproduced action potential dependence on temperature. Thus, we provide an essential building block for the generation of biologically detailed models of cortical neurons.

Calmodulin Interactions with Voltage-Gated Sodium Channels

Calmodulin (CaM) is a small protein that acts as a ubiquitous signal transducer and regulates neuronal plasticity, muscle contraction, and immune response. It interacts with ion channels and plays regulatory roles in cellular electrophysiology. CaM modulates the voltage-gated sodium channel gating process, alters sodium current density, and regulates sodium channel protein trafficking and expression. Many mutations in the CaM-binding IQ domain give rise to diseases including epilepsy, autism, and arrhythmias by interfering with CaM interaction with the channel. In the present review, we discuss CaM interactions with the voltage-gated sodium channel and modulators involved in CaM regulation, as well as summarize CaM-binding IQ domain mutations associated with human diseases in the voltage-gated sodium channel family.

Abstract P361: Reduced Cardiac Tmem65 In Mouse Hearts Results In Intercalated Disc Defects And Eventual Dilated Cardiomyopathy With Cardiac Fibrosis

The intercalated disc (ICD) is unique membrane structure that is indispensable to normal heart function. However, its structural organization is not well understood. Previously, we showed that the ICD-bound transmembrane protein 65 (Tmem65) was required for connexin 43 (Cx43) localization in cultured mouse neonatal cardiomyocytes. Here, we investigated the role of Tmem65 in ICD organization in vivo . A mouse model was established by injecting CD1 mouse pups (3-7 days after birth) with recombinant adeno-associated virus 9 (rAAV9) harboring Tmem65 (or scrambled) shRNA. Quantitative polymerase chain reaction (qPCR) and immunoblots confirmed greater than 85% reduction in Tmem65 expression (7.1±0.7% remained for Tmem65 proteins; 14.4±2.5% remained for Tmem65 transcripts, n =4) in mouse ventricles compared to control hearts. Tmem65 knockdown (KD) mice exhibited heart failure-like symptoms as early as 3 weeks post viral administration. Specifically, Tmem65 KD mice developed eccentric hypertrophic cardiomyopathy in 3 weeks and dilated cardiomyopathy with severe cardiac fibrosis in 7 weeks, as confirmed by H&E and Masson’s Trichrome staining. Echocardiography and electrocardiography, respectively, showed depressed hemodynamics (19.27±1.46ml/min for cardiac output in control hearts vs. 6.63±0.52ml/min for Tmem65 KD hearts, n =6) and impaired conduction, including prolonged PR (22.7±1.85ms in control hearts vs. 28.89±3.85ms in Tmem65 KD hearts, n≥8), QRS intervals (10.47±0.42ms in control hearts vs. 16.35±0.36ms in Tmem65 KD hearts, n≥8), and slowed heart rate (415±10bpm in control hearts vs. 347±16bpm in Tmem65 KD hearts, n≥8) in Tmem65 KD mouse hearts. Immunoprecipitation and super-resolution microscopy confirmed the physical interaction and localization between Tmem65 and voltage-gated sodium channel β subunit (β1) at the ICD and this interaction was evidently required for the establishment of perinexal nanodomains and voltage-gated sodium channel 1.5 (NaV1.5) localization to the ICD. Disrupting Tmem65 function, thus, impaired perinexal structure, reduced conduction velocity, and ultimately resulted in cardiomyopathy in vivo .