Why Is Only Type 1 Electrocardiogram Diagnostic of Brugada Syndrome? Mechanistic Insights From Computer Modeling

Background: Three types of characteristic ST-segment elevation are associated with Brugada syndrome but only type 1 is diagnostic. Why only type 1 ECG is diagnostic remains unanswered. Methods: Computer simulations were performed in single cells, 1-dimensional cables, and 2-dimensional tissues to investigate the effects of the peak and late components of the transient outward potassium current (I to ), sodium current, and L-type calcium current (I Ca,L ) as well as other potassium currents on the genesis of ECG morphologies and phase 2 reentry (P2R). Results: Although a sufficiently large peak I to was required to result in the type 1 ECG pattern and P2R, increasing the late component of I to converted type 1 ECG to type 2 ECG and suppressed P2R. Increasing the peak I to promoted spiral wave breakup, potentiating the transition from tachycardia to fibrillation, but increasing the late I to prevented spiral wave breakup by flattening the action potential duration restitution and preventing P2R. A sufficiently large I Ca,L conductance was needed for P2R to occur, but once above the critical conductance, blocking I Ca,L promoted P2R. However, selectively blocking the window and late components of I Ca,L suppressed P2R, countering the effect of the late I to . Blocking either the peak or late components of sodium current promoted P2R, with the late sodium current blockade having the larger effect. As expected, increasing other potassium currents potentiated P2R, with ATP-sensitive potassium current exhibiting a larger effect than rapid and slow component of the delayed rectifier potassium current. Conclusions: The peak I to promotes type 1 ECG and P2R, whereas the late I to converts type 1 ECG to type 2 ECG and suppresses P2R. Blocking the peak I Ca,L and either the peak or the late sodium current promotes P2R, whereas blocking the window and late I Ca,L suppresses P2R. These results provide important insights into the mechanisms of arrhythmogenesis and potential therapeutic targets for treatment of Brugada syndrome.

IQSEC2 mutation associated with epilepsy, intellectual disability, and autism results in hyperexcitability of patient-derived neurons and deficient synaptic transmission

Mutations in the IQSEC2 gene are associated with drug-resistant, multifocal infantile and childhood epilepsy; autism; and severe intellectual disability (ID). We used induced pluripotent stem cell (iPSC) technology to obtain hippocampal neurons to investigate the neuropathology of IQSEC2-mediated disease. The neurons were characterized at three-time points during differentiation to assess developmental progression. We showed that immature IQSEC2 mutant dentate gyrus (DG) granule neurons were extremely hyperexcitable, exhibiting increased sodium and potassium currents compared to those of CRISPR-Cas9-corrected isogenic controls, and displayed dysregulation of genes involved in differentiation and development. Immature IQSEC2 mutant cultured neurons exhibited a marked reduction in the number of inhibitory neurons, which contributed further to hyperexcitability. As the mutant neurons aged, they became hypoexcitable, exhibiting reduced sodium and potassium currents and a reduction in the rate of synaptic and network activity, and showed dysregulation of genes involved in synaptic transmission and neuronal differentiation. Mature IQSEC2 mutant neurons were less viable than wild-type mature neurons and had reduced expression of surface AMPA receptors. Our studies provide mechanistic insights into severe infantile epilepsy and neurodevelopmental delay associated with this mutation and present a human model for studying IQSEC2 mutations in vitro.

Abstract P201: Negative Regulation Of PVN Pre-sympathetic Neuronal Activity By Resident Microglia

Hypothalamic paraventricular nucleus (PVN) is a critical integrating region in controlling peripheral sympathetic tonicity. While the vast studies have unraveled the regulatory circuits affecting PVN pre-sympathetic neurons, local factors for maintaining the homeostasis of neuronal excitability are barely understood. In the present study we investigated the role of microglia, the primary resident immune cells of the CNS, in this context. By electrophysiological recording, we found that loss of resident microglia induced an increased firing frequency and attenuated outward potassium currents in the PVN pre-sympathetic neurons, tachycardia and impaired heart rate variability. Combining the transcriptomics analysis of the PVN microglia, we identified a releasable factor, which was dominantly expressed in microglia compared to other brain parenchymal cells. ICV infusion of the recombinant peptide restored potassium currents in the PVN pre-sympathetic neurons and autonomic function in microglia-depleted mice. In summary, our results provided a novel intrinsic regulatory mechanism by which microglia suppress neuronal over excitation in physiological condition.

The electrophysiological effects of cannabidiol on action potentials and transmembrane potassium currents in rabbit and dog cardiac ventricular preparations

Cannabis use is associated with known cardiovascular side effects such as cardiac arrhythmias or even sudden cardiac death. The mechanisms behind these adverse effects are unknown. The aim of the present work was to study the cellular cardiac electrophysiological effects of cannabidiol (CBD) on action potentials and several transmembrane potassium currents, such as the rapid (IKr) and slow (IKs) delayed rectifier, the transient outward (Ito) and inward rectifier (IK1) potassium currents in rabbit and dog cardiac preparations. CBD increased action potential duration (APD) significantly in both rabbit (from 211.7 ± 11.2. to 224.6 ± 11.4 ms, n = 8) and dog (from 215.2 ± 9.0 to 231.7 ± 4.7 ms, n = 6) ventricular papillary muscle at 5 µM concentration. CBD decreased IKr, IKs and Ito (only in dog) significantly with corresponding estimated EC50 values of 4.9, 3.1 and 5 µM, respectively, without changing IK1. Although the EC50 value of CBD was found to be higher than literary Cmax values after CBD smoking and oral intake, our results raise the possibility that potassium channel inhibition by lengthening cardiac repolarization might have a role in the possible proarrhythmic side effects of cannabinoids in situations where CBD metabolism and/or the repolarization reserve is impaired.