Bogdan Amuzescu

Magnesium‐inhibited, TRPM6/7‐like channel in cardiac myocytes: permeation of divalent cations and pH‐mediated regulation

Cardiac tissue expresses several TRP proteins as well as a Mg2+‐inhibited, non‐selective cation current (IMIC) that bears many characteristics of TRP channel currents. We used the whole‐cell voltage clamp technique in pig and rat ventricular myocytes to characterize the permeation, blockage properties and regulation of the cardiac IMIC channels in order to compare them with TRP channels, in particular with Mg2+‐sensitive TRPM6 and TRPM7. We show that removing extracellular divalent cations unmasks large inward and outward monovalent currents, which can be inhibited by intracellular Mg2+. Inward currents are suppressed upon replacing extracellular Na+ by NMDG+. Divalent cations block monovalent IMIC and, at 10–20 mm, carry measurable currents. Their efficacy sequence in decreasing outward IMIC (Ni2+= Mg2+ > Ca2+ > Ba2+) and in inducing inward IMIC (Ni2+≫ Mg2+= Ca2+≈ Ba2+), and their permeabilities calculated from reversal potentials are similar to those of TRPM6 and TRPM7 channels. The trivalent cations Gd3+ and Dy3+ also block IMIC in a voltage‐dependent manner (δ= 0.4–0.5). In addition they inhibit the inward current carried by divalent cations. IMIC is regulated by pH. Decreasing or increasing extracellular pH decreased and increased IMIC, respectively (pH0.5= 6.9, nH= 0.98). Qualitatively similar results were obtained on IMIC in rat basophilic leukaemia cells. These effects in cardiac myocytes were absent in the presence of high intracellular buffering by 40 mm Hepes. Our results suggest that IMIC in cardiac cells is due to TRPM channels, most probably to TRPM6 or TRPM7 channels or to their heteromultimeres.

Cooling inhibits capsaicin-induced currents in cultured rat dorsal root ganglion neurones.

Whole-cell and single-channel recordings from rat dorsal root ganglion neurones were used to investigate the temperature dependence of currents through the capsaicin receptor (vanilloid receptor 1, VR1). Reducing the temperature from 31 to 14 degrees C inhibited the current induced by 0.5 microM capsaicin by 80%. The Q(10) (temperature coefficient over a 10 degrees C range) of the whole-cell capsaicin-induced current was 2.3 between 10 and 30 degrees C. Single-channel recordings showed that this inhibition by cooling was due to a marked reduction in the open probability (Q(10)=8.2 between 10 and 30 degrees C). This effect can explain the pain relief and reduction in inflammation caused by strong cooling of the skin.

Action Potential Characterization of Human Induced Pluripotent Stem Cell–Derived Cardiomyocytes Using Automated Patch-Clamp Technology

Recent progress in embryonic stem cell (ESC) and induced pluripotent stem cell (iPSC) research led to high-purity preparations of human cardiomyocytes (CMs) differentiated from these two sources-suitable for tissue regeneration, in vitro models of disease, and cardiac safety pharmacology screening. We performed a detailed characterization of the effects of nifedipine, cisapride, and tetrodotoxin (TTX) on Cor.4U(®) human iPSC-CM, using automated whole-cell patch-clamp recordings with the CytoPatch™ 2 equipment, within a complex assay combining multiple voltage-clamp and current-clamp protocols in a well-defined sequence, and quantitative analysis of several action potential (AP) parameters. We retrieved three electrical phenotypes based on AP shape: ventricular, atrial/nodal, and S-type (with ventricular-like depolarization and lack of plateau). To suppress spontaneous firing, present in many cells, we injected continuously faint hyperpolarizing currents of -10 or -20 pA. We defined quality criteria (both seal and membrane resistance over 1 GΩ), and focused our study on cells with ventricular-like AP. Nifedipine induced marked decreases in AP duration (APD): APD90 (49.8% and 40.8% of control values at 1 and 10 μM, respectively), APD50 (16.1% and 12%); cisapride 0.1 μM increased APD90 to 176.2%; and tetrodotoxin 10 μM decreased maximum slope of phase to 33.3% of control, peak depolarization potential to 76.3% of control, and shortened APD90 on average to 80.4%. These results prove feasibility of automated voltage- and current-clamp recordings on human iPSC-CM and their potential use for in-depth drug evaluation and proarrhythmic liability assessment, as well as for diagnosis and pharmacology tests for cardiac channelopathy patients.

A system for applying rapid warming or cooling stimuli to cells during patch clamp recording or ion imaging

We describe a system for superfusing small groups of cells at a precisely controlled and rapidly adjustable local temperature. Before being applied to the cell or cells under study, solutions are heated or cooled in a chamber of small volume ( approximately 150 microl) and large surface area, sandwiched between four small Peltier elements. The current through the Peltier elements is controlled by a microprocessor using a PID (proportional-integral-derivative) feedback algorithm. The chamber can be heated to at least 60 degrees C and cooled to 0 degrees C, changing its temperature at a maximum rate of about 7 degrees C per second; temperature ramps can be followed under feedback control at up to 4 degrees C per second. Temperature commands can be applied from the digital-to-analogue converter of any laboratory interface or generated digitally by the microprocessor. The peak-to-peak noise contributed by the system does not exceed that contributed by a patch pipette, holder and headstage, making it suitable for single channel as well as whole cell recordings.

Extracellular trypsin increases ASIC1a selectivity for monovalent versus divalent cations

Sustained proton activation of native ASIC channels in primary sensory neurons or HEK293 cells leads to a reduction in the peak amplitude of transient inward currents and the progressive development of a persistent component, which hinders titration experiments in pharmacological studies. Here we report that extracellular trypsin applied for 5 min at 10-45 microg/ml and/or a short exposure to high Ca2+ (75 mM for less than 1 min) alleviate the persistent component, improving reproducibility of acid-elicited transients. Selectivity measurements performed in current clamp mode, in essentially bi-ionic conditions, prove that these two treatments decrease hASIC1a permeability for divalent but not for monovalent cations, producing a significant change in P(Na)/P(Ca) from 8.2+/-2.1 (mean+/-S.D.) to 26.0+/-7.8 (trypsin) or 24.5+/-11.1 (high Ca2+). The slope conductance of the unit inward Ca2+ transient was also lowered from 5.7 to 2.7 pS after trypsin.

Late cardiac sodium current can be assessed using automated patch-clamp

The cardiac late Na + current is generated by a small fraction of voltage-dependent Na + channels that undergo a conformational change to a burst-gating mode, with repeated openings and closures during the action potential (AP) plateau. Its magnitude can be augmented by inactivation-defective mutations, myocardial ischemia, or prolonged exposure to chemical compounds leading to drug-induced (di)-long QT syndrome, and results in an increased susceptibility to cardiac arrhythmias. Using CytoPatch™ 2 automated patch-clamp equipment, we performed whole-cell recordings in HEK293 cells stably expressing human Nav1.5, and measured the late Na + component as average current over the last 100 ms of 300 ms depolarizing pulses to -10 mV from a holding potential of -100 mV, with a repetition frequency of 0.33 Hz. Averaged values in different steady-state experimental conditions were further corrected by the subtraction of current average during the application of tetrodotoxin (TTX) 30 μM. We show that ranolazine at 10 and 30 μM in 3 min applications reduced the late Na + current to 75.0 ± 2.7% (mean ± SEM, n = 17) and 58.4 ± 3.5% ( n = 18) of initial levels, respectively, while a 5 min application of veratridine 1 μM resulted in a reversible current increase to 269.1 ± 16.1% ( n = 28) of initial values. Using fluctuation analysis, we observed that ranolazine 30 μM decreased mean open probability p from 0.6 to 0.38 without modifying the number of active channels n, while veratridine 1 μM increased n 2.5-fold without changing p. In human iPSC-derived cardiomyocytes, veratridine 1 μM reversibly increased APD90 2.12 ± 0.41-fold (mean ± SEM, n = 6). This effect is attributable to inactivation removal in Nav1.5 channels, since significant inhibitory effects on hERG current were detected at higher concentrations in hERG-expressing HEK293 cells, with a 28.9 ± 6.0% inhibition (mean ± SD, n = 10) with 50 μM veratridine.

ASIC1a activation by amitriptyline and FMRF-amide is removed by serine proteases

Analgesia induced by certain tricyclic antidepressants has been largely used for decades, yet the mechanisms involved are incompletely understood. Starting from previously reported dual effects of amitriptyline on wild-type ENaC (Pena F, et al. J Pharm Pharmacol 54:1393-8: 2002), we extended our study to ASIC1a by performing a series of whole cell and single-channel recordings of proton-activated currents in HEK293 cells. Acid pulses were applied at 2 or 5 min intervals, and amitriptyline (1-500 μM) was applied at a holding pH of 7.4 or 8.4 between pulses. Dose-response plots were fitted with dual Hill type functions, yielding a half-activatory constant of 0.3 μM and a half-inhibitory constant of 382 μ M at pH 7.4. At pH 8.4 both constants were shifted to higher values (0.5 and 444 μM, respectively). In whole-cell experiments, FMRF-amide increased the peak amplitude of ASIC1a transients at 0.1 μM and decreased it at 1 and 100 μM. Single-channel recordings were idealized and fitted using an 8-state linear connectivity model comprising four consecutive activation steps. Both amitriptyline (1 μM) and FMRF-amide (0.1 μM) increased the unitary current amplitude, and modified the opening and closing rates of the first gating mode. They also increased the transition rate from the second to the first gating mode, and the rate of final closure. The activatory effect of both compounds vanished after a mild trypsin pretreatment, suggesting the existence of activatory sites for FMRF-amide and amitriptyline in the outer vestibule of ASIC1a, which can be removed by exo- or endogenous serine-proteases.

Design, Fabrication and Characterization of a Low-Impedance 3D Electrode Array System for Neuro-Electrophysiology

Recent progress in patterned microelectrode manufacturing technology and microfluidics has opened the way to a large variety of cellular and molecular biosensor-based applications. In this extremely diverse and rapidly expanding landscape, silicon-based technologies occupy a special position, given their statute of mature, consolidated, and highly accessible areas of development. Within the present work we report microfabrication procedures and workflows for 3D patterned gold-plated microelectrode arrays (MEA) of different shapes (pyramidal, conical and high aspect ratio), and we provide a detailed characterization of their physical features during all the fabrication steps to have in the end a reliable technology. Moreover, the electrical performances of MEA silicon chips mounted on standardized connector boards via ultrasound wire-bonding have been tested using non-destructive electrochemical methods: linear sweep and cyclic voltammetry, impedance spectroscopy. Further, an experimental recording chamber package suitable for in vitro electrophysiology experiments has been realized using custom-design electronics for electrical stimulus delivery and local field potential recording, included in a complete electrophysiology setup, and the experimental structures have been tested on newborn rat hippocampal slices, yielding similar performance compared to commercially available MEA equipments.

Stability and sustained oscillations in a ventricular cardiomyocyte model

The Luo-Rudy I model, describing the electrophysiology of a ventricular cardiomyocyte, is associated with an 8-dimensional discontinuous dynamical system with logarithmic and exponential non-linearities depending on 15 parameters. The associated stationary problem was reduced to a nonlinear system in only two unknowns, the transmembrane potential V and the intracellular calcium concentration [Ca]i. By numerical approaches appropriate to bifurcation problems, sections in the static bifurcation diagram were determined. For a variable steady depolarizing or hyperpolarizing current (Ist), the corresponding projection of the static bifurcation diagram in the (Ist, V) plane is complex, featuring three branches of stationary solutions joined by two limit points. On the upper branch oscillations can occur, being either damped at a stable focus or diverted to the lower branch of stable stationary solutions when reaching the unstable manifold of a homoclinic saddle, thus resulting in early after-depolarizations (EADs). The middle branch of solutions is a series of unstable saddle points, while the lower one a series of stable nodes. For variable slow inward and K+ current maximal conductances (gsi and gK), in a range between 0 and 4-fold normal values, the dynamics is even more complex, and in certain instances sustained oscillations tending to a limit cycle appear. All these types of behavior were correctly predicted by linear stability analysis and bifurcation theory methods, leading to identification of Hopf bifurcation points, limit points of cycles and period doubling bifurcations. In particular settings, e.g. one-fifth-of-normal gsi, EADs and sustained high amplitude oscillations due to an unstable resting state may occur simultaneously.

Amitriptyline has a dual effect on the conductive properties of the epithelial Na channel

This study was undertaken with the aim of testing the action of amitriptyline on the epithelial Na channel (ENaC), which belongs to the same family (Deg/ENaC) as ASICs (acid‐sensing ion channels) and many other putative members in the brain. We assumed that, having a common protein structure, characterization of the amitriptyline‐ENaC interaction could help to elucidate the analgesic mechanism of this tricyclic antidepressant. Na‐channel characteristics were derived from the analysis of blocker‐induced lorentzian noise produced by amiloride. The effect of amitriptyline, present in the mucosal bathing solution, on the transepithelial short‐circuit current (1sc) and conductance (Gt), and on the blocker‐induced noise of apical Na channels, was studied on isolated ventral skin of the frog Rana ridibunda. Amitriptyline exerted a dual effect on the macroscopic short‐circuit current and conductance of the epithelia, increasing these two parameters in the concentration range 0.1–50 μM, while at higher concentrations (100–1000 μM) it showed an inhibitory action. The decrease in the association rate (k01) of amiloride to the apical Na channels from 15.6 ± 4.2 μM−1 S−1 in control Cl‐Ringer to 7.4 ± 1.7 μM−1 S−1 at 200 μM amitriptyline in a concentration‐dependent manner suggests a competitive binding of amitriptyline to the pyrazine ring binding site for amiloride.