The Ionic Selectivity of Lysenin Channels in Open and Sub-Conducting States

The electrochemical gradients established across cell membranes are paramount for the execution of biological functions. Besides ion channels, other transporters, such as exogenous pore-forming toxins, may present ionic selectivity upon reconstitution in natural and artificial lipid membranes and contribute to the electrochemical gradients. In this context, we utilized electrophysiology approaches to assess the ionic selectivity of the pore-forming toxin lysenin reconstituted in planar bilayer lipid membranes. The membrane voltages were determined from the reversal potentials recorded upon channel exposure to asymmetrical ionic conditions, and the permeability ratios were calculated from the fit with the Goldman–Hodgkin–Katz equation. Our work shows that lysenin channels are ion-selective and the determined permeability coefficients are cation and anion-species dependent. We also exploited the unique property of lysenin channels to transition to a stable sub-conducting state upon exposure to calcium ions and assessed their subsequent change in ionic selectivity. The observed loss of selectivity was implemented in an electrical model describing the dependency of reversal potentials on calcium concentration. In conclusion, our work demonstrates that this pore-forming toxin presents ionic selectivity but this is adjusted by the particular conduction state of the channels.

Biophysical characteristics of TRIC-A and TRIC-B channels and their regulation of RYR2

Trimeric intracellular cation channels (TRIC-A and TRIC-B), found in the sarco/endoplasmic reticulum (SR/ER) and nuclear membranes, are thought to provide countercurrents to balance Ca2+-movements across the SR, but there is also evidence that they physically interact with ryanodine receptors (RYR). We therefore investigated if TRIC channels could modulate the single-channel function of RYR2 after incorporation of vesicles isolated from HEK293 cells expressing TRIC-A or TRIC-B with RYR2 into artificial membranes under voltage clamp. We also examined the gating and conductance properties of TRIC channels. Co-expression of RYR2 with either TRIC-A or TRIC-B significantly altered the gating behavior of RYR2; however, co-expression with TRIC-A was particularly effective at potentiating the activating effects of cytosolic Ca2+. Fusing membrane vesicles containing TRIC-A or TRIC-B together with RYR2 into bilayers produced large currents of rapidly gating current fluctuations of multiple amplitudes. In 740 cytosolic/210 luminal mM KCl gradient, current-voltage relationships of macroscopic currents revealed average reversal potentials (Erev) of −13.67 ± 9.02 (n = 7), −2.11 ± 3.84 (n = 11), and 13.19 ± 3.23 (n = 13, **, P = 0.0025) from vesicles from RYR2 only, RyR2 + TRIC-A, or RyR2 + TRIC-B cells, respectively. Thus, with the incorporation of TRIC channels, the Erevs depart further from the calculated Erev for ideally selective cation channels than occurs when vesicles from RYR2-only cells are incorporated, suggesting that TRIC channels are permeable to both K+ and Cl−. In conclusion, our results indicate that both TRIC-A and TRIC-B regulate the gating of RYR2, but that TRIC-A has greater capacity to stimulate the RYR2 opening. The results also suggest that TRIC channels may be relatively nonselective ion channels being permeable to both cations and anions. This property would enable TRIC channels to be versatile providers of counter-ion current throughout the SR of many cell types.

Sparsification of AP firing in adult-born hippocampal granule cells via voltage-dependent α5-GABAA receptors

GABA can depolarize immature neurons close to the action potential (AP) threshold in development and adult neurogenesis. Nevertheless, GABAergic synapses effectively inhibit AP firing in newborn granule cells of the adult hippocampus as early as 2 weeks post mitosis. The underlying mechanisms are largely unclear. Here we analyzed GABAergic inputs in newborn 2- to 4-week-old hippocampal granule cells mediated by soma-targeting parvalbumin (PV) and dendrite-targeting somatostatin (SOM) interneurons. Surprisingly, both interneuron subtypes activate α5-subunit containing GABAA receptors (α5-GABAARs) in young neurons, showing a nonlinear voltage dependence with increasing conductance around the AP threshold. By contrast, in mature cells, PV interneurons mediate linear GABAergic synaptic currents lacking α5-subunits, while SOM-interneurons continue to target nonlinear α5-GABAARs. Computational modelling shows that the voltage-dependent amplification of α5-GABAAR opening in young neurons is crucial for inhibition of AP firing to generate balanced and sparse firing activity, even with depolarized GABA reversal potentials.

Effects of Diffusion Coefficients and Permanent Charge on Reversal Potentials in Ionic Channels

In this work, the dependence of reversal potentials and zero-current fluxes on diffusion coefficients are examined for ionic flows through membrane channels. The study is conducted for the setup of a simple structure defined by the profile of permanent charges with two mobile ion species, one positively charged (cation) and one negatively charged (anion). Numerical observations are obtained from analytical results established using geometric singular perturbation analysis of classical Poisson–Nernst–Planck models. For 1:1 ionic mixtures with arbitrary diffusion constants, Mofidi and Liu (arXiv:1909.01192) conducted a rigorous mathematical analysis and derived an equation for reversal potentials. We summarize and extend these results with numerical observations for biological relevant situations. The numerical investigations on profiles of the electrochemical potentials, ion concentrations, and electrical potential across ion channels are also presented for the zero-current case. Moreover, the dependence of current and fluxes on voltages and permanent charges is investigated. In the opinion of the authors, many results in the paper are not intuitive, and it is difficult, if not impossible, to reveal all cases without investigations of this type.

Neuronal morphologies built for reliable physiology in a rhythmic motor circuit

The neurons of the crustacean stomatogastric ganglion (STG) exhibit highly-conserved firing patterns, voltage waveforms, and circuit functions despite quantifiable animal-to-animal variability in their neuronal morphologies. In recent work, we showed that one neuron type, the Gastric Mill (GM) neuron, is electrotonically compact and operates much like a single compartment, despite having thousands of branch points and a total cable length on the order of 10 mm. Here, we explore how STG neurite morphology shapes voltage signal propagation and summation in four STG neuron types. We use focal glutamate photo-uncaging in tandem with somatic intracellular recordings to examine passive electrotonic structure and voltage signal summation in the GM neuron and three additional STG neuron types: Lateral Pyloric (LP), Ventricular Dilator (VD), and Pyloric Dilator (PD) neurons. In each neuron, we measured the amplitudes and apparent reversal potentials (Erevs) of inhibitory responses evoked with focal glutamate photo-uncaging at more than 20 sites varying in their distance (100–800 μm) from the somatic recording site in the presence of TTX. Apparent Erevs were relatively invariant (mean CVs = 0.04, 0.06, 0.05, and 0.08 for 5–6 GM, LP, PD, VD neurons, respectively), suggesting that all four neuron types are similarly electrotonically uniform and compact. We then characterized the directional sensitivity and arithmetic of voltage summation (with fast sequential activation of 4–6 sites) in individual STG neurites. All four neuron types showed no directional bias in voltage signal summation and linear voltage summation. We motivate these experiments with a proof-of-concept computational model that suggests the immense tapering of STG neurite diameters: from 10–20 μm to sub-micron diameters at the terminal tips, may explain the uniform electrotonic structures experimentally observed and contribute to the robust nature of this central pattern-generating circuit.

When complex neuronal structures may not matter

Much work has explored animal-to-animal variability and compensation in ion channel expression. Yet, little is known regarding the physiological consequences of morphological variability. We quantify animal-to-animal variability in cable lengths (CV = 0.4) and branching patterns in the Gastric Mill (GM) neuron, an identified neuron type with highly-conserved physiological properties in the crustacean stomatogastric ganglion (STG) of Cancer borealis. We examined passive GM electrotonic structure by measuring the amplitudes and apparent reversal potentials (Erevs) of inhibitory responses evoked with focal glutamate photo-uncaging in the presence of TTX. Apparent Erevs were relatively invariant across sites (mean CV ± SD = 0.04 ± 0.01; 7–20 sites in each of 10 neurons), which ranged between 100–800 µm from the somatic recording site. Thus, GM neurons are remarkably electrotonically compact (estimated λ > 1.5 mm). Electrotonically compact structures, in consort with graded transmission, provide an elegant solution to observed morphological variability in the STG.

STIM1 Protein Activates Store-Operated Calcium Channels in Cellular Model of Huntington’s Disease

We have shown that the expression of full-length mutated huntingtin in human neuroblastoma cells (SK-N-SH) leads to an abnormal increase in calcium entry through store-operated channels. In this paper, the expression of the N-terminal fragment of mutated huntingtin (Htt138Q-1exon) is shown to be enough to provide an actual model for Huntingtons disease. We have shown that Htt138Q-1exon expression causes increased store-operated calcium entry, which is mediated by at least two types of channels in SK-N-SH cells with different reversal potentials. Calcium sensor, STIM1, is required for activation of store-operated calcium entry in these cells. The results provide grounds for considering the proteins responsible for the activation and maintenance of the store-operated calcium entry as promising targets for developing novel therapeutics for neurodegenerative diseases.