Eliav Tikochinsky scite author profile

Persistent alterations in neuronal activity elicit homeostatic plastic changes in synaptic transmission and/or intrinsic excitability. However, it is unknown whether these homeostatic processes operate in concert or at different temporal scales to maintain network activity around a set-point value. Here we show that chronic neuronal hyperactivity, induced by M-channel inhibition, triggered intrinsic and synaptic homeostatic plasticity at different timescales in cultured hippocampal pyramidal neurons from mice of either sex. Homeostatic changes of intrinsic excitability occurred at a fast timescale (1-4 h) and depended on ongoing spiking activity. This fast intrinsic adaptation included plastic changes in the threshold current and a distal relocation of FGF14, a protein physically bridging Na v 1.6 and K v 7.2 channels along the axon initial segment. In contrast, synaptic adaptations occurred at a slower timescale (;2 d) and involved decreases in miniature EPSC amplitude. To examine how these temporally distinct homeostatic responses influenced hippocampal network activity, we quantified the rate of spontaneous spiking measured by multielectrode arrays at extended timescales. M-Channel blockade triggered slow homeostatic renormalization of the mean firing rate (MFR), concomitantly accompanied by a slow synaptic adaptation. Thus, the fast intrinsic adaptation of excitatory neurons is not sufficient to account for the homeostatic normalization of the MFR. In striking contrast, homeostatic adaptations of intrinsic excitability and spontaneous MFR failed in hippocampal GABAergic inhibitory neurons, which remained hyperexcitable following chronic M-channel blockage. Our results indicate that a single perturbation such as M-channel inhibition triggers multiple homeostatic mechanisms that operate at different timescales to maintain network mean firing rate.

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CKII Control of Axonal Plasticity Is Mediated by Mitochondrial Ca2+ via Mitochondrial NCLX

Katoshevski

Bar

Tikochinsky

et al. 2022

Cells

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Mitochondrial Ca2+ efflux by NCLX is a critical rate-limiting step in mitochondria signaling. We previously showed that NCLX is phosphorylated at a putative Casein Kinase 2 (CKII) site, the serine 271 (S271). Here, we asked if NCLX is regulated by CKII and interrogated the physiological implications of this control. We found that CKII inhibitors down-regulated NCLX-dependent Ca2+ transport activity in SH-SY5Y neuronal cells and primary hippocampal neurons. Furthermore, we show that the CKII phosphomimetic mutants on NCLX inhibited (S271A) and constitutively activated (S271D) NCLX transport, respectively, rendering it insensitive to CKII inhibition. These phosphomimetic NCLX mutations also control the allosteric regulation of NCLX by mitochondrial membrane potential (ΔΨm). Since the omnipresent CKII is necessary for modulating the plasticity of the axon initial segment (AIS), we interrogated, in hippocampal neurons, if NCLX is required for this process. Similarly to WT neurons, NCLX-KO neurons can exhibit homeostatic plasticity following M-channel block. However, while WT neurons utilize a CKII-sensitive distal relocation of AIS Na+ and Kv7 channels to decrease their intrinsic excitability, we did not observe such translocation in NCLX-KO neurons. Thus, our results indicate that NCLX is regulated by CKII and is a crucial link between CKII signaling and fast neuronal plasticity.

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Contextual fear response is modulated by M-type K+ channels and is associated with subtle structural changes of the axon initial segment in hippocampal GABAergic neurons

Ruiz

Tikochinsky

Rubovitch

et al. 2023

AIMSN

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<abstract><sec> <title>Background</title> In the fear memory network, the hippocampus modulates contextual aspects of fear learning while mutual connections between the amygdala and the medial prefrontal cortex are widely involved in fear extinction. G-protein-coupled receptors (GPCRs) are involved in the regulation of fear and anxiety, so the regulation of GPCRs in fear signaling pathways can modulate the mechanisms of fear memory acquisition, consolidation and extinction. Various studies suggested a role of M-type K+ channels in modulating fear expression and extinction, although conflicting data prevented drawing of clear conclusions. In the present work, we examined the impact of M-type K+ channel blockade or activation on contextual fear acquisition and extinction. In addition, regarding the pivotal role of the hippocampus in contextual fear conditioning (CFC) and the involvement of the axon initial segment (AIS) in neuronal plasticity, we investigated whether structural alterations of the AIS in hippocampal neurons occurred during contextual fear memory acquisition and short-time extinction in mice in a behaviorally relevant context. </sec><sec> <title>Results</title> When a single systemic injection of the M-channel blocker XE991 (2 mg/kg, IP) was carried out 15 minutes before the foot shock session, fear expression was significantly reduced. Expression of c-Fos was increased following CFC, mostly in GABAergic neurons at day 1 and day 2 post-fear training in CA1 and dentate gyrus hippocampal regions. A significantly longer AIS segment was observed in GABAergic neurons of the CA1 hippocampal region at day 2. </sec><sec> <title>Conclusions</title> Our results underscore the role of M-type K + channels in CFC and the importance of hippocampal GABAergic neurons in fear expression. </sec></abstract>

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M-Current Inhibition in Hippocampal Neurons Triggers Intrinsic and Synaptic Homeostatic Responses at Different Temporal Scales

Attali

Lezmy

Katsenelson

et al. 2020

Biophysical Journal

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Robust electrical signal propagation in the form of action potentials (AP) is a hallmark of neuronal activity. While it is well established that changes to ionic gradients across the bilayer are responsible for AP propagation, the contributions of ionic diffusion and membrane morphological heterogeneity are not well understood. New experimental imaging methods have already suggested that spatial complexities of dendrites and the spatial dynamics of ionic species influence membrane voltage locally. However, it remains difficult to extract detailed voltage information at short time and length scales, which motivates a need for mathematical models that can incorporate these spatial complexities and predict and dissect voltage dynamics. Owing to the well-mixed assumption employed by popular models such as the Hodgkin-Huxley model, Morris-Lecar model, and cable theory the influence of morphology on voltage propagation cannot be studied. Therefore, building on these models, we construct a spatial model of AP propagation along dendrites which relaxes the well-mixed assumption. We explicitly model local ionic concentrations and their dynamics as influenced by reaction-diffusion and Hodgkin-Huxley type ion channel currents. The local transmembrane potential is determined by the local transmembrane ionic gradient via the Nernst potential. We compare membrane voltage dynamics from this new model to the traditional passive cable equation for dendrites of various sizes and configurations. Using our model, we find that a) membrane voltage propagation depends on the complex geometries of dendrites, b) the presence of internal organelles modulates membrane voltage propagation, and c) downstream signaling dynamics can affect AP propagation.

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