Moran Rubinstein scite author profile

G protein activated K+ channels (GIRK, Kir3) are switched on by direct binding of Gβγ following activation of G i/o proteins via G protein-coupled receptors (GPCRs). Although Gα i subunits do not activate GIRKs, they interact with the channels and regulate the gating pattern of the neuronal heterotetrameric GIRK1/2 channel (composed of GIRK1 and GIRK2 subunits) expressed in Xenopus oocytes. Coexpressed Gα i3 decreases the basal activity (I basal ) and increases the extent of activation by purified or coexpressed Gβγ. Here we show that this regulation is exerted by the 'inactive' GDP-bound Gα i3 GDP and involves the formation of Gα i3 βγ heterotrimers, by a mechanism distinct from mere sequestration of Gβγ 'away' from the channel. The regulation of basal and Gβγ-evoked current was produced by the 'constitutively inactive' mutant of Gα i3 , Gα i3 G203A, which strongly binds Gβγ, but not by the 'constitutively active' mutant, Gα i3 Q204L, or by Gβγ-scavenging proteins. Furthermore, regulation by Gα i3 G203A was unique to the GIRK1 subunit; it was not observed in homomeric GIRK2 channels. In vitro protein interaction experiments showed that purified Gβγ enhanced the binding of Gα i3 GDP to the cytosolic domain of GIRK1, but not GIRK2. Homomeric GIRK2 channels behaved as a 'classical' Gβγ effector, showing low I basal and strong Gβγ-dependent activation. Expression of Gα i3 G203A did not affect either I basal or Gβγ-induced activation. In contrast, homomeric GIRK1 * (a pore mutant able to form functional homomeric channels) exhibited large I basal and was poorly activated by Gβγ. Expression of Gα i3 GDP reduced I basal and restored the ability of Gβγ to activate GIRK1 * , like in GIRK1/2. Transferring the unique distal segment of the C terminus of GIRK1 to GIRK2 rendered the latter functionally similar to GIRK1 * . These results demonstrate that GIRK1 containing channels are regulated by both Gα i3 GDP and Gβγ, while GIRK2 is a Gβγ-effector insensitive to Gα i3 GDP .

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Dissecting the phenotypes of Dravet syndrome by gene deletion

Rubinstein

Han

Tai

et al. 2015

Brain

113

134

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*These authors contributed equally to this work.Neurological and psychiatric syndromes often have multiple disease traits, yet it is unknown how such multi-faceted deficits arise from single mutations. Haploinsufficiency of the voltage-gated sodium channel Na v 1.1 causes Dravet syndrome, an intractable childhood-onset epilepsy with hyperactivity, cognitive deficit, autistic-like behaviours, and premature death. Deletion of Na v 1.1 channels selectively impairs excitability of GABAergic interneurons. We studied mice having selective deletion of Na v 1.1 in parvalbumin-or somatostatin-expressing interneurons. In brain slices, these deletions cause increased threshold for action potential generation, impaired action potential firing in trains, and reduced amplification of postsynaptic potentials in those interneurons. Selective deletion of Na v 1.1 in parvalbumin-or somatostatin-expressing interneurons increases susceptibility to thermally-induced seizures, which are strikingly prolonged when Na v 1.1 is deleted in both interneuron types. Mice with global haploinsufficiency of Na v 1.1 display autistic-like behaviours, hyperactivity and cognitive impairment. Haploinsufficiency of Na v 1.1 in parvalbuminexpressing interneurons causes autistic-like behaviours, but not hyperactivity, whereas haploinsufficiency in somatostatin-expressing interneurons causes hyperactivity without autistic-like behaviours. Heterozygous deletion in both interneuron types is required to impair long-term spatial memory in context-dependent fear conditioning, without affecting short-term spatial learning or memory. Thus, the multi-faceted phenotypes of Dravet syndrome can be genetically dissected, revealing synergy in causing epilepsy, premature death and deficits in long-term spatial memory, but interneuron-specific effects on hyperactivity and autistic-like behaviours. These results show that multiple disease traits can arise from similar functional deficits in specific interneuron types.

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Genetic background modulates impaired excitability of inhibitory neurons in a mouse model of Dravet syndrome

Rubinstein¹,

Westenbroek²,

Yu³

et al. 2015

Neurobiology of Disease

119

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Dominant loss-of-function mutations in voltage-gated sodium channel NaV1.1 cause Dravet Syndrome, an intractable childhood-onset epilepsy. NaV1.1+/− Dravet Syndrome mice in C57BL/6 genetic background exhibit severe seizures, cognitive and social impairments, and premature death. Here we show that Dravet Syndrome mice in pure 129/SvJ genetic background have many fewer seizures and much less premature death than in pure C57BL/6 background. These mice also have a higher threshold for thermally induced seizures, fewer myoclonic seizures, and no cognitive impairment, similar to patients with Genetic Epilepsy with Febrile Seizures Plus. Consistent with this mild phenotype, mutation of NaV1.1 channels has much less physiological effect on neuronal excitability in 129/SvJ mice. In hippocampal slices, the excitability of CA1 Stratum Oriens interneurons is selectively impaired, while the excitability of CA1 pyramidal cells is unaffected. NaV1.1 haploinsufficiency results in increased rheobase and threshold for action potential firing and impaired ability to sustain high-frequency firing. Moreover, deletion of NaV1.1 markedly reduces the amplification and integration of synaptic events, further contributing to reduced excitability of interneurons. Excitability is less impaired in inhibitory neurons of Dravet Syndrome mice in 129/SvJ genetic background. Because specific deletion of NaV1.1 in forebrain GABAergic interneuons is sufficient to cause the symptoms of Dravet Syndrome in mice, our results support the conclusion that the milder phenotype in 129/SvJ mice is caused by lesser impairment of sodium channel function and electrical excitability in their forebrain interneurons. This mild impairment of excitability of interneurons leads to a milder disease phenotype in 129/SvJ mice, similar to Genetic Epilepsy with Febrile Seizures Plus in humans.

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Mitochondrial Regulation of the Hippocampal Firing Rate Set Point and Seizure Susceptibility

Styr

Gonen

Zarhin

et al. 2019

Neuron

113

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Summary Maintaining average activity within a set-point range constitutes a fundamental property of central neural circuits. However, whether and how activity set points are regulated remains unknown. Integrating genome-scale metabolic modeling and experimental study of neuronal homeostasis, we identified mitochondrial dihydroorotate dehydrogenase (DHODH) as a regulator of activity set points in hippocampal networks. The DHODH inhibitor teriflunomide stably suppressed mean firing rates via synaptic and intrinsic excitability mechanisms by modulating mitochondrial Ca 2+ buffering and spare respiratory capacity. Bi-directional activity perturbations under DHODH blockade triggered firing rate compensation, while stabilizing firing to the lower level, indicating a change in the firing rate set point. In vivo , teriflunomide decreased CA3-CA1 synaptic transmission and CA1 mean firing rate and attenuated susceptibility to seizures, even in the intractable Dravet syndrome epilepsy model. Our results uncover mitochondria as a key regulator of activity set points, demonstrate the differential regulation of set points and compensatory mechanisms, and propose a new strategy to treat epilepsy.

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Gα_i3 primes the G protein‐activated K⁺ channels for activation by coexpressed Gβγ in intact Xenopus oocytes

Rubinstein

Peleg

Berlin

et al. 2007

The Journal of Physiology

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G protein-activated K + channels (GIRK) mediate postsynaptic inhibitory effects of neurotransmitters in the atrium and in the brain by coupling to G protein-coupled receptors (GPCRs). In neurotransmitter-dependent GIRK signalling, Gβγ is released from the heterotrimeric Gαβγ complex upon GPCR activation, activating the channel and attenuating its rectification. Now it becomes clear that Gα is more than a mere Gβγ donor. We have proposed that Gα i3 -GDP regulates GIRK gating, keeping its basal activity low but priming (predisposing) the channel for activation by agonist in intact cells, and by Gβγ in excised patches. Here we have further investigated GIRK priming by Gα i3 using a model in which the channel was activated by coexpression of Gβγ, and the currents were measured in intact Xenopus oocytes using the two-electrode voltage clamp technique. This method enables the bypass of GPCR activation during examination of the regulation of the channel in intact cells. Using this method, we further characterize the priming phenomenon. We tested and excluded the possibility that our estimates of priming are affected by artifacts caused by series resistance or large K + fluxes. We demonstrate that both Gα i3 and membrane-attached Gβγ scavenger protein, m-phosducin, reduce the basal channel activity. However, Gα i3 allows robust channel activation by coexpressed Gβγ, in sharp contrast to m-phosducin, which causes a substantial reduction in the total Gβγ-induced current. Furthermore, Gα i3 also does not impair the Gβγ-dependent attenuation of the channel rectification, in contrast to m-phosducin, which prevents this Gβγ-induced modulation. The Gα i3 -induced enhancement of direct activation of GIRK by Gβγ, demonstrated here for the first time in intact cells, strongly supports the hypothesis that Gα i regulates GIRK gating under physiological conditions.

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Developmental alterations in firing properties of hippocampal CA1 inhibitory and excitatory neurons in a mouse model of Dravet syndrome

Almog

Fadila

Brusel

et al. 2021

Neurobiology of Disease

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Prevention of potential errors in resuscitation medications orders by means of a computerised physician order entry in paediatric critical care

et al. 2007

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Reciprocal Changes in Phosphorylation and Methylation of Mammalian Brain Sodium Channels in Response to Seizures

Baek

Rubinstein

Scheuer

et al. 2014

Journal of Biological Chemistry

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Background: Sodium channels underlie neuronal excitability and are regulated by seizures. Results: Mass spectrometric analysis of brain sodium channels revealed novel phosphorylation and methylation sites that decreased and increased, respectively, after seizures. Inducing methylation increased sodium channel activity. Conclusion: Reciprocal phosphorylation and methylation after seizures will alter sodium channel function. Significance: Such regulation would impact neuronal excitability.

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