Ningning Hu scite author profile

Adenosine-to-inosine (A-to-I) editing of RNA transcripts is an increasingly recognized cellular strategy to modulate the function of proteins involved in neuronal excitability. We have characterized the editing of transcripts encoding the ␣3 subunit of heteromeric GABA A receptors (Gabra3), in which a genomically encoded isoleucine codon (ATA) is converted to a methionine codon (ATI) in a region encoding the predicted third transmembrane domain of this subunit. Editing at this position (I/M site) was regulated in a spatiotemporal manner with ϳ90% of the Gabra3 transcripts edited in most regions of adult mouse brain, but with lower levels of editing in the hippocampus. Editing was low in whole-mouse brain at embryonic day 15 and increased during development, reaching maximal levels by postnatal day 7. GABA-evoked current in transfected cells expressing nonedited ␣3(I)␤3␥2L GABA A receptors activated more rapidly and deactivated much more slowly than edited ␣3(M)␤3␥2L receptors. Furthermore, currents from nonedited ␣3(I)␤3␥2L receptors were strongly outwardly rectifying (corresponding to chloride ion influx), whereas currents from edited ␣3(M)␤3␥2L receptors had a more linear current/voltage relationship. These studies suggest that increased expression of the nonedited ␣3(I) subunit during brain development, when GABA is depolarizing, may allow the robust excitatory responses that are critical for normal synapse formation. However, the strong chloride ion influx conducted by receptors containing the nonedited ␣3(I) subunit could act as a shunt to prevent excessive excitation, providing the delicate balance necessary for normal neuronal development.

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De novo GABRG2mutations associated with epileptic encephalopathies

Shen

Hernández

Shen

et al. 2016

Brain

104

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Epileptic encephalopathies are a devastating group of severe childhood onset epilepsies with medication-resistant seizures and poor developmental outcomes. Many epileptic encephalopathies have a genetic aetiology and are often associated with de novo mutations in genes mediating synaptic transmission, including GABA receptor subunit genes. Recently, we performed next generation sequencing on patients with a spectrum of epileptic encephalopathy phenotypes, and we identified five novel (A106T, I107T, P282S, R323W and F343L) and one known (R323Q) de novo GABRG2 pathogenic variants (mutations) in eight patients. To gain insight into the molecular basis for how these mutations contribute to epileptic encephalopathies, we compared the effects of the mutations on the properties of recombinant α1β2γ2L GABA receptors transiently expressed in HEK293T cells. Using a combination of patch clamp recording, immunoblotting, confocal imaging and structural modelling, we characterized the effects of these GABRG2 mutations on GABA receptor biogenesis and channel function. Compared with wild-type α1β2γ2L receptors, GABA receptors containing a mutant γ2 subunit had reduced cell surface expression with altered subunit stoichiometry or decreased GABA-evoked whole-cell current amplitudes, but with different levels of reduction. While a causal role of these mutations cannot be established directly from these results, the functional analysis together with the genetic information suggests that these GABRG2 variants may be major contributors to the epileptic encephalopathy phenotypes. Our study further expands the GABRG2 phenotypic spectrum and supports growing evidence that defects in GABAergic neurotransmission participate in the pathogenesis of genetic epilepsies including epileptic encephalopathies.

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Functional Effects of Protein Kinase C Activation on the Human Cardiac Na sup + Channel

Murray

Daw

et al. 1997

Circulation Research

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The cardiac Na+ current plays an important role in determining normal and abnormal impulse propagation in the heart. We have investigated the effects of protein kinase C (PKC) activation on the recombinant human cardiac Na+ channel (hH1) following heterologous expression in Xenopus laevis oocytes. Phorbol 12-myristate 13-acetate (PMA), which directly activates PKC, reduced current amplitude at all test potentials (43 +/- 12% at -10 mV). In contrast to the rat brain IIA (rBIIA) channel, there was no apparent change in either macroscopic Na+ current decay or the voltage dependence of channel gating. Further experiments indicate that the effects of PMA were mediated by PKC activation: (1) an inactive stereoisomer, 4 alpha-PMA, had no effect; (2) preincubation with the protein kinase inhibitor chelerythrine prevented the PMA effects; and (3) a hydrolyzable diacylglycerol analogue, 1-oleoyl-2-acetyl-glycerol, also reduced current (22 +/- 5%). In addition, when the alpha 1B-adrenergic receptor was coexpressed with hH1, the alpha-receptor agonist methoxamine reduced hH1 current (45 +/- 10%), an effect that could be eliminated by chelerythrine preincubation. When a conserved consensus PKC site (serine 1503) in the III-IV interdomain linker thought to be responsible for the PKC effects on rBIIA was mutated, PMA still reduced Na+ current, but the magnitude of the effect was smaller compared with that for the wild-type channel. Similar findings were obtained with alpha 1-receptor stimulation following receptor coexpression with the mutant channel. We conclude that activation of PKC modulates the human cardiac Na+ channel by at least two mechanisms, one similar to that seen with rat brain channels, involving a conserved putative PKC site, and a second more specific to the cardiac isoform.

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Epileptic encephalopathy de novo GABRB mutations impair γ‐aminobutyric acid type A receptor function

Janve

Hernández

Verdier

et al. 2016

Annals of Neurology

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Objective The Epi4K consortium recently identified four de novo mutations in the γ-aminobutyric acid type A (GABAA) receptor β3 subunit gene GABRB3 and one in the β1 subunit gene GABRB1 in children with epileptic encephalopathies (EEs) Lennox-Gastaut syndrome (LGS) or infantile spasms (IS). Since the etiology of EEs is often unknown, we determined the impact of GABRB mutations on GABAA receptor function and biogenesis. Methods GABAA receptor α1 and γ2L subunits were co-expressed with wild-type and/or mutant β3 or β1 subunits in HEK 293T cells. Currents were measured using whole cell and single channel patch clamp techniques. Surface and total expression levels were measured using flow cytometry. Potential structural perturbations in mutant GABAA receptors were explored using structural modeling. Results LGS-associated GABRB3(D120N, E180G, Y302C) mutations located at β+ subunit interfaces reduced whole cell currents by decreasing single channel open probability without loss of surface receptors. In contrast, IS-associated GABRB3(N110D) and GABRB1(F246S) mutations at β-subunit interfaces produced minor changes in whole cell current peak amplitude but altered current deactivation by decreasing or increasing single channel burst duration, respectively. GABRB3(E180G) and GABRB1(F246S) mutations also produced spontaneous channel openings. Interpretation All five de novo GABRB mutations impaired GABAA receptor function by rearranging conserved structural domains, supporting their role in EEs. The primary effect of LGS-associated mutations was reduced GABA-evoked peak current amplitudes while the major impact of IS-associated mutations was on current kinetic properties. Despite lack of association with epilepsy syndromes, our results suggest GABRB1 as a candidate human epilepsy gene.

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Ningning Hu

Locating Internet Bottlenecks: Algorithms, Measurements, and Implications

Developmental Modulation of GABAA Receptor Function by RNA Editing

De novo GABRG2mutations associated with epileptic encephalopathies

Functional Effects of Protein Kinase C Activation on the Human Cardiac Na sup + Channel

Epileptic encephalopathy de novo GABRB mutations impair γ‐aminobutyric acid type A receptor function

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