Optogenetic inhibition of the electrical activity of neurons enables the causal assessment of their contributions to brain functions. Red light penetrates deeper into tissue than other visible wavelengths. We present a red-shifted cruxhalorhodopsin, Jaws, derived from Haloarcula (Halobacterium) salinarum (strain Shark) and engineered to result in red light–induced photocurrents three times those of earlier silencers. Jaws exhibits robust inhibition of sensory-evoked neural activity in the cortex and results in strong light responses when used in retinas of retinitis pigmentosa model mice. We also demonstrate that Jaws can noninvasively mediate transcranial optical inhibition of neurons deep in the brains of awake mice. The noninvasive optogenetic inhibition opened up by Jaws enables a variety of important neuroscience experiments and offers a powerful general-use chloride pump for basic and applied neuroscience.
Although failure of GABAergic inhibition is a commonly hypothesized mechanism underlying seizure disorders, the series of events that precipitate a rapid shift from healthy to ictal activity remain unclear. Furthermore, the diversity of inhibitory interneuron populations poses a challenge for understanding local circuit interactions during seizure initiation. Using a combined optogenetic and electrophysiological approach, we examined the activity of identified mouse hippocampal interneuron classes during chemoconvulsant seizure induction in vivo. Surprisingly, synaptic inhibition from parvalbumin- (PV) and somatostatin-expressing (SST) interneurons remained intact throughout the preictal period and early ictal phase. However, these two sources of inhibition exhibited cell-type-specific differences in their preictal firing patterns and sensitivity to input. Our findings suggest that the onset of ictal activity is not associated with loss of firing by these interneurons or a failure of synaptic inhibition but is instead linked with disruptions of the respective roles these interneurons play in the hippocampal circuit.
23Although failure of GABAergic inhibition is a commonly hypothesized mechanism underlying 24 seizure disorders, the series of events that precipitate a rapid shift from healthy to ictal activity 25 remain unclear. Furthermore, the diversity of inhibitory interneuron populations poses a 26 challenge for understanding local circuit interactions during seizure initiation. Using a combined 27 optogenetic and electrophysiological approach, we examined the activity of two identified 28 hippocampal interneuron classes during seizure induction in vivo. We identified cell type-29 specific differences in preictal firing patterns and input sensitivity of parvalbumin-and 30 somatostatin-expressing interneurons. Surprisingly, the impact of both sources of inhibition 31 remained intact throughout the preictal period and into the early ictal phase. Our findings 32 suggest that the onset of ictal activity is not due to a failure of inhibition, but is instead 33 associated with a decoupling of inhibitory cells from their normal relationship with the local 34 hippocampal network. 35 36
If CD4 T-cell count testing is available, a pre-highly active antiretroviral therapy urinary LAM test has no added value to predict TB-IRIS. When CD4 T-cell count is not available, a positive LAM test could identify patients at increased risk of TB-IRIS.
The NMDAR subunit NR3A is most highly expressed during the second postnatal week, when synaptogenesis reaches peak levels. Genetic ablation or overexpression of the NR3A subunit negatively interferes with the maturation of cortical synapses and leads to changes in the shape and number of dendritic spines, the density of which is increased in NR3A knock-out mice and decreased in NR3A-overexpressing transgenic mice. Alterations in spine density have been linked to dysregulation of mTOR signaling and synaptic protein translation. Using a yeast two-hybrid system, we identified the mTOR-activating GTPase Rheb as an interacting protein of the NMDAR subunit NR3A. We confirmed the interaction in mammalian cells by expressing recombinant Rheb and NR3A and showed that Rheb and NR3A could be co-immunoprecipitated from synaptic plasma membranes from the developing rat brain. These data suggest that NR3A sequesters synaptic Rheb and might thus function as a break of the mTOR-dependent synaptic translation of protein.
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