Brie Wamsley scite author profile

The proper construction of neural circuits requires the generation of diverse cell types, their distribution to defined regions, and their specific and appropriate wiring. A major objective in neurobiology has been to understand the molecular determinants that link neural birth to terminal specification and functional connectivity, a task that is especially daunting in the case of cortical interneurons. Considerable evidence supports the idea that an interplay of intrinsic and environmental signalling is crucial to the sequential steps of interneuron specification, including migration, selection of a settling position, morphogenesis and synaptogenesis. However, when and how these influences merge to support the appropriate terminal differentiation of different classes of interneurons remains uncertain. In this Review, we discuss a wealth of recent findings that have advanced our understanding of the developmental mechanisms that contribute to the diversification of interneurons and suggest areas of particular promise for further investigation.

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Rare coding variation provides insight into the genetic architecture and phenotypic context of autism

Satterstrom

et al. 2022

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Some individuals with autism spectrum disorder (ASD) carry functional mutations rarely observed in the general population. We explored the genes disrupted by these variants from joint analysis of protein-truncating (PTV), missense, and copy number variants (CNVs) in a cohort of 63,237 individuals. We discovered 72 ASD risk genes at false discovery rate (FDR)≤0.001 (185 at FDR≤0.05). De novo PTVs, damaging missense variants, and CNVs represented 57.5%, 21.1%, and 8.44% of association evidence, while CNVs conferred greatest relative risk. Meta-analysis with cohorts ascertained for developmental delay (DD, N=91,605) yielded 373 ASD/DD risk genes at FDR≤0.001 (664 at FDR≤0.05), some of which differed in relative frequency of mutation between ASD and DD. The DD-associated genes were enriched in transcriptomes of progenitor and immature neuronal cells whereas genes displaying stronger evidence in ASD were more enriched in maturing neurons and overlapped with schizophreniaassociated genes, emphasizing that these neuropsychiatric disorders share common pathways to risk.

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Early Somatostatin Interneuron Connectivity Mediates the Maturation of Deep Layer Cortical Circuits

Tuncdemir

Wamsley

Stam

et al. 2016

Neuron

191

190

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Summary The precise connectivity of somatostatin and parvalbumin cortical interneurons is generated during development. An understanding of how these interneuron classes incorporate into cortical circuitry is incomplete but essential to elucidate the roles they play during maturation. Here, we report that somatostatin interneurons in infragranular layers receive dense but transient innervation from thalamocortical afferents during the first postnatal week. During this period, parvalbumin interneurons and pyramidal neurons within the same layers receive weaker thalamocortical inputs; yet are strongly innervated by somatostatin interneurons. Further, upon disruption of the early (but not late) somatostatin interneuron network, the synaptic maturation of thalamocortical inputs onto parvalbumin interneurons is arrested. These results suggest that infragranular somatostatin interneurons exhibit a transient early synaptic connectivity that is essential for the establishment of thalamic feed-forward inhibition mediated by parvalbumin interneurons.

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Translational profiling of hypocretin neurons identifies candidate molecules for sleep regulation

et al. 2013

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Hypocretin (orexin; Hcrt)-containing neurons of the hypothalamus are essential for the normal regulation of sleep and wake behaviors and have been implicated in feeding, anxiety, depression, and reward. The absence of these neurons causes narcolepsy in humans and model organisms. However, little is known about the molecular phenotype of these cells; previous attempts at comprehensive profiling had only limited sensitivity or were inaccurate. We generated a Hcrt translating ribosome affinity purification (bacTRAP) line for comprehensive translational profiling of all ribosome-bound transcripts in these neurons in vivo. From this profile, we identified >6000 transcripts detectably expressed above background and 188 transcripts that are highly enriched in these neurons, including all known markers of the cells. Blinded analysis of in situ hybridization databases suggests that 60% of these are expressed in a Hcrt marker-like pattern. Fifteen of these were confirmed with double labeling and microscopy, including the transcription factor Lhx9. Ablation of this gene results in a >30% loss specifically of Hcrt neurons, without a general disruption of hypothalamic development. Polysomnography and activity monitoring revealed a profound hypersomnolence in these mice. These data provide an in-depth and accurate profile of Hcrt neuron gene expression and suggest that Lhx9 may be important for specification or survival of a subset of these cells.[Keywords: translational profiling; hypocretin; orexin; bacTRAP; Lhx9; narcolepsy] Supplemental material is available for this article. Narcolepsy is a profound disorder of sleep regulation, characterized by excessive daytime sleepiness, sleep attacks, cataplexy, and sleep-onset REM (rapid eye movement) periods. Studies indicate that narcolepsy, especially when accompanied by cataplexy, is due to the absence of hypocretinergic neurons and signaling (Nishino et al. 2000;Thannickal et al. 2000;Bourgin et al. 2008). The hypocretins (Hcrts; also called orexins) are peptidergic neurotransmitters used by a discrete population of neurons in the lateral hypothalamus Sakurai et al. 1998). In model organisms, disruption of the gene encoding the Hcrt peptides or a Hcrt receptor (Chemelli et al. 1999;Lin et al. 1999) or, alternatively, the ablation of the neurons producing Hcrt (Gerashchenko et al. 2001;Hara et al. 2001;Zhang et al. 2007) recapitulates features of narcolepsy. In humans, there are two variations of the disorder: narcolepsy with cataplexy (NC) and narcolepsy without cataplexy (NwoC). NC is strongly linked and associated with the HLA DQB1*0602 allele, a T-cell receptor locus, and P2RY11, a receptor that can regulate immune cell survival (Hallmayer et al. 2009;Kornum et al. 2011). This strongly suggests involvement of the immune system in the etiology of NC, while the involvement in NwoC is less clear. Cold Spring Harbor Laboratory Press on May 13, 2018 -Published by genesdev.cshlp.org Downloaded from

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Broad transcriptomic dysregulation occurs across the cerebral cortex in ASD

Gandal

Haney

Wamsley

et al. 2022

Nature

127

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Neuropsychiatric disorders classically lack defining brain pathologies, but recent work has demonstrated dysregulation at the molecular level, characterized by transcriptomic and epigenetic alterations1–3. In autism spectrum disorder (ASD), this molecular pathology involves the upregulation of microglial, astrocyte and neural–immune genes, the downregulation of synaptic genes, and attenuation of gene-expression gradients in cortex1,2,4–6. However, whether these changes are limited to cortical association regions or are more widespread remains unknown. To address this issue, we performed RNA-sequencing analysis of 725 brain samples spanning 11 cortical areas from 112 post-mortem samples from individuals with ASD and neurotypical controls. We find widespread transcriptomic changes across the cortex in ASD, exhibiting an anterior-to-posterior gradient, with the greatest differences in primary visual cortex, coincident with an attenuation of the typical transcriptomic differences between cortical regions. Single-nucleus RNA-sequencing and methylation profiling demonstrate that this robust molecular signature reflects changes in cell-type-specific gene expression, particularly affecting excitatory neurons and glia. Both rare and common ASD-associated genetic variation converge within a downregulated co-expression module involving synaptic signalling, and common variation alone is enriched within a module of upregulated protein chaperone genes. These results highlight widespread molecular changes across the cerebral cortex in ASD, extending beyond association cortex to broadly involve primary sensory regions.

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Brie Wamsley

Genetic and activity-dependent mechanisms underlying interneuron diversity

Rare coding variation provides insight into the genetic architecture and phenotypic context of autism

Early Somatostatin Interneuron Connectivity Mediates the Maturation of Deep Layer Cortical Circuits

Translational profiling of hypocretin neurons identifies candidate molecules for sleep regulation

Broad transcriptomic dysregulation occurs across the cerebral cortex in ASD

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