Mechanisms Underlying Target Selectivity for Cell Types and Subcellular Domains in Developing Neocortical Circuits

Gutman-Wei, Alan Y.; Brown, Solange P.

doi:10.3389/fncir.2021.728832

Cited by 6 publications

(8 citation statements)

References 246 publications

(383 reference statements)

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“…Thus, we could not identify a specific set of neuronal subtypes that may be uniquely vulnerable in autism. In summary, we identified circuit-related genes that are conserved between ALM and VISp for each neuronal subclass and may act as molecular mechanisms underlying stereotyped “canonical circuits” found across the cortex (Kubota, 2014;Harris and Shepherd, 2015b;Gutman-Wei and Brown, 2021). Furthermore, many of them are candidates to disrupt the balance between excitation and inhibition throughout the cortex in developmental disorders (Sohal and Rubenstein, 2019).…”

Section: Resultsmentioning

confidence: 95%

“…There is evidence of cell-types forming local synaptic connections according to their subclass identity (Harris and Shepherd, 2015;Ye et al, 2015;Wester et al, 2019). A prominent example is that across diverse cortical regions, intratelencephalic projection neurons preferentially form local synapses onto pyramidal tract projection neurons (Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021). Among interneurons, stereotyped connections between pre- and post-synaptic cell-types have also been revealed (Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…A prominent example is that across diverse cortical regions, intratelencephalic projection neurons preferentially form local synapses onto pyramidal tract projection neurons (Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021). Among interneurons, stereotyped connections between pre- and post-synaptic cell-types have also been revealed (Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021). In addition to cell-type biased connections, there is evidence of neuronal subclasses preferentially targeting specific subdomains on post-synaptic cells and exhibiting unique synaptic properties dependent on their partner’s identity (Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…Among interneurons, stereotyped connections between pre- and post-synaptic cell-types have also been revealed (Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021). In addition to cell-type biased connections, there is evidence of neuronal subclasses preferentially targeting specific subdomains on post-synaptic cells and exhibiting unique synaptic properties dependent on their partner’s identity (Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021). Together, these findings suggest molecular mechanisms for synaptic targeting and maintenance that are conserved within subclasses.…”

Section: Introductionmentioning

confidence: 99%

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Cell-type specific transcriptomic signatures of neocortical circuit organization and their relevance to autism

Moussa

Wester

2022

Preprint

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A prevailing challenge in neuroscience is understanding how diverse neuronal cell types select their synaptic partners to form circuits. In the neocortex, major subclasses of excitatory projection neurons and inhibitory interneurons are conserved across functionally distinct regions. There is evidence these subclasses form circuits that depend primarily on their identity; however, regional cues likely also influence their choice of synaptic partners. We mined the Allen Brain Institute's single-cell RNA-sequencing database of mouse cortical neurons to study the expression of cellular adhesion molecules (CAMs) necessary for synapse formation in two regions: the anterior lateral motor cortex (ALM) and the primary visual cortex (VISp). We used the Allen's metadata to parse cells by clusters representing major excitatory and inhibitory subclasses that are common to both ALM and VISp. We then performed two types of pairwise differential gene expression analysis: 1) between different neuronal subclasses within the same brain region (ALM or VISp), and 2) between the same neuronal subclass in ALM and VISp. We filtered our results for differentially expressed genes encoding CAMs and developed a novel bioinformatic approach to determine the sets uniquely enriched in each neuronal subclass in ALM, VISp, or both. This analysis provides an organized set of genes that may regulate circuit formation in a cell-type specific manner. Furthermore, it identifies candidate mechanisms for the formation of circuits that are conserved across functionally distinct cortical regions or that are region dependent. Finally, we used the SFARI Human Gene Module to identify CAMs from our analysis that are related to risk for autism spectrum disorder (ASD). From over 3,000 differentially expressed genes, we found 40 ASD-associated CAMs that are enriched in specific neuronal subclasses in both ALM and VISp. Our analysis provides clear molecular targets for future studies to understand neocortical circuit organization and abnormalities that underly autistic phenotypes.

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Section: Resultsmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Cell-type specific transcriptomic signatures of neocortical circuit organization and their relevance to autism

Moussa

Wester

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…Thus, we could not identify a specific set of neuronal classes that may be uniquely vulnerable in autism. In summary, we identified circuit-related genes that are conserved between ALM and VISp for each neuronal class and may mediate molecular mechanisms underlying stereotyped "canonical circuits" found across the cortex (Kubota, 2014;Harris and Shepherd, 2015;Gutman-Wei and Brown, 2021). Furthermore, many of them are candidates to disrupt the balance between excitation and inhibition throughout the cortex in developmental disorders (Sohal and Rubenstein, 2019).…”

Section: Most Circuit-related Genes Identified As Conserved Are Class...mentioning

confidence: 95%

Cell-type specific transcriptomic signatures of neocortical circuit organization and their relevance to autism

Moussa

Wester²

2022

Front. Neural Circuits

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A prevailing challenge in neuroscience is understanding how diverse neuronal cell types select their synaptic partners to form circuits. In the neocortex, major classes of excitatory projection neurons and inhibitory interneurons are conserved across functionally distinct regions. There is evidence these classes form canonical circuit motifs that depend primarily on their identity; however, regional cues likely also influence their choice of synaptic partners. We mined the Allen Institute’s single-cell RNA-sequencing database of mouse cortical neurons to study the expression of genes necessary for synaptic connectivity and physiology in two regions: the anterior lateral motor cortex (ALM) and the primary visual cortex (VISp). We used the Allen’s metadata to parse cells by clusters representing major excitatory and inhibitory classes that are common to both ALM and VISp. We then performed two types of pairwise differential gene expression analysis: (1) between different neuronal classes within the same brain region (ALM or VISp), and (2) between the same neuronal class in ALM and VISp. We filtered our results for differentially expressed genes related to circuit connectivity and developed a novel bioinformatic approach to determine the sets uniquely enriched in each neuronal class in ALM, VISp, or both. This analysis provides an organized set of genes that may regulate synaptic connectivity and physiology in a cell-type-specific manner. Furthermore, it identifies candidate mechanisms for circuit organization that are conserved across functionally distinct cortical regions or that are region dependent. Finally, we used the SFARI Human Gene Module to identify genes from this analysis that are related to risk for autism spectrum disorder (ASD). Our analysis provides clear molecular targets for future studies to understand neocortical circuit organization and abnormalities that underlie autistic phenotypes.

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Ephrin-mediated dendrite-dendrite repulsion regulates compartment-specific targeting of dendrites in the central nervous system

Deng,

Zhu

2024

Preprint

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Neurons often forms synaptic contacts at specific subcellular domains to differentially regulate the activity of target neurons. However, how dendrites are targeted to specific subcellular domains of axons is rarely studied. Here we use Drosophila mushroom body out neurons (MBONs) and local dopaminergic neurons (DANs) as a model system to study how dendrites and axons are targeted to specific subcellular domains (compartments) of mushroom body axonal lobes to form synaptic contacts. We found that Ephrin-mediated dendrite- dendrite repulsion between neighboring compartments restricts the projection of MBON dendrites to their specific compartments and prevents the formation of ectopic synaptic connections with DAN axons in neighboring compartments. Meanwhile, DAN neurons in a subset of compartments may also depend on their partner MBONs for projecting their axons to a specific compartment and cover the same territory as their partner MBON dendrites. Our work reveals that compartment-specific targeting of MBON dendrites and DAN axons is regulated in part by a combination of dendrite-dendrite repulsion between neighboring compartments and dendrite-axon interactions within the same compartment.

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Mechanisms Underlying Target Selectivity for Cell Types and Subcellular Domains in Developing Neocortical Circuits

Cited by 6 publications

References 246 publications

Cell-type specific transcriptomic signatures of neocortical circuit organization and their relevance to autism

Cell-type specific transcriptomic signatures of neocortical circuit organization and their relevance to autism

Cell-type specific transcriptomic signatures of neocortical circuit organization and their relevance to autism

Ephrin-mediated dendrite-dendrite repulsion regulates compartment-specific targeting of dendrites in the central nervous system

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