Channel-independent function of UNC-9/Innexin in spatial arrangement of GABAergic synapses in C. elegans

Hendi, Ardalan; Niu, Long-Gang; Snow, Andrew William; Ikegami, Richard; Wang, Zhao-Wen; Mizumoto, Kota

doi:10.7554/elife.80555

Cited by 9 publications

(7 citation statements)

References 92 publications

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“…This is strengthened by evidence of gap junctions in ultrastructural EM-based analyses in both invertebrates ( Cook et al, 2019 ; Jarrell et al, 2012 ; White et al, 1986 ) and vertebrates ( Smedowski et al, 2020 ; Anderson et al, 2011 ), as well as expression studies showing cell type- and tissue-specific spatial patterns of innexin and connexin genes ( Bhattacharya et al, 2019 ). In addition, studies involving perturbations of innexins and connexins have shown diverse contributions of electrical synapses to neuronal function ( Hendi et al, 2022 ; Bhattacharya et al, 2019 ; Hall, 2017 ; Song et al, 2016 ; Meng et al, 2016 ; Kawano et al, 2011 ; Bloomfield and Völgyi, 2009 ; Yeh et al, 2009 ; Chuang et al, 2007 ).…”

Section: Resultsmentioning

confidence: 99%

“…For chemical synapses, these include reporters labeling pre- and post-synaptic proteins – such as SNB-1/VAMP, RAB-3, SYD-2/Liprin, CLA-1/Piccolo, and GLR-1/AMPAR – fused with a fluorescent protein ( Xuan et al, 2017 ; Mahoney et al, 2006 ; Yeh et al, 2005 ; Shen and Bargmann, 2003 ; Zhen and Jin, 1999 ; Nonet, 1999 ; Rongo et al, 1998 ; Jorgensen et al, 1995 ) and split-fluorophore transsynaptic technology such as GFP Reconstitution Across Synaptic Partners (GRASP) ( Feinberg et al, 2008 ) and other variants ( Feng et al, 2020 ; Feng et al, 2019 ), and Biotin Labeling of Intercellular Contacts (iBLINC) ( Desbois et al, 2015 ; Figure 1A ). In the case of electrical synapses, innexins can be endogenously tagged with fluorescent proteins to visualize homo- or heteromeric electrical synapses ( Hendi et al, 2022 ; Gordon et al, 2020 ; Bhattacharya et al, 2019 ; Figure 1A ). These tools have been somewhat constrained by the relative paucity of cell-specific promoters, but recent single-cell RNA-sequencing studies ( Taylor et al, 2021 ; Packer et al, 2019 ) have yielded novel cell-specific promoters for driving fluorescent proteins in neurons which previously lacked sparse-expressing genes.…”

Section: Introductionmentioning

confidence: 99%

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Toolkits for detailed and high-throughput interrogation of synapses in C. elegans

Majeed,

Han,

Zhang

et al. 2024

eLife

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Visualizing synaptic connectivity has traditionally relied on time-consuming electron microscopy-based imaging approaches. To scale the analysis of synaptic connectivity, fluorescent protein-based techniques have been established, ranging from the labeling of specific pre- or postsynaptic components of chemical or electrical synapses to transsynaptic proximity labeling technology such as GRASP and iBLINC. In this paper, we describe WormPsyQi, a generalizable image analysis pipeline that automatically quantifies synaptically localized fluorescent signals in a high-throughput and robust manner, with reduced human bias. We also present a resource of 30 transgenic strains that label chemical or electrical synapses throughout the nervous system of the nematode C. elegans, using CLA-1, RAB-3, GRASP (chemical synapses), or innexin (electrical synapse) reporters. We show that WormPsyQi captures synaptic structures in spite of substantial heterogeneity in neurite morphology, fluorescence signal, and imaging parameters. We use these toolkits to quantify multiple obvious and subtle features of synapses - such as number, size, intensity, and spatial distribution of synapses - in datasets spanning various regions of the nervous system, developmental stages, and sexes. Although the pipeline is described in the context of synapses, it may be utilized for other ‘punctate’ signals, such as fluorescently-tagged neurotransmitter receptors and cell adhesion molecules, as well as proteins in other subcellular contexts. By overcoming constraints on time, sample size, cell morphology, and phenotypic space, this work represents a powerful resource for further analysis of synapse biology in C. elegans.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Toolkits for detailed and high-throughput interrogation of synapses in C. elegans

Majeed,

Han,

Zhang

et al. 2024

eLife

View full text Add to dashboard Cite

show abstract

“…This is strengthened by evidence of gap junctions in ultrastructural EM-based analyses in both invertebrates (Cook et al, 2019; Jarrell et al, 2012; White et al, 1986) and vertebrates (Smedowski et al, 2020; Anderson et al, 2011), as well as expression studies showing cell type-specific and tissue-specific spatial patterns of innexin and connexin genes (Bhattacharya et al, 2019). In addition, studies involving perturbations of innexins and connexins have shown diverse contributions of electrical synapses to neuronal function (Hendi et al, 2022; Bhattacharya et al, 2019; Hall, 2017; Song et al, 2016; Meng et al, 2016; Kawano et al, 2011; Bloomfield and Völgyi, 2009; Yeh et al, 2009; Chuang et al, 2007).…”

Section: Resultsmentioning

confidence: 99%

“…For chemical synapses, these include reporters labeling pre- and post-synaptic proteins - such as SNB-1/VAMP, RAB-3, SYD-2/Liprin, CLA-1/Piccolo, GLR-1/AMPAR - fused with a fluorescent protein (Xuan et al, 2017; Mahoney et al, 2006; Yeh et al, 2005; Shen and Bargmann, 2003; Zhen and Jin, 1999; Nonet, 1999; Rongo et al, 1998; Jorgensen et al, 1995) and split-fluorophore transsynaptic technology such as GFP Reconstitution Across Synaptic Partners (GRASP) (Feinberg et al, 2008) and other variants (Feng et al, 2020; Feng et al, 2019), and Biotin Labeling of Intercellular Contacts (iBLINC) (Desbois et al, 2015) ( Figure 1A ). In the case of electrical synapses, innexins can be endogenously tagged with fluorescent proteins to visualize homomeric or heteromeric electrical synapses (Hendi et al, 2022; Gordon et al, 2020; Bhattacharya et al, 2019) ( Figure 1A ). These tools have been somewhat constrained by the relative paucity of cell-specific promoters, but recent single cell RNA-sequencing studies (Taylor et al 2021, Packer et al 2019) have yielded novel cell-specific promoters for driving fluorescent proteins in neurons which previously lacked sparse- expressing genes.…”

Section: Introductionmentioning

confidence: 99%

Toolkits for detailed and high-throughput interrogation of synapses inC. elegans

Majeed,

Han,

Zhang

et al. 2023

Preprint

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Visualizing synaptic connectivity has traditionally relied on time-consuming electron microscopy-based imaging approaches. To scale the analysis of synaptic connectivity, fluorescent protein-based techniques have been established, ranging from the labeling of specific pre- or postsynaptic components of chemical or electrical synapses to transsynaptic proximity labeling technology such as GRASP and iBLINC. In this paper, we describe WormPsyQi, a generalizable image analysis pipeline that automatically quantifies synaptically localized fluorescent signals in a high-throughput and robust manner, with reduced human bias. We also present a resource of 30 transgenic strains that label chemical or electrical synapses throughout the nervous system of the nematodeC. elegans, using CLA-1, RAB-3, GRASP (chemical synapses), or innexin (electrical synapse) reporters. We show that WormPsyQi captures synaptic structures in spite of substantial heterogeneity in neurite morphology, fluorescence signal, and imaging parameters. We use these toolkits to quantify multiple obvious and subtle features of synapses - such as number, size, intensity, and spatial distribution of synapses - in datasets spanning various regions of the nervous system, developmental stages, and sexes. Although the pipeline is described in the context of synapses, it may be utilized for other ‘punctate’ signals, such as fluorescently-tagged neurotransmitter receptors and cell adhesion molecules, as well as proteins in other subcellular contexts. By overcoming constraints on time, sample size, cell morphology, and phenotypic space, this work represents a powerful resource for further analysis of synapse biology inC. elegans.

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“…In C. elegans, loss of EGL-20/Wnt leads to axonal tiling defects in the DD5 and DD6 neurons, whereas presynaptic tiling is unaffected. However, when both EGL-20/Wnt and the gap junction protein UNC-9 are ablated, the synaptic tiling between these two neurons is lost [64].…”

Section: Wntsmentioning

confidence: 99%

Cellular and Molecular Mechanisms Underlying Synaptic Subcellular Specificity

Wang,

Fan,

Shao

2024

Brain Sciences

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Chemical synapses are essential for neuronal information storage and relay. The synaptic signal received or sent from spatially distinct subcellular compartments often generates different outcomes due to the distance or physical property difference. Therefore, the final output of postsynaptic neurons is determined not only by the type and intensity of synaptic inputs but also by the synaptic subcellular location. How synaptic subcellular specificity is determined has long been the focus of study in the neurodevelopment field. Genetic studies from invertebrates such as Caenorhabditis elegans (C. elegans) have uncovered important molecular and cellular mechanisms required for subcellular specificity. Interestingly, similar molecular mechanisms were found in the mammalian cerebellum, hippocampus, and cerebral cortex. This review summarizes the comprehensive advances in the cellular and molecular mechanisms underlying synaptic subcellular specificity, focusing on studies from C. elegans and rodents.

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Channel-independent function of UNC-9/Innexin in spatial arrangement of GABAergic synapses in C. elegans

Cited by 9 publications

References 92 publications

Toolkits for detailed and high-throughput interrogation of synapses in C. elegans

Toolkits for detailed and high-throughput interrogation of synapses in C. elegans

Toolkits for detailed and high-throughput interrogation of synapses inC. elegans

Cellular and Molecular Mechanisms Underlying Synaptic Subcellular Specificity

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