Frank Koopmans scite author profile

Graphical Abstract Highlights d SynGO is a public knowledge base and online analysis platform for synapse research d SynGO has annotated 1,112 genes with synaptic localization and/or function d SynGO genes are exceptionally large, well conserved, and intolerant to mutations d SynGO genes are strongly enriched among genes associated with brain disorders Correspondence guus.smit@cncr.vu.nl (A.B.S.), matthijs@cncr.vu.nl (M.V.) In BriefThe SynGO consortium presents a framework to annotate synaptic protein locations and functions and annotations for 1,112 synaptic genes based on published experimental evidence. SynGO reports exceptional features and disease associations for synaptic genes and provides an online data analysis platform. SUMMARYSynapses are fundamental information-processing units of the brain, and synaptic dysregulation is central to many brain disorders (''synaptopathies''). However, systematic annotation of synaptic genes and ontology of synaptic processes are currently lacking. We established SynGO, an interactive knowledge base that accumulates available research about synapse biology using Gene Ontology (GO) annotations to novel ontology terms: 87 synaptic locations and 179 synaptic processes. SynGO annotations are exclusively based on published, expert-curated evidence. Using 2,922 annotations for 1,112 genes, we show that synaptic genes are exceptionally well conserved and less tolerant to mutations than other genes. Many SynGO terms are significantly overrepresented among gene variations associated with intelligence, educational attainment, ADHD, autism, and bipolar disorder and among de novo variants associated with neurodevelopmental disorders, including schizophrenia. SynGO is a public, universal reference for synapse research and an online analysis platform for interpretation of large-scale -omics data (https://syngoportal.org and

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Single-cell isoform RNA sequencing characterizes isoforms in thousands of cerebellar cells

Gupta

et al. 2018

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Full-length RNA sequencing (RNA-Seq) has been applied to bulk tissue, cell lines and sorted cells to characterize transcriptomes 1-11 , but applying this technology to single cells has proven to be difficult, with less than ten single-cell transcriptomes having been analyzed thus far 12,13. Although single splicing events have been described for ≤200 single cells with statistical confidence 14,15 , full-length mRNA analyses for hundreds of cells have not been reported. Singlecell short-read 3′ sequencing enables the identification of cellular subtypes 16-21 , but full-length mRNA isoforms for these cell types cannot be profiled. We developed a method that starts with bulk tissue and identifies single-cell types and their full-length RNA isoforms without fluorescence-activated cell sorting. Using single-cell isoform RNA-Seq (ScISOr-Seq), we identified RNA isoforms in neurons, astrocytes, microglia, and cell subtypes such as Purkinje and Granule cells, and cell-typespecific combination patterns of distant splice sites 6-9,22,23. We used ScISOr-Seq to improve genome annotation in mouse Gencode version 10 by determining the cell-type-specific expression of 18,173 known and 16,872 novel isoforms. Unlike sorting-based methods (Supplementary Fig. 1a), ScISOr-Seq identifies isoforms in >1,000 single cells from bulk tissue without cell sorting by combining two technologies (Fig. 1a). We used microfluidics to amplify full-length cDNA from single cells in a sample. cDNA produced from each single cell was barcoded to enable cell-of-origin identification and then split into two pools, with one pool being used for short-read Illumina 3′ sequencing to measure gene expression and the other pool being used for long-read sequencing and isoform identification. Short-read 3′ sequencing provided molecular counts for each gene and cell, which enabled clustering of cells and cell type assignment using cell-type-specific markers. Long-read sequencing with Pacific Biosciences (PacBio) 1,2,4,5 or Oxford Nanopore 3 was used to identify full-length RNA isoforms. Single-cell barcodes were also present in long reads and could be used to determine the individual

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Stitching the synapse: Cross-linking mass spectrometry into resolving synaptic protein interactions

et al. 2020

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Synaptic transmission is the predominant form of communication in the brain. It requires functionally specialized molecular machineries constituted by thousands of interacting synaptic proteins. Here, we made use of recent advances in cross-linking mass spectrometry (XL-MS) in combination with biochemical and computational approaches to reveal the architecture and assembly of synaptic protein complexes from mouse brain hippocampus and cerebellum. We obtained 11,999 unique lysine-lysine cross-links, comprising connections within and between 2362 proteins. This extensive collection was the basis to identify novel protein partners, to model protein conformational dynamics, and to delineate within and between protein interactions of main synaptic constituents, such as Camk2, the AMPA-type glutamate receptor, and associated proteins. Using XL-MS, we generated a protein interaction resource that we made easily accessible via a web-based platform (http://xlink.cncr.nl) to provide new entries into exploration of all protein interactions identified.

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Frank Koopmans

Mapping genomic loci implicates genes and synaptic biology in schizophrenia

SynGO: An Evidence-Based, Expert-Curated Knowledge Base for the Synapse

Single-cell isoform RNA sequencing characterizes isoforms in thousands of cerebellar cells

Stitching the synapse: Cross-linking mass spectrometry into resolving synaptic protein interactions

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