Transcriptome-wide isoform-level dysregulation in ASD, schizophrenia, and bipolar disorder

Gandal, Michael J.; Zhang, Pan; Hadjimichael, Evi; Walker, Rebecca L.; Chen, Chao; Liu, Shuang; Won, Hyejung; Bakel, Harm van; Varghese, Merina; Wang, Yongjun; Shi, Xu; Haney, Jillian R.; Parhami, Sepideh; Belmont, Judson; Kim, Minsoo; Losada, Patricia Morán; Khan, Zenab; Mleczko, Justyna; Xia, Yan; Dai, Rujia; Wang, Daifeng; Yang, Yu; Xu, Min; Fish, Kenneth; Hof, Patrick R.; Warrell, Jonathan; Fitzgerald, Dominic; White, Kevin P.; Jaffe, Andrew E.; Peters, Mette A.; Gerstein, Mark; Liu, Chunyu; Iakoucheva, Lilia M.; Pinto, Dalila; Geschwind, Daniel H.

doi:10.1126/science.aat8127

Cited by 955 publications

(1,231 citation statements)

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“…Similarly, in human brain, genomic regions associated with schizophrenia are enriched for genes that show differential isoform usage across neurodevelopment 7 , implicating many schizophrenia-associated risk loci in the regulation of the expression of specific RNA transcripts. Consistent with these findings, examples of associations between psychiatric risk-associated loci and the abundance of novel, alternatively spliced transcripts are beginning to emerge [8][9][10] , complementing numerous reports of altered splicing patterns in the brains of psychiatric cases, compared to controls [11][12][13] .…”

Section: Introductionmentioning

confidence: 73%

Long-read sequencing reveals the complex splicing profile of the psychiatric risk gene CACNA1C in human brain

Clark

Wrzesiński

Garcia

et al. 2018

Preprint

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RNA splicing is a key mechanism linking genetic variation and complex diseases, including schizophrenia. Splicing profiles are particularly diverse in the brain, but it is difficult to accurately identify and quantify full-length isoforms using standard approaches. CACNA1C is a large gene that shows robust genetic associations with several psychiatric disorders and encodes multiple, functionally-distinct voltage-gated calcium channels via alternative splicing. We combined long-range PCR with nanopore sequencing to characterise the full-length coding sequences of the CACNA1C gene in human brain. We show that its splice isoform profile varies between brain regions and is substantially more complex than currently appreciated: we identified 38 novel exons and 83 high confidence novel isoforms, many of which are predicted to alter protein function. Our findings demonstrate the capability of long-read amplicon sequencing to effectively characterise human splice isoform diversity, while the accurate characterisation of CACNA1C isoforms will facilitate the identification of disease-linked isoforms.All rights reserved. No reuse allowed without permission.(which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.

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Section: Introductionmentioning

confidence: 73%

Long-read sequencing reveals the complex splicing profile of the psychiatric risk gene CACNA1C in human brain

Clark

Wrzesiński

Garcia

et al. 2018

Preprint

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“…These spatial definitions have to a large extent been based on cytoarchitectural features -such as differences in the density and form of cells -as well as chemoarchitectural definitions derived from distribution of key molecules such as neurotransmitters (5,6). Ongoing collective efforts in the field are now starting to reveal the details of neuron and region connections at the microscale and mesoscale level (4,7,8), and gene expression in the human brain (9,10). These tissue definitions and the resulting mouse brain atlases (11,12) have been essential for establishing the experimental framework to explore brain structure and function relationships, but have also resulted in debate and disagreement over the validity of expert-based region annotations (13).…”

Section: Introductionmentioning

confidence: 99%

Molecular Atlas of the Adult Mouse Brain

Ortiz

Navarro

Jurek

et al. 2019

Preprint

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Brain maps are essential for integrating information and interpreting the structure-function relationship of circuits and behavior. We aimed to generate a systematic classification of the adult mouse brain organization based on unbiased extraction of spatially-defining features. Applying whole-brain spatial transcriptomics, we captured the gene expression signatures to define the spatial organization of molecularly discrete subregions. We found that the molecular code contained sufficiently detailed information to directly deduce the complex spatial organization of the brain. This unsupervised molecular classification revealed new area-and layer-specific subregions, for example in isocortex and hippocampus, and a new division of striatum.

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“…Finally, to evaluate whether the regulation networks related to ASD models could be conserved in human, we examined the expression levels of the hub genes with the data generated in an integrated transcriptional study using data sets of 2,000 high‐quality postmortem brain samples of individuals with SCZ or ASD [Gandal et al, ]. The significance of the alteration of expression levels of the hub genes based on student's t ‐test were calculated (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…The results indicated that these hub genes were involved in drug abuse, bipolar disorder, depressive disorder, SCZ, and autistic disorder, which are a group of closely related disorders that may share some similar pathomechanisms with ASD. Finally, to evaluate whether the regulation networks related to ASD models could be conserved in human, we examined the expression levels of the hub genes with the data generated in an integrated transcriptional study using data sets of 2,000 high-quality postmortem brain samples of individuals with SCZ or ASD [Gandal et al, 2018]. The significance of the alteration of expression levels of the hub genes based on student's t-test were calculated (Fig.…”

Section: Ppi Network Construction and Hub Genes Screeningmentioning

confidence: 99%

Integrated Transcriptome Analyses Revealed Key Target Genes in Mouse Models of Autism

et al. 2019

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Genetic mutations are the major pathogenic factor of Autism Spectrum Disorder (ASD). In recent years, more and more ASD risk genes have been revealed, among which there are a group of transcriptional regulators. Considering the similarity of the core clinical phenotypes, it is possible that these different factors may regulate the expression levels of certain key targets. Identification of these targets could facilitate the understanding of the etiology and developing of novel diagnostic and therapeutic methods. Therefore, we performed integrated transcriptome analyses of RNA‐Seq and microarray data in multiple ASD mouse models and identified a number of common downstream genes in various brain regions, many of which are related to the structure and function of the synapse components or drug addiction. We then established protein–protein interaction networks of the overlapped targets and isolated the hub genes by 11 algorithms based on the topological structure of the networks, including Sdc4, Vegfa, and Cp in the Cortex‐Adult subgroup, Gria1 in the Cortex‐Juvenile subgroup, and Kdr, S1pr1, Ubc, Grm2, Grin2b, Nrxn1, Pdyn, Grin3a, Itgam, Grin2a, Gabra2, and Camk4 in the Hippocampus‐Adult subgroup, many of which have been associated with ASD in previous studies. Finally, we cross compared our results with human brain transcriptional data sets and verified several key candidates, which may play important role in the pathology process of ASD, including SDC4, CP, S1PR1, UBC, PDYN, GRIN2A, GABRA2, and CAMK4. In summary, by integrated bioinformatics analysis, we have identified a series of potentially important molecules for future ASD research. Autism Res 2020, 13: 352–368. © 2019 International Society for Autism Research, Wiley Periodicals, Inc. Lay Summary Abnormal transcriptional regulation accounts for a significant portion of Autism Spectrum Disorder. In this study, we performed transcriptome analyses of mouse models to identify common downstream targets of transcriptional regulators involved in ASD. We identified several recurrent target genes that are close related to the common pathological process of ASD, including SDC4, CP, S1PR1, UBC, PDYN, GRM2, NRXN1, GRIN3A, ITGAM, GRIN2A, GABRA2, and CAMK4. These results provide potentially important targets for understanding the molecular mechanism of ASD.

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Transcriptome-wide isoform-level dysregulation in ASD, schizophrenia, and bipolar disorder

Cited by 955 publications

References 145 publications

Long-read sequencing reveals the complex splicing profile of the psychiatric risk gene CACNA1C in human brain

Long-read sequencing reveals the complex splicing profile of the psychiatric risk gene CACNA1C in human brain

Molecular Atlas of the Adult Mouse Brain

Integrated Transcriptome Analyses Revealed Key Target Genes in Mouse Models of Autism

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