Gene network analysis reveals a role for striatal glutamatergic receptors in dysregulated risk-assessment behavior of autism mouse models

Oron, Oded; Getselter, Dmitriy; Shohat, Shahar; Reuveni, Eli; Lukić, Iva; Shifman, Sagiv; Elliott, Evan

doi:10.1038/s41398-019-0584-5

Cited by 11 publications

(13 citation statements)

References 45 publications

(56 reference statements)

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“…This in silico approach to the investigation of unknown biology stems from the "guilt by association" paradigm [33], which is predicated on the assumption that protein products of highly co-expressed (i.e., coordinately transcribed) genes share functionality, forming multi-gene subsystems within a parent biological system [34][35][36]. Weighted gene co-expression network analysis (WGCNA) [27,37] is a technique that has been successfully deployed in this context to study how genes jointly affect complex human diseases [38][39][40][41][42]. We sought to apply this paradigm to 3q29Del syndrome to glean biological insights into disease-associated driver genes and functional mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Convergent and distributed effects of the schizophrenia-associated 3q29 deletion on the human neural transcriptome

Sefik

Purcell

Merritt-Garza

et al. 2020

Preprint

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The 1.6Mb 3q29 deletion (3q29Del) confers >40-fold increased risk for schizophrenia (SZ) and is also a risk factor for intellectual disability (ID) and autism spectrum disorders (ASD). No single gene in this interval is definitively associated with SZ, ID, or ASD, prompting the hypothesis that neurodevelopmental sequelae emerge upon loss of multiple functionally-connected genes. However, 3q29 interval genes are unevenly annotated and the impact of the 3q29Del on the human neural transcriptome is not known. To formulate unbiased hypotheses, we engaged a systems-level approach using the adult human cortical transcriptome to predict novel biological roles, functional inter-relations and disease associations for individual 3q29 genes. Weighted gene co-expression network analysis showed that the 21 protein-coding genes located in the 3q29 interval segregate into seven clusters, demonstrating both convergent and distributed effects across the transcriptomic landscape. Analysis of 3q29 gene-containing clusters revealed nervous-system specific functions, such as regulation and organization of synaptic signaling, as well as core aspects of cell biology, including transcriptional regulation, chromatin remodeling, protein modifications, and mitochondrial metabolism. Top network neighbors of 3q29 interval genes show significant overlap with known SZ, ASD and ID-risk genes, suggesting that 3q29Del biology is relevant to idiopathic disease. By leveraging “guilt by association”, we propose nine 3q29 genes, including one hub gene, as prioritized drivers of neuropsychiatric risk. To test these predictions, we generated the first human cellular model of 3q29Del syndrome and show that neural progenitor cell (NPC) lines derived from 3q29Del carriers empirically validate network-derived targets, highlighting both the biological relevance of this in silico analysis and this novel NPC model of 3q29Del. These results provide foundational information to formulate testable hypotheses on causal drivers and mechanisms of the largest known genetic risk factor for SZ.

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Section: Introductionmentioning

confidence: 99%

Convergent and distributed effects of the schizophrenia-associated 3q29 deletion on the human neural transcriptome

Sefik

Purcell

Merritt-Garza

et al. 2020

Preprint

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“…Five DEGs showed consistent expression patterns in all five datasets: three upregulated DEGs (Adi1, Scg5, and Serpina3n), and two downregulated DEGs (Nudt19 and Pop4). The expression patterns of 136 DEGs (23 upregulated, 113 downregulated) were consistent between the BTBR/R mice cerebral cortex and striatum and the BTBR/J mice striatum (Oron et al, 2019) datasets, while those of 30 DEGs (6 upregulated, 24 downregulated) were consistent between the BTBR/R mice cerebral cortex and striatum and the BTBR/J mice cerebral cortex (Daimon et al, 2015) datasets (Supplementary Table 14). In total, 208 DEGs showed consistent expression patterns (45 upregulated, 163 downregulated) between the BTBR/R cerebral cortex and striatum and BTBR/J hippocampus (Provenzano et al, 2016) datasets.…”

Section: Fifty-three Asd Candidate Genes Were Included In Degs Betweementioning

confidence: 84%

“…These results suggested that BTBR/R mouse brains have alterations in Kdm5b-mediated epigenetic regulation commonly affected in these ASD models together with those in the maternal immune activation model. We next examined DEGs between two sublines of BTBR mice by comparing our BTBR/R vs. B6 dataset (1,280 DEGs obtained from the cerebral cortex and striatum) with the five independent BTBR/J vs. B6 datasets (1,016 DEGs from the hippocampus by Provenzano et al (2016); 325 DEGs from the cerebellum by Shpyleva et al (2014); 448 DEGs in the striatum by Oron et al (2019); and 328 DEGs from the hippocampus and 328 DEGs from the cerebral cortex by Daimon et al, 2015; Supplementary Table 14). The 341 DEGs identified in our BTBR/R study were also reported as DEGs in at least one of the BTBR/J datasets.…”

Section: Fifty-three Asd Candidate Genes Were Included In Degs Betweementioning

confidence: 99%

Comprehensive Profiling of Gene Expression in the Cerebral Cortex and Striatum of BTBRTF/ArtRbrc Mice Compared to C57BL/6J Mice

Mizuno

Hirota

Ishii

et al. 2020

Front. Cell. Neurosci.

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Mouse line BTBR T+ Iptr3tf/J (hereafter referred as to BTBR/J) is a mouse strain that shows lower sociability compared to the C57BL/6J mouse strain (B6) and thus is often utilized as a model for autism spectrum disorder (ASD). In this study, we utilized another subline, BTBRTF/ArtRbrc (hereafter referred as to BTBR/R), and analyzed the associated brain transcriptome compared to B6 mice using microarray analysis, quantitative RT-PCR analysis, various bioinformatics analyses, and in situ hybridization. We focused on the cerebral cortex and the striatum, both of which are thought to be brain circuits associated with ASD symptoms. The transcriptome profiling identified 1,280 differentially expressed genes (DEGs; 974 downregulated and 306 upregulated genes, including 498 non-coding RNAs [ncRNAs]) in BTBR/R mice compared to B6 mice. Among these DEGs, 53 genes were consistent with ASD-related genes already established. Gene Ontology (GO) enrichment analysis highlighted 78 annotations (GO terms) including DNA/chromatin regulation, transcriptional/translational regulation, intercellular signaling, metabolism, immune signaling, and neurotransmitter/synaptic transmission-related terms. RNA interaction analysis revealed novel RNA–RNA networks, including 227 ASD-related genes. Weighted correlation network analysis highlighted 10 enriched modules including DNA/chromatin regulation, neurotransmitter/synaptic transmission, and transcriptional/translational regulation. Finally, the behavioral analyses showed that, compared to B6 mice, BTBR/R mice have mild but significant deficits in social novelty recognition and repetitive behavior. In addition, the BTBR/R data were comprehensively compared with those reported in the previous studies of human subjects with ASD as well as ASD animal models, including BTBR/J mice. Our results allow us to propose potentially important genes, ncRNAs, and RNA interactions. Analysis of the altered brain transcriptome data of the BTBR/R and BTBR/J sublines can contribute to the understanding of the genetic underpinnings of autism susceptibility.

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“…In our analysis, we highlighted transcriptomic alterations in glutamatergic and GABAergic signaling pathway genes ( Figure 7B), and the corresponding genes were found to be altered not only in BTBR/R but also BTBR/J mice in several instances (Supplementary Table 14). Among the glutamatergic signaling pathway genes, the glutaminase (Gls), phospholipase A2 group IVB (Pla2g4b), and phospholipase A2 group IVE (Pla2g4e) genes were also altered in the hippocampus (Provenzano et al, 2016), dorsal striatum (Oron et al, 2019), and cerebellum (Shpyleva et al, 2014). Of the GABAergic signaling pathway genes, the GABA receptor subunit gamma-2 (Gabrg2) and GABA-A receptor subunit alpha2 (Gabra2) genes were also altered in the hippocampus (Provenzano et al, 2016), cortex (Daimon et al, 2015), and cerebellum (Shpyleva et al, 2014).…”

Section: Transcriptomic Features Of Neurotransmitter Systemsmentioning

confidence: 99%

“…From this point of view, BTBR/J is a valuable animal model of ASD to analyze the molecular and pathological mechanism at the gene and protein expression level. For this purpose, BTBR/J mice have been subjected to transcriptome analyses of the hippocampus (Daimon et al, 2015;Provenzano et al, 2016;Gasparini et al, 2020), frontal cortex (Kratsman et al, 2016), dorsal striatum (Oron et al, 2019), and cerebellum (Shpyleva et al, 2014), as well as proteome analyses of cortical (Jasien et al, 2014;Wei et al, 2016) and hippocampal tissues (Jasien et al, 2014;Daimon et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Gene network analysis reveals a role for striatal glutamatergic receptors in dysregulated risk-assessment behavior of autism mouse models

Cited by 11 publications

References 45 publications

Convergent and distributed effects of the schizophrenia-associated 3q29 deletion on the human neural transcriptome

Convergent and distributed effects of the schizophrenia-associated 3q29 deletion on the human neural transcriptome

Comprehensive Profiling of Gene Expression in the Cerebral Cortex and Striatum of BTBRTF/ArtRbrc Mice Compared to C57BL/6J Mice

Table_11.XLSX

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