Integrative Functional Genomic Analyses Implicate Specific Molecular Pathways and Circuits in Autism

Parikshak, Neelroop N.; Luo, Rui; Zhang, Alice; Won, Hyejung; Lowe, Jennifer K.; Chandran, Vijayendran; Horvath, Steve; Geschwind, Daniel H.

doi:10.1016/j.cell.2013.10.031

Cited by 915 publications

(1,149 citation statements)

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“…Supporting our above hypothesis is a recent study on specific molecular pathways and circuits in autism, where ASD and ID risk genes were mapped onto co-expression networks of developmental trajectories and transcriptional profiles in the fetal and adult cortical laminae. 34 These studies showed bioinformatically that FMRP interacts with a series of ASD genes, one of them being MBD5. 34 Finally, we show that the expression levels of NR1D2 and CRY2 were significantly reduced in 2q23.1 deletion syndrome, SMS, and FXS LCLs.…”

Section: Discussionmentioning

confidence: 99%

“…34 These studies showed bioinformatically that FMRP interacts with a series of ASD genes, one of them being MBD5. 34 Finally, we show that the expression levels of NR1D2 and CRY2 were significantly reduced in 2q23.1 deletion syndrome, SMS, and FXS LCLs. Interestingly, loss of CRY2 has been linked to high anxiety, and NR1D2 was recently shown to protect normal metabolic function.…”

Section: Discussionmentioning

confidence: 99%

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MBD5 haploinsufficiency is associated with sleep disturbance and disrupts circadian pathways common to Smith–Magenis and fragile X syndromes

et al. 2014

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Individuals with autism spectrum disorders (ASD) who have an identifiable single-gene neurodevelopmental disorder (NDD), such as fragile X syndrome (FXS, FMR1), Smith-Magenis syndrome (SMS, RAI1), or 2q23.1 deletion syndrome (del 2q23.1, MBD5) share phenotypic features, including a high prevalence of sleep disturbance. We describe the circadian deficits in del 2q23.1 through caregiver surveys in which we identify several frequent sleep anomalies, including night/early awakenings, coughing/ snoring loudly, and difficulty falling asleep. We couple these findings with studies on the molecular analysis of the circadian deficits associated with haploinsufficiency of MBD5 in which circadian gene mRNA levels of NR1D2, PER1, PER2, and PER3 were altered in del 2q23.1 lymphoblastoid cell lines (LCLs), signifying that haploinsufficiency of MBD5 can result in dysregulation of circadian rhythm gene expression. These findings were further supported by expression microarrays of MBD5 siRNA knockdown cells that showed significantly altered expression of additional circadian rhythm signaling pathway genes. Based on the common sleep phenotypes observed in del 2q23.1, SMS, and FXS patients, we explored the possibility that MBD5, RAI1, and FMR1 function in overlapping circadian rhythm pathways. Bioinformatic analysis identified conserved putative E boxes in MBD5 and RAI1, and expression levels of NR1D2 and CRY2 were significantly reduced in patient LCLs. Circadian and mTOR signaling pathways, both associated with sleep disturbance, were altered in both MBD5 and RAI1 knockdown microarray data, overlapping with findings associated with FMR1. These data support phenotypic and molecular overlaps across these syndromes that may be exploited to provide therapeutic intervention for multiple disorders. Significant sleep problems are highly prevalent in individuals with ASD. 2 Parents of children with ASD report 50-80% prevalence of sleep problems compared with a 9-50% prevalence rate reported by parents of age-matched typically developing children. 2 Common sleep etiological factors that are present in children with ASD are rapid eye movement sleep abnormalities, dysregulation of melatonin synthesis, difficulty in settling to sleep, night waking, irregular sleep patterns, short-duration sleep, and daytime sleepiness. 2,3 Persistent sleep problems are thought to adversely affect cognitive, physical, and social function, learning, mood, and behavior in these individuals and, in addition, cause significant stress for families and caretakers. 3 Better understanding of the sleep difficulties experienced by children with ASD may reduce the adverse effects and decrease family stress, possibly with targeted therapies.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

MBD5 haploinsufficiency is associated with sleep disturbance and disrupts circadian pathways common to Smith–Magenis and fragile X syndromes

et al. 2014

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“…Our study is focused on a specific neurodevelopmental disorder-ASD-because it has been suggested that ASD has its roots in abnormalities in prenatal brain development (50)(51)(52). Specifically, our analysis of the temporal expression patterns of coexpressed gene modules in the developing brain shows that genes in three EGenriched coexpression modules implicated in ASD are expressed at a high level at the earliest stages of brain development, as early as 8 weeks after conception.…”

Section: B C Amentioning

confidence: 99%

Increased burden of deleterious variants in essential genes in autism spectrum disorder

Xiao

Kember

Brown

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Autism spectrum disorder (ASD) is a heterogeneous, highly heritable neurodevelopmental syndrome characterized by impaired social interaction, communication, and repetitive behavior. It is estimated that hundreds of genes contribute to ASD. We asked if genes with a strong effect on survival and fitness contribute to ASD risk. Human orthologs of genes with an essential role in pre-and postnatal development in the mouse [essential genes (EGs)] are enriched for disease genes and under strong purifying selection relative to human orthologs of mouse genes with a known nonlethal phenotype [nonessential genes (NEGs)]. This intolerance to deleterious mutations, commonly observed haploinsufficiency, and the importance of EGs in development suggest a possible cumulative effect of deleterious variants in EGs on complex neurodevelopmental disorders. With a comprehensive catalog of 3,915 mammalian EGs, we provide compelling evidence for a stronger contribution of EGs to ASD risk compared with NEGs. By examining the exonic de novo and inherited variants from 1,781 ASD quartet families, we show a significantly higher burden of damaging mutations in EGs in ASD probands compared with their non-ASD siblings. The analysis of EGs in the developing brain identified clusters of coexpressed EGs implicated in ASD. Finally, we suggest a high-priority list of 29 EGs with potential ASD risk as targets for future functional and behavioral studies. Overall, we show that large-scale studies of gene function in model organisms provide a powerful approach for prioritization of genes and pathogenic variants identified by sequencing studies of human disease.essential genes | mouse knockouts | mutational burden | autism spectrum disorder | coexpression modules A utism spectrum disorder (ASD) is a heterogeneous, heritable neurodevelopmental syndrome characterized by impaired social interaction, communication, and repetitive behavior (1, 2). The highly polygenic nature of ASD (3-5) suggests that the analysis of the full spectrum of sequence variants in hundreds of genes will be necessary for deeper understanding of disrupted neuronal function. Prioritization of ASD risk genes initially focused on known pathways with recognized relevance to pathogenesis of ASD, such as synaptic function and neuronal development (6). However, combined analyses of de novo, inherited, and case-control variation in over 2,500 ASD parentchild nuclear families identified around 100 genes contributing to ASD risk (7-9), converging on pathways implicated in transcriptional regulation and chromatin modeling in addition to synaptic function.The main challenge in the current understanding of genetic architecture of ASD comes from a need to study the interplay between variants with a high effect (for example, recurrent de novo variants) and a background of variants with an intermediate effect but that nevertheless still disrupt proper neuronal development. Essential genes (EGs) or genes that are necessary for successful completion of pre-and postnatal development are prime candi...

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“…Co-expression networks seeded with genes recurrently mutated in autism were found to converge with networks in deep layer projection neurons of the prefrontal and primary motorsomatosensory cortex during midfetal development [193]. Parikshak et al [194] mapped autism risk genes to transcriptional networks throughout development and identified glutamatergic neurons in upper cortical layers as a critical cell type and brain region in autism. Undoubtedly, pathway and related network analyses have identified some degree of convergence with regard to potential mechanisms in which genes may participate, but, at present, these mechanisms remain fairly broad.…”

Section: Autism Genetic Studies May Point To Convergentmentioning

confidence: 99%

Discovery of Rare Mutations in Autism: Elucidating Neurodevelopmental Mechanisms

et al. 2015

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Autism spectrum disorder (ASD) is a group of highly genetic neurodevelopmental disorders characterized by language, social, cognitive, and behavioral abnormalities. ASD is a complex disorder with a heterogeneous etiology. The genetic architecture of autism is such that a variety of different rare mutations have been discovered, including rare monogenic conditions that involve autistic symptoms. Also, de novo copy number variants and single nucleotide variants contribute to disease susceptibility. Finally, autosomal recessive loci are contributing to our understanding of inherited factors. We will review the progress that the field has made in the discovery of these rare genetic variants in autism. We argue that mutation discovery of this sort offers an important opportunity to identify neurodevelopmental mechanisms in disease. The hope is that these mechanisms will show some degree of convergence that may be amenable to treatment intervention.

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Integrative Functional Genomic Analyses Implicate Specific Molecular Pathways and Circuits in Autism

Cited by 915 publications

References 81 publications

MBD5 haploinsufficiency is associated with sleep disturbance and disrupts circadian pathways common to Smith–Magenis and fragile X syndromes

MBD5 haploinsufficiency is associated with sleep disturbance and disrupts circadian pathways common to Smith–Magenis and fragile X syndromes

Increased burden of deleterious variants in essential genes in autism spectrum disorder

Discovery of Rare Mutations in Autism: Elucidating Neurodevelopmental Mechanisms

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