Four Social Brain Regions, Their Dysfunctions, and Sequelae, Extensively Explain Autism Spectrum Disorder Symptomatology

Weston, Charles Stewart E.

doi:10.3390/brainsci9060130

Cited by 25 publications

(26 citation statements)

References 366 publications

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“…While we chose to use the GTEx resource, as these data are more readily accessible—and likely more generalizable to other conditions—compared to resources containing data generated from ASD brain tissue, this may limit the ability to understand genetic differences that may be unique to the brains of individuals with ASD. Specifically, it is hypothesized that brain regions involved in social behavior drive ASD symptomatology; these include the amygdala, orbitofrontal cortex, temporoparietal cortex and insula [ 48 ]. With the exception of the amygdala, gene expression in the precise brain regions that are proposed biomarkers for ASD are not quantified in the GTEx resource potentially explaining why our results were limited to the pituitary.…”

Section: Discussionmentioning

confidence: 99%

An Automated Functional Annotation Pipeline That Rapidly Prioritizes Clinically Relevant Genes for Autism Spectrum Disorder

Veatch

Butler

Elsea

et al. 2020

IJMS

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Human genetic studies have implicated more than a hundred genes in Autism Spectrum Disorder (ASD). Understanding how variation in implicated genes influence expression of co-occurring conditions and drug response can inform more effective, personalized approaches for treatment of individuals with ASD. Rapidly translating this information into the clinic requires efficient algorithms to sort through the myriad of genes implicated by rare gene-damaging single nucleotide and copy number variants, and common variation detected in genome-wide association studies (GWAS). To pinpoint genes that are more likely to have clinically relevant variants, we developed a functional annotation pipeline. We defined clinical relevance in this project as any ASD associated gene with evidence indicating a patient may have a complex, co-occurring condition that requires direct intervention (e.g., sleep and gastrointestinal disturbances, attention deficit hyperactivity, anxiety, seizures, depression), or is relevant to drug development and/or approaches to maximizing efficacy and minimizing adverse events (i.e., pharmacogenomics). Starting with a list of all candidate genes implicated in all manifestations of ASD (i.e., idiopathic and syndromic), this pipeline uses databases that represent multiple lines of evidence to identify genes: (1) expressed in the human brain, (2) involved in ASD-relevant biological processes and resulting in analogous phenotypes in mice, (3) whose products are targeted by approved pharmaceutical compounds or possessing pharmacogenetic variation and (4) whose products directly interact with those of genes with variants recommended to be tested for by the American College of Medical Genetics (ACMG). Compared with 1000 gene sets, each with a random selection of human protein coding genes, more genes in the ASD set were annotated for each category evaluated (p ≤ 1.99 × 10−2). Of the 956 ASD-implicated genes in the full set, 18 were flagged based on evidence in all categories. Fewer genes from randomly drawn sets were annotated in all categories (x = 8.02, sd = 2.56, p = 7.75 × 10−4). Notably, none of the prioritized genes are represented among the 59 genes compiled by the ACMG, and 78% had a pathogenic or likely pathogenic variant in ClinVar. Results from this work should rapidly prioritize potentially actionable results from genetic studies and, in turn, inform future work toward clinical decision support for personalized care based on genetic testing.

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Section: Discussionmentioning

confidence: 99%

An Automated Functional Annotation Pipeline That Rapidly Prioritizes Clinically Relevant Genes for Autism Spectrum Disorder

Veatch

Butler

Elsea

et al. 2020

IJMS

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“…Perception of animacy is disturbed in some children with ASD (Congiu et al, 2010). On top of communicative challenges, individuals with ASD face additional difficulties such as having a lack of understanding of social cues and conventions, disinterest in forming new relationships, and difficulties in conversation such as interpreting jokes, sarcasm, or understanding metaphors (Weston, 2019). These impairments tend to result in anxiety, social withdrawal, dysphoric emotions, and high-stress levels.…”

Section: Autism Spectrum Disordermentioning

confidence: 99%

Neuronal Circuits for Social Decision-Making and Their Clinical Implications

et al. 2021

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Social living facilitates individual access to rewards, cognitive resources, and objects that would not be otherwise accessible. There are, however, some drawbacks to social living, particularly when competing for scarce resources. Furthermore, variability in our ability to make social decisions can be associated with neuropsychiatric disorders. The neuronal mechanisms underlying social decision-making are beginning to be understood. The momentum to study this phenomenon has been partially carried over by the study of economic decision-making. Yet, because of the similarities between these different types of decision-making, it is unclear what is a social decision. Here, we propose a definition of social decision-making as choices taken in a context where one or more conspecifics are involved in the decision or the consequences of it. Social decisions can be conceptualized as complex economic decisions since they are based on the subjective preferences between different goods. During social decisions, individuals choose based on their internal value estimate of the different alternatives. These are complex decisions given that conspecifics beliefs or actions could modify the subject’s internal valuations at every choice. Here, we first review recent developments in our collective understanding of the neuronal mechanisms and circuits of social decision-making in primates. We then review literature characterizing populations with neuropsychiatric disorders showing deficits in social decision-making and the underlying neuronal circuitries associated with these deficits.

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“…Наряду с увеличением общего размера мозга обнаружено увеличение гиппокампа, миндалины и мозжечка [5,23]. Нейроны в глубоких ядрах мозжечка (n. fastigeal, n. globose, n. emboliform) отличались большими размерами и их количество было больше [24].…”

Section: расстройства аутистического спектра как прогрессирующее систunclassified

“…У детей старше 4 лет размеры миндалины и гиппокампа либо не отличались от таковых у НРД, либо были несколько меньше [5,14]. Вместе с тем другие авторы выявили увеличение гиппокампа, особенно в группе больных РАС без когнитивных нарушений [37], а также билатеральное увеличение хвостатых и прилежащих ядер [28,38]; уменьшение мозолистого тела [36].…”

Section: расстройства аутистического спектра как прогрессирующее систunclassified

“…Расстройства аутистического спектра (РАС) включают заболевания и состояния со сходными клиническими проявлениями в виде качественных нарушений социального взаимодействия и показателей коммуникабельности, а также ограниченных повторяющихся паттернов поведения, интересов или действий [1]. У больных РАС наблюдаются коморбидные состояния, включая эпилепсию, желудочно-кишечную дисфункцию, психические расстройства, бессонницу, нарушения мышечного тонуса и двигательных навыков, внимания и эмоций, разной степени выраженности когнитивные и речевые расстройства [2][3][4][5].…”

Section: Introductionunclassified

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Dynamics of age-related structural and functional changes in the brain of patients with autism spectrum disorders

Belokoskova

Георгиевна²,

Malsagova

et al. 2019

Medical academic journal

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The review reflects modern information on the brain dysontogenesis of patients with autism spectrum disorders throughout life. The features of the stages of age-related disorders of the structure and functional state of the brain of such patients are presented. Along with the description of defects in the morphofunctional organization of the brain of patients, attention is focused on the presence of individual differences of such defects, which determines the heterogeneity of the clinical manifestations of the disease.

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Four Social Brain Regions, Their Dysfunctions, and Sequelae, Extensively Explain Autism Spectrum Disorder Symptomatology

Cited by 25 publications

References 366 publications

An Automated Functional Annotation Pipeline That Rapidly Prioritizes Clinically Relevant Genes for Autism Spectrum Disorder

An Automated Functional Annotation Pipeline That Rapidly Prioritizes Clinically Relevant Genes for Autism Spectrum Disorder

Neuronal Circuits for Social Decision-Making and Their Clinical Implications

Dynamics of age-related structural and functional changes in the brain of patients with autism spectrum disorders

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