Abstract
Bulk transcriptomic analyses of autism spectrum disorder (ASD) have revealed dysregulated pathways, while the brain cell type-specific molecular pathology of ASD still needs to be studied. Machine learning-based studies can be conducted for ASD, prioritizing high-confidence gene candidates and promoting the design of effective interventions. Using human brain nucleus gene expression of ASD and controls, we construct cell type-specific predictive models for ASD based on individual genes and gene sets, respectively, to screen cell type-specific ASD-associated genes and gene sets. These two kinds of predictive models can predict the diagnosis of a nucleus with known cell type. Then, we construct a multi-label predictive model for predicting the cell type and diagnosis of a nucleus at the same time. Our findings suggest that layer 2/3 and layer 4 excitatory neurons, layer 5/6 cortico-cortical projection neurons, parvalbumin interneurons, and protoplasmic astrocytes are preferentially affected in ASD. The functions of genes with predictive power for ASD are different and the top important genes are distinct across different cells, highlighting the cell-type heterogeneity of ASD. The constructed predictive models can promote the diagnosis of ASD, and the prioritized cell type-specific ASD-associated genes and gene sets may be used as potential biomarkers of ASD.
Highlights
Autism spectrum disorder (ASD) represents a group of neurodevelopmental disorders, characterized by substantial phenotypic and genetic heterogeneity
To screen genes associated with ASD in each cell type, we constructed cell type-specific predictive models, which can predict the diagnosis of a nucleus whose cell type is known, using the algorithm of partial least squares (PLS)
The authors identified differentially expressed (DE) genes between ASD and controls in a cell type-specific way and found that the top DE neuronal genes were identified in layer 2/3 excitatory neurons (L2/3) and IN-VIP, and the top DE genes in non-neuronal cell types were identified in AST-PP and microglia
Summary
Autism spectrum disorder (ASD) represents a group of neurodevelopmental disorders, characterized by substantial phenotypic and genetic heterogeneity. Genetic studies have identified variants that contribute to the risk of developing ASD (Iossifov et al, 2012; Neale et al, 2012; O’Roak et al, 2012; Sanders et al, 2012; De Rubeis et al, 2014; Gaugler et al, 2014; Turner et al, 2016; Satterstrom et al, 2020). It remains perplexing how these reported variants lead to the pathogenesis of ASD.
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