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    Area of Science:

    • Genomics
    • Bioinformatics
    • Systems Biology

    Background:

    • Transcriptome-wide association study (TWAS) links genetic variations to phenotypic traits using gene expression data.
    • Predicting gene expression is crucial for TWAS, but low heritability in many genes limits model performance.
    • Existing TWAS methods struggle with noise and nonlinearities in gene expression data.

    Purpose of the Study:

    • To propose AE-TWAS, a novel method that enhances TWAS by denoising transcriptome data prior to analysis.
    • To improve the heritability and connectivity of gene expression data for more accurate genotype-phenotype association mapping.
    • To identify functionally relevant genes for diseases through improved TWAS.

    Main Methods:

    • Developed AE-TWAS, incorporating an autoencoder (AE) based data transformation step before standard TWAS.
    • Split the transcriptome into co-expression modules and used AE to reconstruct data within each module, effectively removing noise.
    • Applied the transformed data to downstream TWAS for genotype-phenotype association analysis.

    Main Results:

    • AE-TWAS transformation significantly increased expression heritability, especially for genes with initially low heritability.
    • The denoised transcriptome data exhibited enhanced connectivity within co-expression modules.
    • AE-TWAS improved TWAS performance and identified disease-relevant hub genes with greater functional significance.

    Conclusions:

    • AE-TWAS effectively denoises transcriptome data, enhancing gene expression heritability and module connectivity.
    • The proposed method improves the accuracy and power of TWAS for genotype-phenotype association studies.
    • AE-TWAS facilitates the discovery of functionally relevant genes and potential disease biomarkers.