Project description:Spatial barcoding-based transcriptomic (ST) data require cell type deconvolution for cellular-level downstream analysis. Here we present SDePER, a hybrid machine learning and regression method, to deconvolve ST data using reference single-cell RNA sequencing (scRNA-seq) data. SDePER removes the systematic difference between the ST and scRNA-seq data (platform effects) explicitly and efficiently to ensure the linear relationship between ST data and cell type-specific expression profile. It also considers sparsity of cell types per capture spot and across-spots spatial correlation in cell type compositions. Based on the estimations, SDePER imputes for cell type compositions and gene expression at enhanced resolution. We assessed the performance of SDePER and six existing methods using simulations and four real datasets. All results showed that SDePER achieved significantly more accurate and robust results than the existing methods suggesting the importance of considering platform effects, sparsity and spatial correlation in cell type deconvolution.

Project description:This dataset comprises spatial multi-omic profiling of malignant pleural mesothelioma (MPM) tissue, enabling simultaneous measurement of transcriptomic and protein expression at spatial resolution. To address the lack of spatially resolved proteomic measurements in standard spatial transcriptomics (ST) technologies, we generated this in-house MPM spatial transcriptomics and proteomics dataset and used it to train and evaluate DGAT (Dual-Graph Attention Network), a deep learning framework for imputing protein expression from ST data. DGAT integrates transcriptomic, proteomic, and spatial information using graph attention networks and jointly reconstructs mRNA and protein profiles through multi-task learning. This dataset serves both as a biological resource for understanding the tumor immune microenvironment in MPM and as a benchmark for spatial protein inference. DGAT’s predictions on this dataset enabled improved identification of immune phenotypes and tumor–stroma spatial organization, with implications for biomarker discovery and therapeutic targeting in mesothelioma. Spatial transcriptomics (ST) technologies provide genome-wide mRNA profiles in tissue context but lack direct protein-level measurements, which are critical for interpreting cellular function and microenvironmental organization. We present DGAT (Dual-Graph Attention Network), a deep learning framework that imputes spatial protein expression from transcriptomics-only ST data by learning RNA–protein relationships from spatial CITE-seq datasets. DGAT constructs heterogeneous graphs integrating transcriptomic, proteomic, and spatial information, encoded using graph attention networks. Task-specific decoders reconstruct mRNA and predict protein abundance from a shared latent representation.

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