Model-based prediction of spatial gene expression via generative linear mapping.
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IF: 17.694
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Cited by: 11
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Abstract

Decoding spatial transcriptomes from single-cell RNA sequencing (scRNA-seq) data has become a fundamental technique for understanding multicellular systems; however, existing computational methods lack both accuracy and biological interpretability due to their model-free frameworks. Here, we introduce Perler, a model-based method to integrate scRNA-seq data with reference in situ hybridization (ISH) data. To calibrate differences between these datasets, we develop a biologically interpretable model that uses generative linear mapping based on a Gaussian mixture model using the Expectation-Maximization algorithm. Perler accurately predicts the spatial gene expression of Drosophila embryos, zebrafish embryos, mammalian liver, and mouse visual cortex from scRNA-seq data. Furthermore, the reconstructed transcriptomes do not over-fit the ISH data and preserved the timing information of the scRNA-seq data. These results demonstrate the generalizability of Perler for dataset integration, thereby providing a biologically interpretable framework for accurate reconstruction of spatial transcriptomes in any multicellular system.

Keywords

ProximID
smFISH
Spatial reconstruction
Seurat
novoSpaRc
DistMap
STARmap
Spatial Gene Expression

MeSH terms

Algorithms
Animals
Cell Polarity
Computational Biology
Databases, Genetic
Drosophila melanogaster
Gene Expression Profiling
Gene Expression Regulation, Developmental
In Situ Hybridization
Liver
Mice
Models, Theoretical
RNA-Seq
Single-Cell Analysis
Spatial Analysis
Transcriptome
Visual Cortex
Zebrafish

Authors

Okochi, Yasushi
Sakaguchi, Shunta
Nakae, Ken
Kondo, Takefumi
Naoki, Honda

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