Your search keyword '"single cell multiomics integration"' showing total 3 results

1. Joint cell segmentation and cell type annotation for spatial transcriptomics

Author

Littman, Russell, Hemminger, Zachary, Foreman, Robert, Arneson, Douglas, Zhang, Guanglin, Gómez‐Pinilla, Fernando, Yang, Xia, and Wollman, Roy

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, 1.1 Normal biological development and functioning, Animals, Computer Simulation, Gene Expression Profiling, Mice, Neurons, RNA, Messenger, Transcriptome, cell segmentation and annotation, scRNAseq, single cell multiomics integration, spatial differentially expressed genes, spatial transcriptomics, Biochemistry and Cell Biology, Other Biological Sciences, Bioinformatics, Biochemistry and cell biology

Abstract

RNA hybridization-based spatial transcriptomics provides unparalleled detection sensitivity. However, inaccuracies in segmentation of image volumes into cells cause misassignment of mRNAs which is a major source of errors. Here, we develop JSTA, a computational framework for joint cell segmentation and cell type annotation that utilizes prior knowledge of cell type-specific gene expression. Simulation results show that leveraging existing cell type taxonomy increases RNA assignment accuracy by more than 45%. Using JSTA, we were able to classify cells in the mouse hippocampus into 133 (sub)types revealing the spatial organization of CA1, CA3, and Sst neuron subtypes. Analysis of within cell subtype spatial differential gene expression of 80 candidate genes identified 63 with statistically significant spatial differential gene expression across 61 (sub)types. Overall, our work demonstrates that known cell type expression patterns can be leveraged to improve the accuracy of RNA hybridization-based spatial transcriptomics while providing highly granular cell (sub)type information. The large number of newly discovered spatial gene expression patterns substantiates the need for accurate spatial transcriptomic measurements that can provide information beyond cell (sub)type labels.

Published

2021

2. Joint cell segmentation and cell type annotation for spatial transcriptomics

Author

Russell Littman, Zachary Hemminger, Robert Foreman, Douglas Arneson, Guanglin Zhang, Fernando Gómez‐Pinilla, Xia Yang, and Roy Wollman

Subjects

cell segmentation and annotation, scRNAseq, single cell multiomics integration, spatial differentially expressed genes, spatial transcriptomics, Biology (General), QH301-705.5, Medicine (General), R5-920

Abstract

Abstract RNA hybridization‐based spatial transcriptomics provides unparalleled detection sensitivity. However, inaccuracies in segmentation of image volumes into cells cause misassignment of mRNAs which is a major source of errors. Here, we develop JSTA, a computational framework for joint cell segmentation and cell type annotation that utilizes prior knowledge of cell type‐specific gene expression. Simulation results show that leveraging existing cell type taxonomy increases RNA assignment accuracy by more than 45%. Using JSTA, we were able to classify cells in the mouse hippocampus into 133 (sub)types revealing the spatial organization of CA1, CA3, and Sst neuron subtypes. Analysis of within cell subtype spatial differential gene expression of 80 candidate genes identified 63 with statistically significant spatial differential gene expression across 61 (sub)types. Overall, our work demonstrates that known cell type expression patterns can be leveraged to improve the accuracy of RNA hybridization‐based spatial transcriptomics while providing highly granular cell (sub)type information. The large number of newly discovered spatial gene expression patterns substantiates the need for accurate spatial transcriptomic measurements that can provide information beyond cell (sub)type labels.

Published

2021

3. Joint cell segmentation and cell type annotation for spatial transcriptomics

Author

Robert Foreman, Fernando Gomez-Pinilla, Douglas Arneson, Xia Yang, Guanglin Zhang, Russell Littman, Roy Wollman, and Zachary Hemminger

Subjects

Candidate gene, Medicine (General), Cell, Messenger, Chromatin, Epigenetics, Genomics & Functional Genomics, Transcriptome, Mice, 0302 clinical medicine, Gene expression, Segmentation, Biology (General), Spatial organization, cell segmentation and annotation, Neurons, 0303 health sciences, spatial transcriptomics, Applied Mathematics, Articles, scRNAseq, medicine.anatomical_structure, single cell multiomics integration, Computational Theory and Mathematics, General Agricultural and Biological Sciences, Information Systems, Biotechnology, Cell type, QH301-705.5, Bioinformatics, Methods & Resources, Computational biology, Biology, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, R5-920, medicine, Genetics, Animals, spatial differentially expressed genes, Computer Simulation, RNA, Messenger, 030304 developmental biology, General Immunology and Microbiology, Gene Expression Profiling, Computational Biology, RNA, Biochemistry and Cell Biology, Other Biological Sciences, 030217 neurology & neurosurgery

Abstract

RNA hybridization‐based spatial transcriptomics provides unparalleled detection sensitivity. However, inaccuracies in segmentation of image volumes into cells cause misassignment of mRNAs which is a major source of errors. Here, we develop JSTA, a computational framework for joint cell segmentation and cell type annotation that utilizes prior knowledge of cell type‐specific gene expression. Simulation results show that leveraging existing cell type taxonomy increases RNA assignment accuracy by more than 45%. Using JSTA, we were able to classify cells in the mouse hippocampus into 133 (sub)types revealing the spatial organization of CA1, CA3, and Sst neuron subtypes. Analysis of within cell subtype spatial differential gene expression of 80 candidate genes identified 63 with statistically significant spatial differential gene expression across 61 (sub)types. Overall, our work demonstrates that known cell type expression patterns can be leveraged to improve the accuracy of RNA hybridization‐based spatial transcriptomics while providing highly granular cell (sub)type information. The large number of newly discovered spatial gene expression patterns substantiates the need for accurate spatial transcriptomic measurements that can provide information beyond cell (sub)type labels., JSTA is a new computational method for joint cell segmentation and cell type annotation using spatial transcriptomics data and scRNAseq reference data.

Published

2021