Your search keyword '"probabilistic model"' showing total 7 results

1. Celloscope: a probabilistic model for marker-gene-driven cell type deconvolution in spatial transcriptomics data

Author

Agnieszka Geras, Shadi Darvish Shafighi, Kacper Domżał, Igor Filipiuk, Alicja Rączkowska, Paulina Szymczak, Hosein Toosi, Leszek Kaczmarek, Łukasz Koperski, Jens Lagergren, Dominika Nowis, and Ewa Szczurek

Subjects

Probabilistic model, MCMC sampling, Spatial transcriptomics data, Cell types, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Spatial transcriptomics maps gene expression across tissues, posing the challenge of determining the spatial arrangement of different cell types. However, spatial transcriptomics spots contain multiple cells. Therefore, the observed signal comes from mixtures of cells of different types. Here, we propose an innovative probabilistic model, Celloscope, that utilizes established prior knowledge on marker genes for cell type deconvolution from spatial transcriptomics data. Celloscope outperforms other methods on simulated data, successfully indicates known brain structures and spatially distinguishes between inhibitory and excitatory neuron types based in mouse brain tissue, and dissects large heterogeneity of immune infiltrate composition in prostate gland tissue.

Published

2023

2. CONET: copy number event tree model of evolutionary tumor history for single-cell data

Author

Magda Markowska, Tomasz Cąkała, BłaŻej Miasojedow, Bogac Aybey, Dilafruz Juraeva, Johanna Mazur, Edith Ross, Eike Staub, and Ewa Szczurek

Subjects

Copy number alterations, Tumor evolution, Single-cell sequencing, Probabilistic model, MCMC sampling, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Copy number alterations constitute important phenomena in tumor evolution. Whole genome single-cell sequencing gives insight into copy number profiles of individual cells, but is highly noisy. Here, we propose CONET, a probabilistic model for joint inference of the evolutionary tree on copy number events and copy number calling. CONET employs an efficient, regularized MCMC procedure to search the space of possible model structures and parameters. We introduce a range of model priors and penalties for efficient regularization. CONET reveals copy number evolution in two breast cancer samples, and outperforms other methods in tree reconstruction, breakpoint identification and copy number calling.

Published

2022

3. An integrated multi-omics approach to identify regulatory mechanisms in cancer metastatic processes

Author

Saba Ghaffari, Casey Hanson, Remington E. Schmidt, Kelly J. Bouchonville, Steven M. Offer, and Saurabh Sinha

Subjects

Colon cancer, Metastasis, Transcriptional regulation, Multi-omics, Probabilistic model, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Background Metastatic progress is the primary cause of death in most cancers, yet the regulatory dynamics driving the cellular changes necessary for metastasis remain poorly understood. Multi-omics approaches hold great promise for addressing this challenge; however, current analysis tools have limited capabilities to systematically integrate transcriptomic, epigenomic, and cistromic information to accurately define the regulatory networks critical for metastasis. Results To address this limitation, we use a purposefully generated cellular model of colon cancer invasiveness to generate multi-omics data, including expression, accessibility, and selected histone modification profiles, for increasing levels of invasiveness. We then adopt a rigorous probabilistic framework for joint inference from the resulting heterogeneous data, along with transcription factor binding profiles. Our approach uses probabilistic graphical models to leverage the functional information provided by specific epigenomic changes, models the influence of multiple transcription factors simultaneously, and automatically learns the activating or repressive roles of cis-regulatory events. Global analysis of these relationships reveals key transcription factors driving invasiveness, as well as their likely target genes. Disrupting the expression of one of the highly ranked transcription factors JunD, an AP-1 complex protein, confirms functional relevance to colon cancer cell migration and invasion. Transcriptomic profiling confirms key regulatory targets of JunD, and a gene signature derived from the model demonstrates strong prognostic potential in TCGA colorectal cancer data. Conclusions Our work sheds new light into the complex molecular processes driving colon cancer metastasis and presents a statistically sound integrative approach to analyze multi-omics profiles of a dynamic biological process.

Published

2021

4. Celloscope: a probabilistic model for marker-gene-driven cell type deconvolution in spatial transcriptomics data

Author

Geras, Agnieszka, Darvish Shafighi, Shadi, Domżał, Kacper, Filipiuk, Igor, Rączkowska, Alicja, Szymczak, Paulina, Toosi, Hosein, Kaczmarek, Leszek, Koperski, Łukasz, Lagergren, Jens, Nowis, Dominika, and Szczurek, Ewa

Published

2023

5. CONET: copy number event tree model of evolutionary tumor history for single-cell data

Author

Markowska, Magda, Cąkała, Tomasz, Miasojedow, BłaŻej, Aybey, Bogac, Juraeva, Dilafruz, Mazur, Johanna, Ross, Edith, Staub, Eike, and Szczurek, Ewa

Published

2022

6. An integrated multi-omics approach to identify regulatory mechanisms in cancer metastatic processes

Author

Ghaffari, Saba, Hanson, Casey, Schmidt, Remington E., Bouchonville, Kelly J., Offer, Steven M., and Sinha, Saurabh

Published

2021

7. An integrated multi-omics approach to identify regulatory mechanisms in cancer metastatic processes

Author

Remington E. Schmidt, Saba Ghaffari, Steven M. Offer, Kelly J. Bouchonville, Casey Hanson, and Saurabh Sinha

Subjects

Epigenomics, lcsh:QH426-470, Proto-Oncogene Proteins c-jun, Computational biology, Biology, Metastasis, Histones, Transcriptome, Transcriptional regulation, Cell Movement, Cell Line, Tumor, Neoplasms, medicine, Humans, Neoplasm Metastasis, lcsh:QH301-705.5, Transcription factor, Multi-omics, Research, Gene Expression Profiling, Probabilistic model, Cancer, Prognosis, medicine.disease, Human genetics, Colon cancer, Gene Expression Regulation, Neoplastic, Transcription Factor AP-1, lcsh:Genetics, lcsh:Biology (General), Colonic Neoplasms, Cellular model, Transcription Factors

Abstract

Background Metastatic progress is the primary cause of death in most cancers, yet the regulatory dynamics driving the cellular changes necessary for metastasis remain poorly understood. Multi-omics approaches hold great promise for addressing this challenge; however, current analysis tools have limited capabilities to systematically integrate transcriptomic, epigenomic, and cistromic information to accurately define the regulatory networks critical for metastasis. Results To address this limitation, we use a purposefully generated cellular model of colon cancer invasiveness to generate multi-omics data, including expression, accessibility, and selected histone modification profiles, for increasing levels of invasiveness. We then adopt a rigorous probabilistic framework for joint inference from the resulting heterogeneous data, along with transcription factor binding profiles. Our approach uses probabilistic graphical models to leverage the functional information provided by specific epigenomic changes, models the influence of multiple transcription factors simultaneously, and automatically learns the activating or repressive roles of cis-regulatory events. Global analysis of these relationships reveals key transcription factors driving invasiveness, as well as their likely target genes. Disrupting the expression of one of the highly ranked transcription factors JunD, an AP-1 complex protein, confirms functional relevance to colon cancer cell migration and invasion. Transcriptomic profiling confirms key regulatory targets of JunD, and a gene signature derived from the model demonstrates strong prognostic potential in TCGA colorectal cancer data. Conclusions Our work sheds new light into the complex molecular processes driving colon cancer metastasis and presents a statistically sound integrative approach to analyze multi-omics profiles of a dynamic biological process.

Published

2021