Predicting molecular mechanisms of hereditary diseases by using their tissue-selective manifestation

Eyal Simonovsky; Moran Sharon; Maya Ziv; Omry Mauer; Idan Hekselman; Juman Jubran; Ekaterina Vinogradov; Chanan M. Argov; Omer Basha; Lior Kerber; Yuval Yogev; Ayellet V. Segrè; Hae Kyung Im; Ohad Birk; Lior Rokach; Esti Yeger-Lotem

doi:10.15252/msb.202211407

Predicting molecular mechanisms of hereditary diseases by using their tissue-selective manifestation

Eyal Simonovsky, Moran Sharon, Maya Ziv, Omry Mauer, Idan Hekselman, Juman Jubran, Ekaterina Vinogradov, Chanan M. Argov, Omer Basha, Lior Kerber, Yuval Yogev, Ayellet V. Segrè, Hae Kyung Im, Ohad Birk, Lior Rokach, Esti Yeger-Lotem

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

How do aberrations in widely expressed genes lead to tissue-selective hereditary diseases? Previous attempts to answer this question were limited to testing a few candidate mechanisms. To answer this question at a larger scale, we developed “Tissue Risk Assessment of Causality by Expression” (TRACE), a machine learning approach to predict genes that underlie tissue-selective diseases and selectivity-related features. TRACE utilized 4,744 biologically interpretable tissue-specific gene features that were inferred from heterogeneous omics datasets. Application of TRACE to 1,031 disease genes uncovered known and novel selectivity-related features, the most common of which was previously overlooked. Next, we created a catalog of tissue-associated risks for 18,927 protein-coding genes (https://netbio.bgu.ac.il/trace/). As proof-of-concept, we prioritized candidate disease genes identified in 48 rare-disease patients. TRACE ranked the verified disease gene among the patient's candidate genes significantly better than gene prioritization methods that rank by gene constraint or tissue expression. Thus, tissue selectivity combined with machine learning enhances genetic and clinical understanding of hereditary diseases.

Original language	English
Article number	e11407
Journal	Molecular Systems Biology
Volume	19
Issue number	8
DOIs	https://doi.org/10.15252/msb.202211407
State	Published - 8 Aug 2023

Keywords

data integration
genomic medicine
machine learning
omics
tissue selectivity

ASJC Scopus subject areas

Information Systems
General Biochemistry, Genetics and Molecular Biology
General Immunology and Microbiology
General Agricultural and Biological Sciences
Computational Theory and Mathematics
Applied Mathematics

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Simonovsky, E., Sharon, M., Ziv, M., Mauer, O., Hekselman, I., Jubran, J., Vinogradov, E., Argov, C. M., Basha, O., Kerber, L., Yogev, Y., Segrè, A. V., Im, H. K., Birk, O., Rokach, L., & Yeger-Lotem, E. (2023). Predicting molecular mechanisms of hereditary diseases by using their tissue-selective manifestation. Molecular Systems Biology, 19(8), Article e11407. https://doi.org/10.15252/msb.202211407

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title = "Predicting molecular mechanisms of hereditary diseases by using their tissue-selective manifestation",

abstract = "How do aberrations in widely expressed genes lead to tissue-selective hereditary diseases? Previous attempts to answer this question were limited to testing a few candidate mechanisms. To answer this question at a larger scale, we developed “Tissue Risk Assessment of Causality by Expression” (TRACE), a machine learning approach to predict genes that underlie tissue-selective diseases and selectivity-related features. TRACE utilized 4,744 biologically interpretable tissue-specific gene features that were inferred from heterogeneous omics datasets. Application of TRACE to 1,031 disease genes uncovered known and novel selectivity-related features, the most common of which was previously overlooked. Next, we created a catalog of tissue-associated risks for 18,927 protein-coding genes (https://netbio.bgu.ac.il/trace/). As proof-of-concept, we prioritized candidate disease genes identified in 48 rare-disease patients. TRACE ranked the verified disease gene among the patient's candidate genes significantly better than gene prioritization methods that rank by gene constraint or tissue expression. Thus, tissue selectivity combined with machine learning enhances genetic and clinical understanding of hereditary diseases.",

keywords = "data integration, genomic medicine, machine learning, omics, tissue selectivity",

author = "Eyal Simonovsky and Moran Sharon and Maya Ziv and Omry Mauer and Idan Hekselman and Juman Jubran and Ekaterina Vinogradov and Argov, {Chanan M.} and Omer Basha and Lior Kerber and Yuval Yogev and Segr{\`e}, {Ayellet V.} and Im, {Hae Kyung} and Ohad Birk and Lior Rokach and Esti Yeger-Lotem",

note = "Publisher Copyright: {\textcopyright} 2023 The Authors. Published under the terms of the CC BY 4.0 license.",

year = "2023",

month = aug,

day = "8",

doi = "10.15252/msb.202211407",

language = "English",

volume = "19",

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Simonovsky, E, Sharon, M, Ziv, M, Mauer, O, Hekselman, I, Jubran, J, Vinogradov, E, Argov, CM, Basha, O, Kerber, L, Yogev, Y, Segrè, AV, Im, HK, Birk, O, Rokach, L & Yeger-Lotem, E 2023, 'Predicting molecular mechanisms of hereditary diseases by using their tissue-selective manifestation', Molecular Systems Biology, vol. 19, no. 8, e11407. https://doi.org/10.15252/msb.202211407

TY - JOUR

T1 - Predicting molecular mechanisms of hereditary diseases by using their tissue-selective manifestation

AU - Simonovsky, Eyal

AU - Sharon, Moran

AU - Ziv, Maya

AU - Mauer, Omry

AU - Hekselman, Idan

AU - Jubran, Juman

AU - Vinogradov, Ekaterina

AU - Argov, Chanan M.

AU - Basha, Omer

AU - Kerber, Lior

AU - Yogev, Yuval

AU - Segrè, Ayellet V.

AU - Im, Hae Kyung

AU - Birk, Ohad

AU - Rokach, Lior

AU - Yeger-Lotem, Esti

PY - 2023/8/8

Y1 - 2023/8/8

N2 - How do aberrations in widely expressed genes lead to tissue-selective hereditary diseases? Previous attempts to answer this question were limited to testing a few candidate mechanisms. To answer this question at a larger scale, we developed “Tissue Risk Assessment of Causality by Expression” (TRACE), a machine learning approach to predict genes that underlie tissue-selective diseases and selectivity-related features. TRACE utilized 4,744 biologically interpretable tissue-specific gene features that were inferred from heterogeneous omics datasets. Application of TRACE to 1,031 disease genes uncovered known and novel selectivity-related features, the most common of which was previously overlooked. Next, we created a catalog of tissue-associated risks for 18,927 protein-coding genes (https://netbio.bgu.ac.il/trace/). As proof-of-concept, we prioritized candidate disease genes identified in 48 rare-disease patients. TRACE ranked the verified disease gene among the patient's candidate genes significantly better than gene prioritization methods that rank by gene constraint or tissue expression. Thus, tissue selectivity combined with machine learning enhances genetic and clinical understanding of hereditary diseases.

AB - How do aberrations in widely expressed genes lead to tissue-selective hereditary diseases? Previous attempts to answer this question were limited to testing a few candidate mechanisms. To answer this question at a larger scale, we developed “Tissue Risk Assessment of Causality by Expression” (TRACE), a machine learning approach to predict genes that underlie tissue-selective diseases and selectivity-related features. TRACE utilized 4,744 biologically interpretable tissue-specific gene features that were inferred from heterogeneous omics datasets. Application of TRACE to 1,031 disease genes uncovered known and novel selectivity-related features, the most common of which was previously overlooked. Next, we created a catalog of tissue-associated risks for 18,927 protein-coding genes (https://netbio.bgu.ac.il/trace/). As proof-of-concept, we prioritized candidate disease genes identified in 48 rare-disease patients. TRACE ranked the verified disease gene among the patient's candidate genes significantly better than gene prioritization methods that rank by gene constraint or tissue expression. Thus, tissue selectivity combined with machine learning enhances genetic and clinical understanding of hereditary diseases.

KW - data integration

KW - genomic medicine

KW - machine learning

KW - omics

KW - tissue selectivity

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AN - SCOPUS:85160076208

SN - 1744-4292

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JO - Molecular Systems Biology

JF - Molecular Systems Biology

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ER -

Predicting molecular mechanisms of hereditary diseases by using their tissue-selective manifestation

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