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Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features

To initiate X-Chromosome inactivation (XCI), the long noncoding RNA Xist mediates chromosome-wide gene silencing of one X Chromosome in female mammals to equalize gene dosage between the sexes. The efficiency of gene silencing is highly variable across genes, with some genes even escaping XCI in som...

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Autores principales: Barros de Andrade e Sousa, Lisa, Jonkers, Iris, Syx, Laurène, Dunkel, Ilona, Chaumeil, Julie, Picard, Christel, Foret, Benjamin, Chen, Chong-Jian, Lis, John T., Heard, Edith, Schulz, Edda G., Marsico, Annalisa
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Cold Spring Harbor Laboratory Press 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6633258/
https://www.ncbi.nlm.nih.gov/pubmed/31175153
http://dx.doi.org/10.1101/gr.245027.118
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author Barros de Andrade e Sousa, Lisa
Jonkers, Iris
Syx, Laurène
Dunkel, Ilona
Chaumeil, Julie
Picard, Christel
Foret, Benjamin
Chen, Chong-Jian
Lis, John T.
Heard, Edith
Schulz, Edda G.
Marsico, Annalisa
author_facet Barros de Andrade e Sousa, Lisa
Jonkers, Iris
Syx, Laurène
Dunkel, Ilona
Chaumeil, Julie
Picard, Christel
Foret, Benjamin
Chen, Chong-Jian
Lis, John T.
Heard, Edith
Schulz, Edda G.
Marsico, Annalisa
author_sort Barros de Andrade e Sousa, Lisa
collection PubMed
description To initiate X-Chromosome inactivation (XCI), the long noncoding RNA Xist mediates chromosome-wide gene silencing of one X Chromosome in female mammals to equalize gene dosage between the sexes. The efficiency of gene silencing is highly variable across genes, with some genes even escaping XCI in somatic cells. A gene's susceptibility to Xist-mediated silencing appears to be determined by a complex interplay of epigenetic and genomic features; however, the underlying rules remain poorly understood. We have quantified chromosome-wide gene silencing kinetics at the level of the nascent transcriptome using allele-specific Precision nuclear Run-On sequencing (PRO-seq). We have developed a Random Forest machine-learning model that can predict the measured silencing dynamics based on a large set of epigenetic and genomic features and tested its predictive power experimentally. The genomic distance to the Xist locus, followed by gene density and distance to LINE elements, are the prime determinants of the speed of gene silencing. Moreover, we find two distinct gene classes associated with different silencing pathways: a class that requires Xist-repeat A for silencing, which is known to activate the SPEN pathway, and a second class in which genes are premarked by Polycomb complexes and tend to rely on the B repeat in Xist for silencing, known to recruit Polycomb complexes during XCI. Moreover, a series of features associated with active transcriptional elongation and chromatin 3D structure are enriched at rapidly silenced genes. Our machine-learning approach can thus uncover the complex combinatorial rules underlying gene silencing during X inactivation.
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spelling pubmed-66332582019-07-30 Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features Barros de Andrade e Sousa, Lisa Jonkers, Iris Syx, Laurène Dunkel, Ilona Chaumeil, Julie Picard, Christel Foret, Benjamin Chen, Chong-Jian Lis, John T. Heard, Edith Schulz, Edda G. Marsico, Annalisa Genome Res Research To initiate X-Chromosome inactivation (XCI), the long noncoding RNA Xist mediates chromosome-wide gene silencing of one X Chromosome in female mammals to equalize gene dosage between the sexes. The efficiency of gene silencing is highly variable across genes, with some genes even escaping XCI in somatic cells. A gene's susceptibility to Xist-mediated silencing appears to be determined by a complex interplay of epigenetic and genomic features; however, the underlying rules remain poorly understood. We have quantified chromosome-wide gene silencing kinetics at the level of the nascent transcriptome using allele-specific Precision nuclear Run-On sequencing (PRO-seq). We have developed a Random Forest machine-learning model that can predict the measured silencing dynamics based on a large set of epigenetic and genomic features and tested its predictive power experimentally. The genomic distance to the Xist locus, followed by gene density and distance to LINE elements, are the prime determinants of the speed of gene silencing. Moreover, we find two distinct gene classes associated with different silencing pathways: a class that requires Xist-repeat A for silencing, which is known to activate the SPEN pathway, and a second class in which genes are premarked by Polycomb complexes and tend to rely on the B repeat in Xist for silencing, known to recruit Polycomb complexes during XCI. Moreover, a series of features associated with active transcriptional elongation and chromatin 3D structure are enriched at rapidly silenced genes. Our machine-learning approach can thus uncover the complex combinatorial rules underlying gene silencing during X inactivation. Cold Spring Harbor Laboratory Press 2019-07 /pmc/articles/PMC6633258/ /pubmed/31175153 http://dx.doi.org/10.1101/gr.245027.118 Text en © 2019 Barros de Andrade e Sousa et al.; Published by Cold Spring Harbor Laboratory Press http://creativecommons.org/licenses/by-nc/4.0/ This article, published in Genome Research, is available under a Creative Commons License (Attribution-NonCommercial 4.0 International), as described at http://creativecommons.org/licenses/by-nc/4.0/.
spellingShingle Research
Barros de Andrade e Sousa, Lisa
Jonkers, Iris
Syx, Laurène
Dunkel, Ilona
Chaumeil, Julie
Picard, Christel
Foret, Benjamin
Chen, Chong-Jian
Lis, John T.
Heard, Edith
Schulz, Edda G.
Marsico, Annalisa
Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features
title Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features
title_full Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features
title_fullStr Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features
title_full_unstemmed Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features
title_short Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features
title_sort kinetics of xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features
topic Research
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6633258/
https://www.ncbi.nlm.nih.gov/pubmed/31175153
http://dx.doi.org/10.1101/gr.245027.118
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