Innovative experimental protocols from Molecular Biology provided in recent years quantitative data about the structure of the cell nucleus. These technologies, such as Hi-C, GAM or SPRITE, revealed that the genome has a non-random three-dimensional (3D) spatial organization, which serves functional purposes. In order to dissect the complexity of chromosome folding, models from Polymer Physics have been employed, highlighting many key aspects of large-scale chromatin organization. A deep understanding of the molecular mechanisms underlying the genome architecture is currently a crucial problem in Biology, since chromatin misfolding or structural variants can reconfigure chromatin domains, thereby resulting in pathogenic phenotypes and disease. Here, we discuss a numerical Polymer-Physics-based approach (PRISMR), able to model 3D chromatin folding by using Machine Learning strategies informed with experimental data. Using as a case study the Pitx1 locus, a genomic region critically involved in hindlimb development, we show that the PRISMR algorithm reproduces in silico with high accuracy the experimental contact data, thus providing a powerful computational tool for analyzing and predicting the 3D chromatin structure.

Hybrid Machine Learning and Polymer Physics Approach to Investigate 3D Chromatin Structure / Conte, M.; Esposito, A.; Fiorillo, L.; Annunziatella, C.; Corrado, A.; Musella, F.; Sciarretta, R.; Chiariello, A. M.; Bianco, S.. - 11997:(2020), pp. 572-582. (Intervento presentato al convegno 25th International European Conference on Parallel and Distributed Computing, EuroPar 2019 tenutosi a deu nel 2019) [10.1007/978-3-030-48340-1_44].

Hybrid Machine Learning and Polymer Physics Approach to Investigate 3D Chromatin Structure

Esposito A.;Annunziatella C.;Chiariello A. M.
Co-ultimo
;
Bianco S.
2020

Abstract

Innovative experimental protocols from Molecular Biology provided in recent years quantitative data about the structure of the cell nucleus. These technologies, such as Hi-C, GAM or SPRITE, revealed that the genome has a non-random three-dimensional (3D) spatial organization, which serves functional purposes. In order to dissect the complexity of chromosome folding, models from Polymer Physics have been employed, highlighting many key aspects of large-scale chromatin organization. A deep understanding of the molecular mechanisms underlying the genome architecture is currently a crucial problem in Biology, since chromatin misfolding or structural variants can reconfigure chromatin domains, thereby resulting in pathogenic phenotypes and disease. Here, we discuss a numerical Polymer-Physics-based approach (PRISMR), able to model 3D chromatin folding by using Machine Learning strategies informed with experimental data. Using as a case study the Pitx1 locus, a genomic region critically involved in hindlimb development, we show that the PRISMR algorithm reproduces in silico with high accuracy the experimental contact data, thus providing a powerful computational tool for analyzing and predicting the 3D chromatin structure.
2020
978-3-030-48339-5
978-3-030-48340-1
Hybrid Machine Learning and Polymer Physics Approach to Investigate 3D Chromatin Structure / Conte, M.; Esposito, A.; Fiorillo, L.; Annunziatella, C.; Corrado, A.; Musella, F.; Sciarretta, R.; Chiariello, A. M.; Bianco, S.. - 11997:(2020), pp. 572-582. (Intervento presentato al convegno 25th International European Conference on Parallel and Distributed Computing, EuroPar 2019 tenutosi a deu nel 2019) [10.1007/978-3-030-48340-1_44].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/863897
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