Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>

The three-dimensional structure of chromatin in the cellular nucleus carries important information that is connected to physiological and pathological correlates and dysfunctional cell behaviour. As direct observation is not feasible at present, on one side, several experimental techniques have been...

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Main Authors: Claudia Caudai, Monica Zoppè, Anna Tonazzini, Ivan Merelli, Emanuele Salerno
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Biology
Subjects:
Online Access:https://www.mdpi.com/2079-7737/10/4/338
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spelling doaj-71508bb1e1144c39a10023ae005b6bc42021-04-16T23:06:41ZengMDPI AGBiology2079-77372021-04-011033833810.3390/biology10040338Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>Claudia Caudai0Monica Zoppè1Anna Tonazzini2Ivan Merelli3Emanuele Salerno4National Research Council of Italy, Institute of Information Science and Technologies, 56124 Pisa, ItalyNational Research Council of Italy, Institute of BioPhysics, 20133 Milano, ItalyNational Research Council of Italy, Institute of Information Science and Technologies, 56124 Pisa, ItalyNational Research Council of Italy, Institute of Biomedical Technologies, 20054 Segrate, ItalyNational Research Council of Italy, Institute of Information Science and Technologies, 56124 Pisa, ItalyThe three-dimensional structure of chromatin in the cellular nucleus carries important information that is connected to physiological and pathological correlates and dysfunctional cell behaviour. As direct observation is not feasible at present, on one side, several experimental techniques have been developed to provide information on the spatial organization of the DNA in the cell; on the other side, several computational methods have been developed to elaborate experimental data and infer 3D chromatin conformations. The most relevant experimental methods are Chromosome Conformation Capture and its derivatives, chromatin immunoprecipitation and sequencing techniques (CHIP-seq), RNA-seq, fluorescence in situ hybridization (FISH) and other genetic and biochemical techniques. All of them provide important and complementary information that relate to the three-dimensional organization of chromatin. However, these techniques employ very different experimental protocols and provide information that is not easily integrated, due to different contexts and different resolutions. Here, we present an open-source tool, which is an expansion of the previously reported code <i>ChromStruct</i>, for inferring the 3D structure of chromatin that, by exploiting a multilevel approach, allows an easy integration of information derived from different experimental protocols and referred to different resolution levels of the structure, from a few kilobases up to Megabases. Our results show that the introduction of chromatin modelling features related to CTCF CHIA-PET data, histone modification CHIP-seq, and RNA-seq data produce appreciable improvements in <i>ChromStruct</i>’s 3D reconstructions, compared to the use of HI-C data alone, at a local level and at a very high resolution.https://www.mdpi.com/2079-7737/10/4/338chromatin conformationbayesian statisticsHI-C datachromatin conformation captureCTCF CHIA-PET dataCHIP-seq
collection DOAJ
language English
format Article
sources DOAJ
author Claudia Caudai
Monica Zoppè
Anna Tonazzini
Ivan Merelli
Emanuele Salerno
spellingShingle Claudia Caudai
Monica Zoppè
Anna Tonazzini
Ivan Merelli
Emanuele Salerno
Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>
Biology
chromatin conformation
bayesian statistics
HI-C data
chromatin conformation capture
CTCF CHIA-PET data
CHIP-seq
author_facet Claudia Caudai
Monica Zoppè
Anna Tonazzini
Ivan Merelli
Emanuele Salerno
author_sort Claudia Caudai
title Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>
title_short Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>
title_full Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>
title_fullStr Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>
title_full_unstemmed Integration of Multiple Resolution Data in 3D Chromatin Reconstruction Using <i>ChromStruct</i>
title_sort integration of multiple resolution data in 3d chromatin reconstruction using <i>chromstruct</i>
publisher MDPI AG
series Biology
issn 2079-7737
publishDate 2021-04-01
description The three-dimensional structure of chromatin in the cellular nucleus carries important information that is connected to physiological and pathological correlates and dysfunctional cell behaviour. As direct observation is not feasible at present, on one side, several experimental techniques have been developed to provide information on the spatial organization of the DNA in the cell; on the other side, several computational methods have been developed to elaborate experimental data and infer 3D chromatin conformations. The most relevant experimental methods are Chromosome Conformation Capture and its derivatives, chromatin immunoprecipitation and sequencing techniques (CHIP-seq), RNA-seq, fluorescence in situ hybridization (FISH) and other genetic and biochemical techniques. All of them provide important and complementary information that relate to the three-dimensional organization of chromatin. However, these techniques employ very different experimental protocols and provide information that is not easily integrated, due to different contexts and different resolutions. Here, we present an open-source tool, which is an expansion of the previously reported code <i>ChromStruct</i>, for inferring the 3D structure of chromatin that, by exploiting a multilevel approach, allows an easy integration of information derived from different experimental protocols and referred to different resolution levels of the structure, from a few kilobases up to Megabases. Our results show that the introduction of chromatin modelling features related to CTCF CHIA-PET data, histone modification CHIP-seq, and RNA-seq data produce appreciable improvements in <i>ChromStruct</i>’s 3D reconstructions, compared to the use of HI-C data alone, at a local level and at a very high resolution.
topic chromatin conformation
bayesian statistics
HI-C data
chromatin conformation capture
CTCF CHIA-PET data
CHIP-seq
url https://www.mdpi.com/2079-7737/10/4/338
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