Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci

Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci

Abstract Background Chromatin 3D conformation plays important roles in regulating gene or protein functions. High-throughout chromosome conformation capture (3C)-based technologies, such as Hi-C, have been exploited to acquire the contact frequencies among genomic loci at genome-scale. Various compu...

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Main Authors: Fang-Zhen Li, Zhi-E Liu, Xiu-Yuan Li, Li-Mei Bu, Hong-Xia Bu, Hui Liu, Cai-Ming Zhang
Format: Article
Language:English
Published: BMC 2020-07-01
Series:BMC Bioinformatics
Subjects:
3D organization
Chromosome
Hi-C
Reconstruction
MDS
Online Access:http://link.springer.com/article/10.1186/s12859-020-03612-4
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spelling doaj-baa7560a000b42f8b58237116bfa21b42020-11-25T03:39:23ZengBMCBMC Bioinformatics1471-21052020-07-0121111710.1186/s12859-020-03612-4Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic lociFang-Zhen Li0Zhi-E Liu1Xiu-Yuan Li2Li-Mei Bu3Hong-Xia Bu4Hui Liu5Cai-Ming Zhang6School of Computer Science and Technology, Shandong University of Finance and EconomicsCollege of Physics and Electronic Engineering, Qilu Normal UniversitySchool of Computer Science and Technology, Shandong University of Finance and EconomicsDepartment of Gastroenterology, Shanghai Pudong Hospital, Fudan University Pudong Medical CenterKey Laboratory of Machine Learning and Financial Data Mining in Universities of ShandongSchool of Computer Science and Technology, Shandong University of Finance and EconomicsSchool of Computer Science and Technology, Shandong University of Finance and EconomicsAbstract Background Chromatin 3D conformation plays important roles in regulating gene or protein functions. High-throughout chromosome conformation capture (3C)-based technologies, such as Hi-C, have been exploited to acquire the contact frequencies among genomic loci at genome-scale. Various computational tools have been proposed to recover the underlying chromatin 3D structures from in situ Hi-C contact map data. As connected residuals in a polymer, neighboring genomic loci have intrinsic mutual dependencies in building a 3D conformation. However, current methods seldom take this feature into account. Results We present a method called ShNeigh, which combines the classical MDS technique with local dependence of neighboring loci modeled by a Gaussian formula, to infer the best 3D structure from noisy and incomplete contact frequency matrices. We validated ShNeigh by comparing it to two typical distance-based algorithms, ShRec3D and ChromSDE. The comparison results on simulated Hi-C dataset showed that, while keeping the high-speed nature of classical MDS, ShNeigh can recover the true structure better than ShRec3D and ChromSDE. Meanwhile, ShNeigh is more robust to data noise. On the publicly available human GM06990 Hi-C data, we demonstrated that the structures reconstructed by ShNeigh are more reproducible between different restriction enzymes than by ShRec3D and ChromSDE, especially at high resolutions manifested by sparse contact maps, which means ShNeigh is more robust to signal coverage. Conclusions Our method can recover stable structures in high noise and sparse signal settings. It can also reconstruct similar structures from Hi-C data obtained using different restriction enzymes. Therefore, our method provides a new direction for enhancing the reconstruction quality of chromatin 3D structures.http://link.springer.com/article/10.1186/s12859-020-03612-43D organizationChromosomeHi-CReconstructionMDS
collection DOAJ
language English
format Article
sources DOAJ
author Fang-Zhen Li
Zhi-E Liu
Xiu-Yuan Li
Li-Mei Bu
Hong-Xia Bu
Hui Liu
Cai-Ming Zhang
spellingShingle Fang-Zhen Li
Zhi-E Liu
Xiu-Yuan Li
Li-Mei Bu
Hong-Xia Bu
Hui Liu
Cai-Ming Zhang
Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci
BMC Bioinformatics
3D organization
Chromosome
Hi-C
Reconstruction
MDS
author_facet Fang-Zhen Li
Zhi-E Liu
Xiu-Yuan Li
Li-Mei Bu
Hong-Xia Bu
Hui Liu
Cai-Ming Zhang
author_sort Fang-Zhen Li
title Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci
title_short Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci
title_full Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci
title_fullStr Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci
title_full_unstemmed Chromatin 3D structure reconstruction with consideration of adjacency relationship among genomic loci
title_sort chromatin 3d structure reconstruction with consideration of adjacency relationship among genomic loci
publisher BMC
series BMC Bioinformatics
issn 1471-2105
publishDate 2020-07-01
description Abstract Background Chromatin 3D conformation plays important roles in regulating gene or protein functions. High-throughout chromosome conformation capture (3C)-based technologies, such as Hi-C, have been exploited to acquire the contact frequencies among genomic loci at genome-scale. Various computational tools have been proposed to recover the underlying chromatin 3D structures from in situ Hi-C contact map data. As connected residuals in a polymer, neighboring genomic loci have intrinsic mutual dependencies in building a 3D conformation. However, current methods seldom take this feature into account. Results We present a method called ShNeigh, which combines the classical MDS technique with local dependence of neighboring loci modeled by a Gaussian formula, to infer the best 3D structure from noisy and incomplete contact frequency matrices. We validated ShNeigh by comparing it to two typical distance-based algorithms, ShRec3D and ChromSDE. The comparison results on simulated Hi-C dataset showed that, while keeping the high-speed nature of classical MDS, ShNeigh can recover the true structure better than ShRec3D and ChromSDE. Meanwhile, ShNeigh is more robust to data noise. On the publicly available human GM06990 Hi-C data, we demonstrated that the structures reconstructed by ShNeigh are more reproducible between different restriction enzymes than by ShRec3D and ChromSDE, especially at high resolutions manifested by sparse contact maps, which means ShNeigh is more robust to signal coverage. Conclusions Our method can recover stable structures in high noise and sparse signal settings. It can also reconstruct similar structures from Hi-C data obtained using different restriction enzymes. Therefore, our method provides a new direction for enhancing the reconstruction quality of chromatin 3D structures.
topic 3D organization
Chromosome
Hi-C
Reconstruction
MDS
url http://link.springer.com/article/10.1186/s12859-020-03612-4
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