Producing genome structure populations with the dynamic and automated PGS software

Nan, Haiyang; Tjong, Harianto; Shin, Hanjun; Gong, Ke; Zhou, Xianghong Jasmine; Alber, Frank

doi:10.1038/nprot.2018.008

Cited by 67 publications

(66 citation statements)

References 46 publications

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“…Several data-driven approaches have been developed in order to go from Hi-C to 3D structure of genomes [10][11][12][13][14][15][16][17] (see the summary in [18] for additional related studies). Although these methods are insightful, they do not predict the physical dimensions of the organized chromosomes nor have the methods been validated, especially when the structures are highly heterogeneous.…”

Section: Introductionmentioning

confidence: 99%

From Hi-C Contact Map to Three-dimensional Organization of Interphase Human Chromosomes

Shi

Thirumalai

2020

Preprint

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The probabilities that two loci in chromosomes that are separated by a certain genome length can be inferred using chromosome conformation capture method and related Hi-C experiments. How to go from such maps to an ensemble of three-dimensional structures, which is an important step in understanding the way nature has solved the packaging of the hundreds of million base pair chromosomes in tight spaces, is an open problem. We created a theory based on polymer physics and the maximum entropy principle, leading to the HIPPS (Hi-C-Polymer-Physics-Structures) method allows us to go from contact maps to 3D structures. It is difficult to calculate the mean distance ( rij ) between loci i and j from the contact probability ( pij ) because the contact exists only in a fraction (unknown) of cell populations. Despite this massive heterogeneity, we first prove that there is a theoretical lower bound connecting pij and rij via a power-law relation. We show, using simulations of a precisely solvable model, that the overall organization is accurately captured by constructing the distance map from the contact map even when the cell population is heterogeneous, thus justifying the use of the lower bound. Building on these results and using the mean distance matrix, whose elements are rij , we use maximum entropy principle to reconstruct the joint distribution of spatial positions of the loci, which creates an ensemble of structures for the 23 chromosomes from lymphoblastoid cells. The HIPPS method shows that the conformations of a given chromosome are highly heterogeneous even in a single cell type. Nevertheless, the differences in the heterogeneity of the same chromosome in different cell types (normal as well as cancerous cells) can be quantitatively discerned using our theory.

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Section: Introductionmentioning

confidence: 99%

From Hi-C Contact Map to Three-dimensional Organization of Interphase Human Chromosomes

Shi

Thirumalai

2020

Preprint

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“…Independent of the underlying physical processes, important computational approaches to reconstruct chromosome threedimensional (3D) conformations have been also developed by optimizing scoring functions of Hi-C data to extract a consensus structure (Duan et al, 2010;Hu et al, 2013;Lesne, Riposo, Roger, Cournac, & Mozziconacci, 2014;Peng et al, 2013;Varoquaux, Ay, Noble, & Vert, 2014;Zhang, Li, Toh, & Sung, 2013), its variability by resampling methods (Baù et al, 2011;Rousseau, Fraser, Ferraiuolo, Dostie, & Blanchette, 2011;Serra et al, 2017), population of individual structures by likelihood maximization of contact data and other information (Giorgietti, Galupa, Nora, et al, 2014;Hua et al, 2018;Kalhor, Tjong, Jayathilaka, Alber, & Chen, 2012;Zhang & Wolynes, 2015). However, they are not discussed here.…”

Section: Introductionmentioning

confidence: 99%

Models of polymer physics for the architecture of the cell nucleus

Esposito

Annunziatella

Bianco

et al. 2018

WIREs Mechanisms of Disease

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The depth and complexity of data now available on chromosome 3D architecture, derived by new technologies such as Hi‐C, have triggered the development of models based on polymer physics to explain the observed patterns and the underlying molecular folding mechanisms. Here, we give an overview of some of the ideas and models from physics introduced to date, along with their progresses and limitations in the description of experimental data. In particular, we focus on the Strings&Binders and the Loop Extrusion model of chromatin architecture. This article is categorized under: Analytical and Computational Methods > Computational Methods

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“…The Hi-C subcompartment predictions from SNIPER can be compared to results based on other analysis approaches and datasets. For example, we expect that the SNIPER predictions of Hi-C subcompartments can be used to further validate and compare with results from polymer simulations (Sanborn et al, 2015;Nuebler et al, 2018), 3D genome structure population modeling Hua et al, 2018), and regulatory communities mining based on whole-genome chromatin interactomes . In addition, recently published new genome-wide mapping methods (Chen et al, 2018;Quinodoz et al, 2018;Beagrie et al, 2017) may provide additional training data other than Hi-C, as well as experimental data validation to improve our method.…”

Section: Discussionmentioning

confidence: 99%

Revealing Hi-C subcompartments by imputing high-resolution inter-chromosomal chromatin interactions

Xiong

2018

Preprint

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The higher-order genome organization and its variation in different cellular conditions remains poorly understood. Recent high-resolution genome-wide mapping of chromatin interactions using Hi-C has revealed that chromosomes in the human genome are spatially segregated into distinct subcompartments. However, due to the requirement on sequencing coverage of the Hi-C data to define subcompartments, to date subcompartment annotation is only available in the GM12878 cell line, making it impractical to compare Hi-C subcompartment patterns across multiple cell types. Here we develop a new computational approach, named SNIPER, based on an autoencoder and multilayer perceptron classifier to infer subcompartments using typical Hi-C datasets with moderate coverage. We demonstrated that SNIPER can accurately reveal subcompartments based on Hi-C datasets with moderate coverage and can significantly outperform an existing method that uses numerous epigenomic datasets as input features in GM12878. We applied SNIPER to eight additional cell lines to identify the variation of Hi-C subcompartments across different cell types. SNIPER revealed that chromosomal regions with conserved and more dynamic subcompartment annotations across cell types have different patterns of functional genomic features. This work demonstrates that SNIPER is effective in identifying subcompartments without the need of high-coverage Hi-C data and has the potential to provide new insights into the spatial genome organization variation across different cell types.

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Producing genome structure populations with the dynamic and automated PGS software

Cited by 67 publications

References 46 publications

From Hi-C Contact Map to Three-dimensional Organization of Interphase Human Chromosomes

From Hi-C Contact Map to Three-dimensional Organization of Interphase Human Chromosomes

Models of polymer physics for the architecture of the cell nucleus

Revealing Hi-C subcompartments by imputing high-resolution inter-chromosomal chromatin interactions

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