TY - JOUR
T1 - Measuring the reproducibility and quality of Hi-C data
AU - Yardımcı, Galip Gürkan
AU - Ozadam, Hakan
AU - Sauria, Michael E.G.
AU - Ursu, Oana
AU - Yan, Koon Kiu
AU - Yang, Tao
AU - Chakraborty, Abhijit
AU - Kaul, Arya
AU - Lajoie, Bryan R.
AU - Song, Fan
AU - Zhan, Ye
AU - Ay, Ferhat
AU - Gerstein, Mark
AU - Kundaje, Anshul
AU - Li, Qunhua
AU - Taylor, James
AU - Yue, Feng
AU - Dekker, Job
AU - Noble, William S.
N1 - Publisher Copyright:
© 2019 The Author(s).
PY - 2019/3/19
Y1 - 2019/3/19
N2 - Background: Hi-C is currently the most widely used assay to investigate the 3D organization of the genome and to study its role in gene regulation, DNA replication, and disease. However, Hi-C experiments are costly to perform and involve multiple complex experimental steps; thus, accurate methods for measuring the quality and reproducibility of Hi-C data are essential to determine whether the output should be used further in a study. Results: Using real and simulated data, we profile the performance of several recently proposed methods for assessing reproducibility of population Hi-C data, including HiCRep, GenomeDISCO, HiC-Spector, and QuASAR-Rep. By explicitly controlling noise and sparsity through simulations, we demonstrate the deficiencies of performing simple correlation analysis on pairs of matrices, and we show that methods developed specifically for Hi-C data produce better measures of reproducibility. We also show how to use established measures, such as the ratio of intra- to interchromosomal interactions, and novel ones, such as QuASAR-QC, to identify low-quality experiments. Conclusions: In this work, we assess reproducibility and quality measures by varying sequencing depth, resolution and noise levels in Hi-C data from 13 cell lines, with two biological replicates each, as well as 176 simulated matrices. Through this extensive validation and benchmarking of Hi-C data, we describe best practices for reproducibility and quality assessment of Hi-C experiments. We make all software publicly available at http://github.com/kundajelab/3DChromatin_ReplicateQC to facilitate adoption in the community.
AB - Background: Hi-C is currently the most widely used assay to investigate the 3D organization of the genome and to study its role in gene regulation, DNA replication, and disease. However, Hi-C experiments are costly to perform and involve multiple complex experimental steps; thus, accurate methods for measuring the quality and reproducibility of Hi-C data are essential to determine whether the output should be used further in a study. Results: Using real and simulated data, we profile the performance of several recently proposed methods for assessing reproducibility of population Hi-C data, including HiCRep, GenomeDISCO, HiC-Spector, and QuASAR-Rep. By explicitly controlling noise and sparsity through simulations, we demonstrate the deficiencies of performing simple correlation analysis on pairs of matrices, and we show that methods developed specifically for Hi-C data produce better measures of reproducibility. We also show how to use established measures, such as the ratio of intra- to interchromosomal interactions, and novel ones, such as QuASAR-QC, to identify low-quality experiments. Conclusions: In this work, we assess reproducibility and quality measures by varying sequencing depth, resolution and noise levels in Hi-C data from 13 cell lines, with two biological replicates each, as well as 176 simulated matrices. Through this extensive validation and benchmarking of Hi-C data, we describe best practices for reproducibility and quality assessment of Hi-C experiments. We make all software publicly available at http://github.com/kundajelab/3DChromatin_ReplicateQC to facilitate adoption in the community.
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U2 - 10.1186/s13059-019-1658-7
DO - 10.1186/s13059-019-1658-7
M3 - Article
C2 - 30890172
AN - SCOPUS:85063156719
SN - 1474-7596
VL - 20
JO - Genome biology
JF - Genome biology
IS - 1
M1 - 57
ER -