Your search keyword '"Pei-Yin Hsu"' showing total 3 results

1. Estrogen induces global reorganization of chromatin structure in human breast cancer cells.

Author

Raphaël Mourad, Pei-Yin Hsu, Liran Juan, Changyu Shen, Prasad Koneru, Hai Lin, Yunlong Liu, Kenneth Nephew, Tim H Huang, and Lang Li

Subjects

Medicine, Science

Abstract

In the cell nucleus, each chromosome is confined to a chromosome territory. This spatial organization of chromosomes plays a crucial role in gene regulation and genome stability. An additional level of organization has been discovered at the chromosome scale: the spatial segregation into open and closed chromatins to form two genome-wide compartments. Although considerable progress has been made in our knowledge of chromatin organization, a fundamental issue remains the understanding of its dynamics, especially in cancer. To address this issue, we performed genome-wide mapping of chromatin interactions (Hi-C) over the time after estrogen stimulation of breast cancer cells. To biologically interpret these interactions, we integrated with estrogen receptor α (ERα) binding events, gene expression and epigenetic marks. We show that gene-rich chromosomes as well as areas of open and highly transcribed chromatins are rearranged to greater spatial proximity, thus enabling genes to share transcriptional machinery and regulatory elements. At a smaller scale, differentially interacting loci are enriched for cancer proliferation and estrogen-related genes. Moreover, these loci are correlated with higher ERα binding events and gene expression. Taken together these results reveal the role of a hormone--estrogen--on genome organization, and its effect on gene regulation in cancer.

Published

2014

2. LOcating non-unique matched tags (LONUT) to improve the detection of the enriched regions for ChIP-seq data.

Author

Rui Wang, Hang-Kai Hsu, Adam Blattler, Yisong Wang, Xun Lan, Yao Wang, Pei-Yin Hsu, Yu-Wei Leu, Tim H-M Huang, Peggy J Farnham, and Victor X Jin

Subjects

Medicine, Science

Abstract

One big limitation of computational tools for analyzing ChIP-seq data is that most of them ignore non-unique tags (NUTs) that match the human genome even though NUTs comprise up to 60% of all raw tags in ChIP-seq data. Effectively utilizing these NUTs would increase the sequencing depth and allow a more accurate detection of enriched binding sites, which in turn could lead to more precise and significant biological interpretations. In this study, we have developed a computational tool, LOcating Non-Unique matched Tags (LONUT), to improve the detection of enriched regions from ChIP-seq data. Our LONUT algorithm applies a linear and polynomial regression model to establish an empirical score (ES) formula by considering two influential factors, the distance of NUTs to peaks identified using uniquely matched tags (UMTs) and the enrichment score for those peaks resulting in each NUT being assigned to a unique location on the reference genome. The newly located tags from the set of NUTs are combined with the original UMTs to produce a final set of combined matched tags (CMTs). LONUT was tested on many different datasets representing three different characteristics of biological data types. The detected sites were validated using de novo motif discovery and ChIP-PCR. We demonstrate the specificity and accuracy of LONUT and show that our program not only improves the detection of binding sites for ChIP-seq, but also identifies additional binding sites.

Published

2013

3. LOcating Non-Unique matched Tags (LONUT) to Improve the Detection of the Enriched Regions for ChIP-seq Data

Author

Pei Yin Hsu, Tim H M Huang, Peggy J. Farnham, Xun Lan, Adam Blattler, Yu-Wei Leu, Hang Kai Hsu, Yisong Wang, Yao Wang, Rui Wang, and Victor X. Jin

Subjects

Chromatin Immunoprecipitation, Statistics as Topic, lcsh:Medicine, Biology, Bioinformatics, Deep sequencing, Genome Analysis Tools, Humans, Base sequence, Genome Sequencing, lcsh:Science, Biological data, Multidisciplinary, Base Sequence, business.industry, lcsh:R, Linear model, Computational Biology, Pattern recognition, Genomics, Chip, Computer Science, Linear Models, MCF-7 Cells, lcsh:Q, Human genome, Artificial intelligence, K562 Cells, business, Sequence Analysis, Algorithms, Polynomial regression model, Research Article, Reference genome

Abstract

One big limitation of computational tools for analyzing ChIP-seq data is that most of them ignore non-unique tags (NUTs) that match the human genome even though NUTs comprise up to 60% of all raw tags in ChIP-seq data. Effectively utilizing these NUTs would increase the sequencing depth and allow a more accurate detection of enriched binding sites, which in turn could lead to more precise and significant biological interpretations. In this study, we have developed a computational tool, LOcating Non-Unique matched Tags (LONUT), to improve the detection of enriched regions from ChIP-seq data. Our LONUT algorithm applies a linear and polynomial regression model to establish an empirical score (ES) formula by considering two influential factors, the distance of NUTs to peaks identified using uniquely matched tags (UMTs) and the enrichment score for those peaks resulting in each NUT being assigned to a unique location on the reference genome. The newly located tags from the set of NUTs are combined with the original UMTs to produce a final set of combined matched tags (CMTs). LONUT was tested on many different datasets representing three different characteristics of biological data types. The detected sites were validated using de novo motif discovery and ChIP-PCR. We demonstrate the specificity and accuracy of LONUT and show that our program not only improves the detection of binding sites for ChIP-seq, but also identifies additional binding sites.

Published

2013