MOTIVATION: Recent experimental advancements allow determining positions of nucleosomes for complete genomes. However, the resulting nucleosome occupancy maps are averages of heterogeneous cell populations. Accordingly, they represent a snapshot of a dynamic ensemble at a single time point with an overlay of many configurations from different cells. To study the organization of nucleosomes along the genome and to understand the mechanisms of nucleosome translocation, it is necessary to retrieve features of specific conformations from the population average. RESULTS: Here, we present a method for identifying non-overlapping nucleosome configurations that combines binary-variable analysis and a Monte Carlo approach with a simulated annealing scheme. In this manner, we obtain specific nucleosome configurations and optimized solutions for the complex positioning patterns from experimental data. We apply the method to compare nucleosome positioning at transcription factor binding sites in different mouse cell types. Our method can model nucleosome translocations at regulatory genomic elements and generate configurations for simulations of the spatial folding of the nucleosome chain. AVAILABILITY: Source code, precompiled binaries, test data and a web-based test installation are freely available at http://bioinformatics.fh-stralsund.de/nucpos/
MOTIVATION: Recent experimental advancements allow determining positions of nucleosomes for complete genomes. However, the resulting nucleosome occupancy maps are averages of heterogeneous cell populations. Accordingly, they represent a snapshot of a dynamic ensemble at a single time point with an overlay of many configurations from different cells. To study the organization of nucleosomes along the genome and to understand the mechanisms of nucleosome translocation, it is necessary to retrieve features of specific conformations from the population average. RESULTS: Here, we present a method for identifying non-overlapping nucleosome configurations that combines binary-variable analysis and a Monte Carlo approach with a simulated annealing scheme. In this manner, we obtain specific nucleosome configurations and optimized solutions for the complex positioning patterns from experimental data. We apply the method to compare nucleosome positioning at transcription factor binding sites in different mouse cell types. Our method can model nucleosome translocations at regulatory genomic elements and generate configurations for simulations of the spatial folding of the nucleosome chain. AVAILABILITY: Source code, precompiled binaries, test data and a web-based test installation are freely available at http://bioinformatics.fh-stralsund.de/nucpos/
Authors: Katharina Brandstetter; Tilo Zülske; Tobias Ragoczy; David Hörl; Miguel Guirao-Ortiz; Clemens Steinek; Toby Barnes; Gabriela Stumberger; Jonathan Schwach; Eric Haugen; Eric Rynes; Philipp Korber; John A Stamatoyannopoulos; Heinrich Leonhardt; Gero Wedemann; Hartmann Harz Journal: Biophys J Date: 2022-02-10 Impact factor: 4.033
Authors: Weiwei Dang; George L Sutphin; Jean A Dorsey; Gabriel L Otte; Kajia Cao; Rocco M Perry; Jennifer J Wanat; Dimitra Saviolaki; Christopher J Murakami; Scott Tsuchiyama; Brett Robison; Brian D Gregory; Michiel Vermeulen; Ramin Shiekhattar; F Brad Johnson; Brian K Kennedy; Matt Kaeberlein; Shelley L Berger Journal: Cell Metab Date: 2014-05-08 Impact factor: 27.287
Authors: Jie Xiong; Shan Gao; Wen Dui; Wentao Yang; Xiao Chen; Sean D Taverna; Ronald E Pearlman; Wendy Ashlock; Wei Miao; Yifan Liu Journal: Nucleic Acids Res Date: 2016-08-03 Impact factor: 16.971