Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis
The packing of genomic DNA from double helix into highly-order hierarchical assemblies has a great impact on chromosome flexibility, dynamics and functions. The open and accessible regions of chromosomes are primary binding positions for regulatory elements and are crucial to nuclear processes and b...
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sg-ntu-dr.10356-1623792022-10-17T05:36:45Z Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis Peng, Jiajie Yang, Jinjin Anand, D. Vijay Shang, Xuequn Xia, Kelin School of Physical and Mathematical Sciences School of Biological Sciences Science::Biological sciences 3D Genome Chromosome Flexibility The packing of genomic DNA from double helix into highly-order hierarchical assemblies has a great impact on chromosome flexibility, dynamics and functions. The open and accessible regions of chromosomes are primary binding positions for regulatory elements and are crucial to nuclear processes and biological functions. Motivated by the success of flexibility-rigidity index (FRI) in biomolecular flexibility analysis and drug design, we propose an FRI-based model for quantitatively characterizing chromosome flexibility. Based on Hi-C data, a flexibility index for each locus can be evaluated. Physically, flexibility is tightly related to packing density. Highly compacted regions are usually more rigid, while loosely packed regions are more flexible. Indeed, a strong correlation is found between our flexibility index and DNase and ATAC values, which are measurements for chromosome accessibility. In addition, the genome regions with higher chromosome flexibility have a higher chance to be bound by transcription factors. Recently, the Gaussian network model (GNM) is applied to analyze the chromosome accessibility and a mobility profile has been proposed to characterize chromosome flexibility. Compared with GNM, our FRI is slightly more accurate (1% to 2% increase) and significantly more efficient in both computational time and costs. For a 5Kb resolution Hi-C data, the flexibility evaluation process only takes FRI a few minutes on a single-core processor. In contrast, GNM requires 1.5 hours on 10 CPUs. Moreover, interchromosome interactions can be easily combined into the flexibility evaluation, thus further enhancing the accuracy of our FRI. In contrast, the consideration of interchromosome information into GNM will significantly increase the size of its Laplacian (or Kirchhoff) matrix, thus becoming computationally extremely challenging for the current GNM. The software and supplementary document are available at https://github.com/jiajiepeng/FRI_chrFle. Ministry of Education (MOE) Nanyang Technological University This work was supported in part by Nanyang Technological University Startup (M4081842.110), Singapore Ministry of Education Academic Research fund (Tier 1 RG126/16, RG31/18), and the National Natural Science Foundation of China (Grant Nos. 61702421, 61332014, 61772426). 2022-10-17T05:36:45Z 2022-10-17T05:36:45Z 2022 Journal Article Peng, J., Yang, J., Anand, D. V., Shang, X. & Xia, K. (2022). Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis. Frontiers of Computer Science, 16(4). https://dx.doi.org/10.1007/s11704-021-0304-1 2095-2228 https://hdl.handle.net/10356/162379 10.1007/s11704-021-0304-1 2-s2.0-85120744993 4 16 en M4081842.110 Tier 1 RG126/16 RG31/18 Frontiers of Computer Science © Higher Education Press 2022. All rights reserved. |
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Science::Biological sciences 3D Genome Chromosome Flexibility Peng, Jiajie Yang, Jinjin Anand, D. Vijay Shang, Xuequn Xia, Kelin Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis |
| description |
The packing of genomic DNA from double helix into highly-order hierarchical assemblies has a great impact on chromosome flexibility, dynamics and functions. The open and accessible regions of chromosomes are primary binding positions for regulatory elements and are crucial to nuclear processes and biological functions. Motivated by the success of flexibility-rigidity index (FRI) in biomolecular flexibility analysis and drug design, we propose an FRI-based model for quantitatively characterizing chromosome flexibility. Based on Hi-C data, a flexibility index for each locus can be evaluated. Physically, flexibility is tightly related to packing density. Highly compacted regions are usually more rigid, while loosely packed regions are more flexible. Indeed, a strong correlation is found between our flexibility index and DNase and ATAC values, which are measurements for chromosome accessibility. In addition, the genome regions with higher chromosome flexibility have a higher chance to be bound by transcription factors. Recently, the Gaussian network model (GNM) is applied to analyze the chromosome accessibility and a mobility profile has been proposed to characterize chromosome flexibility. Compared with GNM, our FRI is slightly more accurate (1% to 2% increase) and significantly more efficient in both computational time and costs. For a 5Kb resolution Hi-C data, the flexibility evaluation process only takes FRI a few minutes on a single-core processor. In contrast, GNM requires 1.5 hours on 10 CPUs. Moreover, interchromosome interactions can be easily combined into the flexibility evaluation, thus further enhancing the accuracy of our FRI. In contrast, the consideration of interchromosome information into GNM will significantly increase the size of its Laplacian (or Kirchhoff) matrix, thus becoming computationally extremely challenging for the current GNM. The software and supplementary document are available at https://github.com/jiajiepeng/FRI_chrFle. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Peng, Jiajie Yang, Jinjin Anand, D. Vijay Shang, Xuequn Xia, Kelin |
| format |
Article |
| author |
Peng, Jiajie Yang, Jinjin Anand, D. Vijay Shang, Xuequn Xia, Kelin |
| author_sort |
Peng, Jiajie |
| title |
Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis |
| title_short |
Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis |
| title_full |
Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis |
| title_fullStr |
Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis |
| title_full_unstemmed |
Flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis |
| title_sort |
flexibility and rigidity index for chromosome packing, flexibility and dynamics analysis |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/162379 |
| _version_ |
1749179171374891008 |