DNA methylation is an important epigenetic modification that plays crucial roles in multiple biological processes. Technical advance, especially a variety of deep sequencing-based techniques, have made it possible to monitor DNA methylome changes at a single-base resolution. However, how to interpret the epigenetic information encoded by the fast accumulating methylome data is still challenging. DNA methylation is traditionally considered to disrupt the interactions between transcription factors (TFs) and cis-regulatory regions and thus, silence the expression of downstream target genes. However, recent studies, especially our recent discoveries, suggest that many TFs and co-factors preferentially bind to methylated DNA motifs and, in some cases, transactivate downstream gene expression, challenging the current paradigm of DNA methylation in transcription regulation. Identification of comprehensive sets of functional methylation sites and their interacting partners will greatly expand the protein-DNA interaction landscape in a new direction and promise significant advances in the understanding of the biological roles of DNA methylation. To achieve these goals, we propose four specific aims in this R01 application. First, we will survey all possible 8-base DNA sequence combinations to identify methylated sequences that can be recognized by human TFs. A pool of methylated DNA motifs will be probed on the human TF protein microarrays and the DNA fragments that are captured by the proteins on the microarrays will be recovered and their sequences determined with deep-sequencing. Second, we will predict which of these methylated motifs are likely to play a role in gene regulation and interact with proteins. Those 8-mer sequences that are statistically enriched in the recovered population will be mapped to the available methylomes and examine whether they overlap with the known regulatory regions. The qualified motifs will be synthesized and individually probed on the protein microarrays to identify their binding partners. Third, we will predict the protein domains that are responsible fo methylated DNA binding. The sequences from the same TF subfamilies will be compared and the positions that can best separated the proteins with and without methylated binding activities will be the candidates for methylation binding. The prediction will be tested by site-directed mutagenesis coupled with gel shift and cell-based luciferase assays. Finally, we will use both in vitro and in vivo models of mammalian axon regeneration to investigate the physiological roles of newly identified mCpG-dependent TF-DNA interactions. The positive results provided by this Aim will not only reveal novel epigenetic mechanisms of mammalian axon regeneration, but also provide proof-of-concept evidence that mCpG-dependent TF-DNA interactions are physiological regulators of gene expression.

Public Health Relevance

In this proposal we will generate the most comprehensive pictures of the methylation-dependent protein-DNA interaction landscape relevant to axon regeneration. This project is relevant to public health because the success of this project is expected to provide insights into the molecular mechanisms underlying human developmental biology and regenerative medicine. The proposed research is thus relevant to part of the NIH's mission as this advance in fundamental biological knowledge will help identify better therapeutics for a broad range of neuronal injuries.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM111514-03
Application #
9115212
Study Section
Genomics, Computational Biology and Technology Study Section (GCAT)
Program Officer
Carter, Anthony D
Project Start
2014-08-01
Project End
2018-07-31
Budget Start
2016-08-01
Budget End
2017-07-31
Support Year
3
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Johns Hopkins University
Department
Pharmacology
Type
Schools of Medicine
DUNS #
001910777
City
Baltimore
State
MD
Country
United States
Zip Code
21205
Li, Qiao; Qian, Cheng; Zhou, Feng-Quan (2018) Investigating Mammalian Axon Regeneration: In Vivo Electroporation of Adult Mouse Dorsal Root Ganglion. J Vis Exp :
Wang, Xue-Wei; Li, Qiao; Liu, Chang-Mei et al. (2018) Lin28 Signaling Supports Mammalian PNS and CNS Axon Regeneration. Cell Rep 24:2540-2552.e6
Yoon, Ki-Jun; Song, Guang; Qian, Xuyu et al. (2017) Zika-Virus-Encoded NS2A Disrupts Mammalian Cortical Neurogenesis by Degrading Adherens Junction Proteins. Cell Stem Cell 21:349-358.e6
Wan, Jun; Su, Yijing; Song, Qifeng et al. (2017) Methylated cis-regulatory elements mediate KLF4-dependent gene transactivation and cell migration. Elife 6:
Yang, Zhaoshou; Hou, Yongheng; Hao, Taofang et al. (2017) A Human Proteome Array Approach to Identifying Key Host Proteins Targeted by Toxoplasma Kinase ROP18. Mol Cell Proteomics 16:469-484
Huang, Yi; Zhu, Heng (2017) Protein Array-based Approaches for Biomarker Discovery in Cancer. Genomics Proteomics Bioinformatics 15:73-81
Liu, Sheng; Zibetti, Cristina; Wan, Jun et al. (2017) Assessing the model transferability for prediction of transcription factor binding sites based on chromatin accessibility. BMC Bioinformatics 18:355
Gao, Tianshun; He, Bing; Liu, Sheng et al. (2016) EnhancerAtlas: a resource for enhancer annotation and analysis in 105 human cell/tissue types. Bioinformatics 32:3543-3551
Wang, Jie; Xia, Shuli; Arand, Brian et al. (2016) Single-Cell Co-expression Analysis Reveals Distinct Functional Modules, Co-regulation Mechanisms and Clinical Outcomes. PLoS Comput Biol 12:e1004892
Moore, Cedric D; Ajala, Olutobi Z; Zhu, Heng (2016) Applications in high-content functional protein microarrays. Curr Opin Chem Biol 30:21-27

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