The ways by which gene expression is altered without any change in the underlying DNA sequence is referred to as epigenetics. We envision that the secondary structure of DNA such as the G-quadruplex (GQ) may be yet another epigenetic element that contributes to gene regulation. Once regarded as an experimental artifact, GQ has been rediscovered through recent studies that clearly demonstrated the presence of GQ in the human genome and its enrichment in important regulatory regions such as near gene promoters and replication origin. In addition, there is an accumulating evidence that the GQ elements control gene expression at the level of transcription and translation. These findings are leading to an emerging hypothesis that the GQ in genomic DNA may act like a switch to turn the gene expression on and off. One of the big challenges in testing this hypothesis lies at the high level of heterogeneity in various GQ forming sequences. It is unrealistic to rely on the previously published results since majority of studies focused on probing GQ in the context of single strand DNA (ssDNA) when the genomic GQs are expected to form in double strand DNA (dsDNA). We have devised biochemical and biophysical platforms for examining various GQ forming sequences in dsDNA. Our recently published data already suggest that the GQ formation is drastically different between the ssDNA and dsDNA. We present our preliminary data on GQ folding propensity analysis on 438 GQ forming sequences. Based on this mapping, we propose to examine more complex GQ sequences that are pertinent to/represented in genomic DNA (Aim 1). We present our result on the DNA and RNA polymerase assays which measure strength of GQ sequences and the corresponding barrier effect. With a newly established real time assays which detect mRNA production and GQ formation in mRNA, we will continue to examine the GQ effect in blocking DNAP and RNAP as a way of estimating their role in the process of replication and transcription (Aim 2). The same GQ sequences tested above were cloned into plasmid and E. coli chromosome to measure the magnitude of gene activation/repression induced by the GQ elements. Our new preliminary data demonstrates that the gene repression effect is dependent on GQ folding stability and the GQ positioned in non-template DNA. This work will continue and will be followed by mammalian cell testing (Aim 3). Using these platforms, we propose to test three possible modes of gene switching that includes (i) rheostat (gradient) in which different strength of GQ folding lead to variable levels of gene repression/activation, (ii) rotary (stepwise) where there are several distinct levels of GQ switches that control the gene activity, (iii) toggle (binary, on-off) switch which simply has a set threshold GQ strength beyond which gene expression is turned on. Our systematic approach and stepwise analysis will provide quantitative understanding about the GQ folding strength and its connection to biological processes including replication, transcription and translation.

Public Health Relevance

G-quadruplexes (GQ) are secondary structure of DNA enriched in important regulatory regions including many known oncogenic promoters. We will establish biochemical, biophysical and cellular platforms to systematically analyze the GQ formation and the subsequent changes in gene expression. The experimental platforms to be designed for the proposed work may be applicable for screening drugs targeting GQ and other secondary structures of nucleic acid pertinent to various types of cancers and other diseases.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
1R01GM115631-01A1
Application #
9174593
Study Section
Macromolecular Structure and Function C Study Section (MSFC)
Program Officer
Preusch, Peter
Project Start
2016-09-22
Project End
2020-08-31
Budget Start
2016-09-22
Budget End
2017-08-31
Support Year
1
Fiscal Year
2016
Total Cost
$312,088
Indirect Cost
$114,588
Name
Johns Hopkins University
Department
Physiology
Type
Schools of Arts and Sciences
DUNS #
001910777
City
Baltimore
State
MD
Country
United States
Zip Code
21205
Langdon, Erin M; Qiu, Yupeng; Ghanbari Niaki, Amirhossein et al. (2018) mRNA structure determines specificity of a polyQ-driven phase separation. Science 360:922-927
Koh, Hye Ran; Ghanbariniaki, Amirhossein; Myong, Sua (2017) RNA stem structure governs coupling of dicing and gene silencing in RNA interference. Proc Natl Acad Sci U S A 114:E10349-E10358
Fouquerel, Elise; Lormand, Justin; Bose, Arindam et al. (2016) Oxidative guanine base damage regulates human telomerase activity. Nat Struct Mol Biol 23:1092-1100