University of Illinois Urbana-Champaign

Predicting G-quadruplex Formation

Calvert, Jacob; Kreig, Alex; Sinha, Saurabh; Myong, Sua

Content Files
Calvert_Jacob.pdf

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https://hdl.handle.net/2142/77692

Description

Title
Predicting G-quadruplex Formation
Author(s)
  • Calvert, Jacob
  • Kreig, Alex
  • Sinha, Saurabh
  • Myong, Sua
Contributor(s)
Myong, Sua
Issue Date
2015-05
Keyword(s)
  • Bioengineering
  • g-quadruplex
  • cancer
  • bioinformatics
Date of Ingest
2015-05-14T16:28:28Z
Abstract
Guanine-rich regions of genomic DNA can spontaneously fold into secondary structures called G-quadruplexes (GQs). Akin to tiny switches, GQs regulate genetic processes through their folding and unfolding. Their interest to basic science, as well as their potential as therapeutic targets for human diseases, has motivated the creation of computational tools for their prediction. Currently, GQ folding predictors are based on results from studies of GQs formed in single-stranded DNA. As a result, existing tools perform poorly when applied to the prediction of GQ formation in double-stranded (ds) DNA, the native context within which genomic GQs are found. Here, we present a probabilistic model of GQ formation, which is learned from large-scale human genomic pull-down experiments and applied to the analysis of gene ontological data. Advances in the characterization of GQs in dsDNA have enabled us to integrate results from small-molecule binding assays and singlemolecule FRET microscopy into our model. In order to obtain training sets of sequences, we identified nearly 700,000 unique, potential GQs and categorized them according to pulldown experiment outcomes. Model parameters learned from these training sets agree with experimental evidence and, when asked to predict the folding of dsDNA GQ sequences, outperformed existing models of GQ folding. This tool can be applied to genomic sequences to locate the most strongly forming GQs, revealing valuable information for the design of GQ-targeting therapies, and represents the next step toward the practical, widespread use of GQs in medicine and technology.
Type of Resource
image
Genre of Resource
Conference Poster
Language
en
Permalink
http://hdl.handle.net/2142/77692
Copyright and License Information
  • Copyright 2015 Jacob Calvert
  • Copyright 2015 Alex Kreig
  • Copyright 2015 Saurabh Sinha
  • Copyright 2015 Sua Myong

Owning Collections

Undergraduate Research Symposium 2015 PRIMARY