William A. Roy scite author profile

In this article, we summarize the knowledge and best practices learned from bulk and single molecule measurements to address some of the frequently experienced difficulties in single molecule Förster Resonance Energy Transfer (smFRET) measurements on G-quadruplex (GQ) structures. The number of studies that use smFRET to investigate the structure, function, dynamics, and interactions of GQ structures has grown significantly in the last few years, with new applications already in sight. However, a number of challenges need to be overcome before reliable and reproducible smFRET data can be obtained in measurements that include GQ. The annealing and storage conditions, the location of fluorophores on the DNA construct, and the ionic conditions of the experiment are some of the factors that are of critical importance for the outcome of measurements, and many of these manifest themselves in unique ways in smFRET assays. By reviewing these aspects and providing a summary of best practices, we aim to provide a practical guide that will help in successfully designing and performing smFRET studies on GQ structures.

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A Comparative Study of G-Quadruplex Unfolding and DNA Reeling Activities of Human RECQ5 Helicase

Budhathoki

Maleki

Roy

et al. 2016

Biophysical Journal

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RECQ5 is one of five members of the RecQ family of helicases in humans, which include RECQ1, Bloom (BLM), Werner (WRN), RECQ4, and RECQ5. Both WRN and BLM have been shown to resolve G-quadruplex (GQ) structures. Deficiencies in unfolding GQ are known to result in DNA breaks and genomic instability, which are prominent in Werner and Bloom syndromes. RECQ5 is significant in suppressing sister chromatid exchanges during homologous recombination but its GQ unfolding activity are not known. We performed single-molecule studies under different salt (50-150 mM KCl or NaCl) and ATP concentrations on different GQ constructs including human telomeric GQ (with different overhangs and polarities) and GQ formed by thrombin-binding aptamer to investigate this activity. These studies demonstrated a RECQ5-mediated GQ unfolding activity that was an order of magnitude weaker than BLM and WRN. On the other hand, BLM and RECQ5 demonstrated similar single-stranded DNA (ssDNA) reeling activities that were not coupled to GQ unfolding. These results demonstrate overlap in function between these RecQ helicases; however, the relatively weak GQ destabilization activity of RECQ5 compared to BLM and WRN suggests that RECQ5 is not primarily associated with GQ destabilization, but could substitute for the more efficient helicases under conditions where their activity is compromised. In addition, these results implicate a more general role for helicase-promoted ssDNA reeling activity such as removal of proteins at the replication fork, whereas the association of ssDNA reeling with GQ destabilization is more helicase-specific.

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A force sensor that converts fluorescence signal into force measurement utilizing short looped DNA

Mustafa

Chuang

Roy

et al. 2018

Biosensors and Bioelectronics

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A force sensor concept is presented where fluorescence signal is converted into force information via single-molecule Förster resonance energy transfer (smFRET). The basic design of the sensor is a ~100 base pair (bp) long double stranded DNA (dsDNA) that is restricted to a looped conformation by a nucleic acid secondary structure (NAS) that bridges its ends. The looped dsDNA generates a tension across the NAS and unfolds it when the tension is high enough. The FRET efficiency between donor and acceptor (D&A) fluorophores placed across the NAS reports on its folding state. Three dsDNA constructs with different lengths were bridged by a DNA hairpin and KCl was titrated to change the applied force. After these proof-of-principle measurements, one of the dsDNA constructs was used to maintain the G-quadruplex (GQ) construct formed by thrombin binding aptamer (TBA) under tension while it interacted with a destabilizing protein and stabilizing small molecule. The force required to unfold TBA-GQ was independently investigated with high-resolution optical tweezers (OT) measurements that established the relevant force to be a few pN, which is consistent with the force generated by the looped dsDNA. The proposed method is particularly promising as it enables studying NAS, protein, and small molecule interactions using a highly-parallel FRET-based assay while the NAS is kept under an approximately constant force.

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Converting FRET Signal into Force Information using Short Looped DNA as Force Transducer

Mustafa

Chuang

Roy

et al. 2019

Biophysical Journal

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This project enables the development of a live three-dimensional (3D) imaging system for Biology. Our prototype for the optical microscopy system enables the recording of live 3D volumes fast and simultaneously by capturing 25 focal planes based on a novel design of an aberrationcorrected multifocus microscopy (MFM). Utilizing a 5x5 array of lownoise, fast, and small cameras, we acquired data with the diffraction-limit resolution of up to 100 volumes per second. Based on Dr. Sara Abrahamsson diffractive Fourier optics technique MFM, we utilized UC Santa Barbara Nanofabrication facilities to develop the optical elements for simultaneous 3D imaging without loss of resolution. This technology hopes to advance the field of biology by allowing simultaneous live imaging of 25 focal planes applicable for any optically transparent neural circuit model organisms.

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A Comparative Study on G-Quadruplex Unfolding Activity of RecQ Helicases

Budhathoki

Balci

Yodh

et al. 2016

Biophysical Journal

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William A. Roy

A practical guide to studying G-quadruplex structures using single-molecule FRET

A Comparative Study of G-Quadruplex Unfolding and DNA Reeling Activities of Human RECQ5 Helicase

A force sensor that converts fluorescence signal into force measurement utilizing short looped DNA

Converting FRET Signal into Force Information using Short Looped DNA as Force Transducer

A Comparative Study on G-Quadruplex Unfolding Activity of RecQ Helicases

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