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.
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.
G-quadruplex (GQ) stabilizing small molecule (SM) ligands have been used to stabilize human telomeric GQ (hGQ) to inhibit telomerase activity, or non-telomeric GQs to manipulate gene expression at transcription or translation level. GQs are known to inhibit DNA replication unless destabilized by helicases, such as Bloom helicase (BLM). Even though the impact of SM ligands on thermal stability of GQs is commonly used to characterize their efficacy, how these ligands influence helicase-mediated GQ unfolding is not well understood. Three prominent SM ligands (an oxazole telomestatin derivative, pyridostatin, and PhenDC3), which thermally stabilize hGQ at different levels, were utilized in this study. How these ligands influence BLM-mediated hGQ unfolding was investigated using two independent single-molecule approaches. While the frequency of dynamic hGQ unfolding events was used as the metric in the first approach, the second approach was based on quantifying the cumulative unfolding activity as a function of time. All three SM ligands inhibited BLM activity at similar levels, 2–3 fold, in both approaches. Our observations suggest that the impact of SM ligands on GQ thermal stability is not an ideal predictor for their inhibition of helicase-mediated unfolding, which is physiologically more relevant.
The potential use of G-quadruplex (GQ) stabilizing small molecules as anti-cancer drugs has created a flurry of activity on various aspects of these molecules. Telomestatin and oxazole telomestatin derivatives (OTD) are some of the most prominent of such molecules, yet the underlying dynamics of their interactions with GQ and the extent of heterogeneities in these interactions are not known. We performed single molecule measurements to study binding kinetics, rotational freedom, and dwell time distributions of a Cy5-labeled OTD (L1Cy5–7OTD) as it interacted with several different GQ structures. Our measurements show that L1Cy5–7OTD dwells on more stable GQ for longer times and binds to such GQ with higher frequency. The dwell times showed a broad distribution, but were longer than a minute for a significant fraction of molecules (characteristic dwell time τ = 192 ± 15 s and τ = 98 ± 15 s for the more and less stable GQ, respectively). In addition, L1Cy5–7OTD might be able to bind to GQ in at least two different primary orientations and occasionally transition between these orientations. The dwell time in one of these orientations was significantly longer than that in the other one, suggesting different stabilities for different binding orientations.
We present a collection of single molecule work on the i-motif structure formed by the human telomeric sequence. Even though it was largely ignored in earlier years of its discovery due to its modest stability and requirement for low pH levels (pH < 6.5), the i-motif has been attracting more attention recently as both a physiologically relevant structure and as a potent pH sensor. In this manuscript, we establish single molecule Förster resonance energy transfer (smFRET) as a tool to study the i-motif over a broad pH and ionic conditions. We demonstrate pH and salt dependence of i-motif formation under steady state conditions and illustrate the intermediate states visited during i-motif folding in real time at the single molecule level. We also show the prominence of intermediate folding states and reversible folding/unfolding transitions. We present an example of using the i-motif as an in-situ pH sensor and use this sensor to establish the time scale for the pH drop in a commonly used oxygen scavenging system.
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