G-Quadruplex Structure in the ATP-Binding DNA Aptamer Strongly Modulates Ligand Binding Activity.

Secondary structures formed by single-stranded DNA aptamers can allow for the binding of small-molecule ligands. Some of these secondary structures are highly stable in solution and are great candidates for use in the development of molecular tools for biomarker detection, environmental monitoring, and others. In this paper, we explored adenosine triphosphate (ATP)-binding aptamers for the simultaneous detection of two small-molecule ligands: adenosine triphosphate (ATP) and thioflavin T (ThT). The aptamer can form a G-quadruplex (G4) structure with two G-quartets, and our results show that each of these quartets is equally involved in binding. Using fluorescently labeled and label-free methods, we further explored the role of the G4 motif in modulating the ligand binding property of the aptamer by making two extended variants that can form three or four G-quartet G4 structures. Through equilibrium binding and electrospray ionization mass spectrometry (ESI-MS) analysis, we observed a stronger affinity of aptamers to ATP by the variant G4 constructs relative to the native aptamer (Kd range of 0.040-0.042 µM for variants as compared to 0.15 µM for the native ATP aptamer). Additionally, we observed a dual binding of ThT and ATP to the G4 constructs in the label-free and ESI-MS analyses. These findings together suggest that the G4 motif in the ATP aptamer is a critical structural element that is required for optimum ATP binding and can be modulated for the binding of multiple ligands. These findings are instrumental for designing smart molecular tools for a wide range of applications, including biomarker monitoring and ligand binding studies.

The DHX36-specific-motif (DSM) enhances specificity by accelerating recruitment of DNA G-quadruplex structures.

DHX36 is a eukaryotic DEAH/RHA family helicase that disrupts G-quadruplex structures (G4s) with high specificity, contributing to regulatory roles of G4s. Here we used a DHX36 truncation to examine the roles of the 13-amino acid DHX36-specific motif (DSM) in DNA G4 recognition and disruption. We found that the DSM promotes G4 recognition and specificity by increasing the G4 binding rate of DHX36 without affecting the dissociation rate. Further, for most of the G4s measured, the DSM has little or no effect on the G4 disruption step by DHX36, implying that contacts with the G4 are maintained through the transition state for G4 disruption. This result suggests that partial disruption of the G4 from the 3' end is sufficient to reach the overall transition state for G4 disruption, while the DSM remains unperturbed at the 5' end. Interestingly, the DSM does not contribute to G4 binding kinetics or thermodynamics at low temperature, indicating a highly modular function. Together, our results animate recent DHX36 crystal structures, suggesting a model in which the DSM recruits G4s in a modular and flexible manner by contacting the 5' face early in binding, prior to rate-limiting capture and disruption of the G4 by the helicase core.

The G-quadruplex (G4) resolvase DHX36 efficiently and specifically disrupts DNA G4s via a translocation-based helicase mechanism.

Single-stranded DNA (ssDNA) and RNA regions that include at least four closely spaced runs of three or more consecutive guanosines strongly tend to fold into stable G-quadruplexes (G4s). G4s play key roles as DNA regulatory sites and as kinetic traps that can inhibit biological processes, but how G4s are regulated in cells remains largely unknown. Here, we developed a kinetic framework for G4 disruption by DEAH-box helicase 36 (DHX36), the dominant G4 resolvase in human cells. Using tetramolecular DNA and RNA G4s with four to six G-quartets, we found that DHX36-mediated disruption is highly efficient, with rates that depend on G4 length under saturating conditions (kcat) but not under subsaturating conditions (kcat/Km ). These results suggest that a step during G4 disruption limits the kcat value and that DHX36 binding limits kcat/Km Similar results were obtained for unimolecular DNA G4s. DHX36 activity depended on a 3' ssDNA extension and was blocked by a polyethylene glycol linker, indicating that DHX36 loads onto the extension and translocates 3'-5' toward the G4. DHX36 unwound dsDNA poorly compared with G4s of comparable intrinsic lifetime. Interestingly, we observed that DHX36 has striking 3'-extension sequence preferences that differ for G4 disruption and dsDNA unwinding, most likely arising from differences in the rate-limiting step for the two activities. Our results indicate that DHX36 disrupts G4s with a conventional helicase mechanism that is tuned for great efficiency and specificity for G4s. The dependence of DHX36 on the 3'-extension sequence suggests that the extent of formation of genomic G4s may not track directly with G4 stability.

Dual Binding of an Antibody and a Small Molecule Increases the Stability of TERRA G-Quadruplex.

In investigating the binding interactions between the human telomeric RNA (TERRA) G-quadruplex (GQ) and its ligands, it was found that the small molecule carboxypyridostatin (cPDS) and the GQ-selective antibody BG4 simultaneously bind the TERRA GQ. We previously showed that the overall binding affinity of BG4 for RNA GQs is not significantly affected in the presence of cPDS. However, single-molecule mechanical unfolding experiments revealed a population (48 %) with substantially increased mechanical and thermodynamic stability. Force-jump kinetic investigations suggested competitive binding of cPDS and BG4 to the TERRA GQ. Following this, the two bound ligands slowly rearrange, thereby leading to the minor population with increased stability. Given the relevance of G-quadruplexes in the regulation of biological processes, we anticipate that the unprecedented conformational rearrangement observed in the TERRA-GQ-ligand complex may inspire new strategies for the selective stabilization of G-quadruplexes in cells.

Dual binding of an antibody and a small molecule increases the stability of TERRA G-quadruplex.

In investigating the binding interactions between the human telomeric RNA (TERRA) G-quadruplex (GQ) and its ligands, it was found that the small molecule carboxypyridostatin (cPDS) and the GQ-selective antibody BG4 simultaneously bind the TERRA GQ. We previously showed that the overall binding affinity of BG4 for RNA GQs is not significantly affected in the presence of cPDS. However, single-molecule mechanical unfolding experiments revealed a population (48%) with substantially increased mechanical and thermodynamic stability. Force-jump kinetic investigations suggested competitive binding of cPDS and BG4 to the TERRA GQ. Following this, the two bound ligands slowly rearrange, thereby leading to the minor population with increased stability. Given the relevance of G-quadruplexes in the regulation of biological processes, we anticipate that the unprecedented conformational rearrangement observed in the TERRA-GQ-ligand complex may inspire new strategies for the selective stabilization of G-quadruplexes in cells.

Interaction of G-quadruplexes in the full-length 3' human telomeric overhang.

The 3' human telomeric overhang provides ample opportunities for the formation and interaction of G-quadruplexes, which have shown impacts on many biological functions including telomerase activities in the telomere region. However, in the few investigations on DNA constructs that approach to the full length of the human telomeric overhang, the presence of higher-order quadruplex-quadruplex interactions is still a subject of debate. Herein, we employed dynamic splint ligation (DSL) to prepare a DNA construct, 5'-(TTAGGG)24 or 24G, which has the length comparable to the full stretch of 3' human telomeric overhang. Using mechanical unfolding assays in laser tweezers, we observed a minor population (∼5%) of higher-order interactions between G-quadruplexes, while the majority of the quadruplexes follow the bead-on-a-string model. Analyses on the noninteracting G-quadruplexes in the 24G construct showed features similar to those of the stand-alone G-quadruplexes in the 5'-(TTAGGG)4 (4G) construct. As each 24G construct contains as many as six G-quadruplexes, this method offers increased throughput for the time-consuming mechanical unfolding experiments of non-B DNA structures.

Mechanochemical properties of individual human telomeric RNA (TERRA) G-quadruplexes.

Potential functions: By following the unfolding and refolding of individual human RNA telomeric (TERRA) G-quadruplexes (GQs) in laser tweezers, the mechanical stability and transition kinetics of RNA GQs are obtained. Comparison between TERRA and DNA GQs suggests their different regulatory capacities for processes associated with human telomeres.

Fluorescent lipids as probes for sphingosine kinase activity by capillary electrophoresis.

Capillary electrophoresis (CE) is one among a number of highly sensitive chemical separation techniques used to characterize single or a small number of cells and to develop assays of enzymatic activity. Other commonly used techniques include mass spectrometry and electrochemistry; however, CE using laser-induced fluorescence detection (LIF) is the most sensitive of these techniques. In CE-LIF, fluorescently labeled proteins or lipids are normally separated based on their size to charge ratio in the interior of a small capillary filled with an electrolyte upon the application of an electric field. In this chapter, we describe the application of CE-LIF for the determination of the bioactivity of fluorescently lipids and sphingosine kinase activity.

Structural and mechanical properties of individual human telomeric G-quadruplexes in molecularly crowded solutions.

Recent experiments provided controversial observations that either parallel or non-parallel G-quadruplex exists in molecularly crowded buffers that mimic cellular environment. Here, we used laser tweezers to mechanically unfold structures in a human telomeric DNA fragment, 5'-(TTAGGG)4TTA, along three different trajectories. After the end-to-end distance of each unfolding geometry was measured, it was compared with PDB structures to identify the best-matching G-quadruplex conformation. This method is well-suited to identify biomolecular structures in complex settings not amenable to conventional approaches, such as in a solution with mixed species or at physiologically significant concentrations. With this approach, we found that parallel G-quadruplex coexists with non-parallel species (1:1 ratio) in crowded buffers with dehydrating cosolutes [40% w/v dimethyl sulfoxide (DMSO) or acetonitrile (ACN)]. In crowded solutions with steric cosolutes [40% w/v bovine serum albumin (BSA)], the parallel G-quadruplex constitutes only 10% of the population. This difference unequivocally supports the notion that dehydration promotes the formation of parallel G-quadruplexes. Compared with DNA hairpins that have decreased unfolding forces in crowded (9 pN) versus diluted (15 pN) buffers, those of G-quadruplexes remain the same (20 pN). Such a result implies that in a cellular environment, DNA G-quadruplexes, instead of hairpins, can stop DNA/RNA polymerases with stall forces often <20 pN.

Single-molecule measurements of the binding between small molecules and DNA aptamers.

Aptamers that bind small molecules can serve as basic biosensing platforms. Evaluation of the binding constant between an aptamer and a small molecule helps to determine the effectiveness of the aptamer-based sensors. Binding constants are often measured by a series of experiments with varying ligand or aptamer concentrations. Such experiments are time-consuming, material nonprudent, and prone to low reproducibility. Here, we use laser tweezers to determine the dissociation constant for aptamer-ligand interactions at the single-molecule level from only one ligand concentration. Using an adenosine 5'-triphosphate disodium salt (ATP) binding aptamer as an example, we have observed that the mechanical stabilities of aptamers bound with ATP are higher than those without a ligand. Comparison of the change in free energy of unfolding (ΔG(unfold)) between these two aptamers yields a ΔG of 33 ± 4 kJ/mol for the binding. By applying a Hess-like cycle at room temperature, we obtained a dissociation constant (K(d)) of 2.0 ± 0.2 µM, a value consistent with the K(d) obtained from our equilibrated capillary electrophoresis (CE) (2.4 ± 0.4 µM) and close to that determined by affinity chromatography in the literature (6 ± 3 µM). We anticipate that our laser tweezers and CE methodologies may be used to more conveniently evaluate the binding between receptors and ligands and also serve as analytical tools for force-based biosensing.

Determination of sphingosine kinase 2 activity using fluorescent sphingosine by capillary electrophoresis.

The study of sphingosine and sphingosine-1-phosphate is now widespread due to their immense role as intra- and extracellular messenger molecules. The balance and interplay of these ceramide metabolites is dependent on the activities of kinase and phosphatase enzymes. Sphingosine and sphingosine-1-phosphate are found in very minute quantities in cells; thus, they require highly sensitive techniques for quantitative analysis. In this study, we developed a quantitative assay for the determination of sphingosine kinase 2 (SphK2) activity both in vitro and with cell lysates, using CE-LIF. Sphingosine fluorescein was used as the substrate. The K(M) of SphK2 for sphingosine fluorescein was 2.8 ± 0.8 µM with a V(max) of 2490 ± 520 µM/min and a k(cat) of 1920 ± 402/s. The inhibition of SphK2 was also investigated using four different inhibitors for which 2-(p-hydroxyanilino)-4-(p-chlorophenyl) thiazole inhibitor was the most potent for the in vitro inhibition of SphK2 while N,N-dimethylsphingosine (DMS) did not inhibit but rather increased SphK2 activity. The fluorescence-based approach for the determination of the enzymatic activity of SphK2 proves to be useful for the quantitative determination of SphK2 activity in vitro and in cell lysates, and could be extended to single-cell analysis or applied in drug screening.

Glutathionato-S-Gold(III) complexes formed as intermediates in the reduction of auricyanide by glutathione.

The reduction of auricyanide ([Au(CN)(4)](-), a potential gold(III) metabolite of antiarthritic gold(I) compounds), by glutathione (G(-)SH, an anionic biological reductant) proceeds through two intermediates (I(230) and I(290)) which have previously been identified by their UV-vis spectra, but not isolated. Negative-ion electrospray ionization-mass spectroscopy (ESI-MS) has unambiguously identified them as [Au(CN)(3)(SG)](2-) and [Au(CN)(2)(SG)(2)](3-), respectively, and allowed their formation and decay to be monitored. The spectra also confirm that the products are aurocyanide ([Au(CN)(2)](-), a known metabolite of chrysotherapy agents) and oxidized glutathione (GSSG(2-)). The reactions are dependent on the presence or absence of buffering agents and the pH of the reaction media. The reaction can be driven to the first intermediate by using an excess of auricyanide or by running the reaction at low pH which prevents further reaction. At neutral pH and/or with excess of glutathione present, the reaction proceeds to the second intermediate, which is then reduced to aurocyanide. The monoanions, [Au(CN)(3)(SGH)](-) at m/z=581.2 and [Au(CN)(2)(SGH)(2)](-) at m/z=861.5 generate more intense signals than their respective dianions, [Au(CN)(3)(SG)](2-) at m/2=290.2 and [Au(CN)(2)(SG)(SGH)](2-)m/2=430.9, respectively, whereas the trianion [Au(CN)(2)(SG)(2)](3-) (m/3=281.2) was not observed. These studies demonstrate the value of ESI-MS methods for characterizing reactions of metallopharmaceuticals under biomimetic conditions and suggest that they will be useful for other systems which give strong ESI-MS signals.

Proton-linked bi- and tri-metallic gold cyanide complexes observed by ESI-MS spectrometry.

Electrospray ionization spectra of potential cyanide-containing gold-drug metabolites revealed additional, weak, unanticipated peaks at approximately twice the mass of the gold(I) and gold(III) cyanide complexes. The exact masses correspond to proton-linked bimetallic complexes, [H[Au(CN)(m)](2)](-), (m=2,4). Further investigation revealed a total of 12 examples, including trimetallic complexes, [H(2)[Au(CN)(m)](3)](-); mixed species with two complexes, [H[Au(CN)(2)][Au(CN)(4)]](-); and thiolato species, [H[(RS)Au(CN)(3)](2)](-). trans-[AuX(2)(CN)(2)Cl(2)](-) and trans-[AuX(2)(CN)(2)Br(2)](-) generated (35)Cl/(37)Cl and (79)Br/(81)Br isotopic patterns for the protonated bi- and tri-metallic analogues which were in good agreement with the presence of four or six halide ligands, respectively. Concentration-dependent studies demonstrated that the signals are independent of the solution concentrations of mono-metallic precursors, suggesting formation in the gas phase during or following droplet desolvation.