Intermediates Stabilized by Tryptophan Pairs Exist in Trpzip Beta-Hairpins

Transitions of protein secondary structures, such as alpha-helices and beta-hairpins, are often too small and too fast to follow by many single-molecular approaches. Here we describe new population deconvolution methods to investigate the mechanical unfolding/refolding events in Trpzip β-hairpins that are tethered between two optically trapped polystyrene particles through click chemistry. The application of force to the Trpzip peptides shifted population distribution, which allowed us to identify intermediates from regular force–extension curves of the peptides after population deconvolution analysis. Comparison of the intermediates between the Trpzip2 and Trpzip4 peptides suggests the intermediates are likely stabilized by the tryptophan pair stacking. We anticipate the method of population deconvolution described here can offer a unique capability to investigate fast transitions in small biological structures

A New Concentration Jump Strategy Reveals the Lifetime of i‑Motif at Physiological pH without Force

Concentration jumps for kinetics measurement remain a challenge for single-molecule techniques, which have demonstrated superior signal-to-noise levels compared to ensemble average approaches. Currently, all concentration jumps use mixing strategies. Here, we report a simple and drastically different jump strategy by rapid transportation of molecules between two side-by-side laminar streams in 80 ms. This allowed us to measure the lifetime of bioactive DNA i-motif structures at physiological pH without force. We placed a human telomeric i-motif inside a DNA hairpin-based mechanical reporter. Since the folded or unfolded state of the hairpin correlates with that of the i-motif, by recording hairpin transitions, a half-life of ∼3 s was found for the DNA i-motif at neutral pH without force. Such a lifetime is sufficient for i-motif to interact with proteins to modulate cellular processes. We anticipate this concentration jump offers a generic platform to investigate single-molecule kinetics

Detection of Single Nucleotide Polymorphism Using Tension-Dependent Stochastic Behavior of a Single-Molecule Template

Single nucleotide polymorphism (SNP) is the most common genetic variation among individuals. The association of SNP with individual’s response to pathogens, phenotypic variations, and gene functions emphasizes the importance of sensitive and reliable SNP detection for biomedical diagnosis and therapy. To increase sensitivity, most approaches employ amplification steps, such as PCR, to generate detectable signals that are usually ensemble-averaged. Introduction of amplification steps increases the complexity of a system, whereas ensemble averaging of signals often suffers from background interference. Here, we have exploited the stochastic behavior of a single-molecule probe to recognize SNP sequence in a microfluidic platform using a laser-tweezers instrument. The detection relies on on–off mechanical signals that provide little background interference and high specificity between wild type and SNP sequences. The microfluidic setting allows multiplex sensing and in situ recycling of the SNP probe. As a proof-of-concept, we have detected as low as 100 pM of an SNP target associated with coronary heart diseases within half an hour without any amplification steps. The mechanical signal permits the detection of single mutations involving either G/C or A/T pairs. We anticipate this system has the capacity to function as a highly sensitive generic biosensor after incorporation of a specific recognition element, such as an aptamer for example

Mechanical Stability of DNA Corona Phase on Gold Nanospheres

Noncovalent adsorption of biopolymers on the surface of gold nanoparticles (AuNPs) forms a corona phase that drastically diversify AuNP functions. However, mechanical stabilities of such corona phase are still obscure, hindering the application of biopolymer-coated AuNPs. Here, using optical tweezers, we have observed, for the first time, that DNA corona phase adsorbed on a 5 nm AuNP via two (dA)21 strands in proximity can withstand an average desorption force of 40 pN, which is higher than the stall force of DNA/RNA polymerases. This suggests a new role for AuNPs to modulate replications or transcriptions after binding to prevalent poly(dA) segments in eukaryotic genomes. We have also revealed that with increasing AuNP size (1.8–10 nm), DNA corona becomes harder to remove, likely due to the larger surfaces and flatter facets on bigger AuNPs. These findings provide guidance to design AuNP corona that can withstand harsh environments for biological and materials applications

Quantification of Topological Coupling between DNA Superhelicity and G‑quadruplex Formation

It has been proposed that new transcription modulations can be achieved via topological coupling between duplex DNA and DNA secondary structures, such as G-quadruplexes, in gene promoters through superhelicity effects. Limited by available methodologies, however, such a coupling has not been quantified directly. In this work, using novel magneto-optical tweezers that combine the nanometer resolution of optical tweezers and the easy manipulation of magnetic tweezers, we found that the flexibility of DNA increases with positive superhelicity (σ). More interestingly, we found that the population of G-quadruplex increases linearly from 2.4% at σ = 0.1 to 12% at σ = −0.03. The population then rapidly increases to a plateau of 23% at σ < −0.05. The rapid increase coincides with the melting of double-stranded DNA, suggesting that G-quadruplex formation is correlated with DNA melting. Our results provide evidence for topology-mediated transcription modulation at the molecular level. We anticipate that these high-resolution magneto-optical tweezers will be instrumental in studying the interplay between the topology and activity of biological macromolecules from a mechanochemical perspective

Mechanochemical Sensing of Single and Few Hg(II) Ions Using Polyvalent Principles

Sensitivity of biosensors is set by the dissociation constant (<i>K</i>_d) between analytes and probes. Although potent amplification steps can be accommodated between analyte recognition and signal transduction in a sensor to improve the sensitivity 4–6 orders of magnitude below <i>K</i>_d, they compromise temporal resolution. Here, we demonstrated mechanochemical sensing that broke the <i>K</i>_d limit by 9 orders of magnitude for Hg detection without amplifications. Analogous to trawl fishing, we introduced multiple Hg binding units (thymine (T)–T pairs) in a molecular trawl made of two poly-T strands. Inspired by dipsticks to gauge content levels, mechanical information (force/extension) of a DNA hairpin dipstick was used to measure the single or few Hg²⁺ ions bound to the molecular trawl, which was levitated by two optically trapped particles. The multivalent binding and single-molecule sensitivity allowed us to detect unprecedented 1 fM Hg ions in 20 min in field samples treated by simple filtrations

A Mechanosensor Mechanism Controls the G‑Quadruplex/i-Motif Molecular Switch in the <i>MYC</i> Promoter NHE III₁

<i>MYC</i> is overexpressed in many different cancer types and is an intensively studied oncogene because of its contributions to tumorigenesis. The regulation of <i>MYC</i> is complex, and the NHE III₁ and FUSE elements rely upon noncanonical DNA structures and transcriptionally induced negative superhelicity. In the NHE III₁ only the G-quadruplex has been extensively studied, whereas the role of the i-motif, formed on the opposite C-rich strand, is much less understood. We demonstrate here that the i-motif is formed within the 4CT element and is recognized by hnRNP K, which leads to a low level of transcription activation. For maximal hnRNP K transcription activation, two additional cytosine runs, located seven bases downstream of the i-motif-forming region, are also required. To access these additional runs of cytosine, increased negative superhelicity is necessary, which leads to a thermodynamically stable complex between hnRNP K and the unfolded i-motif. We also demonstrate mutual exclusivity between the <i>MYC</i> G-quadruplex and i-motif, providing a rationale for a molecular switch mechanism driven by SP1-induced negative superhelicity, where relative hnRNP K and nucleolin expression shifts the equilibrium to the on or off state

Direct Measurement of Intermolecular Mechanical Force for Nonspecific Interactions between Small Molecules

Mechanical force can evaluate intramolecular interactions in macromolecules. Because of the rapid motion of small molecules, it is extremely challenging to measure mechanical forces of nonspecific intermolecular interactions. Here, we used optical tweezers to directly examine the intermolecular mechanical force (IMMF) of nonspecific interactions between two cholesterols. We found that IMMFs of dimeric cholesterol complexes were dependent on the orientation of the interaction. The surprisingly high IMMF in cholesterol dimers (∼30 pN) is comparable to the mechanical stability of DNA secondary structures. Using Hess-like cycles, we quantified that changes in free energy of solubilizing cholesterol (ΔGsolubility) by β-cyclodextrin (βCD) and methylated βCD (Me-βCD) were as low as −16 and −27 kcal/mol, respectively. Compared to the ΔGsolubility of cholesterols in water (5.1 kcal/mol), these values indicated that cyclodextrins can easily solubilize cholesterols. Our results demonstrated that the IMMF can serve as a generic and multipurpose variable to dissect nonspecific intermolecular interactions among small molecules into orientational components

Mutation analysis in a 10 mM sodium phosphate buffer (pH 5.5) with 100 mM KCl.

<p>(A) 295 nm UV melting curves of the ILPR-I3 (“Wild Type”) and the mutants at 10 µM concentration. (B) Top panel, <i>T</i>_1/2-melt of the mutants and the ILPR-I3. “W” depicts the wild type ILPR-I3. Bottom panel, CD peak shift of the mutants and the scrambled sequence (ILPR-S3) with respect to the 285 nm peak in the ILPR-I3. The horizontal dotted lines (green) represent the average value for each C4 tract. Statistical treatment is represented by the <i>P</i> values in the bottom panel. Please refer to <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0039271#pone-0039271-t001" target="_blank">Table 1</a> for DNA sequences.</p