Tiny protein detection using pressure through solid‐state nanopores

Solid‐state nanopore is a promising tool to detect proteins and its complexes. Small proteins (sub‐35 kDa) translocate very fast which could not be detected by normal patch‐clamp recording instrument due to low temporal resolution. We first introduce pressure into protein study and detection. The pressure‐derived force, combined with the voltage bias, makes very tiny protein (MW < 6.5 kDa) detection possible. Capture rate for Aprotinin is enhanced five times more than that in traditional voltage‐driven method by fine tuning of pressure and voltage. Temporal resolution of Aprotinin detection has improved by decreasing effective driving force. Moreover, we provide potential method to locate the equilibrium range for BSA movement in ionic solution by modulating driving pressure and retard voltage. Our study is of fundamental significance in nanopore research and provides unique platforms to study small proteins and other tiny biomolecules.     

G‐Quadruplex‐Linked Supersandwich DNA Structure for Electrochemical Amplified Detection of Thrombin

In this paper, a novel strategy of electrochemical amplified detection of thrombin based on G‐quadruplex‐linked supersandwich structure was described. In the presence of K⁺ and hemin, the original hairpin DNA sequence activated an autonomous cross‐opening process to build up hemin/G‐quadruplex structure and can hybridize to form supersandwich structure containing multiple signal labels. With the addition of thrombin, it conjugated with its aptamer, leading to a remarkably descended signal. The supersandwich‐amplified electrochemical sensor system was highly sensitive in the concentration range from 10^?6 to 10^?10 M with a detection limit of 10 pM and also demonstrated excellent selectivity. The amplifying supersandwich structure with multiple labels can be implemented as a versatile sensing platform for analyzing other DNA in the presence of the appropriate probe.     

Direct and Single‐Molecule Visualization of the Solution‐State Structures of G‐Hairpin and G‐Triplex Intermediates

We present the direct and single‐molecule visualization of the in‐pathway intermediates of the G‐quadruplex folding that have been inaccessible by any experimental method employed to date. Using DNA origami as a novel tool for the structural control and high‐speed atomic force microscopy (HS‐AFM) for direct visualization, we captured images of the unprecedented solution‐state structures of a tetramolecular antiparallel and (3+1)‐type G‐quadruplex intermediates, such as G‐hairpin and G‐triplex, with nanometer precision. No such structural information was reported previously with any direct or indirect technique, solution or solid‐state, single‐molecule or bulk studies, and at any resolution. Based on our results, we proposed a folding mechanism of these G‐quadruplexes.     

A G‐Quadruplex/Hemin Complex with Switchable Peroxidase Activity by DNA Hybridization

A hemin‐binding DNA G‐quadruplex (also known as a hemin aptamer or DNAzyme) has been previously reported to be able to enhance the peroxidase activity of hemin. In this work, we described a DNAzyme structure that had an effector‐recognizing part appearing as a single stranded DNA linkage flanked by two split G‐quadruplex halves. Hybridization of the single stranded part in the enzyme with a perfectly matched DNA strand (effector) formed a rigid DNA duplex between the two G‐quadruplex halves and thus efficiently suppressed the enzymatic activity of the G‐quadruplex/hemin complex, while the mismatched effector strand was not able to regulate the peroxidase activity effectively. With 2,2′‐azinobis(3‐ethylbenzthiazoline)‐6‐sulfonic acid (ABTS) as an oxidizable substrate, we were able to characterize the formation of the re‐engineered G‐quadruplex/hemin complex and verify its switchable peroxidase activity. Our results show that the split G‐quadruplex is an especially useful module to design low‐cost and label‐free sensors toward various biologically or environmentally interesting targets.     

A Novel Method for Screening G‐quadruplex Stabilizers to Human Telomeres

We present a simple method based on the Cu²⁺ induced unfolding of G‐quadruplex (G4) of human telomere sequence d[AG₃(T₂AG₃)₃] to screen a number of 3,6‐bis(1‐methyl‐4‐vinylpyridinium)carbazole diiodide (BMVC) analogues for better G4 stabilizers. Using circular dichroism (CD), the screening results suggest that the tri‐cations of 9‐substituted BMVC derivatives are better G4 stabilizers than the bi‐cations of BMVC. In addition, 3,6‐bis(1‐methyl‐4‐vinylpyrazinium)carbazole diiodide (BMVC4) is likely a better core molecule than BMVC for G4 stabilizers.     

Detection of structured single‐strand DNA via solid‐state nanopore

Nanopore is a single‐molecule analysis method which also employed electrophoresis has achieved promising single‐molecule detections. In this study, we designed two kinds of confined spaces by fabricating solid‐state nanopores with desirable diameters to study the structured single‐strand DNA of C‐rich quadruplex. For the nanopore whose diameter is larger than the quadruplex size, the DNA molecule could directly translocate through the nanopore with extremely high speed. For the nanopore whose diameter is smaller than the quadruplex size, DNA molecule which is captured by nanopore could return to the solution without translocation or unzip the quadruplex structure into single‐strand and then pass the nanopore. This study certifies that choosing a suitable sensing interface is the vital importance of observing detailed single‐molecule information. The solid‐state nanopores hold the great potential to study the structural dynamics of quadruplex DNA molecule.     

Interaction of Metal Complexes with G‐Quadruplex DNA

Guanine‐rich sequences of DNA can assemble into tetrastranded structures known as G‐quadruplexes. It has been suggested that these secondary DNA structures could be involved in the regulation of several key biological processes. In the human genome, guanine‐rich sequences with the potential to form G‐quadruplexes exist in the telomere as well as in promoter regions of certain oncogenes. The identification of these sequences as novel targets for the development of anticancer drugs has sparked great interest in the design of molecules that can interact with quadruplex DNA. While most reported quadruplex DNA binders are based on purely organic templates, numerous metal complexes have more recently been shown to interact effectively with this DNA secondary structure. This Review provides an overview of the important roles that metal complexes can play as quadruplex DNA binding molecules, highlighting the unique properties metals can confer to these molecules.     

Pyridyl‐Substituted Corrole Isomers: Synthesis and their Regulation to G‐quadruplex Structures

G‐quadruplex DNA plays an important role in the potential therapeutic target for the design and development of anticancer drugs. As various G‐quadruplex sequences in the promoter regions or telomeres can form different secondary structural modes and display a diversity of biology functions, variant G‐quadruplex interactive agents may be necessary to cure different disease by differentiating variant types of G‐quadruplexes. We synthesize five cationic methylpyridylium corroles and compare the interactions of corroles with different types of G‐quadruplexes such as cmyc, htelo, and bcl2 by using surface plasmon resonance. Because of the importance of human telomere G‐quadruplex DNA, we focus on the biological properties of the interactions between human telomere G‐quadruplex DNA and corrole isomers using CD, T_m, PCR‐stop (PCR= polymerase chain reaction), and polymerase‐stop assay, which demonstrate the excellent ability of the corrole to induce and stabilize the G‐quadruplex. This study provides the first experimental insight into how selectivity might be achieved for different G‐quadruplexes by a single group of methylpyridylium corrole isomers that may be optimized for potential selective cancer therapy.     

Novel application of fluorescence coupled capillary electrophoresis to resolve the interaction between the G‐quadruplex aptamer and thrombin

The dynamic binding status between the thrombin and its G‐quadruplex aptamers and the stability of its interaction partners were probed using our previously established fluorescence‐coupled capillary electrophoresis method. A 29‐nucleic acid thrombin binding aptamer was chosen as a model to study its binding affinity with the thrombin ligand. First, the effects of the cations on the formation of G‐quadruplex from unstructured 29‐nucleic acid thrombin binding aptamer were examined. Second, the rapid binding kinetics between the thrombin and 6‐carboxyfluorescein labeled G‐quadruplex aptamer was measured. Third, the stability of G‐quadruplex aptamer–thrombin complex was also examined in the presence of the interfering species. Remarkably, it was found that the complementary strand of 29‐nucleic acid thrombin binding aptamer could compete with G‐quadruplex aptamer and thus disassociated the G‐quadruplex structure into an unstructured aptamer. These data suggest that our in‐house established fluorescence‐coupled capillary electrophoresis assay could be applied to binding studies of the G‐quadruplex aptamers, thrombin, and their ligands, while overcoming the complicated and costly approaches currently available.     

Solution Structure of a G‐quadruplex Bound to the Bisquinolinium Compound Phen‐DC3

Phen‐DC₃ is a highly promising compound that specifically targets G‐quadruplexes, with potent biological effects observed in vivo. We used NMR spectroscopy to solve the structure of the complex formed between Phen‐DC₃ and an intramolecular G‐quadruplex derived from the c‐myc promoter. Structural information revealed that Phen‐DC₃ interacts with the quadruplex through extensive π‐stacking with guanine bases of the top G‐tetrad. On the basis of our structure, modifications are proposed for the development of this compound for selective targeting of a specific G‐quadruplex conformation.     

Study of binding affinity and selectivity of perylene and coronene derivatives towards duplex and quadruplex DNA by ESI‐MS

In this paper, we report an extensive electrospray ionization mass spectrometry (ESI‐MS) study of the noncovalent interactions between different intermolecular and intramolecular G‐quadruplex structures and several perylene and coronene ligands. The selectivity of these compounds toward quadruplex structures with respect to duplex DNA, a fundamental topic for the biological evaluation and the pharmacological application of these ligands as potential chemotherapeutic agents, has also been investigated. After exploring this topic according to the classical approach based on the very simple duplex model of an autocomplementary dodecamer, we extended our analysis reporting for the first time a competition ESI‐MS experiment in the presence of genomic DNA fragments. Whereas those ligands showing a high level of selectivity between quadruplex and duplex oligonucleotides, in terms of binding constants and percentage of bound DNA, confirmed their selectivity in the competition experiment, the contrary was not always true: some ligands showing poor selectivity with the autocomplementary dodecamer resulted selective in the presence of genomic DNA fragments. This result suggests that physiologically nonrelevant interactions are possible with a short duplex oligonucleotide. This means that the dodecamer can fail in representing a biologically significant structural model, or, better, that it can be used to quickly screen potentially selective molecules, but bearing in mind the high probability of false negative results. Copyright © 2008 John Wiley & Sons, Ltd.     

Structural varieties of selectively mixed G‐ and C‐rich short DNA sequences studied with electrospray ionization mass spectrometry

Short guanine(G)‐repeat and cytosine(C)‐repeat DNA strands can self‐assemble to form four‐stranded G‐quadruplexes and i‐motifs, respectively. Herein, G‐rich and C‐rich strands with non‐G or non‐C terminal bases and different lengths of G‐ or C‐repeats are mixed selectively in pH 4.5 and 6.7 ammonium acetate buffer solutions and studied by electrospray ionization mass spectrometry (ESI‐MS). Various strand associations corresponding to bi‐, tri‐ and tetramolecular ions are observed in mass spectra, indicating that the formation of quadruplex structures is a random strand by strand association process. However, with increasing incubation time for the mixtures, initially associated hybrid tetramers will transform into self‐assembled conformations, which is mainly driven by the structural stability. The melting temperature values of self‐assembled quadruplexes suggest that the length of G‐repeats or C‐repeats shows more significant effect on the stability of quadruplex structures than that of terminal residues. Accordingly, we can obtain the self‐associated tetrameric species generated from the mixtures of various homologous G‐ or C‐strands efficiently by altering the length of G‐ or C‐repeats. Our studies demonstrate that ESI‐MS is a very direct, fast and sensitive tool to provide significant information on DNA strand associations and stoichiometric transitions, particularly for complex mixtures. Copyright © 2016 John Wiley & Sons, Ltd.     

Stabilization of G‐Quadruplex DNA with Platinum(II) Schiff Base Complexes: Luminescent Probe and Down‐Regulation of c‐myc Oncogene Expression

The interactions of a series of platinum(II) Schiff base complexes with c‐myc G‐quadruplex DNA were studied. Complex [PtL ^1a ] ( 1 a ; H₂L ^1a =N,N′‐bis(salicylidene)‐4,5‐methoxy‐1,2‐phenylenediamine) can moderately inhibit c‐myc gene promoter activity in a cell‐free system through stabilizing the G‐quadruplex structure and can inhibit c‐myc oncogene expression in cultured cells. The interaction between 1 a and G‐quadruplex DNA has been examined by ¹H NMR spectroscopy. By using computer‐aided structure‐based drug design for hit‐to‐lead optimization, an in silico G‐quadruplex DNA model has been constructed for docking‐based virtual screening to develop new platinum(II) Schiff base complexes with improved inhibitory activities. Complex [PtL ³ ] ( 3 ; H₂L ³ = N,N′‐bis{4‐[1‐(2‐propylpiperidine)oxy]salicylidene}‐4,5‐methoxy‐1,2‐phenylenediamine) has been identified with a top score in the virtual screening. This complex was subsequently prepared and experimentally tested in vitro for its ability to stabilize or induce the formation of the c‐myc G‐quadruplex. The inhibitory activity of 3 (IC₅₀=4.4 μM ) is tenfold more than that of 1 a . The interaction between 1 a or 3 with c‐myc G‐quadruplex DNA has been examined by absorption titration, emission titration, molecular modeling, and NMR titration experiments, thus revealing that both 1 a and 3 bind c‐myc G‐quadruplex DNA through an external end‐stacking mode at the 3’ terminal face of the G‐quadruplex. Such binding of G‐quadruplex DNA with 3 is accompanied by up to an eightfold increase in the intensity of photoluminescence at λ_max=652 nm. Complex 3 also effectively down‐regulated the expression of c‐myc in human hepatocarcinoma cells.     

Separation of single‐base sequential isomers of single‐stranded DNA by capillary electrophoresis and its application in the discrimination of single‐base DNA mutations

Separation of single‐base substitution sequential DNA isomers remains one of the most challenging tasks in DNA separation by capillary electrophoresis. We developed a simple, versatile capillary electrophoresis technique for the separation of single‐base sequential isomers of DNA having the same chain length. This technique is based on charge differences resulting from the different protonation (acid dissociation) properties of the four DNA bases. A mixture of 13 single‐base sequential isomers of 12‐mer single‐stranded DNA was separated by using an electrophoretic buffer solution containing 20 mM phosphoric acid (pH 2.0) and 8 M urea. We demonstrated that our method could separate all possible mutation patterns under identical experimental conditions. In addition, application of our method to the separation of the polymerase chain reaction product of a 68‐mer gene fragment and its single‐base isomers indicates that in combination with the appropriate genomic DNA extraction techniques, the method can detect single‐base gene mutations.     

Multifunctional G‐Quadruplex Aptamers and Their Application to Protein Detection

Two significant G‐quadruplex aptamers named AGRO100 and T30695 are identified as multifunctional aptamers that can bind the protein ligands nucleolin or HIV‐1 integrase and hemin. Besides their strong binding to target proteins, both AGRO100 and T30695 exhibit high hemin‐binding affinities comparable to that of the known aptamer (termed PS2M) selected by the in vitro evolution process. Most importantly, their corresponding hemin–DNA complexes reveal excellent peroxidase‐like activities, higher than that of the reported hemin–PS2M DNAzyme. This enables these multifunctional aptamers to be applied to the sensitive detection of proteins, which is demonstrated by applying AGRO100 to the chemiluminescence detection of nucleolin expressed at the surface of HeLa cells. Based on the specific AGRO100–nucleolin interaction, the surface‐expressed nucleolin of HeLa cells is labeled in situ with the hemin–AGRO100 DNAzyme, and then determined in the luminol–H₂O₂ system. Through this approach, the sensitive detection of total nucleolin expressed at the surface of about 6000 HeLa cells is accomplished. Our results suggest that exploiting new functions of existing aptamers will help to extend their potential applications in the biochemical field.