Boshi Fu

Novel Amplex Red Oxidases Based on Noncanonical DNA Structures: Property Studies and Applications in MicroRNA Detection

G-triplex has recently been identified as a new secondary structure in G-rich sequences. However, its functions and biological roles remain largely unknown. This study first developed two kinds of Amplex Red oxidases, which were based on relatively new G-triplex structure and a common G-quadruplex one. A collection of DNA binding assays including circular dichroism (CD) spectroscopy, a CD melting assay, and a UV titration study were used to determine the G-triplex structure of G3 oligomer. The low intrinsic oxidative activity of hemin was significantly enhanced using G-triplex or G-quadruplex. Only one key guanine deletion from the G3 oligomer or G4 one could result in a much decreased Amplex Red oxidation activity. To the best of our knowledge, this is the first case reporting direct use of air as the oxidant for fluorescence generation based on DNAzyme strategies. Further mechanism studies demonstrated an involvement of on-site H2O2 generation from O2 and water and a following oxidation of Amplex Red to resorufin, causing a fluorescence enhancement. Furthermore, the newly developed oxidases have been effectively used in microRNA detection, using only one biotin-labeled probe and one small-molecule substrate. The conjugation of a target DNA to the G-triplex- or G-quadruplex-forming sequence enabled one to produce G-triplex or G-quadruplex by endonuclease in the presence of a slight amount of miRNA and amplify the signal of fluorescence from the oxidation of Amplex Red. Our findings of novel Amplex Red oxidases could potentially be used in a wide range of applications.

A highly conserved G-rich consensus sequence in hepatitis C virus core gene represents a new anti-hepatitis C target.

A conserved guanine-rich sequence could be a new target for anti–hepatitis C virus drug development. G-quadruplex (G4) is one of the most important secondary structures in nucleic acids. Until recently, G4 RNAs have not been reported in any ribovirus, such as the hepatitis C virus. Our bioinformatics analysis reveals highly conserved guanine-rich consensus sequences within the core gene of hepatitis C despite the high genetic variability of this ribovirus; we further show using various methods that such consensus sequences can fold into unimolecular G4 RNA structures, both in vitro and under physiological conditions. Furthermore, we provide direct evidences that small molecules specifically targeting G4 can stabilize this structure to reduce RNA replication and inhibit protein translation of intracellular hepatitis C. Ultimately, the stabilization of G4 RNA in the genome of hepatitis C represents a promising new strategy for anti–hepatitis C drug development.

Chemical Targeting of a G-Quadruplex RNA in the Ebola Virus L Gene

In the present study, our bioinformatics analysis first reveals the existence of a conserved guanine-rich sequence within the Zaire ebolavirus L gene. Using various methods, we show that this sequence tends to fold into G-quadruplex RNA. TMPyP4 treatment evidently inhibits L gene expression at the RNA level. Moreover, the mini-replicon assay demonstrates that TMPyP4 effectively inhibits the artificial Zaire ebolavirus mini-genome and is a more potent inhibitor than ribavirin. Although TMPyP4 treatment reduced the replication of the mutant mini-genome when G-quadruplex formation was abolished in the L gene, its inhibitory effect was significantly alleviated compared with wild-type. Our findings thus provide the first evidence that G-quadruplex RNA is present in a negative-sense RNA virus. Finally, G-quadruplex RNA stabilization may represent a new therapeutic strategy against Ebola virus disease.

A two-photon fluorescent probe for intracellular detection of tyrosinase activity.

AAN effective sensor: The two-photon turn-on fluorescent probe NHU was synthesized to optically detect tyrosinase activity in vitro and in melanoma cells. NHU is composed of a 4-aminophenol moiety and a naphthylamine unit, both of which are connected through a urea linkage. Upon exposure to tyrosinase, the 4-aminophenol site is gradually oxidized to the corresponding orthoquinone, ultimately releasing the highly fluorescent product 6-acyl-N-methyl-2-naphthylamine (AAN).

A turn-on fluorescent probe for detection of tyrosinase activity

We have presented a fluorescent probe that exhibits a fluorescence turn-on signal upon reaction with tyrosinase, and we show that it can be readily employed for the assessment of tyrosinase activity and tyrosinase inhibitor activities in buffered aqueous solution.

Small-Molecule-Triggered and Light-Controlled Reversible Regulation of Enzymatic Activity

The fine control of enzyme activity is essential for the regulation of many important cellular and organismal functions. The light-regulation of proteins serves as an important method for the spatiotemporal control over the production and degradation of an enzyme product. This area is of intense interest for researchers. To the best of our knowledge, the use of small molecules as light-triggered molecular switches to reversibly control enzyme activity at the protein level has not yet been studied. In the present study, we demonstrate the light-controlled reversible regulation of the enzyme using a small-molecule-triggered switch, which is based on molecular recognition between an azobenzene derivative and telomere DNA. This molecule interconverts between the trans and cis states under alternate 365 nm UV and visible light irradiation, which consequently triggers the compaction and extension of telomere DNA. We further provide direct evidence for this structural switch using a circular dichroism study. Furthermore, our strategy has been successfully used to effectively control blood clotting in human plasma.

Reversible manipulation of the G-quadruplex structures and enzymatic reactions through supramolecular host–guest interactions

Abstract Supramolecular chemistry addresses intermolecular forces and consequently promises great flexibility and precision. Biological systems are often the inspirations for supramolecular research. The G-quadruplex (G4) belongs to one of the most important secondary structures in nucleic acids. Until recently, the supramolecular manipulation of the G4 has not been reported. The present study is the first to disclose a supramolecular switch for the reversible control of human telomere G4s. Moreover, this supramolecular switch has been successfully used to manipulate an enzymatic reaction. Using various methods, we show that cucurbit[7]uril preferably locks and encapsulates the positively charged piperidines of Razo through supramolecular interactions. They can switch the conformations of the DNA inhibitor between a flexible state and the rigid G4 and are therefore responsible for the reversible control of the thrombin activity. Thus, our findings open a promising route and exhibit potential applications in future studies of chemical biology.

Cucurbit[7]uril-Driven Host–Guest Chemistry for Reversible Intervention of 5-Formylcytosine-Targeted Biochemical Reactions

5-Formylcytosine (5fC) is identified as one of the key players in active DNA demethylation and also as an epigenetic mark in mammals, thus representing a novel attractive target to chemical intervention. The current study represents an attempt to develop a reversible 5fC-targeted intervention tool. A supramolecular aldehyde reactive probe was therefore introduced for selective conversion of the 5fC to 5fC-AD nucleotide. Using various methods, we demonstrate that cucurbit[7]uril (CB7) selectively targets the 5fC-AD nucleotide in DNA, however, the binding of CB7 to 5fC-AD does not affect the hydrogen bonding properties of natural nucleobases in duplex DNA. Importantly, CB7-driven host-guest chemistry has been applied for reversible intervention of a variety of 5fC-targeted biochemical reactions, including restriction endonuclease digestion, DNA polymerase elongation, and polymerase chain reaction. On the basis of the current study, the macrocyclic CB7 creates obstructions that, through steric hindrance, prevent the enzyme from binding to the substrate, whereas the CB7/5fC-AD host-guest interactions can be reversed by treatment with adamantanamine. Moreover, fragment- and site-specific identification of 5fC modification in DNA has been accomplished without sequence restrictions. These findings thus show promising potential of host-guest chemistry for DNA/RNA epigenetics.

The Cucurbit[7]Uril-Based Supramolecular Chemistry for Reversible B/Z-DNA Transition

Abstract As a left‐handed helical structure, Z‐DNA is biologically active and it may be correlated with transcription and genome stability. Until recently, it remained a significant challenge to control the B/Z‐DNA transition under physiological conditions. The current study represents the first to reversibly control B/Z‐DNA transition using cucurbit[7]uril‐based supramolecular approach. It is demonstrated that cucurbit[7]uril can encapsulate the central butanediamine moiety [HN(CH2)4NH] and reverses Z‐DNA caused by spermine back to B‐DNA. The subsequent treatment with 1‐adamantanamine disassembles the cucurbit[7]uril/spermine complex and readily induces reconversion of B‐ into Z‐DNA. The DNA conformational change is unequivocally demonstrated using different independent methods. Direct evidence for supramolecular interactions involved in DNA conformational changes is further provided. These findings can therefore open a new route to control DNA helical structure in a reversible way.