Hongcheng Mei

Conservative secondary structure motif of streptavidin-binding aptamers generated by different laboratories

Aptamers that are selected in vitro from random pools of DNA or RNA molecules by SELEX (Systematic evolution of ligands by exponential enrichment) technique have been extensively explored for analytical and biomedical applications. Although many aptamers with high affinity and specificity against specific ligands have been reported, there is still a lack of well characterized DNA aptamers. Here we report the selection of a group of aptamer candidates (85 mer) against streptavidin. Through comparing the predicted secondary structures of all the candidates, a conservative bulge-hairpin structure section (about 29 mer) was found, and then it was determined to be the binding motif to streptavidin. This binding motif was further discovered to also exist in streptavidin-binding aptamers (SBAs) selected by three other laboratories using different methods. The primary sequences of this secondary structure motif are very different, only several nucleotides in the loop and bulge area are critical for binding and other nucleotides are variable. The streptavidin binding of all the SBAs could be competed by biotin implying that they bind to the same site on streptavidin. These results suggest that the evolution of SBA is predominated by specific groups on streptavidin. The highly variable sequence composition of streptavidin-binding aptamer would make the design of aptameric sensor or device based on streptavidin more flexible and easy.

Characterization of G‐Quadruplex/Hemin Peroxidase: Substrate Specificity and Inactivation Kinetics

Recently, G-quadruplex/hemin (G4/hemin) complexes have been found to exhibit peroxidase activity, and this feature has been extensively exploited for colorimetric detection of various targets. To further understand and characterize this important DNAzyme, its substrate specificity, inactivation mechanism, and kinetics have been examined by comparison with horseradish peroxidase (HRP). G4/hemin DNAzyme exhibits broader substrate specificity and much higher inactivation rate than HRP because of the exposure of the catalytic hemin center. The inactivation of G4/hemin DNAzyme is mainly attributed to the degradation of hemin by H(2)O(2) rather than the destruction of G4. Both the inactivation rate and catalytic oxidation rate of G4/hemin DNAzyme depend on the concentration of H(2)O(2), which suggests that active intermediates formed by G4/hemin and H(2)O(2) are the branch point of catalysis and inactivation. Reducing substrates greatly inhibit the inactivation of G4/hemin DNAzyme by rapidly reacting with the active intermediates. A possible catalytic and inactivation process of G4/hemin has been proposed. These results imply a potential cause for the hemin-mediated cellular injury and provide insightful information for the future application of G4/hemin DNAzyme.

G-quadruplex DNA aptamers for zeatin recognizing

Zeatins, a major type of cytokinin, are ubiquitous in higher plants, and involve in regulating a wide range of developmental processes. The development of highly specific ligands to zeatins would be very useful in plant biological research. Here we describe a group of oligonucleotide ligands (aptamers) generated against trans-zeatin. The optimized aptamers possess strong affinity to trans-zeatin and trans-zeatin riboside (Kd=3-5 μM), and relatively weak affinity (Kd=27-30 μM) to cis-zeatin and dihydrozeatin. These aptamers adopt a hairpin-G-quadruplex structure for binding to zeatin. A fluorescence turn-on aptasensor based on graphene oxide (GO) was developed for the recognition of zeatins. The specificity assay of this aptasensor shows good response to zeatins, and no response to the adenine derivatives (analog of zeatins) abundantly existing in biological samples. These results show the great potential of these aptamers in chemical analysis and biological investigation of zeatins.

G-quadruplex DNA aptamers generated for systemin

Ligands specific to bioactive molecules play important roles in biomedical researches and applications, such as biological assay, diagnosis and therapy. Systemin is a peptide hormone firstly identified in plant. In this paper we report the selection of a group of DNA aptamers that can specifically bind to systemin. Through comparing the predicted secondary structures of all the aptamers, a hairpin structure with G-rich loop was determined to be the binding motif of these aptamers. The G-rich loop region of this binding motif was further characterized to fold into an antiparallel G-quadruplex by truncation-mutation assay and CD spectrum. The apparent equilibrium dissociation constant (K(d)) of one strong binding sequence (S-5-1) was measured to be 0.5 μM. The specificity assay shows that S-5-1 strongly bind to whole systemin, weakly bind to truncated or mutated systemin and does not bind to the scrambled peptide with the same amino acid composition as systemin. The high affinity and specificity make S-5-1 hold potentials to serve as a molecular ligand applied in detection, separation and functional investigation of systemin in plants.

Activity enhancement of G-quadruplex/hemin DNAzyme by spermine

Biogenic polyamines participate in regulating gene expression, activating DNA synthesis and facilitating DNA–protein interaction through interaction with DNA/RNA. The interaction of polyamines with G-quadruplexes (G4s) has been reported to modulate the structure of G4s. In this paper, we investigate the effects of polyamines on one of the properties of G4s, G4/hemin peroxidase. Three polyamines (spermine, spermidine and putrescine) are found to have positive effects on different G4/hemin DNAzymes, in which spermine exhibits the strongest enhancement efficiency. CD and UV/Vis spectral analysis suggests two reasons for the strong activity enhancement: first, spermine protects hemin from rapid degradation by H2O2; second, spermine condenses the G4 structures and provides a favorable microenvironment for the catalytic reaction. Since G4/hemin DNAzymes have been extensively applied in various chemical sensors and biosensors, this finding would be helpful for the design of G4/hemin based sensors and widen the application range of this kind of DNAzyme.

Functional-group specific aptamers indirectly recognizing compounds with alkyl amino group.

Aptamers are usually generated against a specific molecule. Their high selectivity makes them only suitable for studying specific targets. Since it is nearly impossible to generate aptamers for every molecule, it can be of great interest to select aptamers recognizing a common feature of a group of molecules in many applications. In this paper, we describe the selection of aptamers for indirect recognition of alkyl amino groups. Because amino groups are small and positive charged, we introduced a protection group, p-nitrobenzene sulfonyl (p-nosyl) to convert them into a form suitable for aptamer selection. Taking N(ε)-p-nosyl-L-lysine (PSL) as a target, we obtained a group of aptamers using the SELEX technique. Two optimized aptamers, M6b-M14 and M13a exhibit strong affinity to PSL with the K(d) values in the range of 2-5 μM. They also show strong affinity to other compounds containing p-nosyl-protected amino groups except those also possessing an α-carboxyl group. Both aptamers adopt an antiparallel G-quadruplex structure when binding to targets. An aptamer beacon based on M6b-M14 showed good selectivity toward the reaction mixture of p-nosyl-Cl and alkyl amino compounds, and could recognize lysine from amino acid mixtures indirectly, suggesting that aptamers against a common moiety of a certain type of molecules can potentially lead to many new applications. Through this study, we have demonstrated the ability to select aptamers for a specific part of an organic compound, and the chemical conversion approach may prove to be valuable for aptamer selection against molecules that are generally difficult for SELEX.

A fluorescence aptasensor based on DNA charge transport for sensitive protein detection in serum

A novel fluorescence aptasensor based on DNA charge transport for sensitive protein detection has been developed. A 15nt DNA aptamer against thrombin was used as a model system. The aptamer was integrated into a double strand DNA (dsDNA) that was labeled with a hole injector, naphthalimide (NI), and a fluorophore, Alexa532, at its two ends. After irradiation by UV light, the fluorescence of Alexa532 was bleached due to the oxidization of Alexa532 by the positive charge transported from naphthalimide through the dsDNA. In the presence of thrombin, the binding of thrombin to the aptamer resulted in the unwinding of the dsDNA into ssDNA, which led to the blocking of charge transfer and the strong fluorescence emission of Alexa532. By monitoring the fluorescence signal change, we were able to detect thrombin in homogeneous solutions with high selectivity and high sensitivity down to 1.2 pM. Moreover, as DNA charge transfer is resistant to interferences from biological contexts, the aptasensor can be used directly in undiluted serum with similar sensitivity as that in buffer. This new sensing strategy is expected to promote the exploitation of aptamer-based biosensors for protein assays in complex biological matrixes.