Photocaged (photoactivatable) biomolecules are powerful tools for noninvasive control of biochemical activities by light irradiation. DNAzymes (deoxyribozymes) are single-stranded oligonucleotides with a broad range of enzymatic activities. In this work, to construct photocaged DNAzymes, we developed a facile and mild postsynthetic method to incorporate an interesting photolabile modification (thioether-enol phosphate, phenol substituted, TEEP-OH) into readily available phosphorothioate DNA. Upon light irradiation, TEEP-OH transformed into a native DNA phosphodiester, and accordingly the DNAzymes with RNA-cleaving activities were turned "on" from its inactive and caged form. Activation of the TEEP-OH-caged DNAzyme by light was also successful inside live cells.
G-quadruplex-containing DNAzymes and aptamers are widely applied in many research fields because of their high stability and prominent activities versus the protein counterparts. In this work, G-quadruplex DNAs were equipped with photolabile groups to construct photocaged DNAzymes and aptamers. We incorporated TEEP-OH (thioether-enol phosphate, phenol substituted) into phosphodiester backbone of G-quadruplex DNA by a facile post-synthetic method to achieve efficient photocaging of their activities. Upon light irradiation, the peroxidase-mimicking activity of the caged G-quadruplex DNAzyme was activated, through the transformation of TEEP-OH into a native DNA phosphodiester without any artificial scar. Similarly, the caged G-quadruplex thrombin-binding aptamer also showed light-induced activation of thrombin inhibition activity. This method could serve as a general strategy to prepare photocaged G-quadruplex DNA with other activities for noninvasive control of their functions.
Glass slides have been widely used for DNA immobilization in DNA microarray and numerous bioassays for decades, whereas they are faced with limitations of low probe density, time-consuming modification steps, and expensive instruments. In this work, a simple one-step surface modification method using 3-aminopropyl trimethoxysilane (APTMS) has been developed and applied to graft DNA codes on paper. Higher DNA immobilization efficiency was obtained in comparison with that in a conventional method using glass slides. Fluorescence detection, X-ray photoelectron spectroscopy (XPS), infrared spectra (FT-IR), and pH influence studies were employed to characterize the surface modification and subsequent DNA immobilization, which further reveals a mechanism in which this method lies in ionic interactions between the positively charged APTMS-modified paper surface and negatively charged DNA probes. Furthermore, an APTMS-modified paper-based device has been developed to demonstrate application in low-cost detection of a foodborne pathogen, Giardia lamblia, with high sensitivity (the detection limit of 22 nM) and high specificity. Compared with conventional methods using redundant cross-linking reactions, our method is simpler, faster, versatile, and lower-cost, enabling broad applications of paper-based bioassays especially for point-of-care detection in resource-poor settings.
Peroxidase-mimicking DNAzymes containing G-quadruplex structures are widely applied in chemistry as catalysts and signal amplification for biosensing. Enhancing the catalytic activity of these DNAzymes can therefore improve the performance of many catalysts and biosensors using them. In this work, we synthesized cationic peptide conjugates of peroxidase-mimicking DNAzymes, which were found to exhibit both enhanced peroxidase and oxidase activities up to 4-fold and 3-fold compared with the original DNAzymes, respectively. Further investigation suggested that the enhanced activity was ascribed to the stabilization of parallel DNA G-quadruplex structures and hemin binding by the cationic peptide covalently attached to the DNAzyme. Such a mechanism of activity enhancement was successfully utilized for biosensing applications with improved sensitivity and broadened target range. Hydrogen peroxide (H2O2) detection in K(+)-free solutions by the DNAzyme-peptide conjugate showed 2-fold sensitivity enhancement over the unmodified DNAzyme under the same condition, and the activity switch by target-induced cleavage of the DNAzyme-peptide conjugate was also used for the detection of caspase 3 protease with enzymatic amplification in homogeneous solutions.
The uranyl-dependent DNAzyme 39E cleaves its nucleic acid substrate in the presence of uranyl ion (UO 2 2+ ). It has been widely utilized in many sensor designs for selective and sensitive detection of UO 2 2+ in the environment and inside live cells. In this work, by inserting a flexible linker (C3 Spacer) into one critical site (A 20 ) of the 39E catalytic core, we successfully enhanced the original catalytic activity of 39E up to 8.1-fold at low UO 2 2+ concentrations. Applying such a modified DNAzyme (39E-A 20 -C3) in a label-free fluorescent sensor for UO 2 2+ detection achieved more than 1 order of magnitude sensitivity enhancement over using native 39E, with the UO 2 2+ detection limit improved from 2.6 nM (0.63 ppb) to 0.19 nM (0.047 ppb), while the high selectivity to UO 2 2+ over other metal ions was fully preserved. The method was also successfully applied for the detection of UO 2 2+ -spiked environmental water samples to demonstrate its practical usefulness.
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