Catalytic nucleic acids (DNAzymes or ribozymes) are selected by the systematic evolution of ligands by exponential enrichment process (SELEX). The catalytic functions of DNAzymes or ribozymes allow their use as amplifying labels for the development of optical or electronic sensors. The use of catalytic nucleic acids for amplified biosensing was accomplished by designing aptamer-DNAzyme conjugates that combine recognition units and amplifying readout units as in integrated biosensing materials. Alternatively, "DNA machines" that activate enzyme cascades and yield DNAzymes were tailored, and the systems led to the ultrasensitive detection of DNA. DNAzymes are also used as active components for constructing nanostructures such as aggregated nanoparticles and for the activation of logic gate operations that perform computing.
The catalytic enlargement of aptamer-functionalized Au nanoparticles amplifies the optical detection of aptamer-thrombin complexes in solution and on surfaces.
DNAzyme cascades activated by Pb(2+)- or L-histidine-dependent DNAzymes yield the horseradish peroxidase-mimicking catalytic nucleic acids that enable the colorimetric or chemiluminescence detection of Pb(2+) or L-histidine.
The activation of a DNAzyme cascade by the cooperative self-assembly of multicomponent nucleic acid structures is suggested as a method for the amplified sensing of DNA, or the specific substrates of aptamers. According to one configuration, the DNA analyte 1 is detected by two tailored nucleic acids 2 and 3 that form a multicomponent supramolecular structure with a ribonucleobase-containing quasi-circular DNA 4, but only upon the concomitant hybridization with 1. The resulting supramolecular nucleic acid structure includes the Mg(2+)-dependent DNAzyme that cleaves the ribonucleobase site of 4. The cleavage of the quasi-circular DNA 4 results in the fragmentation of the supramolecular structure and the release of two horseradish peroxidase (HRP) mimicking units that were incorporated in the blocked quasi-circular DNA 4. The HRP-mimicking DNAzyme catalyzed the oxidation of 2,2'-azino-bis(3-ethylbenzothiazoline)-6-sulfonic acid (ABTS(2-)) by H(2)O(2) to ABTS(*-), and the product provided the colorimetric readout signal for the analyzed DNA. The method enabled the analysis of DNA with a detection limit of 1 x 10(-12) M. Similarly, an analogous DNAzyme cascade was activated by the low-molecular-weight substrates, adenosine triphosphate (ATP) or cocaine. This was induced by the self-assembly of nucleic acids that included fragments of the respective aptamers and the Mg(2+)-dependent DNAzyme. Furthermore, nucleic acids consisting of fragments of the aptamers against ATP or cocaine and fragments of the HRP-mimicking DNAzyme self-assemble, in the presence of the respective substrates, to the active DNAzyme structure that catalyzes the oxidation of ABTS(2-) by H(2)O(2) to form the colored product ABTS(*-). The resulting product provided the readout signal for the recognition events. The cooperative interaction in the formation of the supramolecular nucleic acid assemblies and the activation of the DNAzymes are discussed.
A conjugate consisting of a thrombin aptamer tethered to the thrombin, Th, with a sensing nucleic acid (1) is used for the optical detection of DNA. The thrombin/aptamer complex blocks the biocatalytic functions of Th. Hybridization of the analyte DNA (2) to the sensing nucleic acid 1 yields a rigid duplex that detaches the aptamer from Th, a process that activates the protein toward the hydrolysis of bis(p-tosyl-Gly-Pro-Arg)-R110 (3) to the rhodamine 110 fluorophore (4). The system allows the DNA sensing with a sensitivity limit of 1 x 10-8 M. The aptamer/Th conjugate is also immobilized on glass slides for the optical detection of DNA. The dissociation of the aptamer/Th complex upon hybridization and the subsequent dehybridization of the duplex and the regeneration of the catalytically inactive Th/aptamer complex duplicate machinery functions.
A bifunctional aptamer that includes two aptamer units for cocaine and adenosine 5'-monophosphate (AMP) is blocked by a nucleic acid to form a hybrid structure with two duplex regions. The blocked bifunctional aptamer assembly is used as a functional structure for the simultaneous sensing of cocaine or AMP. The blocked bifunctional aptamer is dissociated by either of the two analytes, and the readout of the separation of the sensing structure is accomplished by a colorimetric detection, by a released DNAzyme, or by electronic means that use Faradaic impedance spectroscopy or field-effect transistors. In one configuration, the blocked bifunctional aptamer structure is separated by the substrates cocaine or AMP, and the displaced blocker units act as a horseradish peroxidase-mimicking DNAzyme that permits the colorimetric detection of the analytes. In the second system, the blocked bifunctional aptamer hybrid is associated with a Au electrode. The displacement of the aptamer by any of the substrates alters the interfacial electron transfer resistance at the electrode surface, thus providing an electronic signal for the sensing process. In the third configuration, the blocked aptamer hybrid is linked to the gate of a field-effect transistor device. The separation of the complex by means of any of the analytes, cocaine, or AMP alters the gate potential, and this allows the electronic transduction of the sensing process by following the changes in the gate-to-source potentials. The different systems enable not only the simultaneous detection of the two analytes, but they provide a functional assembly that performs a logic gate "OR" operation.
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