Zoya Cheglakov

Diagnosing viruses by the rolling circle amplified synthesis of DNAzymes

Circular DNA is used as a template for the amplified detection of M13 phage ssDNA by a rolling circle amplification (RCA) process that synthesizes DNAzyme chains, thus enabling the colorimetric or chemiluminescent detection of the analyte.

A polycatenated DNA scaffold for the one-step assembly of hierarchical nanostructures

A unique DNA scaffold was prepared for the one-step self-assembly of hierarchical nanostructures onto which multiple proteins or nanoparticles are positioned on a single template with precise relative spatial orientation. The architecture is a topologically complex ladder-shaped polycatenane in which the “rungs” of the ladder are used to bring together the individual rings of the mechanically interlocked structure, and the “rails” are available for hierarchical assembly, whose effectiveness has been demonstrated with proteins, complementary DNA, and gold nanoparticles. The ability of this template to form from linear monomers and simultaneously bind two proteins was demonstrated by chemical force microscopy, transmission electron microscopy, and confocal fluorescence microscopy. Finally, fluorescence resonance energy transfer between adjacent fluorophores confirmed the programmed spatial arrangement between two different nanomaterials. DNA templates that bring together multiple nanostructures with precise spatial control have applications in catalysis, biosensing, and nanomaterials design.

Live Cell MicroRNA Imaging Using Cascade Hybridization Reaction

Recent advances in RNA research have posed new directives in biology and chemistry to uncover the complex roles of ribonucleic acids in cellular processes. Innovative techniques to visualize native RNAs, particularly, short, low-abundance RNAs in live cells, can dramatically impact current research on the roles of RNAs in biology. Herein, we report a novel method for real-time, microRNA imaging inside live cells based on programmable oligonucleotide probes, which self-assemble through the Cascade Hybridization Reaction (CHR).

Ultrasensitive detection of DNA by the PCR-Induced generation of DNAzymes: The DNAzyme primer approach

The ultrasensitive detection of DNA is achieved by PCR-induced evolution of a DNAzyme.

An autonomous fueled machine that replicates catalytic nucleic acid templates for the amplified optical analysis of DNA.

Here we describe a protocol for the amplified detection of a target DNA using a DNA/FokI-based replicating cutting machine. The protocol is based on the design of a sensing hairpin oligonucleotide that is opened upon hybridization with the analyte DNA. The endonuclease FokI binds to the double-stranded complex and cleaves it to a “cutter” unit. The “cutter” unit reacts with a fuel oligonucleotide to generate and amplify the signal. The fuel molecule is an oligonucleotide in a hairpin configuration with a fluorophore/quencher pair attached to the 5′ and 3′ ends. Formation of the duplex between the cutter and the fuel leads to the scission of the duplex by FokI, leading to a second, replicated “cutter”, a fluorescent waste product, and to the regeneration of the original “cutter” unit. The autonomous replication of the “cutter” unit, as a result of the primary recognition of the analyte DNA, leads to the amplified fluorescent detection of the analyte DNA with a sensitivity limit of 1 × 10−14 M. The operation of the machine and the sensing process are monitored by the fluorescence generated by the waste product. Here we apply the protocol, which takes about 2 h to complete, to analyze a Tay-Sachs genetic disorder mutant DNA.

Plasmonic Photothermal Gold Bipyramid Nanoreactors for Ultrafast Real-Time Bioassays

Nucleic acid amplification techniques have been among the most powerful tools for biological and biomedical research, and the vast majority of the bioassays rely on thermocycling that uses time-consuming and expensive Peltier-block heating. Here, we introduce a plasmonic photothermal method for quantitative real-time PCR, using gold bipyramids and light to achieve ultrafast thermocycling. Moreover, we successfully extend our photothermal system to other biological assays, such as isothermal nucleic acid amplification and restriction enzyme digestion.