Manufacturing Reusable NAND Logic Gates and Their Initial Circuits for DNA Nanoprocessors.

DNA-based computers can potentially analyze complex sets of biological markers, thereby advancing diagnostics and the treatment of diseases. Despite extensive efforts, DNA processors have not yet been developed due, in part, to limitations in the ability to integrate available logic gates into circuits. We have designed a NAND gate, which is one of the functionally complete set of logic connectives. The gate's design avoids stem-loop-folded DNA fragments, and is capable of reusable operations in RNase H-containing buffer. The output of the gate can be translated into RNA-cleaving activity or a fluorescent signal produced either by a deoxyribozyme or a molecular beacon probe. Furthermore, three NAND-gate-forming DNA strands were crosslinked by click chemistry and purified in a simple procedure that allowed ≈1013 gates to be manufactured in 16 h, with a hands-on time of about 30 min. Two NAND gates can be joined into one association that performs a new logic function simply by adding a DNA linker strand. Approaches developed in this work could contribute to the development of biocompatible DNA logic circuits for biotechnological and medical applications.

Deoxyribozyme-Based DNA Machines for Cancer Therapy.

Soon after their discovery, RNA-cleaving deoxyribozymes (RCDZ) were explored as anticancer gene therapy agents. Despite low toxicity found in clinical trials, there is no clinically significant anticancer RCDZ-based therapy. Some of the reported disadvantages of RCDZ agents include poor accessibility to folded nucleic acids, low catalytic efficiency inside cells, and problems of intracellular delivery. On the other hand, structural DNA nanotechnology provides an opportunity to build multifunctional nano-associations that can address some of these problems. Herein we discuss the possibility of building RCDZ-based multifunctional DNA nanomachines equipped with RNA unwinding, cancer marker recognition, and RCDZ-based RNA-cleavage functions. An important advantage of such "nanomachines" is the possibility to cleave a housekeeping gene mRNA in a cancer-cell-specific manner. The proposed design could become a starting point for building sophisticated DNA-based nanodevices for cancer treatment.

Cut and Paste for Cancer Treatment: A DNA Nanodevice that Cuts Out an RNA Marker Sequence to Activate a Therapeutic Function.

DNA nanotechnology uses oligonucleotide strands to assemble molecular structures capable of performing useful operations. Here, we assembled a multifunctional prototype DNA nanodevice, DOCTR, that recognizes a single nucleotide mutation in a cancer marker RNA. The nanodevice then cuts out a signature sequence and uses it as an activator for a "therapeutic" function, namely, the cleavage of another RNA sequence. The proposed design is a prototype for a gene therapy DNA machine that cleaves a housekeeping gene only in the presence of a cancer-causing point mutation and suppresses cancer cells exclusively with minimal side effects to normal cells.