If you have an ACS member number, please enter it here so we can link this account to your membership. (optional)

ACS values your privacy. By submitting your information, you are gaining access to C&EN and subscribing to our weekly newsletter. We use the information you provide to make your reading experience better, and we will never sell your data to third party members.


Biological Chemistry

Nanoconjugates Mimic RNAi

Nanozymes enter cells and cleave viral RNA without side effects

by Stu Borman
August 6, 2012 | A version of this story appeared in Volume 90, Issue 32

Credit: Proc. Natl. Acad. Sci. USA
A nanozyme is a gold nanoparticle (orange) combined with endonucleases (green) and DNAs (blue) complementary to a specific target RNA sequence (red). When DNA-RNA recognition occurs, the endonuclease cleaves the target RNA site-specifically.
This is a scheme showing how a nanozyme can cleave targeted RNA.
Credit: Proc. Natl. Acad. Sci. USA
A nanozyme is a gold nanoparticle (orange) combined with endonucleases (green) and DNAs (blue) complementary to a specific target RNA sequence (red). When DNA-RNA recognition occurs, the endonuclease cleaves the target RNA site-specifically.

A new type of nanoparticle-based conjugate is a promising alternative to RNA interference (RNAi) agents for controlling gene expression by cutting RNA selectively in cells, according to its developers (Proc. Natl. Acad. Sci. USA, DOI: 10.1073/pnas.1207766109).

The researchers demonstrated the capabilities of the conjugates, which they call nanozymes, by using them to cleave viral RNA and suppress viral replication in cultured cells and in mice. The nanozymes so far seem to be more stable, longer lasting, and less toxic than RNAi agents. If those qualities prove out in future work, nanozymes may have potential as therapeutics for diseases that can be treated by controlling gene expression.

Chemist Y. Charles Cao and pathologist Chen Liu at the University of Florida designed nanozymes to mimic RNA-induced silencing complexes (RISCs). The working components of RNAi, RISCs use endonucleases and target-complementing strands from small interfering RNAs (siRNAs) to cleave RNA in cells.

Nanozymes are gold nanoparticles decorated both with DNA sequences and endoribonucleases. The DNA sequences act like siRNA strands in that they complement target RNAs. And the nanozyme endoribonucleases, like RISC endoribonucleases, are capable of cleaving those target RNAs.

Cao, Liu, and coworkers customized the DNA sequences of their nanozyme to recognize RNA in the genome of hepatitis C virus (HCV), a cause of hepatitis, cirrhosis, and liver cancer. The nanozymes cut HCV RNA in vitro. They also readily enter cultured virus-infected human liver cells and cleave HCV RNA, reducing viral protein expression and subduing viral replication without causing any obvious toxicity to the cells. When administered to an HCV mouse model, the nanozymes reduce viral RNA levels 99%, also without causing noticeable toxicity or side effects.

The nanozyme approach “has the potential to overcome difficulties associated with the use of siRNA-based drugs,” which are currently being evaluated in clinical trials, Cao says. Nanozymes “are more stable than RNAi therapeutics,” he says, because siRNAs are more susceptible than nanozymes to degradation by endogenous nucleases and agents expressed by pathogens. In addition, nanozymes “can easily enter cells and engage targets,” he says, whereas delivery of RNAi agents remains a major challenge. The group is now further evaluating antihepatitis nanozymes in animals, “such as mice with humanized livers,” Cao says.

Nanobiotechnology and RNAi specialist Peixuan Guo of the University of Kentucky comments that nanozymes represent “an innovative new approach for gene silencing in cells and in vivo.”

Chemistry professor Peter A. Beal at the University of California, Davis, whose areas of specialization include RNAi, says nanozymes “open up new possibilities for targeted RNA cleavage, particularly where RNAi with siRNAs is not possible or is impractical.” siRNAs can cause side effects by binding sequences that are similar but not identical to targets, and they can cause immune reactions by inducing endogenous cytokines. It will now be important to evaluate how nanozymes respond to DNA/target-RNA mismatches and to assess whether they induce a range of different cytokines, Beal notes.

The customized nanozymes “target hepatitis C virus with great results,” says C. Shad Thaxton of Northwestern University’s Feinberg School of Medicine. “This is the type of research that continues to advance therapeutic nanotech forward to fulfill the promise of exquisitely targeted and specific therapies for any number of human disease processes,” he notes.

Nathaniel L. Rosi, a specialist in nanoparticle assembly and materials discovery at the University of Pittsburgh, says the work represents one of the first examples of second-generation nanoparticle-based bioactive agents because it adds endonuclease to first-generation nanoparticle/nucleic acid constructs. First-generation constructs control gene expression by using only nucleic acid binding to block translation. A future third generation of such agents, he says, will add targeting moieties to nanoparticle conjugates to provide greater selectivity for specific tissues such as tumors or specific organs such as the liver.

Cao agrees with this vision of the future. “For use as therapeutics against other protein-expression-related diseases such as cancer, the key hurdle will be how to deliver the nanozyme to specific organs or cell types,” he says. “In principle, our nanozyme platform allows us to add functionality that could direct nanozymes to specific tissues, organs, and even subcellular organelles that express target genes.” He and his coworkers hope to pursue that approach in future work.



This article has been sent to the following recipient:

Chemistry matters. Join us to get the news you need.