Small-scale engineering could bring big progress in medical care

image: Ira A. Fulton Schools of Engineering Associate Professor Xiao Wang's research group draws on expertise in mathematics, physics, molecular biology, biomedical engineering and computer sciences to pursue advances in biological and health systems engineering.

Image: 
Ira A. Fulton Schools of Engineering at Arizona State University

Effective diagnostics, therapies and treatments for diseases and infections could increasingly involve re-engineering the body’s internal biomechanisms at their most basic chemical and molecular foundations.

Growing knowledge about the body’s biological processes is increasing the possibilities for restoring human health, says Xiao Wang, an associate professor of biomedical engineering in Arizona State University’s Ira A. Fulton Schools of Engineering. He and a team of researchers are exploring ways to trigger and control cell differentiation and transition to unlock properties that may change bioengineers’ approach to diagnostics, vaccine development and therapeutic treatments.

Recent research led by Wang and Alexander Green, an assistant professor of biomedical engineering at Boston University, reveals more about the potential for designing small add-on structures for biomolecules that can enhance their properties.

“There could be new and better kinds of applications for diagnostics, therapeutics and treatments, and for genome engineering,” Wang says. “These could be big contributions to biomedicine.”

The details about what the research may yield appear in the paper Predictable control of RNA lifetime using engineered degradation-tuning RNAs, published this week in the research journal Nature Chemical Biology.

Wang and Green’s focus is on messenger RNA, or mRNA, which carries genetic information from DNA, the molecule that contains the genetic blueprint needed to develop and maintain organisms — including humans.

Within cells, mRNA transmits messages from DNA to the protein-producing ribosomes, informing them of which proteins need to be synthesized at a given time. While DNA’s status as the information repository of the cell means that it is very stable, mRNA’s message-carrying role means it rapidly degrades. This degradation has made it harder to implement RNA-based therapies and diagnostics.

Wang, Green and their research team are devising methods of controlling degradation to produce predictable, precise and stable results. The new research paper describes how they are attempting to fine-tune the speed of mRNA degradation to boost the ability to perform biotechnological functions. To do this, they have identified specific RNA structural features to build a library of RNA components called degradation-tuning RNAs, or dtRNAs.

Attaching the dtRNAs to an RNA of interest through genetic engineering enables them to increase or decrease the RNA’s degradation rate, and fine-tune gene expression levels in vivo and in vitro — either inside a living organism or in a laboratory setting.

“We found that dtRNAs could be used with a variety of different types of RNAs and modify gene expression levels over a very wide range. These capabilities can increase the speed and sensitivity of medical diagnostics and give us better control over cell function,” says Green, who was an assistant professor in ASU’s Biodesign Institute and School of Molecular Sciences from 2015 to 2020 and is currently an adjunct professor with the school.

One of the more impactful results of these refining processes could be the development of mRNA-based vaccines that would be especially effective against viruses, Wang says.

“We can actually engineer the structure of RNA molecules in faster and more systematic ways that make them more efficient in how they behave,” he says.

These behavior changes will inform how effective Wang and Green’s bioengineering process will be at boosting the efficacy of diagnostics, vaccines, therapies and treatments.

Credit: 
Arizona State University