Q: Many of us became familiar with RNA because of the development of the COVID-19 vaccine. How was that created and what does it tell us about what RNA can do?

Many years ago, scientists Dr. Drew Weissman and Katalin Karikó started asking: If typical vaccines involve proteins from viruses, is there a different way to make vaccines that don’t involve injecting people with the protein itself, but with the molecule that programs the protein to induce immunity against the virus — the messenger RNA itself? There were practical challenges: RNA is fragile and can also induce a bad inflammatory response. So making a safe, effective vaccine involved not only mastering the immunity-causing mechanism but creating a way to help the RNA last in the cell without causing dangerous inflammation. During the pandemic, the modification that went into this RNA representing the COVID genome worked. And that’s the understanding that won Weissman and Karikó a Nobel Prize last year. Compared to making a protein-based vaccine, which can take many months or even years, it takes no time at all to modify RNA in the lab. The beauty of RNA is that it’s sufficiently stable to help solve a problem or create a cure or a vaccine, but also sufficiently unstable that it doesn’t alter a person’s genetic makeup, as would happen with manipulations of DNA.

Q: What do you see as some of the most exciting potential applications of RNA for health and medicine?

Sequencing all of human RNA and its modifications could help produce new diagnostic tools to detect diseases such as Alzheimer’s, revolutionize understanding of the human body and lead to cures and treatments for illnesses such as cancer. But beyond health and medicine, RNA modifications also show promise for solving other challenges facing humanity, such as addressing starvation by enhancing agricultural productivity.

Q: Let’s talk about modifications: tiny tweaks to the nucleotides that are critical to RNA’s function. Your research focus has been on RNA modifications of a special RNA called transfer RNA (tRNA), which serves as a link between the mRNA molecule and the chain of amino acids that make up a protein. How much of a focus are modifications at the RNA Center?

Adding modifications to RNA is one of the focuses of the RNA Center, and that’s the core of my expertise. There are 185 different chemicals that are added to RNA naturally to create modifications, and you can game them for different purposes. For example, some researchers are testing modifications in the hope of creating a vaccine for cancer. Because adding modifications can be done very quickly in the lab, the field is moving at a very fast pace.

Q: What are some of the outstanding questions about how to use and modify RNA to benefit human health?

Well, in addition to sequencing RNA and its modifications, figuring out what different RNA are doing in the cell, and how RNA relates to different diseases and conditions, we also need to understand how to manipulate it. Compared to typical vaccines, for example, the delivery of RNA is totally different. So how do you take the RNA and deliver it where you want it? This is where a huge part of the research is dedicated now. For example, let's imagine that a person has a problem that is affecting their liver. How do you make RNA so specific that it only targets the liver and nowhere else in the body? This is where bioengineers start playing with different nanoparticles and how they package the RNA so that is has specificity for one organ and none of the others.

Q: How does the Brown RNA Center bring together different academic departments and research disciplines?

I describe it as a series of concentric circles. In the middle are the basic scientists who research molecular biology, genetics, biochemistry and biophysics, because the core of the center should be fundamental RNA science — how RNA is implicated in and impacted by illness and disease so that it might be used in a therapy. The RNA Center just welcomed Shobha Vasudevan, an associate professor of molecular biology, cell biology and biochemistry (research), who is researching the therapeutic applications of RNA; her lab studies the role of RNA mechanisms in cancer cells. The next concentric circle are the bioengineers who are figuring how to use RNA — how to translate the discoveries into therapies, or medication, to treat illnesses, diseases or conditions. The RNA Center just brought in a bioengineering expert named Theresa Raimondo who is well known for her research on the packaging and delivery of RNA for the development of new therapies. Finally, there are the clinicians, who are the ones who will prescribe and use the therapies to help patients. All of those people should be able to talk back and forth and solve each other's problems.

Q: You played a lead role in a Consensus Study Committee convened in 2023 by the National Academies of Science, Engineering, and Medicine to study the direct sequencing of all human RNA and its modifications. In March, the committee released a report, sponsored by The Warren Alpert Foundation and the National Institutes of Health, titled, “Charting a Future for Sequencing RNA and its Modifications.” What were some of the takeaways?

We’ve gotten to the state where many scientists are using different devices to sequence RNA and generating different databases in their own respective labs. And the data doesn’t sync up. When you put RNA through one of these devices, you get around 1 billion pieces of information that have to be sorted out computationally — I mean, that kind of scale is crazy. We currently lack technology that can accurately read RNA molecules and their modifications. The point of the committee was to try to ask the question, can the scientific community study and sequence RNA well, and in a manner that can be reliable and comparable? Can we set standards for devices as well as for data so that we’re all comparing the same findings? In the report, we offer roadmaps for technology, workforce and database development, and call for a substantial investment of time and resources, on a national and international scale.

In late August, there will be an RNA summit in Washington of the other national academies with government and industry partners and members of the National Academies of Science, Engineering, and Medicine committee. The goal is to talk about where we are as a scientific community in terms of understanding this remarkable tool of RNA, where we need to go, and how we’re going to get there.