On Jan. 30, 2026, researchers at the Texas A&M University Health Science Center (Texas A&M Health) announced they had identified a novel RNA molecule that plays a crucial role in preserving the integrity of a key cellular structure, nucleolus (a dense region of the cell containing a subset of crucial genetic material). Their findings also suggest this molecule may influence patient survival in certain blood cancers. The study was study published in the Proceedings of the National Academy of Sciences (PNAS)

RNA, or ribonucleic acid, is a short-lived molecule copied from DNA that enables cells to use genetic information. Specific DNA sequences are copied into RNA, which then delivers these instructions to the cellular machinery responsible for making proteins. Through this process, RNA acts as the go-between, translating DNA’s blueprints into real-time cellular activity. This research reveals an RNA molecule that regulates key cellular functions without turning into protein, thus functioning as a “non-coding” RNA.

The laboratory of Irtisha Singh, PhD, at the Texas A&M Naresh K. Vashisht College of Medicine identified a novel non-coding RNA they named CUL1-IPA that originates from the well-characterized CUL1 protein-coding gene. Unlike the canonical RNA that produces the CUL1 protein, this newly discovered RNA stays in the nucleus. Instead, it performs a completely different cellular function, supporting the structural integrity and activity of the nucleolus, the essential center for ribosome production.

This discovery goes beyond basic biology. The Singh Lab analyzed patient data from two types of blood cancers: multiple myeloma and chronic lymphocytic leukemia. They found that patients with more severe forms of these cancers had higher levels of CUL1-IPA, regardless of how much of the traditional CUL1 RNA was present. Because cancer cells depend on robust ribosome production for rapid growth, regulatory RNAs that support nucleolar function may inadvertently aid tumor progression, making molecules like CUL1-IPA potential biomarkers or therapeutic targets.

The discovery of CUL1-IPA adds to a growing body of evidence that genes are more versatile than once believed. A single gene can produce multiple RNA molecules, each with its own distinct function, some of which may play major roles in health and disease. Molecules such as CUL1-IPA may ultimately be used as biomarkers to guide cancer treatment decisions, or even serve as targets for future therapies, opening the door to a whole new field of possible anti-cancer medications.