Researchers in Singapore unveil a breakthrough RNA strategy that simultaneously silences KRAS mutations and activates immune defenses in hard-to-treat tumors.
As precision oncology moves deeper into RNA-based and immune-modulating therapies, clinical laboratories are finding themselves at the center of a rapidly evolving frontier. New research from Singapore signals just how quickly that future is arriving. In two complementary studies, scientists at the Yong Loo Lin School of Medicine, National University of Singapore (NUS Medicine), unveiled a dual-action RNA strategy that targets KRAS—one of cancer’s most stubborn and historically “undruggable” genes—while simultaneously jump-starting the immune system to recognize and attack tumors.
For lab leaders, the findings hint at a coming era in which molecular diagnostics, immune-response markers, and vesicle-based delivery technologies converge in routine care.
Researchers from NUS Medicine, together with collaborators from Nanyang Technological University (NTU), A*STAR, and international partners, focused on KRAS because of its prevalence and difficulty to treat. KRAS mutations lock the gene’s molecular switch in a permanent “on” state, driving constant cell growth and helping tumors hide from immune detection. These mutations appear in more than 90% of pancreatic cancers and are also common in lung and colorectal malignancies. Traditional drug approaches have faltered because the KRAS protein binds its signaling molecules too tightly and lacks accessible pockets for small-molecule inhibitors.
A Dual RNA Strategy to Break KRAS Resistance
To get around these challenges, the team paired two RNA tools: antisense oligonucleotides (ASOs) to silence mutant KRAS and an immunomodulatory RNA (immRNA) to activate RIG-I, an innate immune pathway usually triggered by viral infections. Turning on RIG-I sends an antiviral-like alarm through the cell, prompting immune activation that can help unmask tumor cells. Both RNA agents were delivered using red blood cell–derived extracellular vesicles (RBCEVs), natural carriers that can transport nucleic acid drugs safely and efficiently into tumor tissue.
The first study, published in Theranostics, demonstrated that this ASO–immRNA combination effectively killed KRAS-driven cancer cells in lung, colorectal, and pancreatic models. The therapy blocked oncogenic KRAS activity while converting “cold” tumors—those typically invisible to immune attack—into “hot” tumors that attract immune cells. In laboratory models, the approach reduced tumor burden, improved survival, and spared healthy cells.
Preclinical Progress in Pancreatic Cancer
The second study, appearing in the Journal of Controlled Release, advanced the platform for pancreatic ductal adenocarcinoma (PDAC). PDAC is one of the deadliest human cancers, with a five-year survival rate around 10%. It often spreads throughout the peritoneal cavity, leaving patients with few effective treatment options.
In preclinical models of PDAC with peritoneal metastasis, the dual-RNA therapy markedly suppressed tumor growth, restricted abdominal spread, and extended survival. Importantly, safety testing showed no observable toxicity. Investigators say this strengthens the case for eventual clinical trials and highlights the broader versatility of extracellular vesicles as delivery vehicles across multiple RNA-based modalities.
The team emphasized that the therapy’s strength lies in its synergy. Associate professor Minh Le, Department of Pharmacology, and Institute for Digital Medicine (WisDM), NUS Medicine described the platform as one that “precisely targets mutants, unleashes interferons, drives immunogenic cell death, and builds T-cell memory,” all while preserving healthy tissue.
Associate professor Minh Le, Department of Pharmacology, and Institute for Digital Medicine (WisDM), NUS Medicine noted, “Our EV platform precisely targets mutants, sparing healthy tissue, and synergizes KRAS knockdown with RIG-I activation to unleash interferons, immunogenic cell death, and T-cell memory—halting tumor growth and extending survival without toxicity.” (Photo credit: NUS)
For clinical laboratories, these advances signal more than a scientific milestone—they point to a near future in which labs may need to measure KRAS knockdown, track immune-activation signatures, quantify extracellular vesicle uptake, and support increasingly complex molecular workflows. While the therapy remains in the preclinical phase, the implications are clear: RNA-based therapeutics and EV-mediated delivery are moving quickly toward clinical reality, and laboratories will play a central role in bringing those innovations to patients.
This article was created with the assistance of Generative AI and has undergone editorial review before publishing.
—Janette Wider
