Scientists use microcellular drones to deliver lung cancer-killing drugs

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Characterization of purified RBCEVs and ASO-loaded RBCEVs. (a) Western blot analysis of ALIX, TSG101, ACTB, STOM, GPA, HBA, BAND3, CANX, and GAPDH protein expression in RBCs and RBCEVs. (b) Transmission electron microscopy (TEM) images of RBCEVs (EVs) and ASO-loaded RBCEVs (ASO-EVs) at 40× magnification. Scale bar: 200 nm. (c-d) Loading efficiency of negative control ASO (NC ASO) into RBCEVs (ASO-EVs) using REG-1, analyzed by agarose gel electrophoresis. (e) Nanoflow cytometric analysis of RBCEVs loaded with FAM-ASOs. (f) Size distribution of RBCEVs and ASO-loaded RBCEVs (ASO-EVs) determined by dynamic light scattering (DLS). (g) Mean size and polydispersity of EVs and ASO-EVs determined by DLS. (h) Zeta potential distribution of EVs and ASO-EVs determined by DLS method. Credit: eBioMedicine (2024). DOI: 10.1016/j.ebiom.2024.105356

In a study led by researchers at the NUS Yong Loo Lin School of Medicine, extracellular vesicles loaded with customizable anti-cancer antisense oligonucleotides suppressed cancer growth.

Lung cancer, specifically non-small cell lung cancer (NSCLC)—the most common subtype of cancer contracted by patients who do not smoke—is a leading cause of cancer mortality and the second most diagnosed cancer globally. The rapid and inevitable emergence of drug resistance mechanisms caused by mutations in cancer severely outpaces the development of small molecule drugs. This phenomenon adds urgency for a new, customizable, safe and effective anti-cancer therapeutic that can be designed, screened, and validated in a short amount of time.

A team of researchers, led by Assistant Professor Minh Le from the Institute for Digital Medicine (WisDM) and Department of Pharmacology at the Yong Loo Lin School of Medicine, National University of Singapore (NUS Medicine), has successfully demonstrated that nano-sized particles released by cells, such as red blood cells, could be repurposed to function as drug delivery platforms to carry antisense oligonucleotide (ASO) molecules targeting cancer cells in the lungs, thereby suppressing cancer progression.

This study was conducted in collaboration with the Cancer Science Institute of Singapore (CSI Singapore) at NUS, Agency for Science, Technology and Research (A*STAR), National Cancer Centre Singapore (NCCS), and Duke-NUS Medical School.

Asst Prof Minh Le said, "Mutant epidermal growth factor receptors (EGFRs) are the most common driver of lung cancer among the Asian population. Therefore, we focused on targeting lung cancer caused by the mutant EGFR. Currently, drugs known as tyrosine kinase inhibitors are the standard of treatment, and they work by inhibiting the mutant EGFR protein to stop cancer progression. As the cancer cells may further mutate and resist these drugs, we sought to find a more effective way to target the cancer."

In the study published in eBioMedicine, the authors looked toward ASOs to not only overcome the issue of drug resistance but also contribute to the development of precision medicine.

Precision medicine tailors the treatment to individual patients and their disease, as compared to a "one-size fits all" broad spectrum therapy. ASOs are molecules that can stick to a specific part of a ribonucleic acid (RNA) and inhibit irregular activity. ASOs are a flexible tool that can be easily redesigned to target and fix problems in different genes. This advantage is critical in the context of NSCLC, which is known to develop resistance against tyrosine kinase inhibitors.

Furthermore, the ASOs can be customized to target unique mutations based on the cancer profile of each individual patient. However, some disadvantages of ASOs are that they are easily degraded in the bloodstream, which results in diluted treatment at the tumor sites. This can be remedied with a method to hold the ASOs and deliver them directly to the tumor site.

To achieve that, the researchers utilized extracellular vesicles (EVs) derived from human red blood cells as a natural carrier to deliver the anti-cancer ASOs to the tumor site. To direct the ASO-loaded EV towards the tumor site, EGFR-targeting moieties were engineered onto the surface of the EVs. This primed the EV to home in on the cancerous cells.

Furthermore, the ASO-loaded EVs were shown to exhibit a potent anti-cancer effect in various models of lung cancer, including patient-derived cells. The specific design of the ASOs allows them to suppress mutant EGFR, while leaving the normal EGFR unaffected. They also demonstrated that the ASO-loaded RBCEVs possessed potent anti-cancer effects against TKI-resistant cancer cells.

Associate Professor Tam Wai Leong, Deputy Executive Director of A*STAR Genome Institute of Singapore (A*STAR GIS), and co-corresponding author of the study, said, "The innovative use of extracellular vesicles as a delivery vehicle for nucleic acid therapeutics added a potentially powerful treatment modality for treating malignancies. The ability to precisely eliminate mutant EGFR cancer cells while sparing normal tissues will enable customized treatment for individual patients. This is a significant step towards addressing cancer drug resistance and advancing the application of personalized cancer medicine."

Professor Goh Boon Cher, Deputy Director of CSI Singapore, Professor of Medicine at NUS Medicine and one of the authors of the study, added, "This work is instrumental in breaking new ground for precise delivery of therapeutic RNA to tumor cells to destroy them by targeting their vulnerabilities. It is a proof of concept that can be broadly applied in other areas of cancer treatment."

More information: Trinh T.T. Tran et al, Customised design of antisense oligonucleotides targeting EGFR driver mutants for personalised treatment of non-small cell lung cancer, eBioMedicine (2024). DOI: 10.1016/j.ebiom.2024.105356

Journal information: EBioMedicine

Provided by National University of Singapore