A groundbreaking study has unearthed a hidden world of intracellular “winds” that could provide significant insight into cancer metastasis, potentially transforming our understanding of this deadly disease progression.
Researchers from the National Institutes of Health (NIH) and the University of California, San Diego (UCSD), recently published their compelling findings in the prestigious journal, Nature Cell Biology. The study highlights previously undiscovered internal cellular movements or “winds”, which might explain how cancer cells break away from a primary tumor and spread, a process known as metastasis.
The scientific process of metastasis has long been a perplexing phenomenon for researchers. The rapid spread of cancer cells from an origin site to other parts of the body increases the complexity and severity of the disease. Around 90% of cancer deaths occur due to metastasis, according to the National Cancer Institute.
“We have discovered fundamentally new structures around the cell nucleus — surprisingly complex, windy passageways in which particles mix within seconds when a cell begins to spread,” said co-senior author Dr. Gaudenz Danuser, from UCSD’s Department of Cell and Molecular Medicine.
The team utilized a revolutionary imaging technique named grid-tagged organelles for nanoscale dissection (GOLD), which helped them to visually dissect the complex network of these windy passageways localized around the cell nucleus.
These winds are not random; instead, they follow intricate patterns formed by microtubules — small hollow structures that form the cell’s cytoskeleton. The “winds” appear to be directed by the interplay between these microtubules and the cell’s nuclear envelope. Importantly, the scientists noticed that this motion escalates when a cell receives signals to move — the same signals a cancer cell might receive in the process of metastasis.
If these winds facilitate cancer’s ominous spread, they could be the key to halting this process at an early stage, a prospect the researchers find exciting.
Dr. Clare Waterman from the NIH, another co-senior author, expressed optimism about the implications of these revelations. “If we can figure out how to manipulate and use these winds, we might be able to guide cells away from cancer and toward regenerative outcomes that can improve people’s lives drastically,” she explained.
The new focus on cellular winds comes after earlier research primarily studied external elements such as the extracellular matrix — a complex network of proteins and carbohydrates where cancer cells can settle during metastasis. The discovery of intracellular movements changes the landscape of how we perceive cell behavior.
The revelation of these interior cell winds has stirred vigorous online discussion in the scientific community. According to a Twitter thread by @DrKatHolt, an associate professor in microbial genomics, the research “has the potential to be a significant step toward controlling and preventing metastasis.”
In contrast, an article in the online science magazine Gizmodo emphasized the preliminary nature of the discovery. The publication underlined that much more research is still needed to fully understand the function of these winds and their connection to metastasis.
While the journey to harness these cellular winds for therapeutic means is undoubtedly a long and uncertain one, the sheer potential of this finding offers renewed optimism for clinicians, patients, and their families. Advancements in understanding the microscopic world of cells continue to open up new avenues for controlling and combating cancer, showing us that life-saving answers can often be found in the tiniest of places.
Original Source: https://www.sciencedaily.com/releases/2026/03/260331001102.htm







