Traveling protein waves reveal how dividing cells set chromosome-splitting spindle size
When a human cell prepares to split into two daughter cells, it must first construct a tiny internal machine called the mitotic spindle—a structure of protein fibers that physically pulls chromosomes apart and deposits one set into each new cell. Get the spindle the right size and the chromosomes segregate cleanly. Getting it wrong could result in the chromosomal errors that fuel cancer.
Bigger cells need bigger spindles, and the two are known to scale together. While we have understood what the spindle does, the question has remained of how the spindle "knows" how big to be. New research from the Yale School of Medicine (YSM) published in Science Advances offers an answer: The cell uses traveling waves.
Waves of protein activity
Cells are filled with structures that must coordinate their behavior across distances far larger than individual molecules can sense directly. During cell division, for example, the mitotic spindle must scale to the size of the entire cell.
"But no single molecule can see the cell as a whole," says Suet Yin Sarah Fung, Ph.D., associate research scientist of cell biology at YSM and lead author on the paper. "The challenge is how information about global cell size is communicated across these vast molecular distances."
In mast cells—cells that serve as a first line of defense in the immune system—Fung and colleagues discovered that before the mitotic spindle begins to form in dividing cells, rhythmic waves of protein activity travel across the cell's surface like ripples spreading across a pond. These waves don't pulse at the same rate in every cell. Bigger cells have slower waves; smaller cells have faster ones.
The team found that the timing of these waves is directly linked to the eventual size of the spindle. "It appears that the information about cell dimensions is encoded in wave dynamics and translated into the geometry of mitotic spindles," Fung says.
The waves are driven by a carefully orchestrated cycle of lipid chemistry on the cell's outer membrane, Fung and her colleagues found. These lipids pulse sequentially. A molecule called phosphatidylinositol 3,4-bisphosphate (or PI(3,4)P2) accumulates in rhythmic pulses, and an enzyme called INPP4B acts as a reset button, breaking it down so the next wave cycle can begin. When the researchers genetically deleted INPP4B, the waves slowed and spindles grew significantly longer.
Furthermore, the waves can retune themselves far faster than any genetic mechanism could explain. "In a single cell, they can actually tune their frequency within seconds," says Min Wu, Ph.D., associate professor of cell biology at YSM and senior author of the study. "That was the most surprising part."
For decades, biologists have largely viewed cellular information as being encoded through genes and the global abundances of molecules. Such rapid adjustments suggest that the cell is not governed by genetic programs. They would be far too slow. Instead, a more dynamic mechanism has to be operating inside the cell.
"The cell behaves like a jazz musician, constantly modulating tempo, rhythm and phrasing while responding to the surrounding ensemble," says Wu.
Golgi apparatus as an orchestrator
The key to understanding why bigger cells have slower waves came unexpectedly from the Golgi apparatus, an organelle typically known for packaging and shipping proteins around the cell.
When a cell enters division, the Golgi breaks apart into small fragments. Fung's team found that these fragments act like a molecular sponge, absorbing INPP4B away from the cell's surface. With less enzyme available, PI(3,4)P2 breaks down more slowly and the waves stretch out. In larger cells, which have proportionally larger Golgi, more enzyme gets absorbed, the waves slow further and the spindle ends up correspondingly longer.
The cell is, in effect, using the disassembly of one of its own organelles to redistribute its contents.
A common principle of cell division
The study took roughly six years to complete—a journey Fung describes as "a good six years of U-turns and reverse parking."
The findings point toward a new perspective in cell biology—one that treats the cell not as a collection of isolated parts, but as an integrated system.
"It makes sense to zoom in on individual subcellular processes to understand them in as much detail as possible," Wu says. "But it is equally important to recognize that none of these processes operate in isolation. Inside the cell, they are constantly interacting and coordinating with one another."
Its implications may extend well beyond mast cells. Similar waves have been observed across a remarkable range of living systems—from slime molds and plants to bacteria and the brain—suggesting that wave-based information encoding may be a fundamental principle of cellular life.
"It feels like there is a common principle underneath all of this that is really coming together," Wu says.
Publication details
Suet Yin Sarah Fung et al, Mitotic Cdc42 waves encode PI(3,4)P 2 signaling and Golgi morphological state to control spindle scaling, Science Advances (2026). DOI: 10.1126/sciadv.aec7705
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Citation: Traveling protein waves reveal how dividing cells set chromosome-splitting spindle size (2026, July 8) retrieved 13 July 2026 from https://phys.org/news/2026-07-protein-reveal-cells-chromosome-spindle.html
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