BERKELEY, Calif., Dec. 28 -- Researchers from the University of California at Berkeley using a customized atomic force microscope (AFM) have discovered new evidence for how the fibrous scaffolding within human cells responds to obstacles in its environment, a technique for tracking a cell's growth history which may one day allow scientists to track the pathways of spreading cancers, immune cells and other cells that move freely through the body. Researchers used an atomic force microscope to open a window into a cell to reveal the actin network and organelles inside a macrophage as it pursues bacterial invaders. Actin forms long filaments that lie just beneath the surface of the cell, giving it structure and stability. As the immune cell crawls and looks for invaders, such as the bacterium E. coli, new actin growth helps to push the cell forward. (Image: Nicolle Rager Fuller, National Science Foundation)Assistant professor Daniel Fletcher of the University of California at Berkeley department of bioengineering, lead authors Sapun Parekh and Ovijit Chaudhuri, also of Berkeley, and Julie Theriot of Stanford University published their findings in the December 2005 issue of Nature Cell Biology."How do cells push in a particular direction when they confront a barrier? That was the initial question in this research," said Fletcher. Among other responsibilities, the protein actin provides the structural support for cells and the growth force necessary for certain cellular activities. "The front of a cell extends forward during crawling, and actin and its associated proteins are necessary for powering that forward motion," says Fletcher. "Other mechanical processes in cells, such as the 'Pac-Man'-like action of an immune cell eating a bacterium, also involve forces generated by growth of actin networks." The networks are collections of proteins, so they are more complicated and more difficult to study than many other cellular components involved with cell motion and force, the researchers said. To track the growth rate and force generated by actin, the bioengineers modified an AFM. In most research, the business end of an AFM is a miniscule, extremely sharp tip that is attached to a thin silicon-nitride cantilever. Because the tip is so slight, even features as tiny as individual atoms can cause the cantilever to deflect as it passes along, or slightly above, a surface. A laser bounces off the cantilever and into a detector, registering the tiny deflections and providing signals a computer translates into an image. For this study, the researchers created a specialized AFM that uses two cantilevers and two lasers. Instead of scanning a surface, the cantilevers served as tiny springboards, one to bend as actin grew beneath it and the other to stay as a reference point close to the floor of the sample chamber. Using the two-cantilever system, the researchers pushed longer on the filaments than in any earlier study, and with more force -- in some cases to the point where the filaments stalled and could grow no further. In multiple experiments, the cantilevers applied an initial force to a slurry of growing actin filaments, then applied a larger force for as long as 30 minutes. They then returned to the original load, at every stage tracking how fast the network grew. Each time, when the cantilever returned to its original load, the growth velocity of the actin was faster. When the fibers endured multiple load cycles, they grew at a rate that was dependent upon all of the cycles. "We've found that the growth of actin is dependent on its loading history -- not just on the load it feels at one moment, as we previously thought," says Fletcher. "This means the structure of a cell has some 'memory' of its physical interactions." The researchers suspect the effect may relate to filament density, and the growth rate may be a function of the network architecture, itself dependent upon the entire load history. "For a given load, proteins assume a certain network architecture," says Fletcher. "This architecture then remodels under a new load. So, if you go back to the original load, the architecture is still tuned for a higher load, resulting in explosive growth." These are fundamental research findings, adds Fletcher, but in the long term they may help scientists and engineers understand cell crawling, potentially aiding future treatments that help white blood cells work better or stop tumor cells from moving to other parts of the body. The research was funded in part by a grant from the National Science Foundation. For more information, visit: www.nsf.gov