Tuesday, November 25, 2008

Cell movement

Cells Coordinate Gene Activity With FM Bursts, Scientists Find
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Proteins Have Controlled Motions, Researcher Shows[/url][/b]
ScienceDaily (Oct. 2, 2008) — How a cell achieves the coordinated control of a number of genes at the same time, a process that's necessary for it to regulate its own behavior and development, has long puzzled scientists.
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Michael Elowitz, an assistant professor of biology and applied physics at the California Institute of Technology (Caltech), along with Long Cai, a postdoctoral research scholar at Caltech, and graduate student Chiraj Dalal, have discovered a surprising answer. Just as human engineers control devices ranging from dimmer switches to retrorockets using pulsed -- or frequency modulated (FM) -- signals, cells tune the expression of groups of genes using discrete bursts of activation.

Elowitz, who is also a Bren Scholar and an investigator with the Howard Hughes Medical Institute, and his colleagues discovered this process by combining mathematical and computational modeling with experiments on individual living cells. The scientists looked specifically at the molecular changes within simple baker's yeast (Saccharomyces cerevisiae) cells after exposure to excess calcium, which increases in concentration in cells in response to stressful conditions such as high salt levels, alkaline pH, and cell wall damage.

The scientists tracked that response using a protein called Crz1 labeled with a green fluorescent tag. Crz1 is stimulated in response to high calcium levels and activates genes that help protect the cell. The glowing of the fluorescent marker allowed Elowitz and colleagues to visualize the movement of Crz1 as it travelled within the cell from the cytoplasm into the cell nucleus and out again into the cytoplasm. Using time-lapse microscopy, they created "movies" of that movement.



Landmark Discovery Of 'Engine' That Drives Cell Movement
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ScienceDaily (Oct. 7, 2008) — How a cell assembles its internal machinery required for cell movement has been revealed for the first time.
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The researchers discovered a complex of three proteins that directly regulates the myosin network within a cell, thus generating traction force to propel the cell forward. (Myosin is the most common protein found in muscle cells, and is responsible for the elastic and contractile properties of muscle. A different form of myosin is involved in cell movement.)

This action of the tripartite protein complex may be likened to a spring in a toy motorcar – when the protein complex assembles and moves backwards within the cell, it resembles the wound up "engine" of the toy car that has been pulled backwards.


Subsequent disassembling of the protein complex and the resultant forward movement of the cell can be likened to the released spring which unleashes the earlier stored potential energy to propel the car forward.

Michael Sheetz, Ph.D., who is William R Kenan Jr Professor of Cell Biology at the Department of Biological Sciences, Columbia University, and also Distinguished Visiting Professor at the National University of Singapore, said, "This is an exciting paper because Leung's group has discovered an unexpected step in cell migration and contractility — a complex of three proteins including a form of myosin, that is responsible for assembling most of the other myosin components involved in motile processes. The assembly mechanism has been a major mystery and is critical in a variety of diseases from cardiovascular to aging. Now we have a new tool to understand the bases of these critical processes."

Of the three proteins MRCK, LRAP35a and MYO18A, MRCK was discovered by the GSK-IMCB group 10 years ago, while the other two had hitherto unknown functions. Dr. Leung of IMCB said, "The success of the work relies on the commitment and perseverance of the team. A major contributor, Dr. Ivan Tan, is a home-grown scientist who has been working on this project for many years and he has had several clues as to how the system functions for some time, but it was only recently that the jigsaw puzzle was put together. The system has the potential to unravel other as yet undiscovered mechanisms that coordinate the different 'engines' for proper cell migration."

Emphasis mine.
Hard work with spectacular results

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