Recent News \| Archives \| Tags \| About \| Newsletter \| Submit News \| Links \| Subscribe

More Articles

Fish can recognize a face based on UV pattern alone

Ancient DNA from rare fossil reveals that polar bears evolved recently and adapted quickly

'Anaconda' meets 'Jurassic Park': Study shows ancient snakes ate dinosaur babies

Scientists locate apparent hydrothermal vents off Antarctica

Mars Express heading for closest flyby of Phobos

Artificial bee silk a big step closer to reality

Predicting the fate of stem cells

Artificial foot recycles energy for easier walking

New fiber nanogenerators could lead to electric clothing

What drives our genes? Researchers map the first complete human epigenome

Juggling enhances connections in the brain

Tracking down the human 'odorprint'

Scientists discover quantum fingerprints of chaos

Researchers help identify cows that gain more while eating less

Engineers show how tiny cell proteins generate force to 'walk' (11/28/2008)

Tags:
cells, proteins

MIT researchers have shown how a cell motor protein exerts the force to move, enabling functions such as cell division.

Kinesin, a motor protein that also carries neurotransmitters, "walks" along cellular beams known as microtubules. For the first time, the MIT team has shown at a molecular level how kinesin generates the force needed to step along the microtubules.

The researchers, led by Matthew Lang, associate professor of biological and mechanical engineering, report their findings in the Nov. 24 online early issue of the Proceedings of the National Academy of Sciences.

Because kinesin is involved in organizing the machinery of cell division, understanding how it works could one day be useful in developing therapies for diseases involving out-of-control cell division, such as cancer.

The protein consists of two "heads," which walk along the microtubule, and a long "tail," which carries cargo. The heads take turns stepping along the microtubule, at a rate of up to 100 steps (800 nanometers) per second.

In the PNAS paper, Lang and his colleagues offer experimental evidence for a model they reported in January in the journal Structure. Their model suggests - and the new experiments confirm - that a small region of the protein, part of which joins the head and tail is responsible for generating the force needed to make kinesin walk. Two protein subunits, known as the N-terminal cover strand and neck linker, line up next to each other to form a sheet, forming the cover-neck bundle that drives the kinesin head forward.

"This is the kinesin power stroke," said Lang.

Next, Lang's team plans to investigate how the two kinesin heads communicate with each other to coordinate their steps.

Note: This story has been adapted from a news release issued by the Massachusetts Institute of Technology