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Article Released Fri-2nd-February-2018 01:43 GMT
Contact: Naoko Odajima Institution: Tohoku University
 Multiple ant-like transport of neuronal cargo by motor proteins

Microtubules (roads made of proteins) extend throughout a cell for motor proteins (carriers) to deliver neuronal cargo packed with many kinds of materials required for life activity.

Multiple ant-like transport of neuronal cargo by motor proteins
Cargo transport by many motors makes neuronal activity fine.
Copyright : Kumiko Hayashi
Microtubules (roads made of proteins) extend throughout a cell for motor proteins (carriers) to deliver neuronal cargo packed with many kinds of materials required for life activity. The delivery is active along neuronal axons, which function like highways in human societies. Deficits in the cargo delivery cause neuronal diseases, such as Alzheimer’s, Parkinson’s or Huntington’s disease.

Dr. Kumiko Hayashi and Dr. Shinsuke Niwa, assistant professors of Tohoku University, have successfully estimated the force exerted by motor proteins acting on neuronal cargo in living worms using a newly developed non-invasive force measurement method (Ref. 1). The force values indicate that a number of carriers are involved in neuronal cargo delivery.

The research shows that cargo packed with synapses was carried cooperatively by multiple motor proteins, much like a group of ants working together, to carry an item too large for any individual motor protein to carry alone. The number of carriers was found to decrease in mutant worms as indicated by the force measurement. The decrease weakened the cargo transport and caused the mis-location of synapses reported recently (Ref. 2). The material delivery by lots of carriers in highway-like axons ensures healthy neuronal activity and is a significant finding in the field.

Despite the need of physical measurements for neuronal cargo transport, it has been difficult to measure force in vivo, until now. The non-invasive force measurement method based on the fluctuation theorem (Ref. 3) enabled measurement by analyzing the fluctuating behavior of cargo vesicles in the cytosol subject to thermal noise and so on. Such movement can easily be observed using fluorescence microscopy. Hayashi and Niwa expect the non-invasive force measurement method to be a strong, new tool in understanding the physical mechanism of neuronal diseases caused by deficits in axonal transport.

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Keywords associated to this article: Motor proteins, Force measurement, Cargo transport, Neuron
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