Researchers
from Delft University of Technology's Kavli Institute
of Nanoscience have discovered how to use the motors
of biological cells in extremely small channels
on a chip. Based on this, they built a transport
system that uses electrical charges to direct the
molecules individually. To demonstrate this, the
Delft researchers sorted the individual molecules
according to their color. Professor Hess of the
University of Florida has called the Delft discovery "the first
traffic control system in biomolecular motor nanotechnology". The research findings
will be published in Science on May 12.
The biological cell is a complex of many different
small protein factories. The necessary transportation
of materials within the cell occurs across a network
of microtubules: long, tubular-shaped proteins that
extend in a star-shaped formation from the nucleus
of the cell to the walls of the cell. Molecular bio-motors,
such as the enzyme kinesin, can walk in small steps
(of 8 nanometers) with a load of material along these
microtubule-networks and thus provide transport within
the cell.
Fascinated by these biological motors, the researchers
at Delft University of Technology's Kavli Institute
of Nanoscience are currently exploring the possibility
of inserting these kinesin-motors and microtubules
in an electrically directed transport system that
is made by the researchers using nano-fabrication
techniques.
The researchers turned the system around: the kinesin-motors
are fastened in large quantities on a surface with
their 'feet' up; the microtubules (measuring approximately
1 to 15 micrometers in length) were then transported
over the 'carpet' of motors. The microtubules are,
as it were, 'crowd surfing' over the sea of small
kinesin motors. A particular challenge of the research
was to ensure beforehand that the microtubule tubes
could be transported in a determined direction and
were not dislodged by collisions of the motor carpet.
PhD student Martin van den Heuvel, master student
Martijn de Graaff and groupleader Professor Cees
Dekker have for the first time achieved to control
and address individual microtubules. An important
step in this was to allow microtubule-transport to
occur in small closed liquid channels. This made
it possible to apply a strong electrical field locally
at the Y-junction in the channels. Because of this,
the electrical force could be exerted on the individual
microtubules. The researchers discovered that by
using this electrical force they could push the front
of the microtubule into the determined direction.
To demonstrate this, the researchers allowed a mixture
of green and red fluorescent microtubules to arrive
at a Y-junction. By changing the direction of the
electrical force, depending on the color of the microtubule,
the Delft researchers were able to collect the green
and red microtubules in different reservoirs.
With their approach to the nano-channels, the researchers
killed two birds with one stone. In addition to the
possibility of steering individual microtubules,
they were able to prevent the microtubules from derailing
from their tracks. Incidentally, the Delft researchers
discovered that their work contained a third interesting
aspect. The closed channels offered the possibility
to observe the electrical transport of freely suspended
microtubules, thus proving that the speed of the
microtubules under an external electrical field is
largely dependent on the orientation of the cylinder-shaped
molecules. This was the first time that this orientation-dependency
of the electrophoretic mobility was observed.
In an accompanying Perspective article in Science,
Professor Hess of the University of Florida wrote
that the Delft researchers had developed the first
traffic control system in biomolecular motor nanotechnology.
Contact: Frank Nuijens
f.w.nuijens@tudelft.nl
31-15-278-4259
Delft University of Technology
|
