Molecular motor

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Molecular motors are biological molecular machines that are the essential agents of movement in living organisms. Generally speaking, a motor may be defined as a device that consumes energy in one form and converts it into motion or mechanical work; for example, many protein-based molecular motors harness the chemical free energy released by the hydrolysis of ATP in order to perform mechanical work [1]. In terms of energetic efficiency, these types of motors can be superior to currently available man-made motors. One important difference between molecular motors and macroscopic motors is that molecular motors operate in the thermal bath, an environment where the fluctuations due to thermal noise are significant.

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[edit] Examples

Some examples of biologically important molecular motors:

  • Motor proteins
  • Polymerases
  • Actin polymerization generates forces and can be used for propulsion
  • FoF1 ATP synthase generates ATP using the transmembrane electrochemical proton gradient inside mitochondria[4]
  • Topoisomerases reduce supercoiling of DNA in the cell
  • The bacterial flagellum responsible for the swimming and tumbling of E. coli and other bacteria acts as a rigid propeller that is powered by a rotary motor. This motor is driven by the flow of ions across a membrane, possibly using a similar mechanism to that found in the Fo motor in ATP synthase.
  • Viral DNA packaging motors inject viral genomic DNA into capsids as part of their replication cycle, packing it very tightly. [5]
  • Synthetic molecular motors have been created by chemists that yield rotation, possibly generating torque

[edit] Theoretical Considerations

Because the motor events are stochastic, molecular motors are often modeled with the Fokker-Planck equation or with Monte Carlo methods. These theoretical models are especially useful when treating the molecular motor as a Brownian motor.

[edit] Experimental Observation

In experimental biophysics, the activity of molecular motors is observed with many different experimental approaches, among them:

  • Fluorescent methods: fluorescence resonance energy transfer (FRET), fluorescence correlation spectroscopy (FCS)
  • Single-molecule electrophysiology can be used to measure the dynamics of individual ion channels
  • Optical tweezers are well-suited for studying molecular motors because of their low spring constants
  • Magnetic tweezers can also be useful for analysis of motors that operate on long pieces of DNA

Many more techniques are also used. As new technologies and methods are developed, it is expected that knowledge of naturally occurring molecular motors will be helpful in constructing synthetic nanoscale motors.

[edit] Non-biological molecular motors

Recently, chemists and those involved in nanotechnology have begun to explore the possibility of creating molecular motors de novo. These synthetic molecular motors currently suffer many limitations that confine their use to the research laboratory. However, many of these limitations may be overcome as our understanding of chemistry and physics at the nanoscale increases. Systems like the nanocars, while not technically motors, are illustrative of recent efforts towards synthetic nanoscale motors.

[edit] References

  1. ^  C. Bustamante, Y. R. Chemla, N. R. Forde, D. Izhaky (2004). "Mechanical processes in biology," Annual Review of Biochemistry, 73: 705-748. PMID 15189157
  2. ^  "Rotation of the c subunit oligomer in fully functional F1Fo ATP synthase" by Satoshi P. Tsunoda, Robert Aggeler, Masasuke Yoshida, and Roderick A. Capaldi in Proc Natl Acad Sci U S A (2001) volume 98 pages 898–902. Full text at PMC: 14681
  3. ^  "Does RNA polymerase help drive chromosome segregation in bacteria?" by Jonathan Dworkin and Richard Losick in Proc Natl Acad Sci U S A (2002) volume 99 pages 14089–14094. Full text at PMC: 137841
  4. ^  Robert Sanders, Molecular motor powerful enough to pack DNA into viruses at greater than champagne pressures, researchers report, Press release, University of California

[edit] See also