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Biophys J, September 1998, p. 1197-1210, Vol. 75, No. 3
*Institute of Molecular Biology and #Howard Hughes Medical Institute, Institute of Molecular Biology and Department of Chemistry, University of Oregon, Eugene, Oregon 97403 USA
We have developed a theory for the extension and force of
B-DNA tethered at a fixed point in a uniform hydrodynamic flow or in a
uniform applied electric field. The chain tethered in an electric field
is considered to be subject to free electrophoresis compensated by free
sedimentation in the opposite direction. This allows the use of results
of free electrophoresis for including the effects of small ions. The
force on the chain is derived for a sequence of ellipsoidal segments,
each twice the persistence length of the wormlike chain. Hydrodynamic
interaction between these segments is based on the long-range limit of
flow around the prolate ellipsoids, as derived from equivalent Stokes
spheres. The chain extension is derived by applying the entropic
elasticity relation of Marko and Siggia (1995 Macromolecules. 28:8759-8770) to each segment for polymer
chains under constant tension. We justify this procedure by comparing
with extension results based on the Boltzmann averaged orientation of
straight, freely jointed segments. Predicted results agree well with
recent extension-flow experiments by Perkins et al., 1995. Science. 258:83-87, and with electrophoretic stretch
experiments by Smith and Bendich (1990 Biopolymers.
29:1167-1173) on fluorescently stained B-DNA. We find that the
equivalence of hydrodynamic and electrophoretic stretch, proposed by
Long et al. (1996 Phys. Rev. Lett. 76:3858-3861; 1996 Biopolymers
39:755-759), is valid only for very small chain deformations, but not
in general.
Biophys J, September 1998, p. 1197-1210, Vol. 75, No. 3
© 1998 by the Biophysical Society 0006-3495/98/09/1197/14 $2.00
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