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Biophys J, February 2001, p. 894-900, Vol. 80, No. 2
Department of Biochemistry, Molecular Biology, and Biophysics, University of Minnesota, St. Paul, Minnesota 55108 USA
In this paper, we consider the implications of the
general theory developed in the accompanying paper, to interpret
experiments on DNA overstretching that involve variables such as
solution temperature, pH, and ionic strength. We find the DNA
helix-coil phase boundary in the force-temperature space. At
temperatures significantly below the regular (zero force) DNA melting
temperature, the overstretching force,
fov(T), is predicted to decrease
nearly linearly with temperature. We calculate the slope of this
dependence as a function of entropy and heat-capacity changes upon DNA
melting. Fitting of the experimental
fov(T) dependence allows
determination of both of these quantities in very good agreement with
their calorimetric values. At temperatures slightly above the regular DNA melting temperature, we predict stabilization of dsDNA by moderate
forces, and destabilization by higher forces. Thus the DNA stretching
curves, f(b), should exhibit two rather than one overstretching transitions: from single stranded (ss) to double stranded (ds) and then back at the higher force. We also predict that
any change in DNA solution conditions that affects its melting temperature should have a similar effect on DNA overstretching force.
This result is used to calculate the dependence of DNA overstretching
force on solution pH, fov(pH), from the known
dependence of DNA melting temperature on pH. The calculated
fov(pH) is in excellent agreement with its
experimental determination (M. C. Williams, J. R. Wenner, I. Rouzina, and V. A. Bloomfield, Biophys. J., accepted for publication). Finally, we
quantitatively explain the measured dependence of DNA overstretching
force on solution ionic strength for crosslinked and noncrosslinked
DNA. The much stronger salt dependence of fov in
noncrosslinked DNA results from its lower linear charge density in the
melted state, compared to crosslinked or double-stranded overstretched
S-DNA.
Biophys J, February 2001, p. 894-900, Vol. 80, No. 2
© 2001 by the Biophysical Society 0006-3495/01/02/894/07 $2.00
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