posted on 2012-05-03, 00:00authored bySandipan Chakraborty, Takashi Uematsu, Christer Svanberg, Per Jacobsson, Jan Swenson, Michael Zäch, Rajendar Trehan, George Armstrong, Bidisha Sengupta
Intrinsic dynamics of DNA plays a crucial role in DNA–protein
interactions and has been emphasized as a possible key component for
in vivo chromatin organization. We have prepared an entangled DNA
microtube above the overlap concentration by exploiting the complementary
cohesive ends of λ-phage DNA, which is confirmed by atomic force
microscopy and agarose gel electrophoresis. Photon correlation spectroscopy
further confirmed that the entangled solutions are found to exhibit
the classical hydrodynamics of a single chain segment on length scales
smaller than the hydrodynamic length scale of single λ-phage
DNA molecule. We also observed that in 41.6% (gm water/gm DNA) hydrated
state, λ-phage DNA exhibits a dynamic transition temperature
(Tdt) at 187 K and a crossover temperature
(Tc) at 246 K. Computational insight reveals
that the observed structure and dynamics of entangled λ-phage
DNA are distinctively different from the behavior of the corresponding
unentangled DNA with open cohesive ends, which is reminiscent with
our experimental observation.