639 research outputs found
Decoupling phenomena in supercooled liquids: Signatures in the energy landscape
A significant deviation from the Debye model of rotational diffusion in the
dynamics of orientational degrees of freedom in an equimolar mixture of
ellipsoids of revolution and spheres is found to begin precisely at a
temperature at which the average inherent structure energy of the system starts
falling with drop in temperature. We argue that this onset temperature
corresponds to the emergence of the alpha-process as a distinct mode of
orientational relaxation. Equally important, we find that the coupling between
the rotational and translational diffusion breaks down at a still lower
temperature where a sharp change occurs in the temperature dependence of the
average inherent structure energy.Comment: Submitted for publicatio
Kinetic proofreading at single molecular level: Aminoacylation of tRNA^{Ile} and the role of water as an editor
Proofreading/editing in protein synthesis is essential for accurate
translation of information from the genetic code. In this article we present a
theoretical investigation of efficiency of a kinetic proofreading mechanism
that employs hydrolysis of the wrong substrate as the discriminatory step in
enzyme catalytic reactions. We consider aminoacylation of tRNA^{Ile} which is a
crucial step in protein synthesis and for which experimental results are now
available. We present an augmented kinetic scheme and then employ methods of
stochastic simulation algorithm to obtain time dependent concentrations of
different substances involved in the reaction and their rates of formation. We
obtain the rates of product formation and ATP hydrolysis for both correct and
wrong substrates (isoleucine and valine in our case), in single molecular
enzyme as well as ensemble enzyme kinetics. The present theoretical scheme
correctly reproduces (i) the amplitude of the discrimination factor in the
overall rates between isoleucine and valine which is obtained as (1.8 \times
10^2).(4.33 \times 10^2) = 7.8 \times 10^4, (ii) the rates of ATP hydrolysis
for both Ile and Val at different substrate concentrations in the
aminoacylation of tRNA^{Ile}. The present study shows a non-michaelis type
dependence of rate of reaction on tRNA^{Ile} concentration in case of valine.
The editing in steady state is found to be independent of amino acid
concentration. Interestingly, the computed ATP hydrolysis rate for valine at
high substrate concentration is same as the rate of formation of Ile-tRNA^{Ile}
whereas at intermediate substrate concentration the ATP hydrolysis rate is
relatively low
Anisotropic translational diffusion in the nematic phase: Dynamical signature of the coupling between orientational and translational order in the energy landscape
We find in a model system of thermotropic liquid crystals that the
translational diffusion coefficient parallel to the director
first increases and then decreases as temperature drops through the nematic
phase, and this reversal occurs where the smectic order parameter of the
underlying inherent structures becomes significant for the first time. We
argue, based on an energy landscape analysis, that the coupling between
orientational and translational order can play a role in inducing the
non-monotonic temperature behavior of . Such a view is likely to
form the foundation of a theoretical framework to explain the anisotropic
translation diffusion.Comment: 10 pages, 4 figure
A mode-coupling theory analysis of the rotation driven translational motion of aqueous polyatomic ions
In contrast to simple monatomic alkali and halide ions, complex polyatomic
ions like nitrate, acetate, nitrite, chlorate etc. have not been studied in any
great detail. Experiments have shown that diffusion of polyatomic ions exhibits
many remarkable anomalies, notable among them is the fact that polyatomic ions
with similar size show large difference in their diffusivity values. This fact
has drawn relatively little interest in scientific discussions. We show here
that a mode-coupling theory (MCT) can provide a physically meaningful
interpretation of the anomalous diffusivity of polyatomic ions in water, by
including the contribution of rotational jumps on translational friction. The
two systems discussed here, namely aqueous nitrate ion and aqueous acetate ion,
although have similar ionic radii exhibit largely different diffusivity values
due to the differences in the rate of their rotational jump motions. We have
further verified the mode-coupling theory formalism by comparing it with
experimental and simulation results that agrees well with the theoretical
prediction
Collective excitations in liquid DMSO : FIR spectrum, Low frequency vibrational density of states and ultrafast dipolar solvation dynamics
Valuable dynamical and structural information about neat liquid DMSO at
ambient conditions can be obtained through study of low frequency vibrations in
the far infrared (FIR), that is, terahertz regime. For DMSO, collective
excitations as well as single molecule stretches and bends have been measured
by different kinds of experiments such as OHD-RIKES and terahertz spectroscopy.
In the present work we investigate the intermolecular vibrational spectrum of
DMSO through three different computational techniques namely (i) the far-infra
red spectrum obtained through Fourier transform of total dipole moment auto
time correlation function, (ii) from Fourier transform of the translational and
angular velocity time autocorrelation functions and a (iii) quenched normal
mode analysis of the parent liquid at 300K. The three spectrum, although
exhibit differences among each other, reveal similar features which are in
good, semi-quantitative, agreement with experimental results. Study of
participation ratio of the density of states obtained from normal mode analysis
shows that the broad spectrum around 100 cm-1 involves collective oscillations
of 300-400 molecules. Dipolar solvation dynamics exhibit ultrafast energy
relaxation (dipolar solvation dynamics) with initial time correlation function
around 140 fs which can be attributed to the coupling to the collective
excitations. We compare properties of DMSO with those of water vis-a-vis the
existence of the low frequency collective modes. Lastly, we find that the
collective excitation spectrum exhibits strong temperature dependence.Comment: 24 pages,8 figure
Origin of the Sub-diffusive Behavior and Crossover From a Sub-diffusive to a Super-diffusive Dynamics Near a Biological Surface
Diffusion of a tagged particle near a constraining biological surface is
examined numerically by modeling the surface-water interaction by an effective
potential. The effective potential is assumed to be given by an asymmetric
double well constrained by a repulsive surface towards and unbound at
large distances. The time and space dependent probability distribution
of the underlying Smoluchowski equation is solved by using Crank-Nicholson
method. The mean square displacement shows a transition from sub-diffusive
(exponent 0.43) to a super-diffusive (exponent
1.75) behavior with time and ultimately to a diffusive dynamics. The decay of
self intermediate scattering function () is non-exponential in
general and shows a power law behavior at the intermediate time. Such features
have been observed in several recent computer simulation studies on dynamics of
water in protein and micellar hydration shell. The present analysis provides a
simple microscopic explanation for the transition from the sub-diffusivity and
super-diffusivity. {\em The super-diffusive behavior is due to escape from the
well near the surface and the sub-diffusive behavior is due to return of
quasi-free molecules to form the bound state again, after the initial escape}Comment: 5 pages including 5 figures and 1 table. Submitted to PhysChemCom
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