Background: Electronic clocks exhibit undesirable jitter or time variations in periodic signals. The circadian clocks of humans, some animals, and plants consist of oscillating molecular networks with peak-to-peak time of approximately 24 hours. Clockwork orange (CWO) is a transcriptional repressor of Drosophila direct target genes. Methodology/Principal Findings: Theory and data from a model of the Drosophila circadian clock support the idea that CWO controls anti-jitter negative circuits that stabilize peak-to-peak time in light-dark cycles (LD). The orbit is confined to chaotic attractors in both LD and dark cycles and is almost periodic in LD; furthermore, CWO diminishes the Euclidean dimension of the chaotic attractor in LD. Light resets the clock each day by restricting each molecular peak to the proximity of a prescribed time. Conclusions/Significance: The theoretical results suggest that chaos plays a central role in the dynamics of the Drosophila circadian clock and that a single molecule, CWO, may sense jitter and repress it by its negative loops

A Goldbeter

AL Goldberger

Eshel Ben-Jacob

H Hao

Hassan M. Fathallah-Shaykh

HM Fathallah-Shaykh

JC Leloup

JE Rutila

K Bae

K Geist

K Tsumoto

L Dicci

L Dieci

MJ McDonald

R Allada

S Honma

S Kadener

TK Darlington

Y He

PLoS ONE

English

PubMed

BACKGROUND: Electronic clocks exhibit undesirable jitter or time variations in periodic signals. The circadian clocks of humans, some animals, and plants consist of oscillating molecular networks with peak-to-peak time of approximately 24 hours. Clockwork orange (CWO) is a transcriptional repressor of Drosophila direct target genes. METHODOLOGY/PRINCIPAL FINDINGS: Theory and data from a model of the Drosophila circadian clock support the idea that CWO controls anti-jitter negative circuits that stabilize peak-to-peak time in light-dark cycles (LD). The orbit is confined to chaotic attractors in both LD and dark cycles and is almost periodic in LD; furthermore, CWO diminishes the Euclidean dimension of the chaotic attractor in LD. Light resets the clock each day by restricting each molecular peak to the proximity of a prescribed time. CONCLUSIONS/SIGNIFICANCE: The theoretical results suggest that chaos plays a central role in the dynamics of the Drosophila circadian clock and that a single molecule, CWO, may sense jitter and repress it by its negative loops

Hassan M Fathallah-Shaykh

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Dynamics of the Drosophila circadian clock: theoretical anti-jitter network and controlled chaos.

Fathallah-Shaykh, Hassan M.

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Dynamics of the Drosophila Circadian Clock: Theoretical Anti-Jitter Network and Controlled Chaos 

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Dynamics of the Drosophila Circadian Clock: Theoretical Anti-Jitter Network and Controlled Chaos

Electronic clocks exhibit undesirable jitter or time variations in periodic signals. The circadian clocks of humans, some animals, and plants consist of oscillating molecular networks with peak-to-peak time of approximately 24 hours. Clockwork orange (CWO) is a transcriptional repressor of Drosophila direct target genes.Theory and data from a model of the Drosophila circadian clock support the idea that CWO controls anti-jitter negative circuits that stabilize peak-to-peak time in light-dark cycles (LD). The orbit is confined to chaotic attractors in both LD and dark cycles and is almost periodic in LD; furthermore, CWO diminishes the Euclidean dimension of the chaotic attractor in LD. Light resets the clock each day by restricting each molecular peak to the proximity of a prescribed time.The theoretical results suggest that chaos plays a central role in the dynamics of the Drosophila circadian clock and that a single molecule, CWO, may sense jitter and repress it by its negative loops

Fathallah-Shaykh Hassan M.

Public Library of Science (PLOS)

Monday, March 7, 2011 309aMolecular Dynamics II
1673-Pos Board B583
Evidence for Pre- and Post-Power Stroke of Cross-Bridges of Contracting
Skeletal Muscle
Krishna K. Midde.
We examined orientational fluctuations of a few molecules of myosin in work-
ing ex-vivo skeletal myofibril. Light Chain 1 (LC1) of myosin was labeled with
fluorescent dye and exchanged with native LC1 of skeletal myofibril. A small
volume within the A-band (~1016L), containing on average 3-4 fluorescent
myosin molecules, was observed by confocal microscopy. The myofibrils
were cross-linked with EDC [1-ethyl-3-[3-(dimethylamino)propyl]carbodii-
mide] to prevent shortening. During muscle contraction myosin tail (containing
LC1) undergoes cyclic fluctuations of orientation. We measured these fluctua-
tions by recording the parallel and perpendicular components of fluorescent
light emitted by myosin LC1-bound fluorophore. The histograms of fluctua-
tions of fluorescent molecules in rigor were represented by a single Gaussian
distribution. In contrast, histograms of contracting muscles could be fitted by
at least two Gaussians. This provides evidence that cross-bridges in working
skeletal muscle assume two distinct conformations, presumably corresponding
to the pre- and post-power stroke.
1674-Pos Board B584
Drift-Oscillatory Steering with the Forward-Reverse Method for Calculat-
ing the Potential of Mean Force
Bryan W. Holland, Mostafa NategholEslam, Bruno Tomberli,
Chris G. Gray.
We present a method that enables the use of the forward-reverse (FR) method
on a broader range of problems in soft matter physics. Our method, which we
call the OFR method, adds an oscillatory steering potential to the constant
velocity steering potential of the FR method. This enables the calculation of
the potential of mean force (PMF) in a single unidirectional oscillatory drift,
rather than multiple drifts in both directions as required by the FR method.
By following small forward perturbations with small reverse perturbations,
the OFR method is able to generate a piecewise reverse path that follows the
piecewise forward path much more closely than any practical set of paths
used in the FR method. We calculate the PMF for four different systems:
a dragged Brownian oscillator, a pair of atoms in a Lennard-Jones liquid,
a Naþ-Cl- ion pair in an aqueous solution, and a deca-alanine molecule being
stretched in an implicit solvent. In all cases, the PMF results are in good agree-
ment with those published previously using various other methods, and to our
knowledge we give for the first time PMFs calculated by nonequilibrium
methods for the Lennard-Jones and Naþ-Cl- systems.
1675-Pos Board B585
Dynamics of the Drosophila Circadian Clock: Theoretical Anti-Jitter
Network and Controlled Chaos
Hassan M. Fathallah-Shaykh.
Electronic clocks exhibit undesirable jitter or time variations in periodic sig-
nals. The circadian clocks of humans, some animals, and plants consist of
oscillating molecular networks with peak-to-peak time of approximately
24 hours. Clockwork orange (CWO) is a transcriptional repressor of Drosophila
direct target genes.
Theory and data from a model of the Drosophila circadian clock support the
idea that CWO controls anti-jitter negative circuits that stabilize peak-to-
peak time in light-dark cycles (LD). The orbit is confined to chaotic attractors
in both LD and dark cycles and is almost periodic in LD; furthermore, CWO
diminishes the Euclidean dimension of the chaotic attractor in LD. Light resets
the clock each day by restricting each molecular peak to the proximity of
a prescribed time.
The theoretical results suggest that chaos plays a central role in the dynamics of
the Drosophila circadian clock and that a single molecule, CWO, may sense jit-
ter and repress it by its negative loops.
1676-Pos Board B586
A novel Method for Coarse Graining of Atomistic Simulations Using
Boltzmann Inversion
Bram van Hoof, Albert J. Markvoort, Rutger A. van Santen,
Peter A.J. Hilbers.
Molecular dynamics (MD) simulations play an important role in many physi-
cal, chemical and biological applications. To allow MD methods to be applied
to sufficiently large systems and sufficiently long timescales, coarse grained
(CG) molecular dynamics methods have been developed in which groups of
atoms are represented by a single pseudo-atom, or coarse grained bead. In gen-
eral, two groups of coarse-grained force-fields for molecular simulation exist,
one in which standard form potentials are tuned to reproduce certain thermody-namic properties of a system of interest, and a second group in which potentials
are chosen to reproduce simulation results from an atomistic MD simulation.
This second procedure to develop a CG force field depends on the ability to
map coarse grained particles on atoms in an atomistic simulation. An example
of this is the Boltzmann inversion method, in which radial distribution
functions are calculated between the mapped CG particles. For (macro)mole-
cules that are mapped onto multiple CG centers this mapping is relatively
straightforward. However, for small molecules, like water which is the basic
component of most biophysically relevant systems, one must map a group of
molecules onto a single CG particle. Finding the optimal division of molecules
into groups for each frame of the atomistic trajectory is far from trivial.
Here, a novel method is introduced that allows for this mapping of CG particles
on a pre-fixed amount of molecules. Our coarse graining algorithm involves
the optimization of the division of the molecules, using simulated annealing.
The feasibility of the method is demonstrated on various systems containing
either pure water, a water-octanol mixture or a solution of sodium chloride
in water and may be very useful for large biological systems such as mem-
branes in the future.
1677-Pos Board B587
Diffusion and Binding of RNase A in Dextran Polymeric Solutions Studied
by Fluorescence Correlation Spectroscopy
Silviya Zustiak, Ralph Nossal, Dan Sackett.
Diffusion of molecules in the cytoplasm of the cells has long been of interest in
the area of targeted drug delivery as well as for describing basic cellular pro-
cesses. Diffusion of molecules through the cytoplasm or especially the nucle-
oplasm involves movement of relatively small, typically charged molecules
through a sea of much larger, charged, molecules and supramolecular assem-
blies and is mainly affected by molecular crowding and charge-mediated bind-
ing. For small molecules such as metabolites and nucleic acids, an important
parameter that describes the cytoplasmic rhelogy is the translational diffusion
coefficient. In this work, we have developed a model system in which both mo-
lecular crowding and charge-mediated binding were addressed independently
in a controlled manner. In particular, we obtained the translational diffusion co-
efficient of the positively charged protein, RNase A, in polymeric solutions of
dextrans of various charges (which affects binding) and differing dextran con-
centrations (which affects crowding), as well as combinations of both. Using
Fluorescence Correlation Spectroscopy (FCS), we observed that the diffusion
of RNase A was unaffected by the presence of the positively charged or the
neutral dextrans up to 20 mM dextran, above which concentration the diffusion
was hindered by crowding. On the other hand, the presence of negatively
charged dextrans slowed the protein diffusion significantly even at 0.2 mM dex-
tran. The compound translational diffusion of RNase A decreased with increase
in negative dextran concentration. The % bound RNase A also increased until
it reached equilibrium binding of ~90% bound RNase A at 14 mM dextran.
Binding of RNase to the negatively charged dextrans was further confirmed
by ultrafiltration. In addition, exact equilibrium dissociation constants were
determined.
1678-Pos Board B588
Conformational Relaxation and Water Penetration Triggered by the
Ionization of Internal Groups in Proteins
Ana Damjanovic, Xiongwu Wu, Bertrand Garcia-Moreno,
Bernard R. Brooks.
Internal ionizable groups in proteins play essential functional roles in biochem-
ical processes related to bioenergetics, including catalysis, proton transport,
and electron transfer reactions. Many proteins harness the coupling between
the ionization of internal groups and structural reorganization for functional
purposes. To elucidate the mechanisms and the structural basis of function in
these proteins, it is necessary to understand how the ionization of internal
groups is coupled to structural reorganization of the protein and how the protein
environment influences the pKa values of internal groups. Through molecular
dynamics simulations and Self-guided Langevin dynamics simulations we
are studying the types of structural responses that can be triggered by ionization
of internal groups. Water penetration, side-chain rotation and backbone relax-
ation are among the structural changes that have been detected with molecular
dynamics simulations. A large family of variants of staphylococcal nuclease
with internal ionizable groups (Lys, Arg, Asp and Glu) are being used to exam-
ine these issues systematically. Some of the ionizable groups exhibit pKa values
that are shifted significantly compared to the normal values in bulk water. Most
computational methods for pKa calculations cannot reproduce accurately the
pKa shifts observed in such variants, primarily because they cannot reproduce
correctly the structural response to the ionization of internal groups. The phys-
ical and structural insight into structural changes promoted by internal charges
will be useful to guide the development of more accurate methods for structure-
based pKa calculations.


A circadian enhancer mediates PERdependent mRNA cycling in Drosophila melanogaster.

A mutant Drosophila homolog of mammalian Clock disrupts circadian rhythms and transcription of period and timeless.

Bifurcations in a mathematical model for circadian oscillations of clock genes.

Circadian regulation of a Drosophila homolog of the mammalian Clock gene: PER and TIM function as positive regulators.

Clockwork Orange is a transcriptional repressor and a new Drosophila circadian pacemaker component.

Closing the circadian loop: CLOCK-induced transcription of its own inhibitors per and tim.

Comparison of different methods for computing Lyapunov exponents.

Computation of a few Lyapunov exponents for continuous and discrete dynamical systems.

CYCLE is a second bHLH-PAS clock protein essential for circadian rhythmicity and transcription of Drosophila period and timeless.

Dec1 and dec2 are regulators of the mammalian molecular clock.

Fractal mechanisms in the electrophysiology of the heart.

From simple to complex oscillatory behavior in metabolic and genetic control networks.

Goldbeter A

Microarray analysis and organization of circadian gene expression in Drosophila.

On the computation of Lyapunov exponents for contnuous dynamical systems.

The transcriptional repressor DEC2 regulates sleep length in mammals.

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Dynamics of the Drosophila Circadian Clock: Theoretical Anti-Jitter Network and Controlled Chaos

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