Your search keyword '"K Purohit"' showing total 6 results

1. Interaction of Anti-DNA Antibody MRL4 with DNA Studied at the Single-Molecule Level

Author

Valerie Tutwiler, T. A. Nevzorova, John W. Weisel, Qingze Zhao, Yakov A. Lomakin, Rustem I. Litvinov, and Prashant K. Purohit

Subjects

Anti-DNA Antibody, chemistry.chemical_compound, Chemistry, Biophysics, Molecule, Molecular biology, DNA

Published

2017

2. Geometry of Mediating Protein Affects the Probability of Loop Formation in DNA

Author

Ravi Radhakrishnan, Neeraj Jagdish Agrawal, and Prashant K. Purohit

Subjects

Models, Molecular, Monte Carlo method, Biophysics, Geometry, Probability density function, Curvature, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Nucleic Acids, 0103 physical sciences, Computer Simulation, 010306 general physics, 030304 developmental biology, 0303 health sciences, Quantitative Biology::Biomolecules, Binding Sites, Models, Statistical, Chemistry, Mode (statistics), DNA, Function (mathematics), DNA-Binding Proteins, Loop (topology), Models, Chemical, Nucleic Acid Conformation, Deformation (engineering), Protein Binding

Abstract

Recent single molecule experiments have determined the probability of loop formation in DNA as a function of the DNA contour length for different types of looping proteins. The optimal contour length for loop formation as well as the probability density functions have been found to be strongly dependent on the type of looping protein used. We show, using Monte Carlo simulations and analytical calculations, that these observations can be replicated using the wormlike-chain model for double-stranded DNA if we account for the nonzero size of the looping protein. The simulations have been performed in two dimensions so that bending is the only mode of deformation available to the DNA while the geometry of the looping protein enters through a single variable which is representative of its size. We observe two important effects that seem to directly depend on the size of the enzyme: 1), the overall propensity of loop formation at any given value of the DNA contour length increases with the size of the enzyme; and 2), the contour length corresponding to the first peak as well as the first well in the probability density functions increases with the size of the enzyme. Additionally, the eigenmodes of the fluctuating shape of the looped DNA calculated from simulations and theory are in excellent agreement, and reveal that most of the fluctuations in the DNA occur in regions of low curvature.

Published

2008

3. Forces during Bacteriophage DNA Packaging and Ejection

Author

Todd M. Squires, Jane Kondev, Rob Phillips, Mandar M. Inamdar, Prashant K. Purohit, and Paul Grayson

Subjects

Models, Molecular, animal structures, Virus Integration, Biophysics, Biophysical Theory and Modeling, Biology, 010402 general chemistry, 01 natural sciences, Genome, Models, Biological, Bacteriophage, 03 medical and health sciences, chemistry.chemical_compound, Viral life cycle, DNA Packaging, Bacteriophages, Computer Simulation, 030304 developmental biology, 0303 health sciences, Molecular Motor Proteins, Biomolecules (q-bio.BM), biology.organism_classification, 0104 chemical sciences, chemistry, Capsid, Structural biology, Biochemistry, Models, Chemical, Quantitative Biology - Biomolecules, FOS: Biological sciences, DNA, Viral, Nucleic Acid Conformation, Stress, Mechanical, Dna packaging, DNA

Abstract

The conjunction of insights from structural biology, solution biochemistry, genetics, and single-molecule biophysics has provided a renewed impetus for the construction of quantitative models of biological processes. One area that has been a beneficiary of these experimental techniques is the study of viruses. In this article we describe how the insights obtained from such experiments can be utilized to construct physical models of processes in the viral life cycle. We focus on dsDNA bacteriophages and show that the bending elasticity of DNA and its electrostatics in solution can be combined to determine the forces experienced during packaging and ejection of the viral genome. Furthermore, we quantitatively analyze the effect of fluid viscosity and capsid expansion on the forces experienced during packaging. Finally, we present a model for DNA ejection from bacteriophages based on the hypothesis that the energy stored in the tightly packed genome within the capsid leads to its forceful ejection. The predictions of our model can be tested through experiments in vitro where DNA ejection is inhibited by the application of external osmotic pressure.

Published

2005

4. Material properties of Caenorhabditis elegans swimming at low Reynolds number

Author

Paulo E. Arratia, Todd Lamitina, Predrag Krajacic, Prashant K. Purohit, and Josué Sznitman

Subjects

Nematode caenorhabditis elegans, Muscle, Motility, and Motor Proteins, Biophysics, Motility, FOS: Physical sciences, Biology, Models, Biological, Quantitative Biology::Cell Behavior, symbols.namesake, Viscosity, Gait (human), Undulatory locomotion, Elastic Modulus, Animals, Physics - Biological Physics, Caenorhabditis elegans, Swimming, Physics::Biological Physics, Quantitative Biology::Neurons and Cognition, Ecology, Fluid Dynamics (physics.flu-dyn), Reynolds number, Physics - Fluid Dynamics, Muscular Dystrophy, Animal, biology.organism_classification, Quantitative Biology::Genomics, Biomechanical Phenomena, Biological Physics (physics.bio-ph), Mutation, symbols, Material properties

Abstract

Undulatory locomotion, as seen in the nematode \emph{Caenorhabditis elegans}, is a common swimming gait of organisms in the low Reynolds number regime, where viscous forces are dominant. While the nematode's motility is expected to be a strong function of its material properties, measurements remain scarce. Here, the swimming behavior of \emph{C.} \emph{elegans} are investigated in experiments and in a simple model. Experiments reveal that nematodes swim in a periodic fashion and generate traveling waves which decay from head to tail. The model is able to capture the experiments' main features and is used to estimate the nematode's Young's modulus $E$ and tissue viscosity $\eta$. For wild-type \emph{C. elegans}, we find $E\approx 3.77$ kPa and $\eta \approx-860$ Pa$\cdot$s; values of $\eta$ for live \emph{C. elegans} are negative because the tissue is generating rather than dissipating energy. Results show that material properties are sensitive to changes in muscle functional properties, and are useful quantitative tools with which to more accurately describe new and existing muscle mutants., Comment: To appear in Biophysical Journal

Published

2009

5. Equilibrium and Kinetics of DNA Overstretching Modeled with a Quartic Energy Landscape

Author

David Argudo and Prashant K. Purohit

Subjects

Phase transition, Stochastic Processes, Physics::Biological Physics, Quantitative Biology::Biomolecules, Models, Genetic, Chemistry, Biophysics, Temperature, Thermodynamics, Ionic bonding, Energy landscape, Cooperativity, DNA, Statistical fluctuations, Kinetic energy, Quantitative Biology::Genomics, Kinetics, Models, Chemical, Computational chemistry, Phase (matter), Molecule, Nucleic Acid Conformation, Proteins and Nucleic Acids, Algorithms

Abstract

It is well known that the dsDNA molecule undergoes a phase transition from B-DNA into an overstretched state at high forces. For some time, the structure of the overstretched state remained unknown and highly debated, but recent advances in experimental techniques have presented evidence of more than one possible phase (or even a mixed phase) depending on ionic conditions, temperature, and basepair sequence. Here, we present a theoretical model to study the overstretching transition with the possibility that the overstretched state is a mixture of two phases: a structure with portions of inner strand separation (melted or M-DNA), and an extended phase that retains the basepair structure (S-DNA). We model the double-stranded DNA as a chain composed of n segments of length l, where the transition is studied by means of a Landau quartic potential with statistical fluctuations. The length l is a measure of cooperativity of the transition and is key to characterizing the overstretched phase. By analyzing the different values of l corresponding to a wide spectrum of experiments, we find that for a range of temperatures and ionic conditions, the overstretched form is likely to be a mix of M-DNA and S-DNA. For a transition close to a pure S-DNA state, where the change in extension is close to 1.7 times the original B-DNA length, we find l ≈ 25 basepairs regardless of temperature and ionic concentration. Our model is fully analytical, yet it accurately reproduces the force-extension curves, as well as the transient kinetic behavior, seen in DNA overstretching experiments.

6. Confinement and Manipulation of Actin Filaments by Electric Fields

Author

Prashant K. Purohit, Yale E. Goldman, Mark E. Arsenault, Hui Zhao, and Haim H. Bau

Subjects

Electromagnetic field, Models, Molecular, Materials science, Biophysical Letters, Protein Conformation, Biophysics, 02 engineering and technology, macromolecular substances, 010402 general chemistry, Radiation Dosage, 01 natural sciences, Molecular physics, Quantitative Biology::Subcellular Processes, Protein filament, Micromanipulation, Electromagnetic Fields, Electric field, Electrochemistry, Computer Simulation, Tension (physics), Conductance, Dose-Response Relationship, Radiation, 021001 nanoscience & nanotechnology, Actin cytoskeleton, Elasticity, 0104 chemical sciences, Actin Cytoskeleton, Classical mechanics, Models, Chemical, Electrode, Stress, Mechanical, 0210 nano-technology, Intensity (heat transfer)

Abstract

When an AC electric field was applied across a small gap between two metal electrodes elevated above a surface, rhodamine-phalloidin-labeled actin filaments were attracted to the gap and became suspended between the two electrodes. The variance 〈s2(x)〉 of each filament’s horizontal, lateral displacement was measured as a function of electric field intensity and position along the filament. 〈s2(x)〉 markedly decreased as the electric field intensity increased. Hypothesizing that the electric field induces tension in the filament, we estimated the tension using a linear, Brownian dynamic model. Our experimental method provides a novel means for trapping and manipulating biological filaments and for probing the surface conductance and mechanical properties of single polymers.