Your search keyword '"Purohit, Prashant K."' showing total 203 results

201. Protein unfolding accounts for the unusual mechanical behavior of fibrin networks.

Author

Purohit PK, Litvinov RI, Brown AE, Discher DE, and Weisel JW

Subjects

Microscopy, Atomic Force, Models, Chemical, Fibrin chemistry, Protein Denaturation

Abstract

We describe the mechanical behavior of isotropic fibrin networks at the macroscopic scale in terms of the nanoscale force response of fibrin molecules that are its basic building blocks. We show that the remarkable extensibility and compressibility of fibrin networks have their origins in the unfolding of fibrin molecules. The force-stretch behavior of a single fibrin fiber is described using a two-state model in which the fiber has a linear force-stretch relation in the folded phase and behaves like a worm-like-chain in the unfolded phase. The nanoscale force-stretch response is connected to the macro-scale stress-stretch response by means of the eight-chain model. This model is able to capture the macroscopic response of a fibrin network in uniaxial tension and appears remarkably simple given the molecular complexity. We use the eight-chain model to explain why fibrin networks have negative compressibility and Poisson's ratio greater than 1 due to unfolding of fibrin molecules., (Copyright © 2011 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2011

202. Multiscale mechanics of fibrin polymer: gel stretching with protein unfolding and loss of water.

Author

Brown AE, Litvinov RI, Discher DE, Purohit PK, and Weisel JW

Subjects

Biopolymers chemistry, Fibrinogen chemistry, Gels, Humans, Mechanical Phenomena, Microscopy, Electron, Models, Molecular, Protein Folding, Stress, Mechanical, Water chemistry, Blood Coagulation, Fibrin chemistry

Abstract

Blood clots and thrombi consist primarily of a mesh of branched fibers made of the protein fibrin. We propose a molecular basis for the marked extensibility and negative compressibility of fibrin gels based on the structural and mechanical properties of clots at the network, fiber, and molecular levels. The force required to stretch a clot initially rises linearly and is accompanied by a dramatic decrease in clot volume and a peak in compressibility. These macroscopic transitions are accompanied by fiber alignment and bundling after forced protein unfolding. Constitutive models are developed to integrate observations at spatial scales that span six orders of magnitude and indicate that gel extensibility and expulsion of water are both manifestations of protein unfolding, which is not apparent in other matrix proteins such as collagen.

Published

2009

203. Mechanics of DNA packaging in viruses.

Author

Purohit PK, Kondev J, and Phillips R

Subjects

Biomechanical Phenomena, Capsid metabolism, DNA, Viral chemistry, Energy Metabolism, Models, Biological, Thermodynamics, DNA Viruses metabolism, DNA, Viral metabolism

Abstract

A new generation of single-molecule experiments has opened up the possibility of reexamining many of the fundamental processes of biochemistry and molecular biology from a unique and quantitative perspective. One technique producing a host of intriguing results is the use of optical tweezers to measure the mechanical forces exerted by molecular motors during key processes such as the transcription of DNA or the packing of a viral genome into its capsid. The objective of the current article is to respond to such measurements on viruses and to use the theory of elasticity and a simple model of charge and hydration forces to derive the force required to pack DNA into a viral capsid as a function of the fraction of the viral genome that has been packed. The results are found to be in excellent accord with recent measurements and complement previous theoretical work. Because the packing of DNA in viral capsids occurs under circumstances of high internal pressure, we also compute how much pressure a capsid can sustain without rupture.

Published

2003