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Phase Transitions in Stretched Multi-Stranded Biomolecules

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Title: Slide 1 Author: Simon Brown Last modified by: Hemant Created Date: 7/13/2005 12:26:50 PM Document presentation format: On-screen Show (4:3) Company – PowerPoint PPT presentation

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Title: Phase Transitions in Stretched Multi-Stranded Biomolecules


1
Phase Transitions in Stretched Multi-Stranded
Biomolecules
  • Hemant Tailor
  • Dept of Physics Astronomy (UCL)

2
Introduction
  • Use statistical field theory to study the
    nucleation of breakage of DNA under strain by
    external forces.
  • More specifically, we are looking at a shearing
    problem where the opposite ends of the two
    back-bone strands of the DNA are pulled apart
    along its axis.
  • Biologically, RNA synthesis is an example of
  • where external forces act on DNA.
  • DNA-related nanotechnology using DNA as
  • Nano-structured devices

3
DNA Toy Model Geometric Representation
  • Represent DNA as a 1-D ladder structure
  • Interactions along the backbone and base-pair are
    assumed to be harmonic.
  • Each base-pair interacts through a potential
    which is dependent on the axial pair separation
    .
  • Backbone spring constant , Base-pair
    spring constant

4
DNA Toy Model - Hamiltonian
  • The substitution of and
    were used to decouple the variables for the
    integration.
  • The following transformations were also applied
    to simplify the calculation
  • The Hamiltonian becomes
  • Inserting this into the configuration Integral we
    get an expression for Z that can be evaluated for
    different breakage patterns.

5
DNA Toy Model - Potential
  • The potential for the base-pair interactions is
    approximated by a harmonic potential between the
    cut-offs .
  • Outside the cut-off we consider the bond broken,
    and hence the potential is constant.

6
Transfer Integral Method (I)
  • With the Transfer Matrices

7
Breakage Patterns
  • Labels determine breakage pattern.

Intact
Frayed
Bubble
8
Transfer Integral Method (II)
  • Transfer Matrices with the breakage pattern
    factor becomes
  • Using the breakage patterns indices, and
    including the boundary conditions,

Almost ready to evaluate Z!!!!
9
Transfer Integral Method (III)
  • Delta functions can now be represented as
  • Eigenfunctions are defined by the following
    eigenvalue equations

Let the solving begin!!!!
10
Transfer Integral Method (III)
Here we have contracted most of the , the
contraction of will depend on the breakage
patterns
11
DNA Intact State
  • All base-pairs are intact, so

12
DNA Intact State (II)
13
DNA Frayed State
  • broken base-pairs where

14
DNA Frayed States (II)
15
DNA Frayed States (III)
16
DNA Bubble State
  • intact base-pairs then broken base-pairs

17
DNA Bubble States (II)
18
Conclusion
  • Still work in progress!!!!
  • Successfully calculated Free Energies for Intact,
    Frayed and Bubble states as a function of strand
    extension
  • See Phase Transitions from the free energy graphs
  • Next is to apply a similar Toy model for Collagen
    (Triple Helix) - Toblerone as our geometric
    model!!!!
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