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Title: Generalizedensemble Algorithms for Molecular Simulations of Proteins


1
Generalized-ensemble Algorithms for Molecular
Simulations of Proteins
  • Hongjun Yue, 4/19/2003

2
Outline
  • Introduction
  • Generalized Ensemble
  • Generalized-ensemble Algorithms
  • Generalized-ensemble Monte Carlo simulations of
    peptides as examples

3
Introduction
  • The function of proteins and peptides are solely
    determined by their 3D shape, such as a-helix and
    ß-sheets
  • One tries to understand the folding of a protein
    or peptide solely from the underlying physical
    laws, taking the interaction between all atoms of
    the protein in account.
  • There are two types of simulations, Monte Carlo
    simulation and Molecular Dynamics simulation.

Reference 1,2,4,5
4
Introduction
  • The energy of protein (can be described by ECEPP
    energy function) contains a huge number of local
    minima.
  • At temperature of experimental interest(300K),
    traditional methods like Monte Carlo or molecular
    dynamics tend to get trapped in one of the local
    minima, because of the biased sampling.
  • A simulation in generalized ensemble performs a
    free random walk in potential energy space and
    can overcome this difficulty.

Reference 1,2,4,5
5
Generalized Ensemble
  • Generalized Ensemble (complete open system)
  • The system can exchange energy, volume and
    particles with the surroundings
  • Keeps the corresponding average values U, V and N
    constant
  • ltEgt
  • ltVgt
  • ltNgt

Reference 2
6
Generalized Ensemble
  • Partition function of Generalized Ensemble
  • The probabilities of the microstates (Pi) in the
    Generalized Ensemble are

Reference 3
7
Generalized-ensemble Algorithms (GEA)
  • Characteristic of GEA
  • Each state is weighted by a non-Boltzmann
    probability weight factor
  • Uniform distribution of pre-chosen physical
    quantity
  • Weights are not priori known
  • Estimators for these weights have to be
    determined often by iterative procedure
  • In a single simulation run, one can obtain
  • the global-minimum-energy state
  • canonical ensemble averages as functions of
    temperature through some reweighting tech.

Reference 1,2,4,5
8
GEA--Multicanonical Ensemble
  • Also Entropic sampling or adaptive umbrella
    sampling of the potential energy, perform a 1D
    random walk in potential energy space
  • The probability distribution of energy is defined
    as Pmun(E)Wmu(E)const.
  • The multicanonical weight factor then satisfies
  • Wmu(E) n-1(E), n(E) is the density of states
    with energy E
  • The weight factor is not a priori know, one has
    to determine it for each system by a few
    iterations of trial MC or MD simulation

Reference 2,5
9
GEA--Multicanonical Ensemble
  • Once the weight factor is obtained, one performs
    a long production simulation run.
  • The global-minimum-energy state thus obtained
  • The canonical distribution PB(T,E) can be
    calculated
  • The expectation value of a physical quantity
    A,ltAgt

Reference 2,5
10
GEASimulated tempering (ST)
  • Also the method of expanded ensemble, performs a
    free random walk in temperature space.
  • Both the configuration and the temperature are
    updated during the simulation with a weight
    WST(E,T).
  • The function a(T) is chosen so that the
    probability distribution of temperature PST(T) is
    flat

Reference 2
11
GEASimulated tempering (ST)
  • Function a(T) is not priori known and have to be
    determined by iterations of short simulations.
  • The canonical distribution PB(E,T) and thus
    expectation of a physical quantity ltAgt and be
    calculation as following.
  • Gm12tm, tm is the integrated autocorrelation
    time at Tm

Reference 2
12
GEMreplica-exchange method
  • Also multiple Markov chain method and parallel
    tempering
  • The system of REM consist of M non-interacting
    replicas of original system in the canonical
    ensemble at M different temperatures Tm.
  • Each replica in canonical ensemble of the fixed
    temperature is simulated simultaneously and
    independently for a certain MC or MD steps.
  • A pair of replicas at neighboring
    temperatures,say xmi and xm1 j with the
    probability w(xmi xm1 j)

Reference 2
13
Monte Carlo simulation of C-peptide
  • (a) X-ray structure of C-peptide
  • (b) the lowest conformations of C-peptide
    obtained from a multicanonical Monte Carlo run of
    1,000,000 MC sweeps in gas phase
  • (C) and in aqueous solution represented by the
    distance-dependent dielectric funtion.

Reference 5
14
Monte Carlo simulation of C-eptide
  • Some comments
  • C-peptide, residues 1-13 of ribonuclease A
  • XRD data of the whole enzyme exhibits a nearly
    3-turn a-helix
  • Simulations predicted a similar a-helix in the
    lowest-energy conformation in aqueous solution
  • The positions of a-helix in both situations are
    of the same

15
Monte Carlo simulation of BPTI(16-36)
  • (a) X-ray structure (structure X) of BPTI(16-36)
  • (b) the lowest conformations of BPTI(16-36)
    obtained from a multicanonical Monte Carlo run of
    1,000,000 MC sweeps in gas phase
  • (C) and in aqueous solution represented by the
    term proportional to the solvent-accessibel
    surface area(structure S).

Reference 5
16
Monte Carlo simulation of BPTI(16-36)
  • Some comments
  • a-helix and ß-sheets from residues 16-36 of
    bovine pancreatic trypsin inhibitor (BPTI)
    studied
  • Structure deduced for simulation is rather
    different from on deduced from the XRD
    experiments of the entire BPTI
  • Obvious agreement between simulation and NMR
    experiment on fragment corresponding to residues
    16-36

17
References
  • 1 Ulrich H.E. Hansmann, Physica A 254(1998)
    15-23.
  • 2 Ayori Mitsutake, Yuji Sugita, Yuko Okamoto
    Biopolymers (Peptide Science) 60, 96-123(2001)
  • 3 Material on General ensemblecan be found at
    http//www.ecm.ub.es/condensed/eduard/papers/massi
    eu/node3.html
  • 4 Ulrich H.E. Hansmann, Physica A 321(2003)
    152-163
  • 5 Material from internet, Yuko Okamoto, Ab
    Initio Predictions of Three-Dimensional
    Structures of Proteins by Monte Carlo
    Simulations.
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