1. Dinamica Molecular y el modelamiento de macromoleculas

2. Historical Perspective
1946 MD calculation
1960 force fields
1969 Levinthal’s paradox on protein folding
1970 MD of biological molecules
1971 protein data bank
1998 ion channel protein crystal structure
1999 IBM announces blue gene project

3. Proteins
Polypeptide chains made up of amino acids or residues linked by peptide bonds
20 aminoacids
residues, atoms
Native structure believed to correspond to energy minimum, since proteins unfold when temperature is increased

4. Proteins: Local Motions
AA, 1 fs -0.1s
Atomic fluctuations
Small displacements for substrate binding in enzymes
Energy “source” for barrier crossing and other activated processes (e.g., ring flips)
Sidechain motions
Opening pathways for ligand (myoglobin)
Closing active site
Loop motions
Disorder-to-order transition as part of virus formation

6. Levinthal paradox
Proteins simply can not fold on a reasonable time scale (Levinthal paradox; J. Chem. Phys., 1968, 65: 44-45)
Each bond connecting amino acids can have several (e.g., three) possible states (conformations). A protein of, say, 101 AA could exist in 3100 = 5 x 1047 conformations. If the protein can sample these conformations at a rate of 1013/sec, 3 x 1020/year, it will take 1027 years to try them all. Nevertheless, proteins fold in a time scale of seconds.

7. Proteins: Rigid-Body Motions
1-10 AA, 1 ns – 1 s
Helix motions
Transitions between substrates (myoglobin)
Hinge-bending motions
Gating of active-site region (liver alcohol dehydroginase)
Increasing binding range of antigens (antibodies)

8. Quantum Mechanical Origins
Fundamental to everything is the Schrödinger equation
wave function
H = Hamiltonian operator
time independent form
Born-Oppenheimer approximation
electrons relax very quickly compared to nuclear motions
nuclei move in presence of potential energy obtained by solving electron distribution for fixed nuclear configuration
it is still very difficult to solve for this energy routinely
usually nuclei are heavy enough to treat classically
Nuclear coordinates
Electronic coordinates

9. Force Field Methods
Too expensive to solve QM electronic energy for every nuclear configuration
Instead define energy using simple empirical formulas
“force fields” or “molecular mechanics”
Decomposition of the total energy
Force fields usually written in terms of pairwise additive interatomic potentials
with some exceptions
Neglect 3- and higher-order terms
Single-atom energy (external field)
Atom-pair contribution
3-atom contribution

10. Conformation optimization for molecular interaction
Molecular Mechanics Approach:

11. Energy minimisation
Calculation of how atoms should move to minimise TOTAL potential energy
At minimum, forces on every
atom are zero.
Optimising structure to remove strain & steric clashes
However, in general finds local rather than global minimum. Energy barriers are not overcome even if much lower energy state is possible ie structures may be locked in. Hence not useful as a search strategy.

12. Energy minimisation Steepest descents Conjugate gradients
Potential energy depends on many parameters
Problem of finding minimum value of a function with >1 parameters. Know value of
function at several points.
Grid search is computationally
not feasible
Methods
Steepest descents
Conjugate gradients

13. Molecular Dynamics: Introduction
Newton’s second law of motion

14. Molecular dynamics F=ma
F is calculated from molecular mechanical potential.
Model conformational changes.
Calculate time-dependent properties (transport properties).

15. Molecular Dynamics: Introduction
We need to know
The motion of the
atoms in a molecule, x(t)
and therefore,
the potential energy, V(x)

16. Molecular Dynamics: Introduction
How do we describe the potential energy V(x) for a
molecule?
Potential Energy includes terms for
Bond stretching
Angle Bending
Torsional rotation
Improper dihedrals

17. Molecular Dynamics: Introduction
Potential energy includes terms for (contd.)
Electrostatic
Interactions
van der Waals

18. Molecular Dynamics: Introduction
To do this, we should know
at given time t,
initial position of the atom x1
its velocity
v1 = dx1/dt
and the acceleration
a1 = d2x1/dt2 = m-1F(x1)

19. Molecular Dynamics: Introduction
The position x2 , of the atom after time interval t would be,
and the velocity v2 would be,

20. Molecular Dynamics: Introduction
In general, given the values x1, v1 and the potential energy V(x), the molecular trajectory x(t) can be calculated, using,

21. How a molecule changes during MD

22. The Necessary Ingredients
Description of the structure: atoms and connectivity
Initial structure: geometry of the system
Potential Energy Function: force field
AMBER
CVFF
CFF95
Universal

23. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross

24. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross

25. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross

26. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross

27. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross

28. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross

29. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
Repulsion
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross
Mixed terms

30. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
Repulsion
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross
Mixed terms

31. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
Repulsion
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross - +
Attraction - +
Mixed terms

32. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
Repulsion
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross - + - +
Attraction
Mixed terms

33. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
Repulsion
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross - + - +
Attraction + - + -
Mixed terms

34. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
Repulsion
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross - + - +
u(2)
Attraction + - + +
u(2) - + - + -
u(N) + -
Mixed terms

35. Contributions to Potential Energy
Total pair energy breaks into a sum of terms
Intramolecular only
Repulsion
UvdW van der Waals
Uel electrostatic
Upol polarization
Ustr stretch
Ubend bend
Utors torsion
Ucross cross - + - +
u(2)
Attraction + - + +
u(2) - + - + -
u(N) + -
Mixed terms

36. Modeling Potential energy
A Taylor series expansion of the full potential gives us an analytical form to which we apply mathematical techniques
- eliminate terms
- find extrema

37. Modeling Potential energy
0 at minimum
A Taylor series expansion of the full potential gives us an analytical form to which we apply mathematical techniques
- eliminate terms
- find extrema

38. Stretch Energy Expand energy about equilibrium position
Model fails in strained geometries
better model is the Morse potential
(neglect)
define
minimum
harmonic
Morse
dissociation energy
force constant

39. Bending Energy q Expand energy about equilibrium position
improvements based on including higher-order terms
Out-of-plane bending
(neglect)
define
minimum
harmonic
u(4) c

40. Torsional Energy f Two new features Fourier series periodic
weak (Taylor expansion in f not appropriate)
Fourier series
terms are included to capture appropriate minima/maxima
depends on substituent atoms
e.g., ethane has three mimum-energy conformations
n = 3, 6, 9, etc.
depends on type of bond
e.g. ethane vs. ethylene
usually at most n = 1, 2, and/or 3 terms are included

41. Van der Waals Attraction
Correlation of electron fluctuations
Stronger for larger, more polarizable molecules
CCl4 > CH4 ; Kr > Ar > He
Theoretical formula for long-range behavior
Only attraction present between nonpolar molecules
reason that Ar, He, CH4, etc. form liquid phases
a.k.a. “London” or “dispersion” forces - + - + - + - +

42. Van der Waals Repulsion
Overlap of electron clouds
Theory provides little guidance on form of model
Two popular treatments
inverse power exponential
typically n ~ two parameters
Combine with attraction term
Lennard-Jones model Exp-6
a.k.a. “Buckingham” or “Hill”
Beware of anomalous Exp-6 short-range attraction
Exp-6 repulsion is slightly softer

43. Electrostatics 1. Interaction between charge inhomogeneities
Modeling approaches
point charges
point multipoles
Point charges
assign Coulombic charges to several points in the molecule
total charge sums to charge on molecule (usually zero)
Coulomb potential
very long ranged

44. Electrostatics 2.
At larger separations, details of charge distribution are less important
Multipole statistics capture basic features
Dipole
Quadrupole
Octopole, etc.
Point multipole models based on long-range behavior
dipole-dipole
dipole-quadrupole
quadrupole-quadrupole
Vector
Tensor
Axially symmetric quadrupole

45. Polarization + -
Charge redistribution due to influence of surrounding molecules
dipole moment in bulk different from that in vacuum
Modeled with polarizable charges or multipoles
Involves an iterative calculation
evaluate electric field acting on each charge due to other charges
adjust charges according to polarizability and electric field
re-compute electric field and repeat to convergence
Re-iteration over all molecules required if even one is moved + - + - + - + - + -

46. Polarization
Approximation
Electrostatic field does not include contributions from atom i

47. Common Approximations in Molecular Models
Rigid intramolecular degrees of freedom
fast intramolecular motions slow down MD calculations
Ignore hydrogen atoms
united atom representation
Ignore polarization
expensive n-body effect
Ignore electrostatics
Treat whole molecule as one big atom
maybe anisotropic
Model vdW forces via discontinuous potentials
Ignore all attraction
Model space as a lattice
especially useful for polymer molecules
Qualitative models

48. Molecular Dynamics: Introduction
Equation for covalent terms in P.E.

49. Molecular Dynamics: Introduction
Equation for non-bonded terms in P.E.

50. An overview of various motions in proteins (1)
-14 to –13
0.5 to 1
Torsional vibration of buried groups
-11 to –10
Rotation of side chains at surface
-12 to –11
1 to 2
Elastic vibration of globular region
0.2 to 0.5
Relative vibration of bonded atoms
Log10 of characteristic time (s)
Spatial extent (nm)
Motion

51. An overview of various motions in proteins (2)
Log10 of characteristic time (s)
Spatial Extent (nm)
Motion
-5 to 2
???
Protein folding
-5 to 1
0.5 to 1
Local denaturation
-5 to 0
0.5 to 4
Allosteric transitions
-4 to 0
0.5
Rotation of medium-sized side chains in interior
-11 to –7
1 to 2
Relative motion of different globular regions (hinge bending)

52. A typical MD simulation protocol
Initial random structure generation
Initial energy minimization
Equilibration
Dynamics run – with capture of conformations at regular intervals
Energy minimization of each captured conformation

53. Essential Parameters for MD (to be set by user)
Temperature
Pressure
Time step
Dielectric constant
Force field
Durations of equilibration and MD run
pH effect (addition of ions)

54. STARTING DNA MODEL

55. DNA MODEL WITH IONS

56. DNA in a box of water

57. SNAPSHOTS

58. Protein dynamics study
Ion channel / water channel
Mechanical properties
Protein stretching
DNA bending
Movie downloaded from theoreticla biophysics group, UIUC

59. Molecular Interactions
water-water interaction
van der Waals’ term
Hydrogen bonding term
ion-water interaction

61. Average number of hydrogen bonds within the first water shell around an ion

63. Solvent dielectric models
Effetive dielectric constant

64. Introduction to Force Fields
Sophisticated (though imperfect!)
mathematical function
Returns energy as a function
of conformation
It looks something like this …
U(conformation) = Ebond + Eangle + Etors + Evdw + Eelec+ …

65. Why do we need force field?
Force field and potential energy surface.
Changes in the energy of a system can be considered as movements on a multidimentional surface call the “energy surface”. Force is the first derivative of the energy.
In molecular mechanics approach, the dimension of potential surface is 3N, N is number of particles.
The probability of the molecular system stay in certain conformations can be calculated if the underlying potential is known.

66. Three types of force field
Quantum mechanics (Schrodinger equation for electrons), usually deal with systems with less than 100 atoms.
Empirical force field: molecular mechanics (for atoms), can be used for systems up to millions of atoms.
Statistical potential (flexible), no restriction.

67. Source of FF components
Geometrical terms: bond, angle, torsion
& vdw parameters come from
empirical data.
Electrostatic charges: two problems arise
 no exp.data for charges
 basis underlying molec. model

68. Molecular mechanical force field
Potential is the summation of the following terms :
Bond stretching,
Angle bending,
Torsion rotation,
Non-bonded interactions
Vdw interaction,
Electrostatic interaction.
(Hydrogen bonds).
(Implicit solvent). …

69. Figures are taken from NIH guide of molecular modeling

72. non-bonded terms

73. Common empirical force fields
Class I
CHARMM
CHARMm (Accelrys)
AMBER
OPLS/AMBER/Schrödinger
ECEPP (free energy force field)
GROMOS
Class II
CFF95 (Biosym/Accelrys)
MM3
MMFF94 (CHARMM, Macromodel, elsewhere)
UFF, DREIDING

74. Assumptions
Hydrogens often not explicitly included (intrinsic hydrogen methods)
“Methyl carbon” equated with 1 C and 3 Hs
System not far from equilibrium geometry (harmonic)
Solvent is vacuum or simple dielectric

75. Assumptions: Harmonic Approximation
Energy is in Joules/molecule
Distance is in Angstroms

76. Assumptions: Harmonic Approximation
Energy is in Joules/molecule
Distance is in Angstroms

77.                                                                                  
Brief History of FF

78. Force Field classification
1.- with rigid/partially rigid geometries
ECEPP, …
2.- without electrostatics
SYBYL, …
3.- simple diagonal FF
Weiner, GROMOS, CHARMm, OPLS/AMBER, …
4.- more complex FF
MM2, MM3, MMFF, …
OVERALLLLLLLLLLLLLLLLLLLLLLLLLLL ….
IN SUMMARY ……..

79. Comparison of the simple diagonal FF
Force Field
Electrostatics
van der Waals
CHARMm
empirical fit to quantum mechanics dimers
empirical (x-ray, crystals)
GROMOS
empirical
OPLS/AMBER
empirical (Monte Carlo on liquids)
empirical (liquids)
Weiner
ESP fit (STO-3G)
Cornell
RESP fit (6-31G*)

80. Transferability AMBER (Assisted Model Building Energy Refinement)
Specific to proteins and nucleic acids
CHARMM (Chemistry at Harvard Macromolecular Mechanics)
Widely used to model solvent effects
Molecular dynamics integrator

81. Transferability MM? – (Allinger et. al.)
Organic molecules
MMFF (Merck Molecular Force Field)
Molecular Dynamics
Tripos/SYBYL
Organic and bio-organic molecules

82. Transferability UFF (Universal Force Field) YETI
Parameters for all elements
Inorganic systems
YETI
Parameterized to model non-bonded interactions
Docking (AmberYETI)

83. MMFF Energy Electrostatics (ionic compounds) D – Dielectric Constant
d - electrostatic buffering constant

84. MMFF Energy Analogous to Lennard-Jones 6-12 potential
London Dispersion Forces
Van der Waals Repulsions
The form for the repulsive part has no physical basis and is for computational convenience when working with large macromolecules. K. Gilbert: Force fields like MM2 which is used for smaller organic systems will use a Buckingham potential (or expontential) which accurately reflects the
chemistry/physics.

85. Pros and Cons N >> 1000 atoms Easily constructed Accuracy
Not robust enough to describe subtle chemical effects
Hydrophobicity
Excited States
Radicals
Does not reproduce quantal nature

86. Simple Statistics on MD Simulation
Atoms in a typical protein and water
simulation
Approximate number of interactions in force
calculation
Machine instructions per force calculation 1000
Total number of machine instructions
Typical time-step size –15 s
Number of MD time steps steps
Physical time for simulation –4 s
Total calculation time (CPU: P4-3.0G ) days 10,000

87. Hardware Strategies Parallel computation
PC cluster
IBM (The blue gene), 106 CPU
Massive distributive computing
Grid computing (formal and in the future)
Server to individual client (now in inexpensive)
Examples: SETI,

88. # publications/year mentioning FF used to model proteins