Molecular Dynamics of Proteins
Transcript of Molecular Dynamics of Proteins
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Molecular Dynamics of Proteins
UbiquitinMyoglobin
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Root Mean Squared Deviation: measure
for equilibration and protein flexibility
NMR structuresaligned together to see flexibility
MD simulationThe color represents mobility of the protein
through simulation (red = more flexible)
RMSD constantprotein equilibrated
Protein sequence
exhibits
characteristic
permanent
flexibility!
Equilibrium Properties of Proteins
Ubiquitin
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Thermal Motion of Ubiquitin from MD
RMSD values per residue
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Thermal Motion of Ubiquitin from MDTemperature Dependence of Crystal Diffraction (Debye-Waller factor)
Bragg’s law
structure factor
But the atom carries out thermal vibrations around equilibriumposition
Accordingly:
The diffraction signal is the sum of thestructure factors of all atoms in the crystal.
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Spatial average:
One can expand:
+ …
One can carry out the expansion further and show
Using for the thermal amplitude of the harmonic oscillator
one obtains
Thermal Motion of Ubiquitin from MDTemperature Dependence of Crystal Diffraction (Debye-Waller factor)
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Equilibrium Properties of Proteins
Energies: kinetic and potential
Kinetic energy (quadratic)
Potentialc energy (not all quadratic)
?
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Equilibrium Properties of Proteins
Energies: kinetic and potential
Kinetic energy (quadratic)
Potentialc energy (not all quadratic)
3,6932,257
1,237
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Maxwell Distribution of Atomic Velocities
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Mean Kinetic EnergyExercise in Statistics
Use formula below:
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Maxwell Kinetic EnergyDistributionSecond Exercise in Statistics
One-dimensional kinetic energy:
(factor 2 from restriction of integration to positive values)
For the total kinetic energy(in three dimensions)holds then
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Analysis of Ekin, T (free dynamics)
The atomic velocities of a
protein establish a thermometer,
but is it accurate?
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The atomic
velocity
thermometer
is inaccurate
due to the
finite size of a
protein!
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N
T
3
22
2=!
Another example,
ubiquitin in water bath
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Show BPTI trajectory
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Dihedral Angle
C!Tyr35
Brownian oscillator,
fully characterized by
<angle>, RMSD, C(t)
2
)()0()(
i
ii
A
A
tAAtC =
Langevin dynamics in strong friction limit
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KmolkcalCubiquitinV !"=
#3
)(1024407.2
Specific Heat of a Protein
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Myoglobin is a small, bright red protein. It is very common in muscle cells, and givesmeat much of its red color. Its job is to store oxygen, for use when muscles are hard at
work. If you look at John Kendrew's PDB file, you will notice that the myoglobin that heused was taken from sperm whale muscles. As you can imagine, marine whales anddolphins have a great need for myoglobin, so that they can store extra oxygen for usein their deep dives undersea.
PDB Molecule of the Month: Myoglobin
Myoglobin
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Oxygen Bound to MyoglobinThis structure of myoglobin, with the accession code 1mbo,shows the location of oxygen. The iron atom at the center ofthe heme group holds the oxygen molecule tightly. Compare
the two pictures. The first shows only a set of thin tubes torepresent the protein chain, and the oxygen is easily seen.But when all of the atoms in the protein are shown in thesecond picture, the oxygen disappears, buried inside theprotein.So how does the oxygen get in and out, if it is totally
surrounded by protein? In reality, myoglobin (and all otherproteins) are constantly in motion, performing small flexingand breathing motions. Temporary openings constantlyappear and disappear, allowing oxygen in and out. Thestructure in the PDB is merely one snapshot of the protein,
caught when it is in a tightly-closed form. Looking at thestatic structure held in the PDB, we must imagine thedynamic structure that actually exists in nature.The twopictures above were created with RASMOL. You can createsimilar pictures by accessing the PDB file 1mbo, and then
clicking on "View Structure." Try switching between the twotypes of pictures shown above, to prove to yourself that theoxygen is buried in this structure!
PDB Molecule of the Month: Myoglobin
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John Cowdery Kendrew
Nobel Prize in Chemistry
Jointly with Max Perutz
Myogobin, the first protein with known structure
Struture model at 6 A resolutionDiffraction pattern observed
Higher resolutionModel:
1) Constructelectron densitymap
2) Build model
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Myoglobin with heme group
• Myoglobin from PDBstructure 1A6M
• X-ray crystal structureat 1.00 A resolution.
• Steps seen in RMSDare due primarily totilting of the helix tothe upper right of theheme in the picture…
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Myoglobin Dynamics to Probe Motion of Fe
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Setup andEquilibration
• Remove oxygen liganded to Fe
• Minimize 1000 steps, fixing theC! atoms.
• Heat for 5 ps with Langevindynamics at 300 K, fixed C!
atoms.
• Simulate in NVT ensemble for19 ns, saving coordinates everyps.
short
long
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Obtain “f” from position distribution
• Best fit “by eye” is"=0.528 Å.
• However: standarddeviation gives"=0.36 (f=kT/ "^2)= 319 pN/A; this iswhat we use below.
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Obtain diffusion coefficient fromposition autocorrelation function
Once we know therestoring force, thediffusion coefficientcan be obtained fromthe positionautocorrelationfunction:
D f/kT = .0321D = 0.0042 A2/10 fs = 0.42 A2 /ps.Compare: Dwater = 0.24 A2 /ps
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Position autocorrelation:underdamped case
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Diffusion coefficient from underdamped oscillator
Fitting parameters: # = 0.0426; b = 0.0811; $2=#2 +b2 /4 = 34.59/ps2. D = 0.556 A2 /ps.
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Mossbauer line shape function
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Moessbauer Line Shape Function - Sampledand Matched to Analytical Formula