Doug Raiford Lesson 17. Framework model Secondary structure first Assemble secondary structure...

Doug RaifordLesson 17

Framework model Secondary structure

first Assemble secondary

structure segments Hydrophobic

collapse Molten: compact but

denatured Formation of

secondary structure after: settles in

van der Waals forces and hydrogen bonds require close proximity

04/21/23 2Protein Conformation Prediction (Part I)

Isolate protein and crystalize Time consuming process Slowly evaporate Many experiments in parallel Different conditions

X-ray crystallographyGet XYZ spatial coordinates

04/21/23 Protein Conformation Prediction (Part I) 3

Store these XYZ coordinates in text files

PDB website


X Y Z Occu Temp ElementATOM 1 N THR A 5 23.200 72.500 13.648 1.00 51.07 N ATOM 2 CA THR A 5 23.930 72.550 12.350 1.00 51.27 C ATOM 3 C THR A 5 23.034 72.048 11.220 1.00 50.34 C ATOM 4 O THR A 5 22.819 72.747 10.228 1.00 51.19 O ATOM 5 CB THR A 5 25.221 71.703 12.416 1.00 51.94 C ATOM 6 OG1 THR A 5 26.159 72.326 13.305 1.00 53.51 O ATOM 7 CG2 THR A 5 25.849 71.583 11.046 1.00 53.33 C

To fully model the folding action of a polypeptide chain Must know all the forces

acting on each aa Must be able to predict

the motion of the aa’s given the forces


Recall that proteins are able to fold because of the torsional rotation of the aa bonds


almost always 180

Must be able to take phi and psi angles and transform into xyz coordinates of various atoms

Don’t forget about R groupsWhat places in space are occupied?

Bump checking


Tetrahedron



almost always 180

Know distancesEach angle is 109.5


4 atoms on same plane, , and ω all relative to R group (O

in case of ω)

One approach Given xyz of last three,

and next torsion angle… Transform so that C is at

origin, BC on new X, AB on plane of new Y

Then apply torsion Start D on X Swing out 70.5

(180-109.5; in the plane of Y)

Rotate by torsion angle04/21/23 11Protein Conformation Prediction (Part I)

To transform a vector space…


X

Y

Z

A

B

C

To transform a vector space…


X

Y

Z

A

B

C

New X axisNew Y axis

New Z axis

It’s all about projections If target vector is a unit vector then

simple dot product


A

B

Dot product of a row with vector yields the projection of the vector onto the vector represented by the row

All three dot products yields all three components


X

Y

Z

A

B

C

New XNew Y

New Z

The new X is BC (as a unit vector)


X’

Y’

Z’

A

B

C

Remember, all we have is the last xyz coordinates

All vectors are assumed to originate at the origin

So BC is actually [XC,YC,ZC]-[XB,YB,ZB]


B

C

Origin

Magnitude of BC


X’

Y’

Z’

A

B

C

First row of transformation matrix


X

Y

Z

A

B

C

New X

AB in plane of new Y so Z component is zero


X

Y

Z

A

B

C

Important piece: Y component

Second row of transformation matrix


X

Y

Z

A

B

C

New Y

Third row of transformation matrix easy once have first two: Cross Product


X

Y

Z

A

B

C

New Y

Know distance to next atomKnow angle is 70.5° (180-109.5)

X component = ||CD|| cos(70.5°) Y component starts out at

||CD|| sin(70.5°)This is the distance from

X to the new D


X

Y

Z

A

B

C

D

Z component is that distance times sinθ (torsion angle) Y = ||CD|| sin(70.5°)*cos θ Z = ||CD|| sin(70.5°)*sin θ


Z

Y

C

Dnew in plane of xy

YC Dnew in

plane of xy

X

Dfinal

Θ (torsional angle)

70.5°

Transform next xyz into new vector space coordinates (same as before

Determine ||CD||


X

Y

Z

A

B

C

D

XYZ coordinates for an amino acid Build the linear transform matrix

used to transform the original vector space into the space defined by the three atoms above.


Atom X Y ZN 2.863 -15.219 -0.703C 3.920 -14.209 -0.705C 5.265 -14.836 -1.065

BC?


Atom X Y Z A N 2.863 -15.219 -0.703 B C 3.920 -14.209 -0.705 C C 5.265 -14.836 -1.065

X

Y

Z

A

B

C

[XC,YC,ZC]-[XB,YB,ZB]

[5.265 -14.836 -1.065]-[3.920 -14.209 -0.705]

[1.345 -0.627 -0.36]

Magnitude of BC?

distance B to C: 1.527

New X axis:[0.880 -0.410 -0.236]

Calculator makes life easier:

[2.863,-15.219,-0.703] sto A[3.920,-14.209,-0.705] sto B[5.265,-14.836,-1.065] sto CunitV (C-B)

unitV under “VECTR / MATH”

Calculator makes life easier:

[2.863,-15.219,-0.703] sto A[3.920,-14.209,-0.705] sto B[5.265,-14.836,-1.065] sto CunitV (C-B)


Actually forgot a stepNeed to translate all three pointsMove in direction of negative CWill place C and origin and

keep A and B relative to C


X

Y

Z

A

B

C

No change to X

CalculatorA-C sto AB-C sto BC-C sto CB-A sto ABC-B sto BC

unitV BC (same answer)


CalculatorA-C sto AB-C sto BC-C sto CB-A sto ABC-B sto BC

unitV BC (same answer)


New Y?


X

Y

Z

A

B

C

New Y axis:[0.440 0.894 0.088]

Calculator

unitV(AB-(dot(AB,BC)/(norm BC)2 * BC))

Norm under “VECTR / MATH”

Calculator

unitV(AB-(dot(AB,BC)/(norm BC)2 * BC))

Norm under “VECTR / MATH”

New Z?


X

Y

Z

A

B

C

New Z axis:[0.174 -0.181 0.968]

CalculatorunitV BC enter sto XunitV(AB-(dot(AB,BC)/(norm BC)2 * BC)) enter sto Ycross(X,Y)

Cross under “VECTR / MATH”

CalculatorunitV BC enter sto XunitV(AB-(dot(AB,BC)/(norm BC)2 * BC)) enter sto Ycross(X,Y)

Cross under “VECTR / MATH”

De novo From first principles

Comparative/Homology Based Sequence similarity


Doug Raiford Lesson 17. Framework model Secondary structure first Assemble secondary structure...

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