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Computational method on biochemistry

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Title: Computational method on biochemistry

1
Computational method on biochemistry

2
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Protein Structure and Dynamics
Bioinformatics
Comparative modeling
Other method

3
Protein structure and dynamics

Time scale in biological phenomena
Newtonian mechanics
Force field
CHARMM
AMBER
Energy minimization
Molecular Dynamics
Example

4
Time scale in biological phenomena
-15
ns
ms
ms
s
ps
fs
hr
5
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6
Force field

??? ???? ? ???? ??-????? ???? ??.
? ?? ??? ??? ???? ?? ???? ???? ?? ????? ?????
???? ??? ??.

7
Newtonian mechanics

Fma
vv0atf(t)
sv0tat2/2g(t)
Emv2/2

?? ???? ??? ??? ??? ??? ??, ???? ???
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Energy minimization
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Energy minimization
??? ???!!
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Molecular Dynamics
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Molecular Dynamics

EtotEpotEkin

15
CHemistry at HARvard Macromolecular Mechanics

CHARMm forcefields
CHARMm, which derives from CHARMM (CHemistry at
HARvard Macromolecular Mechanics), is a highly
flexible molecular mechanics and dynamics program
originally developed in the laboratory of Dr.
Martin Karplus at Harvard University. It was
parameterized on the basis of ab initio energies
and geometries of small organic models.
Applicability
CHARMm performs well over a broad range of
calculations and simulations, including
calculation of geometries, interaction and
conformation energies, local minima, barriers to
rotation, time-dependent dynamic behavior, free
energy, and vibrational frequencies (Momany
Rone, 1992). CHARMm is designed to give good (but
not necessarily "the best") results for a wide
variety of modelled systems, from isolated small
molecules to solvated complexes of large
biological macromolecules however, it is not
applicable to organometallic complexes.

16
Assisted Model Building with Energy Refinement

AMBER forcefield
The standard AMBER forcefield (Weiner et al.
1984, 1986) is parameterized to small organic
constituents of proteins and nucleic acids. Only
experimental data were used in parameterization.
However, AMBER has been widely used not only for
proteins and DNA, but also for many other classes
of models, such as polymers and small molecules.
For the latter classes of models, various authors
have added parameters and extended AMBER in other
ways to suit their calculations. The AMBER
forcefield has also been made specifically
applicable to polysaccharides (Homans 1990, and
see Homans' carbohydrate forcefield).
AMBER is used mainly for modeling proteins and
nucleic acids. It is generally lower in accuracy
and has a limited range of applicability. The use
of AMBER is recommended mainly for those
customers who are familiar with AMBER and have
developed their own AMBER-specific parameters. It
generally gives reasonable results for gas-phase
model geometries, conformational energies,
vibrational frequencies, and solvation free
energies.

17
Application

protein motion
protein folding
enzyme mechanism
model optimization

18
In silico protein folding
1us1,000,000,000 fs(or step) 644 step/sec on 256
CPUs CRAY machine
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Simulation of the travel of potassium
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Bioinformatics

Introduction
Sequence alignment
Pairwise sequence alignment
BLAST
Multiple sequence alignment
CLUSTALW
T-COFFEE
Scoring matrix
Structure Alignment
Example

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Pairwise alignment

Smith-Waterman Algorithm
BLAST local alignment
FASTA global alignment

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Smith-Waterman Algorithm
Align S1ATCTCGTATGATG S2GTCTATCAC
0
0
0
0
0
0
2
1
0
0
2
1
0
2
2
3
4
?1, ?1
5
7
9
8
10
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BLAST

Basic Local Alignment Search Tool
Altschul, S.F., Gish, W., Miller, W.,
Myers, E.W. Lipman, D.J.
Journal of Molecular Biology
v. 215, 1990, pp. 403-410
Used to search sequence databases for local
alignments to a query

25
BLAST algorithm

Keyword search of all words of length w from the
in the query of length n in database of length m
with score above threshold
w 11 for nucleotide queries, 3 for proteins
Do local alignment extension for each found
keyword
Extend result until longest match above threshold
is achieved
Running time O(nm)

26
BLAST algorithm (contd)
keyword
Query KRHRKVLRDNIQGITKPAIRRLARRGGVKRISGLIYEETRGVL
KIFLENVIRD
GVK 18 GAK 16 GIK 16 GGK 14 GLK 13 GNK 12 GRK
11 GEK 11 GDK 11
Neighborhood words
neighborhood score threshold (T 13)
extension
Query 22 VLRDNIQGITKPAIRRLARRGGVKRISGLIYEETRGVLK
60 DN G IR L GK I L E
RGK Sbjct 226 IIKDNGRGFSGKQIRNLNYGIGLKVIADLV-EK
HRGIIK 263
High-scoring Pair (HSP)
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Original BLAST

Dictionary
All words of length w
Alignment
Ungapped extensions until score falls below some
threshold
Output
All local alignments with score gt statistical
threshold

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Original BLAST Example
A C G A A G T A A G G T C
C A G T

w 4
Exact keyword match of GGTC
Extend diagonals with mismatches until score is
under 50
Output result
GTAAGGTCC
GTTAGGTCC

C T G A T C C T G G A T T
G C G A
From lectures by Serafim Batzoglou (Stanford)
29
ClustalW

Popular multiple alignment tool today
Several heuristics to improve accuracy
Sequences are weighted by relatedness
Scoring matrix can be chosen on the fly
Position-specific gap penalties

30
ClustalW (contd)

Often used for protein alignment
W stands for weighted
Different parts of alignment are weighted.
Position/residue specific gap penalties.
Three-step process
1.) Pairwise alignment
2.) Build Guide Tree
3.) Progressive Alignment

31
Step 1 Pairwise Alignment

Aligns each sequence again each other giving a
distance matrix
Distance exact matches / sequence length
(percent identity)

(.17 means 17 identical)
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Step 2 Guide Tree

Create Guide Tree using the distance matrix
ClustalW uses the neighbor-joining method
Guide tree roughly reflects evolutionary relations

33
Step 2 Guide Tree (contd)
S1 S3 S4 S2
Calculates1,3 consensus(s1, s3)s1,3,4
consensus((s1,3),s4)s1,2,3,4
consensus((s1,3,4),s2)
34
Step 3 Progressive Alignment

Align the two most similar sequences
Following the guide tree, add in the next
sequences, aligning to the existing alignment
Insert gaps as necessary

Sample output FOS_RAT
PEEMSVTS-LDLTGGLPEATTPESEEAFTLPLLNDPEPK-PSLEPVKNIS
NMELKAEPFD FOS_MOUSE PEEMSVAS-LDLTGGLPEASTPE
SEEAFTLPLLNDPEPK-PSLEPVKSISNVELKAEPFD FOS_CHICK
SEELAAATALDLG----APSPAAAEEAFALPLMTEAPPAVPPKEPS
G--SGLELKAEPFD FOSB_MOUSE PGPGPLAEVRDLPG-----
STSAKEDGFGWLLPPPPPPP-----------------LPFQ FOSB_HUM
AN PGPGPLAEVRDLPG-----SAPAKEDGFSWLLPPPPPPP---
--------------LPFQ . . .
.. . .
Dots and stars show how well-conserved a column
is.
35
Scoring Matrix

BLOSUM
PAM
PSSM

36
PAM

Percentage of Acceptable point Mutations per 108
years
?? ????? ??? ?????? ?? ? ?? ??? ???? score ??
matrices are based on global alignments of
closely related proteins. The PAM 1 is the matrix
calculated from comparisons of sequences with no
more than 1 divergence. Scores are derived from
a mutation probability matrix where each element
gives the probability of the amino acid in column
X mutating to the amino acid in row Y after a
particular evolutionary time, for example after 1
PAM, or 1 divergence. A PAM matrix is specific
for a particular evolutionary distance, but may
be used to generate matrices for greater
evolutionary distances by multiplying it
repeatedly by itself. However, at large
evolutionary distances the information present in
the matrix is essentially degenerated. It is rare
that a PAM matrix would be used for an
evolutionary distance any greater than 256 PAMs.