Proteins
? 1D 3D
Protein Grammar:
Strict Regularities in Structure-Sequence Relationship
The main rule of protein Sequence – Structure relationship :
The amino acid sequence alone is sufficient to determine a protein's structure.
Christian Anfinsen, 1961
The Nobel Prize in Chemistry 1972
From The Anfinsen rule follows:
1) Protein folding is a physical problem but not biological (?)
Blue Gene is an IBM Research project dedicated to exploring thefrontiers in supercomputing: in computer architecture, in the software required to program and control massively parallel systems, and in the use of computation to advance our understanding of important biological processes such as protein folding
The Blue Gene/L machine has a peak speed of 596 Teraflops
ab initio approach
From The Anfinsen rule follows:
Thus a structure can be determined by analogy with known protein structures of similar sequences.
The idea that sequence similarity translates into structural similarity underlies most modern high-accuracy algorithms of structure prediction
2) it is to be expected that similar sequences would encode similar structures
homology approach
Amino acid Sequences
3D Protein structures
? relationship ?
similar ?
We need to define
similar structures ?
similar sequences ?
similar ?
Fundamental Units of Protein Structure
oxygen
hydrogen atoms
A. alpha-helix B. beta-sheets
Hydrogen bonds form helices - alpha form
and
beta-form
W. Astbury (1930s),
L. Pauling
(1939-1951 )
Similarity of structures ?
The first main rule of Protein structures
Beta Sandwich-like Proteins
two main -sheets packed against each other.
1 2 3 8 9 N…——>…——>…——>……——>…——>…
beta Sandwich-like Proteins
The goal is to find Are any rules in the packing of strands in Sandwich-like structure?
Folding pattern
We analyzed
81 superfamilies and 177 families
~ 8,000 structures.
Stage 1: Collection
All Sandwich Proteins are collected from SCOP and CATH databases.
Part I. Folding pattern of SSS
Stage 2: Structure description
Description of structures in strands: . 5-4-8-9-2 . 6-7-3-1
For over 40 years, researchers have looked at how Secondary structural elements – strands and helices assemble into structure
Secondary structure motif
1 2 3 8 9 N…——>…——>…——>……——>…——>…We introduced a new supersecondary structure unit –”strandon” - a set of the maximum number of consecutive strands, which are connected in the sequential order by hydrogen bonds in 3D structure.
i i +1
Strandon
Supersecondary structure elements
Description of structures in strandons:
IV VI II V III I
Now we suggest to investigate how Supersecondary structure elements - strandons assemble into structure.
(9 1 2 3) (6)
(8 7) (4 5)
I III
IV II
MOTIF
I
II
III
IV
All proteins were described in STRANDON’ notation
Stage 3: SSS classification
supermotif
supermotif motif protein structure
This is the basis of novel hierarchical classification in the Supersecondary structures (SSS) database
I III V I III II VI IV IV II
I III I III VII V II IV II VIII IV VI
I V III III I V VI II IV II IV VI
6 SUPERMOTIFS describe ~ 90% of all sandwich structures.
Stage 4. SSS regularities:
Analysis of all supermotifs in the SSS database led us to the discovery ofdiscovery of
the rule of Supermotifsthe rule of Supermotifs
The Rule of SupermotifsThe Rule of Supermotifs – – Rules of arrangement of strandons strandons in the two main beta sheets.
K=1, N=4 K=4, N=4 K=3, N=6
I III IV II III V I
II IV I III IV II VI
95% of all structures obey the rule of supermotifs.
The rule of supermotifs dramatically restricts the number of permissible
arrangements of strandons.
Analysis of observed arrangements of strands within the strandons leads us to formulate the rule of motifs.
Rule of Motifs
For two neighboring strandons in a sheet, or at the edges of the same side of two beta-sheets, the strands’ numbers in these two strandons will increase in opposite directions.
The Rule of Motifs ( ordering of strands within the strandons )
held true for all strandons in 82% of analyzed protein domains.
In 12 % of the structures the ordering of strands is obeys the Rule of Motifs in all strandons but ONE strandon.
(82 + 12) % domains
Question: How strands come together in structures of Sandwich proteins ?
Answer: Structures of beta-sandwich proteins are governed by well-defined rules:
the Rules of Motifs, and
the Rules of Supermotifs
These rules describe the Folding Patterns
End Part I - Folding patterns
Protein structures similarity definition:
Proteins with the same secondary structure motif and the same orientation of strands in two beta sheets have similar protein structures.
1 2 4
8 7 5 3 8 7 5 3
1 2 4
Sheet A Sheet A
Sheet B Sheet B
Amino acid Sequences
3D Protein structures
? relationship ?
similar
The main problem: How to extract a structure information from the sequence, and how to reconstruct tertiary structure?
Idea:
1) Collect all proteins with similar structures.
2) Find proteins with non-similar sequences (from different protein families.
3) Extract common sequence regularities if exist
Part II - Sequence patterns
Amino acid Sequences
3D Protein structures
? relationship ?
similar
The main problem: How to extract a structure information from the sequence, and how to reconstruct tertiary structure?
Idea:
1) Collect all proteins with similar structures.
2) Find proteins with non-similar sequences (from different protein families.
3) Extract common sequence regularities if exist
Part II - Sequence patterns
non similar
SSS database motif: sheet I: 1 2 5 4
sheet II: 7 6 3
This motif describes proteins from 3 families.
Sequences from different families are strongly dissimilar.
Sequence alignment reveals 1-4% of identical residues.
Alignment 2 sequences:
EMBOSS Needle program Blast program
#1: 1f42 #2: 1oke Identity: 1.9% No significant similarity found
1) Collect all proteins with identical SSS
2) Find proteins with non-similar sequences (from different protein families.
? 3) Extract common sequence regularities if exist
Hypothesis
Proteins with similar structures share a unique set of residues - ‘Structure -determining residues’ - even though they may belong to different protein families and have very low sequence similarities
The problem:
the widely used alignment algorithms - PSI-BLAST, NEEDLE - are not applicable to sequences with very low sequence similarity.
Therefore for comparison of sequences of proteins that share same SSS, we developed a new algorithm of structure-based multi-sequence alignment.
Alignment 2 sequences:
EMBOSS Needle program Blast program
#1: 1f42 #2: 1oke Identity: 1.9% No significant similarity found
The main feature of this algorithm:
Units of alignment are individual strands and loops, rather than whole sequences.
Strands
Alignment of strands in a beta sheet is based on hydrogen bond contacts.
No gaps are allowed within strands.
Loops
Local alignment of each loop separately
With gaps.
New SSS-based multi-sequence alignment algorithm
Structure A a1 a2 a3 a4 a’3 a5 a’1 a6 a7 a8 a’8 a9 a’6 a10 a’5 a11 a’4 Strand 1 Strand 2 Strand 3 b1 b2 b3 b4 b5 b6 b’5 b7 b’3 b8 b’1 b9 b’8 b10 b’7 Structure B Fig. 2
Select the best variant with max numbers of conserved positions (?)
conserved positions (?)
20 amino acids are divided into 2 groups:
Q, E, R,T, Y, P, S, D, G, H, K, N – HYDROPHILIC residues
W, I, A, F, L, C, V, M - HYYDROPHOBIC residues
matching position is conserved if
all (almost) residues in this position belong to one of these groups in all proteins.
601 sequences71,786 sequences
3 protein families
Proteins sheet I: 1 2 5 4
sheet II: 7 6 3
PDB S T R A N D 1 L O O P S T R A N D 2
code chain start end 1 2 3 4 5 6 7 81kcr H 117 218 … S V Y P … … A A A … … L G C L V K …1m7d B 114 213 … S V Y P … … G S S … … L G C L V K …2fbj H 119 220 … T I Y P … … S S D … … I G C L I H …
1ow0 A 242 342 … S L H R … … G S E … … L T C T L T …1fp5 A 336 438 … S A Y L … … K S P … … I T C L V V …
1hxm A 121 206 … S V F V … … N G T … … V A C L V K …1c16 A 181 276 … K A H V … … E G D … … L R C W A L …1svb A 303 395 … T W K R … … S G H … … V V M E V T …1oke A 298 398 … K F K V … … H G T … … I V I R V Q …1f42 A 88 211 … T F L ─ … … S G R … … F T C W W L …
10 representative sequences . for alignment
1) ••• 2) ••• 3) ••• 4) ••• ••• 10) •••
1) [STK] [VILAWF] (4,14)X [GAKSN] [GAS] [TASDEPHR] (0,6)X [LIVF] X [CMI] ...
Strand 1 Loop Strand 2
Set of Structure-determining residues
30 conserved positions:
19 - hydrophilic and 11 - hydrophobic
Question:
Are residues at 30 conserved positions specific and sensitive?
Testing specificity and sensitivity.
Are the residues at conserved positions the SSS-determining residues?
71,786 sequences
How many proteins describes the set of residues at conserved positions in 3 protein families (true positives) and in other proteins (false positives)?
Answer :
EMBOSS/Preg program revealed
304 - true positives (of 601 proteins)
Not good!
0 - false positives
Good!
Refining the definition of SSS-determining residues
1) [STK] [VILAWF] (4,14)X [GAKSN] [GAS] [TASDEPHR] (0,6)X [LIVF] X [CMI] ...2) [STKR] [VLIAWFY] (2,14)X [GAKSNEH] [GAS] [TASDEPHRQ] (0,8)X [LIVFY] X [CMIVLF] ...
Strand 1 Loop Strand 2
1) Find additional residues at the conserved positions: gradually add residues respectively to the hydrophobic and hydrophilic conserved positions and test how a new “extra” residue affects on specificity and sensitivity.
2) Vary the distance between a conserved position in a strand and a conserved position in a loop, and between conserved positions within loops.
Result: EMBOSS/Preg program with the new set of residues revealed:
573 - true positives (of 601 proteins)
0 - false positives
The set of SSS-determining residues with a single mismatch position.
To identify additional true positives any residue is allowed at any single position.
Result: EMBOSS/Preg program with the new set of residues revealed:
additional 18 true positive sequences, and no false positives.
Our analysis found that the remaining 6 sequences have 2 mismatching positions.
Important conclusion: substitution of a hydrophilic for a hydrophobic residue, or vice verse is allowed at just 1-2 conserved positions.
sequence structure . relationship
1) Sequence of amino acids defines 3-D structure;
1-D 3-D
2) Similar 3-D structures have an unique set of structural determinants.
3-D 1-D
Conclusion
Protein sequence-structure relationship is reciprocal.
Acknowledgements
Professor Israel Gelfand, Dr. Yih-Cheng Chiang
Dr. Cyrus ChothiaSSS database
Thank you all.
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