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Pharm 201 Lecture 10, 20091 Reductionism and Classification Require Detailed Comparison Consider 3D Comparison Pharm 201/Bioinformatics I Philip E. Bourne.

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Presentation on theme: "Pharm 201 Lecture 10, 20091 Reductionism and Classification Require Detailed Comparison Consider 3D Comparison Pharm 201/Bioinformatics I Philip E. Bourne."— Presentation transcript:

1 Pharm 201 Lecture 10, 20091 Reductionism and Classification Require Detailed Comparison Consider 3D Comparison Pharm 201/Bioinformatics I Philip E. Bourne Department of Pharmacology, UCSD Reading Chapter 16, Structural Bioinformatics

2 Pharm 201 Lecture 10, 20092 Consider this Course a Workflow Data InUnderstand the scope and complexity of the data Understand the experiment to understand the errors Understand how to best represent (model) the data Understand the methods to physically instantiate the model From initial analysis understand how to control data in Recognize redundancy In the data Classify the dataVisualize the data Analyze the data

3 Pharm 201 Lecture 10, 20093 From Last Time We established the complex relationship between: –Sequence and Structure –Structure and Structure –Structure and Function Today we analyze how the relationships between structure and structure are established

4 Pharm 201 Lecture 10, 20094 Agenda Understand why structure comparison is important Understand why it is not a solved problem Understand the basics of the methods used to address the problem Understand one method (CE) in more detail Review an example where structure comparison has revealed new biological insights

5 Pharm 201 Lecture 10, 20095 Why Structure Comparison is Important Reductionism – needed to classify protein structures Functional assignment and hopefully new biology Alignment of predicted structure against structural templates Establish improved sequence relationships not possible from sequence alone Protein engineering

6 Pharm 201 Lecture 10, 20096 Distinctions - Structure Superposition and Structure Comparison and Alignment are Different Structure superposition assumes you already know which atoms to superimpose – it merely optimizes for the atoms chosen (relatively simple) Structure alignment must first determine what atoms to align (difficult). We are concerned with alignment

7 Pharm 201 Lecture 10, 20097 Distinctions – Pair-wise Alignments are Different from Multiple Structure Alignments Multiple structure alignment algorithms are rare and of questionable quality (see for example Nucleic Acids Research (2004), 32 W100-W103 Multiple structure alignments should not be confused with multiple pair-wise alignments Here we focus on single pair-wise comparison and alignment

8 Pharm 201 Lecture 10, 20098 Why is it Not a Solved Problem?

9 Pharm 201 Lecture 10, 20099 Current State of the Art There are many papers published on this, but relatively few have code to download or Web sites from which to perform comparisons All methods can identify obvious similarities between two structures Remote similarities are detected by a subset of methods – different remote similarities are recognized by different methods Good alignments are much harder to come by Speed is a serious issue with some algorithms

10 Pharm 201 Lecture 10, 200910 Desirables Biologically meaningful alignments not just geometrically meaningful Complete database of all alignments Ability to apply to structures not in the PDB

11 Pharm 201 Lecture 10, 200911 Maintain 9 of 10 interactions RMSD 1.5 Å Maintain 5 of 10 interactions RMSD 0.5 Å Biological vs Geometric Alignments Plastocyanin versus Azurin (from Godzik 1996)

12 Pharm 201 Lecture 10, 200912 Literature Alignments - Flavodoxin vs Che Y Protein From Godzik (1996) Protein Science, 5, 1325-1338.

13 Pharm 201 Lecture 10, 200913 Understand the basics of the methods used to address the problem

14 Pharm 201 Lecture 10, 2009 14 See also http://en.wikipedia.org/wiki/Structural_alignment_software

15 Pharm 201 Lecture 10, 200915 How to Compare Structures? Structure 1 Structure 2 Feature extraction Structure description 1Structure description 2 Comparison algorithm Scores Statistical significance Similarity, classification 1. 2. 3.

16 Pharm 201 Lecture 10, 200916 Components of Structure Alignment 1.Structure Description Local geometry Side chain contacts Geometric hashing Distance matrix (Dali, 1993) Properties (secondary structure, hydrophobic clusters (Comparer, 1990) Secondary structure elements (VAST, 1996) Distances of inter & intra aligned fragment pairs (CE, 1998) Contact map (Celera, 2004) Geometry invariants (Jia et al, 2004)

17 Pharm 201 Lecture 10, 200917 Components of Structure Alignment 2. Alignment algorithms –Monte Carlo (Dali, VAST) – Heuristics (CE) – Dynamic Programming (CE) – Probabilistic 3.Statistical significance

18 Components of Structure Alignment 2. Alignment algorithms  Dynamic programming, Integer programming, Monte Carlo… 3. Statistical significance  Levitt and Gerstein, PNAS, 1998  Random Model and CE scoring function (Jia et al, 2004)  Input & output of alignment algorithm Input: two proteins: and Output: An alignment and scores Constraints: min rmsd: max L min Gaps: 18

19 Pharm 201 Lecture 10, 200919 Understand one method (CE) in more detail I.N. Shindyalov and P.E. Bourne Protein Engineering 1998, 11(9) 739-747. Protein Structure Alignment by Incremental Combinatorial Extension of the Optimum Path. [PDF File] 793 citations![PDF File]

20 Pharm 201 Lecture 10, 200920 Basic Approach Compare octameric fragments – an aligned fragment pair (AFP) (local alignments) Stitch together AFPs Find the optimal path through the AFPs Optimize the alignment through dynamic programming Measure the statistical significance of the alignment

21 Pharm 201 Lecture 10, 200921 Why This Approach? Alignment Space is Very Large and Must be Constrained Without Loosing Meaningful Alignments Similarity Matrix S where: S=(n A -m).(n B -m) m = Length of AFP n A = Length of protein A This is very large to compute – constraints are needed

22 Pharm 201 Lecture 10, 200922

23 Pharm 201 Lecture 10, 200923 Definition of the Alignment Path p A i = AFPs starting residue position in protein A at the ith position of the alignment path m = longest continual path – set as 8 One of the conditions (1)-(3) should be satisfied for 2 consecutive AFPs i and i+1 in the path (1)= 2 consecutive AFPs aligned without gaps (2)= Two consecutive AFPs with a gap in protein A (3)= Two consecutive AFPs with a gap in protein B

24 Pharm 201 Lecture 10, 200924 Extension of the Alignment Path Gap sizes are limited to G – heuristically set as 30 residues

25 Pharm 201 Lecture 10, 200925 1. Distance calculated from independent set of inter-residue distances where each distance is used only once - used for combinations of 2 AFPs 2. Full set of inter-residue distances - used for a single AFP 3. RMSD from least squares superposition - used to select few best fragments Evaluation based upon the following three distance similarity measures

26 Pharm 201 Lecture 10, 200926 1. Distance calculated from independent set of inter-residue distances where each distance is used only once 2. Full set of inter-residue distances 3. RMSD from least squares superposition Evaluation Based Upon the Following Three Distance Similarity Measures

27 Pharm 201 Lecture 10, 200927 How to Extend the Path? 1. Consider all possible AFPs that extend the path 2. Consider only the best AFP 3. Use some intermediate strategy

28 Pharm 201 Lecture 10, 200928 How to Extend the Path? 1. Consider all possible AFPs that extend the path Computationally expensive 2. Consider only the best AFP Works well with the right heuristics 3. Use some intermediate strategy

29 Pharm 201 Lecture 10, 200929 What Heuristics? Candidate AFPs are based upon (9) D 0 = 3Å The best AFP is based upon (10) D 1 = 4Å The decision to extend or terminate the path is based upon (11)

30 Pharm 201 Lecture 10, 200930 Z-Score Evaluate the probability of finding an alignment path of the same length or smaller gaps and distance from a random set of non-redundant structures

31 Pharm 201 Lecture 10, 200931 The 20 best alignments with a Z score above 3.5 are assessed based on RMSD and the best kept. This produces approx. one error in 1000 structures Each gap in this alignment is assessed for relocation up to m/2 Iterative optimization using dynamic programming is performed using residues for the superimposed structures Optimization of the Final Path

32 Pharm 201 Lecture 10, 200932 Test Case: Phycocyanin versus Colicin A

33 Pharm 201 Lecture 10, 200933 Cyclin-dependent kinases Open (purple) Closed (blue) Pavelitch et al. (1997)

34 Pharm 201 Lecture 10, 200934 Limitations Will not find non- topological alignments (outside the bounds of the dotted lines) What are the correct “units” to be comparing? CE works on chains – as we shall see in future weeks domains are the correct units, but definition of the domains is not straightforward

35 Pharm 201 Lecture 10, 200935 Took 11,748 chain in the PDB (1/98) Computed for 1868 representatives 24,000 Cray T3E processor hours Loaded pairwise alignments into database Computation of All x All

36 Pharm 201 Lecture 10, 200936 1-2 Years Ago 40,000 proteins ~ 70,000 chains 70,000 2 /2 * 30 seconds = 2330 yrs Options: –Use a redundant set of chains –Use parallel architectures D. Pekurovsky, I.N. Shindyalov, P.E. Bourne 2004 High Throughput Biological Data Processing on Massively Parallel Computers. A Case Study of Pairwise Structure Comparison and Alignment Using the Combinatorial Extension (CE) Algorithm. Bioinformatics, 20(12) 1940-1947 [PDF].[PDF].

37 Now Using egrid to compute all by all for CE and FatCat Pharm 201 Lecture 10, 200937

38 Pharm 201 Lecture 10, 200938 One Criteria for Redundancy Remove highly homologous chains; The RMSD between two chains is less than 2Å; The length difference between two chains is less than 10%; The number of gap positions in alignment between two chains is less than 20% of aligned residue positions; At least 2/3 of the residue positions in the represented chain are aligned with the representing chain.

39 Pharm 201 Lecture 10, 200939 Review example where structure comparison has revealed new biological insights

40 Pharm 201 Lecture 10, 200940 Example CE revealed putative Ca++ binding domain in acetylcholinesterase Sequence similarity to neuroligins predicts Ca++ binding too – confirmed experimentally Members of the a/b hydrolase family bind Ca++ which may be important for heterologous cell associations Structural similarity between Acetylcholinesterase and Calmodulin found using CE (Tsigelny et al, Prot Sci, 2000, 9:180)

41 Pharm 201 Lecture 10, 200941 The Future (also a general rule) Gold standards are important For structure comparison a human generated alignment standard is important Algorithms are then challenged to meet the standard Eventually those algorithms highlight problems with the standard The cycle continues


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