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Parallel Computational Biochemistry

Parallel Computational Biochemistry. Proteins, DNA, etc. DNA encodes the information necessary to produce proteins. Proteins are the main molecular building blocks of life (for example, structural proteins, enzymes). Proteins, DNA, etc.

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Parallel Computational Biochemistry

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  1. Parallel Computational Biochemistry

  2. Proteins, DNA, etc. DNA encodes the information necessary to produce proteins Proteins are the main molecular building blocks of life (for example, structural proteins, enzymes)

  3. Proteins, DNA, etc. • Proteins are formed from a chain of molecules called amino acids

  4. Proteins, DNA, etc. • The DNA sequence encodes the amino acid sequence that constitutes the protein

  5. Proteins, DNA, etc. • There are twenty amino acids found in proteins, denoted by A, C, D, E, F, G, H, I, ...

  6. Multiple Sequence Alignment

  7. Databases of Biological Sequences NCBI:14,976,310sequences 15,849,921,438 nucleotides >BGAL_SULSO BETA-GALACTOSIDASE Sulfolobus solfataricus. MYSFPNSFRFGWSQAGFQSEMGTPGSEDPNTDWYKWVHDPENMAAGLVSG DLPENGPGYWGNYKTFHDNAQKMGLKIARLNVEWSRIFPNPLPRPQNFDE SKQDVTEVEINENELKRLDEYANKDALNHYREIFKDLKSRGLYFILNMYH WPLPLWLHDPIRVRRGDFTGPSGWLSTRTVYEFARFSAYIAWKFDDLVDE YSTMNEPNVVGGLGYVGVKSGFPPGYLSFELSRRHMYNIIQAHARAYDGI KSVSKKPVGIIYANSSFQPLTDKDMEAVEMAENDNRWWFFDAIIRGEITR GNEKIVRDDLKGRLDWIGVNYYTRTVVKRTEKGYVSLGGYGHGCERNSVS LAGLPTSDFGWEFFPEGLYDVLTKYWNRYHLYMYVTENGIADDADYQRPY YLVSHVYQVHRAINSGADVRGYLHWSLADNYEWASGFSMRFGLLKVDYNT KRLYWRPSALVYREIATNGAITDEIEHLNSVPPVKPLRH Swiss-Prot:104,559sequences 38,460,707 residues PDB: 17,175 structures

  8. Sequence comparison • Compare one sequence (target) to many sequences (database search) • Compare more than two sequences simultaneously

  9. Applications • Phylogenetic analysis • Identification of conserved motifs and domains • Structure prediction

  10. Phylogenetic Analysis

  11. Structure Prediction > RICIN GLYCOSIDASE MYSFPNSFRFGWSQAGFQSEMGTPGSEDPNTDWYKWVHDPENMAAGLVSG DLPENGPGYWGNYKTFHDNAQKMGLKIARLNVEWSRIFPNPLPRPQNFDE SKQDVTEVEINENELKRLDEYANKDALNHYREIFKDLKSRGLYFILNMYH WPLPLWLHDPIRVRRGDFTGPSGWLSTRTVYEFARFSAYIAWKFDDLVDE YSTMNEPNVVGGLGYVGVKSGFPPGYLSFELSRRHMYNIIQAHARAYDGI KSVSKKPVGIIYANSSFQPLTDKDMEAVEMAENDNRWWFFDAIIRGEITR GNEKIVRDDLKGRLDWIGVNYYTRTVVKRTEKGYVSLGGYGHGCERNSVS LAGLPTSDFGWEFFPEGLYDVLTKYWNRYHLYMYVTENGIADDADYQRPY YLVSHVYQVHRAINSGADVRGYLHWSLADNYEWASGFSMRFGLLKVDYNT KRLYWRPSALVYREIATNGAITDEIEHLNSVPPVKPLRH Protein sequences Protein structures Genomic sequences

  12. Clustal W

  13. Human Mouse Drosophila C.elegans S.cerevisiae Progressive Alignment 1. Do pairwise alignment of all sequences and calculate distance matrix Scerevisiae [1] Celegans [2] 0.640 Drosophia [3] 0.634 0.327 Human [4] 0.630 0.408 0.420 Mouse [5] 0.619 0.405 0.469 0.289 2. Create a guide tree based on this pairwise distance mat 3. Align progressively following guide tree. • start by aligning most closely related pairs of sequences • at each step align two sequences or one to an existing subalignment

  14. Parallel pairwise (PW) alignment matrix Parallel guide tree calculation Parallel progressive alignment Human Mouse Drosophila C.elegans S.cerevisiae Parallel Clustal Scerevisiae [1] Celegans [2] 0.640 Drosophia [3] 0.634 0.327 Human [4] 0.630 0.408 0.420 Mouse [5] 0.619 0.405 0.469 0.289

  15. Parallel Clustal - Improvements • Optimization of input parameters • scoring matrices, gap penalties - requires many repetitive Clustal W calculations with various input parameters. • Minimum Vertex Cover • use minimum vertex cover to remove erroneous sequences, and identify clusters of highly similar sequences.

  16. Conflict Graph vertex: sequence edge: conflict (e.g. alignment with very poor score) TASK: remove smallest number of gene sequences that eliminates all conflicts Minimum Vertex Cover

  17. Phase 1: Kernelization Reduce problem to size f(k) Phase 2: Bounded Tree Search Exhausive tree search; exponential in f(k) FPT Algorithms

  18. Kernelization Buss's Algorithm for k-vertex cover • Let G=(V,E) and let S be the subset of vertices with degree k or more. • Remove S and all incident edges G->G’ k -> k'=k-|S|. • IF G' has more than k x k' edges THEN no k-vertex cover exists ELSE start bounded tree search on G'

  19. Bounded Tree Search

  20. Case 1: simple path of length 3 remove selected vertices from G' k' - = 2

  21. Case 2: 3-cycle remove selected vertices from G' k' - = 2

  22. Case 3: simple path of length 2 remove v1, v2 from G' k' - = 1

  23. Case 4: simple path of length 1 remove v, v1 from G' k' - = 1

  24. Depth first search backtrack when k'=0 and G'<>0 ("dead end" )) stop when solution found (G'={}, k'>=0 ) Sequential Tree Search

  25. Basic Idea: Build top log p levels of the search tree (T ') every proc. starts depth-first search at one leaf of T ' randomize depth-first search by selecting random child Parallel Tree Search

  26. Analysis: Balls-in-bins sequential depth-first search path total length:L, #solutions: m expected sequential time (rand. distr.): L/(m+1) parallel search path expected parallel time (rand. distr.): p + L/(p(m+1)) expected speedup: p / (1 + (m+1)/L) if m << L then expected speedup = p

  27. Simulation Experiment L = 1,000,000

  28. Implementation • test platform: • 32 node Beowulf cluster • each node: dual 1.4 GHz Intel Xeon, 512 MB RAM, 60 GB disk • gcc and LAM/MPI on LINUX Redhat 7.2 • code-s: Sequential k-vertex cover • code-p: Parallel k-vertex cover

  29. HPCVL High Performance Computing Virtual Laboratory - HPCVL (www.hpcvl.org) Created by parallel computing researchers from Carleton U. (Comp. Sci.) Queen's (Engineering) Ottawa U. (Life Sci./Hospital) Obtained $30M+ in Federal (CFI) and Ontario (OIT, ORDCF) grants

  30. Test Data • Protein sequences • Same protein from several hundred species • Each protein sequence a few hundred amino acid residues in length • Obtained from the National Center for Biotechnology Information (http://www.ncbi.nlm.nih.gov/)

  31. Test Data • Somatostatin • neuropeptide involved in the regulation of many functions in different organ systems • Clustal Threshold = 10, |V| = 559, |E| = 33652, k = 273, k' = 255

  32. Test Data • WW • small protein domain that binds proline rich sequences in other proteins and is involved in cellular signaling • Clustal Threshold = 10, |V| = 425, |E| = 40182, k = 322, k' = 318

  33. Test Data • Kinase • large family of enzymes involved in cellular regulation • Clustal Threshold = 16, |V| = 647, |E| = 113122, k = 497, k' = 397

  34. Test Data • SH2 (src-homology domain 2) • involved in targeting proteins to specific sites in cells by binding to phosphor-tyrosine • Clustal Threshold = 10, |V| = 730, |E| = 95463, k = 461, k' = 397

  35. Test Data • Thrombin • protease involved in the blood coagulation cascade and promotes blood clotting by converting fibrinogen to fibrin • Clustal Threshold = 15, |V| = 646, |E| = 62731, k = 413, k' = 413

  36. Test Data • PHD (pleckstrin homology domain) • involved in cellular signaling • Clustal Threshold = 10, |V| = 670, |E| = 147054, k = 603, k' = 603

  37. Test Data • Random Graph |V| = 220, |E| = 2155, k = 122, k' = 122 • Grid Graph |V| = 289, |E| = 544, k = 145, k' = 145

  38. Test Data |VC| ~ |V| / 2 k' = k

  39. Sequential Times Kinase, SH2, Thombin: n/a

  40. Code-p on Virtual Proc.

  41. Parallel Times

  42. Speedup: Somatostatin

  43. Speedup: WW

  44. Speedup: Rand. Graph

  45. Speedup: Grid Graph

  46. Thank You! • Questions?

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