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2 Fold Recognition 53Berman HM, Westbrook J, Feng Z, et al. (2000) The protein data bank. Nucleic Acids Res28:235–242Bowie JU, Lüthy R, Eisenberg D (1991) A method to identify protein sequences that fold into aknown three-dimensional structure. Science 253:164–170Bradford JR, Westhead DR (2005) Improved prediction of protein-protein binding sites using asupport vector machines approach. Bioinformatics 21:1487–1494Bryant SH (1996) Evaluation of threading specificity and accuracy. Proteins 26(2): 172–185Busuttil S, Abela J, and Pace GJ (2004) Support vector machines with profile-based kernels forremote protein homology detection. Genome Inform Ser Workshop Genome Inform15:191–200Chivian D, Baker D (2006) Homology modeling using parametric alignment ensemble generationwith consensus and energy-based model selection. Nucleic Acids Res 34:e112Copley RR, Bork P (2000) Homology among (beta/alpha)(8) barrels: implications for the evolutionof metabolic pathways. J Mol Biol 303:627–641Dodson G, Wlodawer A (1998) Catalytic triads and their relatives. Trends Biochem Sci23:347–352Elofsson A (2002) A study on protein sequence alignment quality. Proteins 46:330–339Fisher D (2003) 3D-SHOTGUN: a novel, cooperative, fold-recognition meta-predictor. Proteins51:434–441Garg A, Bhasin M, Raghava GP (2005) Support vector machine-based method for subcellularlocalization of human proteins using amino acid compositions, their order and similaritysearch. J Biol Chem 280:14427–14432Ginalski K, Elofsson A, Fischer D, et al. (2003) 3D-Jury: a simple approach to improve proteinstructure predictions. Bioinformatics 19:1015–1018Heger A, Mallick S, Wilton C, et al. (2008) The global trace graph, a novel paradigm for searchingprotein sequence databases. Bioinformatics 23:2361–2367Hou Y, Hsu W, Lee ML, et al. (2003) Efficient remote homology detection using local structure.Bioinformatics 19:2294–2301.Jaakkola T, Diekhans M, Haussler D (2000) A discriminative framework for detecting remoteprotein homologies. J Comput Biol 7:95–114Jain AK, Duin RPW, Mao JC (2000) Statistical pattern recognition: A review. IEEE Trans PatternAnal 22:4–37Jaroszewski L, Li W, Godzik A (2002) In search for more accurate alignments in the twilight zone.Prot Sci 11:1702–1713Jones DT (1999a) Protein secondary structure prediction based on position-specific scoring matrices.J Mol Biol 292:195–202.Jones DT (1999b) GenTHREADER: an efficient and reliable protein fold recognition method forgenomic sequences. J Mol Biol 287:797–815Jones DT, Taylor WR, Thornton JM (1992) A new approach to protein fold recognition. Nature358:86–89Kabsch W, Sander C (1983) Dictionary of protein secondary structure: pattern recognition ofhydrogen-bonded and geometrical features. Biopolymers 22:2577–2637Kelley LA, MacCallum RM, Sternberg MJ (2000) Enhanced genome annotation using structuralprofiles in the program 3D-PSSM. J Mol Biol 299:499–520Kim H, Park H (2003) Prediction of protein relative solvent accessibility with support vectormachines and long-range interaction 3D local descriptor. Proteins 54:557–562Kumar M, Bhasin M, Natt NK, et al. (2005) BhairPred: prediction of beta-hairpins in a proteinfrom multiple alignment information using ANN and SVM techniques. Nucleic Acids Res33(Web Server issue):154–159Kuncheva LI, Whitaker CJ (2003) Measures of diversity in classifier ensembles and their relationshipwith the ensemble accuracy. Mach Learn 51:181–207Lathrop RH (1999) An anytime local-to-global optimization algorithm for protein threading intheta (m2n2) space. J Comput Biol 6(3–4):405–418
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Daniel John RigdenEditorFrom Protei
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ContentsSection I Generating and In
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Contentsxi4.2.1 Alpha-Helical Bundl
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Contentsxiii7.4.2 Predicting Bindin
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Page 16 and 17: 4 J. Lee et al.about 5.3 million pr
Page 18 and 19: 6 J. Lee et al.Table 1.1 A list of
Page 20 and 21: 8 J. Lee et al.2000; Sorin and Pand
Page 22 and 23: 10 J. Lee et al.Although most knowl
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Page 28 and 29: 16 J. Lee et al.1.3.4 Mathematical
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Page 34 and 35: 22 J. Lee et al.Hsieh MJ, Luo R (20
Page 36 and 37: 24 J. Lee et al.Sippl MJ (1990) Cal
Page 38 and 39: Chapter 2Fold RecognitionLawrence A
Page 40 and 41: 2 Fold Recognition 29It has long be
Page 42 and 43: 2 Fold Recognition 31Fig. 2.2 Graph
Page 44 and 45: 2 Fold Recognition 33distribute the
Page 46 and 47: 2 Fold Recognition 35Table 2.1 (a)
Page 48 and 49: 2 Fold Recognition 37dependent on t
Page 50 and 51: 2 Fold Recognition 39based on the r
Page 52 and 53: 2 Fold Recognition 41The idea of co
Page 54 and 55: 2 Fold Recognition 43query sequence
Page 56 and 57: 2 Fold Recognition 452.3.4 Consensu
Page 58 and 59: 2 Fold Recognition 472.4 Alignment
Page 60 and 61: 2 Fold Recognition 49statistical me
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Page 66 and 67: 2 Fold Recognition 55Tress ML, Jone
Page 68 and 69: 58 A. Fiserwith more than 50% seque
Page 70 and 71: 60 A. FiserIn contrast to ab initio
Page 72 and 73: 62 A. FiserTable 3.1 (continued)SWI
Page 74 and 75: 64 A. Fiserbetween fold recognition
Page 76 and 77: 66 A. FiserFig. 3.1 Comparing accur
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Page 88 and 89: 78 A. FiserA rigorous statistical e
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Page 92 and 93: 82 A. FiserImproved and new methods
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104 T. Nugent and D.T. JonesFig. 4.
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106 T. Nugent and D.T. Jonessubdivi
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108 T. Nugent and D.T. Jonescomplex
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110 T. Nugent and D.T. JonesMartell
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Chapter 5Bioinformatics Approaches
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5 Structure and Function of Intrins
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Chapter 6Function Diversity Within
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6 Function Diversity Within Folds a
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Chapter 7Predicting Protein Functio
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7 Predicting Protein Function from
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Table 7.1 Online resources and tool
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Chapter 83D MotifsElaine C. Meng, B
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8 3D Motifs 189clustering similar s
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8 3D Motifs 191To improve the signa
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8 3D Motifs 193structures together.
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8 3D Motifs 195Table 8.1 (continued
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8 3D Motifs 1978.3.1 User-Defined M
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8 3D Motifs 199Fig. 8.3 The FFF mot
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8 3D Motifs 2018.3.2 Motif Discover
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8 3D Motifs 203In addition to SITE
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8 3D Motifs 205folds; they shared a
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8 3D Motifs 207from a training set
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8 3D Motifs 209Table 8.3 Web server
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8 3D Motifs 211its greater overall
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8 3D Motifs 213Ideally, a 3D motif
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8 3D Motifs 215Ivanisenko VA, Pintu
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Chapter 9Protein Dynamics: From Str
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9 Protein Dynamics: From Structure
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252 R.A. LaskowskiConsequently, man
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254 R.A. Laskowskiucla.edu, and Pro
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256 R.A. LaskowskiFig. 10.2 Gene On
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258 R.A. Laskowski10.2.5 Protein In
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260 R.A. LaskowskiFig. 10.4 Schemat
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262 R.A. Laskowskiaccessibility and
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264 R.A. LaskowskiFig. 10.6 A ligan
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266 R.A. LaskowskiGly97Gly99Tyr98Ty
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268 R.A. LaskowskiFig. 10.8 Example
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270 R.A. LaskowskiReferencesAltschu
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272 R.A. LaskowskiXenarios I, Salwi
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274 J.D. Watson and J.M. ThorntonTh
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276 J.D. Watson and J.M. ThorntonTa
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278 J.D. Watson and J.M. Thorntonva
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280 J.D. Watson and J.M. Thorntonfo
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282 J.D. Watson and J.M. Thorntonin
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284 J.D. Watson and J.M. Thorntonan
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286 J.D. Watson and J.M. ThorntonFi
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288 J.D. Watson and J.M. ThorntonPD
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290 J.D. Watson and J.M. ThorntonKi
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Chapter 12Prediction of Protein Fun
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12 Prediction of Protein Function f
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320 IndexConsensus templates, 205Co
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322 IndexLigand-binding templates,
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324 IndexStructure-function linkage
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