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86 A. FiserHavel TF, Snow ME (1991) A new method for building protein conformations from sequencealignments with homologues of known structure. J Mol Biol 217:1–7Henikoff JG, Pietrokovski S, McCallum CM, et al. (2000) Blocks-based methods for detectingprotein homology. Electrophoresis 21:1700–1706Henikoff S, Henikoff JG (1992) Amino acid substitution matrices from protein blocks. Proc NatlAcad Sci USA 89:10915–10919.Holm L, Sander C (1991) Database algorithm for generating protein backbone and side-chain coordinatesfrom a C alpha trace application to model building and detection of co-ordinateerrors. J Mol Biol 218:183–194Hooft RW, Vriend G, Sander C, et al. (1996) Errors in protein structures. Nature 381:272Jacobson MP, Pincus DL, Rapp CS, et al. (2004) A hierarchical approach to all-atom protein loopprediction. Proteins 55:351–367Jaroszewski L, Rychlewski L, Zhang B, et al. (1998) Fold prediction by a hierarchy of sequence,threading, and modeling methods. Protein Sci 7:1431–1440Jaroszewski L, Rychlewski L, Godzik A (2000) Improving the quality of twilight-zone alignments.Protein Sci 9:1487–1496Jaroszewski L, Rychlewski L, Li Z, et al. (2005) FFAS03: a server for profile–profile sequencealignments. Nucleic Acids Res 33:W284–288Jauch R, Yeo HC, Kolatkar PR, et al. (2007) Assessment of CASP7 structure predictions for templatefree targets. Proteins 69(Suppl 8):57–67Jennings AJ, Edge CM, Sternberg MJ (2001) An approach to improving multiple alignments ofprotein sequences using predicted secondary structure. Protein Eng 14:227–231John B, Sali A (2003) Comparative protein structure modeling by iterative alignment, modelbuilding and model assessment. Nucleic Acids Res 31:3982–3992John B, Sali A (2004) Detection of homologous proteins by an intermediate sequence search.Protein Sci 13:54–62Johnson LN, Lowe ED, Noble ME, et al. (1998) The Eleventh Datta Lecture. The structural basisfor substrate recognition and control by protein kinases. FEBS Lett 430:1–11Jones DT (1999) GenTHREADER: an efficient and reliable protein fold recognition method forgenomic sequences. J Mol Biol 287:797–815Jones TA, Thirup S (1986) Using known substructures in protein model building and crystallography.EMBO J 5:819–822Karchin R, Cline M, Mandel-Gutfreund Y, et al. (2003) Hidden Markov models that use predictedlocal structure for fold recognition: alphabets of backbone geometry. Proteins51:504–514Karplus K, Barrett C, Hughey R (1998) Hidden Markov models for detecting remote proteinhomologies. Bioinformatics 14:846–856Karplus K, Katzman S, Shackleford G, et al. (2005) SAM-T04: what is new in protein-structureprediction for CASP6. Proteins 61(Suppl 7):135–142Kihara D, Skolnick J (2003) The PDB is a covering set of small protein structures. J Mol Biol334:793–802Kiselar JG, Janmey PA, Almo SC, et al. (2003) Structural analysis of gelsolin using synchrotronprotein footprinting. Mol Cell Proteomics 2:1120–1132Koehl P, Delarue M (1995) A self consistent mean field approach to simultaneous gap closure andside-chain positioning in homology modelling. Nat Struct Biol 2:163–170Kolinski A, Bujnicki JM (2005) Generalized protein structure prediction based on combinationof fold-recognition with de novo folding and evaluation of models. Proteins 61(Suppl7):84–90Kolinski A, Betancourt MR, Kihara D, et al. (2001) Generalized comparative modeling(GENECOMP): a combination of sequence comparison, threading, and lattice modeling forprotein structure prediction and refinement. Proteins 44:133–149Kopp J, Schwede T (2006) The SWISS-MODEL Repository: new features and functionalities.Nucleic Acids Res 34:D315–318
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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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Contentsxv12.3 Accuracy and Added V
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4 J. Lee et al.about 5.3 million pr
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6 J. Lee et al.Table 1.1 A list of
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8 J. Lee et al.2000; Sorin and Pand
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10 J. Lee et al.Although most knowl
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12 J. Lee et al.Fig. 1.3 Two exampl
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14 J. Lee et al.rugged containing m
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16 J. Lee et al.1.3.4 Mathematical
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18 J. Lee et al.potentials, each re
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20 J. Lee et al.viewpoint of struct
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22 J. Lee et al.Hsieh MJ, Luo R (20
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24 J. Lee et al.Sippl MJ (1990) Cal
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Chapter 2Fold RecognitionLawrence A
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2 Fold Recognition 29It has long be
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2 Fold Recognition 31Fig. 2.2 Graph
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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 64 and 65: 2 Fold Recognition 53Berman HM, Wes
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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
Page 78 and 79: 68 A. Fiserinto conserved core regi
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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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Page 122 and 123: Chapter 5Bioinformatics Approaches
Page 124 and 125: 5 Structure and Function of Intrins
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5 Structure and Function of Intrins
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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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