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Combinatorial Protein Design Strategies 1915. Walsh, S. T. R., Cheng, H., Bryson, J. W., Roder, H., and DeGrado, W. F. (1999)Solution structure and dynamics of a denovo designed three-helix bundle protein.Proc. Natl. Acad. Sci. USA 96, 5486–5491.16. Voigt, C. A., Gordon, D. B., and Mayo, S. L. (2000) Trading accuracy for speed:a quantitative comparison of search algorithms in protein sequence design. J.Mol. Biol. 299, 789–803.17. Gordon, D. B. and Mayo, S. L. (1998) Radical performance enhancements forcombinatorial optimization algorithms based on the dead-end elimination theorem.J. Comput. Chem. 19, 1505–1514.18. Gordon, D. B. and Mayo, S. L. (1999) Branch-and terminate: a combinatorialoptimization algorithm for protein design. Struct. Fold. Des. 7, 1089–1098.19. Pierce, N. A., Spriet, J. A., Desmet, J., and Mayo, S. L. (2000) Conformationalsplitting: a more powerful criterion for dead-end elimination. J. Comput. Chem.21, 999–1009.20. Looger, L. L. and Hellinga, H. W. (2001) Generalized dead-end eliminationalgorithms make large-scale protein side-chain structure prediction tractable:implications for protein design and structural genomics. J. Mol. Biol. 307,429–445.21. Dahiyat, B. I. and Mayo, S. L. (1997) De novo protein design: fully automatedsequence selection. Science 278, 82–87.22. Marshall, S. A. and Mayo, S. L. (2001) Achieving stability and conformationalspecificity in designed proteins via binary patterning. J. Mol. Biol. 305,619–631.23. Malakauskas, S. M. and Mayo, S. L. (1998) Design, structure, and stability of ahyperthermophilic protein variant. Nat. Struct. Biol. 5, 470–475.24. Strop, P. and Mayo, S. L. (1999) Rubredoxin variant folds without iron. J. Am.Chem. Soc. 121, 2341–2345.25. Shimaoka, M., Shifman, J. M., Jing, H., Takagi, L., Mayo, S. L., and Springer, T. A.(2000) Computational design of an integrin i domain stabilized in the open highaffinity conformation. Nat. Struct. Biol. 7, 674–678.26. Benson, D. E., Wisz, M. S., Liu, W., and Hellinga, H. W. (1998) Construction ofa novel redox protein by rational design: conversion of a disulfide bridge into amononuclear iron-sulfur center. Biochemistry 37, 7070–7076.27. DeGrado, W. F., Summa, C. M., Pavone, V., Nastri, F., and Lombardi, A. (1999)De novo design and structural characterization of proteins and metalloproteins.Annu. Rev. Biochem. 68, 779–819.28. Bolon, D. N. and Mayo, S. L. (2001) Enzyme-like proteins by computationaldesign. Proc. Natl. Acad. Sci. USA 98, 14,274–14,279.29. Street, A. G. and Mayo, S. L. (1999) Computational protein design. Struct. Fold.Des. 7, R105–R109.30. Saven, J. G. (2001) Designing protein energy landscapes. Chem. Rev. 101,3113–3130.31. Gromiha, M. M., Uedaira, H., An, J., Selvaraj, S., Prabakaran, P., and Sarai, A.(2002) Protherm, thermodynamic database for proteins and mutants: developmentsin version 3.0. Nucleic Acids Res. 30, 301, 302.
20 Kono et al.32. Calhoun, J. R., Kono, H., Lahr, S., Wang, W., DeGrado, W. F., and Saven, J. G.(2003) Computational design and characterization of a monomeric helical dinuclearmetalloprotein. J. Mol. Biol. 334, 1101–1115.33. Slovic, A. M., Kono, H., Lear, J. D., Saven, J. G., and DeGrado, W. F. (2004)Computational design of water-soluble analogues of the potassium channel kcsa.Proc. Natl. Acad. Sci. USA 101, 1828–1833.34. Zou, J. and Saven, J. G. (2003) Using self-consistent fields to bias monte carlomethods with applications to designing and sampling protein sequences. J. Chem.Phys. 118, 3843–3854.35. Park, S., Kono, H., Wang, W., Boder, E. T., and Saven, J. G. (2005) Progress inthe development and application of computational methods for probabilistic proteindesign. Comp. Chem. Eng. 24, 407–421.36. Keefe, A. D. and Szostak, J. W. (2001) Functional proteins from a randomsequencelibrary. Nature 410, 715–718.37. Rojas, N. R. L., Kamtekar, S., Simons, C. T., et al. (1997) De novo heme proteinsfrom designed combinatorial libraries. Protein Sci. 6, 2512–2524.38. Roy, S., Ratnaswamy, G., Boice, J. A., Fairman, R., McLendon, G., and Hecht,M. H. (1997) A protein designed by binary patterning of polar and nonpolaramino acids displays native-like properties. J. Am. Chem. Soc. 119, 5302–5306.39. Roy, S., Helmer, K. J., and Hecht, M. H. (1997) Detecting native-like propertiesin combinatorial libraries of de novo proteins. Fold. Des. 2, 89–92.40. Finucane, M. D., Tuna, M., Lees, J. H., and Woolfson, D. N. (1999) Core-directedprotein design. I. An experimental method for selecting stable proteins from combinatoriallibraries. Biochemistry 38, 11,604, 11,612.41. Xu, G. F., Wang, W. X., Groves, J. T., and Hecht, M. H. (2001) Self-assembledmonolayers from a designed combinatorial library of de novo beta-sheet proteins.Proc. Natl. Acad. Sci. USA 98, 3652–3657.42. Case, M. A. and McLendon, G. L. (2000) A virtual library approach to investigateprotein folding and internal packing. J. Am. Chem. Soc. 122, 8089, 8090.43. Arndt, K. M., Pelletier, J. N., Müller, K. M., Alber, T., Michnick, S. W., andPlückthun, A. (2000) A heterodimeric coiled-coil peptide pair selected in vivofrom a designed library-versus-library ensemble. J. Mol. Biol. 295, 627–639.44. Zhao, H. M. and Arnold, F. H. (1997) Combinatorial protein design: strategies forscreening protein libraries. Curr. Opin. Struct. Biol. 7, 480–485.45. Giver, L. and Arnold, F. H. (1998) Combinatorial protein design by in vitrorecombination. Curr. Opin. Chem. Biol. 2, 335–338.46. Hoess, R. H. (2001) Protein design and phage display. Chem. Rev. 101,3205–3218.47. Moffet, D. A. and Hecht, M. H. (2001) De novo proteins from combinatoriallibraries. Chem. Rev. 101, 3191–3203.48. Holm, L. and Sander, C. (1998) Touring protein fold space with dali/fssp. NucleicAcids Res. 26, 316–319.49. Luthy, R., Bowie, J. U., and Eisenberg, D. (1992) Assessment of protein modelswith 3-dimensional profiles. Nature 356, 83–85.
Page 1 and 2: METHODS IN MOLECULAR BIOLOGY 352Pr
Page 4 and 5: M E T H O D S I N M O L E C U L A R
Page 6 and 7: PrefaceProtein engineering is a fas
Page 8 and 9: ContentsPreface ...................
Page 10 and 11: ContributorsKATJA M. ARNDT • Inst
Page 12: Contributors xiKAZUNARI TAIRA • D
Page 16 and 17: 1Combinatorial Protein Design Strat
Page 18 and 19: Combinatorial Protein Design Strate
Page 36 and 37: 2Global Incorporation of Unnatural
Page 38 and 39: Incorporation of Unnatural Amino Ac
Page 48 and 49: 3Considerations in the Design and O
Page 50 and 51: Design of Coiled Coil Structures 37
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Design of Coiled Coil Structures 69
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4Calcium Indicators Based on Calmod
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Protein-Based Ca 2+ Indicators 73Fi
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Protein-Based Ca 2+ Indicators 7512
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Protein-Based Ca 2+ Indicators 8145
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5Design and Synthesis of Artificial
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Design of Zinc Finger Proteins 853.
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Design of Zinc Finger Proteins 89pr
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Design of Zinc Finger Proteins 91Fi
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96 Koide and Koidewhile retaining t
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98 Koide and Koide5. M9-tryptone: M
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100 Koide and Koidetarget-binding s
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102 Koide and Koide4. Discard the s
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104 Koide and Koideup to 1 mM for h
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106 Koide and Koideplate. Incubate
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108 Koide and Koide1. Perform steps
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7Engineering Site-Specific Endonucl
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Engineering Site-Specific Endonucle
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115Fig. 1. Mapping group-specific r
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8Protein Library Design and Screeni
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Protein Library Design and Screenin
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135Fig. 2. Excel worksheet describi
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137Fig. 4. Excel worksheet describi
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9Protein Design by Binary Patternin
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Protein Design by Binary Patterning
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10Versatile DNA Fragmentation and D
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NExT DNA Shuffling 169This chapter
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NExT DNA Shuffling 1713. Methods3.1
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NExT DNA Shuffling 17372°C, 4 min.
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NExT DNA Shuffling 175Fig. 2. Varia
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NExT DNA Shuffling 1773.5.1. Direct
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NExT DNA Shuffling 179Fig. 3. Reass
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181
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NExT DNA Shuffling 183likelihood of
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NExT DNA Shuffling 1853.9.2. Calibr
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NExT DNA Shuffling 187staining. Bec
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NExT DNA Shuffling 1894. Zhao, H.,
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11Degenerate Oligonucleotide Gene S
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Degenerate Oligonucleotide Gene Shu
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12M13 Bacteriophage Coat Proteins E
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Engineered M13 Bacteriophage Coat P
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222 Fujita et al.The methods that h
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224 Fujita et al.3. Streptavidin an
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226 Fujita et al.Fig. 2. (Continued
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228 Fujita et al.Fig. 3. (Continued
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230 Fujita et al.Fig. 3. (A) Schema
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232 Fujita et al.1. Add 2 µg mRNA
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234 Fujita et al.Innovative Bioscie
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236 Fujita et al.30. Kim, Y., Mlsa,
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238 Ghadessy and Holligeraffinity m
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240 Ghadessy and HolligerFig. 1. (A
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242 Ghadessy and HolligerFinally, t
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244 Ghadessy and Holliger2. Prepare
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246 Ghadessy and Holliger2. After 6
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248 Ghadessy and Holliger21. Oberho
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250 Campbell-Valois and Michnickscr
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252 Campbell-Valois and Michnickfol
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254 Campbell-Valois and Michnick7.
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256 Campbell-Valois and MichnickFig
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258 Campbell-Valois and Michnickres
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260Fig. 3. BL21 pREP4 cells were co
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262 Campbell-Valois and MichnickFig
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264 Campbell-Valois and Michnickvar
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276 Hecky et al.improved half-life
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278 Hecky et al.Fig. 1. (A) Scheme
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280 Hecky et al.11. Reverse primer
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282 Hecky et al.high variability in
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284 Hecky et al.coding sequence for
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286 Hecky et al.4. Analyze the resu
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Table 1Amino Acid Substitutions Sel
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290 Hecky et al.Fig. 4. Structure o
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292 Hecky et al.Fig. 5. Expression
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294 Hecky et al.Table 2Kinetic Para
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296 Hecky et al.The thermoactivity
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298 Hecky et al.Fig. 8. Unfolding o
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300 Hecky et al.for the first trans
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302 Hecky et al.7. Thompson, M. J.
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304 Hecky et al.40. Wang, X., Minas
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306 IndexCCalcium indicators, see C
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308 Indexchemiocompetent cellprepar
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310 Indexmaterials, 169, 170mutatio
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312 IndexTerminal truncation, see a
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