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20 Roque and Lowe 71. Bhikhabhai, R., Sjoberg, A., Hedkvist, L., Galin, M., Liljedahl, P., Frigard, T., Pettersson, N., Nilsson, M., Sigrell-Simon, J.A. and Markeland-Johansson, C. (2005) Production of milligram quantities of affinity-tagged proteins using automated multistep chromatographic purification. J. Chromatogr. A 1080, 83–92. 72. Sassenfeld, H.M. and Brewer, S.J. (1984) A polypeptide fusion. Designed for the purification of recombinant proteins. Bio/Technol. 2, 76–81. 73. Smith, M.C., Furman, T.C., Ingolia, T.D. and Pidgeon, J. (1988) Chelating peptide-immobilized metal ion affinity chromatography: a new concept in affinity chromatography for recombinant proteins. J. Biol. Chem. 263, 7211–7215. 74. Smith, D.B. and Johnson, K.S. (1988) Single-step purification of polypeptides expressed in Escherichia coli as fusions with glutathione S-transferase. Gene 67, 31–40. 75. di Guan, C., Li, P., Riggs, P.D. and Inouye, H. (1988) Vectors that facilitate the expression and purification of foreign peptides in Escherichia coli by fusion to maltose-binding protein. Gene 67, 21–30. 76. La Vallie, E.R., DiBlasio, E.A., Kovacic, S., Grant, K.L., Schendel, P.F. and McCoy, J.M. (1993) A thioredoxin gene fusion expression system that circumvents inclusion body formation in the E. coli cytoplasm. Biotechnology (NY) 11, 187–193. 77. Nilsson, B., Moks, T., Jansson, B., Abrahmsen, L., Elmblad, A., Holmgren, E., Henrichson, C., Jones, T.A. and Uhlén, M. (1987) A synthetic IgG-binding domain based on staphylococcal protein A. Protein Eng. 1, 107–113. 78. Davis, G.D., Elisee, C., Newham, D.M. and Harrison, R.G. (1999) New fusion protein systems designed to give soluble expression in Escherichia coli. Biotechnol. Bioeng. 65, 382–388. 79. Balbas, P. (2001) Understanding the art of producing protein and non-protein molecules in Escherichia coli. Mol. Biotechnol. 19, 251–267. 80. Huth, J.R., Bewley, C.A., Jackson, B.M., Hinnebusch, A.G., Clore, G.M. and Gronenborn, A.M. (1997) Design of an expression system for detecting folded protein domains and mapping macromolecular interactions by NMR. Protein Sci. 6, 2359–2364. 81. Lichty, J.J., Malecki, J.L., Agnew, H.D., Michelson-Horowitz, D.J. and Tan, S. (2005) Comparison of affinity tags for protein purification. Protein Expr. Purif. 41, 98–105. 82. Palanisamy, U.D., Hussain, A., Iqbal, S., Sproule, K. and Lowe, C.R. (1999) Design, synthesis and characterisation of affinity ligands for glycoproteins. J. Mol. Recognit. 12, 57–66. 83. Palanisamy, U.D., Winzor, D.J. and Lowe, C.R. (2000) Synthesis and evaluation of affinity adsorbents for glycoproteins: an artificial lectin. J. Chromatogr. B 746, 265–281. 84. Sugimoto, N., Miyoshi, D. and Zou, J. (2000) Development of small peptides recognizing a monosaccharide by combinatorial chemistry. Chem. Commun. 23, 2295–2296.

Page 2: Affinity Chromatography second edit

Page 6: METHODS IN MOLECULAR BIOLOGY TM Aff

Page 10: To Tina, Emmanuella, Natalie, and A

Page 14: viii Preface Affinity tags for puri

Page 18: x Contents 10. Immobilized Metal Io

Page 22: xii Contributors Tzong-Hsien Lee

Page 26: 2 Roque and Lowe cell extract conta

Page 30: 4 Roque and Lowe groups critical in

Page 34: 6 Roque and Lowe of reinforcement e

Page 38: 8 Roque and Lowe unknown factors ar

Page 42: 10 Roque and Lowe receptor domains

Page 46: 12 Roque and Lowe A further issue o

Page 50: 14 Roque and Lowe transgenic system

Page 54: 16 Roque and Lowe 6. Arsenis, C. an

Page 58: 18 Roque and Lowe 39. Burton, S.J.,

Page 64: Affinity Chromatography 21 85. Roqu

Page 68: 2 Immobilized Metal Ion Affinity Ch

Page 72: Immobilized Metal Ion Affinity Chro





Page 92: 38 Kumar et al. protein (5), cellul

Page 96: 40 Kumar et al. Crude protein extra

Page 100: 42 Kumar et al. coordination sites

Page 104: 44 Kumar et al. 5. Repeat the preci

Page 108: 46 Kumar et al. 4. Notes 1. In synt

Page 112: 48 Kumar et al. loosely bound metal

Page 116: 50 Kumar et al. 6. Ong, E., Greenwo

Page 120: 52 Kumar et al. 38. Wuenschell, G.

Page 124: 54 Gallant et al. monoclonal antibo

Page 128: 56 Gallant et al. 10. Flush the col

Page 132: 58 Gallant et al. Fig. 2. Sodium do

Page 136: 60 Gallant et al. 3. Liddell, E. (2

Page 140: 62 Gallant et al. Binding and eluti

Page 144: 64 Gallant et al. 5. Mixing device:

Page 148: 66 Gallant et al. 10. Data interpre

Page 152: 68 Gallant et al. 2. Adjustment of

Page 156: 6 Purification of Proteins Using Di

Page 160: Purification of Proteins Using Disp









Page 196: 7 Rationally Designed Ligands for U

Page 200: Rationally Designed Ligands for Use








Page 232: 112 Casey et al. be constructed by

Page 236: 114 Casey et al. (i) Panning the ra

Page 240: 116 Casey et al. 3. Wash the coated

Page 244: 118 Casey et al. 6) Wash four times

Page 248: 120 Casey et al. 3) Mix the washed

Page 252: 122 Casey et al. C Absorbance 450nm

Page 256: 124 Casey et al. References 1. Smit

Page 260: 126 Forde Utilization of the GST-gl

Page 264: 128 Forde 3. Methods 3.1. Productio

Page 268: 130 Forde 4. Wash the column with 5

Page 272: 132 Forde 5. BDGE is toxic (by inha

Page 276: 134 Forde 250 Elution in response u

Page 280: 136 Forde References 1. Wils P, Esc

Page 284: 138 Charlton and Zachariou 1. Intro

Page 288: 140 Charlton and Zachariou and non-

Page 292: 142 Charlton and Zachariou the maxi

Page 296: 144 Charlton and Zachariou Table 2

Page 300: 146 Charlton and Zachariou the Tabl

Page 304: 148 Charlton and Zachariou for some

Page 308: 11 Methods for the Purification of

Page 312: Purification of HQ-Tagged Proteins








Page 344: 12 Amylose Affinity Chromatography

Page 348: Amylose Affinity Chromatography of










Page 388: 192 Urh et al. and affinity purific

Page 392: 194 Urh et al. beads with HaloTag l

Page 396: 196 Urh et al. 2.3. Detection of Pr

Page 400: 198 Urh et al. 2. Carefully remove

Page 404: 200 Urh et al. 3.2.1.2. Phase 2 Imm

Page 408: 202 Urh et al. 3.2.2. Detection of

Page 412: 204 Urh et al. The following protoc

Page 416: 206 Urh et al. 3. Incubate for 10 m

Page 420: 208 Urh et al. by 0.5% Triton X-100

Page 424: 14 Site-Specific Cleavage of Fusion

Page 428: Site-Specific Cleavage of Fusion Pr








Page 460: 15 The Use of TAGZyme for the Effic

Page 464: Removal of N-Terminal His-Tags 231







Page 492: 16 Affinity Processing of Cell-Cont

Page 496: Affinity Processing of Cell-Contain




Page 512: 258 Benčina et al. 1. Introduction

Page 516: 260 Benčina et al. 3.1.1. Static I

Page 520: 262 Benčina et al. [A] abs orbance

Page 524: 264 Benčina et al. Table 2 Long-Te

Page 528: 266 Benčina et al. Table 3 Effect

Page 532: 268 Benčina et al. 8 7 n RNase 0,0

Page 536: 270 Benčina et al. Table 6 Long-Te

Page 540: 272 Benčina et al. B A PepC marker

Page 544: 274 Benčina et al. 3. Platonova, G

Page 548: 276 Forde diseases, cancer and infe

Page 552: 278 Forde 12. Sample loading buffer

Page 556: 280 Forde 2. Mix 100 μl of sample,

Page 560: 282 Forde 12. Safety Warning: Picog

Page 564: 19 Affinity Chromatography of Phosp

Page 568: Affinity Chromatography of Phosphor




Page 584: 20 Protein Separation Using Immobil

Page 588: Immobilized Phospholipid Chromatogr



Page 600: 21 Analysis of Proteins in Solution

Page 604: Affinity Capillary Electrophoresis

















Page 672: Index Adsorption isotherm, 75, 84 A

Page 676: Index 341 Genenase I, 170, 214, 215

Page 680: Index 343 Saccharomyces cerevisae,

protein

affinity

buffer

proteins

column

binding

chromatography

purification

elution

resin

researchgate

mrc.ac.ir

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