Peptide-Based Drug Design

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Peptidomimetics 227 not without its disadvantages. The greatest disadvantage of peptidosulfonamide peptidomimetics is the ability of sulfonamide moiety to disrupt any defined secondary structure of the parent peptide in solution, even if present at the N-terminus (16,17). The following structural features of the sulfonamide moiety may contribute to this phenomenon: 1. Sulfonamide N-H is more acidic than amide N-H and therefore a better H-bond donor but a poorer H-bond acceptor. 2. The presence of two sulfonamide oxygens as H-bond acceptors may also impair a H-bonding network which holds together a secondary structure. 3. The sulfonamide oxygens can assume varying positions due to less energydemanding rotation about the sulfonamide bond. This may also prevent a proper alignment of the H-bonds necessary for a particular secondary structure. Despite these sulfonamide peptidomimetic disadvantages, the pharmacological properties of peptides may be improved by introducing the sulfonamide residue at one of several possible positions within the peptide sequence while maintaining the desired biological activity (18,19). 3.1.1. Synthesis of Peptidosulfonamide Monomeric Building Blocks The key step in the synthesis of peptidosulfonamides is the conversion of an amino acid into corresponding activated sulfonic acid derivatives such as sulfinyl- and sulfonyl chloride (Fig. 2) (16,20). Typical synthesis of Fmocprotected β-substituted-β-aminoalkylsulfonyl chlorides include reduction of Fmoc-protected amino acid to corresponding alcohol, conversion of the alcohol to sulfonic acid, and, in a final step, chlorination with thionyl chloride (21,22), phosgene (17,23–25), or triphosgene (18,26). Since traces of triphosgen can significantly lower coupling yields during the peptidosulfonamide solid-phase assembly (23) and phosgene is highly toxic, the use of thionyl chloride as a chlorinating agent represents the most practical approach. Another interesting R 1 R 2 -(H)N COOH Cs 2 CO 3 , HSAc, DMF, 50 °C 1) NMM, DME, iBuO-CO-Cl 2) NaBH 4 , H 2 O, –15 °C R 2 -(H)N R 1 R1 = amino acid's side chain R2 = Fmoc, Boc, Cbz, phthalimide SAc 1) H 2 O 2 , HOAc 2) Pd/C R 2 -(H)N R 2 -(H)N R 1 OH R1 O O S OH MsCl, Et 3 N, CH 2 Cl 2 ,0 °C to r.t. SOCl 2 or SOCl 2 /DMF R 2 -(H)N R 2 -(H)N Fig. 2. Synthesis of protected sulfonyl chloride building blocks. R 1 OMs R1 O O S Cl
228 Cudic and Stawikowski approach for the synthesis of β-aminosulfonamides requires synthesis of sulfonyl chlorides followed by coupling of an amino acid or peptide via amino group and subsequent oxidation using an OsO4/N-methylmorpholine-N-oxide (NMMO) mixture (27). The advantage of the sulfonyl chloride approach is their relative high reactivity in the coupling reactions compared to the sulfonyl chlorides, but the disadvantage is sulfonyl chloride’s limited stability and requirements for the oxidation step after completion of the coupling reaction. Therefore, preparation of sulfonyl chloride monomeric building blocks will not be described in this chapter. 3.1.1.1. SULFONYL CHLORIDE SYNTHESIS These protocols were adopted from refs. (21–23) and (28). Reduction step: 1. To a cold (−15 ◦ C) solution of N-protected α-amino acid (10 mmol) in DME (10 mL) add NMM (10 mmol) and isobutyl chloroformate (10 mmol). 2. Remove precipitated N-methylmorpholine hydrochloride by filtration and wash it with DME (5 × 2mL). 3. Combine washings in a large flask and cool to 0 ◦ C. 4. Add solution of NaBH4 (15 mmol) in water (5 mL) (see Note 1). 5. Add additional 250 mL of water. 6. If alcoholic product precipitates, collect precipitate by filtration and wash thoroughly with water and hexane (see Note 2). Mesylation step: 1. To a solution of alcohol (50 mmol) in DCM (150 mL) add Et3N (57 mmol). 2. Cool solution to 0 ◦ C and add dropwise methanesulfonyl chloride (57 mmol). 3. Stir reaction mixture overnight at room temperature. 4. Add 100 mL of DCM and wash the mixture with 5% NaHCO3 (2 × 100 mL), water (2 × 100 mL), and saturated NaCl solution (80 mL). 5. Dry organic phase over Na2SO4, concentrate the filtrate, and purify by column chromatography over silica gel (eluent: DCM/CH3OH = 9/1). Thioacylation step: 1. Add thioacetic acid (51 mmol) to a suspension of Cs2CO3 (47 mmol) in DMF (70 mL). 2. Add in one portion previously prepared mesylate (43 mmol). 3. Stir reaction mixture at 50 ◦ C for 24 h (see Note 3). 4. Pour reaction mixture in to water (250 mL) and extract with EtOAc (3 × 150 mL). 5. Combined organic layers wash with water (150 mL), 5% NaHCO3 (150 mL), and saturated NaCl solution (150 mL). 6. Dry organic phase over Na2SO4, concentrate the filtrate and purify by column chromatography over silica gel (eluent: EtOAc/hexane = 1/1).
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Peptide-Based Drug Design
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METHODS IN MOLECULAR BIOLOGY TM Pep
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Preface Natural products chemistry
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Contents Preface...................
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Contributors Nikolinka Antcheva •
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Contributors xi Alessandro Tossi
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2 Otvos advance of computer power a
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4 Otvos see derivatives active in b
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6 Otvos was designed based on ligan
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8 Otvos 27. Borghouts, C., Kunz, C.
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10 Bulet Key Words: Invertebrate im
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12 Bulet 6. 5 �L or higher volume
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14 Bulet 2.5.2.1. MALDI-TOF-MS 1. M
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16 Bulet 7. Small-volume low-protei
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18 Bulet 3. Centrifuge between 8000
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20 Bulet internal diameter). Increa
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22 Bulet interest. As no instrument
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24 Bulet 3. Incubate the plates in
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26 Bulet bioactive peptides from th
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28 Bulet 21. Chernysh, S., Kim, S.I
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3 Sequence Analysis of Antimicrobia
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Sequence Analysis of Antimicrobial
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4 The Spot Technique: Synthesis and
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The Spot Technique 49 3. For amine
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The Spot Technique 51 2. Biotinylat
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The Spot Technique 53 the solutions
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The Spot Technique 55 solution. Ens
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The Spot Technique 57 (see Fig. 3)
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The Spot Technique 59 Fig. 5. Princ
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The Spot Technique 61 library, the
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The Spot Technique 63 7. Regenerati
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The Spot Technique 65 following rul
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The Spot Technique 67 20. Atherton,
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The Spot Technique 69 50. Bolger, G
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5 Analysis of A� Interactions Usi
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Analysis of Aβ Interactions 73 are
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Analysis of Aβ Interactions 75 Ana
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Analysis of Aβ Interactions 77 3.
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6 NMR in Peptide Drug Development J
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NMR of Peptides 89 usually require
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NMR of Peptides 91 limiting the siz
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NMR of Peptides 93 and STD NMR expe
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NMR of Peptides 95 The basis of the
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NMR of Peptides 97 Fig. 5. Overlay
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NMR of Peptides 99 Fig. 7. Schemati
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NMR of Peptides 101 4.4.2. Saturati
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NMR of Peptides 103 4.6. Diffusion
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NMR of Peptides 105 Fig. 13. Propos
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NMR of Peptides 107 protein prevent
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NMR of Peptides 109 6. Wuthrich, K.
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NMR of Peptides 111 45. Morris, K.
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NMR of Peptides 113 78. Aumailley,
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116 Copps et al. Fig. 1. Potential
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118 Copps et al. Fig. 2. Flowchart
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120 Copps et al. 10. In accordance
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122 Copps et al. Fig. 3. DSSP for g
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124 Copps et al. ingly with the sam
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126 Copps et al. 19. Essman, U., Pe
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128 Hilpert et al. Key Words: Scree
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130 Hilpert et al. Table 1 (Continu
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132 Hilpert et al. different natura
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134 Hilpert et al. wt A C D E F …
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136 Hilpert et al. methods primaril
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144 Hilpert et al. Table 3 Summary
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148 Hilpert et al. of substituting
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150 Hilpert et al. in models that c
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152 Hilpert et al. than control. Gi
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154 Hilpert et al. Table 4 Accuracy
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156 Hilpert et al. 25. Pini, A., Gi
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158 Hilpert et al. 55. Giacometti,
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9 Investigating the Mode of Action
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Proline-Rich Antimicrobial Peptides
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Page 186 and 187: 10 Serum Stability of Peptides Håv
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Page 196 and 197: 11 Preparation of Glycosylated Amin
Page 198 and 199: Glycosylated Amino Acid Synthesis 1
Page 218 and 219: 12 Synthesis of O-Phosphopeptides o
Page 220 and 221: Solid-Phase Synthesis of O-Phosphop
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Page 234 and 235: Peptidomimetics 225 O O R S N H Pep
Page 238 and 239: Peptidomimetics 229 Oxidation step:
Page 240 and 241: Peptidomimetics 231 of peptidosulfo
Page 242 and 243: Peptidomimetics 233 8. Allow the re
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Page 248 and 249: Peptidomimetics 239 nitrogen (73).
Page 250 and 251: Peptidomimetics 241 3. Cover the re
Page 252 and 253: Peptidomimetics 243 efficient synth
Page 254 and 255: Peptidomimetics 245 55. Alsina, J.,
Page 256 and 257: 14 Synthesis of Toll-Like Receptor-
Page 258 and 259: Lipopeptides 249 2. Materials 2.1.
Page 260 and 261: Lipopeptides 251 Fig. 1. Structural
Page 262 and 263: Lipopeptides 253 8. To enable lipid
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Page 266 and 267: Lipopeptides 257 Fig. 2. Immunogeni
Page 268 and 269: Lipopeptides 259 8. A large plastic
Page 270 and 271: Lipopeptides 261 26. Nardin, E.H.,
Page 272 and 273: 264 Otvos response, synthetic pepti
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Page 276 and 277: 268 Otvos 3. Methods The main goal
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Targeted Therapeutic and Imaging Ag
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Index A A� peptides aggregation a
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Index 297 phosphopeptides influenci
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Index 299 for genetically synthetic
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Index 301 peptidosulfonamide, disad
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Index 303 solid phase, 180, 214 sul
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Peptide-Based Drug Design

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