• HOME
  • Search & Results
  • Full Text
  • Thesis Details
 
Page: 173
 
 Full Screen

  • Title
  • DECLARATION 1
  • DECLARATION 2
  • CONTENTS
  • ACKNOWLEDGEMENT
  • ABBREVIATIONS AND ACRONYMS
  • 1. Introduction
  • Introduction
  • Objectives of the work
  • Organization of the Thesis
  • 2. Current trends in solid-phase peptide synthesis
  • Polymer support
  • Fig.2.1. TEGDMA-crosslinked polystyrene
  • Fig.2.1. TTEGDA-crosslinked polystyrene
  • Protecting groups
  • Coupling reagents
  • Table 2.1. Coupling reagents used in peptide synthesis
  • Purification and characterization of peptide
  • Problems associated with solid-phase peptide synthesis Polymer effect
  • Polimer Effect
  • Fig. 2.3. Possible states of polymer (PS) and peptide chain in solvents of varying polarity
  • Aggregation of Peptide
  • 3. Results and Discussion
  • Polymer preparation
  • Preparation of 2% I, 6-hexanediol diacrylate cross linked polystyrene
  • Functionalization of the polymer
  • Fig. 3.1. IR spectrum of 2% hexanediol diacrylate crosslinked polystyrene
  • Functional group assay
  • Fig. 3.2. IR spectrum of chloromethylated HDODA-PS
  • Stability of polymer
  • Synthesis of model peptides
  • Synthesis of (Ala) 3
  • Synthesis of Peptides II to VI
  • Synthesis of Peptides II to IV
  • Fig. 3.3.HPLC trace of VAVAAG
  • Synthesis of peptides V and VI
  • Fig. 3.4. HPLC trace of Glu-Val-Gly-Gln-Val-Gln-Leu-Gly
  • Synthesis of acyl carrier protein fragment (65 - 74)
  • Synthesis of the peptide
  • Table 3.1. Protocol for the synthesis of ACP 65-74
  • Amino acid analysis of the peptidyl resin
  • Table3.2. Coupling difficulty occurred during the synthesis of ACP 65-74 using Merrifield resin and HDODA-PS
  • Table 3.3. Amino acid analysis of ACP 65-74 bound to HDODA-PS and Merrifield resin
  • Cleavage of the peptide from the support
  • Purification of the peptide
  • Fig.3.5. HPLC trace of Crude ACT 65-74
  • Synthesis of a 13-residue peptide.corresponding to the fragment of bovine SPLN.
  • Introduction
  • Synthsis of peptide
  • Table 3.4. Protocol for the incorporation of one amino acid in the synthesis of13-residue peptide
  • Cleavage of the peptide from the support
  • Purication of the peptide
  • Table 3.5. Amino acid analysis of 13-residue peptide
  • Fig. 3.6. FPLC trace of 13-residue peptide
  • Synthesis of a 31-residue peptide
  • Introduction
  • Fig. 3.7.0rientation of stomatitis virus G protein in the Lipid bilayer of cellmembrane of the virus.
  • Synthesis of the peptide
  • Table 3.6. Amino acid analysis of decapeptidyl fragment of 31 residue peptide
  • Fig. 3.8. FPLC trace of the 21-residue peptide
  • Purification of the peptide
  • Fig.3.9. FPLC trace of the 31-residue peptide soluble in methanol
  • Fig. 3.10. FPLC trace of peptide eluted during blank run after methanolic fractions were seperated.
  • Table 3.7. Amino acid analysis of methanolic fraction of 31-residue crude peptide
  • Table 3.8. Amino acid analysis of 31-residue peptide soluble in acetonitrile and that of insoluble part
  • NMR study of 31 -residue peptide
  • NMR study of biomolecules
  • Fig. 3.11. Excitation and mixing procedures in multi-dimensional NMR experiments
  • i) Chemical Shifts
  • ii) Indirect Spin-Spin Coupling
  • Fig. 3.12. Perspective drawing of a L-polypeptide chain showing torsional angles
  • Table 3.9. Different Ф, Ψ and J values of regular structures of protein
  • iv) Hydrogen bonds
  • Molecular modelling and minimization methods
  • Analysis of peptide by NMR
  • Space correlation method
  • Fig. 3.13. Schematic representation showing through space connectivities in typical secondary structural elements in peptides that give NOE cross peaks.
  • Fig. 3.14. 400 MHz 2D NOESY spectrum (at 350 ms mixing time) of the 31 residue peptide. Temperature = 25°C
  • Fig. 3.15.400 MHz 2D DQF COSY spectrum of the 31 residue peptide
  • Fig. 3. 16. 400 MHz 2D TOCSY spectrum (at 100 ms mixing time) of the 31 residue peptide
  • Fig. 3.10. List of chemical shifts for the residues which could be well estimated forthe peptide from the 31 residue peptide in TFA.
  • Fig.3.17. 3-D structure of 31-residue peptide generated by QUANTA CHARMm program
  • IR investigation on solid-state conformation of peptides bound to polymer support.
  • Fig. 3.18. N-methyl acetamide molecule (a), Schematic diagram (b)
  • Table 3.11. Summary of the characteristic bands associated with the peptide linkage
  • Table 3.12. Amide I frequencies characteristics of peptide bond
  • Fig. 3.19. Normal modes of vibration of NMA
  • Table 3.13. The different peptides and their values used for IR investigation
  • Table 3.14. The amide I region of peptidyl resin
  • Fig. 3.20. Amide I regioin of peptidyl resin
  • Fig. 3.21. Amide I region of VAVAAG bound to resin
  • Fig. 3.22. Amide I region of peptide bound to resi
  • Fig. 3.23. Amide I region of ACP fragment bound to resin
  • Fig. 3.24. IR specra of HDODA-PS corresponding to the ester region
  • Fig. 3.25. Hypothetical model of peptide on polymer support
  • 4. Experimental section
  • Materials and methods
  • Purification of solvents
  • Preparation of Boc azide
  • Preparation of Boc amino acids
  • Schnabels procedure
  • t- Butyloxycarbonyloximino-2-phenylacetonitrile (Boc ON) Method
  • Purity of Boc amino acids
  • Preparation of 2%-HDODA-crosslinked polystyrene
  • Functionalization of support - chloromethylation
  • Preparation of chloromethyl methylether
  • Preparation of I M zinc chloride in THF
  • Chloromethylation of polymer support
  • General methods of solid-phase peptide synthesis
  • Attachment of first amino acid
  • Estimation of first amino acid attachment
  • Deprotection procedure
  • Coupling methods
  • Anhydride method
  • HOBt-active ester method
  • Cleavage of peptide from the support
  • Checking the homogeneity of the peptide
  • Thin layer chromatography
  • Fast protein liquid chromatography
  • High performance liquid chromatography
  • Amino acid analysis
  • IR studies of peptidyl resin
  • NMR studies of peptide
  • Solid-phase syntheses of peptides on HDODA-PS
  • Synthesis of (Ala) 3
  • Synthesis of Ala-Ala-GIy
  • Synthesis of Val-Ala-Ala-Gly
  • Synthesis of Val-Ala-VaI-Ala-AIa-Gly
  • Synthesis of GIn-Val-Glu-Leu-Gly
  • Synthesis of Gln-Val-Gly-Gln-Val-Glu-Leu-Gly
  • Solid-phase syntheses of peptides on Merrifield support Synthesis of Ala-Ala-Gly
  • Synthesis of Ala-Ala-Gly
  • Synthesis of Val-Ala-Ala-Gly
  • Synthesis of Val-Ala-Val-Ala-Ala-Gly
  • Synthesis of GIn-Val-Glu-Leu-Gly
  • Synthesis of GIn-Val-GIy-GIn-Val-Glu-Leu-GIy
  • Synthesis of acyl carrier protein fragment 65-74 on HDODA-PS
  • Synthesis of acyl carrier protein fragment 65-74 on Merrifield system
  • Synthesis of a 31 Residue Peptide Corresponding to Vesicular StomatitisVirus G (VSV G) Protein.
  • Synthesis of a 31-residue peptide
  • Synthesis of a 13-residue peptide
  • 5. Summary and Outlook
  • 6. References