Epitope Mapping A Practical Approach,9780199636532

Epitope Mapping A Practical Approach

by ;
ISBN13: 9780199636532
ISBN10: 0199636532
Format: Hardcover
Pub. Date: 2001-05-24
Publisher(s): Oxford University Press
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Summary

Epitope Mapping covers all the major methods for the identification and definition of epitopes. The Pepscan assay is used to define B cell epitopes and makes use of synthetic peptides but can only be used if the amino acid sequence is known. It can be adapted for the delineation of both helper T cells and cytotoxic T cells. The identification of combined B and T cell epitopes can also be achieved using synthetic peptides. There are other methodologies for analyzing for cytotoxic T cell epitopes such as the purification of antigens presented by MHC class I molecules and expression cloning. Site directed mutagenesis is also a powerful tool in epitope mapping and can be used to evaluate the role of single amino acids in immune complex formation. Protein footprinting makes use of monoclonal antibodies produced by hybridoma technology and relies on the fact that the epitope is protected from cleavage when bound as an antibody-antigen complex. It is only useful for small antigens. Other monoclonal antibody assays such as enzyme linked immunosorbent assay and haemaglutination and slot-blotting may also be used in epitope mapping. Random phage display libraries bring together the genetic and amino acid peptide sequence and can be screened with antibody and the resulting peptide DNA sequenced to confirm the amino acid sequence of a specific epitope. Investigation of carbohydrates can also be useful to epitope mapping as deglycosylation can lead to loss of antigenic activity. Epitopes are important to the pharmaceutical industry and wherever appropriate, pharmaceutical applications of the methods described are included. For each method there is a description of the technology, protocols, trouble-shooting, and advice on when to use the method. This book will therefore be invaluable to any researcher involved in epitope mapping.

Table of Contents

List of protocols
xiii
Abbreviations xvii
An introduction to epitope mapping
1(16)
Olwyn M. R. Westwood
Frank C. Hay
Environmental conditions can influence protein structure
1(3)
Locating the epitope of the molecule
2(2)
Lessons from an historical perspective
4(2)
Enzymatic cleavage for epitope mapping
4(1)
Protein sequence analysis
5(1)
Chemical characteristics of sequences
6(1)
Synthetic peptide technologies for epitope mapping
6(1)
Chemical modification of antigens
7(1)
Site-directed mutagenesis as a tool for epitope mapping
8(1)
Hybridoma technology and epitope analysis
9(1)
Protein footprinting in epitope analysis
10(1)
Generating monoclonal antibody
10(1)
Phage display libraries
10(1)
Carbohydrates and their significance when epitope mapping
11(2)
Approaches to epitope mapping
13(4)
Polyclonal or monoclonal antibody?
13(1)
Whole antigen available?
13(1)
Amino acid sequence known?
13(1)
Nucleotide sequence available?
13(1)
References
13(4)
Multiple Pin Peptide Scanning (``Pepscan'')
17(30)
Nazira Sumar
Introduction
17(1)
Brief outline of Pepscan
18(1)
Solid phase peptide synthesis
18(4)
Attachment
19(2)
Deprotection and coupling
21(1)
Elongation of peptide chain
21(1)
Cleavage
21(1)
Multiple peptide synthesis on pins
22(5)
Pins
22(1)
Choice of peptide length
22(5)
Testing of antibody epitopes
27(5)
Pin-bound non-cleavable peptides
27(3)
Biotinylated peptides
30(2)
Results and data analysis
32(1)
Further analysis
33(3)
Window net analysis
33(1)
Replacement net analysis
33(3)
Applications of Pepscan
36(2)
Other systems for epitope analysis
38(9)
Simple precision original test system (SPOTs)
38(1)
Tea-bag synthesis
38(2)
Peptide epitope libraries
40(3)
Acknowledgements
43(1)
References
43(4)
Methodological tips for human T cell epitope mapping when using pin technology peptide arrays
47(44)
David A. Mutch
Olwyn M. R. Westwood
Introduction
47(1)
Historic foundations to large scale T cell epitope mapping
48(1)
Fundamental considerations
49(3)
Lessons from B cell epitope mapping
49(3)
The nature of the peptide antigen
52(1)
Protein sequence databases and sequence analysis
52(1)
Peptide synthesis considerations
52(7)
Types of peptides
53(1)
Features of T cell epitopes
53(6)
Use of pin peptides in human PBMC proliferation and cell culture assays
59(17)
Buffer systems
61(1)
Cleavage of peptide and peptide concentration
61(1)
Using human cells
62(5)
Cell culture conditions
67(8)
Pulse radiolabelling
75(1)
Data analysis using the ALLOC algorithm
76(6)
Example of assay conditions for large scale mapping of T cell epitopes
82(9)
Individual steps in the T cell epitope mapping protocol
82(2)
Example of results obtained
84(3)
References
87(1)
Published methods to detect cellular antigenic stimulation
88(3)
Combined B cell and T cell epitopes
91(12)
Sowsan F. Atabani
Introduction
91(1)
Molecular mapping of antigenic and immunogenic epitopes
92(3)
Identification of antigenic epitopes in vitro
92(2)
Identification of T cell epitopes in vitro
94(1)
In vivo analysis of immunogenicity and antigenicity
95(6)
Investigation of the core sequence of B cell and T cell epitopes
97(1)
Inhibition ELISA for the measurement of antibody affinity as a method to determine the B cell epitope
98(1)
Determination of precise helper T cell epitopes by proliferative and cytokine responses
99(2)
General summary
101(2)
References
102(1)
CTL epitopes
103(40)
Tim Elliott
John S. Haurum
Introduction
103(5)
TcR recognizes a complex between MHC and antigenic peptide
103(2)
Antigen processing
105(2)
Immunodominance
107(1)
Indirect methods of CTL epitope identification using synthetic peptides
108(15)
Peptide binding to class I MHC molecules
112(6)
Correspondence between motifs and binding efficacy
118(2)
Correspondence between peptide binding and immunogenicity/immunodominance
120(3)
Direct identification of CTL epitopes
123(20)
Direct identification of CTL epitopes by immuno-isolation and sequencing
123(5)
Direct identification of CTL epitopes by expression cloning
128(3)
References
131(5)
Class I MHC peptide motifs
136(4)
Class I MHC alleles expressed by TAP-deficient cell lines
140(1)
Monoclonal antibodies specific for class I MHC molecules
141(1)
Index peptides suitable for modification
142(1)
The design, synthesis, and characterization of molecular mimetics
143(16)
Ian T. W. Matthews
Introduction
143(1)
Design, synthesis, and characterization of peptoid oligomers
144(7)
Design of peptoid oligomers
144(3)
The synthesis of peptoid oligomers
147(3)
Characterization of peptoids
150(1)
Further oligomeric peptide mimetics
151(4)
β-Peptides, β-peptoids, retro-peptoids, and amide surrogates
151(4)
Non-oligomeric peptide mimetics
155(4)
Natural templates
155(1)
Non-natural templates
156(1)
References
157(2)
Generating monoclonal antibody probes and techniques for characterizing and localizing reactivity to antigenic determinants
159(40)
Paul N. Nelson
Introduction
159(1)
Immunization strategies
160(3)
Hybridization and culture of hybridomas
163(6)
Monoclonal purification
169(1)
Monoclonal conjugation
170(1)
Techniques for screening and characterizing mAb reactivity to antigenic determinants
171(14)
Enzyme-linked immunosorbent assay (ELISA)
172(4)
Haemagglutination
176(2)
Slot-blotting
178(2)
Immunocytochemistry
180(5)
Physiochemical and chemical modification, pepsin digestion
185(2)
Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and Western blotting
187(7)
Protein determination
194(5)
UV absorption
194(2)
Fluorescence
196(1)
Acknowledgements
197(1)
References
197(2)
Epitope mapping of carbohydrate binding proteins using synthetic carbohydrates
199(26)
U. J. Nilsson
G. Magnusson
Introduction
199(1)
Synthetic carbohydrate analogues
200(4)
Oligosaccharide fragments
200(1)
Deoxy analogues
200(2)
Deoxyfluoro analogues
202(1)
O- and C-methyl analogues
202(1)
Amino and carboxy analogues
203(1)
Conformationally restricted or altered analogues
203(1)
Combinatorial synthesis of carbohydrate libraries
203(1)
Measuring carbohydrate-protein interactions
204(13)
Haemagglutination inhibition
205(2)
Competitive ELISA
207(8)
Techniques for direct measurement of carbohydrate-protein interaction
215(1)
Enzyme assays
216(1)
Qualitative in situ assays
216(1)
Data interpretation
217(8)
Conformational analysis
217(1)
Fragments of oligosaccharides
218(1)
Deoxy and deoxyfluoro analogues
219(1)
Amino and carboxy analogues
220(1)
Conformationally altered analogues
221(1)
References
222(3)
Phage display libraries
225(30)
Samantha Williams
Paul van der Logt
Volker Germaschewski
Introduction
225(6)
General
225(2)
Overview of phage display libraries
227(2)
Applications of phage display libraries
229(2)
Case study: identification of dominant epitopes
231(22)
Project strategy
231(1)
Procedure for the identification of peptide epitopes by phage display
231(12)
Deriving peptide binding antibody fragments
243(10)
Conclusions
253(2)
Acknowledgements
253(1)
References
253(2)
Site-directed mutagenesis in epitope mapping
255(16)
Samuel Perdue
Introduction
255(3)
General approaches to mutagenesis in epitope mapping: techniques in site-directed mutagenesis
258(10)
Traditional approach
258(5)
PCR approach
263(5)
Conclusions
268(3)
References
268(3)
List of suppliers 271(6)
Index 277

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