Antibodies and Antigens: Antibody Combining Site:
E.A. Padlan and E.A. Kabat, Modeling of Antibody Combining Sites.
M.B. Bolger and M.A. Sherman, Computer Modeling of the Combining Site Structure of Anti-hapten Monoclonal Antibodies.
J.S. Huston, M. Mudgett-Hunter, M.-S. Tai, J. McCartney, F. Warren, E. Haber, and H. Oppermann, Protein Engineering of Single-Chain Fv Analogs and Fusion Proteins.
S. Johnson and R.E. Bird, Construction of Single-Chain Fv Derivatives of Monoclonal Antibodies and Their Production in Escherichia coli.
D. Güssow and G. Seemann, Humanization of Monoclonal Antibodies.
A.C.R. Martin, J.C. Cheetham, and A. Rees, Molecular Modeling of Antibody Combining Sites.
I.A. Wilson, J.M. Rini, D.H. Fremont, G.G. Fieser, and E.A Stura, X-Ray Crystallographic Analysis of Free and Antigen-Complexed Fab Fragments to Investigate Structural Basis of Immune Recognition.
J.L. Pellequer, E. Westhof, and M.H.V. Van Regenmortel, Predicting Location of Continuous Epitopes in Proteins from Their Primary Structures.
J.C. Cheetham, C. Redfield, R.E. Griest, C.M. Dobson, and A.R. Rees, Use of Two-Dimensional 1H Nuclear Magnetic Resonance to Study High-Affinity Antibody-Peptide Interactions.
J. Anglister and F. Naider, Nuclear Magnetic Resonance for Studying Peptide-Antibody Complexes by Transferred Nuclear Overhauser Effect Difference Spectroscopy.
P. Tsang, M. Rance, and P.E. Wright, ~Isotope-Edited Nuclear Magnetic Resonance Studies of Fab-Peptide Complexes.
J.E. Jentoft, Reductive Methylation and Carbon-13 Nuclear Magnetic Resonance in Structure-Function Studies of the Fc Fragment and Its Subfragments.
N. Boisset and J.N. Lamy, Immunoelectron Microscopy and Image Processing for Epitope Mapping.
W.-J. Syu and L. Kahan, Characterization of Antigenic Structures by Mapping on Resin-Bound Epitope Analogs.
B.J. Walsh and M.E. Howden, Epitope Mapping of Allergens for Rapid Localization of Continuous Allergenic Determinants.
M. Takahashi, S.A. Fuller, and S. Winston, Design and Production of Bispecific Monoclonal Antibodies by Hybrid Hybridomas for Use in Immunoassay. Catalytic
Antibodies and Vaccines:
K.M. Shokat and P.G. Schultz, Catalytic Antibodies.
D. Hilvert and K.W. Hill, Antibody Catalysis of Concerted, Carbon-Carbon Bond-Forming Reactions.
F. Sinigaglia, P. Romagnoli, M. Guttinger, B. Takacs, and J.R.L. Pink, Selection of T Cell Epitopes and Vaccine Engineering.
D.J. Evans and J.W. Almond, Design, Construction, and Characterization of Poliovirus Antigen Chimeras.
Nucleic Acids and Polysaccharides:
W.K. Olson and P. Zhang, Computer Simulation of DNA Supercoiling.
S. Neidle and T.C. Jenkins, Molecular Modeling to Study DNA Intercalation by Antitumor Drugs.
E.L. Loechler, Molecular Modeling in Mutagenesis and Carcinogenesis.
J. Peltonen, S. Jaakkola, and J. Uitto, In Situ Hybridization and Immunodetection Techniques for Simultaneous Localization of Messenger RNAs and Protein Epitopes in Tissue Sections and Cultured Cells.
P. Schimmel and J.J. Burbaum, Transfer RNA with Double Identity for in Vitro Kinetic Modeling of Transfer RNA Identity in Vivo.
N.R. Pace and D.S. Waugh, Design of Simplified Ribonuclease P RNA by Phylogenetic Comparison.
S. Pérez, Molecular Modeling and Electron Diffraction of Polysaccharides.
A.D. Cardin, D.A. Demeter, H.J.R. Weintraub, and R.L. Jackson, Molecular Design and Modeling of Protein-Heparin Interactions.
Y.C. Martin, Computer-Assisted Rational Drug Design.
D.J. Livingstone, Pattern Recognition in Rational Drug Design.
P.-A. Carrupt, N. El Tayar, A. Karlen, and B. Testa, Molecular Electrostatic Potentials for Characterizing Drug-Biosystem Interactions.
T.M. Gund and C.E. Spivak, Pharmacophore for Nicotinic Agonists.
Cross-Index to Prior Volumes: Related Chapters Published in Previous Volumes of Methods in Enzymology.
Each chapter includes references.
Molecular Design and Modeling: Concepts and Applications, Part B: Antibodies and Antigens, Nucleic Acids, Polysaccharides, and Drugs: Volume 203: Molecular Design and Modelling Part Bby Elsevier Science, John J. Langone, Melvin I. Simon
Pub. Date: 11/01/1991
Publisher: Elsevier Science
Computer-based design and modeling, computational approaches, and instrumental methods for elucidating molecular mechanisms of protein folding and ligand-acceptor interactions are included in Volumes 202 and 203, as are genetic and chemical methods for the production of functional molecules including antibodies and antigens, enzymes, receptors, nucleic acids and
Computer-based design and modeling, computational approaches, and instrumental methods for elucidating molecular mechanisms of protein folding and ligand-acceptor interactions are included in Volumes 202 and 203, as are genetic and chemical methods for the production of functional molecules including antibodies and antigens, enzymes, receptors, nucleic acids and polysaccharides, and drugs.
Table of Contents
Antibodies and Antigens: Antibody Combining Site:
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