Chemistry of antibody binding to a protein

H. Mario Geysen; John A. Tainer; Stuart J. Rodda; Tom J. Mason; Hannah Alexander; Elizabeth D. Getzoff; Richard A. Lerner

doi:10.1126/science.3823878

Chemistry of antibody binding to a protein

H. Mario Geysen, John A. Tainer, Stuart J. Rodda, Tom J. Mason, Hannah Alexander, Elizabeth D. Getzoff, Richard A. Lerner

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212 Scopus citations

Abstract

The chemistry of antibody recognition was studied by mapping the antigenicity of the protein myohemerythrin with peptide homologs of the protein sequence. The results suggest that the entire protein surface is antigenic, but the probability of there being antibodies to a given site is influenced by local stereochemistry. Although accessible to an antibody binding domain,the least reactive positions cluster in the most tightly packed and least mobile regions and are closely associated with narrow, concave grooves inthe molecular surface containing bound water molecules. The most frequently recognized sites form three-dimensional superassemblies characterized by high local mobility, convex surface shape, and often by negative electrostatic potential.

Original language	English (US)
Pages (from-to)	1184-1190
Number of pages	7
Journal	Science
Volume	235
Issue number	4793
DOIs	https://doi.org/10.1126/science.3823878
State	Published - 1987
Externally published	Yes

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title = "Chemistry of antibody binding to a protein",

abstract = "The chemistry of antibody recognition was studied by mapping the antigenicity of the protein myohemerythrin with peptide homologs of the protein sequence. The results suggest that the entire protein surface is antigenic, but the probability of there being antibodies to a given site is influenced by local stereochemistry. Although accessible to an antibody binding domain,the least reactive positions cluster in the most tightly packed and least mobile regions and are closely associated with narrow, concave grooves inthe molecular surface containing bound water molecules. The most frequently recognized sites form three-dimensional superassemblies characterized by high local mobility, convex surface shape, and often by negative electrostatic potential.",

author = "Geysen, {H. Mario} and Tainer, {John A.} and Rodda, {Stuart J.} and Mason, {Tom J.} and Hannah Alexander and Getzoff, {Elizabeth D.} and Lerner, {Richard A.}",

year = "1987",

doi = "10.1126/science.3823878",

language = "English (US)",

volume = "235",

pages = "1184--1190",

journal = "Science",

issn = "0036-8075",

publisher = "American Association for the Advancement of Science",

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T1 - Chemistry of antibody binding to a protein

AU - Geysen, H. Mario

AU - Tainer, John A.

AU - Rodda, Stuart J.

AU - Mason, Tom J.

AU - Alexander, Hannah

AU - Getzoff, Elizabeth D.

AU - Lerner, Richard A.

PY - 1987

Y1 - 1987

N2 - The chemistry of antibody recognition was studied by mapping the antigenicity of the protein myohemerythrin with peptide homologs of the protein sequence. The results suggest that the entire protein surface is antigenic, but the probability of there being antibodies to a given site is influenced by local stereochemistry. Although accessible to an antibody binding domain,the least reactive positions cluster in the most tightly packed and least mobile regions and are closely associated with narrow, concave grooves inthe molecular surface containing bound water molecules. The most frequently recognized sites form three-dimensional superassemblies characterized by high local mobility, convex surface shape, and often by negative electrostatic potential.

AB - The chemistry of antibody recognition was studied by mapping the antigenicity of the protein myohemerythrin with peptide homologs of the protein sequence. The results suggest that the entire protein surface is antigenic, but the probability of there being antibodies to a given site is influenced by local stereochemistry. Although accessible to an antibody binding domain,the least reactive positions cluster in the most tightly packed and least mobile regions and are closely associated with narrow, concave grooves inthe molecular surface containing bound water molecules. The most frequently recognized sites form three-dimensional superassemblies characterized by high local mobility, convex surface shape, and often by negative electrostatic potential.

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DO - 10.1126/science.3823878

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VL - 235

SP - 1184

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JO - Science

JF - Science

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ER -

Chemistry of antibody binding to a protein

Abstract

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