Molecular anatomy: phyletic relationships derived from three-dimensional structures of proteins

Mark S. Johnson; Michael J. Sutcliffe; Tom L. Blundell

doi:10.1007/BF02102452

Molecular anatomy: phyletic relationships derived from three-dimensional structures of proteins

Mark S. Johnson
, Michael J. Sutcliffe
, Tom L. Blundell

University of London
University of Oxford

Research output: Contribution to journal › Article › peer-review

Abstract

A distance measure that reflects the dissimilarity among structures has been developed on the basis of the three-dimensional structures of similar proteins, this being totally independent of sequence in the sense that only the relative spatial positions of mainchain alpha-carbon atoms need be known. This procedure leads to phyletic relationships that are in general correlated with the sequence phylogenies based on residue type. Such relationships among known protein three-dimensional structures are also a useful aid to their classification and selection in knowledge-based modeling using homologous structures. We have applied this approach to six homologous sets of proteins: immunoglobulin fragments, globins, cytochromesc, serine proteinases, eye-lens gamma crystallins, and dinucleotide-binding domains.

Original language	English
Pages (from-to)	43-59
Journal	Journal of Molecular Evolution
Volume	30
Issue number	1
DOIs	https://doi.org/10.1007/BF02102452
Publication status	Published - Jan 1990
Externally published	Yes

Keywords

Chemistry

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keywords = "Chemistry",

author = "Johnson, \{Mark S.\} and Sutcliffe, \{Michael J.\} and Blundell, \{Tom L.\}",

year = "1990",

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AB - A distance measure that reflects the dissimilarity among structures has been developed on the basis of the three-dimensional structures of similar proteins, this being totally independent of sequence in the sense that only the relative spatial positions of mainchain alpha-carbon atoms need be known. This procedure leads to phyletic relationships that are in general correlated with the sequence phylogenies based on residue type. Such relationships among known protein three-dimensional structures are also a useful aid to their classification and selection in knowledge-based modeling using homologous structures. We have applied this approach to six homologous sets of proteins: immunoglobulin fragments, globins, cytochromesc, serine proteinases, eye-lens gamma crystallins, and dinucleotide-binding domains.

KW - Chemistry

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ER -

Molecular anatomy: phyletic relationships derived from three-dimensional structures of proteins

Abstract

Keywords

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