Insights into the substrate specificity of plant peptide deformylase, an essential enzyme with potential for the development of novel biotechnology applicatons in agriculture

Dirk, Lynnette M.A.; Schmidt, Jack J; Cai, Yiying; Barnes, Jonathan C; Hanger, Katherine M; Nayak, Nihar R; Williams, Mark A; Grossman, Robert B; Houtz, Robert L; Rodgers, David W

doi:10.1042/BJ20071641

Title: Insights into the substrate specificity of plant peptide deformylase, an essential enzyme with potential for the development of novel biotechnology applicatons in agriculture

Journal Article · Mon Jul 28 00:00:00 EDT 2008 · Biochem. J.

DOI:https://doi.org/10.1042/BJ20071641· OSTI ID:1006734

Dirk, Lynnette M.A.; Schmidt, Jack J; Cai, Yiying; Barnes, Jonathan C; Hanger, Katherine M; Nayak, Nihar R; Williams, Mark A; Grossman, Robert B; Houtz, Robert L; Rodgers, David W ^[1]

Kentucky

The crystal structure of AtPDF1B [Arabidopsis thaliana PDF (peptide deformylase) 1B; EC 3.5.1.88], a plant specific deformylase, has been determined at a resolution of 2.4 {angstrom} (1 {angstrom}=0.1 nm). The overall fold of AtPDF1B is similar to other peptide deformylases that have been reported. Evidence from the crystal structure and gel filtration chromatography indicates that AtPDF1B exists as a symmetric dimer. PDF1B is essential in plants and has a preferred substrate specificity towards the PS II (photosystem II) D1 polypeptide. Comparative analysis of AtPDF1B, AtPDF1A, and the type 1B deformylase from Escherichia coli, identifies a number of differences in substrate binding subsites that might account for variations in sequence preference. A model of the N-terminal five amino acids from the D1 polypeptide bound in the active site of AtPDF1B suggests an influence of Tyr{sup 178} as a structural determinant for polypeptide substrate specificity through hydrogen bonding with Thr{sup 2} in the D1 sequence. Kinetic analyses using a polypeptide mimic of the D1 N-terminus was performed on AtPDF1B mutated at Tyr{sup 178} to alanine, phenylalanine or arginine (equivalent residue in AtPDF1A). The results suggest that, whereas Tyr{sup 178} can influence catalytic activity, other residues contribute to the overall preference for the D1 polypeptide.

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Research Organization:: Argonne National Lab. (ANL), Argonne, IL (United States). Advanced Photon Source (APS)

Sponsoring Organization:: USDOE

OSTI ID:: 1006734

Journal Information:: Biochem. J., Vol. 413, Issue (3) ; 08, 2008; ISSN 0006-2936

Country of Publication:: United States

Language:: ENGLISH

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Related Subjects

08 HYDROGEN
AGRICULTURE
AMINO ACIDS
ARABIDOPSIS
ARGININE
BIOTECHNOLOGY
BONDING
CHROMATOGRAPHY
CRYSTAL STRUCTURE
ENZYMES
ESCHERICHIA COLI
FILTRATION
HYDROGEN
KINETICS
PEPTIDES
PHENYLALANINE
POLYPEPTIDES
RESIDUES
RESOLUTION
SPECIFICITY
SUBSTRATES

Title: Insights into the substrate specificity of plant peptide deformylase, an essential enzyme with potential for the development of novel biotechnology applicatons in agriculture

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