Substrate Recognition of Anthrax Lethal Factor Examined by Combinatorial and Pre-steady-state Kinetic Approaches

Substrate Recognition of Anthrax Lethal Factor Examined by Combinatorial and Pre-steady-state Kinetic Approaches

Lethal factor (LF), a zinc-dependent protease of high specificity produced by Bacillus anthracis, is the effector component of the binary toxin that causes death in anthrax. New therapeutics targeting the toxin are required to reduce systemic anthrax-related fatalities. In particular, new insights i...

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Veröffentlicht in:The Journal of biological chemistry 2009-07, Vol.284 (27), p.17902-17913
Hauptverfasser: Zakharova, Maria Yu, Kuznetsov, Nikita A., Dubiley, Svetlana A., Kozyr, Arina V., Fedorova, Olga S., Chudakov, Dmitry M., Knorre, Dmitry G., Shemyakin, Igor G., Gabibov, Alexander G., Kolesnikov, Alexander V.
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Sprache:eng
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Amino Acid Sequence
Antigens, Bacterial - genetics
Antigens, Bacterial - metabolism
Apoenzymes - genetics
Apoenzymes - metabolism
Bacillus anthracis - enzymology
Bacillus anthracis - genetics
Bacterial Toxins - genetics
Bacterial Toxins - metabolism
Catalysis
Catalytic Domain - physiology
Cations, Divalent - metabolism
Cloning, Molecular
Enzyme Activation - physiology
Enzyme Catalysis and Regulation
Escherichia coli
Hydrolysis
Kinetics
MAP Kinase Kinase 6 - metabolism
Molecular Sequence Data
Mutagenesis, Site-Directed
Peptide Library
Substrate Specificity
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container_end_page 17913
container_issue 27
container_start_page 17902
container_title The Journal of biological chemistry
container_volume 284
creator Zakharova, Maria Yu
Kuznetsov, Nikita A.
Dubiley, Svetlana A.
Kozyr, Arina V.
Fedorova, Olga S.
Chudakov, Dmitry M.
Knorre, Dmitry G.
Shemyakin, Igor G.
Gabibov, Alexander G.
Kolesnikov, Alexander V.
description Lethal factor (LF), a zinc-dependent protease of high specificity produced by Bacillus anthracis, is the effector component of the binary toxin that causes death in anthrax. New therapeutics targeting the toxin are required to reduce systemic anthrax-related fatalities. In particular, new insights into the LF catalytic mechanism will be useful for the development of LF inhibitors. We evaluated the minimal length required for formation of bona fide LF substrates using substrate phage display. Phage-based selection yielded a substrate that is cleaved seven times more efficiently by LF than the peptide targeted in the protein kinase MKK6. Site-directed mutagenesis within the metal-binding site in the LF active center and within phage-selected substrates revealed a complex pattern of LF-substrate interactions. The elementary steps of LF-mediated proteolysis were resolved by the stopped-flow technique. Pre-steady-state kinetics of LF proteolysis followed a four-step mechanism as follows: initial substrate binding, rearrangement of the enzyme-substrate complex, a rate-limiting cleavage step, and product release. Examination of LF interactions with metal ions revealed an unexpected activation of the protease by Ca2+ and Mn2+. Based on the available structural and kinetic data, we propose a model for LF-substrate interaction. Resolution of the kinetic and structural parameters governing LF activity may be exploited to design new LF inhibitors.
doi_str_mv 10.1074/jbc.M807510200
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New therapeutics targeting the toxin are required to reduce systemic anthrax-related fatalities. In particular, new insights into the LF catalytic mechanism will be useful for the development of LF inhibitors. We evaluated the minimal length required for formation of bona fide LF substrates using substrate phage display. Phage-based selection yielded a substrate that is cleaved seven times more efficiently by LF than the peptide targeted in the protein kinase MKK6. Site-directed mutagenesis within the metal-binding site in the LF active center and within phage-selected substrates revealed a complex pattern of LF-substrate interactions. The elementary steps of LF-mediated proteolysis were resolved by the stopped-flow technique. Pre-steady-state kinetics of LF proteolysis followed a four-step mechanism as follows: initial substrate binding, rearrangement of the enzyme-substrate complex, a rate-limiting cleavage step, and product release. Examination of LF interactions with metal ions revealed an unexpected activation of the protease by Ca2+ and Mn2+. Based on the available structural and kinetic data, we propose a model for LF-substrate interaction. 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Examination of LF interactions with metal ions revealed an unexpected activation of the protease by Ca2+ and Mn2+. Based on the available structural and kinetic data, we propose a model for LF-substrate interaction. 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New therapeutics targeting the toxin are required to reduce systemic anthrax-related fatalities. In particular, new insights into the LF catalytic mechanism will be useful for the development of LF inhibitors. We evaluated the minimal length required for formation of bona fide LF substrates using substrate phage display. Phage-based selection yielded a substrate that is cleaved seven times more efficiently by LF than the peptide targeted in the protein kinase MKK6. Site-directed mutagenesis within the metal-binding site in the LF active center and within phage-selected substrates revealed a complex pattern of LF-substrate interactions. The elementary steps of LF-mediated proteolysis were resolved by the stopped-flow technique. Pre-steady-state kinetics of LF proteolysis followed a four-step mechanism as follows: initial substrate binding, rearrangement of the enzyme-substrate complex, a rate-limiting cleavage step, and product release. 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subjects Amino Acid Sequence
Antigens, Bacterial - genetics
Antigens, Bacterial - metabolism
Apoenzymes - genetics
Apoenzymes - metabolism
Bacillus anthracis - enzymology
Bacillus anthracis - genetics
Bacterial Toxins - genetics
Bacterial Toxins - metabolism
Catalysis
Catalytic Domain - physiology
Cations, Divalent - metabolism
Cloning, Molecular
Enzyme Activation - physiology
Enzyme Catalysis and Regulation
Escherichia coli
Hydrolysis
Kinetics
MAP Kinase Kinase 6 - metabolism
Molecular Sequence Data
Mutagenesis, Site-Directed
Peptide Library
Substrate Specificity
title Substrate Recognition of Anthrax Lethal Factor Examined by Combinatorial and Pre-steady-state Kinetic Approaches
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