Role of distant, intrasubunit residues in catalase-peroxidase catalysis tracing the role of gene duplication and fusion in enzyme structure and function /

Cook, Carma Oshea, Goodwin, Douglas C.,

January 2009

Thesis--Auburn University, 2009. / Abstract. Vita. Includes bibliographical references (p. 224-238).

C-terminal domain. Catalase Peroxidase

Structural and functional analysis of catalase-peroxidases

Wiseman, Benjamin

08 April 2010

Catalase-peroxidases (KatGs), responsible for the activation of the anti-tubercular prodrug isoniazid (INH), are unusual members of the class I plant peroxidase family that possess strong catalase activity as well as peroxidase activity. Due to their strong catalase activity and their ability to activate INH, KatGs have been the subject of intense study for many years, and thus the goal of this work is to further characterize this enzyme in the hope of gaining a better understanding into these unusual reactions. Recent successful crystallization of a few representative KatGs revealed a unique covalent Met-Tyr-Trp cross-link joined to the conserved tryptophan in the heme active site, along with a nearby arginine that is in ionic association with the cross-linked tyrosine. Using the KatG from Burkholderia pseudomallei (BpKatG) as a model, site-directed mutagenesis to these residues revealed that they were essential for catalase, but not peroxidase activity. Structural and kinetic analysis revealed that Arg426 acts as a molecular switch, moving between 2 conformations, favoring heme oxidation when not in association with Tyr238 and favoring heme reduction when in association with Tyr238 by imparting its influence on the heme through the cross-link. Analysis of the reaction with peroxyacetic acid using stopped-flow spectrophotometry revealed an initial, rapidly formed enzyme-substrate complex before the formation of the oxoferryl compound I. Kinetic characterization revealed that formation of both the enzyme-substrate complex and the oxoferryl species were dependent on peroxyacetic acid concentration implying that 2 molecules of peroxyacetic acid are required to form the oxoferryl compound I intermediate. Successful co-crystallization with INH and its co-substrate, NAD+ has revealed their binding sites for the first time in a KatG. The NAD+ binding site is 20 Å from the entrance to the heme cavity, involving interactions primarily with the ADP portion of the molecule. The best defined INH binding site is located in a funnel shaped channel on the opposite side of the protein from the entrance channel that requires the movement of a glutamate residue for binding. The structures suggest that once INH is cleaved to the isonicotinoyl radical it diffuses to the NAD+ binding site to form the final active antimicrobial compound, IN-NAD, in a non-enzymatic reaction enhanced by the enzyme’s ability to bind NAD+.

mycobacterium

tuberculosis

INH

catalase-peroxidase

KatG

biochemistry

x-ray

crystallography

kinetics

stopped-flow

molecular

structural

biology

protein

absorption

spectroscopy

site-directed

mutagenesis

isoniazid

Structural and functional analysis of catalase-peroxidases

Wiseman, Benjamin

08 April 2010

Catalase-peroxidases (KatGs), responsible for the activation of the anti-tubercular prodrug isoniazid (INH), are unusual members of the class I plant peroxidase family that possess strong catalase activity as well as peroxidase activity. Due to their strong catalase activity and their ability to activate INH, KatGs have been the subject of intense study for many years, and thus the goal of this work is to further characterize this enzyme in the hope of gaining a better understanding into these unusual reactions. Recent successful crystallization of a few representative KatGs revealed a unique covalent Met-Tyr-Trp cross-link joined to the conserved tryptophan in the heme active site, along with a nearby arginine that is in ionic association with the cross-linked tyrosine. Using the KatG from Burkholderia pseudomallei (BpKatG) as a model, site-directed mutagenesis to these residues revealed that they were essential for catalase, but not peroxidase activity. Structural and kinetic analysis revealed that Arg426 acts as a molecular switch, moving between 2 conformations, favoring heme oxidation when not in association with Tyr238 and favoring heme reduction when in association with Tyr238 by imparting its influence on the heme through the cross-link. Analysis of the reaction with peroxyacetic acid using stopped-flow spectrophotometry revealed an initial, rapidly formed enzyme-substrate complex before the formation of the oxoferryl compound I. Kinetic characterization revealed that formation of both the enzyme-substrate complex and the oxoferryl species were dependent on peroxyacetic acid concentration implying that 2 molecules of peroxyacetic acid are required to form the oxoferryl compound I intermediate. Successful co-crystallization with INH and its co-substrate, NAD+ has revealed their binding sites for the first time in a KatG. The NAD+ binding site is 20 Å from the entrance to the heme cavity, involving interactions primarily with the ADP portion of the molecule. The best defined INH binding site is located in a funnel shaped channel on the opposite side of the protein from the entrance channel that requires the movement of a glutamate residue for binding. The structures suggest that once INH is cleaved to the isonicotinoyl radical it diffuses to the NAD+ binding site to form the final active antimicrobial compound, IN-NAD, in a non-enzymatic reaction enhanced by the enzyme’s ability to bind NAD+.

mycobacterium

tuberculosis

INH

catalase-peroxidase

KatG

biochemistry

x-ray

crystallography

kinetics

stopped-flow

molecular

structural

biology

protein

absorption

spectroscopy

site-directed

mutagenesis

isoniazid

Study of genes of the phytopathogenic fungus Verticillium longisporum involved in the colonization of xylem vessels of its host Brassica napus / Untersuchung von Genen des pflanzen pathogenen Pilzes Verticillium longisporum, die in die Kolonisation der Xylem gefäßen von der host Brassica napus involviert sind

Singh, Seema

22 January 2009

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Verticillium longisporum

Brassica napus

Chorismate Synthase

Katalase-Peroxidase

Proteom-Analyse

Verticillium longisporum

Brassica napus

chorismate synthase

catalase peroxidase

proteomic analysis

42. Biologie

W