Abstract
Oxalacetate acetylhydrolase (OAH), a member of the phosphoenolpyruvate mutase/isocitrate lyase superfamily, catalyzes the hydrolysis of oxalacetate to oxalic acid and acetate. This study shows that knock-out of the oah gene in Cryphonectria parasitica, the chestnut blight fungus, reduces the ability of the fungus to form cankers on chestnut trees, suggesting that OAH plays a key role in virulence. OAH was produced in Escherichia coli and purified, and its catalytic rates were determined. Oxalacetate is the main OAH substrate, but the enzyme also acts as a lyase of (2R,3S)-dimethyl malate with approximately 1000-fold lower efficacy. The crystal structure of OAH was determined alone, in complex with a mechanism-based inhibitor, 3,3-difluorooxalacetate (DFOA), and in complex with the reaction product, oxalate, to a resolution limit of 1.30, 1.55, and 1.65 A, respectively. OAH assembles into a dimer of dimers with each subunit exhibiting an (alpha/beta)(8) barrel fold and each pair swapping the 8th alpha-helix. An active site "gating loop" exhibits conformational disorder in the ligand-free structure. To obtain the structures of the OAH.ligand complexes, the ligand-free OAH crystals were soaked briefly with DFOA or oxalacetate. DFOA binding leads to ordering of the gating loop in a conformation that sequesters the ligand from the solvent. DFOA binds in a gem-diol form analogous to the oxalacetate intermediate/transition state. Oxalate binds in a planar conformation, but the gating loop is largely disordered. Comparison between the OAH structure and that of the closely related enzyme, 2,3-dimethylmalate lyase, suggests potential determinants of substrate preference.
Highlights
Pathogenesis and virulence [2,3,4,5]
The remaining three enzymes, Petal Death Protein (PDP), DMML, and Oxalacetate acetylhydrolase (OAH), whose amino acid sequences are aligned in Fig. 2, exhibit varying levels of substrate promiscuity except that they do not act on carboxy-PEP
The A. niger OAH was not produced in soluble form, but the closely related B. cinerea OAH catalyzes the hydrolysis of its primary substrate, oxalacetate, with kcat/Km ϭ 1.5 ϫ 105 MϪ1 sϪ1 and the cleavage of (2R,3S)-dimethylmalate with 750-fold lower efficacy of kcat/Km ϭ 2 ϫ 102 MϪ1 sϪ1 [1]
Summary
Pathogenesis and virulence [2,3,4,5]. The virulence mechanism is believed to be due to acidification that triggers lignocellulose degradation, reduces viability of host tissue in favor of pathogen proliferation, and induces crystallization of calcium oxalate, which blocks vessels or bronchioles [4, 6, 7]. Phylogeny analysis of the PEPM/ICL superfamily highlighted an intriguing clade that contains enzymes with different catalytic activities, in contrast to other phylogeny branches, which include enzymes that perform a single catalytic activity [13] This cluster includes the Petal Death Protein (PDP), shown to be a lyase that cleaves ␣-keto and ␣-hydroxycarboxylic acids with broad substrate specificity [20], carboxy-PEPM [21], 2,3dimethylmalate lyase (DMML) [14], and OAH [1]. The A. niger OAH was not produced in soluble form, but the closely related B. cinerea OAH catalyzes the hydrolysis of its primary substrate, oxalacetate, with kcat/Km ϭ 1.5 ϫ 105 MϪ1 sϪ1 and the cleavage of (2R,3S)-dimethylmalate with 750-fold lower efficacy of kcat/Km ϭ 2 ϫ 102 MϪ1 sϪ1 [1]. A strategy to reduce the pathogenicity of C. parasitica by transforming chestnut trees with the oxalate-degrading enzyme, oxalate oxidase, was proposed based on studies that showed that transgenic American chestnut callus tissue expressing oxalate oxidase protected the tissue from loss of lignin [25]
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