Crystal structure of saccharopine reductase from Magnaporthe grisea, an enzyme of the alpha-aminoadipate pathway of lysine biosynthesis.

BACKGROUND: The biosynthesis of the essential amino acid lysine in higher fungi and cyanobacteria occurs via the alpha-aminoadipate pathway, which is completely different from the lysine biosynthetic pathway found in plants and bacteria. The penultimate reaction in the alpha-aminoadipate pathway is catalysed by NADPH-dependent saccharopine reductase. We set out to determine the structure of this enzyme as a first step in exploring the structural biology of fungal lysine biosynthesis. RESULTS: We have determined the three-dimensional structure of saccharopine reductase from the plant pathogen Magnaporthe grisea in its apo form to 2.0 A resolution and as a ternary complex with NADPH and saccharopine to 2.1 A resolution. Saccharopine reductase is a homodimer, and each subunit consists of three domains, which are not consecutive in amino acid sequence. Domain I contains a variant of the Rossmann fold that binds NADPH. Domain II folds into a mixed seven-stranded beta sheet flanked by alpha helices and is involved in substrate binding and dimer formation. Domain III is all-helical. The structure analysis of the ternary complex reveals a large movement of domain III upon ligand binding. The active site is positioned in a cleft between the NADPH-binding domain and the second alpha/beta domain. Saccharopine is tightly bound to the enzyme via a number of hydrogen bonds to invariant amino acid residues. CONCLUSIONS: On the basis of the structure of the ternary complex of saccharopine reductase, an enzymatic mechanism is proposed that includes the formation of a Schiff base as a key intermediate. Despite the lack of overall sequence homology, the fold of saccharopine reductase is similar to that observed in some enzymes of the diaminopimelate pathway of lysine biosynthesis in bacteria. These structural similarities suggest an evolutionary relationship between two different major families of amino acid biosynthetic pathway, the glutamate and aspartate families.

Tight binding inhibitors of scytalone dehydratase: effects of site-directed mutations.

We explore the use of site-directed mutations of scytalone dehydratase to study inhibitor binding interactions. The enzyme is the physiological target of new fungicides and the subject of inhibitor design and optimization. X-ray structures show that potent inhibitors (K(i)'s approximately 10(-)(11) M) interact mostly with 11 amino acid side chains and, in some cases, with a single backbone amide. Fifteen site-directed mutants of the 11 enzyme residues were prepared to disrupt enzyme-inhibitor interactions, and inhibition constants for 13 inhibitors were determined to assess changes in binding potencies. The results indicate that two of the six hydrogen bonds (always present in X-ray structures of native enzyme-inhibitor complexes) are not important for inhibitor binding. The other four hydrogen bonds are important for inhibitor binding, and the strength of the individual bonds is inhibitor-dependent. Inhibitor atoms remote from the hydrogen bonds influence their strength, presumably by effecting small changes in inhibitor orientation. Several hydrophobic amino acid residues are important recognition elements for lipophilic inhibitor functionalities, which is fully consistent with X-ray structures determined from crystals of enzyme-inhibitor complexes grown at neutral pH but not with those determined from crystals grown under acidic conditions. This study of mutant enzymes complements insights from X-ray structures and structure-activity relationships of the wild-type enzyme for refining views of inhibitor recognition.

Cloning, expression, purification and crystallization of saccharopine reductase from Magnaporthe grisea.

The gene coding for saccharopine reductase (E.C. 1.5.1.10), an enzyme of the alpha-aminoadipic pathway of lysine biosynthesis in the pathogenic fungus Magnaporthe grisea, was cloned and expressed in Escherichia coli. The purified enzyme was crystallized in space groups C2 and C222(1) using ammonium sulfate pH 4.8 or PEG 6000 pH 4. 1 as precipitants. The unit-cell parameters are a = 115.0, b = 56.6, c = 74.3 A, beta = 111.1 degrees for space group C2, and a = 89.3, b = 119.0, c = 195.9 A for space group C222(1). The crystals diffract to resolutions of 2.0 A (C2) and 2.4 A (C222(1)) at synchrotron sources.

High-resolution structures of scytalone dehydratase-inhibitor complexes crystallized at physiological pH.

Scytalone dehydratase is a molecular target of inhibitor design efforts aimed at preventing the fungal disease caused by Magnaporthe grisea. A method for cocrystallization of enzyme with inhibitors at neutral pH has produced several crystal structures of enzyme-inhibitor complexes at resolutions ranging from 1.5 to 2.2 A. Four high resolution structures of different enzyme-inhibitor complexes are described. In contrast to the original X-ray structure of the enzyme, the four new structures have well-defined electron density for the loop region comprising residues 115-119 and a different conformation between residues 154 and 160. The structure of the enzyme complex with an aminoquinazoline inhibitor showed that the inhibitor is in a position to form a hydrogen bond with the amide of the Asn131 side chain and with two water molecules in a fashion similar to the salicylamide inhibitor in the original structure, thus confirming design principles. The aminoquinazoline structure also allows for a more confident assignment of donors and acceptors in the hydrogen bonding network. The structures of the enzyme complexes with two dichlorocyclopropane carboxamide inhibitors showed the two chlorine atoms nearly in plane with the amide side chain of Asn131. The positions of Phe53 and Phe158 are significantly altered in the new structures in comparison to the two structures obtained from crystals grown at acidic pH. The multiple structures help define the mobility of active site amino acids critical for catalysis and inhibitor binding.

Catalytic mechanism of scytalone dehydratase: site-directed mutagenisis, kinetic isotope effects, and alternate substrates.

On the basis of the X-ray crystal structure of scytalone dehydratase complexed with an active center inhibitor [Lundqvist, T., Rice, J., Hodge, C. N., Basarab, G. S., Pierce, J. and Lindqvist, Y. (1994) Structure (London) 2, 937-944], eight active-site residues were mutated to examine their roles in the catalytic mechanism. All but one residue (Lys73, a potential base in an anti elimination mechanism) were found to be important to catalysis or substrate binding. Steady-state kinetic parameters for the mutants support the native roles for the residues (Asn131, Asp31, His85, His110, Ser129, Tyr30, and Tyr50) within a syn elimination mechanism. Relative substrate specificities for the two physiological substrates, scytalone and veremelone, versus a Ser129 mutant help assign the orientation of the substrates within the active site. His85Asn was the most damaging mutation to catalysis consistent with its native roles as a general base and a general acid in a syn elimination. The additive effect of Tyr30Phe and Tyr50Phe mutations in the double mutant is consistent with their roles in protonating the substrate's carbonyl through a water molecule. Studies on a synthetic substrate, which has an anomeric carbon atom which can better stabilize a carbocation than the physiological substrate (vermelone), suggest that His110Asn prefers this substrate over vermelone in order to balance the mutation-imposed weakness in promoting the elimination of hydroxide from substrates. All mutant enzymes bound a potent active-site inhibitor in near 1:1 stoichiometry, thereby supporting their active-site integrity. An X-ray crystal structure of the Tyr50Phe mutant indicated that both active-site waters were retained, likely accounting for its residual catalytic activity. Steady-state kinetic parameters with deuterated scytalone gave kinetic isotope effects of 2.7 on kcat and 4.2 on kcat/Km, suggesting that steps after dehydration partially limit kcat. Pre-steady-state measurements of a single-enzyme turnover with scytalone gave a rate that was 6-fold larger than kcat. kcat/Km with scytalone has a pKa of 7.9 similar to the pKa value for the ionization of the substrate's C6 phenolic hydroxyl, whereas kcat was unaffected by pH, indicating that the anionic form of scytalone does not bind well to enzyme. With an alternate substrate having a pKa above 11, kcat/Km had a pKa of 9.3 likely due to the ionization of Tyr50. The non-enzyme-catalyzed rate of dehydration of scytalone was nearly a billion-fold slower than the enzyme-catalyzed rate at pH 7.0 and 25 degrees C. The non-enzyme-catalyzed rate of dehydration of scytalone had a deuterium kinetic isotope effect of 1.2 at pH 7.0 and 25 degrees C, and scytalone incorporated deuterium from D2O in the C2 position about 70-fold more rapidly than the dehydration rate. Thus, scytalone dehydrates through an E1cb mechanism off the enzyme.

Mechanisms of fungicide resistance in phytopathogenic fungi.

The disciplines traditionally used to investigate the mode of action of fungicides have been biochemistry and physiology. Over the past decade, classical and molecular genetics have been brought to bear on this problem with increasing success. Recently, genetic studies of fungicide resistance have led to advances in our understanding of the site of action of chemicals active against plant pathogens and, in some cases, to an appreciation of additional mechanisms of resistance to fungicide action.

Microbial hydroxylation of 1,4-cineole.

Microorganisms were examined for their potential to hydroxylate the oxygenated monoterpene 1,4-cineole. Using gas chromatography and thin-layer chromatography, screening experiments revealed that hydroxylation at position 2 was the most commonly observed microbial transformation reaction. In most microorganisms, the predominant alcohol metabolite was the 2-endo-alcohol isomer. Preparative-scale incubations were conducted in order to isolate and characterize microbial transformation products by comparison of proton nuclear magnetic resonance, mass spectrometry, and chromatography profiles with those of cineole standards. Streptomyces griseus yielded 8-hydroxy-1,4-cineole as the major hydroxylation product together with 2-exo- and 2-endo-hydroxy-1,4-cineoles.

Catalysis of phosphoryl group transfer. The role of divalent metal ions in the hydrolysis of lactic acid O-phenyl phosphate and salicylic acid O-aryl phosphates.

The spontaneous hydrolyses of lactic acid O-phenyl phosphate (I) and, to a lesser extent, 3-hydroxybutyric acid O-phenyl phosphate (II) have been investigated and compared with similar intramolecular and bimolecular reactions. Compared to bimolecular nucleophilic reactions, the reactivity of II is similar to other systems involving the formation of a six-membered ring intermediate, which suggests that the electrostatic barrier to attack of an anionic nucleophile on a phosphate diester anion is fully present in II. The reactivity of I, as compared to that of II, would suggest that at least a partial overcoming of the electrostatic barrier takes place upon closer approimation of the two reacting centers. The Mn-2+-catalyzed hydrolysis of I exhibits saturation kinetics, consistent with the enhanced reactivity of the metal ion-substrate complex. The binding constant for this complex, determined from kinetics, is in good agreement with that obtained by electron spin resonance (ESR) titration. It is argued that the complex of Mn-2+ with II, as observed by pulsed Fourier transform nuclear magnetic resonance (NMR) techniques, is a precursor to the complex of catalytic significance. The hydrolysis of I as catalyzed by a variety of divalent metal ions suggests an optimal metal ion size. The spontaneous and metal ion catalyzed hydrolyses of salicyclic acid O-aryl phosphates (IIIa-d) proceed through cyclic acyl phosphate intermediates after expulsion of phenol. Product studies on the parent compound have failed to detect phenyl phosphate as a product in either the spontaneous or metal ion catalyzed process. The dependence of the second-order rate constant for the metal-catalyzed hydrolysis on leaving group pKa, beta-1-g, decreases significantly relative to beta-1-g for the spontaneous hydrolysis. From the collective data a specific interation of the metal ion with a pentacovalent intermediate is inferred in the rate-determining step for esters I and III. The probable consequences of these mechanistic postulates for phosphoryl transfer reactions in biological systems are discussed.