The molecular structure of rabbit muscle pyruvate kinase, crystallized as a complex with Mn2+, K+, and pyruvate, has been solved to 2.9-A resolution. Crystals employed in the investigation belonged to the space group P1 and had unit cell dimensions a = 83.6 A, b = 109.9 A, c = 146.8 A, alpha = 94.9 degrees, beta = 93.6 degrees, and gamma = 112.3 degrees. There were two tetramers in the asymmetric unit. The structure was solved by molecular replacement, using as the search model the coordinates of the tetramer of pyruvate kinase from cat muscle [Muirhead, H., Claydon, D. A., Barford, D., Lorimer, C. G., Fothergill-Gilmore, L. A., Schiltz, E., & Schmitt, W. (1986) EMBO J.5, 475-481]. The amino acid sequence derived from the cDNA coding for the enzyme from rabbit muscle was fit to the electron density. The rabbit and cat muscle enzymes have approximately 94% sequence identity, and the folding patterns are expected to be nearly identical. There are, however, three regions where the topological models of the cat and rabbit pyruvate kinases differ. Mn2+ coordinates to the protein through the carboxylate side chains of Glu 271 and Asp 295. These two residues are strictly conserved in all known pyruvate kinases. In addition, the density for Mn2+ is connected to that of pyruvate, consistent with chelation through a carboxylate oxygen and the carbonyl oxygen of the substrate. The epsilon-NH2 of Lys 269 and the OH of Thr 327 lie on either side of the methyl group of bound pyruvate. Spherical electron density, assigned to K+, is located within a well-defined pocket of four oxygen ligands contributed by the carbonyl oxygen of Thr 113, O gamma of Ser 76, O delta 1 of Asn 74, and O delta 2 of Asp 112. The interaction of Asp 112 with the side chains of Lys 269 and Arg 72 may mediate, indirectly, monovalent cation effects on activity.
The fosfomycin resistance protein FosA is a member of a distinct superfamily of metalloenzymes containing glyoxalase I, extradiol dioxygenases, and methylmalonyl-CoA epimerase. The dimeric enzyme, with the aid of a single mononuclear Mn2+ site in each subunit, catalyzes the addition of glutathione (GSH) to the oxirane ring of the antibiotic, rendering it inactive. Sequence alignments suggest that the metal binding site of FosA is composed of three residues: H7, H67, and E113. The single mutants H7A, H67A, and E113A as well as the more conservative mutants H7Q, H67Q, and E113Q exhibit marked decreases in the ability to bind Mn2+ and, in most instances, decreases in catalytic efficiency and the ability to confer resistance to the antibiotic. The enzyme also requires the monovalent cation K+ for optimal activity. The K+ ion activates the enzyme 100-fold with an activation constant of 6 mM, well below the physiologic concentration of K+ in E. coli. K+ can be replaced by other monovalent cations of similar ionic radii. Several lines of evidence suggest that the K+ ion interacts directly with the active site. Interaction of the enzyme with K+ is found to be dependent on the presence of the substrate fosfomycin. Moreover, the E113Q mutant exhibits a kcat which is 40% that of wild-type in the absence of K+. This mutant is not activated by monovalent cations. The behavior of the E113Q mutant is consistent with the proposition that the K+ ion helps balance the charge at the metal center, further lowering the activation barrier for addition of the anionic nucleophile. The fully activated, native enzyme provides a rate acceleration of >10(15) with respect to the spontaneous addition of GSH to the oxirane.
Microsomal epoxide hydrolase (MEH) catalyzes the addition of water to epoxides in a two-step reaction involving initial attack of an active site carboxylate on the oxirane to give an ester intermediate followed by hydrolysis of the ester. An efficient bacterial expression system for the enzyme from rat that facilitates the production of native and mutant enzymes for mechanistic analysis is described. Pre-steady-state kinetics of the native enzyme toward glycidyl-4-nitrobenzoates, 1, indicate the rate-limiting step in the reaction is hydrolysis of the alkyl-enzyme intermediate. The enzyme is enantioselective, turning over (2R)-1 about 10-fold more efficiently than (2S)-1, and regiospecific toward both substrates with exclusive attack at the least hindered oxirane carbon. Facile isomerization of the monoglyceride product is observed and complicates the regiochemical analysis. The D226E and D226N mutants of the protein are catalytically inactive, behavior that is consistent with the role of D226 as the active-site nucleophile as suggested by sequence alignments with other alpha/beta-hydrolase fold enzymes. The D226N mutant undergoes hydrolytic autoactivation with a half-life of 9.3 days at 37 degreesC, suggesting that the mutant is still capable of catalyzing the hydrolytic half-reaction (in this instance an amidase reaction) and confirming that D226 is in the active site. The indoylyl side chain of W227, which is in or near the active site, is not required for efficient alkylation of the enzyme or for hydrolysis of the intermediate. However, the W227F mutant does exhibit altered stereoselectivity toward (2R)-1, (2S)-1, and phenanthrene-9,10-oxide, suggesting that modifications at this position might be used to manipulate the stereo- and regioselectivity of the enzyme.
Microsomal epoxide hydrolase (MEH) is a member of the alpha/beta-hydrolase fold family of enzymes, each of which has a catalytic triad consisting of a nucleophile involved in the formation of a covalent intermediate and a general base and charge relay carboxylate that catalyze the hydrolysis of the intermediate. The rate-limiting step in the catalytic mechanism of MEH is hydrolysis of the ester intermediate. An efficient bacterial expression system for a C-terminal hexahistidine tagged version of the native enzyme, which facilitates the isolation of mutant enzymes in which residues involved in the hydrolytic half-reaction have been altered, is described. The H431S mutant of this enzyme is efficiently alkylated by substrate to form the ester intermediate but is unable to hydrolyze the ester to complete the catalytic cycle, a fact that confirms that H431 acts as the base in the hydrolytic half-reaction. The charge relay carboxylate, which is not apparent in paired sequence alignments with other alpha/beta-hydrolase fold enzymes, is thought to be located between residues 340 and 405. A mutagenic survey of all eight Asp and Glu residues in this region reveals that only two (E376 and E404) influence the catalytic mechanism. Steady-state and pre-steady-state kinetic analyses of these residues suggest that both E404 and E376 may serve the charge relay function in the hydrolysis half-reaction. Finally, the tryptophan residue (W150), which resides in the oxyanion hole sequence HGWP, is demonstrated to contribute to the large change in intrinsic protein fluorescence observed when the enzyme is alkylated.
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