Your search keyword '"Frank Jordan"' showing total 56 results

1. Active Site Histidines Link Conformational Dynamics with Catalysis on Anti-Infective Target 1-Deoxy-d-xylulose 5-Phosphate Synthase

Author

Alicia A. DeColli, Frank Jordan, Caren L. Freel Meyers, Xu Zhang, and Kathryn L. Heflin

Subjects

Stereochemistry, Decarboxylation, Protein Conformation, Amino Acid Motifs, Crystallography, X-Ray, Biochemistry, Article, Catalysis, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Protein structure, Biosynthesis, Transferases, Catalytic Domain, Escherichia coli, Histidine, Pyridoxal phosphate, Aldose-Ketose Isomerases, 0303 health sciences, Pentosephosphates, biology, ATP synthase, 030302 biochemistry & molecular biology, Active site, chemistry, biology.protein, DXP synthase

Abstract

The product of 1-deoxy-d-xyluose 5-phosphate (DXP) synthase, DXP, feeds into the bacterial biosynthesis of isoprenoids, thiamin diphosphate (ThDP), and pyridoxal phosphate. DXP is essential for human pathogens but not utilized by humans; thus, DXP synthase is an attractive anti-infective target. The unique ThDP-dependent mechanism and structure of DXP synthase offer ideal opportunities for selective targeting. Upon reaction with pyruvate, DXP synthase uniquely stabilizes the predecarboxylation intermediate, C2α-lactylThDP (LThDP), in a closed conformation. Subsequent binding of d-glyceraldehyde 3-phosphate induces an open conformation that is proposed to destabilize LThDP, triggering decarboxylation. Evidence for the closed and open conformations has been revealed by hydrogen-deuterium exchange mass spectrometry and X-ray crystallography, which indicate that H49 and H299 are involved in conformational dynamics and movement of the fork and spoon motifs away from the active site is important for the closed-to-open transition. Interestingly, H49 and H299 are critical for DXP formation and interact with the predecarboxylation intermediate in the closed conformation. H299 is removed from the active site in the open conformation of the postdecarboxylation state. In this study, we show that substitution at H49 and H299 negatively impacts LThDP formation by shifting the conformational equilibrium of DXP synthase toward an open conformation. We also present a method for monitoring the dynamics of the spoon motif that uncovered a previously undetected role for H49 in coordinating the closed conformation. Overall, our results suggest that H49 and H299 are critical for the closed, predecarboxylation state providing the first direct link between catalysis and conformational dynamics.

Published

2019

2. Elucidation of the Interaction Loci of the Human Pyruvate Dehydrogenase Complex E2·E3BP Core with Pyruvate Dehydrogenase Kinase 1 and Kinase 2 by H/D Exchange Mass Spectrometry and Nuclear Magnetic Resonance

Author

Yun-Hee Park, Frank Jordan, Lazaros Kakalis, Jieyu Zhou, Barbara Birkaya, Sowmini Kumaran, Mulchand S. Patel, Hu Tao, Natalia S. Nemeria, and Junjie Wang

Subjects

Pyruvate dehydrogenase kinase, Molecular Sequence Data, Plasma protein binding, Protein Serine-Threonine Kinases, Biology, Biochemistry, Mass Spectrometry, Protein Structure, Secondary, Article, Serine, 03 medical and health sciences, Nuclear magnetic resonance, Animals, Humans, Amino Acid Sequence, Nuclear Magnetic Resonance, Biomolecular, Peptide sequence, 030304 developmental biology, 0303 health sciences, Protein-Serine-Threonine Kinases, Kinase, 030302 biochemistry & molecular biology, Deuterium Exchange Measurement, Pyruvate Dehydrogenase Acetyl-Transferring Kinase, Pyruvate dehydrogenase complex, Rats, Phosphorylation, Protein Binding

Abstract

The human pyruvate dehydrogenase complex (PDC) comprises three principal catalytic components for its mission: E1, E2, and E3. The core of the complex is a strong subcomplex between E2 and an E3-binding protein (E3BP). The PDC is subject to regulation at E1 by serine phosphorylation by four kinases (PDK1–4), an inactivation reversed by the action of two phosphatases (PDP1 and -2). We report H/D exchange mass spectrometric (HDX-MS) and nuclear magnetic resonance (NMR) studies in the first attempt to define the interaction loci between PDK1 and PDK2 with the intact E2·E3BP core and their C-terminally truncated proteins. While the three lipoyl domains (L1 and L2 on E2 and L3 on E3BP) lend themselves to NMR studies and determination of interaction maps with PDK1 and PDK2 at the individual residue level, HDX-MS allowed studies of interaction loci on both partners in the complexes, PDKs, and other regions of the E2·E3BP core, as well, at the peptide level. HDX-MS suggested that the intact E2·E3BP core enhances the binding specificity of L2 for PDK2 over PDK1, while NMR studies detected lipoyl domain residues unique to interaction with PDK1 and PDK2. The E2·E3BP core induced more changes on PDKs than any C-terminally truncated protein, with clear evidence of greater plasticity of PDK1 than of PDK2. The effect of L1L2S paralleled HDX-MS results obtained with the intact E2·E3BP core; hence, L1L2S is an excellent candidate with which to define interaction loci with these two PDKs. Surprisingly, L3S′ induced moderate interaction with both PDKs according to both methods.

Published

2014

3. Identification of Charge Transfer Transitions Related to Thiamin-Bound Intermediates on Enzymes Provides a Plethora of Signatures Useful in Mechanistic Studies

Author

Michael J. McLeish, Natalia S. Nemeria, Hetalben Patel, Frank Jordan, and Forest H. Andrews

Subjects

Circular dichroism, biology, Molecular Structure, Stereochemistry, Chemistry, Circular Dichroism, Conjugated system, Biochemistry, Electron transport chain, Cofactor, Article, Electron Transport, Covalent bond, Electrophile, biology.protein, Side chain, Molecule, Thiamine, Thiamine Pyrophosphate, Pyruvate Decarboxylase

Abstract

Identification of enzyme-bound intermediates via their spectroscopic signatures, which then allows direct monitoring of the kinetic fate of these intermediates, poses a continuing challenge. As an electrophilic covalent catalyst, the thiamin diphosphate (ThDP) coenzyme forms a number of noncovalent and covalent intermediates along its reaction pathways, and multiple UV–vis and circular dichroism (CD) bands have been identified at Rutgers pertinent to several among them. These electronic transitions fall into two classes: those for which the conjugated system provides a reasonable guide to the observed λmax and others in which there is no corresponding conjugated system and the observed CD bands are best ascribed to charge transfer (CT) transitions. Herein is reported the reaction of four ThDP enzymes with alternate substrates: (a) acetyl pyruvate, its methyl ester, and fluoropyruvate, these providing the shortest side chains attached at the thiazolium C2 atom and leading to CT bands with λmax values of >390 nm, not pertinent to any on-pathway conjugated systems (estimated λmax values of

Published

2014

4. Proton Bridging in the Interactions of Thrombin with Hirudin and Its Mimics

Author

Frank Jordan, Daoning Zhang, Lazaros Kakalis, and Ildiko M. Kovach

Subjects

Models, Molecular, Stereochemistry, Molecular Sequence Data, Hirudin, Peptide, Biochemistry, Antithrombins, Article, Hydrophobic effect, Thrombin, medicine, Humans, Amino Acid Sequence, Binding site, Nuclear Magnetic Resonance, Biomolecular, chemistry.chemical_classification, Serine protease, Binding Sites, biology, Substrate (chemistry), Hydrogen Bonding, Hirudins, chemistry, Covalent bond, biology.protein, Protons, medicine.drug

Abstract

Thrombin is the pivotal serine protease enzyme in the blood cascade system and thus a target of drug design for control of its activity. The most efficient nonphysiologic inhibitor of thrombin is hirudin, a naturally occurring small protein. Hirudin and its synthetic mimics employ a range of hydrogen bonding, salt bridging, and hydrophobic interactions with thrombin to achieve tight binding with K(i) values in the nano- to femtomolar range. The one-dimensional (1)H nuclear magnetic resonance spectrum recorded at 600 MHz reveals a resonance 15.33 ppm downfield from silanes in complexes between human α-thrombin and r-hirudin in pH 5.6-8.8 buffers and between 5 and 35 °C. There is also a resonance between 15.17 and 15.54 ppm seen in complexes of human α-thrombin with hirunorm IV, hirunorm V, an Nα(Me)Arg peptide, RGD-hirudin, and Nα-2-naphthylsulfonyl-glycyl-DL-4-amidinophenylalanyl-piperidide acetate salt (NAPAP), while there is no such low-field resonance observed in a complex of porcine trypsin and NAPAP. The chemical shifts suggest that these resonances represent H-bonded environments. H-Donor-acceptor distances in the corresponding H-bonds are estimated to be

Published

2013

5. Interchain Acetyl Transfer in the E2 Component of Bacterial Pyruvate Dehydrogenase Suggests a Model with Different Roles for Each Chain in a Trimer of the Homooligomeric Component

Author

Jaeyoung Song and Frank Jordan

Subjects

Alanine, Spectrometry, Mass, Electrospray Ionization, Bacteria, Base Sequence, biology, Chemistry, Stereochemistry, Lysine, Pyruvate Dehydrogenase Complex, Trimer, Pyruvate dehydrogenase complex, Biochemistry, Article, Cofactor, Complementation, Biopolymers, Acetyl Coenzyme A, Acetylation, Mutagenesis, Site-Directed, biology.protein, Histidine, DNA Primers

Abstract

The bacterial pyruvate dehydrogenase complex (PDHc) carries out conversion of pyruvate to acetyl-coenzymeA with the assistance of three principal protein components E1, E2 and E3(1) (Scheme 1). In the mammalian enzyme(2), there are three additional components mostly responsible for regulation: a kinase, a phosphatase and an E3-binding protein (E3BP)(3, 4). Each component exists in multiple copies with total molecular masses in the range of 4.5–10 MDa. The multi-domain E2 component forms the core of the complexes [see domain structure for E2 from Escheerichia coli (E2ec) in Scheme 2]. It consists of variable number (1–3) of LD’s to which the cofactor lipoic acid is covalently attached in a post-translational reaction, a PSBD, and a CD, where acetyl-CoA is produced(1). Although the number of copies of the icosahedral mammalian E2 is still controversial, there is agreement that the sum (E2+E3BP) is 60, a multiple of three(5–7), while there are 24 copies of the octahedral E. coli E2 (E2ec), again a multiple of three(1). For the E. coli PDHc a stoichiometry of 12 E1ec dimers, 8 E2ec trimers and 6 E3ec dimers was proposed(8–12). All 24 copies of E2ec have LD and CD, and it is plausible that inter-chain acyl transfer would take place between an LD of one chain and the CD of a different one, with mobility of LD afforded by flexible Ala-Pro-rich linkers(8–11, 13–16). The comment in ref. 12, that “A morphological unit consisting of three subunits appears to be important in the assembly of both types of polyhedral forms” (icosahedral or octahedral), prompted us to explore potential mechanistic consequences of this observation. Scheme 1 Mechanism of pyruvate dehydrogenase complex Scheme 2 Domain architecture of wild-type E2ec. We here address the question of whether the acetyl group is passed from the LD to the CD in an intra- or inter-chain reaction by using an E. coli E2 component designed with only a single LD (1-lip E2ec), rather than the three LDs in the wild type enzyme (3-lip E2ec). Earlier, it was shown that the activities of 1-lip E2ec and 3-lip E2ec are virtually the same, while the 1-lip E2ec offers advantages for mechanistic studies(17–19). Two types of constructs of the 1-lip E2ec were prepared to test our hypothesis: one in which the lysine on the LD ordinarily carrying the lipoic acid is changed to alanine (K41A), and two others in which the histidine believed to catalyze the trans-thiolacetylation in the CD is substituted to A or C, H399C and H399A. The first variant is incompetent towards post-translational ligation of the lipoic acid, hence towards reductive acetylation. The other two variants are potentially incompetent towards acetyl-CoA formation by virtue of the absence of the catalytic histidine residue. These constructs then enable us to carry out a complementation experiment: should acetyl transfer reaction proceed intra-chain, the two types of constructs should each be inactive either together or individually; however, should acetyl transfer proceed inter-chain, addition of the two types of constructs should produce measurable activity. As control, the K41A/H399C doubly substituted variant was also constructed, carrying neither a lipoylation site, nor the active center His. The experimental design for this complementation of E2ec variants is illustrated in Figure 1. We confirmed the results of the kinetics experiments by ascertaining acetylCoA formation from CoA using mass spectrometric analysis. The results suggest a plausible model for utilization of multiples of three chains present in E2 components, and for their assembly in the bacterial class of such complexes. Figure 1 Complementation experiments designed to test for inter-chain acetyl transfer on E2ec. (a) The experiment to monitor inter-subunit acetyl transfer between K41A E2ec and H399C E2ec. (b) Control experiment with doubly substituted variant (K41A/H399C E2ec). ...

Published

2012

6. Double Duty for a Conserved Glutamate in Pyruvate Decarboxylase: Evidence of the Participation in Stereoelectronically Controlled Decarboxylation and in Protonation of the Nascent Carbanion/Enamine Intermediate

Author

Natalia S. Nemeria, Piotr Neumann, Kai Tittmann, Christoph Parthier, Danilo Meyer, Frank Jordan, and Rudolf Friedemann

Subjects

Stereochemistry, Decarboxylation, Glutamic Acid, Protonation, Crystallography, X-Ray, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, Cofactor, Enamine, 03 medical and health sciences, chemistry.chemical_compound, Organic chemistry, Amines, 030304 developmental biology, Carbanion, Zymomonas, 0303 health sciences, Binding Sites, biology, X-Rays, Active site, Lyase, 0104 chemical sciences, chemistry, biology.protein, Thermodynamics, Thiamine Pyrophosphate, Pyruvate decarboxylase

Abstract

Pyruvate decarboxylase (PDC) catalyzes the nonoxidative decarboxylation of pyruvate into acetaldehyde and carbon dioxide and requires thiamin diphosphate (ThDP) and a divalent cation as cofactors. Recent studies have permitted the assignment of functional roles of active site residues; however, the underlying reaction mechanisms of elementary steps have remained hypothetical. Here, a kinetic and thermodynamic single-step analysis in conjunction with X-ray crystallographic studies of PDC from Zymomonas mobilis implicates active site residue Glu473 (located on the re-face of the ThDP thiazolium nucleus) in facilitating both decarboxylation of 2-lactyl-ThDP and protonation of the 2-hydroxyethyl-ThDP carbanion/enamine intermediate. Variants carrying either an isofunctional (Glu473Asp) or isosteric (Glu473Gln) substitution exhibit a residual catalytic activity of less than 0.1% but accumulate different intermediates at the steady state. Whereas the predecarboxylation intermediate 2-lactyl-ThDP is accumulated in Glu473Asp because of a 3000-fold slower decarboxylation compared to that of the wild-type enzyme, Glu473Gln is not impaired in decarboxylation but generates a long-lived 2-hydroxyethyl-ThDP carbanion/enamine postdecarboxylation intermediate. CD spectroscopic analysis of the protonic and tautomeric equilibria of the cocatalytic aminopyrimidine part of ThDP indicates that an acidic residue is required at position 473 for proper substrate binding. Wild-type PDC and the Glu473Asp variant bind the substrate analogue acetylphosphinate with the same affinity, implying a similar stabilization of the predecarboxylation intermediate analogue on the enzyme, whereas Glu473Gln fails to bind the analogue. The X-ray crystallographic structure of 2-lactyl-ThDP trapped in the decarboxylation-deficient variant Glu473Asp reveals a common stereochemistry of the intermediate C2α stereocenter; however, the scissile C2α-C(carboxylate) bond deviates by ∼25-30° from the perpendicular "maximum overlap" orientation relative to the thiazolium ring plane as commonly observed in ThDP enzymes. Because a reactant-state stabilization of the predecarboxylation intermediate can be excluded to account for the slower decarboxylation, the data suggest a strong stereoelectronic effect for the transition state of decarboxylation as supported by additional DFT studies on models. To the best of our knowledge, this is a very rare example in which the magnitude of a stereoelectronic effect could be experimentally estimated for an enzymatic system. Given that variant Glu473Gln is not decarboxylation-deficient, electrostatic stress can be excluded as a driving force for decarboxylation. The apparent dual function of Glu473 further suggests that decarboxylation and protonation of the incipient carbanion are committed and presumably proceed in the same transition state.

Published

2010

7. Proton Bridging in the Interactions of Thrombin with Small Inhibitors

Author

Ildiko M. Kovach, Frank Jordan, Carol Eddy, Ahmet Tarik Baykal, and Paul Kelley

Subjects

Serine Proteinase Inhibitors, Stereochemistry, Amino Acid Chloromethyl Ketones, Biochemistry, Article, chemistry.chemical_compound, Thrombin, medicine, Humans, chemistry.chemical_classification, Serine protease, Molecular Structure, biology, Hydrogen-Ion Concentration, Phosphate, Phosphonate, Enzyme, chemistry, Covalent bond, biology.protein, Protons, medicine.drug

Abstract

Thrombin is the pivotal serine protease enzyme in the blood cascade system. Phe-Pro-Arg-chloromethylketone (PPACK), phosphate, and phosphonate ester inhibitors form a covalent bond with the active-site Ser of thrombin. PPACK, a mechanism-based inhibitor, and the phosphate/phosphonate esters form adducts that mimic intermediates formed in reactions catalyzed by thrombin. Therefore, the dependence of the inhibition of human alpha-thrombin on the concentration of these inhibitors, pH, and temperature was investigated. The second-order rate constant (ki/Ki) and the inhibition constant (Ki) for inhibition of human alpha-thrombin by PPACK are (1.1 +/- 0.2) x 10(7) M(-1) s(-1) and (2.4 +/- 1.3) x 10(-8) M, respectively, at pH 7.00 in 0.05 M phosphate buffer and 0.15 M NaCl at 25.0 +/- 0.1 degrees C, in good agreement with previous reports. The activation parameters at pH 7.00 in 0.05 M phosphate buffer and 0.15 M NaCl are as follows: DeltaH = 10.6 +/- 0.7 kcal/mol, and DeltaS = 9 +/- 2 cal mol(-1) degrees C(-1). The pH dependence of the second-order rate constants of inhibition is bell-shaped. Values of pKa1 and pKa2 are 7.3 +/- 0.2 and 8.8 +/- 0.3, respectively, at 25.0 +/- 0.1 degrees C. A phosphate and a phosphonate ester inhibitor gave higher values, 7.8 and 8.0 for pKa1 and 9.3 and 8.6 for pKa2, respectively. They inhibit thrombin more than 6 orders of magnitude less efficiently than PPACK does. The deuterium solvent isotope effect for the second-order rate constant at pH 7.0 and 8.3 at 25.0 +/- 0.1 degrees C is unity within experimental error in all three cases, indicating the absence of proton transfer in the rate-determining step for the association of thrombin with the inhibitors, but in a 600 MHz 1H NMR spectrum of the inhibition adduct at pH 6.7 and 30 degrees C, a peak at 18.10 ppm with respect to TSP appears with PPACK, which is absent in the 1H NMR spectrum of a solution of the enzyme between pH 5.3 and 8.5. The peak at low field is an indication of the presence of a short-strong hydrogen bond (SSHB) at the active site in the adduct. The deuterium isotope effect on this hydrogen bridge is 2.2 +/- 0.2 (phi = 0.45). The presence of an SSHB is also established with a signal at 17.34 ppm for a dealkylated phosphate adduct of thrombin.

Published

2009

8. Detection and Time Course of Formation of Major Thiamin Diphosphate-Bound Covalent Intermediates Derived from a Chromophoric Substrate Analogue on Benzoylformate Decarboxylase

Author

Gregory A. Petsko, Michael J. McLeish, Anand Balakrishnan, Alejandra Yep, Frank Jordan, Sumit Chakraborty, Gabriel S. Brandt, Natalia Nemeria, Malea M. Kneen, Dagmar Ringe, and George L. Kenyon

Subjects

Time Factors, Carboxy-Lyases, Pyridines, Decarboxylation, Stereochemistry, Crystallography, X-Ray, Biochemistry, Catalysis, Article, Benzoylformate decarboxylase, Substrate Specificity, Adduct, Enamine, Benzaldehyde, chemistry.chemical_compound, Fluorescent Dyes, Binding Sites, Pseudomonas putida, Substrate (chemistry), Lyase, Butyrates, Kinetics, chemistry, Covalent bond, Thiamine Pyrophosphate, Protein Binding

Abstract

The mechanism of the enzyme benzoylformate decarboxylase (BFDC), which carries out a typical thiamin diphosphate (ThDP)-dependent nonoxidative decarboxylation reaction, was studied with the chromophoric alternate substrate (E)-2-oxo-4(pyridin-3-yl)-3-butenoic acid (3-PKB). Addition of 3-PKB resulted in the appearance of two transient intermediates formed consecutively, the first one to be formed a predecarboxylation ThDP-bound intermediate with lambda(max) at 477 nm, and the second one corresponding to the first postdecarboxylation intermediate the enamine with lambda(max) at 437 nm. The time course of formation/depletion of the PKB-ThDP covalent complex and of the enamine showed that decarboxylation was slower than formation of the PKB-ThDP covalent adduct. When the product of decarboxylation 3-(pyridin-3-yl)acrylaldehyde (PAA) was added to BFDC, again an absorbance with lambda(max) at 473 nm was formed, corresponding to the tetrahedral adduct of PAA with ThDP. Addition of well-formed crystals of BFDC to a solution of PAA resulted in a high resolution (1.34 A) structure of the BFDC-bound adduct of ThDP with PAA confirming the tetrahedral nature at the C2alpha atom, rather than of the enamine, and supporting the assignment of the lambda(max) at 473 nm to the PAA-ThDP adduct. The structure of the PAA-ThDP covalent complex is the first example of a product-ThDP adduct on BFDC. Similar studies with 3-PKB indicated that decarboxylation had taken place. Evidence was also obtained for the slow formation of the enamine intermediate when BFDC was incubated with benzaldehyde, the product of the decarboxylation reaction thus confirming its presence on the reaction pathway.

Published

2009

9. Probing the Active Center of Benzaldehyde Lyase with Substitutions and the Pseudosubstrate Analogue Benzoylphosphonic Acid Methyl Ester

Author

Alejandra Yep, Gabriel S. Brandt, Michael J. McLeish, Natalia Nemeria, George L. Kenyon, Sumit Chakraborty, Frank Jordan, Dagmar Ringe, and Gregory A. Petsko

Subjects

Models, Molecular, Stereochemistry, Crystallography, X-Ray, Biochemistry, Article, Cofactor, Substrate Specificity, Active center, Benzaldehyde, chemistry.chemical_compound, Benzoin, Aromatic amino acids, Aldehyde-Lyases, chemistry.chemical_classification, Binding Sites, biology, Circular Dichroism, Active site, Lyase, Amino acid, Kinetics, Enzyme, chemistry, Benzaldehydes, biology.protein, Thiamine Pyrophosphate

Abstract

Benzaldehyde lyase (BAL) catalyzes the reversible cleavage of ( R)-benzoin to benzaldehyde utilizing thiamin diphosphate and Mg (2+) as cofactors. The enzyme is important for the chemoenzymatic synthesis of a wide range of compounds via its carboligation reaction mechanism. In addition to its principal functions, BAL can slowly decarboxylate aromatic amino acids such as benzoylformic acid. It is also intriguing mechanistically due to the paucity of acid-base residues at the active center that can participate in proton transfer steps thought to be necessary for these types of reactions. Here methyl benzoylphosphonate, an excellent electrostatic analogue of benzoylformic acid, is used to probe the mechanism of benzaldehyde lyase. The structure of benzaldehyde lyase in its covalent complex with methyl benzoylphosphonate was determined to 2.49 A (Protein Data Bank entry 3D7K ) and represents the first structure of this enzyme with a compound bound in the active site. No large structural reorganization was detected compared to the complex of the enzyme with thiamin diphosphate. The configuration of the predecarboxylation thiamin-bound intermediate was clarified by the structure. Both spectroscopic and X-ray structural studies are consistent with inhibition resulting from the binding of MBP to the thiamin diphosphate in the active centers. We also delineated the role of His29 (the sole potential acid-base catalyst in the active site other than the highly conserved Glu50) and Trp163 in cofactor activation and catalysis by benzaldehyde lyase.

Published

2008

10. Mechanism of Benzaldehyde Lyase Studied via Thiamin Diphosphate-Bound Intermediates and Kinetic Isotope Effects

Author

Michael J. McLeish, Natalia Nemeria, Alejandra Yep, Frank Jordan, Sumit Chakraborty, and George L. Kenyon

Subjects

Phenylpyruvic Acids, Pyridines, Stereochemistry, Decarboxylation, Pseudomonas fluorescens, Photochemistry, Biochemistry, Aldehyde, Enamine, Adduct, Benzaldehyde, chemistry.chemical_compound, Benzoin, Acrolein, Aldehyde-Lyases, chemistry.chemical_classification, Circular Dichroism, Phenylpyruvic acid, Deuterium Exchange Measurement, Glyoxylates, Tautomer, Butyrates, Kinetics, Models, Chemical, chemistry, Benzaldehydes, Mandelic Acids, Thiamine Pyrophosphate

Abstract

Direct spectroscopic observation of thiamin diphosphate-bound intermediates was achieved on the enzyme benzaldehyde lyase, which carries out reversible and highly enantiospecific conversion of ( R)-benzoin to benzaldehyde. The key enamine intermediate could be observed at lambda max 393 nm in the benzoin breakdown direction and in the decarboxylase reaction starting with benzoylformate. With benzaldehyde as substrate, no intermediates could be detected, only formation of benzoin at 314 nm. To probe the rate-limiting step in the direction of ( R)-benzoin synthesis, the (1)H/ (2)H kinetic isotope effect was determined for benzaldehyde labeled at the aldehyde position and found to be small (1.14 +/- 0.03), indicating that ionization of the C2alphaH from C2alpha-hydroxybenzylthiamin diphosphate is not rate limiting. Use of the alternate substrates benzoylformic and phenylpyruvic acids (motivated by the observation that while a carboligase, benzaldehyde lyase could also catalyze the slow decarboxylation of 2-oxo acids) enabled the observation of the substrate-thiamin covalent intermediate via the 1',4'-iminopyrimidine tautomer, characteristic of all intermediates with a tetrahedral C2 substituent on ThDP. The reaction of benzaldehyde lyase with the chromophoric substrate analogue ( E)-2-oxo-4(pyridin-3-yl)-3-butenoic acid and its decarboxylated product ( E)-3-(pyridine-3-yl)acrylaldehyde enabled the detection of covalent adducts with both. Neither adduct underwent further reaction. An important finding of the studies is that all thiamin-related intermediates are in a chiral environment on benzaldehyde lyase as reflected by their circular dichroism signatures.

Published

2008

11. Conformations of Alanine-Based Peptides in Water Probed by FTIR, Raman, Vibrational Circular Dichroism, Electronic Circular Dichroism, and NMR Spectroscopy

Author

Reinhard Schweitzer-Stenner, Frank Jordan, Lazaros Kakalis, Silvia Pizzanelli, Kai Griebenow, Thomas J. Measey, and Claudia Forte

Subjects

Circular dichroism, Protein Conformation, Spectrum Analysis, Raman, Vibration, Biochemistry, Spectral line, symbols.namesake, BACKBONE CONFORMATIONS, Spectroscopy, Fourier Transform Infrared, NUCLEAR MAGNETIC RESONANCE, Fourier transform infrared spectroscopy, Nuclear Magnetic Resonance, Biomolecular, Polyproline helix, Alanine, EXCITONIC COUPLING MODE, Chemistry, Circular Dichroism, Nuclear magnetic resonance spectroscopy, L UNFOLDED STATES, Crystallography, POLYPROLINE II, Vibrational circular dichroism, symbols, Raman spectroscopy, Oligopeptides

Abstract

We have used a combination of FTIR, VCD, ECD, Raman, and NMR spectroscopies to probe the solution conformations sampled by H-(AAKA)-OH by utilizing an excitonic coupling model and constraints imposed by the 3JCalphaHNH coupling constants of the central residues to simulate the amide I' profile of the IR, isotropic Raman, anisotropic Raman, and VCD spectra in terms of a mixture of three conformations, i.e., polyproline II, beta-strand and right-handed helical. The representative coordinates of the three conformations were obtained from published coil libraries. Alanine was found to exhibit PPII fractions of 0.60 or greater, mixed with smaller fractions of helices and beta-strand conformations. Lysine showed no clear conformational propensity in that it samples polyproline II, beta-strand, and helical conformations with comparable probability. This is at variance with results obtained earlier for ionized polylysine, which suggest a high polyproline II propensity. We reanalyzed previously investigated tetra- and trialanine by combining published vibrational spectroscopy data with 3JCalphaHNH coupling constants and obtained again blends dominated by PPII with smaller admixtures of beta-strand and right-handed helical conformations. The polyproline II propensity of alanine was found to be higher in tetraalanine than in trialanine. For all peptides investigated, our results rule out a substantial population of turn-like conformations. Our results are in excellent agreement with MD simulations on short alanine peptides by Gnanakaran and Garcia [(2003) J. Phys. Chem. B 107, 12555-12557] but at variance with multiple MD simulations particularly for the alanine dipeptide.

Published

2007

12. Function of a Conserved Loop of the β-Domain, Not Involved in Thiamin Diphosphate Binding, in Catalysis and Substrate Activation in Yeast Pyruvate Decarboxylase

Author

Kai Tittmann, Wen Wei, Frank Jordan, and Ebenezer Joseph

Subjects

chemistry.chemical_classification, Activator (genetics), Chemistry, Stereochemistry, Saccharomyces cerevisiae, Biochemistry, Catalysis, Yeast, Protein Structure, Tertiary, Enzyme Activation, Active center, Kinetics, Enzyme, Amino Acid Substitution, Mutagenesis, Site-Directed, Proton NMR, Amino Acid Sequence, Enzyme kinetics, Thiamine Pyrophosphate, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

The X-ray crystal structure of pyruvamide-activated yeast pyruvate decarboxylase (YPDC) revealed a flexible loop spanning residues 290 to 304 on the beta-domain of the enzyme, not seen in the absence of pyruvamide, a substrate activator surrogate. Site-directed mutagenesis studies revealed that residues on the loop affect the activity, with some residues reducing k(cat)/K(m) by at least 1000-fold. In the pyruvamide-activated form, the loop located on the beta domain can transfer information to the active center thiamin diphosphate (ThDP) located at the interface of the alpha and gamma domains. The sigmoidal v(0)-[S] curve with wild-type YPDC attributed to substrate activation is modulated for most variants, but is not abolished. Pre-steady-state stopped-flow studies for product formation on these loop variants provided evidence for three enzyme conformations connected by two transitions, as already noted for the wild-type YPDC at pH 5.0 [Sergienko, E. A., and Jordan, F. (2002) Biochemistry 41, 3952-3967]. (1)H NMR analysis of the intermediate distribution resulting from acid quench [Tittmann et al. (2003) Biochemistry 42, 7885-7891] with all YPDC variants indicated that product release is rate limiting in the steady state. Apparently, the loop is not solely responsible for the substrate activation behavior, rather it may affect the behavior of residue C221 identified as the trigger for substrate activation. The most important function of the loop is to control the conformational equilibrium between the "open" and "closed" conformations of the enzyme identified in the pyruvamide-activated structure [Lu et al. (2000) Eur. J. Biochem. 267, 861-868].

Published

2006

13. Electronic and Nuclear Magnetic Resonance Spectroscopic Features of the 1‘,4‘-Iminopyrimidine Tautomeric Form of Thiamin Diphosphate, a Novel Intermediate on Enzymes Requiring This Coenzyme

Author

Frank Jordan, Ahmet Tarik Baykal, and Lazaros Kakalis

Subjects

Circular dichroism, Stereochemistry, chemistry.chemical_element, Ring (chemistry), Biochemistry, Article, Cofactor, Enzyme catalysis, chemistry.chemical_compound, Nuclear magnetic resonance, Isomerism, Nuclear Magnetic Resonance, Biomolecular, Binding Sites, biology, Chemistry, Circular Dichroism, Tautomer, Nitrogen, Solvent, Pyrimidines, Models, Chemical, biology.protein, Electronics, Thiamine Pyrophosphate, Protein Binding, Methyl group

Abstract

Appropriate compounds were synthesized to create models for the 1',4'-imino tautomer of the 4'-aminopyrimidine ring of thiamin diphosphate recently found to exist on the pathway of enzymatic reactions requiring this cofactor [Jordan, F., and Nemeria, N. S. (2005) Bioorg. Chem. 33, 190-215]. The N1-methyl-4-aminopyrimidinium compounds synthesized on treatment with a strong base produce the 1,4-imino tautomer whose UV spectrum indicates a maximum between 300 and 320 nm, depending on the absence or presence of a methyl group at the 4-amino nitrogen. The lambda(max) found is in the same wavelength range as the positive circular dichroism band observed on several enzymes and showed a very strong dependence on solvent dielectric constant. To help with the 15N chemical shift assignments, the model compounds were specifically labeled with 15N at the amino nitrogen atom. The chemical shift of the amino nitrogen was deshielded by N1-methylation and then dramatically further deshielded by more than 100 ppm on formation of the 1,4-iminopyrimidine tautomer. Both the UV spectroscopic values and the 15N chemical shift for the 1,4-iminopyrimidine tautomer should serve as useful guides to the assignment of enzyme-bound signals.

Published

2006

14. Evidence for Dramatic Acceleration of a C−H Bond Ionization Rate in Thiamin Diphosphate Enzymes by the Protein Environment

Author

Sheng Zhang, Yan Yan, Zhen Zhang, Yu Zou, Frank Jordan, Leon Zhou, and Natalia S. Nemeria

Subjects

Stereochemistry, Pyruvate Dehydrogenase Complex, Biochemistry, Mass Spectrometry, Substrate Specificity, Catalysis, Enamine, chemistry.chemical_compound, Reaction rate constant, Ionization, Enzyme Stability, Spectroscopy, Fourier Transform Infrared, Nuclear Magnetic Resonance, Biomolecular, chemistry.chemical_classification, Chemistry, Hydrogen bond, Escherichia coli Proteins, Deuterium Exchange Measurement, Substrate (chemistry), Acetylation, Hydrogen Bonding, Pyruvate dehydrogenase complex, Protein Structure, Tertiary, Kinetics, Protein Subunits, Enzyme, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Protons, Thiamine Pyrophosphate, Oxidation-Reduction

Abstract

The hypothesis that thiamin diphosphate-dependent enzymes achieve a significant fraction of their catalytic rate acceleration by providing a protein environment that helps to stabilize unstable zwitterionic/dipolar intermediates (including the enamine/C2alpha-carbanion present on all such enzymes) was tested experimentally using the intermediate C2alpha-hydroxyethylthiamin diphosphate (HEThDP) with the Escherichia coli pyruvate dehydrogenase complex and its E1 subunit (PDHc-E1). Using pre-steady-state and steady-state methods, it was shown that HEThDP is a substrate for this enzyme after ionization of the C2alpha-H bond. An experiment was then carried out to measure the PDHc-E1 catalyzed pre-steady-state rate constant for the D --> H exchange from the C2alpha position of HEThDP-d(4), as an indicator of the formation of the enamine. Importantly, the enzyme accelerates the rate of ionization of this bond by a factor of 10(7), corresponding to a 10 kcal/mol stabilization of the enamine intermediate by the enzyme. This finding is likely a general feature of thiamin diphosphate enzymes.

Published

2005

15. Amino-Terminal Residues 1−45 of the Escherichia coli Pyruvate Dehydrogenase Complex E1 Subunit Interact with the E2 Subunit and Are Required for Activity of the Complex but Not for Reductive Acetylation of the E2 Subunit

Author

Frank Jordan, Leon Zhou, Wen Wei, Natalia S. Nemeria, and Yun-Hee Park

Subjects

Pyruvate decarboxylation, Hot Temperature, Pyruvate dehydrogenase kinase, Molecular Sequence Data, Pyruvate Dehydrogenase Complex, Biology, Pyruvate dehydrogenase phosphatase, Dihydrolipoyllysine-Residue Acetyltransferase, medicine.disease_cause, Peptide Mapping, Biochemistry, Mass Spectrometry, Enzyme Stability, medicine, Pyruvate Dehydrogenase (Lipoamide), Trypsin, Amino Acid Sequence, Dihydrolipoyl transacetylase, Escherichia coli, Chromatography, High Pressure Liquid, Sequence Deletion, Thioctic Acid, Escherichia coli Proteins, Hydrolysis, Genetic Variation, Acetylation, Pyruvate dehydrogenase complex, Peptide Fragments, Protein Structure, Tertiary, Enzyme Activation, Molecular Weight, Protein Subunits, Amino Acid Substitution, Oxoglutarate dehydrogenase complex, Branched-chain alpha-keto acid dehydrogenase complex, Dimerization, Oxidation-Reduction, Protein Binding

Abstract

While N-terminal amino acids 1-55 are not seen in the structure of the Escherichia coli pyruvate dehydrogenase complex E1 subunit (PDHc-E1), mass spectrometric analysis indicated that this amino-terminal region of PDHc-E1 was protected by PDHc-E2. Hence, five deletion constructs of PDHc-E1 were created, Delta6-15, Delta16-25, Delta26-35, Delta36-45, and Delta46-55, along with single-site substitutions at Asp7, Asp9, Pro10, Ile11, Glu12, Thr13, Arg14, and Asp15. The decarboxylation of pyruvate and the ability of PDHc-E1 to dimerize are not affected by any of the deletions or substitutions. While Delta46-55 and the Pro10Ala, Ile11Ala, and Thr13Ala variants could form a complex with PDHc-E2, and produced NADH in the overall assay, Delta16-25, Delta26-35, and Delta36-45 and the Asp7Ala, Asp9Ala, Glu12Gln, Glu12Asp, Arg14Ala, and Asp15Ala variants failed in both respects. Remarkably, all constructs of PDHc-E1 from E. coli, as well as PDHc-E1 from Mycobacterium tuberculosis, could carry out reductive acetylation of the E. coli lipoyl domain, but only constructs of the E. coli PDHc-E1 could reductively acetylate E. coli PDHc-E2. It was concluded that there are at least two loci of interaction between the PDHc-E1 and PDHc-E2 subunits: (1) the thiamin diphosphate-bound substrate on PDHc-E1 and the lipoylamide of PDHc-E2, as reflected by the ability to reductively acetylate the latter; and (2) amino terminal residues 1-45 of PDHc-E1 with regions of PDHc-E2 (so far undefined for the E. coli complex), as reflected by the overall activity of the entire complex. These studies add important information regarding recognition within this multienzyme complex class with an alpha(2) E1 assembly.

Published

2004

16. Structural Determinants of Enzyme Binding Affinity: The E1 Component of Pyruvate Dehydrogenase from Escherichia coli in Complex with the Inhibitor Thiamin Thiazolone Diphosphate

Author

Natalia S. Nemeria, Frank Jordan, Palaniappa Arjunan, Krishnamoorthy Chandrasekhar, William Furey, Martin Sax, and Andrew Brunskill

Subjects

Protein Conformation, Stereochemistry, Crystallography, X-Ray, Biochemistry, Cofactor, Structure-Activity Relationship, Protein structure, Oxidoreductase, Pyruvate Dehydrogenase (Lipoamide), Enzyme Inhibitors, Binding site, chemistry.chemical_classification, Binding Sites, biology, Escherichia coli Proteins, Active site, Hydrogen Bonding, Pyruvate dehydrogenase complex, Enzyme binding, Enzyme, chemistry, biology.protein, Thiamine Pyrophosphate, Dimerization, Protein Binding

Abstract

Thiamin thiazolone diphosphate (ThTDP), a potent inhibitor of the E1 component from the Escherichia coli pyruvate dehydrogenase multienzyme complex (PDHc), binds to the enzyme with greater affinity than does the cofactor thiamin diphosphate (ThDP). To identify what determines this difference, the crystal structure of the apo PDHc E1 component complex with ThTDP and Mg(2+) has been determined at 2.1 A and compared to the known structure of the native holoenzyme, PDHc E1-ThDP-Mg(2+) complex. When ThTDP replaces ThDP, reorganization occurs in the protein structure in the vicinity of the active site involving positional and conformational changes in some amino acid residues, a change in the V coenzyme conformation, addition of new hydration sites, and elimination of others. These changes culminate in an increase in the number of hydrogen bonds to the protein, explaining the greater affinity of the apoenzyme for ThTDP. The observed hydrogen bonding pattern is not an invariant feature of ThDP-dependent enzymes but rather specific to this enzyme since the extra hydrogen bonds are made with nonconserved residues. Accordingly, these sequence-related hydrogen bonding differences likewise explain the wide variation in the affinities of different thiamin-dependent enzymes for ThTDP and ThDP. The sequence of each enzyme determines its ability to form hydrogen bonds to the inhibitor or cofactor. Mechanistic roles are suggested for the aforementioned reorganization and its reversal in PDHc E1 catalysis: to promote substrate binding and product release. This study also provides additional insight into the role of water in enzyme inhibition and catalysis.

Published

2004

17. Structural and Kinetic Analysis of Catalysis by a Thiamin Diphosphate-Dependent Enzyme, Benzoylformate Decarboxylase

Author

Michael J. McLeish, Eduard A. Sergienko, Elena S. Polovnikova, Miriam S. Hasson, Frank Jordan, Natalie L. Anderson, George L. Kenyon, Asim K. Bera, and John T. Burgner

Subjects

Carboxy-Lyases, Stereochemistry, Crystallography, X-Ray, Ligands, Binding, Competitive, Biochemistry, Catalysis, Benzoylformate decarboxylase, Cofactor, Serine, chemistry.chemical_compound, Histidine, Enzyme kinetics, Carboxylate, Enzyme Inhibitors, Alanine, Binding Sites, biology, Pseudomonas putida, Chemistry, Circular Dichroism, Active site, Lyase, Enzyme binding, Kinetics, Spectrophotometry, Mutagenesis, Site-Directed, biology.protein, Mandelic Acids, Thiamine Pyrophosphate

Abstract

Benzoylformate decarboxylase is a member of the family of enzymes that are dependent on the cofactor thiamin diphosphate. A structure of this enzyme binding (R)-mandelate, a competitive inhibitor, suggests that at least two hydrogen bonds are formed between the substrate, benzoylformate, and active site side chains. The first is between the carboxylate group of benzoylformate and the hydroxyl group of S26, and the second is between carbonyl group of the substrate and an imidazole nitrogen of H70. Steady-state kinetic studies indicate that the catalytic parameters are strongly affected in three active site mutants, S26A, H70A, and H281A. The K(m) of S26A was increased most dramatically, 25-fold more than that of the wild-type enzyme, while the K(i) of (R)-mandelate was increased 100-fold, suggesting that the serine hydroxyl is important for substrate binding. The k(cat) of H70A is reduced more than 3 orders of magnitude, strongly implicating this residue in catalysis, and H281 showed significant, but smaller magnitude, effects on both K(m) and k(cat). Stopped-flow experiments using an alternative substrate, p-nitrobenzoylformate, lead to kinetic resolution of the fate of key thiamin diphosphate-bound intermediates. Together, the experimental results suggest the following roles for residues in the active site. The residue H70 is important for the protonation of the 2-alpha-mandelyl-ThDP intermediate, thereby assisting in decarboxylation, and for the deprotonation of the 2-alpha-hydroxybenzyl-ThDP intermediate, aiding product release. H281 is involved in protonation of the enamine. Surprisingly, S26 appears to be involved not only in substrate binding but also in other steps of the reaction.

Published

2003

18. Yeast Pyruvate Decarboxylase Tetramers Can Dissociate into Dimers along Two Interfaces. Hybrids of Low-Activity D28A (or D28N) and E477Q Variants, with Substitution of Adjacent Active Center Acidic Groups from Different Subunits, Display Restored Activity

Author

Frank Jordan and Eduard A. Sergienko

Subjects

Stereochemistry, Dimer, Saccharomyces cerevisiae, Biochemistry, Dissociation (chemistry), Active center, chemistry.chemical_compound, Catalytic Domain, Protein Structure, Quaternary, chemistry.chemical_classification, biology, Low activity, Genetic Variation, Active site, Hydrogen-Ion Concentration, Chromatography, Ion Exchange, Yeast, Kinetics, Protein Subunits, Enzyme, Amino Acid Substitution, chemistry, biology.protein, Dimerization, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

The tetrameric enzyme yeast pyruvate decarboxylase (YPDC) has been known to dissociate into dimers at elevated pH values. However, the interface along which the dissociation occurs, as well as the fundamental kinetic properties of the resulting dimers, remains unknown. The active sites of YPDC are comprised of amino acid residues from two subunits, a property which we utilize to address the issue as to which dimer interface is cleaved under different conditions of dissociation. Hydroxide-induced dissociation of the active site D28A (or D28N) and E477Q variants, each at least 100 times less reactive than wild-type YPDC, followed by reassociation of D28A (or D28N) and E477Q variants led to a remarkable 35-50-fold increase in activity. This result is possible only if the hydroxide-induced dissociation results in a cleavage along the interface between two subunits so that residues D28 and E477 are now separated. Upon reassociation, one of the two active sites of the hybrid dimer will have both residues substituted, whereas the second one will be of the wild-type phenotype. In contrast to the hydroxide-induced dimers, the urea-induced dissociation recently proposed results in dissociation along dimer-dimer interfaces, without separating the active sites, and therefore, on reassociation, these dimers do not regain activity. The significance of the results is discussed in light of a recently proposed alternating sites mechanism for YPDC. A preparative ion-exchange method is reported for the separation and purification of hybrid enzymes.

Published

2002

19. New Model for Activation of Yeast Pyruvate Decarboxylase by Substrate Consistent with the Alternating Sites Mechanism: Demonstration of the Existence of Two Active Forms of the Enzyme

Author

Eduard A. Sergienko and Frank Jordan

Subjects

Models, Molecular, chemistry.chemical_classification, biology, Protein Conformation, Chemistry, Stereochemistry, Circular Dichroism, Acetoin, Kinetics, Allosteric regulation, Substrate (chemistry), Active site, Regulatory site, Saccharomyces cerevisiae, Biochemistry, Enzyme Activation, Spectrometry, Fluorescence, Enzyme, biology.protein, Steady state (chemistry), Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Pyruvate decarboxylase from yeast (YPDC, EC 4.1.1.1) exhibits a marked lag phase in the progress curves of product (acetaldehyde) formation. The currently accepted kinetic model for YPDC predicts that, only upon binding of substrate in a regulatory site, a slow activation step converts inactive enzyme into the active form. This allosteric behavior gives rise to sigmoidal steady-state kinetics. The E477Q active site variant of YPDC exhibited hyperbolic initial rate curves at low pH, not consistent with the model. Progress curves of product formation by this variant were S-shaped, consistent with the presence of three interconverting conformations with distinct steady-state rates. Surprisingly, wild-type YPDC at pHor =5.0 also possessed S-shaped progress curves, with the conformation corresponding to the middle steady state being the most active one. Reexamination of the activation by substrate of wild-type YPDC in the pH range of 4.5-6.5 revealed two characteristic transitions at all pH values. The values of steady-state rates are functions of both pH and substrate concentration, affecting whether the progress curve appears "normal" or S-shaped with an inflection point. The substrate dependence of the apparent rate constants suggested that the first transition corresponded to substrate binding in an active site and a subsequent step responsible for conversion to an asymmetric conformation. Consequently, the second enzyme state may report on "unregulated" enzyme, since the regulatory site does not participate in its generation. This enzyme state utilizes the alternating sites mechanism, resulting in the hyperbolic substrate dependence of initial rate. The second transition corresponds to binding a substrate molecule in the regulatory site and subsequent minor conformational adjustments. The third enzyme state corresponds to the allosterically regulated conformation, previously referred to as activated enzyme. The pH dependence of the Hill coefficient suggests a random binding of pyruvate in a regulatory and an active site of wild-type YPDC. Addition of pyruvamide or acetaldehyde to YPDC results in the appearance of additional conformations of the enzyme.

Published

2002

20. Catalytic Acid−Base Groups in Yeast Pyruvate Decarboxylase. 1. Site-Directed Mutagenesis and Steady-State Kinetic Studies on the Enzyme with the D28A, H114F, H115F, and E477Q Substitutions

Author

Min Liu, Jue Wang, Eduard A. Sergienko, Kai Tittmann, Gerhard Hübner, Frank Jordan, Fusheng Guo, and William Furey

Subjects

Stereochemistry, Decarboxylation, Glutamine, Phenylalanine, DNA, Recombinant, Glutamic Acid, Saccharomyces cerevisiae, Biochemistry, Catalysis, Benzoylformate decarboxylase, Cofactor, Substrate Specificity, Deprotonation, Catalytic Domain, Histidine, Cloning, Molecular, Site-directed mutagenesis, Aspartic Acid, Alanine, biology, Chemistry, Substrate (chemistry), Carbon Dioxide, Hydrogen-Ion Concentration, Recombinant Proteins, Enzyme Activation, Kinetics, Amino Acid Substitution, Mutagenesis, Site-Directed, biology.protein, Steady state (chemistry), Thiamine Pyrophosphate, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

The roles of four of the active center groups with potential acid-base properties in the region of pH optimum of pyruvate decarboxylase from Saccharomyces cerevisiae have been studied with the substitutions Asp28Ala, His114Phe, His115Phe, and Glu477Gln, introduced by site-directed mutagenesis methods. The steady-state kinetic constants were determined in the pH range of activity for the enzyme. The substitutions result in large changes in k(cat) and k(cat)/S(0.5) (and related terms), indicating that all four groups have a role in transition state stabilization. Furthermore, these results also imply that all four are involved in some manner in stabilizing the rate-limiting transition state(s) both at low substrate (steps starting with substrate binding and culminating in decarboxylation) and at high substrate concentration (steps beginning with decarboxylation and culminating in product release). With the exception of some modest effects, the shapes of neither the bell-shaped k(cat)/S(0.5)-pH (and related functions) plots nor the k(cat)-pH plots are changed by the substitutions. Yet, the fractional activity still remaining after substitutions virtually rules out any of the four residues as being directly responsible for initiating the catalytic process by ionizing the C2H. There is no effect on the C2 H/D exchange rate exhibited by the D28A and E477Q substitutions. These results strongly imply that the base-induced deprotonation at C2 is carried out by the only remaining base, the iminopyrimidine tautomer of the coenzyme, via intramolecular proton abstraction. The first product is released as CO(2) rather than HCO(3)(-) by both wild-type and E477Q and D28A variants, ruling out several mechanistic alternatives.

Published

2001

21. Catalytic Acid−Base Groups in Yeast Pyruvate Decarboxylase. 3. A Steady-State Kinetic Model Consistent with the Behavior of both Wild-Type and Variant Enzymes at All Relevant pH Values

Author

Frank Jordan and Eduard A. Sergienko

Subjects

Decarboxylation, Glutamine, Glutamic Acid, Regulatory site, Acetaldehyde, Saccharomyces cerevisiae, Biochemistry, Substrate Specificity, Active center, chemistry.chemical_compound, Catalytic Domain, Computer Simulation, Pyruvates, chemistry.chemical_classification, Aspartic Acid, Alanine, Binding Sites, Substrate (chemistry), Hydrogen-Ion Concentration, Recombinant Proteins, Kinetics, Enzyme, Amino Acid Substitution, Models, Chemical, chemistry, Steady state (chemistry), Asparagine, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

The widely quoted kinetic model for the mechanism of yeast pyruvate decarboxylase (YPDC, EC 4.1.1.1), an enzyme subject to substrate activation, is based on data for the wild-type enzyme under optimal experimental conditions. The major feature of the model is the obligatory binding of substrate in the regulatory site prior to substrate binding at the catalytic site. The activated monomer would complete the cycle by irreversible decarboxylation of the substrate and product (acetaldehyde) release. Our recent kinetic studies of YPDC variants substituted at positions D28 and E477 at the active center necessitate some modification of the mechanism. It was found that enzyme without substrate activation apparently is still catalytically competent. Further, substrate-dependent inhibition of D28-substituted variants leads to an enzyme form with nonzero activity at full saturation, requiring a second major branch point in the mechanism. Kinetic data for the E477Q variant suggest that three consecutive substrate binding steps may be needed to release product acetaldehyde, unlikely if YPDC monomer is the minimal catalytic unit with only two binding sites for substrate. A model to account for all kinetic observations involves a functional dimer operating through alternation of active sites. In the context of this mechanism, roles are suggested for the active center acid-base groups D28, E477, H114, and H115. The results underline once more the enormous importance that both aromatic rings of the thiamin diphosphate, rather than only the thiazolium ring, have in catalysis, a fact little appreciated prior to the availability of the 3-dimensional structure of these enzymes.

Published

2001

22. Catalytic Acid−Base Groups in Yeast Pyruvate Decarboxylase. 2. Insights into the Specific Roles of D28 and E477 from the Rates and Stereospecificity of Formation of Carboligase Side Products

Author

Frank Jordan and Eduard A. Sergienko

Subjects

Decarboxylation, Stereochemistry, Glutamine, Glutamic Acid, Acetaldehyde, Saccharomyces cerevisiae, Biochemistry, Substrate Specificity, Active center, chemistry.chemical_compound, Stereospecificity, Catalytic Domain, Pyruvic Acid, chemistry.chemical_classification, Aspartic Acid, Alanine, Circular Dichroism, Acetoin, Stereoisomerism, Hydrogen-Ion Concentration, Recombinant Proteins, Acetolactate Synthase, Kinetics, Enzyme, chemistry, Electrophile, Lactates, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Yeast pyruvate decarboxylase (YPDC), in addition to forming its metabolic product acetaldehyde, can also carry out carboligase reactions in which the central enamine intermediate reacts with acetaldehyde or pyruvate (instead of the usual proton electrophile), resulting in the formation of acetoin and acetolactate, respectively (typically, 1% of the total reaction). Due to the common mechanism shared by the acetaldehyde-forming and carboligase reactions through decarboxylation, a detailed analysis of the rates and stereochemistry of the carboligase products formed by the E477Q, D28A, and D28N active center YPDC variants was undertaken. While substitution at either position led to an approximately 2-3 orders of magnitude lower catalytic efficiency in acetaldehyde formation, the rate of acetoin formation by the E477Q and D28N variants was higher than that by wild-type enzyme. Comparison of the steady-state data for acetaldehyde and acetoin formation revealed that the rate-limiting step for acetaldehyde formation by the D28A, H114F, H115F, and E477Q variants is a step post-decarboxylation. In contrast to the wild-type YPDC and the E477Q variant, the D28A and D28N variants could synthesize acetolactate as a major product. The lower overall rate of side-product formation by the D28A variant than wild-type enzyme attests to participation of D28 in steps leading up to and including decarboxylation. The results also provide insight into the state of ionization of the side chains examined. (R)-Acetoin is produced by the variants with greater enantiomeric excess than by wild-type YPDC. (S)-Acetolactate is the predominant enantiomer produced by the D28-substituted variants, the same configuration as produced by the related plant acetolactate synthase.

Published

2001

23. Spectroscopic Detection of Transient Thiamin Diphosphate-Bound Intermediates on Benzoylformate Decarboxylase

Author

Jue Wang, Frank Jordan, George L. Kenyon, Michael J. McLeish, Lena S. Polovnikova, Eduard A. Sergienko, and Miriam S. Hasson

Subjects

chemistry.chemical_classification, Alanine, Binding Sites, Carboxy-Lyases, Stereochemistry, Decarboxylation, Glyoxylates, food and beverages, Biochemistry, Benzoylformate decarboxylase, Substrate Specificity, Kinetics, Enzyme, Amino Acid Substitution, chemistry, Spectrophotometry, Nitrobenzoates, Mandelic Acids, Histidine, Indicators and Reagents, Spectroscopic detection, Thiamine Pyrophosphate, human activities

Abstract

Thiamin diphosphate (ThDP)-dependent enzymes catalyze a range of transformations, such as decarboxylation and ligation. We report a novel spectroscopic assay for detection of some of the ThDP-bound intermediates produced on benzoylformate decarboxylase. Benzoylformate decarboxylase was mixed with its alternate substrate p-nitrobenzoylformic acid on a rapid-scan stopped-flow instrument, resulting in formation of three absorbing species (lambda(max) in parentheses): I(1) (a transient at 620 nm), I(2) (a transient at 400 nm), and I(3) (a stable absorbance with lambda(max)730 nm). Analysis of the kinetics of the two transient species supports a model in which a noncovalent complex of the substrate and the enzyme is converted to the first covalent intermediate I(1); the absorbance corresponding to I(1) is probably a charge-transfer band arising from the interaction of the thiamin diphosphate-p-nitrobenzoylformic acid covalent adduct (2-p-nitromandelylThDP) and the enzyme. The rate of disappearance of I(1) parallels the rate of formation of I(2). Chemical models suggest the lambda(max) of I(2) (near 400 nm) to be appropriate to the enamine, a key intermediate in ThDP-dependent reactions resulting from the decarboxylation of the thiamin diphosphate-p-nitrobenzoylformic acid covalent adduct. Therefore, the rate of disappearance of I(1) and/or the appearance of I(2) directly measure the rate of decarboxylation. A relaxation kinetic treatment of the pre-steady-state kinetic data also revealed a hitherto unreported facet of the mechanism, alternating active-sites reactivity. Parallel studies of the His70Ala BFD active-site variant indicate that it cannot form the complex reported by the charge-transfer band (I(1)) at the level of the wild-type protein.

Published

2000

24. Role of Glutamate 91 in Information Transfer during Substrate Activation of Yeast Pyruvate Decarboxylase

Author

Frank Jordan, William Furey, and Haijuan Li

Subjects

Models, Molecular, Circular dichroism, Hot Temperature, Stereochemistry, Glutamic Acid, Cooperativity, Saccharomyces cerevisiae, Biochemistry, Substrate Specificity, Protein structure, Enzyme Stability, biology, Chemistry, Circular Dichroism, Wild type, Substrate (chemistry), Active site, Hydrogen-Ion Concentration, Recombinant Proteins, Protein Structure, Tertiary, Turnover number, Enzyme Activation, Kinetics, Spectrometry, Fluorescence, Amino Acid Substitution, Mutagenesis, Site-Directed, biology.protein, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Oligonucleotide-directed site-specific mutagenesis was carried out on pyruvate decarboxylase (EC 4.1.1.1) from Saccharomyces cerevisiae at E91, located on the putative substrate activation pathway and linking the alpha and gamma domains of the enzyme. While C221 on the beta domain is the residue at which substrate activation is triggered [Baburina, I., et al. (1994) Biochemistry 33, 5630-5635; Baburina, I., et al. (1996) Biochemistry 35, 10249-10255], that information, via the substrate bound at C221, is transmitted to H92 on the alpha domain, across the domain divide from C221 [Baburina, I. , et al. (1998) Biochemistry 37, 1235-1244], thence to E91 on the alpha domain, and then on to W412 on the gamma domain [Li, H., and Jordan, F. (1999) Biochemistry 38, 10004-10012] and to the active site thiamin diphosphate located at the interface of the alpha and gamma domains [Arjunan, D., et al. (1996) J. Mol. Biol. 256, 590-600]. Substitution at E91 with Q, D, or A led to modest reductions in the specific activity (4-, 5-, and 30-fold), as well as in both the turnover number and the catalytic efficiency, in that order. Interestingly, the Hill coefficient was only slightly reduced for the E91D variant, but cooperativity was virtually abolished for the E91Q and E91A variants. The thermal stability of the variants was reduced in the following order: wild type > E91Q > E91D > E91A; circular dichroism and fluorescence experiments also demonstrated that the tertiary structure of the enzyme was affected by these substitutions. The variants could be purified as apoenzymes, demonstrating their impaired ability to bind thiamin diphosphate. Apparently, the charge at residue 91 is quite important for maintaining optimal cooperativity. To maintain strong domain-domain interactions, the length of the side chain at position 91 with hydrogen bonding potential to W412 is sufficient.

Published

1999

25. <scp>d</scp>,<scp>l</scp>-S-Methyllipoic Acid Methyl Ester, a Kinetically Viable Model for S-Protonated Lipoic Acid as the Oxidizing Agent in Reductive Acyl Transfers Catalyzed by the 2-Oxoacid Dehydrogenase Multienzyme Complexes

Author

Ke Pan and Frank Jordan

Subjects

Magnetic Resonance Spectroscopy, Acylation, education, Salt (chemistry), Protonation, Dehydrogenase, Biochemistry, Medicinal chemistry, Catalysis, chemistry.chemical_compound, Multienzyme Complexes, Oxidizing agent, Organic chemistry, Mesylates, chemistry.chemical_classification, Thioctic Acid, Bridged Bicyclo Compounds, Heterocyclic, Kinetics, Lipoic acid, Models, Chemical, chemistry, Oxoacid, lipids (amino acids, peptides, and proteins), Oxidation-Reduction, Protein Kinases, Trifluoromethanesulfonate

Abstract

D,L-S(6,8)-Methyllipoic acid methyl ester triflate salt (D,L-S-methyllipoic acid methyl ester) was synthesized as a model for S-protonated lipoic acid, suggested to be the active form of lipoic acid in the reductive acylation catalyzed by the E1 and E2 enzymes of the 2-oxoacid dehydrogenase multienzyme complexes by a previous model [Chiu, C. C., Chung, A., Barletta, G., and Jordan, F. (1996) J. Am. Chem. Soc. 118, 11026-11029]. While in that earlier study lipoic acid could only trap only the enamine/C2 alpha-carbanion intermediate in an intramolecular model, and with the assistance of mercury compound to shift the equilibrium to the products, D,L-S-methyllipoic acid methyl ester could trap the enamine derived from 2-alpha-methoxybenzyl-3,4,5-trimethylthiazolium salt in an intermolecular reaction in the absence of a mercury compound, and with a rate constant of 6.6 x 10(4) M-1 S-1. A tetrahedral adduct at the C2 alpha-position formed between the enamine and D,L-S-methyllipoic acid methyl ester was isolated and characterized. The reaction likely takes place by two-electron nucleophilic attack, since no evidence was found for C2 alpha-linked homodimers, expected from a free-radical mechanism. The results suggest that, in the reductive acyl transfer, there is nucleophilic attack by the enamine at one of the sulfur atoms of the lipoic acid [probably at S8, according to Frey, P. A., Flournoy, D. S., Gruys, K., and Yang, Y. S. (1989) Ann. N.Y. Acad. Sci. 373, 21-35], while there is concomitant electrophilic catalysis by a proton juxtaposed at S6 via a general acid catalyst located on the E1 enzyme. Oxidation of the enamine derived from C2 alpha-hydroxybenzyl-3,4,5-trimethylthiazolium salt by D,L-S-methyllipoic acid methyl ester was also deduced on the basis of the formation of 2-benzoylthiazolium ion as a major product; however, the tetrahedral intermediate could not be detected. Oxidation of the enamine by D,L-S-methyllipoic acid methyl ester can take place with either an ether or an alcohol at the C2 alpha position of the enamine.

Published

1998

26. Interdomain Information Transfer during Substrate Activation of Yeast Pyruvate Decarboxylase: The Interaction between Cysteine 221 and Histidine 92

Author

Irina Baburina, William Furey, Brian Bennion, Haijuan Li, and Frank Jordan

Subjects

chemistry.chemical_classification, biology, Stereochemistry, Saccharomyces cerevisiae, Mutagenesis, Substrate (chemistry), biology.organism_classification, Biochemistry, Active center, Enzyme, chemistry, Pyruvate decarboxylase, Histidine, Cysteine

Abstract

Oligonucleotide-directed site-specific mutagenesis was carried out on pyruvate decarboxylase (EC 4.1.1.1) from Saccharomyces cerevisiae at two cysteines on the beta domain (221 and 222) and at H92 on the alpha domain, across the domain divide from C221. While C221 has been shown to provide the trigger for substrate activation [Baburina, I., et al. (1994) Biochemistry 33, 5630-5635], the information must be transmitted from the substrate bound at this site [Arjunan, D., et al. (1996) J. Mol. Biol. 256, 590-600] to the active center thiamin diphosphate located at the interface of the alpha and gamma domains. Substitution at H92 with G, A, or C leads to great reduction of the Hill coefficient (from 2.0 in the wild-type enzyme to 1.2-1.3), while substitution for Lys affords an active enzyme with a Hill coefficient of 1.5-1.6. Iodoacetate at 10 mM reduced the Hill coefficient from 2.0 to 1.1, while also causing significant inactivation of the enzyme, presumably by carboxymethylation of C221. 1,3-Dibromoacetone, a potential cross-linker when added to the H92C/C222S variant at 0.1 mM, abolished substrate activation while reducing the activity only by 30%. Therefore, 1,3-dibromoacetone may cross-link C92 and C221. It was concluded that H92 is on the information transfer pathway during the substrate activation process and the interaction between C221 on the beta domain and H92 on the alpha domain is required for substrate activation. Extensive pH studies of the steady-state kinetic constants provide support for the interaction of C221 and H92 and the transmission of regulatory information to the active center via this pathway and pKaS for the two groups. This important interaction between the C221-bound pyruvate and His92 probably has both electrostatic and steric components.

Published

1998

27. Three of Four Cysteines, Including That Responsible for Substrate Activation, Are Ionized at pH 6.0 in Yeast Pyruvate Decarboxylase: Evidence from Fourier Transform Infrared and Isoelectric Focusing Studies

Author

Ara Kahyaoglu, Frank Jordan, Richard Mendelsohn, David J. Moore, Irina Baburina, and Alexander N. Volkov

Subjects

chemistry.chemical_classification, biology, Chemistry, Isoelectric focusing, Saccharomyces cerevisiae, Mutagenesis, Substrate (chemistry), Hydrogen-Ion Concentration, biology.organism_classification, Biochemistry, Yeast, Substrate Specificity, Enzyme Activation, Enzyme, Spectroscopy, Fourier Transform Infrared, Mutagenesis, Site-Directed, Cysteine, Isoelectric Focusing, Pyruvate Decarboxylase, Pyruvate decarboxylase, DNA Primers

Abstract

Oligonucleotide-directed site-specific mutagenesis was carried out on pyruvate decarboxylase (EC 4.1.1.1) from Saccharomyces cerevisiae at three of the four cysteines (152, 221, and 222), the fourth (69) being buried according to X-ray crystallographic results [Arjunan et al. (1996) J. Mol. Biol. 256, 590-600]. All of the variants still retained significant activity, and all could be purified to homogeneity. FT-IR experiments were run on the C221S, C222S, C221S/C222S and C152A variants, as well as on the wild-type enzyme. There is a band present at 2557 cm-1 in the spectra of all variants and the wild-type enzyme, except in the spectrum of the C152A variant. This frequency is appropriate to a cysteine S-H stretching mode. It was therefore concluded that C152 is the only undissociated cysteine on the enzyme at pH 6.0, the pH optimum of this enzyme, whereas C221, C222, and C69 are all ionized. Isoelectric focusing experiments were carried out on all of these variants, as well as on the H92A variant (H92 is across the domain divide on the alpha domain, from C221 located on the beta domain). The variation in isoelectric points deduced from the data was consistent with removal of negative charges concomitant with the C221S, C222S, and C221S/C222S substitutions and removal of a positive charge with the H92A substitution when compared to that of the wild-type enzyme. The results of these two types of experiments are in good accord and suggest that the site of substrate activation at C221 [Baburina et al. (1994) Biochemistry 33, 5630-5635] is comprised of a Cys221S- +HHis92 ion pair, not unlike that found in papain and glyceraldehyde-3-phosphate dehydrogenase. This finding suggests that the regulatory site of this enzyme has been optimized for nucleophilic reactivity between the thiolate of C221 and the keto carbon of the 2-oxoacid.

Published

1996

28. Glyoxylate carboligase: a unique thiamin diphosphate-dependent enzyme that can cycle between the 4'-aminopyrimidinium and 1',4'-iminopyrimidine tautomeric forms in the absence of the conserved glutamate

Author

David M. Chipman, Hetalben Patel, Frank Jordan, Ilan Vered, Anand Balakrishnan, Elad Binshtein, Boaz Shaanan, Ze'ev Barak, and Natalia Nemeria

Subjects

Models, Molecular, Circular dichroism, Stereochemistry, Decarboxylation, Glyoxylate cycle, Glutamic Acid, Protonation, Biochemistry, Article, Substrate Specificity, Active center, Ligases, chemistry.chemical_compound, Pyruvic Acid, Molecular Structure, Chemistry, Circular Dichroism, Glutamic acid, Hydrogen-Ion Concentration, Tautomer, Pyrimidines, Amino Acid Substitution, Gene Expression Regulation, Mutagenesis, Site-Directed, Pyruvic acid, Thiamine Pyrophosphate

Abstract

Glyoxylate carboligase (GCL) is a thiamin diphosphate (ThDP)-dependent enzyme, which catalyzes the decarboxylation of glyoxylate and ligation to a second molecule of glyoxylate to form tartronate semialdehyde (TSA). This enzyme is unique among ThDP enzymes in that it lacks a conserved glutamate near the N1' atom of ThDP (replaced by Val51) or any other potential acid-base side chains near ThDP. The V51D substitution shifts the pH optimum to 6.0-6.2 (pK(a) of 6.2) for TSA formation from pH 7.0-7.7 in wild-type GCL. This pK(a) is similar to the pK(a) of 6.1 for the 1',4'-iminopyrimidine (IP)-4'-aminopyrimidinium (APH(+)) protonic equilibrium, suggesting that the same groups control both ThDP protonation and TSA formation. The key covalent ThDP-bound intermediates were identified on V51D GCL by a combination of steady-state and stopped-flow circular dichroism methods, yielding rate constants for their formation and decomposition. It was demonstrated that active center variants with substitution at I393 could synthesize (S)-acetolactate from pyruvate solely, and acetylglycolate derived from pyruvate as the acetyl donor and glyoxylate as the acceptor, implying that this substitutent favored pyruvate as the donor in carboligase reactions. Consistent with these observations, the I393A GLC variants could stabilize the predecarboxylation intermediate analogues derived from acetylphosphinate, propionylphosphinate, and methyl acetylphosphonate in their IP tautomeric forms notwithstanding the absence of the conserved glutamate. The role of the residue at the position occupied typically by the conserved Glu controls the pH dependence of kinetic parameters, while the entire reaction sequence could be catalyzed by ThDP itself, once the APH(+) form is accessible.

Published

2012

29. Substrate Activation of Brewers' Yeast Pyruvate Decarboxylase Is Abolished by Mutation of Cysteine 221 to Serine

Author

Zhixiang Hu, Yuhong Gao, William Furey, Irina Baburina, Frank Jordan, and Stefan Hohmann

Subjects

Molecular Sequence Data, Saccharomyces cerevisiae, Mutant, Biochemistry, Substrate Specificity, Serine, Escherichia coli, Cysteine, DNA Primers, chemistry.chemical_classification, Binding Sites, Base Sequence, biology, Substrate (chemistry), biology.organism_classification, Recombinant Proteins, Enzyme Activation, Kinetics, Enzyme, chemistry, Mutation, Steady state (chemistry), Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Brewers' yeast pyruvate decarboxylase (EC 4.1.1.1), a thiamin diphosphate and Mg(II)-dependent enzyme, isolated from Saccharomyces cerevisiae possesses four cysteines/subunit at positions 69, 152, 221, and 222. Earlier studies conducted on a variant of the enzyme with a single Cys at position 221 (derived from a gene that was the product of spontaneous fusion) showed that this enzyme is still subject to substrate activation [Zeng, X., Farrenkopf, B., Hohmann, S., Jordan, F., Dyda, F., & Furey, W. (1993) Biochemistry 32, 2704-2709], indicating that if Cys was responsible for this activation, it had to be C221. To further test the hypothesis, the C221S and C222S single and the C221S-C222S double mutants were constructed. It is clearly shown that the mutation at C221, but not at C222, leads to abolished substrate activation according to a number of kinetic criteria, both steady state and pre steady state. On the basis of the three-dimensional structure of the enzyme [Dyda, F., Furey, W., Swaminathan, S., Sax, M., Farrenkopf, B., Jordan, F. (1993) Biochemistry 32, 6165-6170], it is obvious that while C221 is located on the beta domain, whereas thiamin diphosphate is wedged at the interface of the alpha and gamma domains, addition of pyruvate or pyruvamide as a hemiketal adduct to the sulfur of C221 can easily bridge the gap between the beta and alpha domains. In fact, residues in one or both domains must be dislocated by this adduct formation. It is very likely that regulation as expressed in substrate activation is transmitted via this direct contact made between the two domains in the presence of the activator.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1994

30. A covalently trapped folding intermediate of subtilisin E: Spontaneous dimerization of a prosubtilisin E Ser49Cys mutant in vivo and its autoprocessing in vitro

Author

Xueli Zhu, Masayori Inouye, Frank Jordan, and Zhixiang Hu

Subjects

Protein Folding, Hot Temperature, Macromolecular Substances, Stereochemistry, Dimer, Molecular Sequence Data, Biochemistry, chemistry.chemical_compound, Enzyme Stability, Escherichia coli, Amino Acid Sequence, Subtilisins, Cloning, Molecular, Protein Precursors, Guanidine, Protein precursor, chemistry.chemical_classification, Base Sequence, biology, Circular Dichroism, Subtilisin, Molten globule, Amino acid, Monomer, chemistry, Chaperone (protein), Mutation, Mutagenesis, Site-Directed, biology.protein, Bacillus subtilis

Abstract

The propeptide of subtilisin E (the N-terminal 77 amino acid extension) is required for the proper folding of the nascent mature protein and is also a potent and specific inhibitor of the active enzyme. Previous studies have demonstrated that the propeptide can renature denatured mature sequence either in cis or in trans and can be considered an intramolecular chaperone, since it is not required for activity of the mature enzyme. In this paper it is shown that a prosubtilisin-S49C mutant can be expressed in Escherichia coli either as a monomer or as a disulfide-linked dimer, (prosubtilisin-S49C)2, depending on the vector selected. Interconversion between (prosubtilisin-S49C)2 and prosubtilisin-S49C could be readily achieved by reduction and oxidation in denaturing solutions, such as guanidine hydrochloride or urea. While the monomer can undergo autoprocessing in vitro under refolding conditions, the dimer is trapped in an intermediate state which could not be processed into active enzyme. Remarkably, the autoprocessing of this trapped intermediate could be induced readily upon reduction by dithiothreitol. This disulfide-linked (prosubtilisin-S49C)2 is fairly stable, but does tend to aggregate when the ionic strength of the solution is reduced below 0.1 M. The disulfide-linked (prosubtilisin-S49C)2 has far- and near-UV CD spectra revealing the presence of both secondary and tertiary structures, respectively, similar to those of the active mature monomer. Hence this autoprocessing-competent state appears to be a "late" folding intermediate, arising after the "molten globule" state formed in the absence of the prosequence, that has no discernible tertiary structure.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1994

31. Assignment of function to histidines 260 and 298 by engineering the E1 component of the Escherichia coli 2-oxoglutarate dehydrogenase complex; substitutions that lead to acceptance of substrates lacking the 5-carboxyl group

Author

Junjie Wang, Hetalben Patel, Jaeyoung Song, Frank Jordan, Natalia S. Nemeria, Anand Balakrishnan, Da Jeong Shim, and Edgardo T. Farinas

Subjects

chemistry.chemical_classification, Escherichia coli Proteins, Molecular Sequence Data, Protein engineering, Biology, Pyruvate dehydrogenase complex, medicine.disease_cause, Protein Engineering, Biochemistry, Article, Substrate Specificity, Enzyme, chemistry, medicine, Histidine, Ketoglutarate Dehydrogenase Complex, Amino Acid Sequence, Saturated mutagenesis, Branched-chain alpha-keto acid dehydrogenase complex, Escherichia coli, Peptide sequence

Abstract

The first component (E1o) of the Escherichia coli 2-oxoglutarate dehydrogenase complex (OGDHc) was engineered to accept substrates lacking the 5-carboxylate group by subjecting H260 and H298 to saturation mutagenesis. Apparently, H260 is required for substrate recognition, but H298 could be replaced with hydrophobic residues of similar molecular volume. To interrogate whether the second component would allow synthesis of acyl-coenzyme A derivatives, hybrid complexes consisting of recombinant components of OGDHc (o) and pyruvate dehydrogenase (p) enzymes were constructed, suggesting that a different component is the "gatekeeper" for specificity for these two multienzyme complexes in bacteria, E1p for pyruvate but E2o for 2-oxoglutarate.

Published

2011

32. Snapshot of a reaction intermediate: analysis of benzoylformate decarboxylase in complex with a benzoylphosphonate inhibitor

Author

Gabriel S. Brandt, Michael J. McLeish, Malea M. Kneen, Dagmar Ringe, Natalia S. Nemeria, Ahmet Tarik Baykal, Alejandra Yep, Frank Jordan, Gregory A. Petsko, David I. Ruby, Sumit Chakraborty, and George L. Kenyon

Subjects

Circular dichroism, Stereochemistry, Chemistry, Carboxy-Lyases, Circular Dichroism, Organophosphonates, Stereoisomerism, Reaction intermediate, Lyase, Crystallography, X-Ray, Biochemistry, Tautomer, Binding, Competitive, Benzoylformate decarboxylase, Article, Adduct, Substrate Specificity, Kinetics, Biocatalysis, Enzyme Inhibitors, Aldehyde-Lyases

Abstract

Benzoylformate decarboxylase (BFDC) is a thiamin diphosphate- (ThDP-) dependent enzyme acting on aromatic substrates. In addition to its metabolic role in the mandelate pathway, BFDC shows broad substrate specificity coupled with tight stereo control in the carbon-carbon bond-forming reverse reaction, making it a useful biocatalyst for the production of chiral alpha-hydroxy ketones. The reaction of methyl benzoylphosphonate (MBP), an analogue of the natural substrate benzoylformate, with BFDC results in the formation of a stable analogue (C2alpha-phosphonomandelyl-ThDP) of the covalent ThDP-substrate adduct C2alpha-mandelyl-ThDP. Formation of the stable adduct is confirmed both by formation of a circular dichroism band characteristic of the 1',4'-iminopyrimidine tautomeric form of ThDP (commonly observed when ThDP forms tetrahedral complexes with its substrates) and by high-resolution mass spectrometry of the reaction mixture. In addition, the structure of BFDC with the MBP inhibitor was solved by X-ray crystallography to a spatial resolution of 1.37 A (PDB ID 3FSJ). The electron density clearly shows formation of a tetrahedral adduct between the C2 atom of ThDP and the carbonyl carbon atom of the MBP. This adduct resembles the intermediate from the penultimate step of the carboligation reaction between benzaldehyde and acetaldehyde. The combination of real-time kinetic information via stopped-flow circular dichroism with steady-state data from equilibrium circular dichroism measurements and X-ray crystallography reveals details of the first step of the reaction catalyzed by BFDC. The MBP-ThDP adduct on BFDC is compared to the recently solved structure of the same adduct on benzaldehyde lyase, another ThDP-dependent enzyme capable of catalyzing aldehyde condensation with high stereospecificity.

Published

2009

33. Elucidation of the chemistry of enzyme-bound thiamin diphosphate prior to substrate binding: defining internal equilibria among tautomeric and ionization states

Author

George L. Kenyon, Mulchand S. Patel, Frank Jordan, Lioubov G. Korotchkina, Michael J. McLeish, and Natalia S. Nemeria

Subjects

Stereochemistry, Carboxy-Lyases, Pyruvate Oxidase, Pyruvate Dehydrogenase Complex, Ring (chemistry), Pseudomonas fluorescens, Biochemistry, Cofactor, Catalysis, Substrate Specificity, Ionization, Humans, Aldehyde-Lyases, chemistry.chemical_classification, biology, Pseudomonas putida, Circular Dichroism, Substrate (chemistry), Stereoisomerism, Hydrogen-Ion Concentration, Tautomer, Enzymes, Kinetics, Enzyme, chemistry, Intramolecular force, biology.protein, Thiamine Pyrophosphate, Lactobacillus plantarum

Abstract

Both solution and crystallographic studies suggest that the 4'-aminopyrimidine ring of the thiamin diphosphate coenzyme participates in catalysis, likely as an intramolecular general acid-base catalyst via the unusual 1',4'-iminopyrimidine tautomer. It is indeed uncommon for a coenzyme to be identified in its rare tautomeric form on its reaction pathways, yet this has been possible with thiamin diphosphate, in some cases even in the absence of substrate [Nemeria, N., Chakraborty, S., Baykal, A., Korotchkina, L., Patel, M. S., and Jordan, F. (2007) Proc. Natl. Acad. Sci. U.S.A. 104, 78-82.]. The ability to detect both the aminopyrimidine and iminopyrimidine tautomeric forms of thiamin diphosphate on enzymes has enabled us to assign the predominant tautomeric form present in individual intermediates on the pathway. Herein, we report the pH dependence of these tautomeric forms providing the first data for the internal thermodynamic equilibria on thiamin diphosphate enzymes for the various ionization and tautomeric forms of this coenzyme on four enzymes: benzaldehyde lyase, benzoylformate decarboxylase, pyruvate oxidase, and the E1 component of the human pyruvate dehydrogenase multienzyme complex. Evidence is provided for an important function of the enzyme environment in altering both the ionization and tautomeric equilibria on the coenzyme even prior to addition of substrate. The pKa for the 4'-aminopyrimidinium moiety coincides with the pH for optimum activity thereby ensuring that all ionization states and tautomeric states are accessible during the catalytic cycle. The dramatic influence of the protein on the internal equilibria also points to conditions under which the long-elusive ylide intermediate could be stabilized.

Published

2007

34. Tetrahedral intermediates in thiamin diphosphate-dependent decarboxylations exist as a 1',4'-imino tautomeric form of the coenzyme, unlike the michaelis complex or the free coenzyme

Author

Ahmet Tarik Baykal, Frank Jordan, Sheng Zhang, William Furey, Ebenezer Joseph, Yan Yan, and Natalia S. Nemeria

Subjects

Models, Molecular, Phosphonoacetic Acid, Circular dichroism, Stereochemistry, Decarboxylation, Protein Conformation, Coenzymes, Pyruvate Dehydrogenase Complex, Biochemistry, Cofactor, Catalysis, Adduct, Fungal Proteins, Point Mutation, chemistry.chemical_classification, Fungal protein, Binding Sites, biology, Circular Dichroism, Titrimetry, Electron acceptor, Tautomer, chemistry, Models, Chemical, biology.protein, Thiamine Pyrophosphate, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Two circular dichroism signals observed on thiamin diphosphate (ThDP)-dependent enzymes, a positive band in the 300-305 nm range and a negative one in the 320-330 nm range, were investigated on yeast pyruvate decarboxylase (YPDC) and on the E1 subunit of the Escherichia coli pyruvate dehydrogenase complex (PDHc-E1). Addition of the tetrahedral ThDP-acetaldehyde adduct, 2-alpha-hydroxyethylThDP, to PDHc-E1 generates the positive band at 300 nm, consistent with the formation of the 1',4'-iminopyrimidine tautomer, as also demonstrated for phosphonolactylthiamin diphosphate, a stable analogue of the tetrahedral ThDP-pyruvate adduct 2-alpha-lactylThDP (Jordan, F. et al. (2003) J. Am. Chem. Soc. 125, 12732-12738). Therefore, we suggest that all tetrahedral ThDP-bound covalent complexes will also prefer this tautomer, and that the 4'-aminopyrimidine of ThDP participates in multiple steps of acid-base catalysis on ThDP enzymes. Studies with YPDC and PDHc-E1, and their active center variants, in conjunction with chemical models, enabled assignment of the negative band at 330 nm to a charge-transfer transition between the 4'-aminopyrimidine tautomer (presumed electron donor) and the thiazolium ring (presumed electron acceptor) of ThDP, with no significant contributions from any amino acid side chain of the proteins. However, in both YPDC and PDHc-E1, the presence of substrate or substrate surrogate was required to enable detection, suggesting that the band at 320-330 nm be used as a reporter for the Michaelis complex, involving the amino tautomer, on both enzymes. As the positive band near 300 nm reports on the 1',4'-imino tautomer of ThDP, methods are now available for kinetic monitoring of both tautomeric forms.

Published

2004

35. NMR analysis of covalent intermediates in thiamin diphosphate enzymes

Author

Frank Jordan, Ralph Golbik, Gerhard Hübner, Gunter Schneider, David M. Chipman, Kathrin Uhlemann, Kai Tittmann, Ronald G. Duggleby, Mulchand S. Patel, and Ludmila Khailova

Subjects

chemistry.chemical_classification, Models, Molecular, Zymomonas, Binding Sites, Magnetic Resonance Spectroscopy, biology, Stereochemistry, Active site, Biochemistry, Benzoylformate decarboxylase, Cofactor, Catalysis, Enzyme, chemistry, Covalent bond, biology.protein, Mutagenesis, Site-Directed, Protons, Thiamine Pyrophosphate, Site-directed mutagenesis, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Enzymic catalysis proceeds via intermediates formed in the course of substrate conversion. Here, we directly detect key intermediates in thiamin diphosphate (ThDP)-dependent enzymes during catalysis using (1)H NMR spectroscopy. The quantitative analysis of the relative intermediate concentrations allows the determination of the microscopic rate constants of individual catalytic steps. As demonstrated for pyruvate decarboxylase (PDC), this method, in combination with site-directed mutagenesis, enables the assignment of individual side chains to single steps in catalysis. In PDC, two independent proton relay systems and the stereochemical control of the enzymic environment account for proficient catalysis proceeding via intermediates at carbon 2 of the enzyme-bound cofactor. The application of this method to other ThDP-dependent enzymes provides insight into their specific chemical pathways.

Published

2003

36. Histidine 407, a phantom residue in the E1 subunit of the Escherichia coli pyruvate dehydrogenase complex, activates reductive acetylation of lipoamide on the E2 subunit. An explanation for conservation of active sites between the E1 subunit and transketolase

Author

Natalia S. Nemeria, Yan Yan, Farzad Sheibani, Sheng Zhang, William Furey, Palaniappa Arjunan, Andrew Brunskill, Wen Wei, and Frank Jordan

Subjects

Pyruvate decarboxylation, Saccharomyces cerevisiae Proteins, Protein subunit, Pyruvate Dehydrogenase Complex, Transketolase, Calorimetry, Dihydrolipoyllysine-Residue Acetyltransferase, Biochemistry, chemistry.chemical_compound, Acetyltransferases, Multienzyme Complexes, Histidine, Pyruvate Dehydrogenase (Lipoamide), Conserved Sequence, Alanine, Binding Sites, biology, Thioctic Acid, Escherichia coli Proteins, Titrimetry, Active site, Isothermal titration calorimetry, Acetylation, Pyruvate dehydrogenase complex, Recombinant Proteins, Protein Structure, Tertiary, Enzyme Activation, chemistry, biology.protein, Lipoamide, Mutagenesis, Site-Directed, Oxidation-Reduction

Abstract

Least squares alignment of the E. coli pyruvate dehydrogenase multienzyme complex E1 subunit and yeast transketolase crystal structures indicates a general structural similarity between the two enzymes and provides a plausible location for a short-loop region in the E1 structure that was unobserved due to disorder. The residue H407, located in this region, is shown to be able to penetrate the active site. Suggested by this comparison, the H407A E1 variant was created, and H407 was shown to participate in the reductive acetylation of both an independently expressed lipoyl domain and the intact 1-lipoyl E2 subunit. While the H407A substitution only modestly affected the reaction through pyruvate decarboxylation (ca. 14% activity compared to parental E1), the overall complex has a much impaired activity, at most 0.15% compared to parental E1. Isothermal titration calorimetry measurements show that the binding of the lipoyl domain to the H407A E1 variant is much weaker than that to parental E1. At the same time, mass spectrometric measurements clearly demonstrate much impaired reductive acetylation of the independently expressed lipoyl domain and of the intact 1-lipoyl E2 by the H407A variant compared to the parental E1. A proposal is presented to explain the remarkable conservation of the three-dimensional structure at the active centers of the E. coli E1 subunit and transketolase on the basis of the parallels in the ligation-type reactions carried out and the need to protonate a very weak acid, a dithiolane sulfur atom in the former, and a carbonyl oxygen atom in the latter.

Published

2002

37. Structure of the pyruvate dehydrogenase multienzyme complex E1 component from Escherichia coli at 1.85 A resolution

Author

Frank Jordan, Andrew Brunskill, Yan Yan, John R. Guest, Palaniappa Arjunan, William Furey, Martin Sax, Krishnamoorthy Chandrasekhar, and Natalia S. Nemeria

Subjects

Models, Molecular, Stereochemistry, Dimer, Protein subunit, Molecular Sequence Data, Pyruvate Dehydrogenase Complex, medicine.disease_cause, Crystallography, X-Ray, Biochemistry, Cofactor, chemistry.chemical_compound, Oxidoreductase, medicine, Escherichia coli, Computer Simulation, Magnesium, Amino Acid Sequence, chemistry.chemical_classification, Binding Sites, biology, Active site, Water, Pyruvate dehydrogenase complex, Crystallography, Enzyme, chemistry, biology.protein, Solvents, Thiamine Pyrophosphate, Dimerization, Protein Binding

Abstract

The crystal structure of the recombinant thiamin diphosphate-dependent E1 component from the Escherichia coli pyruvate dehydrogenase multienzyme complex (PDHc) has been determined at a resolution of 1.85 A. The E. coli PDHc E1 component E1p is a homodimeric enzyme and crystallizes with an intact dimer in an asymmetric unit. Each E1p subunit consists of three domains: N-terminal, middle, and C-terminal, with all having alpha/beta folds. The functional dimer contains two catalytic centers located at the interface between subunits. The ThDP cofactors are bound in the "V" conformation in clefts between the two subunits (binding involves the N-terminal and middle domains), and there is a common ThDP binding fold. The cofactors are completely buried, as only the C2 atoms are accessible from solution through the active site clefts. Significant structural differences are observed between individual domains of E1p relative to heterotetrameric multienzyme complex E1 components operating on branched chain substrates. These differences may be responsible for reported alternative E1p binding modes to E2 components within the respective complexes. This paper represents the first structural example of a functional pyruvate dehydrogenase E1p component from any species. It also provides the first representative example for the entire family of homodimeric (alpha2) E1 multienzyme complex components, and should serve as a model for this class of enzymes.

Published

2002

38. Solvent kinetic isotope effects monitor changes in hydrogen bonding at the active center of yeast pyruvate decarboxylase concomitant with substrate activation: the substituent at position 221 can control the state of activation

Author

Wen Wei, Frank Jordan, and Min Liu

Subjects

Models, Molecular, Stereochemistry, Decarboxylation, Substituent, Biochemistry, Cofactor, Substrate Specificity, Active center, Enzyme activator, chemistry.chemical_compound, Protein structure, Kinetic isotope effect, Zymomonas, Binding Sites, biology, Chemistry, Water, Hydrogen Bonding, Hydrogen-Ion Concentration, Protein Structure, Tertiary, Enzyme Activation, Kinetics, Models, Chemical, biology.protein, Mutagenesis, Site-Directed, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Substrate activation of yeast pyruvate decarboxylase has been studied extensively in the authors' laboratories providing strong evidence that interaction of substrate with residue C221 provides the trigger, and the information is then transmitted along the C221 to H92 to E91 to W412 to G413 pathway to the 4'-amino nitrogen of the thiamin diphosphate cofactor. Earlier, it was found that the C221S substitution reduced the Hill coefficient from 2.0 to 0.8-0.9, the C221A substitution to 1.0, even though C221 is located on the beta domain some 20 A from the active center thiamin diphosphate cofactor, which is at the interface of the alpha and gamma domains. Here are reported experiments on the C221D/C222A and C221E/C222A variants, in which a negative charge is built onto the C221 side chain, to better mimic the effect of a pyruvate molecule covalently bonded to C221 as a thiohemiketal. Both variants were purified to an optimal activity of 70% of the wild-type enzyme, higher activity than that with the earlier uncharged substitutions at this position. The Hill coefficient for both variants is exactly 1.0. The deuterium solvent kinetic isotope effects (SKIE) on k(cat) for these variants were similar to that for the wild-type enzyme and the C221A/C222A variant, suggesting that starting with the first irreversible step (decarboxylation) the rate-limiting transition states are very similar for all of these enzyme forms. In contrast, such SKIE on k(cat)/K(m) are quite different for the C221A/C222A variant (0.62) than for the C221E/C222A or C221D/C222A variants (0.80-0.82), clearly indicating the effect of the C221 substitutions on transition states starting with the binding of the first substrate to the enzyme and terminating with the decarboxylation step. The results provide strong additional evidence for the involvement of residue C221 in the substrate activation process and suggest that the C221D (C221E) substitution shifts the enzyme into a conformation that resembles the activated conformation. A comparison with SKIE for the wild-type enzyme provides insight to changes in hydrogen bonding at the active center as a result of substrate activation.

Published

2002

39. Consequences of a modified putative substrate-activation site on catalysis by yeast pyruvate decarboxylase

Author

Birgitta Seliger, Kai Tittmann, Gerhard Hübner, Frank Jordan, Michael Spinka, Jue Wang, and Ralph Golbik

Subjects

Stereochemistry, Kinetics, Saccharomyces cerevisiae, Biochemistry, Catalysis, Substrate Specificity, Active center, Residue (chemistry), Serine, Cysteine, Deuterium Oxide, chemistry.chemical_classification, Alanine, Chemistry, Yeast, Recombinant Proteins, Enzyme Activation, Thiazoles, Enzyme, Models, Chemical, Solvents, Thiamine Pyrophosphate, Pyruvate Decarboxylase, Pyruvate decarboxylase, Hydrogen

Abstract

Earlier, it had been proposed in the laboratories at Halle that a cysteine residue is responsible for the hysteretic substrate activation behavior of yeast pyruvate decarboxylase. More recently, this idea has received support in a series of studies from Rutgers with the identification of residue C221 as the site where substrate is bound to transmit the information to H92, to E91, to W412, and finally to the active center thiamin diphosphate. According to steady-state kinetic assays, the C221A/C222A variant is no longer subject to substrate activation yet is still a well-functioning enzyme. Several further experiments are reported on this variant: (1) The variant exhibits lag phases in the product formation progress curves, which can be attributed to a unimolecular step in the pre-steady-state stage of catalysis. (2) The rate of exchange with solvent deuterium of the thiamin diphosphate C2H atom is slowed by a factor of 2 compared to the wild-type enzyme, suggesting that the reduced activity that results from the substitutions some 20 A from the active center is also seen in the first key step of the reaction. (3) The solvent (deuterium oxide) kinetic isotope effect was found to be inverse on V(max)/K(m) (0.62), and small but normal on V(max) (1.26), virtually ruling out residue C221 as being responsible for the inverse effects reported for the wild-type enzyme at low substrate concentrations. The solvent kinetic isotope effects are compared to those on two related enzymes not subject to substrate activation, Zymomonas mobilis pyruvate decarboxylase and benzoylformate decarboxylase.

Published

2001

40. Effects of substitution of tryptophan 412 in the substrate activation pathway of yeast pyruvate decarboxylase

Author

Haijuan Li and Frank Jordan

Subjects

Hot Temperature, Stereochemistry, Phenylalanine, Saccharomyces cerevisiae, Biochemistry, Substrate Specificity, Residue (chemistry), Apoenzymes, Enzyme Stability, chemistry.chemical_classification, Alanine, Binding Sites, biology, Circular Dichroism, Mutagenesis, Tryptophan, Active site, Substrate (chemistry), Hydrogen-Ion Concentration, biology.organism_classification, Recombinant Proteins, Protein Structure, Tertiary, Enzyme Activation, Kinetics, Enzyme, Spectrometry, Fluorescence, chemistry, Amino Acid Substitution, biology.protein, Mutagenesis, Site-Directed, Thiamine Pyrophosphate, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Oligonucleotide-directed site-specific mutagenesis was carried out on pyruvate decarboxylase (EC 4.1.1.1) from Saccharomyces cerevisiae at W412, located on the putative substrate activation pathway and linking E91 on the alpha domain with W412 on the gamma domain of the enzyme. While C221 on the beta domain is the residue at which substrate activation is triggered [Baburina, I., et al. (1994) Biochemistry 33, 5630-5635; Baburina, I., et al. (1996) Biochemistry 35, 10249-10255], that information, via the substrate bound at C221, is transmitted to H92 on the alpha domain, across the domain divide from C221 [Baburina, I., et al. (1998) Biochemistry 37, 1235-1244; Baburina, I., et al. (1998) Biochemistry 37, 1245-1255], thence to E91 on the alpha domain [Li, H., and Jordan, F. (1999) Biochemistry 38, 9992-10003], and then on to W412 on the gamma domain and to the active site thiamin diphosphate located at the interface of the alpha and gamma domains [Arjunan, D., et al. (1996) J. Mol. Biol. 256, 590-600]. Substitution at W412 with F and A was carried out, resulting in active enzymes with specific activities about 4- and 10-fold lower than that of the wild-type enzyme. Even though W412 interacts with E91 and H115 via a main chain hydrogen bond donor and acceptor, respectively, there is clear evidence for the importance of the indole side chain of W412 from a variety of experiments: thermostability, fluorescence quenching, and the binding constants of the thiamin diphosphate, and circular dichroism spectroscopy, in addition to conventional steady-state kinetic measurements. While the substrate activation is still prominent in the W412F variant, its level is very much reduced in the W412A variant, signaling that the size of the side chain is also important in positioning the amino acids surrounding the active center to achieve substrate activation. The fluorescence studies demonstrate that W412 is a relatively minor contributor to the well-documented fluorescence of apopyruvate decarboxylase in its native state. The information about the W412 variants provides strong additional support for the putative substrate activation pathway from C221 --H92 --E91 --W412 --G413 --thiamin diphosphate. The accumulating evidence for the central role of the beta domain in stabilizing the overall structure is summarized.

Published

1999

41. Is a hydrophobic amino acid required to maintain the reactive V conformation of thiamin at the active center of thiamin diphosphate-requiring enzymes? Experimental and computational studies of isoleucine 415 of yeast pyruvate decarboxylase

Author

Ara Kahyaoglu, Ramy Farid, Frank Jordan, Fusheng Guo, and Deqi Zhang

Subjects

Models, Molecular, Binding Sites, biology, Chemistry, Stereochemistry, Protein Conformation, Computational Biology, Transketolase, Biochemistry, Binding, Competitive, Cofactor, Substrate Specificity, Residue (chemistry), Kinetics, Amino Acid Substitution, Valine, biology.protein, Pyruvate oxidase, Threonine, Isoleucine, Thiamine Pyrophosphate, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

The residue I415 in pyruvate decarboxylase from Saccharomyces cerevisiae was substituted with a variety of uncharged side chains of varying steric requirements to test the hypothesis that this residue is responsible for supporting the V coenzyme conformation reported for this enzyme [Arjunan et al. (1996) J. Mol. Biol. 256, 590-600]. Changing the isoleucine to valine and threonine decreased the kcat value and shifted the kcat-pH profile to more alkaline values progressively, indicating that the residue at position 415 not only is important for providing the optimal transition state stabilization but also ensures correct alignment of the ionizable groups participating in catalysis. Substitutions to methionine (the residue used in pyruvate oxidase for this purpose) or leucine (the corresponding residue in transketolase) led to greatly diminished kcat values, showing that for each thiamin diphosphate-dependent enzyme an optimal hydrophobic side chain evolved to occupy this key position. Computational studies were carried out on the wild-type enzyme and the I415V, I415G, and I415A variants in both the absence and the presence of pyruvate covalently bound to C2 of the thiazolium ring (the latter is a model for the decarboxylation transition state) to determine whether the size of the side chain is critically required to maintain the V conformation. Briefly, there are sufficient conformational constraints from the binding of the diphosphate side chain and three conserved hydrogen bonds to the 4'-aminopyrimidine ring to enforce the V conformation, even in the absence of a large side chain at position 415. There appears to be increased coenzyme flexibility on substitution of Ile415 to Gly in the absence compared with the presence of bound pyruvate, suggesting that entropy contributes to the rate acceleration. The additional CH3 group in Ile compared to Val also provides increased hydrophobicity at the active center, likely contributing to the rate acceleration. The computational studies suggest that direct proton transfer to the 4'-imino nitrogen from the thiazolium C2H is eminently plausible.

Published

1998

42. Reactivity at the substrate activation site of yeast pyruvate decarboxylase: inhibition by distortion of domain interactions

Author

Irina Baburina, Fusheng Guo, George Dikdan, Frank Jordan, Barbara Root, and Guillermo I. Tous

Subjects

Stereochemistry, Saccharomyces cerevisiae, Molecular Sequence Data, Peptide, Tritium, Biochemistry, Substrate Specificity, Fatty Acids, Monounsaturated, Residue (chemistry), Amino Acid Sequence, Carbon Radioisotopes, Cysteine, Acrolein, Chromatography, High Pressure Liquid, chemistry.chemical_classification, biology, Chemistry, Sulfhydryl Reagents, Maleates, Glyoxylates, biology.organism_classification, Yeast, Malonates, Trypsinization, Protein Structure, Tertiary, Enzyme Activation, Kinetics, Enzyme, Thiamine Pyrophosphate, Peptides, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

The residue C221 on pyruvate decarboxylase (EC. 4.1.1.1) from Saccharomyces cerevisiae has been shown to be the site where the substrate activation cascade is triggered [Baburina et al. (1994) Biochemistry 33, 5630-5635] and is located on the beta domain [Arjunan et al. (1996) J. Mol. Biol. 256, 590], while the active-center thiamin diphosphate is located20 A away, at the interface of the alpha and gamma domains. The reactivity of all three exposed cysteines (152, 221, and 222) was examined under the influence of known activators and inhibitors. Protein chemical methods, in conjunction with [1-14C] and [3-3H] analogues of the mechanism-based inhibitor p-ClC6H4CH=CHCOCOOH, demonstrated that the holoenzyme bound approximately 2-3 atoms of tritium/atom of C-14. However, when the labeled enzyme was subjected to trypsinization, followed by sequencing of the labeled peptide, only the tritium label was in evidence at C221, with a stoichiometry of 2 atoms of tritium/tetrameric holoenzyme. Apparently, the product of decarboxylation bonded to the enzyme survived the limited proteolysis and sequencing, but the bound 2-oxoacid was released during the protocol. Surprisingly, the C221S or C222A variants, although they still possess 20-30% specific activity compared to the wild-type enzyme, could still be inhibited by the XC6H4CH=CHCOCOOH class of inhibitors/substrate analogues, as well as by the product of decarboxylation from such compounds, cinnamaldehydes. Other potential nucleophilic sites for the inhibitor [C152 (the third exposed cysteine), residues D28, H114, H115, and E477 at the active center and H92 at the regulatory site] were also substituted by a nonnucleophilic side chain. All variants were still subject to inhibition by p-ClC6H4CH=CHCOCOOH, the active-center variants being inactivated even faster than the wild-type enzyme, suggesting that the active center is involved in the inactivation process. It appears that C221 is one of only two sites of interaction with such compounds (perhaps the result of a Michael addition across the C=C bond), yet the bound [1-14C]-labeled inhibitor could no longer be detected after peptide mapping at this site or at the catalytic site. Upon combining the tritiated inhibitor with [2-14C]-thiamin diphosphate, no evidence could be found for a thiamin-inhibitor-protein ternary complex, suggesting that the thiamin-bound enamine intermediate did not react further with the protein. It is likely that the second form of inhibition is at the active center, with the inhibitor cofactor-bound, which would have been released during the proteolytic protocol. Among other known activators, ketomalonate was found to react at C221 only. Glyoxalic acid, a mechanism-based inhibitor, on the other hand, could react at both the regulatory and the catalytic center. The high reactivity of C221 is consistent with it being in the thiolate form at the optimal pH of the enzyme [forming a Cys221S(-) + HHis92 ion pair; see Baburina et al. (1996) Biochemistry 35, 10249-10255, and Baburina et al. (1998) Biochemistry 37, 1235-1244]. Several additional compounds were tested as potential regulatory site-directed reagents: iodoacetate, 1,3-dibromoacetone, and 1-bromo-2-butanone. All three compounds reduced the Hill coefficient and hence appear to react at C221. It was concluded that either substitution of C221 by a nonnucleophilic residue or large groups attached to C221 in the wild-type enzyme lead to a distortion of domain interactions, interactions which are required for both optimal activity and substrate activation.

Published

1998

43. Systematic study of the six cysteines of the E1 subunit of the pyruvate dehydrogenase multienzyme complex from Escherichia coli: none is essential for activity

Author

Frank Jordan, Laurie Zipper, John R. Guest, Angela Brown, Jizu Yi, Alexander Volkov, and Natalia S. Nemeria

Subjects

Protein subunit, Pyruvate Dehydrogenase Complex, Biology, medicine.disease_cause, Biochemistry, Binding, Competitive, Feedback, Enzyme activator, chemistry.chemical_compound, Plasmid, Acetyl Coenzyme A, medicine, Escherichia coli, Cysteine, Pyruvates, chemistry.chemical_classification, Genetic Variation, Pyruvate dehydrogenase complex, Molecular biology, Enzyme Activation, Kinetics, Enzyme, chemistry, Fatty Acids, Unsaturated, Mutagenesis, Site-Directed, Thiamine Pyrophosphate, Dimerization, Thiamine pyrophosphate, Plasmids

Abstract

Variants of the Escherichia coli 1-lip pyruvate dehydrogenase multienzyme complex (1-lip PDHc) with the C259N and C259S substitutions in the putative thiamin diphosphate-(ThDP-) binding motif of the pyruvate dehydrogenase component (E1, EC 1.2.4.1) were characterized. Single substitutions were made at the five remaining cysteines of the E1 component, creating the C120A, C575A, C610A, C654A, and C770S variants to test the hypothesis that the activity loss that accompanies exposure of the enzyme to fluoropyruvate, bromopyruvate, and 2-oxo-3-butynoic acid is the result of the modification of approximately one cysteine residue per E1 monomer. Surprisingly, all single cysteine E1 variants could be reconstituted with E2-E3 subcomplex and showed PDHc activity ranging from 74% to 96% that of the parental enzyme. The specific activities of C259N and C259S variants of 1-lip PDHc were 58% and 27% relative to that of the parental 1-lip PDHc. All five single cysteine E1 variants, along with the C259N and C259S variants of 1-lip PDHc, could also (1) be inactivated with fluoropyruvate and 2-oxo-3-butynoic acid, (2) were subject to inactivation by the monoclonal antibody 18A9 reported from one of our laboratories, and (3) were subject to regulation by pyruvate and acetyl-CoA. It was therefore concluded that none of the six cysteine residues is essential for the activity of the E1 component or of the complex. When tested with the putative transition-state analogue, thiamin 2-thiothiazolone diphosphate, all but the C259S and C259N variants were very potently inhibited, the stoichiometry for parental E1 being about 1.6 mol of inhibitor/mol of E1 subunit. The C259S and C259N E1 variants required at least 25-fold greater inhibitor concentration to achieve the same level of inhibition. C259 is located in the putative thiamin diphosphate-binding motif of the enzyme [more exactly, it is adjacent to a ligand to the Mg(II) ion]. It is therefore concluded that thiamin 2-thiothiazolone diphosphate is not a transition-state analogue; rather, it is a potent inhibitor of the complex because of a specific interaction with the C259 residue.

Published

1998

44. 2-Oxo-3-alkynoic acids, universal mechanism-based inactivators of thiamin diphosphate-dependent decarboxylases: synthesis and evidence for potent inactivation of the pyruvate dehydrogenase multienzyme complex

Author

Jizu Yi, Deqi Zhang, Frank Jordan, John R. Guest, Angela Brown, Natalia S. Nemeria, Rosane S. Machado, and William B. Jordan

Subjects

Pyruvate decarboxylation, Pyruvate dehydrogenase kinase, Stereochemistry, Pyruvate Oxidase, Substituent, Mechanism based, Pyruvate Dehydrogenase Complex, Saccharomyces cerevisiae, Pyruvate dehydrogenase phosphatase, Biology, Pyruvate dehydrogenase complex, Biochemistry, Enzyme Activation, Fungal Proteins, chemistry.chemical_compound, Kinetics, Lactobacillus, chemistry, Bacterial Proteins, Escherichia coli, Fatty Acids, Unsaturated, Thiamine Pyrophosphate, Pyruvate Decarboxylase

Abstract

A new class of compounds, the 2-oxo-3-alkynoic acids with a phenyl substituent at carbon 4 was reported by the authors as potent irreversible and mechanism-based inhibitors of the thiamin diphosphate- (ThDP-) dependent enzyme pyruvate decarboxylase [Chiu, C.-F.,Jordan, F. (1994) J. Org. Chem. 59, 5763-5766]. The method has been successfully extended to the synthesis of the 4-, 5-, and 7-carbon aliphatic members of this family of compounds. These three compounds were then tested on three ThDP-dependent pyruvate decarboxylases: the Escherichia coli pyruvate dehydrogenase multienzyme complex (PDHc) and its E1 (ThDP-dependent) component, pyruvate oxidase (POX, phosphorylating; from Lactobacillus plantarum),and pyruvate decarboxylase (PDC) from Saccharomycescerevisiae. All three enzymes were irreversibly inhibited by the new compounds. The 4-carbon acid is the best substrate-analog inactivator known to date for PDHc, more potent than either fluoropyruvate or bromopyruvate. The following conclusions were drawn from extensive studies with PDHc: (a) The kinetics of inactivation of PDH complexes and of resolved E1 by 2-oxo-3-alkynoic acids is time- and concentration-dependent. (b) The 4-carbon acid has a Ki 2 orders of magnitude stronger than the 5-carbon acid, clearly demonstrating the substrate specificity of PDHc. (c) The rate of inactivation of PDH complexes and of resolved E1 by 2-oxo-3-alkynoic acids is enhanced by the addition of ThDP and MgCl2. (d) Pyruvate completely protects E1 and partially protects PDHc from inactivation by 2-oxo-3-butynoic acid. (e) E1 but not E2-E3 is the target of inactivation by 2-oxo-3-butynoic acid. (f) Inactivation of E1 by 2-oxo-3-butynoic acid is accompanied by modification of 1.3 cysteines/E1 monomer. The order of reactivity with the 4-carbon acid was PDHcPOXPDC. While the order of reactivity with PDHc and POX was 2-oxo-3-butynoic acid2-oxo-3-pentynoic acid2-oxo-3-heptynoic acid, the order of reactivity was reversed with PDC.

Published

1997

45. Catalytic centers in the thiamin diphosphate dependent enzyme pyruvate decarboxylase at 2.4-A resolution

Author

Frank Jordan, Martin Sax, Bruce Farrenkopf, William Furey, Fred Dyda, and Subramanyam Swaminathan

Subjects

chemistry.chemical_classification, Models, Molecular, Cofactor binding, Protein Folding, Binding Sites, biology, Stereochemistry, Dimer, Active site, Biochemistry, Benzoylformate decarboxylase, Catalysis, Amino acid, chemistry.chemical_compound, Saccharomyces, chemistry, X-Ray Diffraction, biology.protein, Protein folding, Computer Simulation, Binding site, Thiamine Pyrophosphate, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

The crystal structure of brewers' yeast pyruvate decarboxylase, a thiamin diphosphate dependent alpha-keto acid decarboxylase, has been determined to 2.4-A resolution. The homotetrameric assembly contains two dimers, exhibiting strong intermonomer interactions within each dimer but more limited ones between dimers. Each monomeric subunit is partitioned into three structural domains, all folding according to a mixed alpha/beta motif. Two of these domains are associated with cofactor binding, while the other is associated with substrate activation. The catalytic centers containing both thiamin diphosphate and Mg(II) are located deep in the intermonomer interface within each dimer. Amino acids important in cofactor binding and likely to participate in catalysis and substrate activation are identified.

Published

1993

46. Role of cysteines in the activation and inactivation of brewers' yeast pyruvate decarboxylase investigated with a PDC1-PDC6 fusion protein

Author

Xiaoping Zeng, Bruce Farrenkopf, William Furey, Frank Jordan, Stefan Hohmann, and Fred Dyda

Subjects

chemistry.chemical_classification, Time Factors, Stereochemistry, Decarboxylation, Recombinant Fusion Proteins, Genes, Fungal, Substrate (chemistry), Saccharomyces cerevisiae, Biology, Hydrogen-Ion Concentration, Biochemistry, Fusion protein, Fusion gene, Enzyme Activation, Kinetics, Enzyme, chemistry, Sulfhydryl reagent, Cysteine, Cloning, Molecular, Pyruvate Decarboxylase, Pyruvate decarboxylase

Abstract

Possible roles of the Cys side chains in the activation and inactivation mechanisms of brewers' yeast pyruvate decarboxylase were investigated by comparing the behavior of the tetrameric enzyme pdc1 containing four cysteines/subunit (positions 69, 152, 221, and 222) with that of a fusion enzyme (pdc1-6, a result of spontaneous gene fusion between PDC1 and PDC6 genes) that is 84% identical in sequence with pdc1 and has only Cys221 (the other three Cys being replaced by aliphatic side chains). The two forms of the enzyme are rather similar so far as steady-state kinetic parameters and substrate activation are considered, as tested for activation by the substrate surrogate pyruvamide. Therefore, if a cysteine is responsible for substrate activation, it must be Cys221. The inactivation of the two enzymes was tested with several inhibitors. Methylmethanethiol sulfonate, a broad spectrum sulfhydryl reagent, could substantially inactivate both enzymes, but was slightly less effective toward the fusion enzyme. (p-Nitrobenzoyl)formic acid is an excellent alternate substrate, whose decarboxylation product p-nitrobenzaldehyde inhibited both enzymes possibly at a Cys221, the only one still present in the fusion enzyme. Exposure of the fusion enzyme, just as of pdc1, to (E)-2-oxo-4-phenyl-3-butenoic acid type inhibitors/alternate substrates enabled detection of the enzyme-bound enamine intermediate at 440 nm. However, unlike pdc1, the fusion enzyme was not irreversibly inactivated by these substrates. These substrates are now known to cause inactivation of pdc1 with concomitant modification of one Cys of the four [Zeng, X.; Chung, A.; Haran, M.; Jordan, F. (1991) J. Am. Chem. Soc. 113, 5842-49].(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1993

47. Synthesis of 9-(3,4-dioxopentyl)hypoxanthine, the first arginine-directed purine derivative: an irreversible inactivator for purine nucleoside phosphorylase

Author

Salvatore J. Salamone and Frank Jordan

Subjects

Purine, chemistry.chemical_classification, Time Factors, biology, Stereochemistry, Affinity label, Purine analogue, Purine nucleoside phosphorylase, Biochemistry, chemistry.chemical_compound, Adenosine deaminase, Purine-Nucleoside Phosphorylase, chemistry, Hypoxanthines, medicine, biology.protein, Nucleotide, Pentosyltransferases, Inosine, Mathematics, Hypoxanthine, medicine.drug

Abstract

The synthesis of two potential arginine-directed purine-based analogues, 6-chloro-9-(3,4-dioxopentyl)purine (6) and 9-(3,4-dioxopentyl)hypoxanthine (7), is reported. Compound 7 was extensively tested as a potential affinity label of purine nucleoside phosphorylase (EC 2.4.2.1) from human erythrocytes. Evidence that 7 reacted with the catalytic center of purine nucleoside phosphorylase includes the following: (1) time-dependent inactivation of the enzyme by 7 was observed; (2) a plot of the pseudo-first-order rate constant for inactivation of the enzyme vs. concentration of 7 was hyperbolic, characteristic of saturation phenomenon; (3) substrates (Pi, arsenate, inosine) and a competitive inhibitor (formycin B) protected the enzyme from inactivation by 7. Compound 7 was 25 times more effective in inhibiting purine nucleoside phosphorylase than butanedione. Evidence that 7 modified arginine(s) includes the following: (1) when the inactivation was performed in borate, both the rate and the extent of inactivation were enhanced compared to those of the controls run in tris(hydroxymethyl)aminomethane hydrochloride (Tris-HCl) buffer; (2) dialysis of inactivator reversed the inactivation in Tris-HCl but not in borate buffer. All the above evidence combined with the previous demonstration [Jordan, F., & Wu, A. (1978) Arch. Biochem. Biophys. 190, 699-704] that butanedione modified only arginines in purine nucleoside phosphorylases and the results presented here demonstrating the similarities in the behavior of butanedione and 7 imply that compound 7 can be called an arginine-directed affinity label for purine nucleoside phosphorylase.

Published

1982

48. Solvent effects on thiamin-enzyme model interactions. I. Interactions with tryptophan

Author

Frank Jordan, Yitbarek H. Mariam, and Bijan Farzami

Subjects

Binding Sites, Aqueous solution, Quenching (fluorescence), Chemistry, Tryptophan, Protonation, Hydrogen-Ion Concentration, Photochemistry, Biochemistry, Fluorescence, Solvent, Kinetics, Spectrometry, Fluorescence, Models, Chemical, Enzyme model, Thermodynamics, Spectrophotometry, Ultraviolet, Thiamine Pyrophosphate, Solvent effects, Mathematics, Protein Binding

Abstract

The solvent polarity dependence of the interaction between thiamin and tryptophan was studied by spectrophotometric methods. The ultraviolet (UV) data clearly indicate that the interaction is weakened when the complex is transferred from water to aqueous ethanol or aqueous dioxane. The interaction of thiamin and tryptophan could also be detected by fluorescence-quenching studies (excitation of tryptophan at 287 nm, maximum emission at 348 nm). Appropriate treatment of the quenching data allowed dissection into static and dynamic contributions. A pyrimidine derivative related to thiamin, both in its neutral and protonated states, was shown to interact with tryptophan by fluorescence techniques, but not by UV. A thiazolium model was shown to interact with tryptophan by UV but was an inefficient quencher of the tryptophan fluorescence. Theoretical models are presented to explain the solvent dielectric constant dependence of the association constant between tryptophan and thiamin. Both electrostatic and dispersion forces are found to contribute to the stability of the complex.

Published

1977

49. Brewers' yeast pyruvate decarboxylase produces acetoin from acetaldehyde: a novel tool to study the mechanism of steps subsequent to carbon dioxide loss

Author

Frank Jordan and Gloria Chao Chen

Subjects

Pyruvate decarboxylation, Reaction mechanism, Carboxy-Lyases, Chemistry, Decarboxylation, Acetoin, Acetaldehyde, Saccharomyces cerevisiae, Biochemistry, Butanones, Kinetics, chemistry.chemical_compound, Kinetic isotope effect, Organic chemistry, Pyruvic acid, Pyruvate Decarboxylase, Mathematics, Pyruvate decarboxylase

Abstract

A gas-liquid chromatographic technique was developed for the determination of both acetaldehyde and the 3-4% acetoin side product that results from the brewers' yeast pyruvate decarboxylase (EC 4.1.1.1) catalyzed reaction of pyruvic acid. Employing this method enabled the demonstration of the catalysis of acetaldehyde condensation to acetoin by the enzyme. It was found that the acetoin produced enzymatically from pyruvic acid or from acetaldehyde was optically active, thus providing stereochemical information about the reaction. Deuterium kinetic isotope effects (employing CH3CHO and CH3CDO) were determined on the steady-state kinetic parameters to be 4.5 (Vmax) and 3.2 (Vmax/Kappm), respectively. This enabled, for the first time, the estimation of relative kinetic barriers for steps past decarboxylation. It could be concluded that (a) C-H bond scission was part of rate limitation in the enzyme-catalyzed condensation of acetaldehyde to acetoin and that (b) among the steps leading to the release of acetaldehyde, protonation of the key enamine intermediate was part of rate limitation. This latter finding is also directly applicable to the mechanism of pyruvate decarboxylation.

Published

1984

50. Metabolism of D-glucose in a wall-less mutant of Neurospora crassa examined by carbon-13 and phosphorus-31 nuclear magnetic resonances: effects of insulin

Author

John Lenard, Foluso Adebodun, Norma J. Greenfield, Maureen A. McKenzie, and Frank Jordan

Subjects

chemistry.chemical_classification, Glycogen, Stereochemistry, Metabolism, Carbohydrate, Biochemistry, Trehalose, chemistry.chemical_compound, chemistry, D-Glucose, Monosaccharide, Hexose, Phosphorus-31 NMR spectroscopy

Abstract

/sup 13/C NMR and /sup 31/P NMR have been used to investigate the metabolism of glucose by a wall-less strain of Neurospora crassa (slime), grown in a supplemented nutritionally defined medium and harvested in the early stationary stage of growth. With D-(1-/sup 13/C)- or D-(6-/sup 13/C)glucose as substrates, the major metabolic products identified from /sup 13/C NMR spectra were (2-/sup 13/C)ethanol, (3-/sup 13/C)alanine, and C/sub 1/- and C/sub 6/-labeled trehalose. Several observations suggested the existence of a substantial hexose monophosphate (HMP) shunt: (i) a 70% greater yield of ethanol from C/sub 6/- than from C/sub 1/-labeled glucose; (ii) C/sub 1/-labeled glucose yielded 19% C/sub 6/-labeled trehalose, while C/sub 6/-labeled glucose yielded only 4% C/sub 1/-labeled trehalose; (iii) a substantial transfer of /sup 13/C from C/sub 2/-labeled glucose to the C/sub 2/-position of ethanol. /sup 31/P NMR spectra showed millimolar levels of intracellular inorganic phosphate (P/sub i/), phosphodiesters, and diphosphates including sugar diphosphates and polyphosphate. Addition of glucose resulted in a decrease in cytoplasmic P/sub i/ and an increase in sugar monophosphates, which continued for at least 30 min. Phosphate resonances corresponding to metabolic intermediates of both the glycolytic and HMP pathways were identified in cell extracts. Addition of insulin (100more » nM) with the glucose had the following effects relative to glucose alone: (i) a 24% increase in the rate of ethanol production; (ii) a 38% increase in the rate of alanine production; (iii) a 27% increase in the rate of glucose disappearance. Insulin thus increases the rates of production of ethanol and alanine in these cells, in addition to increasing production of CO/sub 2/ and glycogen, as previously shown.« less

Published

1988