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Second Substrate (second + substrate)

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Chemistry100%

Selected Abstracts

Inhibition of pea ferredoxin,NADP(H) reductase by Zn-ferrocyanide

FEBS JOURNAL, Issue 22 2004
Daniela L. Catalano Dupuy
Ferredoxin,NADP(H) reductases (FNRs) represent a prototype of enzymes involved in numerous metabolic pathways. We found that pea FNR ferricyanide diaphorase activity was inhibited by Zn2+ (Ki 1.57 µm). Dichlorophenolindophenol diaphorase activity was also inhibited by Zn2+ (Ki 1.80 µm), but the addition of ferrocyanide was required, indicating that the inhibitor is an arrangement of both ions. Escherichia coli FNR was also inhibited by Zn-ferrocyanide, suggesting that inhibition is a consequence of common structural features of these flavoenzymes. The inhibitor behaves in a noncompetitive manner for NADPH and for artificial electron acceptors. Analysis of the oxidation state of the flavin during catalysis in the presence of the inhibitor suggests that the electron-transfer process between NADPH and the flavin is not significantly altered, and that the transfer between the flavin and the second substrate is mainly affected. Zn-ferrocyanide interacts with the reductase, probably increasing the accessibility of the prosthetic group to the solvent. Ferredoxin reduction was also inhibited by Zn-ferrocyanide in a noncompetitive manner, but the observed Ki was about nine times higher than those for the diaphorase reactions. The electron transfer to Anabaena flavodoxin was not affected by Zn-ferrocyanide. Binding of the apoflavodoxin to the reductase was sufficient to overcome the inhibition by Zn-ferrocyanide, suggesting that the interaction of FNRs with their proteinaceous electron partners may induce a conformational change in the reductase that alters or completely prevents the inhibitory effect. [source]

Recombinant human glucose-6-phosphate dehydrogenase

FEBS JOURNAL, Issue 14 2002
Evidence for a rapid-equilibrium random-order mechanism
Cloning and over-expression of human glucose 6-phosphate dehydrogenase (Glc6P dehydrogenase) has for the first time allowed a detailed kinetic study of a preparation that is genetically homogeneous and in which all the protein molecules are of identical age. The steady-state kinetics of the recombinant enzyme, studied by fluorimetric initial-rate measurements, gave converging linear Lineweaver,Burk plots as expected for a ternary-complex mechanism. Patterns of product and dead-end inhibition indicated that the enzyme can bind NADP+ and Glc6P separately to form binary complexes, suggesting a random-order mechanism. The Kd value for the binding of NADP+ measured by titration of protein fluorescence is 8.0 µm, close to the value of 6.8 µm calculated from the kinetic data on the assumption of a rapid-equilibrium random-order mechanism. Strong evidence for this mechanism and against either of the compulsory-order possibilities is provided by repeating the kinetic analysis with each of the natural substrates replaced in turn by structural analogues. A full kinetic analysis was carried out with deaminoNADP+ and with deoxyglucose 6-phosphate as the alternative substrates. In each case the calculated dissociation constant upon switching a substrate in a random-order mechanism (e.g. that for NADP+ upon changing the sugar phosphate) was indeed constant within experimental error as expected. The calculated rate constants for binding of the leading substrate in a compulsory-order mechanism, however, did not remain constant when the putative second substrate was changed. Previous workers, using enzyme from pooled blood, have variously proposed either compulsory-order or random-order mechanisms. Our study appears to provide unambiguous evidence for the latter pattern of substrate binding. [source]

Characterization of carbonic anhydrase from Neisseria gonorrhoeae

FEBS JOURNAL, Issue 6 2001
Björn Elleby
We have investigated the steady state and equilibrium kinetic properties of carbonic anhydrase from Neisseria gonorrhoeae (NGCA). Qualitatively, the enzyme shows the same kinetic behaviour as the well studied human carbonic anhydrase II (HCA II). This is reflected in the similar pH dependencies of the kinetic parameters for CO2 hydration and the similar behaviour of the kinetics of 18O exchange between CO2 and water at chemical equilibrium. The pH profile of the turnover number, kcat, can be described as a titration curve with an exceptionally high maximal value of 1.7 × 106 s,1 at alkaline pH and a pKa of 7.2. At pH 9, kcat is buffer dependent in a saturable manner, suggesting a ping-pong mechanism with buffer as the second substrate. The ratio kcat/Km is dependent on two ionizations with pKa values of 6.4 and 8.2. However, an 18O-exchange assay identified only one ionizable group in the pH profile of kcat/Km with an apparent pKa of 6.5. The results of a kinetic analysis of a His66,Ala variant of the bacterial enzyme suggest that His66 in NGCA has the same function as a proton shuttle as His64 in HCA II. The kinetic defect in the mutant can partially be overcome by certain buffers, such as imidazole and 1,2-dimethylimidazole. The bacterial enzyme shows similar Ki values for the inhibitors NCO,, SCN, and N3, as HCA II, while CN, and the sulfonamide ethoxzolamide are considerably weaker inhibitors of the bacterial enzyme than of HCA II. The absorption spectra of the adducts of Co(II)-substituted NGCA with acetazolamide, NCO,, SCN,, CN, and N3, resemble the corresponding spectra obtained with human Co(II)-isozymes I and II. Measurements of guanidine hydrochloride (GdnHCl)-induced denaturation reveal a sensitivity of the CO2 hydration activity to the reducing agent tris(2-carboxyethyl)phosphine (TCEP). However, the A292/A260 ratio was not affected by the presence of TCEP, and a structural transition at 2.8,2.9 m GdnHCl was observed. [source]

Application of automated matrix-assisted laser desorption/ionization time-of-flight mass spectrometry for the measurement of enzyme activities

RAPID COMMUNICATIONS IN MASS SPECTROMETRY, Issue 15 2001
Min-Jung Kang
Sample preparation methods and data acquisition protocols were optimized for the application of matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS) to high-throughput quantitative analysis of low molecular mass substrates and products of an enzyme-catalyzed reaction. Using a deuterlum-labeled internal standard, precise standard curves were obtained (r2,=,0.9998) over two orders of magnitude of concentration of rac -1-phenylethylamine (PEA), which is converted to 2-methoxy- N -[(1R)-1-phenylethyl]acetamide (MET) by a lipase-catalyzed reaction with ethylmethoxyacetate (EMA) as second substrate. Reliable relative standard deviations were achieved (,5%) using automated analysis with peak intensity ratios between 0.2 and 5 of analyte to internal standard. This method permitted quantitative analysis of the lipase reaction, producing results comparable to those from gas chromatographic (GC) analysis in the dynamic range of GC. This work shows that MALDI-TOFMS can be applied for the high-throughput screening of enzymes. Copyright © 2001 John Wiley & Sons, Ltd. [source]

Structure of macrophomate synthase

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 7 2004
Toyoyuki Ose
Macrophomate synthase (MPS) is an enzyme that catalyzes an extraordinarily complex conversion reaction, including two decarboxylations, two carbon,carbon bond formations and a dehydration, to form the benzoate analogue macrophomate from a 2-pyrone derivative and oxalacetate. Of these reactions, the two carbon,carbon bond formations are especially noteworthy because previous experiments have indicated that they proceed via a Diels,Alder reaction, one of the most widely used reactions in organic synthesis. The structural evidence that MPS catalyzes an intermolecular Diels,Alder reaction has been reported recently [Ose et al. (2003), Nature (London), 422, 185,189]. Interestingly, the tertiary structure as well as the quaternary structure of MPS are similar to those of 2-dehydro-3-deoxygalactarate (DDG) aldolase, a carbon,carbon bond-forming enzyme that catalyzes the reversible reaction of aldol condensation/cleavage. Here, the structure of MPS is described in detail and compared with that of DDG aldolase. Both enzymes have a (,/,)8 -barrel fold and are classified as belonging to the enolase superfamily based on their reaction strategy. The basic principles for carbon,carbon bond formation used by both MPS and DDG aldolase are the same with regard to trapping the enolate substrate and inducing subsequent reaction. The major differences in the active sites between these two enzymes are the recognition mechanisms of the second substrates, 2-pyrone and DDG, respectively. [source]