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,

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

doi:10.1021/bi100828r

Cited by 45 publications

(67 citation statements)

References 41 publications

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“…The structure of the stable LThDP analog phosphonolactyl ThDP on PDHc E1 in the V‐conformation shows an almost perpendicular C2α–Pβ bond . An additional study on Zymomonas mobilis pyruvate decarboxylase may also provide insights into the long‐lived LThDP intermediate on DXP synthase. In this case, LThDP accumulates on E437D pyruvate decarboxylase, and the scissile C2α–C(carboxylate) bond deviates significantly from the perpendicular orientation required for efficient decarboxylation.…”

Section: Discussionmentioning

confidence: 98%

Defining critical residues for substrate binding to 1‐deoxy‐d‐xylulose 5‐phosphate synthase – active site substitutions stabilize the predecarboxylation intermediate C2α‐lactylthiamin diphosphate

et al. 2014

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1-Deoxy-d-xylulose 5-phosphate (DXP) synthase catalyzes formation of DXP from pyruvate and d-glyceraldehyde 3-phosphate (d-GAP) in a thiamin diphosphate (ThDP)-dependent manner, and is the first step in the essential pathway to isoprenoids in human pathogens. Understanding the mechanism of this unique enzyme is critical for developing new anti-infective agents that selectively target isoprenoid biosynthesis. The present study uses mutagenesis and a combination of protein fluorescence, circular dichroism and kinetics experiments to investigate the roles of Arg-420, Arg-478 and Tyr-392 in substrate binding and catalysis. The results support a random sequential, preferred order mechanism and predict Arg-420 and Arg-478 are involved in binding of the acceptor substrate, d-GAP. d-Glyceraldehyde, an alternative acceptor substrate lacking the phosphoryl group predicted to interact with Arg-420 and Arg-478, also accelerates decarboxylation of the pre-decarboxylation intermediate C2α-lactylthiamin diphosphate (LThDP) on DXP synthase, indicating this binding interaction is not absolutely required, and the hydroxyaldehyde sufficiently triggers decarboxylation. Unexpectedly, Tyr-392 contributes to d-GAP affinity and is not required for LThDP formation or its d-GAP-promoted decarboxylation. Time-resolved CD spectroscopy and NMR experiments indicate LThDP is significantly stabilized on R420A and Y392F variants compared to wild type DXP synthase in the absence of acceptor substrate, yet these substitutions do not appear to impact the rate of d-GAP-promoted LThDP decarboxylation in the presence of high d-GAP, and LThDP formation remains the rate-limiting step. These results suggest a role of these residues to promote d-GAP binding which in turn facilitates decarboxylation, and further highlight interesting differences between DXP synthase and other ThDP-dependent enzymes.

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Section: Discussionmentioning

confidence: 98%

Defining critical residues for substrate binding to 1‐deoxy‐d‐xylulose 5‐phosphate synthase – active site substitutions stabilize the predecarboxylation intermediate C2α‐lactylthiamin diphosphate

et al. 2014

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“…Ile469 is, however, located in a region of the enzyme which may be sensitive to changes. It is positioned adjacent to Glu468, important in catalytic activity, Ile467, involved in substrate recognition, and Ile471, crucial for substrate positioning (Pohl et al, 1998;Siegert et al, 2005;Meyer et al, 2010). Figure 1).…”

Section: Amino Acid Sequence Considerations In the G Oxydans Pdcmentioning

confidence: 99%

“…, 2010) and supports the interpretation that PDCs requires a protonated residue for efficient binding of the substrate. The ionizable group is thought to be the aminopyrimidine ring of the ThDP coenzyme (Meyer et al, 2010). The GoxPDC enzyme displayed normal Michaelis Menten kinetics with pyruvate as the substrate and was not subject to allosteric substrate activation as has been seen in PDCs from plants, yeasts and the bacterium S. ventriculi (Konig et al, 2009).…”

Section: Kinetic Characterization Of the Goxpdc Enzymementioning

confidence: 99%

Engineering pyruvate decarboxylase-mediated ethanol production in the thermophilic host Geobacillus thermoglucosidasius

Zyl

Taylor

Eley

et al. 2013

Appl Microbiol Biotechnol

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This study reports the expression, purification and kinetic characterization of a PDC from Gluconobacter oxydans. Kinetic analyses showed the enzyme to have high affinity for pyruvate (120µM at pH 5), high catalytic efficiency (4.75 x 10 5 M -1 s -1 at pH 5), a pH opt of approximately 4.5 and an in vitro temperature optimum at approximately 55°C (the highest yet reported for a b a c t e r i a l P D C ) . D u e t o g o o d in vitro thermostablity (approximately 40% enzyme activity retained after 30 minutes at 65°C) this PDC was considered to be a suitable candidate for heterologous expression in the thermophile Geobacillus thermoglucosidasius. Initial studies using a variety of methods failed to detect activity at any growth temperature. However, the application of codon harmonization (i.e., mimicry of the heterogeneous host's transcription and translational rhythm) yielded a protein that was fully functional in the thermophilic strain at 45°C (as determined by enzyme activity, Western blot, mRNA detection and ethanol productivity). Here we describe the successful expression of PDC in a true thermophile. Yields as high as 0.35 g/g ±0.04 ethanol per gram of glucose consumed were detected, highly competitive to those reported in ethanologenic thermophilic mutants. Although activities could not be detected at temperatures approaching the growth optimum for the strain, this study highlights that the possibility that previously unsuccessful expression of pdcs in Geobacillus spp. may be the result of ineffective transcription / translation coupling.

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“…This geometry is thought to promote decarboxylation by allowing maximum overlap of π electrons of the thiazolium ring and the p-orbital of the scissile bond [25,45]. The conformation has been observed in the X-ray structures of all the first tetrahedral intermediates, and intermediate analogues [25,42,[46][47][48]. Further, Ser26 has been proposed to assist in the decarboxylation step by carrying out a nucleophilic attack on carboxylate group of MThDP [40].…”

Section: X-ray Structure Of Bfdc T377l/a460ymentioning

confidence: 98%

“…To see how this was achieved we compared the binding of the LTHDP to PDC and to BFDC T377L/A460Y. Previously, the ZmPDC E473D structure in complex with LThDP was solved [42]. In this structure the methyl substituent of the lactyl moiety is within 5 Å of 11 atoms evenly distributed across seven different residues.…”

Section: X-ray Structure Of Bfdc T377l/a460ymentioning

confidence: 99%

Mechanistic and Structural Insight to an Evolved Benzoylformate Decarboxylase with Enhanced Pyruvate Decarboxylase Activity

et al. 2016

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Benzoylformate decarboxylase (BFDC) and pyruvate decarboxylase (PDC) are thiamin diphosphate-dependent enzymes that share some structural and mechanistic similarities. Both enzymes catalyze the nonoxidative decarboxylation of 2-keto acids, yet differ considerably in their substrate specificity. In particular, the BFDC from P. putida exhibits very limited activity with pyruvate, whereas the PDCs from S. cerevisiae or from Z. mobilis show virtually no activity with benzoylformate (phenylglyoxylate). Previously, saturation mutagenesis was used to generate the BFDC T377L/A460Y variant, which exhibited a greater than 10,000-fold increase in pyruvate/benzoylformate substrate utilization ratio compared to that of wtBFDC. Much of this change could be attributed to an improvement in the K m value for pyruvate and, concomitantly, a decrease in the k cat value for benzoylformate. However, the steady-state data did not provide any details about changes in individual catalytic steps. To gain insight into the changes in conversion rates of pyruvate and benzoylformate to acetaldehyde and benzaldehyde, respectively, by the BFDC T377L/A460Y variant, reaction intermediates of both substrates were analyzed by NMR and microscopic rate constants for the elementary catalytic steps were calculated. Herein we also report the high resolution X-ray structure of the BFDC T377L/A460Y variant, which provides context for the observed changes in substrate specificity.

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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,

Cited by 45 publications

References 41 publications

Defining critical residues for substrate binding to 1‐deoxy‐d‐xylulose 5‐phosphate synthase – active site substitutions stabilize the predecarboxylation intermediate C2α‐lactylthiamin diphosphate

Defining critical residues for substrate binding to 1‐deoxy‐d‐xylulose 5‐phosphate synthase – active site substitutions stabilize the predecarboxylation intermediate C2α‐lactylthiamin diphosphate

Engineering pyruvate decarboxylase-mediated ethanol production in the thermophilic host Geobacillus thermoglucosidasius

Mechanistic and Structural Insight to an Evolved Benzoylformate Decarboxylase with Enhanced Pyruvate Decarboxylase Activity

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