Structurally diverse dehydroshikimate dehydratase variants participate in microbial quinate catabolism

Peek, James; Roman, Joseph; Moran, Graham R.; Christendat, Dinesh

doi:10.1111/mmi.13542

Cited by 15 publications

(44 citation statements)

References 56 publications

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“…Recombinant protein expression and purification were carried out using an established protocol (Christendat et al ., ; Singh and Christendat, ; Peek et al ., ). Bacterial protein expression plasmids containing the genes for S. lycopersicum QDH, N. tabacum QDH, B. rapa QDH/SDH and B. napus QDH/SDH were transformed into E. coli BL21 CodonPlus (Agilent Technologies, https://www.agilent.com/).…”

Section: Methodsmentioning

confidence: 97%

“…DHQD activity was assessed using an enzyme‐coupled assay. In this assay, we utilized a microbial dehydroshikimate dehydratase enzyme that converts the dehydroshikimate produced by DHQD to protocatechuate, which can readily be detected by HPLC (Peek et al ., ) (Figure S1). All reaction mixtures were set up with the respective cofactors, NAD + or NADP + , quinate/shikimate and dehydroshikimate dehydratase enzyme.…”

Section: Methodsmentioning

confidence: 99%

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Structural and biochemical approaches uncover multiple evolutionary trajectories of plant quinate dehydrogenases

et al. 2018

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Quinate is produced and used by many plants in the biosynthesis of chlorogenic acids (CGAs). Chlorogenic acids are astringent and serve to deter herbivory. They also function as antifungal agents and have potent antioxidant properties. Quinate is produced at a branch point of shikimate biosynthesis by the enzyme quinate dehydrogenase (QDH). However, little information exists on the identity and biochemical properties of plant QDHs. In this study, we utilized structural and bioinformatics approaches to establish a QDH-specific primary sequence motif. Using this motif, we identified QDHs from diverse plants and confirmed their activity by recombinant protein production and kinetic assays. Through a detailed phylogenetic analysis, we show that plant QDHs arose directly from bifunctional dehydroquinate dehydratase-shikimate dehydrogenases (DHQD-SDHs) through different convergent evolutionary events, illustrated by our findings that eudicot and conifer QDHs arose early in vascular plant evolution whereas Brassicaceae QDHs emerged later. This process of recurrent evolution of QDH is further demonstrated by the fact that this family of proteins independently evolved NAD and NADP specificity in eudicots. The acquisition of QDH activity by these proteins was accompanied by the inactivation or functional evolution of the DHQD domain, as verified by enzyme activity assays and as reflected in the loss of key DHQD active site residues. The implications of QDH activity and evolution are discussed in terms of plant growth and development.

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Section: Methodsmentioning

confidence: 97%

Section: Methodsmentioning

confidence: 99%

Structural and biochemical approaches uncover multiple evolutionary trajectories of plant quinate dehydrogenases

et al. 2018

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“…This level of identity allowed us to predict the 3D structure of QsuB based on the QuiC1 crystal structure (PDB ID: 5HMQ) (Fig 2). All the residues (Arg64, Leu97, Glu134, Leu136, His168, Asp165, Gln191, Ser206, Arg210 and Glu239) identified previously in the active site of DSD of QuiC1 [14] were also present in the N-terminal domain of QsuB.…”

Section: Resultsmentioning

confidence: 85%

“…DSD is encoded by the asbF gene and, being identical in Bacillus anthracis and Bacillus thuringiensis , has been thoroughly investigated [12, 13]. Based on primary structure analysis, all known DSDs were divided into four groups: fungal single-domain, bacterial two-domain, AsbF-like, and bacterial membrane-associated enzymes [14]. The application of AsbF and fungal ( Podospora pauciseta ) and bacterial two-domain ( Klebsiella pneumoniae ) enzymes to obtain 3,4-DHBA as an intermediate for the generation of valuable compounds from glucose has been demonstrated [10, 11, 15, 16].…”

Section: Introductionmentioning

confidence: 99%

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Characterization of theCorynebacterium glutamicumdehydroshikimate dehydratase QsuB and its potential for microbial production of protocatechuic acid

Shmonova

Voloshina

Ovsienko

et al. 2020

Preprint

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2 The dehydroshikimate dehydratase (DSD) from Corynebacterium glutamicum 3 encoded by the qsuB gene is related to the previously described QuiC1 protein 4 (39.9% identity) from Pseudomonas putida. QuiC1 and QsuB are both two-domain 5 bacterial DSDs. The N-terminal domain provides dehydratase activity, while the 6 C-terminal domain has sequence identity with 4-hydroxyphenylpyruvate 7 dioxygenase. Here, the QsuB protein and its DSD domain (N-QsuB) were 8 expressed in the T7 system, purified and characterized. QsuB was present mainly 9 in octameric form (60%), while N-QsuB had a predominantly monomeric structure 10 (80%) in solution. Both proteins possessed DSD activity with one of the following 11 cofactors (listed in order of decreasing activity): Co 2+ , Mg 2+ , Mn 2+ or Ca 2+ . The K m 12 and k cat values for QsuB were two and three times higher, respectively (K m ~ 1 13 mM, k cat ~ 61 s -1 ) than those for N-QsuB. Notably, 3,4-DHBA inhibited both 14 enzymes via an uncompetitive mechanism. QsuB and N-QsuB were tested for 3,4-15 DHBA production from glucose in E. coli. MG1655aroE P lac qsuB produced at 16 least two times more 3,4-DHBA than MG1655aroE P lac n-qsuB in the presence 17 of isopropyl β-D-1-thiogalactopyranoside.18

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The structural complexity of pyomelanin impacts UV shielding in Pseudomonas species with different lifestyles

Diaz Appella,

Kolender,

Oppezzo

et al. 2024

FEBS Letters

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Pyomelanin, a polymeric pigment in Pseudomonas, arises mainly from alterations in tyrosine degradation. The chemical structure of pyomelanin remains elusive due to its heterogeneous nature. Here, we report strain‐specific differences in pyomelanin structural features across Pseudomonas using PAO1 and PA14 reference strains carrying mutations in hmgA (a gene involved in pyomelanin synthesis), a melanogenic P. aeruginosa clinical isolate (PAM), and a melanogenic P. extremaustralis (PexM). UV spectra showed dual peaks for PAO1 and PA14 mutants and single peaks for PAM and PexM. FTIR phenol : alcohol ratio changes and complex NMR spectra indicated non‐linear polymers. UVC radiation survival increased with pyomelanin addition, correlating with pigment absorption attenuation. P. extremaustralis UVC survival varied with melanin source, with PAO1 pyomelanin being the most protective. These findings delineate structure‐based pyomelanin subgroups, having distinct physiological effects.

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Structurally diverse dehydroshikimate dehydratase variants participate in microbial quinate catabolism

Cited by 15 publications

References 56 publications

Structural and biochemical approaches uncover multiple evolutionary trajectories of plant quinate dehydrogenases

Structural and biochemical approaches uncover multiple evolutionary trajectories of plant quinate dehydrogenases

Characterization of theCorynebacterium glutamicumdehydroshikimate dehydratase QsuB and its potential for microbial production of protocatechuic acid

The structural complexity of pyomelanin impacts UV shielding in Pseudomonas species with different lifestyles

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