Expanding the current knowledge and biotechnological applications of the oxygen‐independent <scp><i>ortho</i></scp>‐phthalate degradation pathway

Sanz, David J.; Garcı́a, José Luis; Dı́az, Eduardo

doi:10.1111/1462-2920.15119

Cited by 8 publications

(3 citation statements)

References 85 publications

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“…chlorobenzoate DSM 18012 (on chromosome) ( 19 ). Furthermore, Sanz et al ( 43 ) suggested that the complete o -phthalic acid degradation pathway in denitrifying bacteria, together with the o -phthalic acid transporter gene, is successfully transferred to heterologous bacteria that are unable to use o -phthalic acid as a substrate. In the present study, a similar observation was made in DEHP side chain-degrading Burkholderiales Bin13 and o -phthalic acid-degrading Aestuariibacter Bin44.…”

Section: Discussionmentioning

confidence: 99%

Integrated Multi-omics Investigations Reveal the Key Role of Synergistic Microbial Networks in Removing Plasticizer Di-(2-Ethylhexyl) Phthalate from Estuarine Sediments

Wei

Chen

et al. 2021

mSystems

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Section: Discussionmentioning

confidence: 99%

Integrated Multi-omics Investigations Reveal the Key Role of Synergistic Microbial Networks in Removing Plasticizer Di-(2-Ethylhexyl) Phthalate from Estuarine Sediments

Wei

Chen

et al. 2021

mSystems

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“…PA01 (on chromosome), and T. chlorobenzoate DSM18012 (on chromosome) [19]. Furthermore, Sanz [42] suggested that the complete o-phthalic acid degradation pathway in denitrifying bacteria, together with the o-phthalic acid transporter gene, is successfully transferred to heterologous bacteria that are unable to use ophthalic acid as a substrate. In the present study, a similar observation was made in DEHP sidechains-degrading Burkholderiales Bin13 and o-phthalic acid-degrading Aestuariibacter Bin44.…”

Section: Discussionmentioning

confidence: 99%

Integrated multi-omics investigations reveal the key role of synergistic microbial networks in removing plasticizer di-(2-ethylhexyl) phthalate from estuarine sediments

Wei

Chen

et al. 2021

Preprint

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Di-(2-ethylhexyl) phthalate (DEHP) is the most widely used plasticizer worldwide with an annual global production of over eight million tons. Because of its improper disposal, endocrine-disrupting DEHP often accumulates in estuarine sediments in industrialized countries at sub-millimolar levels, resulting in adverse effects on both ecosystems and human beings. The microbial degraders and biodegradation pathways of DEHP in O2-limited estuarine sediments remain elusive. Here, we employed an integrated meta-omics approach to identify the DEHP degradation pathway and major degraders in this ecosystem. Estuarine sediments were treated with DEHP or its derived metabolites, o-phthalic acid and benzoic acid. The rate of DEHP degradation in denitrifying mesocosms was two times slower than that of o-phthalic acid, suggesting that side-chain hydrolysis of DEHP is the rate-limiting step of anaerobic DEHP degradation. On the basis of microbial community structures, functional gene expression, and metabolite profile analysis, we proposed that DEHP biodegradation in estuarine sediments is mainly achieved through synergistic networks between denitrifying proteobacteria. Acidovorax and Sedimenticola are the major degraders of DEHP side-chains; the resulting o-phthalic acid is mainly degraded by Aestuariibacter through the UbiD-dependent benzoyl-CoA pathway. We isolated and characterized Acidovorax sp. strain 210-6 and its extracellular hydrolase, which hydrolyzes both alkyl side-chains of DEHP. Interestingly, genes encoding DEHP/MEHP hydrolase and phthaloyl-CoA decarboxylase—key enzymes for side-chain hydrolysis and o-phthalic acid degradation, respectively—are flanked by transposases in these proteobacterial genomes, indicating that DEHP degradation capacity is likely transferred horizontally in microbial communities.

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“…A TAXI transporter from Azoarcus sp. CIB has been shown to transport orthophthalate 38 , and phenotypic analysis of a TAXI gene knockout in Psychrobacter arcticus suggest it is involved in the uptake of butyrate, glutamate, fumarate, and acetate 39 . This limited number of examples hints that TAXIs can also transport a range of substrates akin to the DctP-type TRAPs.…”

Section: Introductionmentioning

confidence: 99%

Structure, substrate selectivity determinants and membrane interactions of a Glutamate-specific TAXI TRAP binding protein fromVibrio cholerae

Davies,

Daab,

Massouh

et al. 2024

Preprint

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Tripartite ATP independent periplasmic (TRAP) transporters are widespread in prokaryotes and are responsible for the transport of a variety of different ligands, primarily organic acids. TRAP transporters are secondary active transporters that employ a substrate binding protein to bind and present the substrate to membrane embedded translocation component. TRAP transporters can be divided into two subclasses; DctP-type and TAXI type, which share the same overall architecture and requirement of the SBP for transport, but their SBPs share no similarity. The DctP-type transporters are very well studied and have been shown to transport a range of compounds including dicarboxylates, keto acids, sugar acids. However, the TAXI type transporters are relatively poorly understood, with the range of transportable compounds still to be discovered and selectivity requirements for binding unknown. To address these shortfalls in our understanding, we have structurally and biochemically characterized VC0430 from Vibrio cholerae revealing it to be a monomeric high affinity glutamate binding protein. VC0430 is stereoselective, binding the L-isomer preferentially, and can also bind L-glutamine and L-pyroglutamate, but with low affinity relative to L-glutamate. Structural characterization of ligand bound VC0430 reveals details of the binding site and biophysical characterization of binding site mutant reveal the substrate binding determinants, which differ substantially from the DctP-type TRAPs. Finally, we have analysed in silico the interaction between VC0430 and its cognate membrane component revealing an architecture hitherto unseen. To our knowledge, this is the first transporter in V. cholerae to be identified as specific to glutamate, which plays a key role in osmoadaptation of V. cholerae, making this transporter a potential therapeutic target.

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Expanding the current knowledge and biotechnological applications of the oxygen‐independent ortho‐phthalate degradation pathway

Cited by 8 publications

References 85 publications

Integrated Multi-omics Investigations Reveal the Key Role of Synergistic Microbial Networks in Removing Plasticizer Di-(2-Ethylhexyl) Phthalate from Estuarine Sediments

Integrated Multi-omics Investigations Reveal the Key Role of Synergistic Microbial Networks in Removing Plasticizer Di-(2-Ethylhexyl) Phthalate from Estuarine Sediments

Integrated multi-omics investigations reveal the key role of synergistic microbial networks in removing plasticizer di-(2-ethylhexyl) phthalate from estuarine sediments

Structure, substrate selectivity determinants and membrane interactions of a Glutamate-specific TAXI TRAP binding protein fromVibrio cholerae

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