Structure of the plastic-degrading Ideonella sakaiensis MHETase bound to a substrate

Palm, Gottfried J.; Reisky, Lukas; Böttcher, Dominique; Müller, Henrik; Michels, Emil A. P.; Walczak, Miriam C.; Berndt, L.; Weiss, M.S.; Bornscheuer, Uwe T.; Weber, Gert

doi:10.1038/s41467-019-09326-3

Cited by 299 publications

(286 citation statements)

References 39 publications

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“…Although in our crystal structure W159H formed hydrogen bonding with the backbone oxygen atom of H237, molecular dynamics (MD) simulations has revealed a new hydrogen bonding formed between W159H and Ser160, whereas the original catalytic residue His237 may flip "up" out of the catalytic triad to play an aromatic stabilization role with PET ( Figure 5A). The reconstruction of the catalytic triad in the active site was also suggested by Austin et al 15 . For I168R and S188Q mutations, in addition to the new salt-bridge interaction formed between I168R and D186, the guanidine group is also suggested to donate new hydrogen bonds to the amide oxygen and backbone oxygen atoms of S188Q in the MD simulations for 10.36% of the trajectory to stabilize the enzyme structure.…”

Section: Underlying Mechanism Of the Improved Properties Of Durapetasementioning

confidence: 53%

“…Not content with the finite repertoire of naturally occurring enzymes, numerous research groups have concerned on the engineering of IsPETase, which has been summarized by Taniguchi recently 14 . Recently crystal structures of PET degrading enzymes allow for expedients that exploit rational design to improve the PET degradation activity [15][16][17][18][19][20][21] . The successful single point mutations afford 1.2 to 3.1 folds higher affinity to PET [18][19][20][21][22] , and very recently, Kim's group has succeeded in creating IsPETase S121E/D186H/R280A variant with enhanced thermal stability by 8.81 °C and 14-fold higher PET degradation activity at 40 °C 12 .…”

Section: Introductionmentioning

confidence: 99%

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Computational redesign of a PETase for plastic biodegradation by the GRAPE strategy

Chen

Liu

et al. 2019

Preprint

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The excessive use of plastics has been accompanied by severe ecologically damaging effects. The recent discovery of a PETase from Ideonella sakaiensis that decomposes poly(ethylene terephthalate) (PET) under mild conditions provides an attractive avenue for the biodegradation of plastics. However, the inherent instability of the enzyme limits its practical 20 15 and the Biological Resources Program (KFJ-BRP-009) of the Chinese Academy of Sciences.

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Section: Underlying Mechanism Of the Improved Properties Of Durapetasementioning

confidence: 53%

Section: Introductionmentioning

confidence: 99%

Computational redesign of a PETase for plastic biodegradation by the GRAPE strategy

Chen

Liu

et al. 2019

Preprint

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“…In 2016 the bacterium Ideonella sakaiensis was reported to degrade amorphous PET when cultured in the presence of yeast extract as an additional carbon source 15 . The molecular basis of the ester-bond hydrolyzing PETase and mono- (2-hydroxyethyl)TA (MHET)ase enzymes of this strain was reported in several publications (e.g., 16,17 ).…”

Section: Graphical Abstract 1 Introductionmentioning

confidence: 75%

Bio-upcycling of polyethylene terephthalate

Tiso¹,

Narancic²,

Wei³

et al. 2020

Preprint

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Over 359 million tons of plastics were produced worldwide in 2018, with significant growth expected in the near future, resulting in the global challenge of end-of-life management. The recent identification of enzymes that degrade plastics previously considered non-biodegradable opens up opportunities to steer the plastic recycling industry into the realm of biotechnology.Here, we present the sequential conversion of polyethylene terephthalate (PET) into two types of bioplastics: a medium chain-length polyhydroxyalkanoate (PHA) and a novel bio-based poly(amide urethane) (bio-PU). PET films were hydrolyzed by a thermostable polyester hydrolase yielding 100% terephthalate and ethylene glycol. A terephthalate-degradingPseudomonas was evolved to also metabolize ethylene glycol and subsequently produced PHA.The strain was further modified to secrete hydroxyalkanoyloxy-alkanoates (HAAs), which were used as monomers for the chemo-catalytic synthesis of bio-PU. In short, we present a novel value-chain for PET upcycling, adding technological flexibility to the global challenge of endof-life management of plastics.

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“…Structures lacking the α/β‐hydrolase fold were discarded, and the remaining centroid sequences were reclustered by USEARCH with an identity threshold of 60% to reduce the number of queries for later BLAST searches. In addition, the sequences of three recently identified structures of MHETases, which also belong to the family of α/β‐hydrolases, were added to the centroids . Each centroid served as a seed sequence of a homologous family and was assigned to a superfamily , which was named by its respective architecture.…”

Section: Methodsmentioning

confidence: 99%

The modular structure of α/β‐hydrolases

2019

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The α/β‐hydrolase fold family is highly diverse in sequence, structure and biochemical function. To investigate the sequence–structure–function relationships, the Lipase Engineering Database (https://led.biocatnet.de) was updated. Overall, 280 638 protein sequences and 1557 protein structures were analysed. All α/β‐hydrolases consist of the catalytically active core domain, but they might also contain additional structural modules, resulting in 12 different architectures: core domain only, additional lids at three different positions, three different caps, additional N‐ or C‐terminal domains and combinations of N‐ and C‐terminal domains with caps and lids respectively. In addition, the α/β‐hydrolases were distinguished by their oxyanion hole signature (GX‐, GGGX‐ and Y‐types). The N‐terminal domains show two different folds, the Rossmann fold or the β‐propeller fold. The C‐terminal domains show a β‐sandwich fold. The N‐terminal β‐propeller domain and the C‐terminal β‐sandwich domain are structurally similar to carbohydrate‐binding proteins such as lectins. The classification was applied to the newly discovered polyethylene terephthalate (PET)‐degrading PETases and MHETases, which are core domain α/β‐hydrolases of the GX‐ and the GGGX‐type respectively. To investigate evolutionary relationships, sequence networks were analysed. The degree distribution followed a power law with a scaling exponent γ = 1.4, indicating a highly inhomogeneous network which consists of a few hubs and a large number of less connected sequences. The hub sequences have many functional neighbours and therefore are expected to be robust toward possible deleterious effects of mutations. The cluster size distribution followed a power law with an extrapolated scaling exponent τ = 2.6, which strongly supports the connectedness of the sequence space of α/β‐hydrolases. Database Supporting data about domains from other proteins with structural similarity to the N‐ or C‐terminal domains of α/β‐hydrolases are available in Data Repository of the University of Stuttgart (DaRUS) under doi: https://doi.org/10.18419/darus-458.

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Structure of the plastic-degrading Ideonella sakaiensis MHETase bound to a substrate

Cited by 299 publications

References 39 publications

Computational redesign of a PETase for plastic biodegradation by the GRAPE strategy

Computational redesign of a PETase for plastic biodegradation by the GRAPE strategy

Bio-upcycling of polyethylene terephthalate

The modular structure of α/β‐hydrolases

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