Reductive Enzyme Cascades for Valorization of PET Deconstruction Products

Gopal, Madan R.; Dickey, Roman M.; Butler, Neil D.; Talley, Michael R.; Mohapatra, Ashlesha; Watson, Mary P.; Chen, Wilfred; Kunjapur, Aditya M.

doi:10.1101/2022.12.16.520786

Cited by 7 publications

(17 citation statements)

References 71 publications

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“…Infinity with a Zorbax Eclipse Plus-C18 column with a guard column installed. The methods for detection of TPAL, 4HMB, 4HMBA, BDM, and pXYL used were described in Gopal et al 14 3 | RESULTS…”

Section: Hplc Analysismentioning

confidence: 99%

“…12,13 We recently identified carboxylic acid reductase enzymes that can efficiently generate the versatile dialdehyde terephthalaldehyde (TPAL) from TPA. 14 Our first step was to report the use of these enzymes in vitro, in part because it is unclear if these steps would function well in live cells given the potential instability and reactivity of TPAL. 15 However, the use of live cells to convert TPAL to useful chemical building blocks could provide a more cost effective and efficient biosynthetic process compared with the use of purified enzymes.…”

Section: Introductionmentioning

confidence: 99%

“…Here, we envision utilizing the dialdehyde functionality of TPAL to access potential new opportunities in biosynthetic pathways, including asymmetrically functionalized products. Aldehyde-derived biosynthetic targets have ranged broadly, 19 including diamine polymer building blocks, 14,20 hydroxylated non-standard amino acids, [21][22][23][24][25] nitro alcohols, 26 and pharmaceutical mono-amine precursors. [27][28][29] Despite the biosynthetic possibilities available from aldehydes, their redox instability in cellular environments due to endogenous oxidoreductase activity remains a key challenge.…”

Section: Introductionmentioning

confidence: 99%

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Genome engineering allows selective conversions of terephthalaldehyde to multiple valorized products in bacterial cells

Dickey,

Jones,

Butler

et al. 2023

AIChE Journal

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Deconstruction of polyethylene terephthalate (PET) plastic waste generates opportunities for valorization to alternative products. We recently designed an enzymatic cascade that could produce terephthalaldehyde (TPAL) from terephthalic acid. Here, we showed that the addition of TPAL to growing cultures of Escherichia coli wild‐type strain MG1655 and an engineered strain for reduced aromatic aldehyde reduction (RARE) strain resulted in substantial reduction. We then investigated if we could mitigate this reduction using multiplex automatable genome engineering (MAGE) to create an E. coli strain with 10 additional knockouts in RARE. Encouragingly, we found this newly engineered strain enabled a 2.5‐fold higher retention of TPAL over RARE after 24 h. We applied this new strain for the production of para‐xylylenediamine (pXYL) and observed a 6.8‐fold increase in pXYL titer compared with RARE. Overall, our study demonstrates the potential of TPAL as a versatile intermediate in microbial biosynthesis of chemicals that derived from waste PET.

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Section: Hplc Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Genome engineering allows selective conversions of terephthalaldehyde to multiple valorized products in bacterial cells

Dickey,

Jones,

Butler

et al. 2023

AIChE Journal

View full text Add to dashboard Cite

show abstract

“…Aliphatic aldehydes generated from fermentation or fatty acid synthesis have been used to produce fuels and commodities based on alcohols (Akhtar et al, 2013; Sheppard et al, 2014) or alkanes (Kallio et al, 2014; Sheppard et al, 2016). Exemplary newer aldehyde-derived biosynthetic targets that have applications in the pharmaceutical and materials industries are tetrahydroisoquinoline alkaloid plant natural products (Pyne et al, 2020), primary or heterocyclic mono-amine precursors to small molecule pharmaceuticals (Citoler et al, 2019; France et al, 2016; Hepworth et al, 2017), diamine polymer building blocks (Fedorchuk et al, 2020; Gopal et al, 2022), hydroxylated non-standard amino acids (Doyon et al, 2022; Ellis et al, 2022; Kumar et al, 2021; Xu et al, 2020, 2019), and β-lactone antibiotics (Schaffer et al, 2017; Scott et al, 2017). Additionally, opportunities to blend biological and abiological synthesis methods to access additional chemical functional groups are emerging, such as the recent chemoenzymatic synthesis of nitriles (Horvat et al, 2022; Winkler et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Combinatorial gene inactivation of aldehyde dehydrogenases mitigates aldehyde oxidation catalyzed by resting cells ofE. coliRARE strains

Butler

Anderson

Dickey

et al. 2023

Preprint

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Aldehydes are attractive chemical targets given applications as end products in the flavors and fragrances industry and as intermediates due to their propensity for C-C bond formation. While biosynthetic routes to diverse aldehydes have been designed, a common challenge is the stability of these aldehydes in the presence of microbial hosts of engineered pathways. Here, we identify and address unexpected oxidation of a model collection of aromatic aldehydes, including many that originate from biomass degradation, in the presence ofEscherichia colistrains that were engineered to minimize aldehyde reduction. Of heightened interest to us were resting cell conditions as they offer numerous advantages for the bioconversion of toxic metabolites. Surprisingly, when diverse aldehydes are supplemented toE. coliRARE cells grown under aerobic conditions, they remain stabilized on the timescale of days, whereas when these same aldehydes are supplemented to resting cell preparations ofE. coliRARE that had been grown under the same conditions, we observe substantial oxidation. By performing combinatorial inactivation of six candidate aldehyde dehydrogenase genes in theE. coligenome using multiplexed automatable genome engineering (MAGE), we demonstrate that this oxidation can be substantially slowed, with greater than 50% retention of 6 out of 8 aldehydes when assayed 4 hours after their addition. Given that our newly engineered strain exhibits Reduced Oxidation And Reduction of aromatic aldehydes, we dubbed it theE. coliROAR strain. Seeking to apply this new strain to resting cell biocatalysis, we compared the capability to synthesize the aldehyde furfural from 2-furoic acid via the carboxylic acid reductase enzyme from Nocardia iowensis. Here, we found that use of ROAR resting cells achieved 2-fold enhancement in furfural titer after 4 h and nearly 9-fold enhancement after 20 h as compared to resting cells of the RARE strain. Moving forward, the use of this strain to generate resting cells should allow aldehyde product isolation, further enzymatic conversion, or chemical reactivity under cellular contexts that better accommodate aldehyde toxicity.

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“…The ωTAs are pyridoxal 5’-phosphate (PLP)-dependent enzymes that have previously been applied to reversibly catalyze amination by transferring an amine group from an amine donor to the substrate aldehyde or ketone through a pyridoxamine 5’-phosphate (PMP) intermediate (Höhne and Bornscheuer, 2009; Ngo et al, 2022; Rocha et al, 2019). Recently, we reported bioprospecting of diverse CAR enzymes and their coupling to the well-known ω-TA from Chromobacter violaceum (cvTA) to build a one-pot cascade for highly selective and efficient conversion of deconstruction product from polyethylene terephthalate (PET) to mono-and diamines (Gopal et al, 2023).…”

Section: Introductionmentioning

confidence: 99%

Reductive amination cascades in cell-free and resting whole cell formats for valorization of lignin deconstruction products

Nain,

Dickey,

Somasundaram

et al. 2023

Preprint

Self Cite

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The selective introduction of amine groups within deconstruction products of lignin could provide an avenue for valorizing waste biomass while achieving a green synthesis of industrially relevant building blocks from sustainable sources. Here, we built and characterized enzyme cascades that create aldehydes and subsequently primary amines from diverse lignin-derived carboxylic acids using a carboxylic acid reductase (CAR) and an ω-transaminase (TA). We report a detailed characterization of two reaction formats - cell-free biocatalysis and resting whole-cell biocatalysis - using the conversion of vanillate to vanillyl amine as model chemistry. We showed that resting whole-cell reactions could be competitive with cell-free reactions (97% and 70% yields, respectively) while avoiding steps of cell lysis, purification, and cofactor supplementation. We also demonstrated the recyclability of resting whole cells for multiple batches of catalysis without significant loss in productivity. Finally, we used the knowledge gained from this study to produce several amines from carboxylic acid precursors using one-pot biocatalytic reactions. These results expand our knowledge of these industrially relevant enzyme families to new substrates and contexts for environmentally friendly and potentially low-cost synthesis of diverse aryl aldehydes and amines.

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Reductive Enzyme Cascades for Valorization of PET Deconstruction Products

Cited by 7 publications

References 71 publications

Genome engineering allows selective conversions of terephthalaldehyde to multiple valorized products in bacterial cells

Genome engineering allows selective conversions of terephthalaldehyde to multiple valorized products in bacterial cells

Combinatorial gene inactivation of aldehyde dehydrogenases mitigates aldehyde oxidation catalyzed by resting cells ofE. coliRARE strains

Reductive amination cascades in cell-free and resting whole cell formats for valorization of lignin deconstruction products

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