Your search keyword '"Morgan A. Ingraham"' showing total 4 results

1. Feedstock variability impacts the bioconversion of sugar and lignin streams derived from corn stover by Clostridium tyrobutyricum and engineered Pseudomonas putida

Author

Ilona A. Ruhl, Robert S. Nelson, Rui Katahira, Jacob S. Kruger, Xiaowen Chen, Stefan J. Haugen, Morgan A. Ingraham, Sean P. Woodworth, Hannah Alt, Kelsey J. Ramirez, Darren J. Peterson, Ling Ding, Philip D. Laible, Jeffrey G. Linger, and Davinia Salvachúa

Subjects

Biotechnology, TP248.13-248.65

Abstract

Abstract Feedstock variability represents a challenge in lignocellulosic biorefineries, as it can influence both lignocellulose deconstruction and microbial conversion processes for biofuels and biochemicals production. The impact of feedstock variability on microbial performance remains underexplored, and predictive tools for microbial behaviour are needed to mitigate risks in biorefinery scale‐up. Here, twelve batches of corn stover were deconstructed via deacetylation, mechanical refining, and enzymatic hydrolysis to generate lignin‐rich and sugar streams. These batches and their derived streams were characterised to identify their chemical components, and the streams were used as substrates for producing muconate and butyrate by engineered Pseudomonas putida and wildtype Clostridium tyrobutyricum, respectively. Bacterial performance (growth, product titers, yields, and productivities) differed among the batches, but no strong correlations were identified between feedstock composition and performance. To provide metabolic insights into the origin of these differences, we evaluated the effect of twenty‐three isolated chemical components on these microbes, including three components in relevant bioprocess settings in bioreactors, and we found that growth‐inhibitory concentrations were outside the ranges observed in the streams. Overall, this study generates a foundational dataset on P. putida and C. tyrobutyricum performance to enable future predictive models and underscores their resilience in effectively converting fluctuating lignocellulose‐derived streams into bioproducts.

Published

2024

2. Natural diversity screening, assay development, and characterization of nylon-6 enzymatic depolymerization

Author

Elizabeth L. Bell, Gloria Rosetto, Morgan A. Ingraham, Kelsey J. Ramirez, Clarissa Lincoln, Ryan W. Clarke, Japheth E. Gado, Jacob L. Lilly, Katarzyna H. Kucharzyk, Erika Erickson, and Gregg T. Beckham

Subjects

Science

Abstract

Abstract Successes in biocatalytic polyester recycling have raised the possibility of deconstructing alternative polymers enzymatically, with polyamide (PA) being a logical target due to the array of amide-cleaving enzymes present in nature. Here, we screen 40 potential natural and engineered nylon-hydrolyzing enzymes (nylonases), using mass spectrometry to quantify eight compounds resulting from enzymatic nylon-6 (PA6) hydrolysis. Comparative time-course reactions incubated at 40-70 °C showcase enzyme-dependent variations in product distributions and extent of PA6 film depolymerization, with significant nylon deconstruction activity appearing rare. The most active nylonase, a NylCK variant we rationally thermostabilized (an N-terminal nucleophile (Ntn) hydrolase, NylCK-TS, T m = 87.4 °C, 16.4 °C higher than the wild-type), hydrolyzes 0.67 wt% of a PA6 film. Reactions fail to restart after fresh enzyme addition, indicating that substrate-based limitations, such as restricted enzyme access to hydrolysable bonds, prohibit more extensive deconstruction. Overall, this study expands our understanding of nylonase activity distribution, indicates that Ntn hydrolases may have the greatest potential for further development, and identifies key targets for progressing PA6 enzymatic depolymerization, including improving enzyme activity, product selectivity, and enhancing polymer accessibility.

Published

2024

3. Catalytic carbon–carbon bond cleavage in lignin via manganese–zirconium-mediated autoxidation

Author

Chad T. Palumbo, Nina X. Gu, Alissa C. Bleem, Kevin P. Sullivan, Rui Katahira, Lisa M. Stanley, Jacob K. Kenny, Morgan A. Ingraham, Kelsey J. Ramirez, Stefan J. Haugen, Caroline R. Amendola, Shannon S. Stahl, and Gregg T. Beckham

Subjects

Science

Abstract

Abstract Efforts to produce aromatic monomers through catalytic lignin depolymerization have historically focused on aryl–ether bond cleavage. A large fraction of aromatic monomers in lignin, however, are linked by various carbon–carbon (C–C) bonds that are more challenging to cleave and limit the yields of aromatic monomers from lignin depolymerization. Here, we report a catalytic autoxidation method to cleave C–C bonds in lignin-derived dimers and oligomers from pine and poplar. The method uses manganese and zirconium salts as catalysts in acetic acid and produces aromatic carboxylic acids as primary products. The mixtures of the oxygenated monomers are efficiently converted to cis,cis-muconic acid in an engineered strain of Pseudomonas putida KT2440 that conducts aromatic O-demethylation reactions at the 4-position. This work demonstrates that autoxidation of lignin with Mn and Zr offers a catalytic strategy to increase the yield of valuable aromatic monomers from lignin.

Published

2024

4. Mixed plastics waste valorization through tandem chemical oxidation and biological funneling

Author

Kevin P. Sullivan, Allison Z. Werner, Kelsey J. Ramirez, Lucas D. Ellis, Jeremy R. Bussard, Brenna A. Black, David G. Brandner, Felicia Bratti, Bonnie L. Buss, Xueming Dong, Stefan J. Haugen, Morgan A. Ingraham, Mikhail O. Konev, William E. Michener, Joel Miscall, Isabel Pardo, Sean P. Woodworth, Adam M. Guss, Yuriy Román-Leshkov, Shannon S. Stahl, Gregg T. Beckham, Department of Energy (US), Advanced Manufacturing Office (US), Bioenergy Technologies Office (US), National Renewable Energy Laboratory (US), Sullivan, Kevin P. [0000-0003-3324-1145], Werner, Allison Z. [0000-0001-7147-2863], Ellis, Lucas D. [0000-0001-6026-1825, Black, Brenna A. [0000-0003-0035-7942], Brandner, David G. [0000-0003-4296-4855], Bratti, Felicia [0000-0003-2381-953X], Buss, Bonnie L. [0000-0001-7977-0670], Dong, Xueming [0000-0001-8726-7565], Haugen, Stefan J. [0000-0003-3999-0796], Ingraham, Morgan A. [0000-0002-7350-4862], Michener, William E. [0000-0001-6023-7286], Miscall, Joel [0000-0002-4513-8703], Pardo, Isabel [0000-0002-8568-1559], Guss, Adam M. [0000-0001-5823-5329], Román-Leshkov, Yuriy [0000-0002-0025-4233], Beckham, Gregg T. [0000-0002-3480-212X], Sullivan, Kevin P., Werner, Allison Z., Ellis, Lucas D., Black, Brenna A., Brandner, David G., Bratti, Felicia, Buss, Bonnie L., Dong, Xueming, Haugen, Stefan J., Ingraham, Morgan A., Michener, William E., Miscall, Joel, Pardo, Isabel, Guss, Adam M., Román-Leshkov, Yuriy, and Beckham, Gregg T.

Subjects

Soil, Multidisciplinary, Pseudomonas putida, Polyhydroxyalkanoates, Oxidation-Reduction, Plastics

Abstract

115 p.-4 fig.-45 fig. supl.-14 tab supl., Mixed plastics waste represents an abundant and largely untapped feedstock for the production of valuable products. The chemical diversity and complexity of thesematerials, however, present major barriers to realizing this opportunity. In this work, we show that metal-catalyzed autoxidation depolymerizes comingled polymers into a mixture of oxygenated small molecules that are advantaged substrates for biological conversion. We engineer a robust soil bacterium, Pseudomonas putida, to funnel these oxygenated compounds into a single exemplary chemical product, either b-ketoadipate or polyhydroxyalkanoates. This hybrid process establishes a strategy for the selective conversion of mixed plastics waste into useful chemical products., Funding was provided by the US Department of Energy, Office of Energy Efficiency and Renewable Energy, Advanced Manufacturing Office (AMO), and Bioenergy Technologies Office (BETO). This work was performed as part of the BOTTLE Consortium and was supported by AMO and BETO under contract no. DE-AC36- 08GO28308 with the National Renewable Energy Laboratory (NREL),operated by the Alliance for Sustainable Energy, LLC. The BOTTLE Consortium includes members from MIT, funded under contract no. DE-AC36-08GO28308 with NREL. Contributions by S.S.S. were supported by the US Department of Energy, Office of Basic Energy Sciences, under award no. DEFG02-05ER15690.

Published

2022