Characterization of Clostridium ljungdahlii OTA1: a non-autotrophic hyper ethanol-producing strain.

dc.contributor.author

Whitham, Jason M

dc.contributor.author

Schulte, Mark J

dc.contributor.author

Bobay, Benjamin G

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Bruno-Barcena, Jose M

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Chinn, Mari S

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Flickinger, Michael C

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Pawlak, Joel J

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Grunden, Amy M

dc.date.accessioned

2023-09-01T14:16:49Z

dc.date.available

2023-09-01T14:16:49Z

dc.date.issued

2017-02

dc.date.updated

2023-09-01T14:16:49Z

dc.description.abstract

A Clostridium ljungdahlii lab-isolated spontaneous-mutant strain, OTA1, has been shown to produce twice as much ethanol as the C. ljungdahlii ATCC 55383 strain when cultured in a mixotrophic medium containing fructose and syngas. Whole-genome sequencing identified four unique single nucleotide polymorphisms (SNPs) in the C. ljungdahlii OTA1 genome. Among these, two SNPs were found in the gene coding for AcsA and HemL, enzymes involved in acetyl-CoA formation from CO/CO2. Homology models of the respective mutated enzymes revealed alterations in the size and hydrogen bonding of the amino acids in their active sites. Failed attempts to grow OTA1 autotrophically suggested that one or both of these mutated genes prevented acetyl-CoA synthesis from CO/CO2, demonstrating that its activity was required for autotrophic growth by C. ljungdahlii. An inoperable Wood-Ljungdahl pathway resulted in higher CO2 and ethanol yields and lower biomass and acetate yields compared to WT for multiple growth conditions including heterotrophic and mixotrophic conditions. The two other SNPs identified in the C. ljungdahlii OTA1 genome were in genes coding for transcriptional regulators (CLJU_c09320 and CLJU_c18110) and were found to be responsible for deregulated expression of co-localized arginine catabolism and 2-deoxy-D-ribose catabolism genes. Growth medium supplementation experiments suggested that increased arginine metabolism and 2-deoxy-D-ribose were likely to have minor effects on biomass and fermentation product yields. In addition, in silico flux balance analysis simulating mixotrophic and heterotrophic conditions showed no change in flux to ethanol when flux through HemL was changed whereas limited flux through AcsA increased the ethanol flux for both simulations. In characterizing the effects of the SNPs identified in the C. ljungdahlii OTA1 genome, a non-autotrophic hyper ethanol-producing strain of C. ljungdahlii was identified that has utility for further physiology and strain performance studies and as a biocatalyst for industrial applications.

dc.identifier

10.1007/s00253-016-7978-6

dc.identifier.issn

0175-7598

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1432-0614

dc.identifier.uri

https://hdl.handle.net/10161/28907

dc.language

eng

dc.publisher

Springer Science and Business Media LLC

dc.relation.ispartof

Applied microbiology and biotechnology

dc.relation.isversionof

10.1007/s00253-016-7978-6

dc.subject

Clostridium

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Carbon Dioxide

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Carbon Monoxide

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Ethanol

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Multienzyme Complexes

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Acetyl Coenzyme A

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Aldehyde Oxidoreductases

dc.title

Characterization of Clostridium ljungdahlii OTA1: a non-autotrophic hyper ethanol-producing strain.

dc.type

Journal article

duke.contributor.orcid

Bobay, Benjamin G|0000-0003-4775-3686

pubs.begin-page

1615

pubs.end-page

1630

pubs.issue

4

pubs.organisational-group

Duke

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School of Medicine

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Clinical Science Departments

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Radiology

pubs.publication-status

Published

pubs.volume

101

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