Transcriptomic characterization of recombinant Clostridium beijerinckii NCIMB 8052 expressing methylglyoxal synthase and glyoxal reductase from Clostridium pasteurianum ATCC 6013

Transcriptomic characterization of recombinant Clostridium beijerinckii NCIMB 8052 expressing methylglyoxal synthase and glyoxal reductase from Clostridium pasteurianum ATCC 6013

Bioconversion of abundant lactose-replete whey permeate to value-added chemicals holds promise for valorization of this expanding food processing waste. Efficient conversion of whey permeate-borne lactose requires adroit microbial engineering to direct carbon to the desired chemical. An engineered s...

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Published in:Applied and environmental microbiology Vol. 90; no. 10; p. e0101224
Main Authors: Kumar, Santosh, Agyeman-Duah, Eric, Awaga-Cromwell, Marian M, Ujor, Victor C
Format: Journal Article
Language:English
Published: United States 23-10-2024
Subjects:
Bacterial Proteins - genetics
Bacterial Proteins - metabolism
Butanols - metabolism
Clostridium - enzymology
Clostridium - genetics
Clostridium - metabolism
Clostridium beijerinckii - enzymology
Clostridium beijerinckii - genetics
Clostridium beijerinckii - metabolism
Lactose - metabolism
Metabolic Engineering
Transcriptome
Whey - metabolism
methylglyoxal
cysteine desaturase
signal transduction
NAD biosynthesis
butanol production
iron uptake
transcriptomic analysis
Clostridium beijerinckii
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Summary:Bioconversion of abundant lactose-replete whey permeate to value-added chemicals holds promise for valorization of this expanding food processing waste. Efficient conversion of whey permeate-borne lactose requires adroit microbial engineering to direct carbon to the desired chemical. An engineered strain of NCIMB 8052 ( _mgsA+mgR) that produces 87% more butanol on lactose than the control strain was assessed for global transcriptomic changes. The results revealed broadly contrasting gene expression patterns in _mgsA+mgR relative to the control strain. These were characterized by widespread decreases in the abundance of mRNAs of Fe-S proteins in _mgsA+mgR, coupled with increased differential expression of lactose uptake and catabolic genes, iron uptake genes, two-component signal transduction and motility genes, and genes involved in the biosynthesis of vitamins B and B , aromatic amino acids (particularly tryptophan), arginine, and pyrimidines. Conversely, the mRNA patterns suggest that the L-aspartate-dependent biosynthesis of NAD as well as biosynthesis of lysine and asparagine and metabolism of glycine and threonine were likely down-regulated. Furthermore, genes involved in cysteine and methionine biosynthesis and metabolism, including cysteine desulfurase-a central player in Fe-S cluster biosynthesis-equally showed reductions in mRNA abundance. Genes involved in biosynthesis of capsular polysaccharides and stress response also showed reduced mRNA abundance in _mgsA+mgR. The results suggest that remodeling of cellular and metabolic networks in _mgsA+mgR to counter anticipated effects of methylglyoxal production from heterologous expression of methylglyoxal synthase led to enhanced growth and butanol production in _mgsA+mgR. Biological production of commodity chemicals from abundant waste streams such as whey permeate represents an opportunity for decarbonizing chemical production. Whey permeate remains a vastly underutilized feedstock for bioproduction purposes. Thus, enhanced understanding of the cellular and metabolic repertoires of lactose-mediated production of chemicals such as butanol promises to identify new targets that can be fine tuned in recombinant and native microbial strains to engender stronger coupling of whey permeate-borne lactose to value-added chemicals. Our results highlight new genetic targets for future engineering of for improved butanol production on lactose and ultimately in whey permeate.
ISSN:1098-5336
DOI:10.1128/aem.01012-24