Retro-biosynthetic screening of a modular pathway design achieves selective route for microbial synthesis of 4-methyl-pentanol

Sheppard, Micah J.; Kunjapur, Aditya M.; Wenck, Spencer J.; Prather, Kristala L. J.

doi:10.1038/ncomms6031

Cited by 54 publications

(58 citation statements)

References 72 publications

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“…Although microbial FFAs have been produced for decades, recent work has demonstrated the potential for obtaining advanced fuels or valuable chemicals as derivatives of FFAs (50)(51)(52)(53). Based on the broad substrate range and known activities of carboxylic acid reductases, their addition to these pathways can result in production of C 4 to C 18 aliphatic aldehydes (25,26). Microbial synthesis of other valuable aldehyde classes, such as terpenoid aldehydes, could potentially occur in E. coli using variations of previously engineered terpenoid pathways (54).…”

Section: Engineering Aldehyde Biosynthetic Reactions and Pathwaysmentioning

confidence: 99%

“…Later publications from Rosazza and colleagues demonstrated that Car Ni requires one-time activation by a phosphopantetheinyl transferase and that Car Ni has activity in vitro on a broader range of substrates that includes several citric acid cycle dicarboxylic acids (23,24). Motivated by the activity of Car Ni on diverse carboxylic acid substrates, we investigated its activity on straight-chain and branched-chain aliphatic acids ranging from C 2 to C 8 (25). A homolog of Car Ni from Mycobacterium marinum was also demonstrated to have activity on straight-chain aliphatic acids ranging from C 6 to C 18 (26).…”

Section: Engineering Aldehyde Biosynthetic Reactions and Pathwaysmentioning

confidence: 99%

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Microbial Engineering for Aldehyde Synthesis

Kunjapur

Prather

2015

Appl Environ Microbiol

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143

129

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Aldehydes are a class of chemicals with many industrial uses. Several aldehydes are responsible for flavors and fragrances present in plants, but aldehydes are not known to accumulate in most natural microorganisms. In many cases, microbial production of aldehydes presents an attractive alternative to extraction from plants or chemical synthesis. During the past 2 decades, a variety of aldehyde biosynthetic enzymes have undergone detailed characterization. Although metabolic pathways that result in alcohol synthesis via aldehyde intermediates were long known, only recent investigations in model microbes such as Escherichia coli have succeeded in minimizing the rapid endogenous conversion of aldehydes into their corresponding alcohols. Such efforts have provided a foundation for microbial aldehyde synthesis and broader utilization of aldehydes as intermediates for other synthetically challenging biochemical classes. However, aldehyde toxicity imposes a practical limit on achievable aldehyde titers and remains an issue of academic and commercial interest. In this minireview, we summarize published efforts of microbial engineering for aldehyde synthesis, with an emphasis on de novo synthesis, engineered aldehyde accumulation in E. coli, and the challenge of aldehyde toxicity.

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Section: Engineering Aldehyde Biosynthetic Reactions and Pathwaysmentioning

confidence: 99%

Section: Engineering Aldehyde Biosynthetic Reactions and Pathwaysmentioning

confidence: 99%

Microbial Engineering for Aldehyde Synthesis

Kunjapur

Prather

2015

Appl Environ Microbiol

Self Cite

143

129

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“…[22,25] Withint he context of metabolic pathwayi ncorporation, scientists in the Prather group used the Duet systemf or the biosynthesis of (R)-and (S)-3-hydroxybutyrate, [26] butanol [27] and the non-natural alcohols pentanol [28] and 4-methyl-1-pentanol. [29] Thel ast compound is formed via at en-step de novo pathway with enzymest aken from nine different microorganisms.I n the cases of non-naturala lcohol production, enzymes are groupedi nm odules that allowed rational combination of different modules to elevate product titers.…”

Section: The Challenges Of Multiple Recombinant Protein Expressionmentioning

confidence: 99%

Designer Microorganisms for Optimized Redox Cascade Reactions – Challenges and Future Perspectives

et al. 2015

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“…Batch, 48 h Overexpression of LeuABCD pathway; Rational enzyme mutagenesis on leuA and kivD [28] E. coli 4-Methyl-pentanol 192 mg L À1 Batch, 48 h Retrosynthetic design for creation of de novo pathways [29] E. coli n-Pentanol 109 mg L À1 Batch, 48 h Retrosynthetic design for creation of >de novo pathways [30] Isoprenoids…”

Section: G L à1mentioning

confidence: 99%

“…Such an approach substantially increased the relative purity of products in E. coli strains harboring de novo pathways designed for 4-methyl-pentanol and n-pentanol. [29,30] …”

Section: Extended Linear-and Branched-chain Alcoholsmentioning

confidence: 99%

Metabolic Engineering for Advanced Biofuels Production and Recent Advances Toward Commercialization

Meadows

Kang

Lee

2017

Biotechnology Journal

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Research on renewable biofuels produced by microorganisms has enjoyed considerable advances in academic and industrial settings. As the renewable ethanol market approaches maturity, the demand is rising for the commercialization of more energy-dense fuel targets. Many strategies implemented in recent years have considerably increased the diversity and number of fuel targets that can be produced by microorganisms. Moreover, strain optimization for some of these fuel targets has ultimately led to their production at industrial scale. In this review, the recent metabolic engineering approaches for augmenting biofuel production derived from alcohols, isoprenoids, and fatty acids in several microorganisms are discussed. In addition, the successful commercialization ventures for each class of biofuel targets are discussed.

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Retro-biosynthetic screening of a modular pathway design achieves selective route for microbial synthesis of 4-methyl-pentanol

Cited by 54 publications

References 72 publications

Microbial Engineering for Aldehyde Synthesis

Microbial Engineering for Aldehyde Synthesis

Designer Microorganisms for Optimized Redox Cascade Reactions – Challenges and Future Perspectives

Metabolic Engineering for Advanced Biofuels Production and Recent Advances Toward Commercialization

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