Production of Optically Pure
            <scp>d</scp>
            -Lactic Acid in Mineral Salts Medium by Metabolically Engineered
            <i>Escherichia coli</i>
            W3110

Zhou, Shengde; Causey, Thomas B.; Hasona, Adnan; Shanmugam, K. T.; Ingram, L. O.

doi:10.1128/aem.69.1.399-407.2003

Cited by 206 publications

(154 citation statements)

References 41 publications

Supporting

Mentioning

150

Contrasting

Unclassified

Order By: Relevance

“…1). Previous reports indicate that E. coli with a ppc knockout does not grow on glucose as the sole carbon source (1,17,22,24,33). In our present study, ALS961 (YYC202 ppc) similarly did not grow aerobically in shake flasks with GAM medium.…”

Section: Production Of Lactatesupporting

confidence: 44%

“…PEP carboxylase is the primary anaplerotic pathway in E. coli, and as expected, a ppc mutation prevents growth on glucose minimal medium (1,18,22,24,33). Although PEP carboxykinase (encoded by the pckA gene) and malic enzymes (encoded by maeB and sfcA) also catalyze reversible C-3 carboxylation/ C-4 decarboxylation reactions, these two pathways appear to be responsible for decarboxylation in E. coli rather than for carboxylation (22).…”

Section: Vol 73 2007mentioning

confidence: 99%

“…The second strategy examined for prevention of succinate accumulation was a knockout of frdABCD (3,33). In E. coli, two distinct enzymes catalyze succinate oxidation and fumarate reduction (4): succinate-ubiquinone oxidoreductase functions aerobically as part of the TCA cycle, and menaquinol-fumarate oxidoreductase (QFR) is mainly used for anaerobic respiration and succinate production.…”

Section: Vol 73 2007mentioning

confidence: 99%

“…Similarly, the ldhA mutant of JP203 containing pLS65 encoding Lactobacillus casei L-LDH was grown aerobically to 7.2 g/liter DCW and generated 45 g/liter L-lactate, with a 0.7 g/g yield and a productivity of 0.67 g/liter · h after an anaerobic switch (6). A pflB frdBC adhE ackA mutant (SZ63) grown in minimal media generated 48 g/liter D-lactate of 99% optical purity, close to the theoretical maximum yield of 1.0 g/g (33). After part of the chromosomal ldhA coding region was replaced with Pediococcus acidilactici ldhL, encoding L-LDH, the new strain (SZ85) generated 50 g/liter L-lactate at a 95% yield, with a productivity of 0.42 g/liter · h (34).…”

mentioning

confidence: 99%

See 3 more Smart Citations

Homolactate Fermentation by Metabolically Engineered Escherichia coli Strains

Zhu

Eiteman

DeWitt

et al. 2007

Appl Environ Microbiol

View full text Add to dashboard Cite

We report the homofermentative production of lactate in Escherichia coli strains containing mutations in the aceEF, pfl, poxB, and pps genes, which encode the pyruvate dehydrogenase complex, pyruvate formate lyase, pyruvate oxidase, and phosphoenolpyruvate synthase, respectively. The process uses a defined medium and two distinct fermentation phases: aerobic growth to an optical density of about 30, followed by nongrowth, anaerobic production. Strain YYC202 (aceEF pfl poxB pps) generated 90 g/liter lactate in 16 h during the anaerobic phase (with a yield of 0.95 g/g and a productivity of 5.6 g/liter · h). Ca(OH) 2 was found to be superior to NaOH for pH control, and interestingly, significant succinate also accumulated (over 7 g/liter) despite the use of N 2 for maintaining anaerobic conditions. Strain ALS961 (YYC202 ppc) prevented succinate accumulation, but growth was very poor. Strain ALS974 (YYC202 frdABCD) reduced succinate formation by 70% to less than 3 g/liter. 13 C nuclear magnetic resonance analysis using uniformly labeled acetate demonstrated that succinate formation by ALS974 was biochemically derived from acetate in the medium. The absence of uniformly labeled succinate, however, demonstrated that glyoxylate did not reenter the tricarboxylic acid cycle via oxaloacetate. By minimizing the residual acetate at the time that the production phase commenced, the process with ALS974 achieved 138 g/liter lactate (1.55 M, 97% of the carbon products), with a yield of 0.99 g/g and a productivity of 6.3 g/liter · h during the anaerobic phase.Lactic acid (lactate) and its derivatives have a wide range of applications in the food, pharmaceutical, leather, and textile industries (13,27). Recently, polylactic acid has been developed as a renewable, biodegradable, and environmentally friendly polymer (16,28). An advantage of a biological process over a chemical process for the production of lactate is the prospect of generating optically pure lactate (2, 26, 28), which is an important characteristic for many of its end uses (2, 10, 26).Although several microorganisms can produce lactate by fermentation of glucose and other renewable resources (13), Escherichia coli has many advantages, including rapid growth and simple nutritional requirements. Moreover, the ease of genetic manipulation of E. coli makes possible metabolic engineering strategies for improving lactate accumulation in E. coli (6). Several E. coli strains have been studied for lactate production. For example, a pfl ldhA mutant (FBR11) containing a plasmid with the ldh gene from Streptococcus bovis (Llactate dehydrogenase [L-LDH]) produced L-lactic acid anaerobically on complex media (11). Using glucose, a concentration of 73 g/liter was obtained with a yield of 0.93 g/g and a productivity of 2.3 g/liter · h. A small amount of succinate was also generated (0.9 to 2.2 g/liter). A pta ppc mutant (JP203) first grown aerobically in complex media to 10 g/liter dry cell weight (DCW) generated 62 g/liter of D-lactate under subsequent anaerobic conditions, with ...

show abstract

Section: Production Of Lactatesupporting

confidence: 44%

Section: Vol 73 2007mentioning

confidence: 99%

Section: Vol 73 2007mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Homolactate Fermentation by Metabolically Engineered Escherichia coli Strains

Zhu

Eiteman

DeWitt

et al. 2007

Appl Environ Microbiol

View full text Add to dashboard Cite

show abstract

“…E. coli also metabolizes pentose sugars through the pentose phosphate pathway, which feeds intermediates into the EMP pathway towards homolactate production, in contrast to the use of phosphoketolase by lactic acid bacteria, which leads to production of a mixture of lactic acid and acetic acid during pentose fermentation. Because E. coli ferments all the sugars present in plant biomass in a simple salt-based medium, this organism has been engineered for production of optically pure lactic acid by deleting competing pathways (Chang et al, 1999;Dien et al, 2001;Zhou et al, 2003aZhou et al, ,b, 2005. E. coli produces only the D-())-LDH enzyme, and the resulting product is 100% D-()) lactic acid (Zhou et al, 2003a).…”

Section: Lactococcus Lactis and Lactococcus Casei As Well Asmentioning

confidence: 99%

Microbial conversion of sugars from plant biomass to lactic acid or ethanol

2008

View full text Add to dashboard Cite

SummaryConcerns for our environment and unease with our dependence on foreign oil have renewed interest in converting plant biomass into fuels and 'green' chemicals. The volume of plant matter available makes lignocellulose conversion desirable, although no single isolated organism has been shown to depolymerize lignocellulose and efficiently metabolize the resulting sugars into a specific product. This work reviews selected chemicals and fuels that can be produced from microbial fermentation of plant-derived cell-wall sugars and directed engineering for improvement of microbial biocatalysts. Lactic acid and ethanol production are highlighted, with a focus on engineered Escherichia coli.

show abstract

Microbial Primary Metabolites: Biosynthesis and Perspectives

Sánchez

Demain

2009

Encyclopedia of Industrial Biotechnology

View full text Add to dashboard Cite

The microbial production of primary metabolites contributes significantly to the quality of life. Fermentative production of these compounds is still an important goal of modern biotechnology. Through fermentation, microorganisms growing on inexpensive carbon and nitrogen sources produce valuable products such as amino acids, nucleotides, organic acids, and vitamins, which can be added to food to enhance its flavor, or increase its nutritive values. The contribution of microorganisms goes well beyond the food and health industries with the renewed interest in solvent fermentations. Microorganisms have the potential to provide many petroleum‐derived products as well as the ethanol necessary for liquid fuel. Additional applications of primary metabolites lie in their impact as precursors of many pharmaceutical compounds. The roles of primary metabolites and the microbes which produce them will certainly increase in importance as time goes on. Overproduction of microbial metabolites is related to developmental phases of microorganisms. Inducers, effectors, inhibitors, and various signal molecules play a role in different types of overproduction. Biosynthesis of enzymes catalyzing metabolic reactions in microbial cells is controlled by well‐known positive and negative mechanisms, for example, induction, nutritional regulation (carbon or nitrogen source regulation), and feedback regulation. In the early years of fermentation processes, development of producing strains initially depended on classical strain breeding involving repeated random mutations, each followed by screening or selection. More recently, methods of molecular genetics have been used for the overproduction of primary metabolic products. The development of modern tools of molecular biology enabled more rational approaches for strain improvement. Techniques of transcriptome, proteome, and metabolome analysis, as well as metabolic flux analysis, have recently been introduced in order to identify new and important target genes and to quantify metabolic activities necessary for further strain improvement.

show abstract

Production of Optically Pure d -Lactic Acid in Mineral Salts Medium by Metabolically Engineered Escherichia coli W3110

Cited by 206 publications

References 41 publications

Homolactate Fermentation by Metabolically Engineered Escherichia coli Strains

Homolactate Fermentation by Metabolically Engineered Escherichia coli Strains

Microbial conversion of sugars from plant biomass to lactic acid or ethanol

Microbial Primary Metabolites: Biosynthesis and Perspectives

Contact Info

Product

Resources

About