Efficient Homolactic Fermentation by
            <i>Kluyveromyces lactis</i>
            Strains Defective in Pyruvate Utilization and Transformed with the Heterologous
            <i>LDH</i>
            Gene

Bianchi, Michele M.; Brambilla, Luca; Protani, Francesca; Liu, Chi-Li; Lievense, Jeff; Porro, Danilo

doi:10.1128/aem.67.12.5621-5625.2001

Cited by 80 publications

(51 citation statements)

References 18 publications

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“…Bianchi et al used K. lactis strains lacking either PDC activity or PDC and PDH activities, transformed with the LDH gene placed under the control of the promoter of KlPDC1 gene and cloned into stable multicopy vector. Transgenic K. lactis strains showed remarkable improvement under the fed-batch condition (3).…”

mentioning

confidence: 99%

Efficient Production ofl-Lactic Acid by Metabolically EngineeredSaccharomyces cerevisiaewith a Genome-Integratedl-Lactate Dehydrogenase Gene

Ishida

Saitoh

Tokuhiro

et al. 2005

Appl Environ Microbiol

116

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We developed a metabolically engineered yeast which produces lactic acid efficiently. In this recombinant strain, the coding region for pyruvate decarboxylase 1 (PDC1) on chromosome XII is substituted for that of the L-lactate dehydrogenase gene (LDH) through homologous recombination. The expression of mRNA for the genome-integrated LDH is regulated under the control of the native PDC1 promoter, while PDC1 is completely disrupted. Using this method, we constructed a diploid yeast transformant, with each haploid genome having a single insertion of bovine LDH. Yeast cells expressing LDH were observed to convert glucose to both lactate (55.6 g/liter) and ethanol (16.9 g/liter), with up to 62.2% of the glucose being transformed into lactic acid under neutralizing conditions. This transgenic strain, which expresses bovine LDH under the control of the PDC1 promoter, also showed high lactic acid production (50.2 g/liter) under nonneutralizing conditions. The differences in lactic acid production were compared among four different recombinants expressing a heterologous LDH gene (i.e., either the bovine LDH gene or the Bifidobacterium longum LDH gene): two transgenic strains with 2m plasmid-based vectors and two genome-integrated strains.

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mentioning

confidence: 99%

Efficient Production ofl-Lactic Acid by Metabolically EngineeredSaccharomyces cerevisiaewith a Genome-Integratedl-Lactate Dehydrogenase Gene

Ishida

Saitoh

Tokuhiro

et al. 2005

Appl Environ Microbiol

116

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“…16) Additional inactivation of PDH activity was required to increase the yield of L-lactic acid in K. lactis, 9) although this was accompanied by a significant growth defect, which is not considered desirable, particularly in fermentation processes. In C. utilis, however, inactivation of PDC activity alone was sufficient to obtain high yields of L-lactic acid, the yield being 95.1% (103.3 g/l; >99:9% e.e.)…”

Section: Discussionmentioning

confidence: 99%

“…This relatively high optimal temperature is also advantageous because lactic acid at high concentrations easily becomes solidified in the medium due to low solubility. Usually, fermentation of S. cerevisiae and K. lactis is limited at lower temperatures from 30 to 32 C. [5][6][7][9][10][11][12][13][14] The pH value of the medium also appeared to be important for the production of L-lactic acid, since a previous study showed that adjustment of pH was effective for the high expression of PDC in C. utilis.…”

Section: Discussionmentioning

confidence: 99%

“…4) Decreasing PDC activity has been found to boost the production of L-lactic acid in Saccharomyces cerevisiae [4][5][6][7][8] and Kluyveromyces lactis. 9,10) In the case of S. cerevisiae, which is known as a Crabtree-positive yeast, and which has three PDC genes (ScPDC1, ScPDC5, and ScPDC6), reduction/inactivation of PDC activity causes a severe growth defect. Increasing the copy number of L-LDH and the use of EMS-generated mutants in which the growth defect is suppressed has resulted in better strain performance.…”

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confidence: 99%

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Genetic Engineering ofCandida utilisYeast for Efficient Production ofL-Lactic Acid

Ikushima¹,

Fujii²,

Kobayashi³

et al. 2009

Bioscience, Biotechnology, and Biochemistry

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Polylactic acid is receiving increasing attention as a renewable alternative for conventional petroleum-based plastics. In the present study, we constructed a metabolically-engineered Candida utilis strain that produces L-lactic acid with the highest efficiency yet reported in yeasts. Initially, the gene encoding pyruvate decarboxylase (CuPDC1) was identified, followed by four CuPDC1 disruption events in order to obtain a null mutant that produced little ethanol (a by-product of L-lactic acid). Two copies of the L-lactate dehydrogenase (L-LDH) gene derived from Bos taurus under the control of the CuPDC1 promoter were then integrated into the genome of the CuPdc1-null deletant. The resulting strain produced 103.3 g/l of L-lactic acid from 108.7 g/l of glucose in 33 h, representing a 95.1% conversion. The maximum production rate of L-lactic acid was 4.9 g/l/h. The optical purity of the L-lactic acid was found to be more than 99.9% e.e.

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“…This is more critical as we attempt to replace petroleum-based plastics with renewable PLA-based plastics, which would require production of the base chemical in large quantities and lignocellulosic biomass as the feedstock for fermentation. Biocatalysts currently being developed to reduce the cost of production of optically pure isomers of lactic acid include Kluyveromyces (Bianchi et al, 2001;Porro et al, 1999), Saccharomyces (van Maris et al, 2004;Saitoh et al, 2005), Pichia (Ilmen et al, 2007), Rhizopus (Skory, 2000) and Lactobacillus (Liu et al, 2007); however, Escherichia coli stands out as an excellent microbial biocatalyst for this purpose (Dien et al, 2001;Grabar et al, 2006). E. coli is a well studied bacterium that uses glycolysis via the Embden-Meyerhoff-Parnas (EMP) pathway to convert hexose sugars into a mixture of acids (lactic, acetic, formic and succinic) and ethanol (Clark, 1989).…”

Section: Lactococcus Lactis and Lactococcus Casei As Well Asmentioning

confidence: 99%

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

2008

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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.

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Efficient Homolactic Fermentation by Kluyveromyces lactis Strains Defective in Pyruvate Utilization and Transformed with the Heterologous LDH Gene

Cited by 80 publications

References 18 publications

Efficient Production ofl-Lactic Acid by Metabolically EngineeredSaccharomyces cerevisiaewith a Genome-Integratedl-Lactate Dehydrogenase Gene

Efficient Production ofl-Lactic Acid by Metabolically EngineeredSaccharomyces cerevisiaewith a Genome-Integratedl-Lactate Dehydrogenase Gene

Genetic Engineering ofCandida utilisYeast for Efficient Production ofL-Lactic Acid

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

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