Abstract
BackgroundCrude glycerol is the main byproduct of the biodiesel industry. Although it can have different applications, its purification is costly. Therefore, in this study a biotechnological route has been proposed for further utilization of crude glycerol in the fermentative production of lactic acid. This acid is largely utilized in food, pharmaceutical, textile, and chemical industries, making it the hydroxycarboxylic acid with the highest market potential worldwide. Currently, industrial production of lactic acid is done mainly using sugar as the substrate. Thus here, for the first time, Pichia pastoris has been engineered for heterologous l-lactic acid production using glycerol as a single carbon source. For that, the Bos taurus lactate dehydrogenase gene was introduced into P. pastoris. Moreover, a heterologous and a novel homologous lactate transporter have been evaluated for l-lactic acid production.ResultsBatch fermentation of the P. pastoris X-33 strain producing LDHb allowed for lactic acid production in this yeast. Although P. pastoris is known for its respiratory metabolism, batch fermentations were performed with different oxygenation levels, indicating that lower oxygen availability increased lactic acid production by 20 %, pushing the yeast towards a fermentative metabolism. Furthermore, a newly putative lactate transporter from P. pastoris named PAS has been identified by search similarity with the lactate transporter from Saccharomyces cerevisiae Jen1p. Both heterologous and homologous transporters, Jen1p and PAS, were evaluated in one strain already containing LDH activity. Fed-batch experiments of P. pastoris strains carrying the lactate transporter were performed with the batch phase at aerobic conditions followed by an aerobic oxygen-limited phase where production of lactic acid was favored. The results showed that the strain containing PAS presented the highest lactic acid titer, reaching a yield of approximately 0.7 g/g.ConclusionsWe showed that P. pastoris has a great potential as a fermentative organism for producing l-lactic acid using glycerol as the carbon source at limited oxygenation conditions (below 0.05 % DO in the bioreactor). The best strain had both the LDHb and the homologous lactate transporter encoding genes expressed, and reached a titer 1.5 times higher than the strain with the S. cerevisiae transporter. Finally, it was also shown that increased lactic acid production was concomitant to reduction of acetic acid formation by half.
Highlights
Crude glycerol is the main byproduct of the biodiesel industry
This study has shown for the first time that genetically engineered P. pastoris strains are able to produce L-lactic acid, making this organism a potential biocatalyst for the conversion of crude glycerol into products of biotechnological interest
Another novelty of this study is the identification of a putative lactate transporter in P. pastoris
Summary
Crude glycerol is the main byproduct of the biodiesel industry. it can have different applications, its purification is costly. In this study a biotechnological route has been proposed for further utilization of crude glycerol in the fermentative production of lactic acid. For the first time, Pichia pastoris has been engineered for heterologous l-lactic acid production using glycerol as a single carbon source. With the aim of developing strains that will further be able to use crude glycerol as a carbon source, glycerol was used in this study as the substrate for genetically engineered Pichia pastoris strains to produce lactic acid. Recent studies have reported metabolically-engineered microorganisms such as Escherichia coli [5, 6], Rhyzopus oryzae [7] and Enterococcus faecalis [8] for improving lactic acid (2-hydroxyproponoic acid) production using glycerol as a single carbon source. Yeasts are generally robust and resistant microorganisms which can survive in industrial conditions, and are easy to use in scale-up bioprocesses [9]
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