Optimization of Yarrowia lipolytica’s β-oxidation pathway for γ-decalactone production

Waché, Yves; Aguedo, Mário; LeDall, M.-T.; Nicaud, Jean‐Marc; Belin, Jean‐Marc

doi:10.1016/s1381-1177(02)00185-6

Cited by 48 publications

(36 citation statements)

References 13 publications

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“…3) is very comparable showing without doubt the capacity of this strain to degrade ␥-decalactone contrasting with the results obtained with the previous pox3 pox4 pox5 construction [14]. A possible explanation for these different results is that the previous construction grew very slowly whereas the new one grows at a rate similar to that of the wild type.…”

Section: Lactone Production By the Various Strainsmentioning

confidence: 59%

“…The deletion of pox5 decreased activity on the complete chain-length spectrum whereas the deletion of pox4 exhibited no significant effect. To confirm the activity or inactivity of these enzymes, a construction was made involving the deletion of several acyl-CoA oxidase encoding genes ( pox2 pox3 pox5) and a multicopy insertion of POX2, the long-chain specific encoding gene [14] but, as the efficiency of the multicopy insertion was low, the constructed strain exhibited an altered growth resulting in a low production and no degradation of ␥-decalactone but whether the absence of detectable degradation was due to a lack of short-chain active acyl-CoA oxidases or to a rate of degradation lower than the rate of production was not determined. As the growth rate of mutant strains is very important for industrial application and as this parameter is linked to the number of deletion of genes coding for lipid-degradation-enzymes, it is of fundamental interest to establish the role of each of these enzymes.…”

Section: Introductionmentioning

confidence: 99%

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Genetic engineering of the β-oxidation pathway in the yeast Yarrowia lipolytica to increase the production of aroma compounds

Groguenin¹

2004

Journal of Molecular Catalysis B: Enzymatic

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The yeast Yarrowia lipolytica possesses five acyl-CoA oxidases (Aox1p to 5), the enzyme catalysing the first reaction of ␤-oxidation. The understanding of the specific role of each acyl-CoA oxidase is important to construct a yeast strain growing at a good rate and able to produce without degrading the aroma compound ␥-decalactone. In this study we observed that Aox4p exhibits a slight activity on a broad spectrum of substrates and that it is involved in lactone degradation. We constructed a strain lacking this activity. Its growth was only slightly altered and it produced 10 times more lactone than the wild type in 48 h.

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Section: Lactone Production By the Various Strainsmentioning

confidence: 59%

Section: Introductionmentioning

confidence: 99%

Genetic engineering of the β-oxidation pathway in the yeast Yarrowia lipolytica to increase the production of aroma compounds

Groguenin¹

2004

Journal of Molecular Catalysis B: Enzymatic

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“…By disrupting the corresponding genes (pox4, pox5), one takes the risk of constructing a strain which is not very active, as the only active Aox remaining would be Aox2. We therefore constructed a strain disrupted for pox2, pox3 and pox5 (which still possesses POX4, encoding a weakly active Aox) and with POX2 reincorporated in multicopies (WachØ et al 2002). The metabolism of this strain was slow, but no lactone degradation was observed.…”

Section: Optimising the Biotransformationmentioning

confidence: 99%

Catabolism of hydroxyacids and biotechnological production of lactones by Yarrowia lipolytica

Waché¹,

Aguedo²,

Nicaud

et al. 2003

Appl Microbiol Biotechnol

114

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The g-and d-lactones of less than 12 carbons constitute a group of compounds of great interest to the flavour industry. It is possible to produce some of these lactones through biotechnology. For instance, g-decalactone can be obtained by biotransformation of methyl ricinoleate. Among the organisms used for this bioproduction, Yarrowia lipolytica is a yeast of choice. It is well adapted to growth on hydrophobic substrates, thanks to its efficient and numerous lipases, cytochrome P450, acylCoA oxidases and its ability to produce biosurfactants. Furthermore, genetic tools have been developed for its study. This review deals with the production of lactones by Y. lipolytica with special emphasis on the biotransformation of methyl ricinoleate to g-decalactone. When appropriate, information from the lipid metabolism of other yeast species is presented.

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“…[283] Yarrowia lipolytica with genetically engineered genes of the b-oxidation genes is able to reach 10 g/l g-decalactone production from ricinoleic acid esters. [285][286][287][288][289] Volatile dicarboxylic acids can accumulate at amounts up to 80 g/l, when various yeasts having genetically interrupted b-oxidation and amplified w-hydroxylation were fed with fatty acids and alkanes.…”

Section: Genetically Engineered Microorganismsmentioning

confidence: 99%

“…Deleted acyl-CoA oxidases, selective for short chain fatty acids 10-Fold increase in g-decalactone production from fatty acids [287,288,289] Various yeasts (Candida, Saccharomyces, Schizosachcaromyces, Pichia, Yarrowia,…”

Section: Mucuna Pruriensmentioning

confidence: 99%

Biotechnology for the production of essential oils, flavours and volatile isolates. A review.

Gounaris

2010

Flavour & Fragrance J

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Various applications of biotechnological methods for the production of volatile compounds useful to the food and pharmaceutical industries are discussed. The yields obtained from intact or genetically modified plants are compared to those achieved by microbial methods. Plant yields are too low for the products to compete commercially to those synthesized chemically. Still lower yields are obtained with in vitro-cultured plant tissues. Trangenic plants with altered methylerythritol path gave 50% more essential oil in the best case. The 100-fold increases in shikimate-derived volatiles, obtained with overexpressed alcohol dehydrogenase and five-fold more C6 volatle aldehydes and 2-phenylethanol, were produced with overexpressed lipoxygenase and 2-phenylethanol dehydrogenase, respectively. However, the most spectacular yields were observed with biotransformations catalysed by microorganisms. Kluyveromyces marxianus, produces over 26 g/l 2-phenylethanol from phenyalanine, whereas Candida sorbophila, Mucor circillenoides or Yarrowia lipolytica can produce 5-40 g/l g-decalactone from ricinoleic acid. Vanillin production from ferulic acid is in the range 12-60 g/l with Amycolatopsis and Streptomyces species. Vanillin can be produced at 5 g/l by Escherichia coli and amorphadiene yields of 37 g/l have been observed with Saccharomyces cerevisiae, both with the genetically overexpressed methyl-erythritol path. Genetically engineered b-oxidation genes result in yields of 10 g/l g-decalactone byYarrowia lipolytica and up to 80 g/l dicaboxylic acids by various yeasts. These results far exceed the theoretical limit of about 1 g/l required for consideration of a procedure as a commercially interesting process, alternative to chemical sythesis.

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Optimization of Yarrowia lipolytica’s β-oxidation pathway for γ-decalactone production

Cited by 48 publications

References 13 publications

Genetic engineering of the β-oxidation pathway in the yeast Yarrowia lipolytica to increase the production of aroma compounds

Genetic engineering of the β-oxidation pathway in the yeast Yarrowia lipolytica to increase the production of aroma compounds

Catabolism of hydroxyacids and biotechnological production of lactones by Yarrowia lipolytica

Biotechnology for the production of essential oils, flavours and volatile isolates. A review.

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