α,ω-Dicarboxylic acid accumulation by acyl-CoA oxidase deficient mutants of <Emphasis Type="Italic">Yarrowia lipolytica</Emphasis>

α,ω-Dicarboxylic acid accumulation from alkanes and alkane degradation intermediates was investigated using Yarrowia lipolytica wild type strain W29 as well as a double, a triple and a quadruple POX-deleted strains. Six genes, POX1 through POX6, encode six acyl-CoA oxidase isozymes in Y. lipolytica. All the strains accumulated dodecanedioic acid (5–20 mg ml⁻¹) from the diterminal functionalised 1,12-dodecane diol and 12-hydroxdodecanoic acid. The quadruple-deleted strain was the only strain that was able to accumulate dioic acids from C16 alkanol and monocarboxylic acid as well as from C12, C14 and C16 alkanes (maximum 8 mg ml⁻¹ from dodecane).     

Comparison of promoters suitable for regulated overexpression of β-galactosidase in the alkane-utilizing yeastYarrowia lipolytica

Promoters of the genesG3P, ICL1, POT1, POX1, POX2 andPOX5 of the yeastY. lipolytica were studied in respect to their regulations and activities during growth on different carbon sources. The aim of this study was to select suitable promoters for high expression of heterologous genes in this yeast. For this purpose the promoters were fused with the reporter genelacZ ofE. coli and integrated as single copies into the genome ofY. lipolytica strain PO1d. The measurement of expressed activities of β-galactosidase revealed thatpICL1, pPOX2 andpPOT1 are the strongest regulable promoters available forY. lipolytica, at present.pPOX2 andpPOT4 were highly induced during growth on oleic acid and were completely repressed by glucose and glycerol.pICL1 was strongly inducible by ethanol besides alkanes and fatty acids, however, not completely repressible by glucose or glycerol. Ricinoleic acid methyl ester appeared as a very strong inducer forpPOT1 andpPOX2, in spite of that it inhibited growth ofY. lipolytica transformants.     

Cloning of theHIS3 gene ofYarrowia lipolytica

TheHIS3 gene of the yeastYarrowia lipolytica has been cloned from a genomic library by complementation of thehis3 mutation ofSaccharomyces cerevisiae. The gene was subsequently subcloned inEscherichia coli and characterized by restriction enzyme mapping.     

Role of β-Oxidation Enzymes in γ-Decalactone Production by the Yeast Yarrowia lipolytica

Some microorganisms can transform methyl ricinoleate into γ-decalactone, a valuable aroma compound, but yields of the bioconversion are low due to (i) incomplete conversion of ricinoleate (C₁₈) to the C₁₀ precursor of γ-decalactone, (ii) accumulation of other lactones (3-hydroxy-γ-decalactone and 2- and 3-decen-4-olide), and (iii) γ-decalactone reconsumption. We evaluated acyl coenzyme A (acyl-CoA) oxidase activity (encoded by the POX1 through POX5 genes) in Yarrowia lipolytica in lactone accumulation and γ-decalactone reconsumption in POX mutants. Mutants with no acyl-CoA oxidase activity could not reconsume γ-decalactone, and mutants with a disruption of pox3, which encodes the short-chain acyl-CoA oxidase, reconsumed it more slowly. 3-Hydroxy-γ-decalactone accumulation during transformation of methyl ricinoleate suggests that, in wild-type strains, β-oxidation is controlled by 3-hydroxyacyl-CoA dehydrogenase. In mutants with low acyl-CoA oxidase activity, however, the acyl-CoA oxidase controls the β-oxidation flux. We also identified mutant strains that produced 26 times more γ-decalactone than the wild-type parents.     

Lipid Accumulation, Lipid Body Formation, and Acyl Coenzyme A Oxidases of the Yeast Yarrowia lipolytica

Yarrowia lipolytica contains five acyl-coenzyme A oxidases (Aox), encoded by the POX1 to POX5 genes, that catalyze the limiting step of peroxisomal β-oxidation. In this study, we analyzed morphological changes of Y. lipolytica growing in an oleic acid medium and the effect of POX deletions on lipid accumulation. Protrusions involved in the uptake of lipid droplets (LDs) from the medium were seen in electron micrographs of the surfaces of wild-type cells grown on oleic acid. The number of protrusions and surface-bound LDs increased during growth, but the sizes of the LDs decreased. The sizes of intracellular lipid bodies (LBs) and their composition depended on the POX genotype. Only a few, small, intracellular LBs were observed in the mutant expressing only Aox4p (Δpox2 Δpox3 Δpox5), but strains expressing either Aox3p or both Aox3p and Aox4p had the same number of LBs as did the wild type. In contrast, strains expressing either Aox2p or both Aox2p and Aox4p formed fewer, but larger, LBs than did the wild type. The size of the LBs increased proportionately with the amount of triacylglycerols in the LBs of the mutants. In summary, Aox2p expression regulates the size of cellular triacylglycerol pools and the size and number of LBs in which these fatty acids accumulate.     

Engineering polyhydroxyalkanoate content and monomer composition in the oleaginous yeast <Emphasis Type="Italic">Yarrowia lipolytica</Emphasis> by modifying the ß-oxidation multifunctional protein

Recombinant strains of the oleaginous yeast Yarrowia lipolytica expressing the PHA synthase gene (PhaC) from Pseudomonas aeruginosa in the peroxisome were found able to produce polyhydroxyalkanoates (PHA). PHA production yield, but not the monomer composition, was dependent on POX genotype (POX genes encoding acyl-CoA oxidases) (Haddouche et al. FEMS Yeast Res 10:917–927, 2010). In this study of variants of the Y. lipolytica β-oxidation multifunctional enzyme, with deletions or inactivations of the R-3-hydroxyacyl-CoA dehydrogenase domain, we were able to produce hetero-polymers (functional MFE enzyme) or homo-polymers (with no 3-hydroxyacyl-CoA dehydrogenase activity) of PHA consisting principally of 3-hydroxyacid monomers (>80%) of the same length as the external fatty acid used for growth. The redirection of fatty acid flux towards β-oxidation, by deletion of the neutral lipid synthesis pathway (mutant strain Q4 devoid of the acyltransferases encoded by the LRO1, DGA1, DGA2 and ARE1 genes), in combination with variant expressing only the enoyl-CoA hydratase 2 domain, led to a significant increase in PHA levels, to 7.3% of cell dry weight. Finally, the presence of shorter monomers (up to 20% of the monomers) in a mutant strain lacking the peroxisomal 3-hydroxyacyl-CoA dehydrogenase domain provided evidence for the occurrence of partial mitochondrial β-oxidation in Y. lipolytica.     

Control of Lipid Accumulation in the Yeast Yarrowia lipolytica

A genomic comparison of Yarrowia lipolytica and Saccharomyces cerevisiae indicates that the metabolism of Y. lipolytica is oriented toward the glycerol pathway. To redirect carbon flux toward lipid synthesis, the GUT2 gene, which codes for the glycerol-3-phosphate dehydrogenase isomer, was deleted in Y. lipolytica in this study. This Δgut2 mutant strain demonstrated a threefold increase in lipid accumulation compared to the wild-type strain. However, mobilization of lipid reserves occurred after the exit from the exponential phase due to β-oxidation. Y. lipolytica contains six acyl-coenzyme A oxidases (Aox), encoded by the POX1 to POX6 genes, that catalyze the limiting step of peroxisomal β-oxidation. Additional deletion of the POX1 to POX6 genes in the Δgut2 strain led to a fourfold increase in lipid content. The lipid composition of all of the strains tested demonstrated high proportions of FFA. The size and number of the lipid bodies in these strains were shown to be dependent on the lipid composition and accumulation ratio.     

Effect of <Emphasis Type="Italic">POX3</Emphasis> gene disruption using self-cloning <Emphasis Type="Italic">CRF1</Emphasis> cassette in <Emphasis Type="Italic">Yarrowia lipolytica</Emphasis> on the γ-decalactone production

γ-Decalactone, an important flavor compound, can be produced by Yarrowia lipolytica, but the yield is poor because of lactone degradation by enzyme Aox3 (POX3 gene encoded). A yeast strain Yarrowia lipolytica TA1 of high γ-decalactone yield was constructed by integrating copper-resistance gene CRF1 from Yarrowia lipolytica into the locus of POX3 genes. After being cultured in shake-flask at 28°C for 90 h, TA1 reached a γ-decalactone yield of 0.531 g/l (highest at 63 h), being 2.9 times higher than that of Yarrowia lipolytica As2.1045 (0.194 g/l, highest at 57 h). It was free of heterologous DNA sequences and drug-resistance genes and could be safely used in γ-decalactone production. And this work may throw a new light on addressing the problems in commercial fragrance manufacture.     

Accumulation of Uridinediphospho-N-acetylmuramyl-peptides Induced by Glycine and Penicillin

The genes POX2 and POX4, which encode the subunits (PXP-2 and PXP-4) of peroxisomal fatty acyl-coenzyme A oxidase of Candida tropicalis, were introduced into the related yeast Candida maltosa. The cells transformed with POX2 or POX4 gave much PXP-2 or PXP-4 in the purified peroxisomes. The polypeptides associated with the heterologous organelle were resistant to added protease, implying that they were transported into the peroxisomes. Genes for curtailed versions of PXP-4 were constructed in vitro and introduced into the host cells. Peptide-C, the COOH-terminal two-thirds of PXP-4, was efficiently transported into the host peroxisomes, and the polypeptide containing the NH₂-terminal one-third was also, in much lesser amount. These and other results suggested that there were at least two regions of peroxisomal targeting information in PXP-4 and the primary information was internal. The deletions in Peptide-C inhibited the transport of many, but not all, of the host-cell peroxisomal polypeptides. This suggested heterogeneous transport systems on the peroxisomal membrane.     

Cloning,Characterization, and Expression of the Gene Encoding Alkaline Protease in the Marine Yeast <Emphasis Type="Italic">Aureobasidium pullulans</Emphasis> 10

The alkaline protease structural gene (ALP1 gene) was isolated from both the genomic DNA and cDNA of Aureobasidium pullulans 10 by inverse PCR and RT-PCR. An open reading frame of 1248 bp encoding a 415 amino-acid protein with calculated molecular weight of 42.9 kDa was characterized. The gene contained two introns, which had 54 bp and 50 bp, respectively. The promoter of ALP1 gene was located from -62 to -112 and had two CCAAT boxes and one TATA box. The terminator of ALP1gene contained the sequence with a hairpin structure (AAAAAGTT TGGTTTTT). The protein sequence deduced from ALP1 gene exhibited 55.24%, 50.35%, and 31.68% identity with alkaline proteases from Aspergillus fumigatus, Acremonium chrysogenum, and Yarrowia lipolytica, respectively. The protein was found to have the conserved serine active site and histidine active site of serine proteases in the subtilisin family. The recombinant A. pullulans alkaline protease produced in Y. lipolytica formed clear zones on the double plates with 2% casein and alkaline protease activity in the supernatant of the recombinant Y. lipolytica culture was detected, suggesting that the cloned ALP1 gene is expressed in Y. lipolytica and the expressed alkaline protease is secreted into the medium.     

Genetic and cell biological aspects of the yeast vacuolar H+-ATPase

The yeast vacuolar proton-translocating ATPase is a member of the third class of H⁺-pumping ATPase. A family of this type of H⁺-ATPase is now known to be ubiquitously distributed in eukaryotic vacuo-lysosomal organelles and archaebacteria. NineVMA genes that are indispensable for expression of the enzyme activity have been cloned and characterized in the yeastSaccharomyces cerevisiae. This review summarizes currently available information on theVMA genes and cell biological functions of theVMA gene products.     

AgTHR4, a new selection marker for transformation of the filamentous fungusAshbya gossypii, maps in a four-gene cluster that is conserved betweenA. gossypii andSaccharomyces cerevisiae

Single-read sequence analysis of the termini of eight randomly picked clones ofAshbya gossypii genomic DNA revealed seven sequences with homology toSaccharomyces cerevisiae genes (15% to 69% on the amino acid level). One of these sequences appeared to code for the carboxy-terminus of threonine synthase, the product of theS. cerevisiae THR4 gene (52.4% identity over 82 amino acids). We cloned and sequenced the complete putativeAgTHR4 gene ofA. gossypii. It comprises 512 codons, two less than theS. cerevisiae THR4 gene. Overall identity at the amino acid sequence level is 67.4%. A continuous stretch of 32 amino acids displaying complete identity between these two fungal threonine synthases presumably contains the pyridoxal phosphate attachment site. Disruption of theA. gossypii gene led to threonine auxotrophy, which could be complemented by transformation with replicating plasmids carrying theAgTHR4 gene and variousS. cerevisiae ARS elements. Using these plasmids only very weak complementation of aS. cerevisiae thr4 mutation was observed. Investigation of sequences adjacent to theAgTHR4 gene identified three additional ORFs. Surprisingly, the order and orientation of these four ORFs is conserved inA. gossypii andS. cerevisiae.     

Dominant mutations affecting expression of pH-regulated genes inYarrowia lipolytica

In the yeastYarrowia lipolytica the levels of the alkaline extracellular protease (AEP) and acid extracellular protease (AXP) are controlled by the pH of the growth medium. When the pH of growth medium is kept close to 4.0, levels of AXP are high and those of AEP are low, whereas at pH above 6.0 the opposite is true. Mutations which mimic the effects on the protease system of growth at alkaline pH have been identified in two genes,RPH1 andRPH2, inY. lipolytica. Detailed genetic studies showed that mutations in these two genes are dominant in heterozygous diploids, and that their effects are additive in haploid double mutants. These mutants show that pH regulates AEP expression independently from other metabolic signals. These mutants are not detectably affected in their growth rates, nor in internal pH homeostasis.     

Secretion of active urokinase-type plasminogen activator from the yeast<Emphasis Type="Italic">Yarrowia lipolytica</Emphasis>

In order to study the secretion of the human urokinase-type plasminogen activator, u-PA, from the yeastYarrowia lipolytica, three kinds of integrative expression vector were constructed. These vectors differed only in their secretion control regions, pre-, pre-dip- (dipeptide stretch) or pre-dip-pro sequences of the alkaline extracellular protease, which were joined inframe to the human u-PA cDNA. The recombinantY. lipolytica strains, transformed with the expression vectors, secreted the hyperglycosylated u-PA. A fibrin plate assay of the culture supernatants showed that the hyperglycosylated u-PA proteins could catalyze fibrinolysis, and that the pre-dip sequence was the most efficient secretory signal for the secretion of the u-PA fromY. lipolytica. This result suggests thatY. lipolytica can be developed as a potential host for the production of recombinant human u-PA.     

A multicopy suppressor ofnin1-1 of the yeastSaccharomyces cerevisiae is a counterpart of theDrosophila melanogaster diphenol oxidase A2 gene,Dox-A2

NIN1 is an essential gene for growth of the yeastSaccharomyces cerevisiae and was recently found to encode a component of the regulatory subunit of the 26S proteasome. Thenin1-1 mutant is temperature sensitive and its main defect is in G₁/S progression and G₂/M progression at non-permissive temperatures. One of the two multicopy suppressors ofnin1-1, SUN2 (SUppressor of Nin1-1), was found to encode a protein of 523 amino acids whose sequence is similar to those ofDrosophila melanogaster diphenol oxidase A2 and the mouse mast-cell Tum^– transplantation antigen, P91A. The C-terminal half of Sun2p was found to be functional as Sun2p at 25° C, 30° C, and 34° C but not at 37° C. The open reading frame (ORF) of theDrosophila diphenol oxidase A2 gene (Dox-A2) was obtained from a lambda phage cDNA library using the polymerase chain reaction technique. TheDox-A2 ORF driven by theTDH3 promoter complemented the phenotype of a strain deleted forsun2. ThisDox-A2-dependent strain was temperature sensitive and accumulated dumb-bell-shaped cells, with an undivided nucleus at the isthmus, after temperature upshift. This morphology is similar to that ofnin1-1 cells kept at a restrictive temperature. These results suggest thatSUN2 is a functional counterpart ofDox-A2 and that these genes play a pivotal role in the cell cycle in each organism.     

Osmoregulation in the model organismEscherichia coli: genes governing the synthesis of glycine betaine and trehalose and their use in metabolic engineering of stress tolerance

Glycine betaine is known to be the preferred osmoprotectant in many bacteria, and glycine betaine accumulation has also been correlated with increased cold tolerance. Trehalose is often a minor osmoprotectant in bacteria and it is a major determinant for desiccation tolerance in many so-called anhydrobiotic organisms such as baker's yeast(Saccharomyces cerevisiae). Escherichia coli has two pathways for synthesis of these protective molecules; i.e., a two-step conversion of UDP-glucose and glucose-6-phosphate to trehalose and a two-step oxidation of externally-supplied choline to glycine betaine. The genes governing the choline-to-glycine betaine pathway have been studied inE. coli and several other bacteria and higher plants. The genes governing UDP-glucose-dependent trehalose synthesis have been studied inE. coli andS. cerevisiae. Because of their well-documented function in stress protection, glycine betaine and trehalose have been identified as targets for metabolic engineering of stress tolerance. Examples of this experimental approach include the expression of theE. coli betA andArthrobacter globiformis codA genes for glycine betaine synthesis in plants and distantly related bacteria, and the expression of theE. coli otsA and yeastTPS1 genes for trehalose synthesis in plants. The published data show that glycine betaine synthesis protects transgenic plants and phototrophic bacteria against stress caused by salt and cold. Trehalose synthesis has been reported to confer increased drought tolerance in transgenic plants, but it causes negative side effects which is of concern. Thus, the much-used model organismE. coli has now become a gene resource for metabolic engineering of stress tolerance.