Characterization of ω3 fatty acid desaturases from oomycetes and their application toward eicosapentaenoic acid production in Mortierella alpina.

ω3 Polyunsaturated fatty acids are currently obtained mainly from fisheries; thus, sustainable alternative sources such as oleaginous microorganisms are required. Here, we describe the isolation, characterization, and application of 3 novel ω3 desaturases with ω3 polyunsaturated fatty acid-producing activity at ordinary temperatures (28 °C). First, we selected Pythium sulcatum and Plectospira myriandra after screening for oomycetes with high eicosapentaenoic acid/arachidonic acid ratios and isolated the genes psulω3 and pmd17, respectively, which encode ω3 desaturases. Subsequent characterization showed that PSULω3 exhibited ω3 desaturase activity on both C18 and C20 ω6 polyunsaturated fatty acids while PMD17 exhibited ω3 desaturase activity exclusively on C20 ω6 polyunsaturated fatty acids. Expression of psulω3 and pmd17 in the arachidonic acid-producer Mortierella alpina resulted in transformants that produced eicosapentaenoic acid/total fatty acid values of 38% and 40%, respectively, at ordinary temperatures. These ω3 desaturases should facilitate the construction of sustainable ω3 polyunsaturated fatty acid sources.

Improving operational stability of thermostable Pythium myriotylum secretory serine protease by preparation of cross-linked enzyme aggregates (CLEAs).

Present study was undertaken to develop cross-linked enzyme aggregate (CLEA)of alkaline serine proteases (sp) from Pythium myriotylum (Pm), a necrotrophic oomycete reported to considerably secrete serine proteases. Among various precipitants screened for spPm1-CLEA preparation, ammonium sulfate at 80% saturation (w/v) yielded 100% activity recovery and retention of spherical morphology as observed by SEM analysis. Addition of glutaraldehyde as cross-linker at 1% (v/v) concentration with optimized ammonium sulfate concentration for 1 hour at 100 rpm yielded 100% activity recovery of spPm1-CLEA from 8-day old P. myriotylum culture filtrate. Addition of BSA (10 mg/ml) to CLEA cross-linking reaction mix reduced CLEA size from the range of 1.82-1.19 µm to 394-647 nm. spPm1-CLEA preparations retained 100% activity at temperature of 80 °C and pH 12.0 signifying their potential commercial applications. In terms of kinetic parameters, present process enhanced kinetic parameters as revealed by 1.67 U.mg-1 specific activity, Km of 0.062 mM and Vmax of 0.145 µmol.min-1.mg-1 for the spPm1-CLEA compared to 0.288 U.mg-1 specific activity, Km of 0.060 mM and Vmax of 0.20 µmol.min-1.mg-1 determined for the free spPm1 enzyme. Study has successfully demonstrated the concept of CLEA in enhancing spPm1 stability and the results so generated can be translated in future towards development of robust biocatalysts.

The glycoside hydrolase 18 family chitinases are associated with development and virulence in the mosquito pathogen Pythium guiyangense.

Chitinases, the enzymes responsible for the biological degradation of chitin, participate in numerous physiological processes such as nutrition, parasitism, morphogenesis and immunity in various organisms. However, the genome-wide distribution, evolution and biological functions of chitinases are rarely reported in oomycetes. This study systematically investigated the glycoside hydrolase 18 (GH18) family of chitinases from the mosquito pathogenic oomycete, Pythium guiyangense using bioinformatics and experimental assays. A total of 3 pairs of GH18 chitinase genes distributed in three distinct phylogenic clusters were identified from P. guiyangense genome, which is consistent with the ones in plant pathogenic oomycetes. Further transcriptional analysis revealed that Pgchi1/2 was highly expressed at the development stages, while Pgchi3/4 and Pgchi5/6 were up-regulated at the infection stages. The biological function analysis of chitinase genes using genetic transformation silencing method showed that silencing of Pgchi1/2 resulted in reduced zoospore production, without affecting the virulence. However, attenuation of Pgchi3/4 and Pgchi5/6 genes regulated not only oxidative stress responses, but also led to decreased infection rates to mosquito larvae. Taken together, this study provides a comprehensive overview of P. guiyangense chitinase family and reveals their diverse roles in the development, stress response, and virulence, which would elucidate insightful information on the molecular mechanism of chitinase in entomopathogenic pathogens.

Genome-wide and functional analyses of tyrosine kinase-like family genes reveal potential roles in development and virulence in mosquito pathogen Pythium guiyangense.

The tyrosine kinase-like (TKL) gene family is widely existed in most eukaryotes and participates in many biological processes, however, has been rarely studied in oomycetes. In this study we performed bioinformatic and experimental analyses to characterize TKLs in Pythium guiyangense, a promising mosquito biological control agent. Our results revealed that TKLs were widely distributed in all the detected oomycetes, but were largely expanded in P. guiyangense in a species-specific expansion manner. The expansion was mostly driven by whole-genome duplication and tandem duplication. Domain distributions and exon-intron structures were highly conserved in the same group while diverse in different groups, suggesting of functional divergence. Transcriptional analysis revealed that over one fourth of TKLs were differentially expressed after infection of mosquito larvae, implying that these genes might participate in the infection process. Furthermore, subgroup A TKLs were functionally investigated using genetic transformation silencing method. Our findings demonstrated that subgroup A TKLs were up-regulated at the early infection stages and silencing of subgroup A TKLs led to reduced mycelia growth, zoospore production and alteration of stress responses. Pathogenicity assays also revealed that silencing of subgroup A TKLs reduced P. guiyangense virulence to mosquito larvae. Taken together, this study provides a comprehensive overview of P. guiyangense TKL family and reveals their potential roles in growth, development, stress response, and especially virulence.

An AGC kinase, PgAGC1 regulates virulence in the entomopathogenic oomycete Pythium guiyangense.

Mosquitoes are the most important medical species by transmitting some of deadly infectious diseases to human. In recent years extensive studies of vector control have been focused on biological control agents due to the grave issue raised by continuous application of chemical compounds. Pythium guiyangense X.Q. Su was first isolated from infected larvae of Aedes albopictus in 2006 in China and it has been proven to be a promising mosquito control agent. However, the molecular mechanisms of this oomycete pathogenic to mosquitoes are still not clear. In this study, we identified a new gene from the genome of P. guiyangense, PgAGC1 that belongs to the AGC kinase group and we found that the transcriptional expression levels of this gene were significantly up-regulated during infection of mosquito Culex pipiens pallens. Disruption of the PgAGC1gene via genetic transformation methods affects colony growth and stress responses and results in reduced mortality and infection rates. All the evidence revealed that, besides its role in growth and stress resistance, PgAGC1 is putative determinants of P. guiyangense virulence. The results of this study become of particular importance in understanding the mechanisms of oomycete-mosquito interactions.

Differential diagnosis for pythiosis using thermophilic helicase DNA amplification and restriction fragment length polymorphism (tHDA-RFLP).

Pythiosis is caused by Pythium insidiosum, a fungus-like microbe belonging to the kingdom Stramenopila. Its diagnosis is challenging due to clinical and histopathological similarities with the fungal microbes that cause mucormycosis and entomophthoramycosis. In addition, the proper identification of P. insidiosum in the clinical laboratory is difficult. We have developed a rapid and accurate, species-specific identification method using a thermophilic helicase DNA amplification (tHDA) technique, to differentiate this pathogen from closely related pathogenic fungi. Sixty-seven fungal isolates, including 39 of P. insidiosum, were evaluated. A 91 base-pair (bp) DNA fragment was consistently amplified using a COX2 primer. The limiting concentrations of the one- and two-step tHDA protocols were 100 picograms (1.74 × 102 copies) and 100 femtograms (1.74 × 10-1 copies), respectively. The CviKI-1 enzyme in restriction fragment length polymorphism (RFLP) with the 91 bp amplicons accurately separated P. insidiosum from other fungal species. The data suggest that this tHDA-RFLP assay is a rapid and accurate test for the identification of P. insidiosum. The potential use of the assay directly in clinical samples is also discussed.

Microevolutionary analyses of Pythium insidiosum isolates of Brazil and Thailand based on exo-1,3-ß-glucanase gene.

Pythium insidiosum is an important oomycete due to its ability to infect humans and animals. It causes pythiosis, a disease of difficult treatment that occurs more frequently in humans in Thailand and in horses in Brazil. Since cell-wall components are frequently related to host shifts, we decided here to use sequences from the exo-1,3-ß-glucanase gene (exo1), which encodes an immunodominant protein putatively involved in cell wall remodeling, to investigate the microevolutionary relationships of Brazilian and Thai isolates of P. insidiosum. After neutrality ratification, the phylogenetic analyses performed through Maximum parsimony (MP), Neighbor-joining (NJ), Maximum likelihood (ML), and Bayesian analysis (BA) strongly supported Thai isolates being paraphyletic in relation to those from Brazil. The structure recovered by these analyses, as well as by Spatial Analysis of Molecular Variance (SAMOVA), suggests the subdivision of P. insidiosum into three clades or population groups, which are able to explain almost 81% of the variation encountered for exo1. Moreover, the two identified Thai clades were almost as strongly differentiated between each other, as they were from the Brazilian clade, suggesting an ancient Asian subdivision. The derived positioning in the phylogenetic tree, linked to the lower diversity values and the recent expansion signs detected for the Brazilian clade, further support this clade as derived in relation to the Asian populations. Thus, although some patterns presented here are compatible with those recovered with different molecular markers, exo1 was revealed to be a good marker for studying evolution in Pythium, providing robust and strongly supported results with regard to the patterns of origin and diversification of P. insidiosum.

The codon-optimized Δ(6)-desaturase gene of Pythium sp. as an empowering tool for engineering n3/n6 polyunsaturated fatty acid biosynthesis.

BACKGROUND: The ∆(6)-desaturase gene, encoding a key enzyme in the biosynthesis of polyunsaturated fatty acids, has potential in pharmaceutical and nutraceutical applications. RESULTS: The ∆(6)-desaturase gene has been isolated from a selected strain of Oomycetes, Pythium sp. BCC53698. The cloned gene (PyDes6) contained an open reading frame (ORF) of 1401 bp encoding 466 amino acid residues. The deduced amino acid sequence shared a high similarity to those of other ∆(6)-desaturases that contained the signature features of a membrane-bound ∆(6)-desaturase, including a cytochrome b 5 and three histidine-rich motifs and membrane-spanning regions. Heterologous expression in Saccharomyces cerevisiae showed that monoene, diene and triene fatty acids having ∆(9)-double bond were substrates for PyDes6. No distinct preference between the n-3 and n-6 polyunsaturated fatty acyl substrates was found. The ∆(6)-desaturated products were markedly increased by codon optimization of PyDes6. CONCLUSION: The codon-optimized ∆(6)-desaturase gene generated in this study is a promising tool for further reconstitution of the fatty acid profile, in a host system of choice, for the production of economically important fatty acids, particularly the n-3 and n-6 polyunsaturated fatty acids.

Detection of the oomycete Pythium insidiosum by real-time PCR targeting the gene coding for exo-1,3-ß-glucanase.

Pythiosis is a life-threatening infectious disease caused by Pythium insidiosum. Early and accurate diagnosis is the key to prompt treatment and an improved prognosis for patients with pythiosis. An alternative to microbiological and immunological approaches for facilitating diagnosis of pythiosis is the PCR-based assay. Until recently, the ribosomal DNA (rDNA) region was the only target available for PCR-based detection of P. insidiosum. Failure to detect P. insidiosum by PCR amplification using the rDNA-specific primers has been reported. PinsEXO1, encoding an exo-1,3-ß-glucanase, is an alternative, novel and efficient target for identification of P. insidiosum by conventional PCR. In this study, we aimed to develop a real-time (RT)-PCR approach targeting PinsEXO1 and compare its performance with conventional PCR for the detection of P. insidiosum. Both conventional and RT-PCR assays were positive for all 35 P. insidiosum strains tested, whilst all 58 control fungi were negative. The turnaround time for conventional PCR was 10 h, whilst that for RT-PCR was 7.5 h. The lowest amounts of genomic DNA template required for successful amplification by conventional and RT-PCR were 1 and 1 × 10(-4) ng, respectively. In conclusion, the RT-PCR assay retained 100% sensitivity and 100% specificity for detection of P. insidiosum. It showed a substantially improved analytical sensitivity and turnaround time that could improve diagnosis of pythiosis. The assay could also facilitate quantitative DNA analysis and epidemiological studies of P. insidiosum.

Sequence and Bioinformatic Analysis of Family 1 Glycoside Hydrolase (GH) 1 Gene from the Oomycete Pythium myriotylum Drechsler.

The oomycetous phytopathogen Pythium myriotylum secretes cellulases for growth/nutrition of the necrotroph. Cellulases are multi-enzyme system classified into different glycoside hydrolase (GH) families. The present study deals with identification and characterization of GH gene sequence from P. myriotylum by a PCR strategy using consensus primers. Cloning of the full-length gene sequence using genome walker strategy resulted in identification of 1230-bp P. myriotylum GH gene sequence, designated as PmGH1. Analysis revealed that PmGH1 encodes a predicted cytoplasmic 421 amino acid protein with an apparent molecular weight of 46.77 kDa and a theoretical pI of 8.11. Tertiary structure of the deduced amino acid sequence showed typical (α/ß)8 barrel folding of family 1 GHs. Sequence characterization of PmGH1 identified the conserved active site residues, viz., Glu 181 and Glu 399, that function as acid-base catalyst and catalytically active nucleophile, respectively. Binding sites for N-acetyl-D-glucosamine (NAG) were revealed in the PmGH1 3D structure with Glu181 and Glu399 positioned on either side to form a catalytic pair. Phylogenetic analysis indicated a closer affiliation of PmGH1 with sequences of GH1 family. Results presented are first attempts providing novel insights into the evolutionary and functional perspectives of the identified P. myriotylum GH.

Purification and characterization of secretory serine protease from necrotrophic oomycete, Pythium myriotylum Dreschler.

Progressive increase in extracellular proteolytic activity with respect to growth was detected in cultures of necrotrophic oomycete Pythium myriotylum Dreschler with maximum activity detected at stationary phase of growth. The secretory protease from P. myriotylum designated, spPm1 was purified to homogeneity giving a single band of 47 kDa molecular mass on non-reducing SDS-PAGE and exhibiting caseinolytic activity in the zymogram. Under reducing conditions, an additional band of 27.0 kDa molecular size observed was subjected to matrix-assisted laser desorption/ionization-time-of-flight mass spectrometry (MALDI-TOF-MS) analysis. Resulting peptide identified as an autolytic product and generated under reducing conditions on SDS-PAGE, showed homology to domains of oomycete effector molecules. spPm1 retained proteolytic activity over broad pH (5.0-12.0) and temperature (10-80 °C) ranges with optimal pH and temperature at 8.0 and 60 °C respectively. spPm1 was identified as a serine protease following experiments with inhibitors specific to various protease groups. spPm1 displayed high stability to surfactants, organic solvents, oxidizing agents and to metal-ion chelator, EDTA. Kinetic parameters, Km and Vmax were determined as 0.04 mM and 7.52 U min(-1) mg(-1) respectively. Preferential hydrolysis of synthetic fluorogenic substrate, SAAPPPA (N-succinyl-L-alanyl-alanyl-proline-phenylalanine-p-nitroanilide) confirmed spPm1 as belonging to subtilisin serine protease family. The excellent stability of spPm1 protease characterized from P. myriotylum is discussed with respect to its potential industrial applications.

Carbohydrate-related enzymes of important Phytophthora plant pathogens.

Carbohydrate-Active enZymes (CAZymes) form particularly interesting targets to study in plant pathogens. Despite the fact that many CAZymes are pathogenicity factors, oomycete CAZymes have received significantly less attention than effectors in the literature. Here we present an analysis of the CAZymes present in the Phytophthora infestans, Ph. ramorum, Ph. sojae and Pythium ultimum genomes compared to growth of these species on a range of different carbon sources. Growth on these carbon sources indicates that the size of enzyme families involved in degradation of cell-wall related substrates like cellulose, xylan and pectin is not always a good predictor of growth on these substrates. While a capacity to degrade xylan and cellulose exists the products are not fully saccharified and used as a carbon source. The Phytophthora genomes encode larger CAZyme sets when compared to Py. ultimum, and encode putative cutinases, GH12 xyloglucanases and GH10 xylanases that are missing in the Py. ultimum genome. Phytophthora spp. also encode a larger number of enzyme families and genes involved in pectin degradation. No loss or gain of complete enzyme families was found between the Phytophthora genomes, but there are some marked differences in the size of some enzyme families.

Purification and biochemical characterization of an extracellular endoglucanase from the necrotrophic oomycete, Pythium myriotylum Dreschler.

An extracellular endoglucanase (EG) that catalyzes the hydrolysis of carboxy-methyl cellulose (CMC) as substrate was purified to homogeneity from the soft-rot causing oomycete P. myriotylum with maximum EG production observed in presence of 1% (w/v) sucrose. The enzyme designated PmEG was observed to be monomeric with a molecular weight of 78 kDa as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Optimal activity of PmEG was determined at pH 5.0 and 25 °C with stability observed at pH extending over acidic to alkaline ranges viz., 3.0-10.0 and thermal stability upto 75 °C for 1 h. Optimal PmEG activity was obtained by addition of metal ions viz., Ca(2+) , Fe(3+) , Zn(2+) , Cu(2+) , Al(3+) , and also in presence of DTT and ß-mercaptoethanol while it was inhibited by Cr(2+) . Various organic solvents, surfactants, and the oxidant, H2 O2 had little/no effect on PmEG activity reflecting its robustness and potential commercial significance. Kinetic constants of PmEG, Km and Vmax were determined as 1.1 mM and 407 µmol min(-1) mg(-1) protein, respectively. Glucose was observed to cause mixed non-competitive inhibition of PmEG.

Novel elongase of Pythium sp. with high specificity on Δ(6)-18C desaturated fatty acids.

We identified a novel elongase gene from a selected strain of the Oomycete, Pythium sp. BCC53698. Using a PCR approach, the cloned gene (PyElo) possessed an open reading frame (ORF) of 834 bp encoding 277 amino acid residues. A similarity search showed that it had homology with the PUFA elongases of several organisms. In addition, the signature characteristics, including four conserved motifs, a histidine-rich catalytic motif and membrane-associated feature were present in the Pythium gene. Heterologous expression in Saccharomyces cerevisiae showed that it was specific for fatty acid substrates, having a double bond at Δ(6)-position, which included γ-linolenic acid (GLA) and stearidonic acid (STA), and preferentially elongated the n3-18C PUFA. This is an elongase in Oomycete fungi, which displays very high specificity on Δ(6)-18C desaturated fatty acids. This will be a powerful tool to engineer PUFA biosynthesis in organisms of interest through the n-6 series pathway for producing value-added fatty acids.

Enzymatic variability among Brazilian Pythium insidiosum isolates

Background. Pythium insidiosum is an oomycete classified in the kingdom Stramenopila. P. insidiosum hyphae are not able to initiate infection without the secretion of hydrolytic enzymes, which are considered an important factor in microbial virulence. Aims. To evaluate the extracellular enzymatic activity of 14 Brazilian P. insidiosum isolates and a standard strain (ATCC 58637) by the API-ZYM System screening method. Methods. Zoospores were grown in RPMI 1640 broth, and 65 μL of the liquid phase were inoculated in each cupule of the API-ZYM strips. Results. Differences in the enzymatic activities were observed among the isolates, although phosphohydrolases and ester hydrolases were conspicuous among all isolates. β-glucosidase was also present in most of the isolates. Enzymatic activities of β-glucosidase and chymotrypsin were not observed, differing from a previous study involving Australian isolates and intracellular enzymes. Conclusions. The discrepancy in the enzymatic profile observed among Brazilian P. insidiosum isolates reflects the phenotypic variations found in susceptibility tests

A peptide ELISA to detect antibodies against Pythium insidiosum based on predicted antigenic determinants of exo-1,3-beta-glucanase.

Human pythiosis is a life-threatening infectious disease caused by the oomycete Pythium insidiosum. Diagnosis of pythiosis relies on culture identification, serodiagnosis, and molecular-based assay. Preparation of a serodiagnostic test requires culture filtrate antigen (CFA) extracted from the live pathogen. A 74-kDa immunoreactive protein of P. insidiosum, is encoded by the exo-1,3-beta-glucanase gene (PinsEXO1). PinsEXO1 protein is recognized by sera from pythiosis patients but not by sera from uninfected patients; therefore, this protein could be used to detect anti-P. insidiosum antibodies. In this study we aimed to: identify, synthesize, and evaluate an antigenic determinant (epitope) of PinsEXO1 to be used to serodiagnose pythiosis based on peptide ELISA, and to compare the diagnostic performance of that test with the current CFA-based ELISA. Two antigenic determinants of PinsEXO1 (Peptide-A and -B) were predicted using the PREDITOP program. The sera from 34 pythiosis patients and 92 control subjects were evaluated. Peptide-A, Peptide-B, and CFA-based ELISAs all had a specificity of 100%. Peptide-B ELISA had a sensitivity of 91% and an accuracy of 98% and both Peptide-A and CFA-based ELISAs had a sensitivity of 100% and an accuracy of 100%. Peptide-A is a more efficient epitope than Peptide-B, and can be used as an alternative antigen to develop a serodiagnostic assay for pythiosis.

Carbohydrate-active enzymes in pythium and their role in plant cell wall and storage polysaccharide degradation.

Carbohydrate-active enzymes (CAZymes) are involved in the metabolism of glycoconjugates, oligosaccharides, and polysaccharides and, in the case of plant pathogens, in the degradation of the host cell wall and storage compounds. We performed an in silico analysis of CAZymes predicted from the genomes of seven Pythium species (Py. aphanidermatum, Py. arrhenomanes, Py. irregulare, Py. iwayamai, Py. ultimum var. ultimum, Py. ultimum var. sporangiiferum and Py. vexans) using the "CAZymes Analysis Toolkit" and "Database for Automated Carbohydrate-active Enzyme Annotation" and compared them to previously published oomycete genomes. Growth of Pythium spp. was assessed in a minimal medium containing selected carbon sources that are usually present in plants. The in silico analyses, coupled with our in vitro growth assays, suggest that most of the predicted CAZymes are involved in the metabolism of the oomycete cell wall with starch and sucrose serving as the main carbohydrate sources for growth of these plant pathogens. The genomes of Pythium spp. also encode pectinases and cellulases that facilitate degradation of the plant cell wall and are important in hyphal penetration; however, the species examined in this study lack the requisite genes for the complete saccharification of these carbohydrates for use as a carbon source. Genes encoding for xylan, xyloglucan, (galacto)(gluco)mannan and cutin degradation were absent or infrequent in Pythium spp.. Comparative analyses of predicted CAZymes in oomycetes indicated distinct evolutionary histories. Furthermore, CAZyme gene families among Pythium spp. were not uniformly distributed in the genomes, suggesting independent gene loss events, reflective of the polyphyletic relationships among some of the species.

Characterization of major hydrolytic enzymes secreted by Pythium myriotylum, causative agent for soft rot disease.

Pythium myriotylum, an oomycetous necrotroph is the causal agent of soft rot disease affecting several crops. Successful colonization by necrotrophs depends on their secretion of a diverse array of plant cell wall degrading enzymes (CWDEs). The induction dynamics of CWDEs secreted by P. myriotylum was analysed as little information is available for this pathogen. Activities of CWDEs that included pectinase, cellulase, xylanase and protease were detected using radial diffusion assay and differential staining. In Czapek Dox minimal medium supplemented with respective substrates as carbon source, the increase in CWDE activities was observed till 8 days of incubation after which a gradual decline in enzymatic activities was observed. With sucrose as sole carbon source, all the enzymes studied showed increase in activity with fungal growth while with cell wall material derived from ginger rhizome as sole carbon source, an initial spurt in cellulase, xylanase and pectinase activities was observed 3 days post incubation while protease activity increased from three days of incubation and reached maximum at 13 days of incubation. To further evaluate the role of CWDEs in pathogenicity, UV-induced mutants (pmN14uv1) were generated wherein significant reduction in cellulase, pectinase and protease activities were observed while that of xylanase remained unchanged compared to wild type isolate (RGCBN14). Bioassays indicated changes in infection potential of pmN14uv1 thereby suggesting the crucial role played by P. myriotylum CWDEs in initiating the rotting process. Hence appropriate strategies that target the production/activity of these secretory hydrolytic enzymes will help in reducing disease incidence/pathogen virulence.

Enzymatic variability among Brazilian Pythium insidiosum isolates.

BACKGROUND: Pythium insidiosum is an oomycete classified in the kingdom Stramenopila. P. insidiosum hyphae are not able to initiate infection without the secretion of hydrolytic enzymes, which are considered an important factor in microbial virulence. AIMS: To evaluate the extracellular enzymatic activity of 14 Brazilian P. insidiosum isolates and a standard strain (ATCC 58637) by the API-ZYM System screening method. METHODS: Zoospores were grown in RPMI 1640 broth, and 65 µL of the liquid phase were inoculated in each cupule of the API-ZYM strips. RESULTS: Differences in the enzymatic activities were observed among the isolates, although phosphohydrolases and ester hydrolases were conspicuous among all isolates. ß-glucosidase was also present in most of the isolates. Enzymatic activities of α-glucosidase and chymotrypsin were not observed, differing from a previous study involving Australian isolates and intracellular enzymes. CONCLUSIONS: The discrepancy in the enzymatic profile observed among Brazilian P. insidiosum isolates reflects the phenotypic variations found in susceptibility tests.

Identification and characterization of new Δ-17 fatty acid desaturases.

ω-3 fatty acid desaturase is a key enzyme for the biosynthesis of ω-3 polyunsaturated fatty acids via the oxidative desaturase/elongase pathways. Here we report the identification of three ω-3 desaturases from oomycetes, Pythium aphanidermatum, Phytophthora sojae, and Phytophthora ramorum. These new ω-3 desaturases share 55 % identity at the amino acid level with the known Δ-17 desaturase of Saprolegnia diclina, and about 31 % identity with the bifunctional Δ-12/Δ-15 desaturase of Fusarium monoliforme. The three enzymes were expressed in either wild-type or codon optimized form in an engineered arachidonic acid producing strain of Yarrowia lipolytica to study their activity and substrate specificity. All three were able to convert the ω-6 arachidonic acid to the ω-3 eicosapentanoic acid, with a substrate conversion efficiency of 54-65 %. These enzymes have a broad ω-6 fatty acid substrate spectrum, including both C18 and C20 ω-6 fatty acids although they prefer the C20 substrates, and have strong Δ-17 desaturase activity but weaker Δ-15 desaturase activity. Thus, they belong to the Δ-17 desaturase class. Unlike the previously identified bifunctional Δ-12/Δ-15 desaturase from F. monoliforme, they lack Δ-12 desaturase activity. The newly identified Δ-17 desaturases could use fatty acids in both acyl-CoA and phospholipid fraction as substrates. The identification of these Δ-17 desaturases provides a set of powerful new tools for genetic engineering of microbes and plants to produce ω-3 fatty acids, such as eicosapentanoic acid and docosahexanoic acid, at high levels.