Genetic Analysis of Biosurfactant Production in Ustilago maydis

The dimorphic basidiomycete Ustilago maydis produces large amountsof surface-active compounds under conditions of nitrogen starvation.These biosurfactants consist of derivatives of two classes ofamphipathic glycolipids. Ustilagic acids are cellobiose lipidsin which the disaccharide is O-glycosidically linked to 15,16-dihydroxyhexadecanoicacid. Ustilipids are mannosylerythritol lipids derived fromacylated ß-D-mannopyranosyl-D-erythritol. Whereasthe chemical structure of these biosurfactants has been determined,the genetic basis for their biosynthesis and regulation is largelyunknown. Here we report the first identification of two genes,emt1 and cyp1, that are essential for the production of fungalextracellular glycolipids. emt1 is required for mannosylerythritollipid production and codes for a protein with similarity toprokaryotic glycosyltransferases involved in the biosynthesisof macrolide antibiotics. We suggest that Emt1 catalyzes thesynthesis of mannosyl-D-erythritol by transfer of GDP-mannose.Deletion of the gene cyp1 resulted in complete loss of ustilagicacid production. Cyp1 encodes a cytochrome P450 monooxygenasewhich is highly related to a family of plant fatty acid hydroxylases.Therefore we assume that Cyp1 is directly involved in the biosynthesisof the unusual 15,16-dihydroxyhexadecanoic acid. We could showthat mannosylerythritol lipid production is responsible forhemolytic activity on blood agar, whereas ustilagic acid secretionis required for long-range pheromone recognition. The mutantsdescribed here allow for the first time a genetic analysis ofglycolipid production in fungi.

INTRODUCTION

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Introduction

Many microorganisms produce surface-active compounds that canfulfill different roles in microbial physiology. Biosurfactantsallow the adhesion of microorganisms to hydrophobic surfaces,increase the bioavailability of water-insoluble substrates,and often show antimicrobial activity (35). Many bacterial speciessecrete high-molecular-weight biosurfactants consisting mainlyof polysaccharides, lipoproteins, or lipopolysaccharides. Low-molecular-weightbiosurfactants are generally glycolipids or lipopeptides andare produced by a variety of microorganisms, including bacteriaand fungi. Secreted lipopeptide antibiotics with high surfaceactivity were first found in Bacillus subtilis, which producessurfactin (4). Extracellular glycolipids consist of differentmono- or disaccharides that are either acylated or glycosidicallylinked to long-chain fatty acids. Although these microbial glycolipidshave attracted some technological interest (12), very littleis known about their regulation and biosynthesis (43). The productionof rhamnolipid by Pseudomonas aeruginosa is the best-understoodpathway at the genetic level. The synthesis of this glycolipidproceeds by sequential glycosyl transfer reactions. The genesinvolved in rhamnolipid biosynthesis are encoded on a plasmid,and their expression is regulated by a quorum sensing system(for review, see reference 28).

Production of extracellular glycolipids has also been detectedin many fungal species. Sophorose lipids are secreted by Candidabombicola (21), mannosylerythritol lipids (MEL) were first isolatedin the dimorphic fungus Ustilago maydis as extracellular oilwith a higher density than water (19) and were later detectedalso in Candida antarctica, Schizonella melanogramma, and Geotrichumcandidum (11, 24, 27). The primary structure of these glycolipidshas been determined (6, 13, 16, 27). They consist of a disaccharideformed by mannose and erythritol, which is acylated at the mannosemoiety with fatty acids of different lengths (Fig. 1C). Recently,mannosylerythritol lipids from U. maydis were identified ina screen for inhibitors of mammalian dopamine receptors (27).The authors of this study named these glycolipids ustilipidsand determined the composition of the main variants of theseglycolipids by mass spectrometry (27).

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FIG. 1. Glycolipid production in U. maydis. (A) Haploid cells of U. maydis strain MB215 produce large amounts of insoluble glycolipids under conditions of nitrogen starvation. Glycolipids are visible as needle-like precipitates. Length of scale bar, 20 µm. (B and C) Chemical structures of (B) ustilagic acids and (C) ustilipids.

In addition to MEL production, U. maydis secretes a second classof glycolipids, the cellobiose lipid ustilagic acid. Ustilagicacid was first described in 1950 by Haskins, who observed insubmerged culture of U. maydis the formation of an insolublecompound with antibiotic activity (18) (Fig. 1A). The sugarmoiety of ustilagic acid is the disaccharide cellobiose, whichis O-glycosidically linked to the ${omega}$ -hydroxyl group of the unusuallong-chain fatty acid 15,16-dihydroxyhexadecanoic acid or 2,15,16-trihydroxyhexadecanoicacid (Fig. 1B). In addition, the cellobiose is esterified atseveral positions with either acetyl or medium-chain hydroxyfatty acids (30). Cellobiose-derived glycolipids have sincebeen detected in other fungal species (26, 34). The fungal biocontrolagent Pseudozyma flocculosa produces flocculosin, a rare cellobioselipid with antifungal activity (9). Production of both typesof glycolipids in U. maydis occurs readily under conditionsof nitrogen starvation and can reach large yields (up to 23g/liter). The yield and ratio of both classes of glycolipidsdepend on the available carbon source and can be shifted towardseither of these biosurfactants (42).

Although glycolipid production in fungi has been known for along time, the genetic basis of their production and regulationis largely unknown. Here we describe the cloning of two genesinvolved in glycolipid biosynthesis in U. maydis. We have identifieda putative glycosyltransferase, Emt1, which is required forproduction of mannosylerythritol lipids. Sequence similaritywith mycosamine transferases from macrolide-producing actinomycetessuggests that Emt1 catalyzes the transfer of mannose to erythritol.In addition, we could abolish the production of the cellobiose-lipidustilagic acid by deleting the P450 monooxygenase Cyp1. Sinceustilagic acid contains the unusual 15,16-dihydroxyhexadecanoicacid, we assume that Cyp1 is involved in terminal and/or subterminalhydroxylation of this fatty acid. These mutants allow, for thefirst time, a molecular characterization of glycolipid biosynthesisin fungi.

MATERIALS AND METHODS

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Materials and Methods

Strains, plasmids, and culture conditions.
U. maydis strains FB1 (a1 b1) and FB2 (a2 b2) have been described^.(5). Strain MB215 is a wild isolate and was collected in northernGermany. Its mating type was determined as a2 b13. Strain MB215and the derived emt1 and cyp1 mutants were deposited at theGerman Collection of Microorganisms and Cell Cultures (DSMZ)(accession numbers: DSM17144 [MB215], DSM17145 [MB215cyp1],DSM17146 [MB215emt1], and DSM17147 [MB215cyp1emt1]). U. maydisstrains were grown at 28°C in liquid YEPS (1% yeast extract,2% peptone, 2% sucrose) or on solid potato dextrose agar (PDA).Solid medium contained 1.5% (wt/vol) Bacto-agar. For selection,PD plates containing 2 µg/ml carboxin or 200 µg/mlhygromycin were used. Glycolipid production strains were preculturedat 28°C in liquid potato dextrose broth (PDB) (2.4%) tologarithmic phase and then shifted to nitrogen starvation mediumcontaining 1.7 g/liter YNB (yeast nitrogen base without ammoniumsulfate) and 5% glucose as the carbon source. Glycolipids wereisolated after cultivating cells for 4 days at 28°C on therotary shaker. Transformation of U. maydis was performed asdescribed (38).

Escherichia coli strains DH5 ${alpha}$ and XL1-Blue MR [mcrA183 ${Delta}$ (mcrCB-hsdSMR-mrr)173endA1 supE44 thi-1 recA1 gyrA96 relA1 lac] were used for allDNA manipulations. E. coli was grown in LB medium (1% NaCl,1% tryptone, 0.5% yeast extract) or in dYT medium (1.6% tryptone,1% yeast extract, 0.5% NaCl).

Generation and characterization of mutants defective for glycolipid production.
The ${Delta}$ emt1 and ${Delta}$ cyp1 mutants were generated according to the publishedprotocol (23). The upstream flanking region of emt1 was amplifiedby PCR with primers 5'-GCCGCTGTGGCACGTCTCTG-3' and 5'-CACGGCCTGAGTGGCCCAGGGAGGGGGAGGGAGAGAG-3',which introduces an SfiI site (italic). The downstream flankingregion was amplified by PCR using primers 5'-GTGGGCCATCTAGGCCGGCTCCGCTCATGCATTTCCTCG-3'and 5'-GGCTTGACCTCTGGCAACAGC-3'. The amplified fragments werecut with SfiI and ligated to the SfiI-digested hygromycin resistancecassette. The knockout construct was amplified with the distalprimers and transformed into U. maydis.

The cyp1 gene was replaced accordingly using primers 5'-CAATCTGCCGACGACGGGand 5'-CACGGCCTGAGTGGCCTCTGCAGACCTTCACATAC-3' for the upstreamflanking region and primers 5'-GTGGGCCATCTAGGCCTTCACGATTGTCTTGCCACGGG-3'and 5'-GCCCGCCCGCAGACCACGCG-3' for the downstream flanking region.

For Southern blot analysis of the ${Delta}$ emt1 and ${Delta}$ cyp1 mutant strains,genomic DNA was isolated according to (20). ${Delta}$ emt1 DNA was digestedwith BamHI and probed with an internal 1-kb fragment of theemt1 gene, which was amplified by PCR using primers 5'-GCAGCCACAATGGTCCGCG-3'and 5'-CGAGTCTGTGAGGCCAGGCGTG-3'. For Southern analysis of thecyp1 mutant strain, the genomic DNA was digested with EcoRVand probed with an internal 500-bp fragment of the cyp1 gene,which was amplified by PCR using primers 5'-GAAGGTGCTCGACATGCGC-3'and 5'-CTTGGGGATCGATGGATGC-3'.

Northern analysis.
Total RNA was isolated for Northern blot analysis (37). Cultureswere grown at 28°C to logarithmic phase in YNB medium containing5% glucose and 0.2% ammonium sulfate. After centrifugation thecells were resuspended in the same volume of fresh medium containing5% glucose but lacking a nitrogen source. RNA was prepared atthe times indicated. Northern blots were prepared (36). Forthe emt1 expression analysis, an internal probe of the genewas used. This 500-bp probe was amplified by PCR using primers5'-AACCTGACATGACTAACCCTGTCATCTTGATT-3' and 5'-ACATATGTCAATCGCTCCCAACAGTGG-3'.For the cyp1 expression analysis a 500-bp internal probe ofthe gene was used. This probe was amplified by PCR using primers5'-GAAGGTGCTCGACATGCGC-3' and 5'-CTTGGGGATCGATGGATGC-3'. Northernhybridization was performed as described (46).

Isolation of glycolipids.
Extracellular glycolipids were extracted from suspension cultures(0.5 ml) with 1 volume of ethyl acetate. The ethyl acetate phasewas evaporated and glycolipids were dissolved in methanol (12).Glycolipids were analyzed by thin-layer chromatography (TLC)on silica plates (Silica gel 60; Merck) with a solvent systemconsisting of chloroform-methanol-water (65:25:4, vol/vol).The plate was dried thoroughly and sugar-containing compoundswere visualized by spraying with a mixture of glacial aceticacid-sulfuric acid-p-anisaldehyde (50:1:0,5, vol/vol) and heatingat 150°C for 3 min (14).

Phenotypic characterization of mutants.
Hemolytic activity was analyzed by spotting 10 µl of anovernight culture on blood agar plates (24 g/liter potato dextrose,20 g/liter agar, 8 g/liter NaCl, and 5% sheep blood [Oxoid]).Hemolysis was monitored after incubation for 3 days at 28°C.

Confrontation assays were performed as described previously(40). Plant infections were essentially done as described previously(15). For infections the maize cultivar Early Golden Bantam(purchased from Olds Seed Solutions, Madison, WI) was used.

The surface activity of supernatants of strains grown underconditions of nitrogen starvation was assayed by their abilityto collapse droplets on a hydrophobic surface (parafilm M laboratoryfilm) as described (25); 25 µl of culture supernatantwere pipetted after adding xylene cyanol for staining. The dyexylene cyanol has no influence on the shape of the droplets.

RESULTS

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Results

Isolation of a strain with a high level of glycolipid production.
Extracellular glycolipids were detected in U. maydis more than50 years ago (18). Nevertheless, very little is known abouttheir biosynthesis and their biological function. Thereforewe aimed at generating mutants defective for glycolipid production.Since the commonly used laboratory strain FB1 (5) produces onlysmall amounts of ustilagic acid (Fig. 3, lane 1), we screenedseveral wild isolates for enhanced glycolipid production. Cellswere grown in rich medium and shifted to nitrogen starvation.After incubation for 4 days, secreted glycolipids were extractedwith ethyl acetate and subjected to thin-layer chromatographyon silica plates. We could identify strain MB215, which secreteslarge amounts of both ustilipids and ustilagic acids (Fig. 3,lane 2). We used this strain in a reverse genetics approachto identify genes that are involved in glycolipid biosynthesisin U. maydis.

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FIG. 3. Analysis of glycolipid production by wild-type and glycolipid-deficient strains. Ethyl acetate extracts of extracellular glycolipids were analyzed by thin-layer chromatography. Wild-type strains FB1 and MB215 produce both mannosylerythritol lipids (MEL) and ustilagic acids (UA). ${Delta}$ emt1 and ${Delta}$ cyp1 mutant strains are deficient for MEL and ustilagic acid production, respectively. Double emt1 cyp1 mutants produce neither of these substances. The slow-migrating band with low intensity which is visible in the ${Delta}$ cyp1 strains corresponds to an unidentified compound.

Putative mannosyltransferase Emt1 is required for ustilipid production.
To generate mutants of U. maydis that are unable to producemannosylerythritol lipids (MELs), we reasoned that a major stepin MEL biosynthesis would be the generation of the central mannosyl-ß-D-erythritolmoiety. This assumption is supported by the fact that this compoundhas been isolated in significant amounts from MEL-producingU. maydis cells as a water-soluble substance (7). The most likelypathway would be the transfer of activated GDP-mannose to theC-4 hydroxyl group of meso-erythritol. No enzyme has been describedso far that catalyzes such a reaction. Therefore, we searchedthe publicly available genome database of U. maydis for putativeglycosyltransferases that could be involved in the generationof this moiety.

About 40 genes encoding proteins with some similarity to glycosyltransferaseswere identified in the U. maydis database. The function of someof these enzymes could be derived by similarity to known glycosyltransferasesinvolved in cell wall biosynthesis or protein glycosylation.For the remaining candidate genes, mutants were systematicallygenerated by a PCR-based deletion strategy (23). In brief, flankingsequences were amplified with primers that introduce specificsticky ends. These were used to ligate both flanks with a hygromycinresistance cassette, which carries compatible ends. After anotherround of PCR amplification, the replacement constructs weretransformed into protoplasts of the haploid U. maydis strainsMB215 and FB1. Transformants were checked for successful deletionof the respective genes by Southern analysis (Fig. 2A). Thedeletion mutants were grown in rich medium and shifted to nitrogenstarvation. After 4 days glycolipids were extracted with ethylacetateand subjected to thin layer chromatography. One of the mutantsshowed a total loss of mannosylerythritol (MEL) production asdetected by TLC analysis (Fig. 3, lanes 3 and 4). Whereas inextracts from wild-type strains, several bands could be detectedthat correspond to the different ustilipids, no such signalswere visible in extracts from the mutant strain. The lack ofustilipid secretion was confirmed by liquid chromatography/massspectometry analysis of the ethyl acetate extract (data notshown). Thus, deletion of this putative glycosyltransferasecompletely blocks MEL production.

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FIG. 2. Southern and Northern blot analysis of emt1 and cyp1 genes. (A) Southern analysis of emt1 deletion mutants. Genomic DNA was cut with BamHI and probed with an internal 1-kb emt1 fragment. (B) Southern analysis of ${Delta}$ cyp1 mutants. DNA was digested with EcoRV and probed with an internal 500-bp cyp1 fragment. (C) Northern analysis of emt1 and cyp1 expression. Total RNA was prepared at the indicated time points after shifting cells to nitrogen starvation medium. The expression of the constitutively expressed ppi gene was used as a control. ppi encodes the U. maydis peptidyl-prolyl cis-trans isomerase (accession number EAK84904).

The corresponding gene of this mutant encodes a 628-amino-acidpolypeptide (accession number XP_400732) that displayed thehighest similarity to a predicted protein from Aspergillus nidulans(accession number XP_412272) whose function has not been determined(Fig. 4). More informative is the significant similarity toa group of actinomycete glycosyltransferases, which are involvedin the production of macrolide antibiotics (for review, seereference 3). These prokaryotic enzymes have been proposed totransfer GDP-mycosamine, which is derived from GDP-mannose,to the polyketide structure of macrolides. Therefore we assumethat U. maydis uses GDP-mannose to transfer a mannosyl residueto the C-4 hydroxyl group of meso-erythritol. Thus, we termedthe corresponding gene emt1 (Erythritol-mannosyl-transferase).

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FIG. 4. Sequence alignment of the U. maydis Emt1 glycosyltransferase. The amino acid sequence of Emt1 was aligned with the Emt1 homologue AN8135.2 from A. nidulans (accession number EAA58772) and with the PimK protein from Streptomyces natalensis, involved in pimaricin biosynthesis (accession number CAC20918).

Emt1 expression is highly induced under conditions of glycolipid production.
Secretion of ustilipids is observed only in medium that containsa carbon source but lacks nitrogen. Therefore we analyzed theexpression pattern of emt1 under these conditions. By Northernanalysis we could not detect any expression of emt1 in richmedium. Under conditions of nitrogen starvation, expressionof emt1 is visible after 4 h and reaches its maximum at 24 h.The time point of emt1 expression correlates perfectly withthe onset of glycolipid production (Fig. 2C).

Next we asked whether overexpression of Emt1 stimulates glycolipidproduction. We placed the open reading frame of Emt1 under controlof the arabinose-inducible crg promoter (8). If this constructwas transformed into the ${Delta}$ emt1 mutant strain, restoration ofMEL production was observed. Although the crg promoter is knownto result in high levels of expression, only weak MEL productioncould be observed in arabinose-containing medium. This is mostlikely due to low glycolipid production in the presence of arabinoseas a carbon source since wild-type strains also produce onlysmall amounts of glycolipids if arabinose is the only availablecarbon source (data not shown).

Isolation of mutants defective in ustilagic acid production.
All of the glycosyltransferase mutant strains that we generatedwere still able to secrete the cellobiose lipid ustilagic acid.Therefore we decided to search for other candidate genes involvedin the production of this cellobiose lipid. Ustilagic acid containsan unusual fatty acid which caries two vicinal hydroxyl groupsat its distal end (15,16-dihydroxyhexadecanoic acid or 2,15,16-trihydroxyhexadecanoicacid). We reasoned that these hydroxy fatty acids are most probablyderived from nonhydroxylated precursors. Such hydroxylationreactions are often catalyzed by cytochrome P450 enzymes (forreview, see reference 17); 23 genes in the genome database ofU. maydis are annotated as P450 enzymes (http://mips.gsf.de/genre/proj/ustilago/).

We have concentrated on two of these genes that code for proteinsrelated to the CYP94A1 family of P450 enzymes. Members of thisfamily have been identified in the plant Vicia sativa as fattyacid omega-hydroxylases (44). The U. maydis genes cyp1 (accessionnumber EAK87170) and cyp2 (accession number EAK82744), bothencoding P450 enzymes, were deleted by gene replacement (Southernanalysis shown for cyp1 in Fig. 2B). The resulting mutants weretested for glycolipid secretion. Whereas the production of glycolipidswas not affected in the cyp2 deletion mutant, no cellobioselipids could be detected in the ethyl acetate extract of cyp1mutant cells (Fig. 3).

The predicted Cyp1 polypeptide sequence consists of 628 aminoacids and contains a single intron. Cyp1 is very similar toanother U. maydis P450 enzyme (Um06473, accession number EAK87284)and a P450 enzyme from the related fungus Rhodotorula sp. strainCBS 8446 (accession number AY316198) (Fig. 5). In a BLAST searchwith the Cyp1 sequence, many P450 enzymes of plant origin werefound to be very similar to Cyp1. Of these plant enzymes, onlythe members of the CYP94A1 family from Vicia sativa have beencharacterized on the molecular level. CYP94A1 catalyzes the ${omega}$ -hydroxylation of epoxy and hydroxy fatty acids, probably aspart of a plant defense reaction (33). The highly related P450enzyme CYP94A2 of V. sativa hydroxylates medium-chain fattyacids at their terminal or subterminal end, depending on thelength of the fatty acid. Thus, we suggest that Cyp1 may catalyzethe terminal or subterminal hydroxylation of hexadecanoic acidto generate the precursor for ustilagic acid biosynthesis.

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FIG. 5. Comparison of P450 enzymes similar to U. maydis Cyp1. The conserved domain characteristic of cytochrome P450 enzymes is shaded. The number indicates the percentage of identical amino acids compared to Cyp1. The following sequences were aligned to Cyp1 using the BLAST algorithm (2): U. maydis Um06473 (accession number EAK87284), Rhodotorula sp. strain CBS 8446 cytochrome P450 gene (accession number AY316198), and Vicia sativa CYP94A2 (accession number AAG33645).

Expression of cyp1 is induced by nitrogen starvation but isdetectable only 24 h after shifting cells to the new medium(Fig. 2C). This correlates with the time course of glycolipidproduction in U. maydis, which reaches significant levels after2 to 4 days of cultivation (42).

Phenotype of glycolipid-defective mutants.
To create a strain which is unable to secrete any glycolipids,we crossed mutants of compatible mating type by infecting cornseedlings. The haploid progeny were analyzed for glycolipidproduction. We could easily detect strains that secreted neitherof the two glycolipids (Fig. 3). We checked the double mutantsfor their mating type and selected strains with compatible aand b mating types (SH6 ${Delta}$ emt1 ${Delta}$ cyp1 and SH9 ${Delta}$ emt1 ${Delta}$ cyp1). With the glycolipid-defectivemutants at hand, we were able to analyze the phenotype of thesestrains in more detail.

To test whether glycolipid secretion is required for cell recognitionduring mating, ${Delta}$ emt1, ${Delta}$ cyp1, and ${Delta}$ emt1/ ${Delta}$ cyp1 mutants were testedfor mating on charcoal-containing agar plates (10). None ofthese mutants showed a significant mating defect in combinationwith either wild-type or mutant strains (data not shown). Totest whether pheromone recognition over larger distances isaffected in the mutants, we used the confrontation assay (40).In this assay compatible strains were placed close to each otheron water agar and incubated under liquid paraffin. In combinationsof wild-type cells, the induction of conjugation hyphae growingtowards the pheromone source is observed predominantly in cellsof the a2 mating type (Fig. 6, WT). Deletion of the emt1 genedid not interfere with the formation of conjugation hyphae,but cells appeared to stick to each other in the hydrophobicenvironment (Fig. 6, ${Delta}$ emt1). Loss of ustilagic production in ${Delta}$ cyp1 mutants, however, abolishes conjugation tube induction,indicating that this glycolipid is required for pheromone recognitionover large distances. The phenotype of double mutants appearsto be a combination of that of single mutants (Fig. 6).

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FIG. 6. Confrontation assay to test for pheromone recognition. Compatible combinations of cells with the indicated genotype were placed in close proximity on water agar and covered with liquid paraffin. After cultivation for 16 h, cells were observed under the microscope. Formation of conjugation hyphae occurs only in combinations of wild-type (WT) and ${Delta}$ emt1 strains. The mating type of the strains is indicated at the left. Length of scale bar, 30 µm.

Next we tested whether the loss of glycolipid production affectsthe ability of the fungus to infect corn plants. Mutants weremixed with compatible wild-type or mutant strains and injectedinto corn seedlings. Tumor formation occurred with all combinationswith similar incidences, and the symptoms induced were indistinguishablefrom those induced by wild-type strains (Table 1). Thus, glycolipidproduction is not essential for the virulence of U. maydis.

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TABLE 1. Pathogenicity assay

Hemolytic activity of U. maydis is caused by mannosylerythritol lipid secretion.
Many biosurfactant-producing microorganisms can be detectedby their hemolytic activity on blood agar plates (47). Thereforewe tested wild-type and mutant strains for hemolytic activity.On blood agar plates, the wild isolate MB215 induces a prominentclear zone around the growing cells, which is significantlylarger than that caused by the laboratory strain FB1 (Fig. 7A).Deletion of the P450 enzyme involved in ustilagic acid productiondoes not cause a significant reduction of hemolytic activity.Loss of mannosylerythritol production, however, results in completelack of hemolytic activity (Fig. 7A). Next we tested whetherthe hemolytic activity is mainly due to the surface activityof secreted glycolipids. The effect of glycolipid secretionon the surface tension of culture supernatants was assessedby estimating their ability to cause the collapse of dropletsof culture supernatants on hydrophobic surfaces (25). The presenceof cellobiose lipids resulted in only a small reduction of surfacetension, whereas the presence of mannosylerythritol lipids inthe medium caused a significant collapse of the droplet (Fig.7B). The effect of glycolipids was additive since the surfacetension of culture supernatants from the double mutants appearedto be higher than that of the single mutants (Fig. 7B).

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FIG. 7. Determination of surface activity of secreted glycolipids. (A) Hemolytic activity of U. maydis strains is observed on blood agar plates after incubation for 2 days. A clear zone of hemolysis is observed only for wild-type (WT) and ${Delta}$ cyp1 mutant strains. (B) Secretion of amphipathic glycolipids reduces the surface tension of the culture supernatant. The effect of glycolipid secretion on the surface tension of the culture medium was visualized by placing 25 µl of culture supernatant on the hydrophobic surface of parafilm. Fresh culture medium was used as a control. The pictures were taken directly from above the droplets (upper panel) and from the side (lower panel).

DISCUSSION

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Discussion

We have identified two genes required for glycolipid productionin the dimorphic fungus Ustilago maydis. To our knowledge, thisis the first molecular characterization of fungal mutants thatare affected in the production of glycolipid biosurfactants.In the fungus Pseudozyma flocculosa, which is used as a biocontrolagent, random mutants have been generated by insertional mutagenesisand screened for their antagonistic properties (9). One of thesemutants was defective for the production of a cellobiose glycolipid(flocculosin). However, the mutant has not been characterizedat the molecular level (9). Thus, it is not known whether structuralgenes of biosurfactant synthesis are affected in this mutant.

Synthesis of mannosylerythritol lipids.
The Emt1 protein required for mannosylerythritol lipid productiondisplays a high level of sequence similarity with glycosyltransferasesinvolved in actinobacterial macrolide antibiotic production.In the synthesis of candicidin, amphotericin- and pimaricin-relatedenzymes have been proposed to transfer mycosamine to the macrolidechain (3). Mycosamine is a derivative of mannose and is generatedby the activity of several enzymes that modify the activatedGDP-mannose. Therefore we suggest that the U. maydis Emt1 proteinmay use GDP-mannose for the generation of the mannosylerythritolmoiety of ustilipids.

In the secreted mannosylerythritol lipids, the mannose is acylatedby one long-chain and several short-chain fatty acids. In principlethese alterations could occur at the level of GDP-mannose; however,MEL-producing U. maydis cells contain significant amounts ofwater-soluble mannose erythritol (19). Thus, we assume thatEmt1 directly transfers mannose to the C-4 atom of meso-erythritol.This reaction has to be stereospecific, since only mannosyl-D-erythritolis generated. We are currently investigating whether this reactioncan be followed in vitro using Emt1 protein overexpressed inE. coli cells. If this reaction pathway could be confirmed,it would constitute a novel enzymatic activity which may havesome interesting biotechnological applications, since mannosylerythritolcompounds have been used for the production of diverse products(12).

P450 enzyme is required for cellobiose lipid production.
We have identified the cytochrome P450-encoding gene cyp1, whichis essential for the production of the cellobiose lipid ustilagicacid. A main characteristic of ustilagic acid is the presenceof unusual hydroxy fatty acids which are O-glycosidically linkedto cellobiose at their terminal hydroxyl group. Whereas manyenzymes have been detected that are able to hydroxylate terminalor subterminal carbon atoms of long- and medium-chain fattyacids, no enzymatic activity has been described so far thatwould generate a pair of vicinal hydroxyl groups at the distalend of long-chain fatty acids.

Clues about the function of Cyp1 may come from its similarityto the plant enzyme CYP94A2 from Vicia sativa which hydroxylatesmedium-chain fatty acids (29). Characteristically, the positionof the introduced hydroxyl group depends on the length of thefatty acid precursor. Whereas short molecules like C₁₂ fattyacids are predominantly hydroxylated at their C-terminal ends,longer fatty acids with 14 or 16 carbon atoms are hydroxylatedat their subterminal position (29). To explain this peculiarregioselectivity, it has been suggested that the enzyme recognizesthe carboxyl end of the fatty acid and hydroxylates the position,which is reached by the catalytic core (29). In accordance withthis hypothesis, it was found that CYP94A2 is unable to hydroxylatealkanes. In addition, a mutant of CYP94A2 was identified inwhich a single amino acid substitution has altered this regiospecificity(22).

Thus, we suggest that production of the dihydroxyhexadecanoicacid in U. maydis occurs by two subsequent hydroxylation events.Whether subterminal hydroxylation follows the terminal hydroxylationor vice versa remains to be elucidated. In addition, it hasto be clarified whether Cyp1 alone is sufficient to catalyzeboth steps or whether another specific P450 enzyme is required.A good candidate for such an additional enzyme could be theU. maydis enzyme encoded by the gene Um06473, which is highlysimilar to Cyp1 (Fig. 6). We are currently generating mutantsto test whether deletion of this gene also affects cellobioselipid production.

In principle, the vicinal hydroxyl groups of the proposed ustilagicacid precursor could also be the result of epoxide-hydrolase-catalyzedhydrolysis of a terminal epoxide (39). The reactive epoxidecould be the result of epoxidation of a corresponding unsaturatedfatty acid derivative. However, neither such an unsaturatedfatty acid nor the necessary desaturase activity has ever beenfound in U. maydis or in any other fungus.

Biological function of glycolipid production in U. maydis.
We observed that the expression of both genes involved in glycolipidproduction was strongly induced by nitrogen starvation. Althoughthe molecular basis of nitrogen regulation is well known insome fungi (for review, see references 31 and 32), similar studieshave not yet been performed in U. maydis. However, inspectionof the genome sequence revealed the presence of a GATA-liketranscription factor (accession number XP_401867) which is highlysimilar to AreA, the central regulator of nitrogen metabolismin Aspergillus nidulans. AreA and the related GATA-like transcriptionfactors recognize binding sequences which carry the characteristicDNA motif GATA. Inspection of the promoter sequences of bothemt1 and cyp1 revealed the presence of several GATA elements.Some of these are located as pairs within 30 bp and thus arepotential strong binding sites for GATA transcription factors.However, whether emt1 and cyp1 are directly controlled by aGATA factor or whether the observed induction is indirect remainsto be tested.

The observed expression pattern correlated with the time courseof glycolipid production. The fact that expression of thesegenes cannot be detected under normal conditions and that deletionof these genes is not lethal imply that these glycolipids aretypical secondary metabolites (45). U. maydis is the only fungusknown so far that produces two different classes of glycolipidssimultaneously in significant amounts. Both compounds displaysurface activity, but the effect of the mannosylerythritol lipidappears to be significantly higher. Thus, it might be that bothbiosurfactants fulfill distinct requirements during the lifecycle of U. maydis.

Since we have generated mutant strains that produce only eitherone of these glycolipids or none, we are now able to dissectthe different contributions of these biosurfactants. Secretionof glycolipids occurs in the haploid phase, when U. maydis growsunicellular by budding. We could demonstrate that the cellobioselipids are required for pheromone recognition over large distancesduring mating. The pheromones secreted by U. maydis are hydrophobiclipopeptides that are nearly insoluble in water (41). We couldimagine that the biosurfactants produced by the fungus mightform a thin layer at the interface between hydrophobic and hydrophilicsurfaces. Two-dimensional diffusion of pheromones within thisfilm will then greatly enhance the chance to be detected bycells that are at a distance (1). The observation that mutantsare still able to infect corn plants indicates that the experimentalconditions used to infect corn seedlings in the greenhouse maynot be sensitive enough to detect slight differences in pheromonerecognition. In particular, large amounts of cells (>10⁷cells) are injected into the stem of corn seedlings and thusare likely to come into direct contact within the plant tissue.

The isolation of mutants that are specifically affected in glycolipidproduction will help us to understand the molecular mechanismsinvolved in the biosynthesis of these interesting natural compounds.At the same time, these mutants will allow further phenotypicassays and competition experiments to be devised to determinethe biological function of extracellular glycolipids in theirnatural environments.

ACKNOWLEDGMENTS

We thank Thorsten Selmer and Uwe Linne for mass spectrometryof glycolipid preparations. We acknowledge the assistance ofBeate Teichmann in isolating the cyp1 gene. We thank BjörnSandrock for critical reading of the manuscript and Kay Schinkfor improving the layout of sequence alignments.

This work was supported by special grant program SFB395 fromthe Deutsche Forschungsgemeinschaft.

FOOTNOTES

* Corresponding author. Mailing address: Philipps-Universität Marburg, Fachbereich Biologie-Genetik, D-35032 Marburg, Germany. Phone: 49-6421-282 1536. Fax: 49-6421-282 8971. E-mail: boelker{at}staff.uni-marburg.de.

REFERENCES

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