Mitogen-Activated Protein Kinase hog1 in the Entomopathogenic Fungus Beauveria bassiana Regulates Environmental Stress Responses and Virulence to Insects

Beauveria bassiana is an economically important insect-pathogenicfungus which is widely used as a biocontrol agent to controla variety of insect pests. However, its insecticide efficacyin the field is often influenced by adverse environmental factors.Thus, understanding the genetic regulatory processes involvedin the response to environmental stress would facilitate engineeringand production of a more efficient biocontrol agent. Here, amitogen-activated protein kinase (MAPK)-encoding gene, Bbhog1,was isolated from B. bassiana and shown to encode a functionalhomolog of yeast HIGH-OSMOLARITY GLYCEROL 1 (HOG1). A Bbhog1null mutation was generated in B. bassiana by targeted genereplacement, and the resulting mutants were more sensitive tohyperosmotic stress, high temperature, and oxidative stressthan the wild-type controls. These results demonstrate the conservedfunction of HOG1 MAPKs in the regulation of abiotic stress responses.Interestingly, ${Delta}$ Bbhog1 mutants exhibited greatly reduced pathogenicity,most likely due to a decrease in spore viability, a reducedability to attach to insect cuticle, and a reduction in appressoriumformation. The transcript levels of two hydrophobin-encodinggenes, hyd1 and hyd2, were dramatically decreased in a ${Delta}$ Bbhog1mutant, suggesting that Bbhog1 may regulate the expression ofthe gene associated with hydrophobicity or adherence.

INTRODUCTION

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INTRODUCTION

Mycoinsecticides are important insect pest control agents (10,19, 41). Unlike entomopathogenic bacteria and viruses that invadeinsects through their digestive tracks, fungal pathogens penetratethe host integument and are considered the only group of microbialbiocontrol agents active against sucking-type insect pests (21,49). However, low killing speed and sensitivity to adverse environmentfactors such as desiccation, high temperature, and UV radiationlimit the widespread use of entomopathogenic fungi (6, 22, 40).Thus, an understanding of the regulatory processes involvedin response to environment stress is essential for commercialdevelopment and improvement of these biocontrol fungi.

Mitogen-activated protein kinases (MAPKs), a family of serine-threonineprotein kinases, are widespread in eukaryotic cells and playcrucial roles in transduction of a variety of extracellularsignals and regulation of various development and differentiationprocesses (37, 45). MAPKs are usually activated by MAPK kinases,which are in turn activated by MAPK kinase kinases. These MAPKkinase kinase-MAPK kinase-MAPK cascades are conserved in eukaryoticcells and have been studied extensively in many organisms (45).In Saccharomyces cerevisiae, at least five MAPK pathways havebeen identified. These pathways are designated the FUS3, KSS1,HOG1, SLT2, and SMK1 MAPK cascades, and they are involved inmating, filamentous growth, the high-osmolarity response, cellintegrity, and ascospore formation, respectively (20). Recentstudies showed that homologs of HOG1 are involved in responsesto osmotic stress (12, 29, 44, 58), oxidative stress (28, 47),heat shock (28), and tolerance to a phenylpyrrole fungicide(12, 29, 58) in several other fungi. For instance, deletionof HOG1-encoding genes in Candida albicans (44), Neurosporacrassa (58), Magnaporthe grisea (12), and Colletotrichum lagenarium(29) causes a defect in adaptation to high-osmolarity conditions.A hog1-silenced strain of Trichoderma harzianum was highly sensitiveto osmotic stress and showed intermediate levels of sensitivityto oxidative stress (11). HOG1 MAP kinase is activated by highosmolarity, oxidative stress, and UV stress in Debaryomyceshansenii (47). In Aspergillus nidulans, a SakA protein kinaserelated to HOG1 has been implicated in stress signal transduction,sexual development, and spore survival (28). Inactivation ofHOG1 orthologs in M. grisea, N. crassa, and C. lagenarium resultsin increased resistance to the phenylpyrrole fungicide fludioxonil(12, 29, 58). A T. harzianum strain overexpressing the hog1(F315S)allele was highly resistant to the calcineurin inhibitor cyclosporineA, which suggests that there are links between the two pathways(11). In addition, HOG1 orthologs participating in fungal pathogen-hostinteractions have been demonstrated to be present in the plantpathogen Mycosphaerella graminicola and the mycoparasitic fungusT. harzianum. Deletion of the HOG1 kinase gene in M. graminicolaresults in mutants that are nonpathogenic to the host plant(35). In T. harzianum, either hyperactivation [with the hog1(F315S)allele] or silencing (using RNA interference) of a HOG1 proteinleads to strongly reduced antagonistic activity against someplant fungal pathogens (11). These results suggested that HOG1MAPKs might provide a clue for understanding the regulatorymechanism that responds to environmental stresses in fungi andfungal pathogenesis. However, whether HOG1-type MAPKs in entomopathogenicfungi are involved in the response to environmental stress andpathogenesis is far from clear.

Here, we characterized a HOG1-related MAPK gene, designatedBbhog1, in Beauveria bassiana, an important entomopathogenicfungus which targets a variety of insect pests, including agriculturalpests and vectors of human pathogens (5, 8, 32). Our data showedthat Bbhog1 regulates responses to stress stimuli. Interestingly,disruption of Bbhog1 resulted in a significant reduction invirulence and impairment of characteristics associated withpathogenicity.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Fungal and bacterial strains.
B. bassiana single-spore isolate Bb0062 has been described previously(17). Cultures were grown on Sabouraud's dextrose agar (DifcoLaboratories, Detroit, MI) supplemented with 1% (wt/vol) yeastextract for 14 days at 26°C with a cycle consisting of 15h of light and 9 h of darkness. Escherichia coli DH5 ${alpha}$ was employedfor DNA manipulations and transformations. Agrobacterium tumefaciensAGL-1 was used for fungal transformations.

Identification of the HOG1 MAPK-encoding gene.
Fungal genomic DNA was prepared as described previously (39),and total RNA was isolated from B. bassiana using the methodof Wan and Wilkins (53). RQ1 RNase-free DNase (Promega) wasused to remove DNA contamination in RNA samples. To PCR amplifya fragment of the HOG1 gene from B. bassiana, degenerate primersBh-F and Bh-R (Table 1) were designed based on alignments ofC. lagenarium OSC1 (29), N. crassa OS-2 (58), M. grisea OSM1(12), and S. cerevisiae HOG1 (7). PCR was performed using ExTaqDNA polymerase (TaKaRa). The resulting PCR product was shownto be a fragment of a HOG1-related MAPK gene. The complete genewas subsequently cloned by PCR walking using the Y-shaped adaptor-dependentextension (YADE) method as described previously (14). The primersused for PCR walking are shown in Table 1. All PCR productswere cloned into the A-T cloning vector pGEM-T Easy (Promega)according to manufacturer's instructions and subsequently sequenced.Designated Bbhog1, the complete gene was resolved using thePCR and YADE products based on overlapping regions. Primers(Table 1) were designed to clone the cDNA sequence of this geneusing the 3' full random amplification of cDNA ends (RACE) coreset (TaKaRa).

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TABLE 1. Oligonucleotides used in this study

Disruption of Bbhog1.
Plasmid pK2-BarGFP containing the herbicide resistance genebar and the enhanced green fluorescent protein gene egfp wasgenerated by inserting a Bar::GFP fusion gene (27) into EcoRIand HindIII sites of the binary vector pPK2 (34) in which anhph cassette was deleted. The 3' end of Bbhog1 (3' hog1) wascloned by performing PCR with primers R1 and R2 (Table 1) usingExTaq DNA polymerase (TaKaRa). The resulting PCR product wasdigested with SpeI and SmaI and inserted into HindIII and XbaIsites of pK2-BarGFP which was blunt ended using T4 DNA polymeraseat a HindIII site, to form pK2-BarGFP:3'hog1. The 5' end ofBbhog1 (5' hog1) was amplified with primers L1 and L2 with ExTaqDNA polymerase (TaKaRa). The PCR product was cloned into pGEM-TEasy (Promega) to form pGEM-5'hog1. Then the 5' end of Bbhog1was excised from pGEM-5'hog1 with EcoRI and inserted into theunique EcoRI site of pK2-BarGFP:3'hog1. The resulting gene replacementvector was confirmed by performing PCR with primers L1 and B2(5' end sequence of Bar) (Table 1) to be a 3.5-kb fragment anddesignated pBG ${Delta}$ hog1, and then it was mobilized into A. tumefaciensAGL-1 for fungal transformation (17).

Bbhog1 disruption mutants were initially selected on the basisof herbicide (glufosinate ammonium) resistance and expressionof green fluorescent protein. PCR performed with the primerpairs G1/R2 and G1/R2' (Table 1), Southern blotting, reversetranscription-PCR (RT-PCR), and Western blotting were used toconfirm disruption of Bbhog1 in B. bassiana transformants.

Blotting analysis.
Southern gel blot analysis was performed with about 25 µgDNA digested with appropriate restriction enzymes for each sample.The DNA probes were labeled with [ ${alpha}$ -³²P]dCTP using a labelingkit (Amersham).

Fungal proteins were extracted as described previously (28).For Western blot analysis, 20 µg proteins was transferredfrom a sodium dodecyl sulfate-12% polyacrylamide gel electrophoresisgel to a polyvinylidene difluoride membrane (Roche), and immunoblottingand blot development were carried out according to the instructionsprovided with an Opti-4CN Western blot kit (Bio-Rad). Proteinsrelated to HOG1 were detected using anti-Hog1p antibody y-215(Santa Cruz Biotech, United States).

Quantification of spore yield.
Twenty-milliliter portions of 1:4-diluted Sabouraud's dextroseagar supplemented with 1% (wt/vol) yeast extract or Czapek agarcontaining 0.5% (wt/vol) peptone (CZP agar) were tempered to45°C, mixed with 50 µl of conidial suspensions ata concentration of 1 x 10⁷ conidia ml^–1, and poured into90-mm-diameter petri dishes. After incubation at 26°C usinga cycle consisting of 15 h of light and 9 h of darkness fora total of 15 days, conidia were collected in 0.05% (vol/vol)Tween 80 and filtered through four layers of lens-cleaning tissue(Hangzhou Special Paper Industry Co., Ltd., People's Republicof China) to remove mycelial debris. The number of conidia producedwas determined by counting the conidia with a hemocytometerusing a Motic microscope (E220G). The experiment was repeatedfour times with three replicates for each strain.

Identification of compatible solutes for B. bassiana.
Two grams (fresh weight) of mycelia harvested from 48-h liquidcultures was inoculated into 100 ml Sabouraud's dextrose brothcontaining 1% (wt/vol) yeast extract (pH 7.0) (SDY broth) supplementedwith 0 or 0.4 M NaCl and incubated at 26°C on a rotary shaker(180 rpm) for 24 h. Mycelia were harvested, frozen in liquidnitrogen, and freeze-dried under a vacuum for 3 to 5 days forcarbohydrate extraction using a method described previously(12). A 0.5-g (dry weight) portion of mycelia was used to extractcarbohydrates after addition of 20 µg ribitol as the internalstandard by a previously described method (12). The mannitol,trehalose, erythritol, arabitol, and glycerol contents of myceliawere determined using a gas-liquid chromatography method describedpreviously (25). The experiment was repeated three times.

Bioassay.
Apterous adults of Myzus persicae ( $≤$ 2 days after the last ecdysis)reared on cabbage in the greenhouse were prepared by using apreviously described method (51) and used for a bioassay. Afungal conidial suspension was diluted to obtain suspensionscontaining 5 x 10⁷ and 1 x 10⁷ conidia ml^–1 using 0.05%(vol/vol) Tween 80. For inoculation, the aphids on each cabbageleaf (replicates were used for each treatment) were exposedto a spray consisting of 1 ml of a conidial suspension usinga Potter precision laboratory spray tower (Burkard ManufacturingCo., Ltd., United Kingdom) and then transferred to an HPG-280Hartificial climate cell (Harbin Donglian Electronic & TechnologyDevelopment Co. Ltd. of China) kept at 22 to 24°C. Controlaphids were treated with water plus 0.05% (vol/vol) Tween 80.For each treatment there were three replicates, each with 30to 40 aphids, and the experiments were repeated three times.Aphid mortality was examined daily and corrected using Abbott'sformula: P_T = [(P_O – P_C)/(100 – P_C)] x 100, whereP_O is the observed mortality and P_C is the control mortality(1).

Determination of conidial germination, adherence, appressorium formation, and hyphal body differentiation.
One hundred microliters of a conidial suspension containing1 x 10⁷ spores ml^–1 was spread onto CZP agar plates andincubated at 26°C. After 8 h, the percentage of germinatedconidia was assessed hourly. Three hundred conidia were examinedfor each time, and all experiments were repeated on three differentdates. A conidium was considered to have germinated if the lengthof its germ tube was greater than its width.

Conidial adherence to cicada hind wings was investigated byusing a previously described method (55). Appressoria were inducedon cicada hind wings using a method described previously (54),and the frequency of appressorium formation was determined bycounting the number of appressoria that developed from 300 germinatedconidia after 22 h. All experiments were repeated three times.

Hyphal body differentiation was investigated by injecting conidiainto insects. Third instars of Pieris brassicae larvae wereinoculated with 2 µl of a conidial suspension containing5 x 10⁷ spores ml^–1 and bled at 12-h intervals to observehyphal bodies with a microscope.

RT-PCR.
Two micrograms of total RNA was reverse transcribed using anoligo(dT)-primed cDNA synthesis kit (MBI Fermentas), and thefirst-strand cDNA was amplified with the Bbhog1, Bgpd, and β-tubulinprimers listed in Table 1. The expression of these three geneswas investigated during growth in CZP broth supplemented with0.4 M NaCl for 0, 10, and 20 min.

Real-time RT-PCR analysis.
First-strand cDNA was synthesized using oligo(dT) primers accordingto the manufacturer's instructions for a cDNA synthesis kit(MBI Fermentas). Five micrograms of total RNA was used for cDNAsynthesis, and the cDNA was subsequently diluted with nuclease-freewater to obtain a concentration of 10 ng µl^–1. Onemicroliter of diluted cDNA was used as a template for subsequentPCR amplification using a quantitative real-time PCR kit (Bio-Rad).The transcript levels of two hydrophobin-encoding genes, hyd1and hyd2 (9), the Pr1 protease gene cdep1 (18), and the chitinasegene Bbchit1 (14) were analyzed using real-time RT-PCR. Thestability of expression of four potential reference genes, the18S rRNA, β-tubulin, actin, and Bgpd genes, was evaluatedusing the wild type and Bbhog1 disruption mutants grown in insectcuticle or chitin medium (9) and a method described previously(52). Three of the four reference genes with the most stablegene expression were selected to normalize levels of gene transcriptionusing geNORM (52). Primer sequences for the eight genes usedare shown in Table 1.

The transcript levels of hyd1 and hyd2 were ascertained usinginsect cuticle media as described previously (9). Conidia harvestedfrom plates were inoculated into 1:4-diluted Sabouraud's dextrosebroth containing 1% (wt/vol) cicada cuticle at a final concentrationof 5 x 10⁵ conidia ml^–1 and were grown for 3 days at 26°Cwith aeration, after which the total RNA was extracted and subjectedto real-time RT-PCR analysis.

The levels of expression of cdep1 and Bbchit1 in insect cuticlebroth (basal salt medium supplemented with 0.5% [wt/vol] cicadacuticle as the sole carbon and nitrogen source) were also assessed.Two grams of washed mycelia was transferred from SDY mediuminto cicada cuticle broth and grown for an additional 12, 24,36, 48, 60, and 72 h. Total RNA was extracted and subjectedto real-time RT-PCR analysis.

Data analysis.
Variation among the treatments in a given experiment was differentiatedby using one-way analysis of variance, and the significancebetween treatments was tested using the lease significant differenceor the Dunnett T3 method. All statistical analyses were carriedout with the SPSS 8.0 program.

Nucleotide sequence accession numbers.
Data reported here have been deposited in the GenBank databaseunder the following accession numbers: AY572854 for Bbhog1 genomicDNA, EF452344 for hyd1 mRNA, EF520285 for hyd2 mRNA, AY040532for cdep1 genomic DNA, AY145440 for Bbchit1 genomic DNA, andAY679162 for Bgpd genomic DNA.

RESULTS

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RESULTS

Cloning of the Bbhog1 gene.
A HOG1-like MAPK gene, designated Bbhog1, was cloned from B.bassiana by performing PCR with degenerate primers (Table 1)and YADE (14). Based on the putative coding sequence identifiedusing BLASTX, additional primers (described in Materials andMethods) were designed to clone the cDNA using 3' RACE. ThecDNA fragment contained a 1,077-bp open reading frame whichencodes a 358-amino-acid protein with a predicted molecularmass of 49.9 kDa and a deduced pI of 8.7. Eight introns wereidentified in the DNA sequence by comparison to the cDNA sequence.The predicted Bbhog1 contained the conserved TGY activationloop at positions 171 to 173 found in the stress-activated proteinkinase subgroup of MAPKs (42). The amino acid sequence of Bbhog1showed 96%, 94%, 94%, and 80% identity to C. lagenarium OSC1(29), M. grisea OSM1 (12), N. crassa OS-2 (58), and S. cerevisiaeHOG1 (7), respectively. Southern analysis indicated that a singlecopy of Bbhog1 is present in B. bassiana (data not shown).

Disruption of Bbhog1 leads to sensitivity to high osmolarity, oxidative stress, and high temperature and resistance to the fungicide fludioxonil.
To investigate the roles of Bbhog1, a gene disruption strategywas used. The gene replacement vector pBG ${Delta}$ hog1 was constructedto delete 677 bp of the Bbhog1 coding region and to replaceit with a 4.2-kb Bar::GFP fusion gene cassette (see Fig. S1Ain the supplemental material). The disruption of Bbhog1 wasfirst screened by PCR with both primer pair G1/R2 and primerpair G1/R2' (Table 1) as a 2.8-kb fragment (data not shown)and then confirmed by Southern blotting (see Fig. S1B in thesupplemental material), RT-PCR (see Fig. S1C in the supplementalmaterial), and Western blotting (see Fig. S1D in the supplementalmaterial). Transformants were selected randomly for furtherstudy.

On standard medium (CZP medium), no obvious variation in thegrowth rate (Fig. 1A) or hyphal morphology (Fig. 1B) was observedin ${Delta}$ Bbhog1 mutants. However, the mutants did not form obviousdaylight rings resulting in rhythmic sporulation like the wild-typestrain (Fig. 1A), which was confirmed by a significant reductionin conidiation on agar plates. The numbers of conidia producedby ${Delta}$ Bbhog1 mutants on 1:4-diluted Sabouraud's dextrose agar supplementedwith 1% (wt/vol) yeast extract (3.3 x 10⁵ ± 0.6 x 10⁵conidia mm^–2) and CZP agar (1.0 x 10⁵ ± 0.1 x 10⁵conidia mm^–2) plates were 75.6% (df = 6; t = 11.33; P< 0.001) and 90.5% (df = 6; t = 22.69; P < 0.001) lessthan the numbers of conidia produced by the wild-type strain,respectively.

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FIG. 1. Disruption of Bbhog1 influences the growth of B. bassiana. Wild-type strain Bb0062 (WT) and the Bbhog1 disruption mutant ( ${Delta}$ Bbhog1) were incubated on CZP agar plates at 26°C for 10 days (A) or in CZP broth at 26°C on a rotary shaker (180 rpm) for 12 h (B) (control). The test strains were incubated on CZP agar plates supplemented with 0.4 M NaCl at 26°C for 10 days (C), in CZP broth containing 0.4 M NaCl at 26°C on a rotary shaker (180 rpm) for 12 h (D), on CZP agar plates supplemented (E) or not supplemented (F) with 0.4 M NaCl at 32°C for 10 days, or on CZP agar plates containing 20 mM H₂O₂ (G) or 2.5 µg ml^–1 fludioxonil (H) at 26°C for 10 days. Scale bars in panels B and D, 20 µm.

Under hyperosmotic stress conditions, the growth of the mutantswas dramatically reduced compared to that of the wild-type strain(Fig. 1C). Hyperosmotic stress also led to a distinct morphologicalchange in the mutant hyphae, which became swollen and vacuolated(Fig. 1D). The reduction in radial growth of the mutants wasalso found to be consistent with the biomass formation duringosmotic stress in shake flasks (see Fig. S2 in the supplementalmaterial). Similar reductions in growth were observed when ${Delta}$ Bbhog1mutants were subjected to chronic hyperosmotic stress by exposureto concentrations of glycerol or KCl generating identical osmoticpotentials (data not shown). The sensitivity to osmotic stressof ${Delta}$ Bbhog1 mutants was alleviated at a higher temperature (32°C)(Fig. 1E), like that of S. cerevisiae (48). Furthermore, disruptionof Bbhog1 increased the sensitivities to high temperature andoxidative stress. At 32°C or in medium containing 20 mMH₂O₂, ${Delta}$ Bbhog1 mutants showed a significant reduction in growthcompared to the wild-type strain (Fig. 1F and G). In addition, ${Delta}$ Bbhog1 mutants exhibited remarkable resistance to the fungicidefludioxonil (Fig. 1H), demonstrating that Bbhog1 has the samefunction in regulating sensitivity to fludioxonil as HOG1 MAPKsin other fungal species.

Disruption of Bbhog1 alters erythritol and arabitol accumulation.
To determine the effect of the ${Delta}$ Bbhog1 mutation on the cellularresponse to hyperosmotic stress, we prepared mycelial extractsfrom wild-type and ${Delta}$ Bbhog1 mutant cultures under isosmotic andhyperosmotic conditions and measured mannitol, trehalose, erythritol,arabitol, and glycerol concentrations using the gas-liquid chromatographymethod (25).

Disruption of Bbhog1 in B. bassiana did not interfere with theaccumulation of mannitol and glycerol in mycelium. Under normalconditions, B. bassiana accumulated mannitol as a major carbohydratein the mycelium (400.11 ± 6.71 µmol g^–1 [dryweight] mycelium). During hyperosmotic stress, which was imposedby incubating fungal mycelium in 0.4 M NaCl, the level of mannitolincreased by 30.0% (Fig. 2A). Compared to the mannitol contentsof the wild-type strain, no significant changes in the mannitolcontents of the ${Delta}$ Bbhog1 mutant were observed under normal conditionsor under hyperosmotic stress conditions (Fig. 2A). Smaller amountsof glycerol were present both in the wild-type strain and inthe ${Delta}$ Bbhog1 mutant, and the amounts increased by 50.5% and 61.8%during osmotic stress, respectively (Fig. 2B). The trehaloseaccumulation patterns were similar in the wild-type and ${Delta}$ Bbhog1strains, although the levels were decreased during hyperosmoticstress (data not shown).

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FIG. 2. Compatible solute production in mycelia of the wild-type strain and the ${Delta}$ Bbhog1 mutant. Mycelia were grown for 48 h in SDY broth before they were transferred to SDY broth or SDY broth containing 0.4 M NaCl and incubated for a further 24 h. Carbohydrates were extracted and quantified by gas-liquid chromatography (25). (A) Mannitol; (B) glycerol; (C) erythritol; (D) arabitol. The error bars indicate standard deviations from three repeats of the experiment. WT, wild type.

Significant changes in erythritol and arabitol accumulationin the ${Delta}$ Bbhog1 mutant were found when the mycelium was exposedto the osmotic stress. Erythritol is a major solute that accumulatesin B. bassiana under osmotic stress conditions (23). When theorganisms were stressed with 0.4 M NaCl, the concentration oferythritol increased rapidly in wild-type cells, reaching levelsthat were 11.7-fold higher than the levels under normal conditions(Fig. 2C). In cells of the ${Delta}$ Bbhog1 mutant, erythritol accumulatedat very low levels under normal conditions, reaching only 7.8%(F_3,₁₁ = 38.27; least significant difference for the post hoctest, P < 0.001) of the level in the wild-type strain. Althoughosmotic stress led to an erythritol level in the ${Delta}$ Bbhog1 mutantmycelium that was 8.9-fold-higher than the level under normalconditions, the level was still much lower than that in thewild-type strain (Fig. 2C). Arabitol, which was present at onlylow levels (2.82 ± 0.20 µmol g^–1 [dry weight]mycelium) during growth of B. bassiana under isosmotic conditions,accumulated dramatically in response to hyperosmotic stress,and the level was 17.7-fold greater than the level under normalconditions (Fig. 2D). In contrast, the levels of arabitol incells of the ${Delta}$ Bbhog1 mutant during growth under normal conditionswere significantly lower than those in cells of the wild-typestrain (F_3,11 = 1935.45; Dunnett T3 for the post hoc test, P< 0.001) and did not increase like the levels in the wild-typestrain in response to hyperosmotic stress (Fig. 2D). These resultssuggested that accumulation of erythritol and accumulation ofarabitol were regulated by Bbhog1 in B. bassiana.

Disruption of Bbhog1 leads to a significant decrease in virulence.
The bioassay results showed that disruption of Bbhog1 in B.bassiana significantly reduced the virulence against M. persicae.Significantly more aphids survived after inoculation of the ${Delta}$ Bbhog1 mutant at concentrations of 1 x 10⁷ and 5 x 10⁷ conidiaml^–1 than after inoculation of the wild-type strain. Nodistinct difference in survival rates was observed for aphidsinoculated with the ectopic integration transformant T270 andaphids inoculated with the wild type (Fig. 3). For instance,at day 6 after inoculation, the survival rates for aphids inoculatedusing concentrations of 5 x 10⁷ and 1 x 10⁷ conidia ml^–1in assays with the ${Delta}$ Bbhog1 mutant were in the range from 75.2to 81.7% (df = 2 and 8), compared to 20.3 to 53.3% (df = 2 and8) for assays with the wild-type strain (Fig. 3). Meanwhile,6 days after inoculation, the corrected mortality rates forM. persicae treated with the ${Delta}$ Bbhog1 mutant using concentrationsof 1 x 10⁷ and 5 x 10⁷ conidia ml^–1 were reduced by 66.5%and 72.5%, respectively, compared to the mortality rates forM. persicae inoculated with the same concentrations of the wild-typestrain. The results suggested that Bbhog1 is an important virulencefactor of B. bassiana.

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FIG. 3. Trends for mean survival of M. persicae after spraying. M. persicae peach aphids were sprayed with 1-ml portions of conidial suspensions containing 5 x 10⁷ conidia ml^–1 (A) and 1 x 10⁷ conidia ml^–1 (B), and the survival was recorded every day after inoculation. Control insects were sprayed with a conidial suspension prepared with the ectopic integration transformant T270 and sterilized water. For each treatment there were three replicates with 30 to 40 aphids each, and the experiments were repeated three times.

Disruption of Bbhog1 decreases spore viability and adherence and impairs appressorium formation.
To investigate the effect of Bbhog1 disruption on virulence-relatedfactors, we examined the conidial viability, adherence, appressoriumformation, and hyphal body differentiation of ${Delta}$ Bbhog1 mutants.The conidial germination rates of the ${Delta}$ Bbhog1 mutant on agarplates during the 8 to 14 h after inoculation were significantlylower (P < 0.01) than those of the wild-type strain (Fig.4A). The median germination time of the mutant was ca. 1.50h longer than that of the wild-type strain. The results suggestedthat disruption of Bbhog1 in B. bassiana caused a reductionin spore viability.

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FIG. 4. Determination of conidial germination, adherence, and appressorium formation. (A) Conidial germination. Conidia were inoculated onto CZP agar plates, and germinated conidia were counted hourly beginning 8 h after inoculation. (B) Conidial adherence on cicada hind wings. The assay was performed by using a previously described method (48). (C) Frequency of appressorium formation on cicada hind wings after 22 h of incubation. All experiments were repeated three times with three replicates for each repeat. WT, wild type.

Conidial adherence was assayed using cicada hind wings and amethod described previously (55). At 8 h after inoculation,only 37.7% ± 9.3% of the mutant conidia remained on thewings and could not be washed off by 0.05% (vol/vol) Tween 20,compared to 81.1% ± 10.5% of the wild-type strain conidia(df = 4; t = 6.17; P < 0.01) (Fig. 4B), indicating that conidialadherence to the insect cuticle was severely impaired by thegene disruption.

Appressoria were induced on cicada hind wings using a methoddescribed previously (54). The results showed that althoughthe appressorium structure of the ${Delta}$ Bbhog1 mutant was morphologicallysimilar to that of the wild type (Fig. 5A), the frequency ofappressorium formation for the ${Delta}$ Bbhog1 mutant was significantlylower than that for the wild-type strain. Twenty-two hours followinginoculation, only 18.2% ± 6.4% of germinated conidiaof the mutant differentiated into appressoria, a 77.9% decreasecompared to the results for the wild-type strain (82.5% ±7.5%) (df = 4; t = 27.09; P < 0.001) (Fig. 4C).

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FIG. 5. (A) Appressorium morphology. Appressorium formation was induced on cicada hind wings using a method described previously (54). AP, appressorium; GE, germ tube; CO, conidium. Bar = 20 µm. (B) Hyphal body differentiation at 3 days after injection of conidia into P. brassicae larva. Bar = 20 µm. WT, wild type.

In addition, we also investigated the hyphal body differentiationof ${Delta}$ Bbhog1 mutants inside the insect body. At day 3 after injection,the ${Delta}$ Bbhog1 mutant produced the same amount of hyphal bodiesin the hemolymph of the third-instar larvae of P. brassicaeas the wild-type strain (Fig. 5B), suggesting that inactivationof Bbhog1 may not influence the postpenetration developmentof B. bassiana.

Bbhog1 disruption suppresses expression of the hydrophobin-encoding genes hyd1 and hyd2.
The ranking of the four internal reference genes after determinationof gene stability was as follows (from least stable to moststable): actin, 18S rRNA, β-tubulin, Bgpd. Thus, we selectedthe Bgpd, β-tubulin, and 18S rRNA genes to normalize thelevels of gene transcription using geNORM (52). The transcriptlevels of two hydrophobin-encoding genes, hyd1 and hyd2, weredetermined by real-time RT-PCR when the fungal cells were grownin the presence of insect cuticle for 3 days. The results showedthat the transcript levels of hyd1 and hyd2 in the ${Delta}$ Bbhog1 mutantwere 46.4-fold and 41.5-fold lower, respectively, than thosein the wild-type strain (Fig. 6). Similar reductions in thelevels of expression of hyd1 and hyd2 were observed when ${Delta}$ Bbhog1mutants were grown in chitin broth (data not shown).

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FIG. 6. Expression of the hydrophobin-encoding genes hyd1 and hyd2 in the ${Delta}$ Bbhog1 mutant and the wild-type strain. Real-time RT-PCR was used to determine the relative levels of expression of hyd1 and hyd2 using Bgpd, β-tubulin, and 18S rRNA as loading controls to normalize samples by a method described previously (52) when the fungal cells were grown in the presence of cicada cuticle for 3 days. The error bars indicate standard deviations.

We also analyzed the transcript levels of the genes encodingtwo cuticle-degrading enzymes, the Pr1 protease CDEP1 and thechitinase Bbchit1, in ${Delta}$ Bbhog1 mutants and the wild type by real-timeRT-PCR using RNA from mycelia induced by using the cicada cuticle.The transcript patterns of these two genes were similar in thewild-type and ${Delta}$ Bbhog1 strains (data not shown), suggesting thatinactivation of Bbhog1 in B. bassiana does not affect the expressionof genes encoding cuticle-degrading enzymes.

DISCUSSION

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DISCUSSION

Bbhog1 disruption mutants showed sensitivity to hyperosmoticstress, high temperature, and oxidative stress and exhibiteda remarkable resistance to the fungicide fludioxonil. Theseresults demonstrate that there is a conserved function of HOG1MAPKs in regulation of abiotic stress responses. Similar tothe situation in S. cerevisiae (48, 57), the sensitivity toosmotic stress of ${Delta}$ Bbhog1 mutants could be alleviated by a highertemperature (32°C) (Fig. 1E), suggesting that a similarmode of response to hyperosmotic conditions and an elevatedtemperature may be present in B. bassiana. In addition, twostrong bands were detected using HOG1 antibody in mycelial extractsof the B. bassiana wild-type strain, but no signal was observedin Bbhog1 disruption mutants (see Fig. 1SD in the supplementalmaterial), demonstrating that both of the bands are relatedto HOG1 MAPK. This phenomenon has also been observed for Botrytiscinerea (29). The relationship of these two bands is unclear.

Under osmotic stress conditions, fungal cells often accumulatehigh levels of a compatible solute to maintain cellular turgor(33). The HOG1 pathway is required for regulation of the accumulationof some carbohydrates to increase osmolarity in several fungalspecies. In S. cerevisiae, hyperosmotic conditions induce anincrease in the level of intracellular glycerol (36). In thisprocess, HOG1 MAPK is involved in glycerol synthesis by regulatingexpression of the glycerol synthesis genes GPD1 and HOR2 (20).In C. albicans, glycerol accumulation under hyperosmotic stressconditions is also partially controlled by this pathway (44).However, in the phytopathogenic fungus M. grisea, it is arabitoland not glycerol that is the major compatible solute for adaptationto acute and chronic hyperosmotic stress. The accumulation ofglycerol and turgor generation in appressoria are not alteredby disruption of the HOG1 MAPK gene osm1 (12). Disruption ofBbhog1 in B. bassiana resulted in a significant decrease inerythritol and arabitol accumulation under both normal and hyperosmoticstress conditions (Fig. 2). Thus, HOG1-mediated carbohydrateaccumulation varies among fungal species.

Although inactivation of Bbhog1 did not result in a measurabledefect in the growth of B. bassiana under normal conditions,a significant reduction in conidiation in agar plates was observedfor Bbhog1 disruption mutants. This phenomenon was also observedfor the rice blast fungus M. grisea, in which disruption ofthe osm1 gene (a homologue of HOG1) leads to a dramatic reductionin conidial production in standard medium (12). Furthermore,a different MAPK in the corn leaf pathogen Cochliobolus heterostrophus(CHK1, an ortholog of FUS3/KSS1) was required for conidiation(31). However, the mechanism of conidiation regulated by MAPKsis poorly understood. In several filamentous fungi, the heterotrimericG protein signaling pathway is involved in conidiation, as wellas morphogenesis and pathogenesis (3, 16, 30). The regulatoryG protein signaling gene Bbrgs1 is also required for conidiationin B. bassiana (15). Although G proteins are generally upstreamof MAPK pathways, it is not yet known whether conidiation ofB. bassiana mediated by Bbrgs1 occurs through activation ofMAPKs. Further experiments are needed to elucidate the crosstalk between MAPKs and G protein signal pathways for regulationof conidiation.

Accumulating data have shown that HOG1 kinases are involvedmainly in stress responses. However, there is little evidencecorrelating HOG1 kinases with the virulence or pathogenicityof pathogens. In the phytopathogenic fungus M. grisea, disruptionof the osm1 gene homologous to the HOG1 gene does not alterthe virulence, and ${Delta}$ osm1 mutants are fully pathogenic (12). Incontrast, MgHog1 disruption mutants of the plant pathogen M.graminicola do not infect wheat leaves due to impaired initiationof infectious germ tubes (35). Either hyperactivation or silenceof a HOG1 protein, ThHog1, in T. harzianum results in stronglyreduced antagonistic activity against the plant pathogens Phomabetae and Colletotrichum acutatum (11). Here we found that Bbhog1was an important virulence determinant of B. bassiana and influencedat least three aspects of infection, spore viability, adherenceto the insect cuticle, and appressorium formation.

The rate of conidial germination is an important indicator ofvirulence in entomopathogenic fungi and is to some degree correlatedwith virulence (2, 26, 43, 46). It was demonstrated previouslythat physical manipulation of growth conditions can significantlymodify the endogenous compounds synthesized and channeled intothe propagules of fungi (33, 38). Optimization of erythritoland glycerol contents in conidia of entomopathogenic fungi,such as B. bassiana, Metarhizium anisopliae, and Paecilomycesfarinosus, has increased the germination rate and improved thepathogenicity at a low relative humidity (22, 23, 33). A reductionin the spore viability of ${Delta}$ Bbhog1 mutants may be due to lowerlevels of some compatible solutes in mature conidia comparedto the levels in the wild-type strain (Fig. 2).

Cuticle attachment has been considered a reliable determinantof pathogenicity (2, 24, 55). Fungal cell attachment to thecuticle may involve specific receptor-ligand and/or nonspecifichydrophobic and electrostatic mechanisms (4, 5, 13). Hydrophobinsare generally thought to be ubiquitous proteins of fungal walls.These proteins form an outer layer of hyphae and conidia andplay a role in a broad range of processes in the growth anddevelopment of filamentous fungi. They are involved in the formationof aerial structures and in the attachment of hyphae to hydrophobicsurfaces (9, 56). For instance, the hydrophobin MPG1 of M. griseadirects formation of a rodlet layer on conidia, which contributesto the hydrophobicity of the surface. A ${Delta}$ mpg1 mutant showed reducedinfectivity and an inability to form appressoria (50). Recently,two hydrophobins, Hyd1 and Hyd2, were also isolated from B.bassiana, and Hyd2 has been identified as the major componentof the rodlet layer in the aerial conidium surface (9). Herewe found that transcript levels of hyd1 and hyd2 were markedlyreduced in a ${Delta}$ Bbhog1 mutant when the fungal cells were grownin the presence of insect cuticle (Fig. 6), suggesting thatBbhog1 may influence the expression of some genes associatedwith hydrophobicity or adherence. In addition, hyd2 is expressedmore strongly than hyd1 both in wild-type strain Bb0062 andin a ${Delta}$ Bbhog1 mutant, which is not consistent with the data describedpreviously (9). The difference may be due to genetic diversityof different isolates.

Like the conidia of many plant-pathogenic fungi, conidia ofentomopathogenic fungi, such as M. anisopliae and B. bassiana,often differentiate to form appressoria on the host surface.The formation of appressoria is pivotal for penetrating thehost cuticle and establishing a pathogenic relationship withthe host (10). Consequently, impairment of appressorium formationreduces the virulence of the fungal pathogen to host. It hasbeen demonstrated that attachment is required to trigger theappropriate stimuli necessary to initiate appressorium development(50). Therefore, we may reasonably speculate that impairmentof appressorium formation in ${Delta}$ Bbhog1 mutants is partially dueto the reduction in attachment which is to a certain extentmediated by hydrophobins.

ACKNOWLEDGMENTS

This work was supported by grants from the Ministry of Scienceand Technology of China (grants 2009CB118904 and 2006AA10A212),the Natural Science Foundation of China (grant 30471174), andthe Program for the First Excellent Talents of University inChongqing.

FOOTNOTES

* Corresponding author. Mailing address: Key Laboratory of Biotechnology and Crop Quality Improvement of Ministry of Agriculture of China, Biotechnology Research Center, Southwest University, Chongqing 400716, People's Republic of China. Phone and fax: 86-23-68250515. E-mail: peiyan3{at}swu.edu.cn

Published ahead of print on 10 April 2009.

Supplemental material for this article may be found at http://aem.asm.org/.

REFERENCES

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