Figures
Abstract
In Ascomycota the protein methyltransferase LaeA is a global regulator that affects the expression of secondary metabolite gene clusters, and controls sexual and asexual development. The common mycoparasitic fungus Trichoderma atroviride is one of the most widely studied agents of biological control of plant-pathogenic fungi that also serves as a model for the research on regulation of asexual sporulation (conidiation) by environmental stimuli such as light and/or mechanical injury. In order to learn the possible involvement of LAE1 in these two traits, we assessed the effect of deletion and overexpression of lae1 gene on conidiation and mycoparasitic interaction. In the presence of light, conidiation was 50% decreased in a Δlae1 and 30–50% increased in lae1-overexpressing (OElae1) strains. In darkness, Δlae1 strains did not sporulate, and the OElae1 strains produced as much spores as the parent strain. Loss-of-function of lae1 also abolished sporulation triggered by mechanical injury of the mycelia. Deletion of lae1 also increased the sensitivity of T. atroviride to oxidative stress, abolished its ability to defend against other fungi and led to a loss of mycoparasitic behaviour, whereas the OElae1 strains displayed enhanced mycoparasitic vigor. The loss of mycoparasitic activity in the Δlae1 strain correlated with a significant underexpressionn of several genes normally upregulated during mycoparasitic interaction (proteases, GH16 ß-glucanases, polyketide synthases and small cystein-rich secreted proteins), which in turn was reflected in the partial reduction of formation of fungicidal water soluble metabolites and volatile compounds. Our study shows T. atroviride LAE1 is essential for asexual reproduction in the dark and for defense and parasitism on other fungi.
Citation: Aghcheh RK, Druzhinina IS, Kubicek CP (2013) The Putative Protein Methyltransferase LAE1 of Trichoderma atroviride Is a Key Regulator of Asexual Development and Mycoparasitism. PLoS ONE 8(6): e67144. https://doi.org/10.1371/journal.pone.0067144
Editor: Gustavo Henrique Goldman, Universidade de Sao Paulo, Brazil
Received: March 24, 2013; Accepted: May 14, 2013; Published: June 24, 2013
Copyright: © 2013 Aghcheh et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This study was supported by a grant of the Austrian Science Fund to CPK:P 21266. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Comparison of the genomic inventory of T. reesei, T. atroviride and T. virens identified mycotrophy (i.e. successful feeding on either living or killed fungi) as the innate nature of the genus [1]. This lifestyle involves a combination of traits such as host recognition, attachment to and sometimes coiling around the host hyphae, and the secretion of antibiotic metabolites and cell-wall-degrading enzymes [2]–[4]. The molecular mechanisms involved have been studied mainly with regards to the possible involvement of hydrolytic enzymes (chitinases, glucanases and proteases) and secondary metabolites (gliotoxin, peptaibols, 6-pentyl-2H-pyran-2-one [6PP]) in antagonism, and of heterotrimeric G proteins and their receptors in sensing of host signals [5]. Mukherjee and Kenerley [6] reported the developmental regulator VEL1 (an orthologue of the Aspergillus nidulans veA, which encodes a conserved global regulator of development and secondary metabolism) [7], [8] regulates mycoparasitism that in T. virens.
In A. nidulans, most of the effects of VeA depend on the formation of a trimeric protein complex consisting of VeA, VelB and LaeA [9]. The latter protein, a putative S-adenosylmethionine-dependent methyltransferase, was originally described as a global regulator of secondary metabolism in several Aspergillus spp. [10], [11], and later on shown to be also required for the biosynthesis of secondary metabolites in the industrially applied fungus Penicillium chrysogenum (e.g. penicillin) and the phytopathogenic fungi Fusarium fujikuroi, F. verticillioides and Cochliobolus heterostrophus, respectively [12]–[15]. Further evidence emerged that LaeA also controls numerous developmental events in fungi, such as conidiation and fruiting body formation [12]–[14]. In plant and human pathogenic fungi, LaeA has also been demonstrated to be a virulence factor [13], [14], [16], [17].
We have recently studied the function of LAE1, the LaeA orthologue of Trichoderma reesei [18], [19]. Interestingly, in this fungus that has specialized to saprotrophic growth on pre-decayed wood, LAE1 is a major regulator for the expression of cellulases and hemicellulases that are required for feeding on this substrate [18], [19]. One may thus hypothesize that LAE1 controls different strategies to aid the fitness of the fungus in its environment.
As emphasized above, mycotrophy is the innate nature of T. atroviride [1]. In this work we have therefore tested the hypothesis that in T. atroviride LAE1 may be involved in mycoparasitic interaction of this species.
Materials and Methods
Fungal Strain and Culture Conditions
Trichoderma atroviride P1 (ATCC 74058) [20] was used throughout this work. For selected experiments, T. atroviride IMI 206040, and its blr1 and blr2 deletion mutants [21] were also used. It was grown on PDA (Difco™ potato-dextrose-agar) plates at 25°C. Rhizoctonia solani C.P.K. 3753, Botrytis cinerea C.P.K. 4679 and Alternaria alternata C.P.K 3737 were grown on 2% (w/v) potato dextrose agar (PDA) under 12 h cycles of light and darkness at 25 C.
Escherichia coli JM109 (Promega, Madison, Wisconsin) was used for plasmid construction and amplification.
Manipulation of lae1 Gene Expression in T. atroviride
To obtain mutants not expressing lae1, the 1.2 kb lae1 coding region was replaced by the hygromycin B phosphotransferase (hph) gene from E. coli under Trichoderma 5′ and 3′ regularory signals [22]. To this end, 1.3 and 1.2 kb of the up- and downstream non-coding region of lae1 were amplified using the primer pairs Patro_FW_ConMeth_ApaI (5′-TGGGCCCCATCATATCTGCTACTTGGCTC-3′)/Patro_Rev_ConMeth_XhoI (5′-TCTCGAGCGAGTATGGCGAGTCCTATAG-3′), and Tatro_FW_ConMeth_XhoI (5′-TCTCGAGGACCTAACCCGCATTACTTTG-3′)/Tatro_Rev_ConMeth_SmaI (5′- TCCCGGGCATCAAGAGCGTAGCACTG-3′) respectively. The two resulting PCR fragments were digested with ApaI/XhoI (upstream region) and SmaI/XhoI (downstream region), dephosphorylated and ligated into pBluescript SK(+) (Stratagene, La Jolla, California), previously cut with ApaI/SmaI, followed by the insertion of the 2.4 kb XhoI/SalI fragment of hph casette into the XhoI site resulting in pRKA_D 42103hph.
Vector pRKA_OE41617hph, which bears the T. reesei lae1 gene under the constitutive expression signals of tef1 [23] was used to generate lae1 overexpressing strains of T. atroviride.
Transformation of Trichoderma
Transformation has been carried out as described by Guangtao et al [24]. The strains were purified twice to obtain mitotic stability, and integration of the expression cassettes was verified by PCR analysis (Fig. S1).
Assay for Growth and Conidiation
Cultures were grown on PDA at 25°C in a Sanyo incubator containing a Philips-master light source (TLD-15 W/840), either with illumination (12 hour cycles of light and dark; 1100 [±30] lux, 30 cm distance) or in full darkness (dark conditions), as specified. To this end, each plate was inoculated with a mycelial plug (5 mm diameter) taken from the edge of a 3-day-old non-sporulating plate. Three replica were done for each treatment. Conidia were harvested by gently rubbing them off in an equal volume of physiologically salt (0.1%, w/v, Tween and 0.8% w/v NaCl ), filtering through glass wool, and centrifugation (5000×g, 10 min). The conidia were then suspended in 2.5 g/l phytagel (Phytagel™, SIGMA, Steinheim, Germany), mixed and their transmission measured at 590 nm in a Biolog standard turbidimeter. The number of conidia was calculated using a calibration curve with T. reesei conidia.
Phenotype Microarrays
Growth of T. atroviride P1 and the lae1 mutant strains derived from it on 95 carbon sources and water was investigated using Biolog® phenotype microarrays as described by Friedl et al. [25]. One-way or main-effect analyses of variance (ANOVAs) were used to compare the growth of selected strains on individual carbon sources. Tukey's honest significant difference (Tukey HSD) test as implemented in STATISTICA 6.1 was used for post hoc comparisons to detect the contribution of each variable to the main effect of the F test resulting from the ANOVA. Only p-values <0.05 were considered as significant.
Assays for Fungal Antagonism
The ability of T. atroviride P1 and the respective recombinant mutants to antagonize and eventually parasitize other fungi was tested in dual confrontation assays on PDA plates as described earlier [26]. To study the ability to coil around hyphae of other fungi, 2% sucrose nutrient agar (SNA) (1.0 g/l KH2PO4, 1.0 g/l KNO3, 0.5 g/l MgSO4.7H2O, 0.5 g/l KCl, 0.2 g/l glucose, 0.2 g/l sucrose) was used, and the interaction monitored under the light microscope at the zone of interaction after 10, 14 and 21 days.
To test for a possible involvement of water soluble secreted compounds in antagonism, the T. atroviride strains were grown on PDA plates covered by cellophane. After the strains had covered approximately two thirds of the plates, the cellophane with T. atroviride was removed, and A. alternata, R. solani and B. cinerea were inoculated into the middle of these plates, and incubation continued until the respective controls reached 2 mm distance from the edge of the plates. The respective colony radius was monitored and compared to a control where the same fungus was pregrown.
Triggering Conidiation by Mechanical Injury
To induce conidiation by mechanical injury [21], T. atroviride and its mutants were grown at 25°C on plates containing either minimal medium, Vogel’s medium or SNA in darkness. After the mycelium had spread over the whole plate, it was cut with a sterile cold scalpel and incubated in darkness for additional 24–48 hrs.
Testing the Effect of Volatile Compounds (VOC)
T. atroviride P1 and its Δlae1 mutants were grown on PDA at 25°C for 72 h in periodic light and in darkness. Then the dishes were opened under sterile conditions and two dishes each arranged as an upside-down sandwich, in which the Δlae1 mutant plate was on the top. The sandwich was sealed with Parafilm tape and the incubation continued at 25°C for 8 days. Control plates (i.e. both plates contained the same strain) were always included.
The same test was applied when the effect of VOC on other fungi was tested. A. alternata, R. solani and B. cinerea were grown in the top plate.
Hydrogen Peroxide Sensitivity
To test for sensitivity of the Trichoderma strains against hydrogen peroxide, they were grown on PDA plates supplemented with 0, 0.5, 1, 5 and 20 mM of H2O2, and incubated until the time that the fungi reached the edge of the plates. Changes in radial growth were measured 3 times per day.
Assay for Cellulase Formation
The Trichoderma strains were grown in Mandels-Andreotti medium [27] containing 1% (w/v) carboxymethyl cellulose (CMC) as carbon source on 2% (w/v) agar plates. The inoculated plates were then incubated at 25°C for 3 days. Thereafter, they were incubated at 50°C for 18 hrs. The hydrolyzed cellulose was detected by staining with a 0.1% (w/v) Congo-Red solution, followed by subsequent washing with 1M NaCl. The hydrolysis of cellulose becomes visible by the bright halos around the fungal colony, and expressed as ratio of the diameter of the halo to that of the fungal colony. A ratio of 1 indicates absence of cellulase formation.
Quantitative PCR
Following RNA isolation (using the RNeasy plant kit, Promega) 5 µg of the total RNA was treated with DNAse (DNase I, RNase free; Fermentas) and reverse transcribed (RevertAid™ First Strand cDNA Kit, Fermentas) using a 1∶1 mixture of oligo-dT and random hexamer primers. All quantitative RT-PCR experiments were performed on a Bio-Rad (Hercules, CA) iCycler IQ. For the reaction the IQ SYBR Green Supermix (Bio-Rad, Hercules, CA) was prepared for 25 ml assays with standard MgCl2 concentration (3 mM) and a final primer concentration of 100 nM each. All assays were carried out in 96-well plates. Determination of the PCR efficiency was performed using triplicate reactions from a dilution series of cDNA (1; 0.1; 0.01; 0.001). Amplification efficiency was then calculated from the given slopes in the IQ5 Optical system Software v2.0. Primers, amplification efficiency and Tm values are given in Table S1. Expression of the reference gene tef1 was measured with both protocols for reference calculation. Expression ratios were calculated using REST© Software [28]. All samples were analyzed in at least two independent experiments with three replicates in each run.
Results
Identification of the LAE1 Orthologue of T. atroviride
We have recently identified LAE1 from T. reesei, and shown that it forms a supported clade with putative orthologues of T. virens and T. atroviride [18]. The annotation of the T. atroviride orthologue (Triat2∶302782; old number Triat1∶42103) was manually corrected (correct sequence deposited under NCBI GeneBank accession number KC174792). LAE1 is encoded by a 1328 nt ORF that is interrupted by 5 introns and encodes a putative 363 aa protein. The aa’s 110–205 specify the expected SAM-dependent methyltransferase domain (Pfam group PF13489).
Phenotype of T. atroviride LAE1 Mutants
To investigate the function of T. atroviride lae1, we prepared knock out- and overexpressing strains (see Materials and Methods). Several mitotically stable Δlae1 and OElae1 strains were obtained and verified by PCR (Fig. S1). Several Δlae1 strains and OElae1 strains bearing one additional copy were then investigated with respect to growth and conidiation. Strains bearing the same mutation (Δlae1 or OElae1 respectively; see below) displayed identical phenotypes. Despite several attempts we failed to introduce the wild-type lae1 copy into the Δlae1 strains. Two Δlae1 or OElae1 strains were thus selected for all further experiments, and gave essentially similar results (selected cases are shown in the supplementary information; see below). The Δlae1 strains showed a 25–30% reduced growth rate on plates with D-glucose or D-galactose as a carbon source, whereas growth of the OElae1 strain was the same as that of the parent strain (data not shown). Otherwise the mutants did not show any morphological differences from the parent strain.
LAE1 is Essential for Cellulase Formation in T. atroviride
In T. reesei lae1 is essential for growth on cellulose and expression of cellulase and hemicellulase genes in T. reesei [18]. In order to learn whether this is also the case in T. atroviride, we grew the strains on plates with carboxymethyl cellulose as the only carbon source and analyzed cellulase secretion by Congo red staining. Indeed, T. atroviride P1 exhibited a ratio of halo diameter vs colony diameter of 1.29 (±0.011), which was slightly enhanced in the OElae1 strain (1.47±0.036). The Δlae1 strain, however, yielded a value close to 1 (1.07±0.016) indicating no or only very little cellulase secretion (which was also reflected in the very small colonies). Thus the observed LAE1-dependent regulation of cellulase formation in T. reesei also extends to T. atroviride.
LAE1 Effects Conidiation in T. atroviride in a Carbon Source and Light/darkness Dependent Manner
The loss-of-function of lae1 of T. atroviride significantly affected the intensity of conidiation, albeit the effect differed in light and darkness (Figure 1): when cultivated on PDA in light, conidiation intensity was reduced by approximately 50% in the Δlae1 strain. Conidiation in the dark, however, was reduced to almost zero. The OElae1 strains, on the other hand, exhibited an increased conidiation density under illumination, whereas it displayed the same level of conidiation as the parent strain P1 in darkness (Figure 1).
(A) Quantitation of conidiation of the parent (P1), Δlae1-1 and OElae1 strains on PDA in light (white bars) and in darkness (full bars). Values are means of at least three independent biological experiments. Similar investigations with strain Δlae1-2 yielded values within ±8% of those of Δlae1-1. All values are statistically different by the students t-test (p<0.05).
Impairment of Conidiation in the T. atroviride Δlae1 Strain cannot be Rescued by Volatile Components from the Parent Strain
Conidiation in Trichoderma has been shown to be triggered by volatile compounds (VOC) from neighboring Trichoderma colonies [29]. We therefore surmised that the loss of conidiation in darkness could be due to a loss of the ability to form VOC. Consequently we tested whether VOC released by the parent strain of T. atroviride would rescue conidiation in the darkness in the Δlae1 mutant. However, this hypothesis had to be rejected: using an upside-down sandwich of two plates, in which the Δlae1 mutant was growing in the plate on the top and the parent strain P1 on the bottom, the Δlae1 strain maintained being unable to form conidia (shown for two mutants, Δlae1-1 and Δlae1-2 in Fig. S2).
There is no Cross Talk between LAE1 and the Two Blue Light Receptors BLR-1 and BLR-2
The significant effect of the Δlae1 mutation on conidiation in response to light prompted us to investigate a possible cross-talk between LAE1 and the two blue light receptors BLR-1 and BLR-2, which form the top of the cascade that signals the presence of light to T. atroviride [21]. However, their transcripts were equally abundant in the parent, OElae1 and Δlae1 strains (Figure 2 A) indicating that their expression is unaffected by lae1 modulation. Also lae1 was expressed at the same level in Δblr1 and Δblr2 mutants (Figure 2 B). Hence, lae1 and blr1/blr2 do not influence the expression of each other.
Vertical bars indicate the standard deviation (N ≥3). Expression of lae1, blr1 and blr2 was normalized to the expression of tef1. Relative gene expression is calculated as the ratio of the normalized expression in the mutant in –fold of that of the parent strain P1. None of the difference was found to be statistically relevant by students t-test (p>0.15).
LAE1 is also Required Triggering of Conidiation by Mechanical Injury
Conidiation in Trichoderma can also be induced by mechanical injury via generation of radical oxygen species (ROS) [21], [30]–[32]. We have therefore investigated if LAE1 is also required for conidiation triggered by mechanical injury in darkness. As shown in Fig. S3, mechanical injury resulted in conidiation only in the parent and OElae1 strain but not in the Δlae1 strain, and LAE1 therefore influences sporulation also when triggered by mechanical injury.
LAE1 is Required for Oxidative Stress Tolerance in T. atroviride
Wu et al. [14] recently showed LAE1 is necessary for the oxidative stress response in the plant pathogen Cochliobolus heterotrophus. To find out whether LAE1 is required for the response to oxidative stress in T. atroviride, we tested the effect of hydrogen peroxide on the T. atroviride parent, the Δlae1 and the OElae1 strain (Figure 3). The parent strain P1 proved to be resistant to hydrogen peroxide up to a concentration of at least 5 mM, and displayed about 60% of its original growth rate at 20 mM. Similar data were obtained for the OElae1 mutant. The Δlae1 mutant, however, only showed 64% of its growth rate at 5 mM hydrogen peroxide, and exhibited only 39% of its original growth rate at 20 mM. Thus we conclude that LAE1 is partially involved in the defense against oxidative stress in T. atroviride.
Growth on PDA was monitored in intervals of 6–12 hrs for a period of up to 100 hrs. Growth rates were calculated from the phase where the increase in colony diameter vs time was linear and were calculated as mm/h. In the figure, the growth rate of the strain in the absence of hydrogen peroxide was set to 100%, and all other growth rates related to it. Data are means from at least 8 independent biological replicas.
LAE1 is Essential for T. atroviride Antagonism and Defense against Other Fungi
To analyze whether LAE1 would be relevant for the mycoparasitic activities of T. atroviride, we confronted the parent strain P1, and the Δlae1 and OElae1 mutants on plates with three standard model fungi used for antagonism experiments (i.e. Alternaria alternata, Rhizoctonia solani, and Botrytis cinerea). Their growth was monitored over the time in the presence and absence of T. atroviride and its lae1 mutants (Fig. S4 A). As can be seen, all three test fungi were initially able to grow in the presence of T. atroviride and its lae1 mutants at the same rate as in their absence, but stopped their growth when getting close (1–2 mm) to T. atroviride (plates for the second mutant strains shown in Fig S4 B ) This was about 50 h for all three fungi when confronted by strains P1 and OElae1, whereas it occurred in the Δlae1 mutant only after 65 hrs with R. solani and B. cinerea and 85 hrs with A. alternata. Correspondingly, the final colony diameter of these three fungi was higher when confronted with the Δlae1 mutant than with P1 or OElae1, which also corresponded with a smaller colony diameter of the Δlae1 mutant strain. However, in addition to this slower growth of the Δlae1 strain, visual examination of the plates (Figure 4; Fig. S4B) showed that it also failed to overgrow and feed on the tested plant pathogenic fungi, and in contrast its growth was suppressed by them. In confrontation with R. solani, T. atroviride Δlae1 almost completely also lost its ability to conidiate. In contrast, the mycoparasitic vigor of the OElae1 strain was even increased, and we particularly noted an increased formation of coils around mycelia of R. solani (data not shown).
Left plates are photographed from the backside, right plates are photographed from top. (B) Test for production of WSC: T. atroviride parent strain, and the Δlae1-1 and OElae1 mutants were grown on PDA agar covered by cellophane, and then removed and Alternaria alternata (Aa), Rhizoctonia solani (Rs) and Sclerotinia sclerotiorum (Ss) placed on these plates. The plates were photographed after 7 days.
LAE1 Regulates the Formation of Extracellular Antifungal Components
The dependence of mycoparasitism and antagonism on LAE1 prompted us to test whether this could be due to an involvement of LAE1 in the formation of water soluble extracellular compounds (WSC) that aid in the inhibition of growth of the plant pathogenic fungi. To this end, we grew T. atroviride P1, and its Δlae1 and OElae1 mutants on plates covered by cellophane. After T. atroviride had covered most of the plates, the fungal mycelium and the cellophane were removed, and A. alternata, R. solani and B. cinerea inoculated into the middle of these plates. As shown in Figure 4 B, the three fungi failed to grow on the plates on which the parent strain or the OElae1 mutant had been pregrown, whereas they were still able to grow on plates on which the Δlae1 had been grown. Yet the latter growth was nevertheless clearly slower then on plates not precolonized by Trichoderma. Consequently we conclude that LAE1 contributes to but is not essential for the formation of extracellular antifungal compounds by T. atroviride.
Loss of Function of lae1 Decreases the Expression of Mycoparasitism-associated Genes
In order to learn whether loss of function of LAE1 would be due to a decreased expression of genes known to be associated with mycoparasitism, we have investigated the expression of 13 genes that were recently shown to be strongly upregulated during interaction of T. atroviride with R. solani [26]. These were two GH16 ß-1,3/1,4-glucanases, two aspartyl proteases, two subtilisin proteases, two polyketide synthases, two C-type lectins, one cyanovirin-type lectin and two small cysteine-rich secreted proteins. Figure 5 A shows that indeed 8 of these 13 genes were significantly underexpressed in the Δlae1 mutant. Interestingly, the expression of none of these genes was enhanced in the OElae1 strain, implying that the superior mycoparasitic activity of this mutant (vide supra) cannot be due to the increased expression of any of these genes. Nevertheless, the data demonstrate that in T. atroviride LAE1 is necessary for the expression of some of the genes encoding extracellular hydrolases, secondary metabolites and proteins that putatively interact with other organisms.
Ratios of expression between the parent strain and either the Δlae1-1 (blue bars) or the OElae1 strain (red bars) are shown. The * and Δ symbols indicate p<0.05. Genes are given by their Triat2 number: 34350, GH16 ß-glycosidase; 144038, aspartyl protease; 160930, aspartyl protease; 128831, C-type lectin; 132795, C-type lectin; 134073, cyanovirin-N; 156014, GH16 ß-1,3/ß-1,4-glucanase; 85006, polyketide synthase (PKS); 53332, small cystein-rich secreted protein (SSCP); 131539, SSCP; 145909, subtilisin-like protease; 149951, subtilisin-like protease. Data are plotted relative to wild-type (P1) control. (B) Expression of the lipoxygenase gene in the Δlae1 and OElae1 strains in light (L) and darkness (D). (C) Growth of A. alternata in the presence of VOC from the T. atroviride parent strain and the lae1 mutants. Only R. solani is shown but essentially similar results were also obtained with R. solani and B. cinerea. Single plates from several (N>4) experiments are shown.
LAE1 Affects γ-pentyl-pyrone Formation by T. atroviride
One of the known antifungal metabolites produced by T. atroviride is 6PP [33], [34], which exhibits an intensive coconut smell. During the antagonism experiments, we observed this aroma in plates of the parent strain and even more in plates of the OElae1 strain of T. atroviride, whereas it was absent from those of the two Δlae1 strains and only appeared faintly when this culture initiated its sporulation in the presence of light. To experimentally test whether LAE1 indeed regulates 6PP formation, we examined the expression of the lipoxygenase gene (Triat2∶33350) that is putatively involved in 6PP formation [3], and which is strongly upregulated during mycoparasitism [26]. In fact, the lipoxygenase transcript was strongly down regulated in Δlae1, both in ambient light and in dark. It was also upregulated in OElae1 in the dark but not in light (Figure 5 B).
To test whether reduced 6PP formation would contribute to the reduced antagonistic activity in the T. atroviride Δlae1 strain, we tested the effect of VOC from the parent strain, the OElae1 and the Δlae1 strain on growth of the test fungi. The data show that VOC indeed reduce the growth of R. solani and also of A. alternata (data not shown), but only partially, and that this effect is much weaker in the Δlae1 strain (Figure 5 C).
Discussion
The putative protein methyltransferase LaeA is still an enigmatic protein: it has originally been identified as a regulator of secondary metabolite (aflatoxin) biosynthesis [10], but subsequently was found to have – among other traits – also key functions in development: as an example, deletion of the laeA gene in A. fumigatus and A. flavus reduces conidiation [16], [35]. In P. chrysogenum and in A. nidulans, this impairment of asexual sporulation is seen both in light as well as in darkness [12], [19], whereas in C. heterostrophus, the Chlae1 mutant was relieved from repression of conidiation in the dark and produced numbers of conidia similar to wild-type in light [14]. In T. reesei, whose sporulation is not enhanced by light [18], [36], formation of conidia is reduced to almost zero in both light and darkness. In the present study, we found that the T. atroviride Δlae1 mutant fail to conidiate in the dark on all carbon sources, while conidiation – which is stimulated by light [30], [31], [37] - was only reduced by 50% in light. Thus, while LaeA/LAE1 all affect asexual sporulation, the necessity for a functional LAE1 in T. atroviride prevails predominantly in darkness and appears to be partially counteracted by light, which is a unique case in the fungi studied so far.
One special trait of Trichoderma conidiation is that it can be induced by mechanical injury of the mycelium [21], [30]–[32]. The present results showed that injury-triggered sporulation of T. atroviride in the dark was also dependent on LAE1 function, as no conidia were formed in its absence. Mechanical injury has been shown to be triggered by an oxidative stress response caused by NADPH oxidase-dependent production of radical oxygen species (ROS), for which the proteins NOX1 and NOXR are essential [32]. We have not tested whether the expression of nox1 and noxR is affected by LAE1 loss-of-function in T. atroviride (the T. reesei orthologues are not) [19] but tested whether – as in C. heterostrophus [14] – the Δlae1 strain is affected in its sensitivity to oxidative stress provoked by hydrogen peroxide. While we found that this indeed the case, the reduction of resistance against hydrogen peroxide was not complete and required much higher concentrations than in C. heterostrophus [14]. We therefore conclude that – even in the absence of lae1 function - T. atroviride can still respond to oxidative stress. The complete loss of conidiation upon mechanical injury in the Δlae1 strain must therefore be due to a requirement for LAE1 by other components needed for this process.
One of them could be VOC formation: sporulation by T. atroviride has been shown to be triggered by VOC from other Trichoderma colonies [29], and Roze et al. [38] showed that in A. parasiticus, the Velvet A protein VeA is required for production of VOC that mediates asexual conidiation and sclerotia formation. Because of the known interaction of VeA with LaeA [8], [9], which has also been shown in T. reesei [19], we tested whether LAE1 would be involved in the stimulation of T. atroviride sporulation by VOC. However, VOC from the parent strain were unable to overcome the reduced conidiation in Δlae1. Thus, either the effect of VeA on induction of sporulation is independent of LaeA (e.g. in P. chrysogenum, the VeA and LaeA orthologues PcVelA and PcLaeA have different and independent roles in asexual development) [12], or this process is differentially regulated in A. parasiticus and T. atroviride.
The most striking and not yet reported phenotype of loss-of-function of LaeA is that the T. atroviride Δlae1 strain had completely lost its mycoparasitic ability, and also the ability to defend itself against other fungi. This is similar to data that have been reported for Δvel1 strains of T. virens, suggesting that mycoparasitism is indeed controlled by the VEL1/LAE1/VEL2 (VeA/LaeA/VelB) complex [8], [9]. We should like to stress that lae1 and vel1 are so far the only genes that have been identified as global regulators of Trichoderma antagonism, and whose loss-of-function is not compromised by severe growth defects: deletion or silencing of other genes, such as those encoding G-proteins or their receptors, while also leading to impaired mycoparasitic activity, also caused significant reductions in the growth rate of Trichoderma [5] and it is therefore difficult to assess whether their effect on mycoparasitism is direct or indirect. Although the T. atroviride Δlae1 strains showed some reduction of growth on some carbon sources, the effects did not exceed ±30% of that of the parent strain under conditions of antagonism with the test fungi, and particularly the hyphal morphology was not significantly altered (data not shown). We therefore do not believe that the loss of antagonistic abilities could be solely due to this fact.
Interestingly, qPCR analyses showed that this loss of mycoparasitic ability correlated with a loss of expression of genes encoding cell wall hydrolases (GH16 glucanases), secondary metabolites (PKS), and proteins supposed to mediate hyphal contact to the host (lectins, SSCPRs). This would be in excellent agreement the current view of mechanism of Trichoderma mycoparasitism [1]. However, none of these genes displayed enhanced expression in the OElae1 strain, and the superior mycoparasitic activity in OElae1 strains thus remains unexplained. We have recently observed that overexpression of lae1 even converts other Trichoderma spp. that exhibit only weak antagonistic activities, into vigorous mycoparasites (R.A. Karimi, M. Marzouk and I.S. Druzhinina, unpublished data). LAE1 therefore must act at a target that is central to the mycoparasitic response that still awaits identification.
Work on LaeA and its orthologues in several Aspergilli, but also in P. chrysogenum, Fusarium fujikuroi, F. verticillioides and C. heterostrophus has consistently proven that it regulates secondary metabolism [12]–[14], [16], [17], [35]. However, only a few genes of secondary metabolism were affected by a loss of function of lae1 in T. reesei [19], suggesting that the function of LAE1 may have diverged in this genus. The present investigation with T. atroviride supports this view: while some of the secondary metabolism genes that have recently been shown to be upregulated during antagonism of T. atroviride against R. solani [26] were significantly underexpressed in the Δlae1 mutant, there was a less strong effect of LAE1 on the formation of inhibitory WSC and VOC, thus implying that the Δlae1 strain still can form WSC and VOC. Whether this is due to a decreased expression of several genes, or the complete blockage of expression of some of them remains to be determined. One must also bear in mind that the tests for WSC and VOC formation depends on the prior cultivation of T. atroviride in the absence of its prey, and it is possible that stronger effects may become apparent when the formation of these components is investigated under confrontation conditions. Yet it is clear from these studies that the lack of mycoparasitic activity in the Δlae1 strain cannot be explained by the observed changes in the expression of its secondary metabolism genes.
The present findings that LAE1 regulates the antagonistic and defensive reaction of the mycoparasite T. atroviride, is a further example of involvement of this protein in a specific response of a fungus to the environment. A similar conclusion has also been drawn by Sarikaya Bayram et al. [39], i.e. that LaeA is involved in the protective as well as the nutritional function for preparing the next generation for future life. Such a role would be in excellent agreement with an epigenetic function of LaeA/LAE1 [40], which however so far is only a speculation.
Supporting Information
Figure S1.
Construction and proof for T. atroviride OElae1 and Δlae1 strains: (A) constructs used to disrupt lae1 (top) and to express it under the tef1 promoter (bottom). Numbers over the scheme indicate the size (in bp’s) of the promoter, ORF and terminator used; the number below the scheme of the nucleotide fragment amplified by the respective primers used. Bold numbers over the small bold arrows specify the primers used: 1, Patro_FW_ConMeth_ApaI; 2, Tatro_Rev_ConMeth_SmaI; 3, tef1SC; 4, TrLae1TermHind. For primer sequences see Materials and Methods of the main manuscript. (B) Identification of two Δlae1 strains among 8 transformants; the two arrows point to the 5 and 4 kb marker (M) band (from top); (C) Identification of OElae1 strains among 6 transformants and the P1 parent strain (track 7). The two arrows point to the 3 and 2.5 kb marker (M) band.
https://doi.org/10.1371/journal.pone.0067144.s001
(TIF)
Figure S2.
Lack of induction of conidiation in T. atroviride Δlae1 by volatiles from strains P1, OElae1 and Δlae1-1 and Δlae1-2 ( = control) in the presence of light (L) or in darkness (D).
https://doi.org/10.1371/journal.pone.0067144.s002
(TIF)
Figure S3.
Triggering of conidiation in the T. atroviride parent and lae1 mutant strains by mechanical injury. The mycelium of the strains shown was cut with a scalpel and incubated under periodic illumination condition for 24 hrs. Single plates from several (N>4) experiments are shown.
https://doi.org/10.1371/journal.pone.0067144.s003
(TIF)
Figure S4.
Effect of modulation of lae1 expression on the ability of T. atroviride to inhibit growth of R. solani, B. cinerea and A. alternata. A: (full ◊ indicate growth in the absence of T. atroviride; full Δ indicates growth in the presence of T. atroviride P1; full □ shows growth in the presence of T. atroviride OElae1; and × specifies growth in the presence of T. atroviride Δlae1. Full arrows define the time point where T. atroviride P1 and OElae1 stopped growth of the other fungi, whereas the dotted arrow specifies the time where T. atroviride Δlae1 strain stopped fungal growth. The solid and dotted horizontal line show the respective biomass formed by the three test fungi at the time of inhibition. B: confrontation of T. atroviride strain Δlae1-2 with R. solani, B. cinerea and A. alternata.
https://doi.org/10.1371/journal.pone.0067144.s004
(TIF)
Acknowledgments
The expert help of Lea Atanasova during this work is gratefully acknowledged. R.K.A. is also grateful to Michael Freitag (Oregon State University) and Levente Karaffa (University of Debrecen) for the generosity to perform some of the experiments used in this paper in their labs.
Author Contributions
Conceived and designed the experiments: RKA ISD CPK. Performed the experiments: RKA. Analyzed the data: RKA ISD CPK. Contributed reagents/materials/analysis tools: CPK ISD. Wrote the paper: CPK ISD.
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