Regulation of Morphogenesis and Biocontrol Properties in Trichoderma virens by a VELVET Protein,Vel1

Mycoparasitic strains of Trichoderma are applied as commercial biofungicides for control of soilborne plant pathogens. Although the majority of commercial biofungicides are Trichoderma based, chemical pesticides, which are ecological and environmental hazards, still dominate the market. This is because biofungicides are not as effective or consistent as chemical fungicides. Efforts to improve these products have been limited by a lack of understanding of the genetic regulation of biocontrol activities. In this study, using gene knockout and complementation, we identified the VELVET protein Vel1 as a key regulator of biocontrol, as well as morphogenetic traits, in Trichoderma virens, a commercial biocontrol agent. Mutants with mutations in vel1 were defective in secondary metabolism (antibiosis), mycoparasitism, and biocontrol efficacy. In nutrient-rich media they also lacked two types of spores important for survival and development of formulation products: conidia (on agar) and chlamydospores (in liquid shake cultures). These findings provide an opportunity for genetic enhancement of biocontrol and industrial strains of Trichoderma, since Vel1 is very highly conserved across three Trichoderma species.Trichoderma-based formulation products account for about 60% of the biofungicide market (35). Despite the use of Trichoderma-based biofungicides as an alternative and additive to chemical fungicides, the applications of these preparations are limited because their efficacy is lower than that of fungicides. A lack of understanding of the regulation of biocontrol has limited progress in enhancing the competitiveness of these fungi through genetic manipulation of desired traits. The success of a biocontrol agent also depends on the ability of researchers to develop an effective formulation based on active propagules that survive under the conditions that occur in nature and are effective against the target pathogens. Trichoderma spp. produce two types of propagules, conidia during solid-state fermentation and chlamydospores during liquid fermentation. Both types are used in commercial formulations depending on the growth conditions (17, 35). Thus, understanding how the two sporulation pathways are controlled is critical for obtaining an improved, balanced formulation product. Identification of a global regulator of morphogenesis and biocontrol properties (such as antibiosis and mycoparasitism) would provide an opportunity to manipulate the morphogenetic and antagonistic traits, leading to wider commercial acceptance of Trichoderma spp. in the long run.Trichoderma virens is a commercially formulated biocontrol agent that is effective against soilborne plant pathogens, such as Rhizoctonia solani, Sclerotium rolfsii, and Pythium spp.; its major direct mode of action is antibiosis and mycoparasitism (20, 36). This species has also been used as a model system for studies of biocontrol mechanisms, and the genome has recently been sequenced (http://genome.jgi-psf.org/Trive1). The role of beta-glucanases, chitinases, and proteases in biocontrol has been reported previously (2, 8, 29). Some strains of T. virens (designated Q strains) produce copious amounts of the antibiotic gliotoxin that is involved in biocontrol (10, 12, 39). In an attempt to identify regulators of biocontrol properties, the role of a mitogen-activated protein kinase (MAPK) pathway was studied previously (22, 24). Deletion of the TmkA/Tvk1 MAPK gene resulted in derepressed conidiation and different biocontrol behavior for two strains of T. virens; Mukherjee et al. (24) noted the reduced ability of these mutants to parasitize the sclerotia of S. rolfsii and R. solani, while Mendoza-Mendoza et al. (22) found that deletion of this MAPK gene improved the biocontrol activity of T. virens against R solani and P. ultimum. The production of secondary metabolites was not affected by deletion of this gene. To date, no gene that regulates the balance between conidiation or chlamydospore formation, secondary metabolism, and antagonistic or biocontrol properties has been identified in any Trichoderma sp.The Vel1 VELVET protein has been shown to be a regulator of morphogenesis and secondary metabolism in some filamentous fungi (6). In Aspergillus nidulans, VeA physically interacts with VelB and the regulator of secondary metabolism LaeA to form a complex that regulates secondary metabolism and sexual reproduction (3). Deletion of the VeA gene leads to an increase in asexual development (conidiation in the dark) and reduced biosynthesis of sterigmatocystin (the product of a polyketide synthetase [PKS]) and penicillin (the product of a nonribosomal peptide synthetase [NRPS]), while it reduces and delays sexual reproduction (15, 16). VeA is also required for the production of sclerotia and for aflatoxin biosynthesis in Aspergillus parasiticus (7). Deletion of the VeA gene in Neurospora crassa, like deletion of the VeA gene in A. nidulans, results in deregulated conidiation, while in Acremonium chrysogenum, loss of VeA leads to increased hyphal fragmentation and reduced cephalosporin production (4, 9). Deletion of the VeA gene in Fusarium verticilliodes resulted in a loss of hydrophobicity and an increased macroconidium-to-microconidium ratio; these defects could be restored by growing the organism on osmotically stabilized media (18). The mutants were also defective in production of the mycotoxins fumonisin and fusarin (25).To test the hypothesis that Vel1 is a global regulator of gene expression in T. virens, we examined the functions of Vel1 in this organism by using gene knockout and complementation. Here we report that in addition to a role in conidiation and secondary metabolism, Vel1 also regulates conidiophore aggregation, chlamydosporogenesis, mycoparasitism, and biocontrol efficacy in T. virens. Thus, we identified the first master regulator of morphogenesis and antagonistic properties in this economically important fungus.