Histopathological studies of sclerotia of phytopathogenic fungi parasitized by a GFP transformed Trichoderma virens antagonistic strain

The gfp gene from the jellyfish Aequorea victoria, coding for the Green Fluorescent Protein (GFP), was used as a reporter gene to transform a Trichoderma virens strain I10, characterized as having a promising biocontrol activity against a large number of phytopathogenic fungi. On the basis of molecular and biological results, a stable GFP transformant was selected for further experiments. In order to evaluate the effects of GFP transformation on mycoparasitic ability of T. virens I10, sclerotia of Sclerotium rolfsii, Sclerotinia sclerotiorum and S. minor were inoculated with the T. virens strain I10 GFP transformant or the wild type strain. Statistical analysis of percentages of decayed sclerotia showed that the transformation of the antagonistic isolate with the GFP reporter gene did not modify mycoparasitic activity against sclerotia. Sclerotium colonization was followed by fluorescent microscopy revealing intracellular growth of the antagonist in the cortex (S. rolfsii) and inter-cellular growth in the medulla (S. rolfsii, and S. sclerotiorum). The uniformly distributed mycelium of T. virens just beneath the rind of sclerotia of both S. rolfsii and S. sclerotiorum suggests that the sclerotia became infected at numerous randomly distributed locations without any preferential point of entry.     

Biocontrol of Sclerotinia sclerotiorum infection of cabbage by Coniothyrium minitans and Trichoderma spp.

Nine fungal isolates [Clonostachys rosea (1), Coniothyrium minitans (1), Trichoderma crassum (1), T. hamatum (4), T. rossicum (1) and T. virens (1)] were tested in two bioassays for their ability to degrade sclerotia and reduce apothecial production and carpogenic infection of cabbage seedlings. C. minitans LU112 reduced apothecial production in both bioassays, with T. virens LU556 significantly reducing apothecial production in the sclerotial parasitism assay. Both isolates also reduced sclerotial viability in this assay to 5% for C. minitans and 22% for T. virens. C. minitans LU112 and T. virens LU556 reduced the infection of cabbage seedlings in the pot bioassay 126 days after sowing but not after 147 days, partly due to ascospore cross-infection between treatments. C. minitans LU112, T. virens LU556 and T. hamatum LU593 as maizemeal-perlite (MP) soil incorporation and transplant potting mix incorporation were evaluated for their ability to control Sclerotinia sclerotiorum disease of cabbage in field experiments. S. sclerotiorum infection of cabbage was reduced by 46–52% and 31–57% by both C. minitans LU112 and T. hamatum LU593 as MP soil incorporations, respectively, in the two field experiments. T. virens LU556 MP soil incorporation and C. minitans LU112 and T. hamatum LU593 transplant potting mix incorporations reduced S. sclerotiorum disease in the first experiment but not in the second experiment. A commercial C. minitans LU112 formulation, C. Mins LU112 WG, also significantly reduced S. sclerotiorum disease by 59%. Soil incorporation of C. minitans and T. hamatum was shown to have potential to control S. sclerotiorum disease in cabbage.     

Comparative Antagonistic Properties of Gliocladium virens and Trichoderma harzianum on Sclerotium rolfsii and Rhizoctonia solani—its Relevance to Understanding the Mechanisms of Biocontrol

An isolate of Trichoderma harzianum which is less effective than G. virens in suppressing S. rolfsii and R. solani was compared with G. virens for various mechanisms of antagonism in vitro, viz., antagonism in dual culture/hyphal parasitism, parasitism of sclerotia and antibiosis. G. virens and T. harzianum were equally effective in parasitizing the hyphae of R. solani. Only T. harzianum parasitized the hyphae of S. rolfsii, and the two antagonists were comparable with respect to antibiosis on the test pathogens. However, G. virens readily parasitized the sclerotia of the test pathogens and was found to be more effective than T. harzianum in destroying the sclerotia. Under SEM, G. virens was found to colonize, penetrate, and sporulate inside the sclerotia of the test pathogens.Parasitism of sclerotia is suggested as the principal mechanism of biological control of S. rolfsii and R. solani by G. virens.     

Colonisation of sclerotia of Sclerotinia sclerotiorum by a fungivorous nematode

Aphelenchoides saprophilus nematodes fed on sclerotia, mycelium, and alginate-formulated pellets of Sclerotinia sclerotiorum, mycelium of Trichoderma harzianum, and mixed fungal cultures. As many as 500 nematodes were found inside individual sclerotia. Results suggest potential impacts of fungivory on S. sclerotiorum and its ecological interactions with plant hosts and biocontrol fungi.     

Pre-germinated conidia of Coniothyrium minitans enhances the foliar biological control of Sclerotinia sclerotiorum

The relatively slow germination rate of Coniothyrium minitans limits its control efficiency against Sclerotinia sclerotiorum. Pre-germinated conidia of C. minitans enhanced its efficiency significantly: in foliar experiments with oilseed rape, hyphal extension of S. sclerotiorum was inhibited by 68%, while formation of sclerotia was completely inhibited when pre-germinated conidia were applied.Revisions requested 27 July 2004; Revisions received 7 September     

Comparison of real-time PCR and microscopy to evaluate sclerotial colonisation by a biocontrol fungus

The biocontrol agent Trichoderma harzianum colonises sclerotia of the plant pathogenic fungus Sclerotinia sclerotiorum. Plating of sclerotia typically has been used to determine the incidence of mycoparasitism, but does not quantify the extent to which individual sclerotia are colonised. We developed a specific PCR primer/probe set for the green fluorescent protein (GFP)-transformant T. harzianum ThzID1-M3, which exhibited high precision and reproducibility. Quantitative real-time PCR was evaluated along with epifluorescence microscopy and image analysis to investigate dynamics of colonisation of sclerotia in non-sterile soil. Amounts of ThzID1-M3 DNA and S. sclerotiorum DNA from entire individual sclerotia were quantified using real-time PCR. Epifluorescence micrographs were captured from sclerotial thin-section samples, and GFP fluorescence from these was quantified using computer image analysis in order to estimate colonisation on a per-sclerotium basis. As determined by either method, ThzID1-M3 colonised sclerotia in soil, and both methods quantified colonisation dynamics over time. In a separate experiment, colonisation of sclerotia on agar plates was observed using confocal laser scanning microscopy to view the GFP-fluorescing hyphae of ThzID1-M3. This method, while highly labour-intensive, provided high spatial resolution of colonisation dynamics. Thus, each method has advantages: microscopy combined with image analysis can provide useful information on the spatial and temporal dynamics of colonisation, while real-time PCR can provide a more precise assessment of the extent of sclerotial colonisation over time and can more easily be used to sample entire sclerotia.     

Colonization of Sclerotinia sclerotiorum sclerotia by a biocontrol isolate of Trichoderma harzianum,and effects on myceliogenic germination

Sclerotia of Sclerotinia sclerotiorum were incubated on cultures of Trichoderma harzianum. Myceliogenic germination decreased by 50% within 1 day and continued to decrease over time. Quantitative PCR showed a decrease in Sclerotinia DNA for older sclerotia, but not fresh sclerotia. Trichoderma DNA increased and persisted inside older sclerotia but not fresh sclerotia.     

The Role of White Mold-Infected White Bean (Phaseolus vulgaris L.) Seeds in the Dissemination of Sclerotinia sclerotiorum (Lib.) de Bary

Sclerotinia sclerotiorum survived in infected seeds of white beans as dormant mycelium in testa and cotyledons. The rate of survival averaged 85 to 89% and did not change appreciably over a 3-year period. When the infected bean seeds were sown in soil or sand, 88 to 100% failed to germinate. The seeds that failed to germinate, depending on the severity of seed infection, were rotted by S. sclerotiorum. In place of each seed, 3 to 6 sclerotia were formed. A low percentage of these sclerotia germinated carpogenically with or without preconditioning, (2.5 and 11.5% respectively). Myceliogenic germination of sclerotia with and without preconditioning was 35.5% and 70.5% on water agar and 81.0% and 93.0% on glucose agar, respectively. Both, preconditioning and nonpreconditioned sclerotia which were scattered on soil surface could germinate myceliogenically and infect bean leaves by contact. It is therefore, concluded that dormant mycelia in the infected seeds play an important role notonly in dissemination of the fungus but also in epidemiology of the disease.     

Biological control of Sclerotinia disease by Aspergillus sp. on oilseed rape in the field

Sclerotinia sclerotiorum causes serious yield losses to many crops worldwide. Aspergillus sp. Asp-4, previously shown to inhibit germination of sclerotia of S. sclerotiorum in vitro and in the field, was evaluated in field trials for suppression of this pathogen on oilseed rape. Spray application of Asp-4 to the soil prior to sowing rice in a rice–oilseed rape rotation resulted in a significant reduction in incidence of Sclerotinia stem rot on oilseed rape compared with the non-treated control in two field trials. This application of Asp-4 also resulted in a significant reduction in germination of sclerotia relative to the non-treated control in these field trials, suggesting that this reduction in sclerotial germination led to disease control. Microscopic examination demonstrated that Asp-4 could effectively colonise external and internal portions of sclerotia of S. sclerotiorum in vitro. Incubation of Asp-4 with sterile sclerotial material induced production of β-glucanase and chitinase activities by this isolate; β-glucanase and chitinase being potentially capable of degrading the glucan and chitin polymeric components of sclerotia. Incubation of Asp-4 with sterile sclerotial material also resulted in a significant reduction in dry weight of this sclerotial material relative to the non-treated control in 96?h in vitro experiments. Experiments reported here indicate that Aspergillus sp. Asp-4 has promise as a biological control agent for S. sclerotiorum on oilseed rape. Experiments reported here suggest that disease control results from inhibition of germination of sclerotial resting structures due to mycoparasitic colonisation by Asp-4.     

Mycoparasitism by Coniothyrium minitans on Sclerotinia sclerotiorum and its Effect on Sclerotial Germination

Scanning electron microscopy showed that hyphae of Coniothyrium minitans produced appressorium-like swellings when they came in contact with Sclerotinia sclerotiorum in dual culture on PDA. The parasitized hyphae gradually skrank and collapsed, and hyphae of the mycoparasite were found inside the host hyphae. The mycoparasite hyphae grew inter- and intracellularly within the sclerotia of S. sclerotiorum. In the later stages of parasitism, hyphae of the mycoparasite proliferated extensively within the sclerotia and formed pycnidia near the sclerotial surface. At this stage, the sclerotia became flattened, soft and disintegrated. Sclerotia parasitized by C. minitans failed to germinate either myceliogenically or carpogenically.     

Use of Coniothyrium minitans and other microorganisms for reducing Sclerotinia sclerotiorum

Biological control agents (BCAs) Bacillus subtilis QST 713, Coniothyrium minitans CON/M/91-08, Streptomyces lydicus WYEC 108, and Trichoderma harzianum T-22 were evaluated for their efficacy in the reduction of survival of sclerotia and production of apothecia of Sclerotinia sclerotiorum under controlled environments. A growth chamber assay was conducted where 25 sclerotia were buried in pots containing potting soil, and BCAs were drenched into the soil at various concentrations, and five soybean seeds were planted in each pot. The presence and number of S. sclerotiorum apothecia were recorded daily. Sclerotinia sclerotiorum sclerotia were retrieved six weeks after seeding and viability was assessed on water agar plates. All BCAs were effective in reducing S. sclerotiorum inoculum at various efficacies. In general, efficacy was positively correlated with the rate of application. At the rate of application when the efficacy did not change significantly by increasing the rate, the BCAs had various reductions of apothecia and sclerotia. B. subtilis reduced apothecia and sclerotia by 91.2 and 29.6%, respectively; C. minitans reduced apothecia and sclerotia by 81.2 and 50%, respectively; Streptomyces lydicus reduced apothecia and sclerotia by 100 and 29.6%, respectively; Trichoderma harzianum reduced apothecia and sclerotia by 80.5 and 31.7%, respectively. In addition, the commercial strain of C. minitans CON/M/91-08, and a wild Michigan strain of C. minitans W09 were compared for their growth and sclerotial reduction. W09 had faster growth rate than the commercial strain, indicating potential diversities of biological control strains to be studied.     

Field management of Sclerotinia stem rot of soybean using biological control agents

Biological control agents (BCAs) were evaluated for their efficacy on reducing the number of sclerotia of Sclerotinia sclerotiorum (Lib.) de Bary in the soil and on Sclerotinia stem rot in soybean production systems in Michigan. BCAs included Coniothyrium minitans CON/M/91–08 (Product name: Contans®WG), Streptomyces lydicus WYEC 108 (Actinovate®AG), Trichoderma harzianum T-22 (PlantShield®HC), and Bacillus subtilis QST 713 (Serenade®MAX). At two field locations, soil artificially infested with S. sclerotiorum sclerotia, was treated by incorporating the above BCAs in the topsoil before planting and boscalid was applied as a foliar fungicide at growth stage R1 as a positive control. C. minitans was the most effective BCA and reduced the disease severity index (DSI) by 68.5% and the number of sclerotia of S. sclerotiorum in the soil by 95.3%. S. lydicus and T. harzianum reduced DSI by 43.1% and 38.5% and sclerotia in soil by 90.6% and 70.8%, respectively. B. subtilis only had a marginal effect on S. sclerotiorum. Populations of Bacillus, Streptomyces, Trichoderma spp., and C. minitans collected from soil samples and at 3, 28, 71, and 169 days after BCA application indicated that the population of Streptomyces, Trichoderma spp., and C. minitans did not change significantly throughout the season, which may be the reason for their effectiveness.     

Soil temperatures and inoculation techniques affect emergence and reisolation of Sclerotinia sclerotiorum from soybean

Emergence of Amsoy soybean (Glycine max) seed inoculated withSclerotinia sclerotiorum was significantly reduced below noninoculated seed at soil temperatures of 25°, 30°, and 35 °C, but not at 20 °C.S. sclerotiorum was readily reisolated from wound-inoculated stems of seedlings and nearly mature plants above the point of inoculation and below to the crown area, but not from roots. The fungus was recovered from stems but not roots of 15-day seedlings grown in sterile soil before infestation of the soil surface with a suspension of mycelium and sclerotia and assayed at 15 days after soil infestation. When compared to healthy, seeds, infected seeds withS. sclerotiorum were characterized by appearing flattened.Supported in part by the Illinois Agricultural Experiment Station; Regional Project S-72; and U.S. Agency for International Development, grant csd-1922.     

Soil temperatures and inoculation techniques affect emergence and reisolation of sclerotinia Sclerotiorum from soybean

Emergence of Amsoy soybean (Glycine max) seed inoculated withSclerotinia sclerotiorum was significantly reduced below noninoculated seed at soil temperatures of 25, 30 and 35 °C, but not at 20 °C.S. sclerotiorum was readily·reisolated from wound-inoculated stems of seedlings and nearly mature plants above the point of inoculation below to the crown area, but not from roots. The fungus was recovered from stems but not roots of seedlings grown in sterile soil for 15 days before infestation of the soil surface with a suspension of mycelium and sclerotia and assayed at 15 days after soil infestation. When compared to healthy, seed infected withS. sclerotiorum were characterized by appearing flattened.Supported in part by the Illinois Agricultural Experiment Station; Regional Project S-72; and U.S. Agency for International Development, grant csd-1922.     

Morphological development of sclerotia by <Emphasis Type="Italic">Sclerotinia sclerotiorum</Emphasis>: a view from light and scanning electron microscopy

Sclerotinia sclerotiorum is a worldwide pathogen with a broad host spectrum pathogenic to around 400 plant species. Sclerotia formed by S. sclerotiorum serve as resting structures that secure fungal survival in soil for prolonged periods in the absence of a host plant or may help to overcoming periods of unsuitable growth conditions. In the present study, the morphological development of sclerotia was examined by light and scanning electron microscopy of fungal microcultures. Observations from microscopy indicated that, during the first 4 days of culture, the sclerotial primordial originate by dichotomous branching of apical hyphae and from the 5th day mycelial clusters were also observed, indicating the initiation stage of sclerotia formation. From the 6th to the 8th day, sclerotia turned from white to dark color, and water drops (exudates) were observed on their surface. The process of sclerotia formation ended at the 9th day when they were easy to detach from the culture medium and had a black coloration. All the morphological processes involved in the formation of sclerotia by S. sclerotiorum were observed with both light and scanning electron microscopy.     

Clonostachys rosea BAFC3874 as a Sclerotinia sclerotiorum antagonist: mechanisms involved and potential as a biocontrol agent

Aims: To establish the modes of action of the antagonistic fungal strain Clonostachys rosea BAFC3874 isolated from suppressive soils against Sclerotinia sclerotiorum and to determine its potential as a biocontrol agent. Methods and Results: The antagonistic activity of C. rosea BAFC3874 was determined in vitro by dual cultures. The strain effectively antagonized S. sclerotiorum in pot‐grown lettuce and soybean plants. Antifungal activity assays of C. rosea BAFC3874 grown in culture established that the strain produced antifungal compounds against S. sclerotiorum associated with secondary metabolism. High mycelial growth inhibition coincided with sclerotia production inhibition. The C. rosea strain produced a microheterogeneous mixture of peptides belonging to the peptaibiotic family. Moreover, mycoparasitism activity was observed in the dual culture. Conclusions: Clonostachys rosea strain BAFC3874 was proved to be an effective antagonist against the aggressive soil‐borne pathogen S. sclerotiorum in greenhouse experiments. The main mechanisms involve peptaibiotic metabolite production and mycoparasitism activity. Significance and Impact of the Study: Clonostachys rosea BAFC3874 may be a good fungal biological control agent against S. sclerotiorum. In addition, we were also able to isolate and identify peptaibols, an unusual family of compounds in this genus of fungi.     

Carpogenic Germination of Sclerotia of Sclerotinia sclerotiorum after Periods of Conditioning in Soil

Periods of conditioning in soil reduced the length of the resting period needed before sclerotia of Sclerotinia sclerotiorum could germinate to form apothecia. Curves for germination of sclerotia were fitted by a form of the log-logistic equation and from this equation the time taken for 50% germination (x₅₀) was calculated. These x₅₀ values were used as the basis for comparing germinability of sclerotia collected from infected sunflower plants and others conditioned in soil, or moist vermiculite for various times. Sclerotia from sunflower roots germinated sooner than those from the stem cavities. Germinability increased with the length of the conditioning period. Conditioning in soil was more effective than in moist vermiculite.     

Selection of a Streptomyces strain able to produce cell wall degrading enzymes and active against Sclerotinia sclerotiorum

Control of plant pathogen Sclerotinia sclerotiorum is an ongoing challenge because of its wide host range and the persistence of its sclerotia in soil. Fungicides are the most commonly used method to control this fungus but these can have ecotoxicity impacts. Chitinolytic Streptomyces strains isolated from Brazilian tropical soils were capable of inhibiting S. sclerotiorum growth in vitro, offering new possibilities for integrated pest management and biocontrol, with a new approach to dealing with an old problem. Strain Streptomyces sp. 80 was capable of irreversibly inhibiting fungal growth. Compared to other strains, its crude enzymes had the highest chitinolytic levels when measured at 25°C and strongly inhibited sclerotia from S. sclerotiorum. It produced four hydrolytic enzymes involved in fungal cell wall degradation when cultured in presence of the fungal mycelium. The best production, obtained after three days, was 0.75 U/ml for exochitinase, 0.9 U/ml for endochitinase, 0.16 U/ml for glucanase, and 1.78 U/ml for peptidase. Zymogram analysis confirmed two hydrolytic bands of chitinolytic activity with apparent molecular masses of 45.8 and 206.8 kDa. One glucanase activity with an apparent molecular mass of 55 kDa was also recorded, as well as seven bands of peptidase activity with apparent molecular masses ranging from 15.5 to 108.4 kDa. Differential interference contrast microscopy also showed alterations of hyphal morphology after co-culture. Streptomyces sp. 80 seems to be promising as a biocontrol agent against S. sclerotiorum, contributing to the development of new methods for controlling plant diseases and reducing the negative impact of using fungicides.     

Volatiles from biofumigant plants have a direct effect on carpogenic germination of sclerotia and mycelial growth of <Emphasis Type="Italic">Sclerotinia sclerotiorum</Emphasis>

Aims

Sclerotia of Sclerotinia sclerotiorum survive in soil and germinate to produce apothecia which release airborne ascospores. Current control methods rely predominantly on the use of fungicides to kill ascospores. The aim of this research was to identify potential biofumigation treatments which suppress sclerotial germination, providing a potential alternative and long-term approach to disease management.

Methods

Microcosm and in vitro experiments were conducted using dried and milled plant material from six different biofumigant crop plants to determine effects on carpogenic germination of sclerotia and mycelial growth of S. sclerotiorum.

Results

All biofumigant plants significantly reduced germination of S. sclerotiorum sclerotia in the microcosm experiments, but were less effective against larger sclerotia. In vitro experiments showed a direct effect of biofumigant volatiles on both the mycelial growth of S. sclerotiorum, and carpogenic germination of sclerotia, where the most effective treatment was B. juncea ‘Vittasso’.

Conclusions

It was clear from this study that biofumigant crop plants have potential as part of an integrated disease management system for control of S. sclerotiorum. The microcosm experiments described here provide a straightforward and reliable screening method for evaluating different biofumigants for activity.

     

Aspergillus spp. eliminate Sclerotinia sclerotiorum by imbalancing the ambient oxalic acid concentration and parasitizing its sclerotia

Sclerotinia sclerotiorum, a pathogen of more than 600 host plants, secretes oxalic acid to regulate the ambient acidity and provide conducive environment for pathogenicity and reproduction. Few Aspergillus spp. were previously proposed as potential biocontrol agents for S. sclerotiorum as they deteriorate sclerotia and prevent pathogen's overwintering and initial infections. We studied the nature of physical and biochemical interactions between Aspergillus and Sclerotinia. Aspergillus species inhibited sclerotial germination as they colonized its rind layer. However, Aspergillus-infested sclerotia remain solid and viable for vegetative and carpogenic germination, indicating that Aspergillus infestation is superficial. Aspergillus spp. of section Nigri (Aspergillus japonicus and Aspergillus niger) were also capable of suppressing sclerotial formation by S. sclerotiorum on agar plates. Their culture filtrate contained high levels of oxalic, citric and glutaric acids comparing to the other Aspergillus spp. tested. Exogenous supplementation of oxalic acid altered growth and reproduction of S. sclerotiorum at low concentrations. Inhibitory concentrations of oxalic acid displayed lower pH values comparing to their parallel concentrations of other organic acids. Thus, S. sclerotiorum growth and reproduction are sensitive to the ambient oxalic acid fluctuations and the environmental acidity. Together, Aspergillus species parasitize colonies of Sclerotinia and prevent sclerotial formation through their acidic secretions.