Differentiation of Sclerotinia minor depends on thiol redox state and oxidative stress

Antifungal effects of 3-(2-pyridyl)methyl-2-(4-chlorphenyl) iminothiazolidine against Sclerotinia sclerotiorum

BACKGROUND

Sclerotinia stem rot (SSR) caused by Sclerotinia sclerotiorum threatens oilseed rape cultivation, and the emergence of fungicide-resistant strains has led to control failures worldwide. Identifying novel chemical alternatives with different modes of action and high antifungal activities is thus crucial. Herein we evaluated the antifungal effects of 3-(2-pyridyl)methyl-2-(4-chlorphenyl)imino- thiazolidine (PMAS) on S. sclerotiorum to determine its efficacy for SSR management.

RESULTS

PMAS had an inhibitory effect on mycelial growth; the EC₅₀ values were 17.83 and 21.15 μg mL^-1 for the carbendazim-susceptible strain Ss01 and carbendazim-resistant strain Hm25, respectively. PMAS treatment changed the color of inhibited mycelia to green, and the hyphae were sustained in the undifferentiated stage. Cysteine supplementation made this green color disappear, whereas methionine enhanced the color. Moreover, PMAS treatment markedly inhibited oxalic acid biogenesis, increased free thiol content in mycelia, and weakened the activities of oxaloacetase and malate dehydrogenase, but had little effect on the activity of glyoxylate dehydrogenase. Cysteine could reverse the inhibitory effects of PMAS on mycelial morphogenesis and biochemical constituents, except thiol production. In the pot-culture experiment, PMAS showed a good protective effect, with the control efficacy being >91% on SSR.

CONCLUSION

PMAS appears to be an effective fungicide for SSR management. © 2020 Society of Chemical Industry.

Sclerotial formation of Polyporus umbellatus by low temperature treatment under artificial conditions

BACKGROUND

Polyporus umbellatus sclerotia have been used as a diuretic agent in China for over two thousand years. A shortage of the natural P. umbellatus has prompted researchers to induce sclerotial formation in the laboratory.

METHODOLOGY/PRINCIPAL FINDING

P. umbellatus cultivation in a sawdust-based substrate was investigated to evaluate the effect of low temperature conditions on sclerotial formation. A phenol-sulfuric acid method was employed to determine the polysaccharide content of wild P. umbellatus sclerotia and mycelia and sclerotia grown in low-temperature treatments. In addition, reactive oxygen species (ROS) content, expressed as the fluorescence intensity of mycelia during sclerotial differentiation was determined. Analysis of ROS generation and sclerotial formation in mycelia after treatment with the antioxidants such as diphenyleneiodonium chloride (DPI), apocynin (Apo), or vitamin C were studied. Furthermore, macroscopic and microscopic characteristics of sclerotial differentiation were observed. Sclerotia were not induced by continuous cultivation at 25°C. The polysaccharide content of the artificial sclerotia is 78% of that of wild sclerotia. In the low-temperature treatment group, the fluorescent intensity of ROS was higher than that of the room temperature (25°C) group which did not induce sclerotial formation all through the cultivation. The antioxidants DPI and Apo reduced ROS levels and did not induce sclerotial formation. Although the concentration-dependent effects of vitamin C (5-15 mg mL(-1)) also reduced ROS generation and inhibited sclerotial formation, using a low concentration of vitamin C (1 mg mL(-1)) successfully induced sclerotial differentiation and increased ROS production.

CONCLUSIONS/SIGNIFICANCE

Exposure to low temperatures induced P. umbellatus sclerotial morphogenesis during cultivation. Low temperature treatment enhanced ROS in mycelia, which may be important in triggering sclerotial differentiation in P. umbellatus. Moreover, the application of antioxidants impaired ROS generation and inhibited sclerotial formation. Our findings may help to provide new insights into the biological mechanisms underlying sclerotial morphogenesis in P. umbellatus.

Hydrogen peroxide is involved in the sclerotial differentiation of filamentous phytopathogenic fungi

AIMS

The purpose of this study was to investigate the role of H(2) O(2) and the related oxidative stress markers catalase (CAT) and lipid peroxidation in the sclerotial differentiation of the phytopathogenic filamentous fungi Sclerotium rolfsii, Sclerotinia minor, Sclerotinia sclerotiorum and Rhizoctonia solani.

METHODS AND RESULTS

Using the H(2) O(2) -specific scopoletin fluorometric assay and the CAT-dependent H(2) O(2) consumption assays, it was found that the production rate of intra/extracellular H(2) O(2) and CAT levels in the sclerotiogenic fungi were significantly higher and lower, respectively, than those of their nondifferentiating counterpart strains. They peaked in the transition between the undifferentiated and the differentiated state of the sclerotiogenic strains, suggesting both a cell proliferative and differentiative role. In addition, the indirect indicator of oxidative stress, lipid peroxidation, was substantially decreased in the nondifferentiating strains.

CONCLUSIONS

These findings suggest that the differentiative role of H(2) O(2) is expressed via induction of higher oxidative stress in the sclerotiogenic filamentous phytopathogenic fungi.

SIGNIFICANCE AND IMPACT OF THE STUDY

This study shows that the direct marker of oxidative stress H(2) O(2) is involved in the sclerotial differentiation of the phytopathogenic filamentous fungi S. rolfsii, S. minor, S. sclerotiorum and R. solani, which could have potential biotechnological implications in terms of developing antifungal strategies by regulating intracellular H(2) O(2) levels.

Streptomyces lividans inhibits the proliferation of the fungus Verticillium dahliae on seeds and roots of Arabidopsis thaliana

Verticillium wilt, a vascular disease in more than 200 dicotyledonous plants, is due to the ascomycete fungus Verticillium dahliae. As documented by video-microscopy, the soil bacterium Streptomyces lividans strongly reduces the germination of V. dahliae conidia, and the subsequent growth of hyphae. Quantification by the use of DNA-intercalating dyes and Calcofluor-staining revealed that during prolonged co-cultivation, bacterial hyphae proliferate to a dense network, provoke a poor development of V. dahliae vegetative hyphae and lead to an enormous reduction of conidia and microsclerotia. Upon individual application to seeds of the model plant Arabidopsis thaliana, either the bacterial spores or the fungal conidia germinate at or within the mucilage, including its volcano-shaped structures. The extension of hyphae from each individual strain correlates with the reduction of the pectin-containing mucilage-layer. Proliferating hyphae then spread to roots of the emerging seedlings. Plants, which arise in the presence of V. dahliae within agar or soil, have damaged root cells, an atrophied stem and root, as well as poorly developed leaves with chlorosis symptoms. In contrast, S. lividans hyphae settle in bunches preferentially at the outer layer near tips and alongside roots. Resulting plants have a healthy appearance including an intact root system. Arabidopsis thaliana seeds, which are co-inoculated with V. dahliae and S. lividans, have preferentially proliferating bacterial hyphae within the mucilage, and at roots of the outgrowing seedlings. As a result, plants have considerably reduced disease symptoms. As spores of the beneficial S. lividans strain are obtainable in large quantity, its application is highly attractive.

Superoxide radical is involved in the sclerotial differentiation of filamentous phytopathogenic fungi: identification of a fungal xanthine oxidase

This study shows that the direct indicator of oxidative stress superoxide radical (O·₂⁻) is involved in the sclerotial differentiation of the phytopathogenic filamentous fungi Rhizoctonia solani, Sclerotinia sclerotiorum, Sclerotium rolfsii, and Sclerotinia minor. The production rate of O·₂⁻ and the antioxidant enzyme superoxide dismutase (SOD) levels in the sclerotiogenic fungi were significantly higher and lower, respectively, than those of their non-differentiating counterpart strains, which strongly suggests that the oxidative stress of the sclerotium differentiating fungi is higher than that of the non-differentiating ones. Xanthine oxidase (XO), which was detected for the first time in fungi in general, was localized in the cytoplasmic membrane. The contribution of XO in the overall O·₂⁻production was very significant, reaching 30-70% among the strains, especially in the transition developmental stage between the undifferentiated and the differentiated state, suggesting a sclerotium triggering and a phytopathogenic role of XO during plant infection. The additional finding that these fungi secrete extracellular SOD can be related to their protection from the response of plants to produce O·₂⁻ at infection sites.

Superoxide radical induces sclerotial differentiation in filamentous phytopathogenic fungi: a superoxide dismutase mimetics study

This study shows that the superoxide radical (O2 •−), a direct indicator of oxidative stress, is involved in the differentiation of the phytopathogenic filamentous fungi Rhizoctonia solani, Sclerotinia sclerotiorum, Sclerotium rolfsii and Sclerotinia minor, shown by using superoxide dismutase (SOD) mimetics to decrease their sclerotial differentiation. The production rate of O2 •− and SOD levels in these fungi, as expected, were significantly lowered by the SOD mimetics, with concomitant decrease of the indirect indicator of oxidative stress, lipid peroxidation.

Protocol for the quantitative assessment of DNA concentration and damage (fragmentation and nicks)

An ultrasensitive protocol is presented for the quantitative assessment of fragmented and nicked dsDNA using PicoGreen and consists of four methods. The first quantifies the concentration of DNA, whereas the second (quantitative complement of the Comet assay) quantifies the degree of DNA fragmentation seen in a typical DNA agarose electrophoresis gel. Both methods have sensitivity of 5 pg of DNA. The third method (quantitative counterpart of the electrophoresis-based qualitative apoptotic and necrotic DNA assays) quantifies the polyethylene glycol-fractionated small-size (0-1 kb) fragmented DNA. This method also detects up to 5 pg of damaged DNA and requires a minimum sample of quantity 0.2 ml of 2.5 microg ml(-1). The fourth method measures the percentage of DNA nicks by alkaline DNA unwinding and requires up to 15 pg of DNA sample. The time required for processing 10 DNA samples is 1/2, 1, 13 and 1 h for the first, second, third and fourth method, respectively.