Morphological and Pathogenic Characterization of Genetically Diverse Sclerotinia Isolates from European Red Clover Crops (Trifolium Pratense L.)

Clover rot, an important disease in European red clover crops, is caused by Sclerotinia trifoliorum or Sclerotinia sclerotiorum. Until today, little is known about the variation in aggressiveness among Sclerotinia isolates from red clover. Aggressiveness has never been correlated with morphological characteristics. Rapidly growing isolates may be more aggressive, but this was never investigated in S. trifoliorum before. Also nothing is known about the link between sclerotia production and aggressiveness. Oxalic acid is an important pathogenicity factor in Sclerotinia species, but its effect on aggressiveness is unknown in S. trifoliorum isolates. For this study, we selected 30 Sclerotinia isolates from 25 locations Europe: 26 S. trifoliorum isolates and 4 S. sclerotiorum isolates from two locations in France (Fr.A and Fr.B). For each isolate, the in vitro growth speed, sclerotia production, oxalate production and aggressiveness were analysed and correlations were estimated between aggressiveness and the other characteristics. Aggressiveness was assessed in vitro on detached leaves and in a greenhouse on young plants. Our isolates differed significantly in growth speed, sclerotia production, oxalate production and aggressiveness. The infections on detached leaves and young plants revealed interaction between isolates and plant genotypes and between isolates and cultivars, but there was no indication that pathotypes exist. In vitro growth speed and in vitro aggressiveness on detached leaves were positively correlated with aggressiveness on young plants, while sclerotia production was negatively correlated with aggressiveness on young plants. These factors can be used as predictors of aggressiveness of Sclerotinia isolates from red clover crops.     

Association of polyphosphate with protein in freeze-substituted sclerotia ofSclerotinia minor

Summary In freeze-substituted sclerotia stained with aqueous toluidine blue O, metachromatic material was found throughout the cytoplasm in discrete granules. It was also distributed evenly throughout spherical and elongate protein bodies. This material stained at low pH and was extracted by cold acid, indicating that it was polyphosphate. Retention of metachromatic material was much greater than previously reported in chemically fixed, conventionally processed sclerotia. X-ray microanalysis of dry-cut, unstained sections of freeze-substituted sclerotia confirmed that phosphorus was distributed evenly throughout the protein bodies and was not localised in discrete granules but phosphorus levels in the cytoplasm were very low. It is concluded that polyphosphate is lost during conventional preparation procedures but retained in dry-cut, unstained sections of freeze-substituted material. However, when freeze-substituted sections were stained with toluidine blue O, water soluble polyphosphate was extracted and subsequently precipitated in the cytoplasm as polyphosphate granules. Therefore it is considered that polyphosphate granules are an artefact, and that protein bodies are the major site for storage of phosphorus in this fungus.Abbreviations STEM scanning transmission electron microscope - ER endoplasmic reticulum     

In vitro mutation and selection of doubled-haploid Brassica napus lines with improved resistance to Sclerotinia sclerotiorum

This paper describes a new protocol to develop doubled-haploid (DH) Brassica napus lines with improved resistance to Sclerotinia sclerotiorum. In this protocol, haploid seedlings derived from microspore cultures of B. napus were used to produce haploid calli for in vitro mutation-selection. For routine screening, mutation was induced by EMS (ethylmethane sulfonate) or occurred spontaneously, and screening for resistant mutants occurred on media with added oxalic acid (OA) as a selection agent. In tests with selected lines, the optimal concentration of EMS for mutation was determined to be 0.15%, and the optimal concentration of OA for in vitro screening was 3 mmol/l (half lethal dose was 3.1 mmol/l) for the first cycle of screening. There was an accumulated effect of OA toxicity on calli over two cycles of screening, but the growth and capacity of the surviving calli for regenerating seedlings were not affected by OA. Of the 54 DH lines produced from the in vitro mutation-selection, two DH lines of resistant mutants, named M083 and M004, were selected following seedling and glasshouse tests. The resistance of M083 and M004 to S. sclerotiorum following tests with both mycelial inoculum and OA was greater than that of their donor lines and the resistant control Zhongyou 821. In both glasshouse and field disease nurseries, disease indices on M083 and M004 were less than 50% of those of the control. The time required for M083 and M004 to mature was 14 days and 10 days shorter, respectively, than that of their donor lines. Furthermore, M083 had more pods per inflorescence, a greater 1,000 seed weight and higher yield than its donor line. Random amplified polymorphic DNA characterisation showed that M083 had DNA band patterns that differed from its donor line.     

Detoxification of the cruciferous phytoalexin brassinin in Sclerotinia sclerotiorum requires an inducible glucosyltransferase

The phytoalexins, brassinin, 1-methoxybrassinin and cyclobrassinin, were metabolized by the stem rot fungus Sclerotinia sclerotiorum into their corresponding glucosyl derivatives displaying no detectable antifungal activity. Importantly, co-incubation of S. sclerotiorum with camalexins, various phytoalexin analogs, and brassinin indicated that a synthetic camalexin derivative could slow down substantially the rate of brassinin detoxification. Furthermore, inducible brassinin glucosyltransferase (BGT) activity was detected in crude cell-free extracts of S. sclerotiorum. BGT activity was induced by the phytoalexin camalexin, and the brassinin analogs methyl tryptamine dithiocarbamate and methyl 1-methyltryptamine dithiocarbamate. The overall results suggest that the fungus S. sclerotiorum in its continuous adaptation and co-evolution with brassinin producing plants, has acquired efficient glucosyltransferase(s) that can disarm some of the most active plant chemical defenses.     

Sclerotinia sclerotiorum: when "to be or not to be" a pathogen?

Sclerotinia sclerotiorum is unusual among necrotrophic pathogens in its requirement for senescent tissues to establish an infection and to complete the life cycle. A model for the infection process has emerged whereby the pathogenic phase is bounded by saprophytic phases; the distinction being that the dead tissues in the latter are generated by the actions of the pathogen. Initial colonization of dead tissue provides nutrients for pathogen establishment and resources to infect healthy plant tissue. The early pathogenicity stage involves production of oxalic acid and the expression of cell wall degrading enzymes, such as specific isoforms of polygalacturonase (SSPG1) and protease (ASPS), at the expanding edge of the lesion. Such activities release small molecules (oligo-galacturonides and peptides) that serve to induce the expression of a second wave of degradative enzymes that collectively bring about the total dissolution of the plant tissue. Oxalic acid and other metabolites and enzymes suppress host defences during the pathogenic phase, while other components initiate host cell death responses leading to the formation of necrotic tissue. The pathogenic phase is followed by a second saprophytic phase, the transition to which is effected by declining cAMP levels as glucose becomes available and further hydrolytic enzyme synthesis is repressed. Low cAMP levels and an acidic environment generated by the secretion of oxalic acid promote sclerotial development and completion of the life cycle. This review brings together histological, biochemical and molecular information gathered over the past several decades to develop this tri-phasic model for infection. In several instances, studies with Botrytis species are drawn upon for supplemental and supportive evidence for this model. In this process, we attempt to outline how the interplay between glucose levels, cAMP and ambient pH serves to coordinate the transition between these phases and dictate the biochemical and developmental events that define them.     

A sunflower leaf antifungal peptide active against Sclerotinia sclerotiorum

A 5-kDa antifungal peptide (APS) was isolated from Helianthus annum L. (line HA89) leaves infected with a virulent isolate of Sclerotinia sclerotiorum (Lib.) de Bary. AP5 was purified by gel filtration, cation exchange chromatography and reverse phase FPLC and HPLC. This peptide in vitro inhibits ascospores germination of the fungal pathogen S. sclerotiorum or produces mycelial growth inhibition, depending on its concentration. The effective concentration of AP5 giving 50% growth inhibition (IC₅₀) against S. sclerotiorum was 0.4 μM. The antifungal efficacy of AP5 is higher than that of other antimicrobial proteins already described that have no appreciable effect on S. sclemtiorum below 4 μM. The relevance of this finding with regard to the function of AP5 in sunflower resistance to pathogens is discussed.     

Effect of Sclerotial Damage of Sclerotinia sclerotiorum on the Mycoparasitic Activity of Trichoderma hamatum

Damaged sclerotia of Sclerotinia sclerotiorum buried in soil infested with Trichoderma hamatum isolate TMCS - 3 were degraded rapidly when the medulla of sclerotia was com pletely exposed by the feeding activity of larvae of the fungus gnat Bradysia coprophila. These heavily damaged sclerotia also enhanced , in vitro, the growth of TMCS - 3 . Growth of TMCS - 3 in liquid culture was studied using different carbon sources as substrates , including sclerotia of S. sclerotiorum. Significantly more biomass of TMCS - 3 was recovered using sclerotia as a substrate compared to other carbon sources tested . Exudates from sclerotia whose melanized rinds had been completely removed by feeding larvae accelerated the germination of conidia of TMCS - 3 . Concentrations of amino acids , carbohydrates and proteins in the sclerotial exudates were not increased as damage to sclerotia was increased . Exudation of electrolytes was higher in undamaged than damaged sclerotia . Glucanase activity of TMCS - 3 was slightly increased when the fungus was exposed to damaged sclerotia . However , chitinase activity was not increased by damaging the sclerotia . Larval damage altered the sclerotia not only physically but also chemically , thereby enhancing the activity of the fungus T. hamatum.     

Biological control of Sclerotinia sclerotiorum attacking soybean plants. Degradation of the cell walls of this pathogen by Trichoderma harzianum (BAFC 742)

Two experiments of biological control of Sclerotinia sclerotiorum, one in the greenhouse and the other in the field, were carried out with soybean and Trichoderma harzianum as host and antagonist, respectively. Significant control of disease was achieved in both experiments, but there were no significant differences in plant growths. In the greenhouse, the application of T. harzianum as alginate capsules, increased the survival of soybean plants more than 100% with respect to the disease treatment. In the field, T. harzianum treated plants survived 40% more than those from the disease treatment, showing a similar survival level to control plants. Besides, a significant reduction (62.5%) in the number of germinated sclerotia was observed in the Trichoderma treated plot. Chitinase and 1,3-β- glucanase activities were detected when T. harzianum was grown in a medium containing Sclerotinia sclerotiorum cell walls as sole carbon source. In addition, electrophoretic profiles of proteins induced in T. harzianum showed quantitative differences between major bands obtained in the media induced by S. sclerotiorum cell walls and that containing glucose as a sole carbon source. This revised version was published online in June 2006 with corrections to the Cover Date.     

Cloning of molecular markers for disease resistance in sunflower, Helianthus annuus L.

 A candidate-gene approach to analyse the resistance of plants to phytopathogenic fungi is presented. The resistance of sunflower (Helianthus annuus L.) to downy mildew (Plasmopara halstedii) shows a gene-for-gene interaction (monogenic resistance), whereas resistance to white rot (Sclerotinia sclerotiorum) is quantitative, with different levels of resistance for different plant parts. By homology cloning, probes were obtained homologous to some plant resistance genes (nucleotide binding site-like, NBS, genes and serine-threonine protein kinase-like, PK, genes). These clones were used as probes for linkage mapping of the corresponding genes. It was demonstrated that at least three NBS-like loci are located on linkage-group 1, in the region where downy mildew resistance loci have been described. Quantitative trait loci for S. sclerotiorum resistance to penetration or extension of the mycelium in different tissues were studied in three crosses. Major QTLs for resistance were found on linkage group 1, with up to 50% of the phenotypic variability explained by peaks at the map position of the PK locus, 25 cM from the downy mildew loci. Received: 24 September 1997 / Accepted: 21 October 1997     

Valuable New Resistances Ensure Improved Management of Sclerotinia Stem Rot (Sclerotinia sclerotiorum) in Horticultural and Oilseed Brassica Species

Field resistances against Sclerotinia rot (SR) (Sclerotinia sclerotiorum) were determined in 52 Chinese genotypes of Brassica oleracea var. capitata, 14 Indian Brassica juncea genotypes carrying wild weedy Brassicaceae introgression(s) and four carrying B‐genome introgression, 22 Australian commercial Brassica napus varieties, and 12 B. napus and B. juncea genotypes of known resistance. All plants were individually inoculated by securing an agar disc from a culture of S. sclerotiorum growing on a glucose‐rich medium to the stem above the second internode with Parafilm tape. Mean stem lesion length across tested genotypes ranged from <1 to >68 mm. While there was considerable diversity within the germplasm sets from each country, overall, 65% of the B. oleracea var. capitata genotypes from China showed the highest levels of stem resistance, a level comparable with the highest resistance ever recorded for oilseed B. napus or B. juncea from China or Australia. One Indian B. juncea line carrying weedy introgression displayed a significant level of both stem and leaf resistance. However, the vast majority of commercial Australian oilseed B. napus varieties fell within the most susceptible 40% of genotypes tested for stem disease. There was no correlation between expressions of stem versus leaf resistance, suggesting their independent inheritance. A few Chinese B. oleracea var. capitata genotypes that expressed combined extremely high‐level stem (≤1 mm length) and leaf (≤0.5 mean number of infections/plant) resistance will be particularly significant for developing new SR‐resistant horticultural and oilseed Brassica varieties.