Reactive oxygen intermediates and oxalic acid in the pathogenesis of the necrotrophic fungus Sclerotinia sclerotiorum

An effective colonization of the host plant tissue by the necrotrophic fungus Sclerotinia sclerotiorum requires the secretion of the non-host specific toxin oxalic acid (OA), which is known to suppress the generation of reactive oxygen intermediates (ROI). A full-length cDNA coding for an oxalate decarboxylase (TOXDC), which converts OA into CO₂ and formate, was isolated from the basidiomycete Trametes versicolor. It was overexpressed in tobacco plants to study the role of ROI and OA in the interaction between tobacco and S. sclerotiorum. The transgenic plants contained less OA and showed a delayed colonization of S. sclerotiorum; furthermore a strong ROI accumulation and nearly no catalase activity compared to the wild type (WT) plants could be detected. In addition, inoculation experiments with transgenic catalase-deficient plants (CAT1AS) and in vitro studies showed that S. sclerotiorum copes with strong ROI stress. Our results indicate that OA supports the infection process caused by S. sclerotiorum and the fungus itself is able to tolerate high ROI concentrations. The nucleotide sequence data is available from the NCBI Genbank nucleotide-sequence database under the number AY370675     

ABA signaling inhibits oxalate-induced production of reactive oxygen species and protects against <Emphasis Type="Italic">Sclerotinia sclerotiorum</Emphasis> in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Oxalic acid is an essential virulence factor of Sclerotinia sclerotiorum that elicits wilting symptoms in infected host plants. Foliar wilting in response to oxalic acid is known to be dependent on an increase in stomatal conductance. To determine whether stomatal regulation controls susceptibility to S. sclerotiorum, abscisic acid-insensitive and open stomata mutants of Arabidopsis thaliana were analyzed. Whereas abscisic acid-insensitive mutants were hypersusceptible to S. sclerotiorum, open stomata mutants were as susceptible as wild type. It was concluded that stomatal regulation does not control susceptibility to S. sclerotiorum because open stomata mutants are known to only impair guard cells whereas abscisic acid-insensitive mutants also affect other cell types. Guard cell-independent processes also control sensitivity to oxalic acid because oxalic acid was more toxic to abscisic acid-insensitive mutants than to open stomata mutants. To explore a possible mechanism of toxicity, production of reactive oxygen species was measured in plant cells after exposure to oxalic acid. Oxalic acid was found to elicit reactive oxygen species production independently of abscisic acid. Nevertheless, cancellation of reactive oxygen species elicitation after co-stimulation of wild-type guard cells with oxalic acid and abscisic acid provided evidence for antagonistic interaction between both molecules.     

A Polymerase Chain Reaction (PCR) Assay for the Detection of Inoculum of Sclerotinia sclerotiorum

The development of a polymerase chain reaction (PCR) assay for the detection of inoculum of the plant pathogenic fungus Sclerotinia sclerotiorum is described. The PCR primers were designed using nuclear ribosomal DNA internal transcribed spacer sequences. Specific detection of DNA from S. sclerotiorum was possible even in the presence of a 40-fold excess of DNA from the closely related fungus Botrytis cinerea. PCR products were obtained from suspensions of untreated S. sclerotiorum ascospores alone, but DNA purification was required for detection in the presence of large numbers of B. cinerea conidiospores. Specific detection of inoculum of S. sclerotiorum was possible in field-based air-samples, using a Burkard spore trap, and from inoculated oilseed rape petals. The assay has potential for incorporation into a risk management system for S. sclerotiorum in oilseed rape crops.     

Population structure of Sclerotinia sclerotiorum in crop and wild hosts in the UK

Sclerotinia sclerotiorum is an important pathogen of many crop plants which also infects wild hosts. The population structure of this fungus was studied for different crop plants and Ranunculus acris (meadow buttercup) in the UK using eight microsatellite markers and sequenced sections of the intergenic spacer (IGS) region of the rRNA gene and the elongation factor 1‐alpha (EF) gene. A total of 228 microsatellite haplotypes were identified within 384 isolates from 12 S. sclerotiorum populations sampled in England and Wales. One microsatellite haplotype was generally found at high frequency in each population and was distributed widely across different hosts, locations and years. Fourteen IGS and five EF haplotypes were found in the 12 populations, with six IGS haplotypes and one EF haplotype exclusive to buttercup. Analysis of published sequences for S. sclerotiorum populations from the USA, Canada, New Zealand and Norway showed that three of the IGS haplotypes and one EF haplotype were widely distributed, while eight IGS haplotypes were only found in the UK. Although common microsatellite and IGS/EF haplotypes were found on different hosts in the UK, there was evidence of differentiation, particularly for one isolated population on buttercup. However, overall there was no consistent differentiation of S. sclerotiorum populations from buttercup and crop hosts. Sclerotinia sclerotiorum therefore has a multiclonal population structure in the UK and the wide distribution of one microsatellite haplotype suggests spatial mixing at a national scale. The related species S. subarctica was also identified in one buttercup population.     

基于丁香酚的异(口恶)唑啉类化合物的设计合成及抑菌活性

为了探索新型异齅唑啉类化合物作为杀菌剂候选化合物开发的潜力,本研究以廉价易得的芳香醛类化合物为原料制备了32个氯代肟类化合物,通过其与天然产物丁香酚的1,3-偶极环加成反应和后期官能团化反应,制备了35个异齅唑啉类化合物 ( D1 ~ D32 , E1 ~ E3 ),其中34个为新化合物。所有化合物的结构均经过液相色谱-电喷雾质谱 (LC-ESI-MS)、核磁共振氢谱 (1H NMR) 及元素分析确认。初步抑菌活性测试结果表明:多数目标化合物对油菜菌核病菌、水稻纹枯病菌、番茄早疫病菌和辣椒疫霉病菌具有较好的抑菌活性,其中化合物 D26 对油菜菌核病菌的活性最高,有效抑制中浓度 (EC₅₀) 为14.3 mg/L,具有进一步研究的价值。     

核盘菌自噬相关基因SsATG5和SsATG8的功能分析

为探究自噬在核盘菌Sclerotinia sclerotiorum致病过程中的作用,利用酵母Saccharomyces自噬相关基因（autophagy-related gene,ATG）编码的蛋白序列比对核盘菌基因组,获得核盘菌假定ATG,并以核盘菌1980菌株为出发菌株,基于同源重组的原理对假定ATG进行敲除和回补,并测定不同突变体的生长表型和致病能力。结果表明,从核盘菌基因组中比对到2个ATG,分别命名为SsATG5和SsATG8,两者在核盘菌致病过程中均上调表达。SsATG5和SsATG8敲除突变体在菌丝生长、产草酸和侵染垫形成方面与野生型菌株无明显差异,但SsATG5敲除突变体在离体拟南芥Arabidopsis thaliana叶片上的致病力显著下降了约40%,在活体拟南芥植株上的致病力显著下降了约80%,同时SsATG5回补突变体恢复了正常的致病力。表明SsATG5参与了核盘菌的致病过程,证实自噬在核盘菌致病过程中发挥着重要作用。     

Soybean plants expressing an active oligomeric oxalate oxidase from the wheat gf-2.8 (germin) gene are resistant to the oxalate-secreting pathogen Sclerotina sclerotiorum

Sclerotinia stem rot (SSR) caused by Sclerotinia sclerotiorum (Lib.) De Bary is a serious fungal disease of soybean. Senescing petals provide a starting nutrient source for the invasion of healthy tissue by the advancing oxalic acid secreting fungal hyphae. Since oxalic acid is a major pathogenicity factor of SSR, transgenic soybean capable of degrading oxalic acid may be resistant to the pathogen. Transgenic soybean plants were produced byAgrobacterium -mediated transformation with the wheat germin gene (gf-2.8) encoding an oligomeric protein, oxalate oxidase (OxO), which oxidizes oxalic acid to carbon dioxide and hydrogen peroxide (H₂O₂). Transgenic soybean homozygous for 35S- gf-2.8 produced an approx. 130 kDa protein indistinguishable from wheat germin, and with OxO activity. OxO activity was prominent in cell walls proximal to the site of pathogen attack. The transgenics had greatly reduced disease progression and lesion length following cotyledon and stem inoculation with S. sclerotiorum indicating that the germin gene product conferred resistance to SSR. This is the first report of plant resistance to the fungal pathogen S. sclerotiorum in transgenic plants expressing OxO.     

Resistance to a highly aggressive isolate of Sclerotinia sclerotiorum in a Brassica napus diversity set

Sclerotinia stem rot (SSR) of oilseed rape (OSR, Brassica napus), caused by Sclerotinia sclerotiorum, is a serious problem in the UK and worldwide. As fungicide‐based control approaches are not always reliable, identifying host resistance is a desirable and sustainable approach to disease management. This research initially examined the aggressiveness of 18 Sclerotinia isolates (17 S. sclerotiorum, one S. subarctica) on cultivated representatives of B. rapa, B. oleracea and B. napus using a young plant test. Significant differences were observed between isolates and susceptibility of the brassica crop types, with B. rapa being the most susceptible. Sclerotinia sclerotiorum isolates from crop hosts were more aggressive than those from wild buttercup (Ranunculus acris). Sclerotinia sclerotiorum isolates P7 (pea) and DG4 (buttercup), identified as ‘aggressive’ and ‘weakly aggressive’, respectively, were used to screen 96 B. napus lines for SSR resistance in a young plant test. A subset of 20 lines was further evaluated using the same test and also in a stem inoculation test on flowering plants. A high level of SSR resistance was observed for five lines and, although there was some variability between tests, one winter OSR (line 3, Czech Republic) and one rape kale (line 83, UK) demonstrated consistent resistance. Additionally, one swede (line 69, Norway) showed an outstanding level of resistance in the stem test. Resistant lines also had fewer sclerotia forming in stems. New pre‐breeding material for the production of SSR resistant OSR cultivars relevant to conditions in the UK and Europe has therefore been identified.     

Overexpression of barley oxalate oxidase gene induces partial leaf resistance to Sclerotinia sclerotiorum in transgenic oilseed rape

Sclerotinia stem rot (SSR) is a severe disease of oilseed rape, which severely impacts the crop productivity worldwide. Sclerotinia sclerotiorum causes SSR, resulting in the secretion of oxalic acid (OA), which can be further degraded to carbon dioxide (CO₂) and hydrogen peroxide (H₂O₂) by oxalate oxidase (OXO). In the present investigation, the barley oxalate oxidase (BOXO, Y14203) gene was introduced into oilseed rape by Agrobacterium‐mediated transformation to investigate the mechanism by which OXO promotes resistance to S. sclerotiorum. Compared to the control 72 h post‐inoculation, there were c. 15–61% fewer lesions on leaves of the transgenic oilseed rape, which thus exhibited a detectable level of partial resistance in leaf tissue to S. sclerotiorum. Transgenic oilseed rape also showed decreased oxalate and increased hydrogen peroxide levels compared to the control, and the expression of defence response genes involved in the hydrogen peroxide signalling pathway was also induced. Therefore, the improved resistance of oilseed rape could be attributed to the enhanced OA metabolism, production of hydrogen peroxide and the hydrogen peroxide‐mediated defence levels during infection.     

Polygalacturonase inhibiting proteins fromAllium porrumL. and their role in plant tissue against fungal endo-polygalacturonases

Five endo-polygalacturonases (PGs), three produced in culture filtrate byFusarium moniliforme, Sclerotium cepivorumandBotrytis aclada,respectively, and two (one acidic and one basic isoform) obtained fromSclerotinia sclerotiorumsoybean infected hypocotyls, were purified in order to characterize the activity of polygalacturonase inhibitor(s) (PGIP(s)) from leek stalk tissue (Allium porrumL.). Three apparently different PGIPs (PGIP-I, PGIP-II and PGIP-III) were purified from the leek tissue. The two more abundant PGIPs (PGIP-I and PGIP-III), although possessing similar pIs of about 6.5, differed in chromatographic behaviour, their molecular mass (39 and 42 kDa, respectively), and specific activity when assayed with the fungal endo-PGs. In addition, PGIP-I was solubilized from tissue homogenate with a low-salt buffer whilst PGIP-III needed a high-salt buffer for extraction (behaving as an ionically wall-bound protein). PGIP-II had very similar properties to PGIP-I, but was extracted using the high-salt buffer. The purified PGIPs and the crude leek extract showed similar inhibition activity patterns against the five fungal endo-PGs. The maximum inhibition activity was observed against the basic endo-PG fromS. sclerotiorum,followed by the acidic endo-PG ofS. sclerotiorumand the endo-PG fromB. aclada.In contrast, no inhibition of endo-PGs fromS. cepivorumandF. moniliformewas observed. Four different concentrations of the five fungal endo-PGs were incubated separately with slices of leek stalk, and the galacturonides released in the incubation mixture were measured. At every level used the endo-PGs ofF. moniliformeandS. cepivorumshowed the maximum activity in uronide releasing. The endo-PGs ofS. sclerotiorum(acidic PG) andB. acladawere active only when high levels were used while the basic endo-PG ofS. sclerotiorumwas not active in combustion with any level of PGIP. These results indicate that a close relationship exists between PGIP activityin vitroand the ability of PGIP to protect leek tissue from endo-PG degradation.     

White mould of sweet basil: conditions influencing its development in greenhouses and cultural measures for disease management

During the winter season, Sclerotinia sclerotiorum infects the stem bases of greenhouse‐grown sweet basil plants and, in severe epidemics, it may also infect the shoots. Sclerotia of S. sclerotiorum, and the ascospores that are released from the apothecia that form on them, serve as the inoculum for white mould epidemics. This research aimed to identify cropping parameters associated with lower incidence of white mould in a survey of the main basil‐growing region in Israel, and study cultural methods that might suppress the disease. The survey revealed that this mould, in the main growing area in Israel, has one cycle of infection. Factors associated with increased moisture in the greenhouse were found to be associated with increased levels of the disease. The use of a lower planting density reduced the incidence of white mould in semi‐commercial experimental plots, as well as the severity of the disease on shoots infected by S. sclerotiorum after harvest, in comparison to the commonly used higher planting density, with no negative effect on yield. Mulching the beds with polyethylene effectively reduced disease, and a combination of polyethylene mulch and increased plant spacing reduced disease severity on cut shoots in a synergistic manner. In conclusion, cultural control methods reduced disease incidence under field conditions and severity of the disease on cut shoots.     

Biocontrol of sclerotinia stem rot (Sclerotinia sclerotiorum) of soybean using novel Bacillus subtilis strain SB24 under control conditions

Sclerotinia stem rot (SSR), caused by Sclerotinia sclerotiorum, is a major disease of soybean in Canada. Laboratory and greenhouse experiments were conducted to evaluate potential effectiveness of cell suspensions, cell‐free culture filtrates and broth cultures of Bacillus subtilis strain SB24 for suppression of SSR. The SB24 cell suspensions and cell‐free culture filtrates significantly reduced mycelial growth of S. sclerotiorum by 50 to 75% and suppressed sclerotial formation by > 90%. The severity on soybean was negatively correlated (r < ?0·84, P < 0·01) to the concentrations of cell suspension, cell‐free culture filtrate and broth culture applied. The cell suspension and broth culture preparations significantly (P < 0·01) reduced SSR severity by 45 to 90% at concentrations ranging from 5 × 10⁶ to 10⁹ CFU mL^?1. The most effective concentration was 5 × 10⁸ CFU mL^?1 for all three preparations, reducing the severity by 60 to 90%. The B. subtilis SB24 was most effective in reducing disease severity when applied ≤ 24 h before plant inoculation with S. sclerotiorum and a significant effectiveness was observed up to 15 days after plant inoculation. The population density of B. subtilis on soybean leaves decreased by 1·5 to 2·5 log units over 15 days under field conditions, and by 0·8 log units over 5 weeks under control conditions. The decrease in population density was significantly correlated with rainfall in the field (r < ?0·93, P < 0·01), suggesting that the biocontrol bacteria may be washed away by rain.     

Tolerance ofsclerotinia sclerotiorum to glyceollin i,a soybean phytoalexin

Glyceollin I was fungistatic rather than fungicidal towardSclerotinia sclerotiorum. Within the mycelial mat apical cells were more vulnerable than mature cells.S. sclerotiorum removed large amounts of glyceollin from solution by a non-energy-requiring process. Contribution from Ministero dell’Università e della Ricerca Scientifica e Tecnologica.     

Efficiency of isolates ofConiothyrium minitans as mycoparasites ofSclerotinia sclerotiorum,Sclerotium cepivorum andBotrytis cinerea on tomato stem pieces

Summary Twenty five isolates ofConiothyrium minitans were screened for antagonism toSclerotinia sclerotiorum in a Petri dish bioassay using tomato stem segments placed on sterile sand. The antagonistic activity of 23 isolates was quite uniform and only two less antagonistic isolates were identified. Antagonism, expressed as a reduction in the rate of tissue colonization byS. sclerotiorum, occurred, whetherC. minitans was co-inoculated at the same time, one day before or one day afterS. sclerotiorum, but was slightly restricted whenS. sclerotiorum was given a lead of one day. On average, 50–80% of sclerotia of S.sclerotiorum formed on the stem pieces were infected byC. minitans two weeks after inoculation. Excluding the less antagonistic isolates,Coniothyrium minitans was recovered from over 80% ofS. sclerotiorum-infected stem segments when co-inoculated but from a maximum of only 7% of stem pieces when exposed toC. minitans alone. When the experiments were carried out on non-sterile soil instead of sterile sand, infection of stem pieces byS. sclerotiorum was reduced and recovery ofS. sclerotiorum andC. minitans from stem segments was decreased. SevenC. minitans isolates were also screened againstSclerotium cepivorum andBotrytis cinerea and, whereas the effect ofC. minitans onS. cepivorum-infected tissue and sclerotia was essentially similar to that observed withS. sclerotiorum, B. cinerea infected tissue and sclerotia were not invaded by the antagonist.     

Activity of carbendazim,dimethachlon, iprodione,procymidone and boscalid against Sclerotinia stem rot in Jiangsu Province of China

Carbendazim (MBC) was widely used to control Sclerotinia stem rot routinely during the 1980s in China, but development of MBC resistance in the causal agent Sclerotinia sclerotiorum led to control failures of this disease. In this study it was found that the MBC resistance in S. sclerotiorum populations was widespread throughout Jiangsu Province with a resistance frequency of 29.54% in the 1786 collected isolates during the growing seasons of 2006 to 2008. The resistance frequencies differed among sampled cities, ranging from 3.1% to 54.9%. The field MBC-resistant isolates showed comparable mycelial growth, sclerotia production and pathogenicity to the wild-type sensitive isolates, which suggested that the field MBC-resistant isolates might have sufficient parasitic fitness to compete with the field MBC-sensitive isolates in the field. In the in vitro sensitivity test, boscalid showed greater activity against S. sclerotiorum than dicarboximide fungicides (dimethachlon, iprodione and procymidone). The treatment 50% boscalid (WG) 125 g a.i. ha⁻¹ was comparable in efficacy to the treatment 50% iprodione (WP) 600 g a.i. ha⁻¹, and better than other treatments of 6% dimethachlon (WP) 690 g a.i. ha⁻¹ and 50% procymidone (WP) 337.5 g a.i. ha⁻¹, whereas MBC failed to control Sclerotinia stem rot (control efficacy only 16.0%). The most active agent for controlling Sclerotinia stem rot was boscalid in our study.     

Infection of alfalfa pollen bySclerotinia sclerotiorum

Blossom blight, caused bySclerotinia sclerotiorum, has become an important disease of alfalfa (Medicago sativa L.) in seed production areas of western Canada. Studies using light microscopy and scanning and transmission electron microscopy revealed that pollen grains of alfalfa are susceptible to infection byS. sclerotiorum. Ascospores ofS. sclerotiorum germinated readily in water with or without pollen grains. Examinations of ascospore—pollen mixtures incubated at room temperature (20–22°C) for 5 days revealed that numerous pollen grains were infected byS. sclerotiorum by direct hyphal penetration through the equatorial germinative pores or through the exine and intine layers of the pollen wall without the formation of infection cushions or appressoria. After penetration, hyphae ramified within the pollen grains, causing plasmolysis of the cytoplasmic membrane and eventual disintegration of the pollen cytoplasm. The study suggests that alfalfa pollen may play a role in the epidemiology of blossom blight in alfalfa.     

Chemical and biological control of Sclerotinia sclerotiorum in witloof chicory culture

BACKGROUND: Sclerotinia sclerotiorum (Lib.) de Bary is a major pathogen of witloof chicory. For lack of authorised field treatment, post‐harvest sprays with dicarboximide fungicides have been standard practice since the 1970s to prevent root rot and chicory heart decay during the forcing phase. However, the registration of procymidone and vinclozolin has been withdrawn in Europe. The development of organic agriculture and the necessity to reduce fungicide applications in conventional agriculture prompted an assessment of the efficacy of new fungicides and the use of the mycoparasite Coniothyrium minitans (Campbell). RESULTS: A mixture of the fungicides fludioxonil and cyprodinil (Switch^®) applied on chicory roots achieved a very good control of S. sclerotiorum (up to 95%). The use of C. minitans limited root infection, both when applied in the field (50–65% efficacy) and before the forcing period (post‐harvest treatment up to 80%). CONCLUSION: In organic agriculture, two treatments with C. minitans (in field and later at the forcing period) could improve protection against S. sclerotiorum. In conventional agriculture, after the field biological treatment, a post‐harvest chemical treatment could be applied. The addition of other prophylactic methods could lead to a high level of performance in practice against decay caused by S. sclerotiorum. Copyright © 2010 Society of Chemical Industry     

Use of <Emphasis Type="Italic">Coniothyrium minitans</Emphasis> as a biocontrol agent and some molecular aspects of sclerotial mycoparasitism

The use of the sclerotial mycoparasite Coniothyrium minitans as a biological control agent of diseases caused by sclerotium-forming pathogens especially Sclerotinia sclerotiorum is briefly reviewed. A number of studies have examined production and application methods, integrated control, ecology, and modes of action in order to understand the biology of the mycoparasite and enhance activity and reproducibility of use. Recently, development of a number of molecular-based techniques has begun to allow the examination of genes involved in mycoparasitism. Some of these procedures have been applied to identify pathogenicity genes involved in the infection of sclerotia of S. sclerotiorum by C. minitans and this work is discussed.     

Reaction of glucosinolate-myrosinase defence system in <Emphasis Type="Italic">Brassica</Emphasis> plants to pathogenicity factor of <Emphasis Type="Italic">Sclerotinia sclerotiorum</Emphasis>

The glucosinolate-myrosinase defence system, specific to Brassicales plants, produces toxic volatile compounds during mechanical injury or pathogen attack. The reaction of this system to oxalic acid, known as a pathogenicity factor of Sclerotinia sclerotiorum, is not fully understood. The hydrolysis of glucosinolates was studied at varying conditions in the presence of oxalic acid in the substrate. In a bioassay, colonies of the pathogen were exposed to volatiles from hydrated mustard powder used as a myrosinase and glucosinolate source. The glucosinolate-myrosinase (GSL-M) system was activated in the presence of oxalic acid at a concentration and pH similar to that expected in vivo. Volatile production was inhibited only when the pH fell to 3 or below. It is unlikely that oxalic acid plays a significant role in disarming the GSL-M system during infection of Brassica hosts.     

Polygalacturonase isoenzymes and oxalic acid produced by Sclerotinia sclerotiorum in soybean hypocotyls as elicitors of glyceollin

The polygalacturonases (PG) and oxalic acid produced by Sclerotinia sclerotiorum in infected soybean hypocotyls were investigated as elicitors of the phytoalexin glyceollin I.Purification to homogeneity through isoelectrofocusing and ion-exchange fast protein liquid chromatography revealed three endo-PG isoenzymes (PG-I, PG-II and PG-IV) and one exo-PG (PG-III) in 6-day-old etiolated soybean hypocotyls infected with the B-24 isolate of S. sclerotiorum.PG-I and PG-III, in the range of concentrations tested (0·15–1·2 reducing units ml⁻¹), did not act as elicitors of glyceollin I synthesis. Some elicitor activity was shown by PG-II at 0·6–1·2 reducing units ml⁻¹. PG-IV, at lower doses (0·038–0·30 reducing units ml⁻¹), was even more effective in inducing phytoalexin synthesis. However higher concentrations of PG-IV induced tissue softening and decreased phytoalexin accumulation.PG-II and PG-IV released heat-stable elicitors from purified soybean cell walls supporting the evidence that uronides are intermediate inducers in elicitation by endo-PGs. Oxalic acid was an active elicitor of glyceollin I over the range of concentrations tested (0·31–20 m ) with the maximum at a concentration of 5 m . The inability of oxalic acid to release uronides from purified cell walls makes it unlikely that uronide intermediate elicitors are involved in elicitation by oxalic acid.