Ss-Sl2, a novel cell wall protein with PAN modules, is essential for sclerotial development and cellular integrity of Sclerotinia sclerotiorum

The sclerotium is an important dormant body for many plant fungal pathogens. Here, we reported that a protein, named Ss-Sl2, is involved in sclerotial development of Sclerotinia sclerotiorum. Ss-Sl2 does not show significant homology with any protein of known function. Ss-Sl2 contains two putative PAN modules which were found in other proteins with diverse adhesion functions. Ss-Sl2 is a secreted protein, during the initial stage of sclerotial development, copious amounts of Ss-Sl2 are secreted and accumulated on the cell walls. The ability to maintain the cellular integrity of RNAi-mediated Ss-Sl2 silenced strains was reduced, but the hyphal growth and virulence of Ss-Sl2 silenced strains were not significantly different from the wild strain. Ss-Sl2 silenced strains could form interwoven hyphal masses at the initial stage of sclerotial development, but the interwoven hyphae could not consolidate and melanize. Hyphae in these interwoven bodies were thin-walled, and arranged loosely. Co-immunoprecipitation and yeast two-hybrid experiments showed that glyceraldehyde-3-phosphate dehydrogenase (GAPDH), Woronin body major protein (Hex1) and elongation factor 1-alpha interact with Ss-Sl2. GAPDH-knockdown strains showed a similar phenotype in sclerotial development as Ss-Sl2 silenced strains. Hex1-knockdown strains showed similar impairment in maintenance of hyphal integrity as Ss-Sl2 silenced strains. The results suggested that Ss-Sl2 functions in both sclerotial development and cellular integrity of S. sclerotiorum.     

Sclerotial development in Sclerotinia sclerotiorum: awakening molecular analysis of a “Dormant” structure

Sclerotia are hard, asexual, resting structures which can survive for years in soil. In Sclerotinia sclerotiorum, which provides a good model system for studying sclerotial development, sclerotial development has been traditionally divided to three macroscopically distinct stages (initiation, development and maturation). However, additional phases (which can be visualized microscopically) indicate a complex, multi-step, process is involved. Environmental changes, primary metabolism and secondary messengers have been well documented factors affecting sclerotial development, yet analysis of the molecular mechanisms involved in sclerotial development is in its infancy. Here, we review the current status of the known molecular components involved in sclerotial development, with an emphasis on phosphorylative regulation of sclerotial development in S. sclerotiorum. Components such as cAMP-dependent protein kinase, ERK-like mitogen-activated protein kinase and Ser/Thr phosphatases type 2A and 2B, shown to regulate other developmental processes in fungi, have recently been shown to also be involved in regulation of sclerotium development. Reversible protein phosphorylation, as well as additional regulatory mechanisms of gene expression such as DNA methylation and ribosome inactivation, most likely function in concert with secondary metabolites, reactive oxygen species, pH and light in order to regulate sclerotial development in different fungi. The diversity of sclerotium-producing fungi promises to yield exciting variations into the molecular mechanisms regulating this developmental process in different species.     

Electrophoretic and Immunological Comparisons of Developmentally Regulated Proteins in Members of the Sclerotiniaceae and Other Sclerotial Fungi

The fungal stroma is a distinct developmental stage, a compact mass of hyphal cells enveloped by a melanized layer of rind cells which is produced from vegetative mycelium. Two types of stromata that are characteristic of members of the Sclerotiniaceae but are also produced in a wide range of other fungi, i.e., the determinate tuberlike sclerotium and the indeterminate platelike substratal stroma, were compared in these studies. Developmental proteins found in determinate sclerotial and indeterminate substratal stromata, but not in mycelia, were characterized and compared in 52 isolates of fungi, both ascomycetes (including 18 species in the Sclerotiniaceae and 5 species of Aspergillus) and the basidiomycete Sclerotium rolfsii. One-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis of mycelial, stromatal initial, and stromatal extracts demonstrated that all members of the Sclerotiniaceae produced proteins unique to stromatal extracts within a molecular weight range of 31,000 to 39,500 which composed 13 to 58% of the total protein in stromata. Proteins unique to the sclerotial stage were also produced in Sclerotium rolfsii and the Aspergillus species but within a generally lower-molecular-weight range of 11,000 to 30,000. The proteins were then characterized by two-dimensional electrophoresis to determine the number and isoelectric point of polypeptides composing each protein. Polyclonal antibodies were raised to the major 36-kDa sclerotial protein of Sclerotinia sclerotiorum (Ssp). Immunoblots demonstrated that all sclerotial proteins from species in the Sclerotiniaceae cross-reacted with anti-Ssp antibodies, while no cross-reaction was observed with proteins from substratal stromatal species in the Sclerotiniaceae, sclerotial species of Aspergillus, or Sclerotium rolfsii. Results of discriminant analysis of the data from competitive inhibition enzyme-linked immunosorbent assays were consistent with the results of immunoblotting. Three groupings, sclerotial species in the Sclerotiniaceae, substratal stromatal species in the family, and sclerotial species outside the family, were delimited on the basis of relative decreasing ability to compete for anti-Ssp antibody. These data demonstrate that stromatal proteins differ among different taxonomic groups of fungi and suggest that the Sclerotiniaceae may include two distinct lineages of genera.     

Increase in Endogenous and Exogenous Cyclic AMP Levels Inhibits Sclerotial Development in Sclerotinia sclerotiorum

Growth and development of a wild-type Sclerotinia sclerotiorum isolate were examined in the presence of various pharmacological compounds to investigate signal transduction pathways that influence the development of sclerotia. Compounds known to increase endogenous cyclic AMP (cAMP) levels in other organisms by inhibiting phosphodiesterase activity (caffeine and 3-isobutyl-1-methyl xanthine) or by activating adenylate cyclase (NaF) reduced or eliminated sclerotial development in S. sclerotiorum. Growth in the presence of 5 mM caffeine correlated with increased levels of endogenous cAMP in mycelia. In addition, incorporation of cAMP into the growth medium decreased or eliminated the production of sclerotia in a concentration-dependent manner and increased the accumulation of oxalic acid. Inhibition of sclerotial development was cAMP specific, as exogenous cyclic GMP, AMP, and ATP did not influence sclerotial development. Transfer of developing cultures to cAMP-containing medium at successive time points demonstrated that cAMP inhibits development prior to or during sclerotial initiation. Together, these results indicate that cAMP plays a role in the early transition between mycelial growth and sclerotial development.     

Role of mRNA 5'-terminal caps in translational dormancy of Physarum polycephalum

Translational regulation of protein synthesis accompanies sclerotization in Physarum polycephalum. Plasmodial and sclerotial poly(A)+ RNA were translated in a message-dependent wheat germ lysate in the presence of the cap analogue 7-methylguanosine-triphosphate to determine whether 5' structural alterations in mRNA accompany translational repression. The translation of plasmodial and sclerotial poly(A)+ RNA was reduced to identical levels suggesting that both RNA populations are capped. The 5'-termini of plasmodial and sclerotial poly(A)+ RNA were identified as m7G5'ppp5'Cm. Alterations in the 5'-cap of mRNA during sclerotization do not appear to be responsible for translational dormancy.     

ROS and trehalose regulate sclerotial development in Rhizoctonia solani AG-1 IA

Rhizoctonia solani AG-1 IA is the causal agent of rice sheath blight (RSB) and causes severe economic losses in rice-growing regions around the world. The sclerotia play an important role in the disease cycle of RSB. In this study, we report the effects of reactive oxygen species (ROS) and trehalose on the sclerotial development of R. solani AG-1 IA. Correlation was found between the level of ROS in R. solani AG-1 IA and sclerotial development. Moreover, we have shown the change of ROS-related enzymatic activities and oxidative burst occurs at the sclerotial initial stage. Six genes related to the ROS scavenging system were quantified in different sclerotial development stages by using quantitative RT-PCR technique, thereby confirming differential gene expression. Fluorescence microscopy analysis of ROS content in mycelia revealed that ROS were predominantly produced at the hyphal branches during the sclerotial initial stage. Furthermore, exogenous trehalose had a significant inhibitory effect on the activities of ROS-related enzymes and oxidative burst and led to a reduction in sclerotial dry weight. Taken together, the findings suggest that ROS has a promoting effect on the development of sclerotia, whereas trehalose serves as an inhibiting factor to sclerotial development in R. solani AG-1 IA.     

Stored Messenger Ribonucleoprotein Particles in Differentiated Sclerotia of Physarum polycephalum

Starvation induces vegetative microplasmodia of Physarum polycephalum to differentiate into translationally-dormant sclerotia. The existence and the biochemical nature of stored mRNA in sclerotia is examined in this report. The sclerotia contain about 50% of the poly(A)-containing RNA [poly(A)+RNA] complement of microplasmodia as determined by [³H]-poly(U) hybridization. The sclerotial poly(A)+RNA sequences are associated with proteins in a ribonucleoprotein complex [poly(A)+mRNP] which sediments more slowly than the polysomes. Sclerotial poly(A)+RNP sediments more rapidly than poly(A)+RNP derived from the polysomes of microplasmodia despite the occurrence of poly(A)+RNA molecules of a similar size in both particles suggesting the existence of differences in protein composition. Isolation of poly(A)+RNP by oligo (dT)-cellulose chromatography and the analysis of its associated proteins by polyacrylamide gel electrophoresis show that sclerotial poly(A)+RNP contains at least 14 major polypeptides, 11 of which are different in electrophoretic mobility from the polypeptides found in polysomal poly(A)+RNP. Three of the sclerotial poly(A)+RNP polypeptides are associated with the poly(A) sequence (18, 46, and 52 × 10³ mol. wt. components), while the remaining eight are presumably bound to non-poly(A) portions of the poly(A)+RNA. Although distinct from polysomal poly(A)+RNP, the sclerotial poly(A)+RNP is similar in sedimentation behavior and protein composition (with two exceptions) to the microplasmodial free cytoplasmic poly(A)+RNP. The results suggest that dormant sclerotia store mRNA sequences in association with a distinct set of proteins and that these proteins are similar to those associated with the free cytoplasmic poly(A)+RNP of vegetative plasmodia.     

Oxidative Stress in Relation to Lipid Peroxidation, Sclerotial Development and Melanin Production by Sclerotium rolfsii

Melanin pigments constituted 13.9% of the chemical composition of the sclerotial walls of Sclerotium rolfsii and was associated with proteins, reducing sugars and amino acids. The lipid and ash contents in the sclerotial walls were double those in the hyphal walls of the fungus. Increasing age of the culture and maturation of the sclerotia were always accompanied by elevation of lipid peroxides and melanin pigments. Such behaviour may indicate that lipid peroxidation and melanin formation are operating in parallel during sclerotial biogenesis and maturation. These two processes depend on the theory of oxidative stress, as affected by growth conditions. Both processes could be stopped or sharply retarded when subjected to some antioxidant growth factors such as vitamins (ascorbic acid), micro-elements (selenium) and sulfhydryl compounds (glutathione). A clear relation between oxidative stress, myceliogenic germination and lytic activity via melanin production was observed. This finding appears promising in applying a new control measure against diseases caused by sclerotia-producing fungi without using traditional toxic fungicides.     

Polyamine metabolism during sclerotial development of Sclerotinia sclerotiorum

A study on polyamine metabolism and the consequences of polyamine biosynthesis inhibition on the development of Sclerotinia sclerotiorum sclerotia was conducted. Concentrations of the triamine spermidine and the tetramine spermine, as well as ornithine decarboxylase and S-adenosyl-methionine decarboxylase activities, decreased during sclerotia maturation. In turn, the concentration of the diamine putrescine was reduced at early stages of sclerotial development but it increased later on. This increment was not related to de novo biosynthesis, as demonstrated by the continuous decrease in ornithine decarboxylase activity. Alternatively, it could be explained by the release of putrescine from the conjugated polyamine pool. α-Difluoro-methylornithine and cyclohexylamine, which inhibit putrescine and spermidine biosynthesis, respectively, decreased mycelial growth, but did not reduce the number of sclerotia produced in vitro even though they disrupted polyamine metabolism during sclerotial development. It can be concluded that sclerotial development is less dependent on polyamine biosynthesis than mycelial growth, and that the increase of free putrescine is a typical feature of sclerotial development. The relationship between polyamine metabolism and sclerotial development, as well as the potential of polyamine biosynthesis inhibition as a strategy for the control of plant diseases caused by sclerotial fungi are discussed.     

Major sclerotial polypeptides of psychrophilic pathogenic fungi: Intracellular localization and antigenic relatedness

Summary Major sclerotial polypeptides from the psychrophiles,Myriosclerotinia borealis (W 51),Coprinus psychromorbidus (LRS 131),Typhula idahoensis (W 21), andTyphula incarnata (W 21) were purified by using polyacrylamide gel electrophoresis and electroelution. Polyclonal antibodies were raised against these major sclerotial polypeptides. Immunofluorescence microscopy showed that the major sclerotial polypeptides from all four psychrophilic species were sequestered in discrete protein bodies of cultured and field-grown sclerotia. Western blot analysis indicated that all antisera reacted positively with their respective antigens, the major sclerotial polypeptides. Reciprocal immunological cross-reactions were observed between the major sclerotial polypeptides ofM. borealis (W 51) andT. idahoensis (W 21). Antiserum to the major sclerotial polypeptides of bothM. borealis andT. idahoensis also recognized the major sclerotial polypeptides ofC. psychromorbidus (LRS 131). It is suggested that the major sclerotial polypeptides of these psychrophilic plant pathogens may act as storage proteins.Abbreviations W 51 Myriosclerotinia borealis (W 51) - LRS 131 Coprinus psychromorbidus (LRS 131) - W 21 Typhula idahoensis (W 21) - W 29 Typhula incarnata (W 29) - anti W 51 antiserum to the major sclerotial polypeptide ofM. borealis W 51 - anti LRS 131 antiserum to the major sclerotial polypeptides ofC. psychromorbidus (LRS 131) - anti W 21 antiserum to the major sclerotial polypeptides ofT. idahoensis (W 21) - anti W 29 antiserum to the major sclerotial polypeptides ofT. incarnata (W 29) - SDS sodium dodecylsulfate - kDa kilodalton - PAGE polyacrylamide gel electrophoresis - HRP horseradish peroxidase - PBS phosphate buffered saline - TBS Tris buffered saline - FITC fluorescein isothiocyanate     

cAMP blocks MAPK activation and sclerotial development via Rap-1 in a PKA-independent manner in Sclerotinia sclerotiorum

Sclerotinia sclerotiorum is a filamentous ascomycete phytopathogen able to infect an extremely wide range of cultivated plants. Our previous studies have shown that increases in cAMP levels result in the impairment of the development of the sclerotium, a highly differentiated structure important in the disease cycle of this fungus. cAMP also inhibits the activation of a S. sclerotiorum mitogen-activated protein kinase (MAPK), which we have previously shown to be required for sclerotial maturation; thus cAMP-mediated sclerotial inhibition is modulated through MAPK. However, the mechanism(s) by which cAMP inhibits MAPK remains unclear. Here we demonstrate that a protein kinase A (PKA)-independent signalling pathway probably mediates MAPK inhibition by cAMP. Expression of a dominant negative form of Ras, an upstream activator of the MAPK pathway, also inhibited sclerotial development and MAPK activation, suggesting that a conserved Ras/MAPK pathway is required for sclerotial development. Evidence from bacterial toxins that specifically inhibit the activity of small GTPases, suggested that Rap-1 or Ras is involved in cAMP action. The Rap-1 inhibitor, GGTI-298, restored MAPK activation in the presence of cAMP, further suggesting that Rap-1 is responsible for cAMP-dependent MAPK inhibition. Importantly, inhibition of Rap-1 is able to restore sclerotial development blocked by cAMP. Our results suggest a novel mechanism involving the requirement of Ras/MAPK pathway for sclerotial development that is negatively regulated by a PKA-independent cAMP signalling pathway. Cross-talk between these two pathways is mediated by Rap-1.     

Deletion of the Delta12-oleic acid desaturase gene of a nonaflatoxigenic Aspergillus parasiticus field isolate affects conidiation and sclerotial development

AIMS: To investigate how linoleic acid affects conidial production and sclerotial development in a strictly mitotic Aspergillus parasiticus field isolate as related to improving biocompetitivity of atoxigenic Aspergillus species. METHODS AND RESULTS: We disrupted A. parasiticusDelta12-oleic acid desaturase gene (odeA) responsible for the conversion of oleic acid to linoleic acid. We examined conidiation and sclerotial development of SRRC 2043 and three isogenic mutant strains deleted for the odeA gene (DeltaodeA), either with or without supplementing linoleic acid, on one complex potato dextrose agar (PDA) medium and on two defined media: nitrate-containing Czapek agar (CZ) and Cove's ammonium medium (CVN). The DeltaodeA mutants produced less conidia than the parental strain on all media. Linoleic acid supplementation (as sodium linoleate at 0.3 and 1.2 mg ml(-1)) restored the DeltaodeA conidial production comparable to or exceeding the unsupplemented parental level, and the effect was medium dependent, with the highest increase on CVN and the least on PDA. SRRC 2043 and the DeltaodeA mutants were unable to produce sclerotia on CVN. On unsupplemented PDA and CZ, DeltaodeA sclerotial mass was comparable to that of SRRC 2043, but sclerotial number increased significantly to two- to threefold. Supplementing linoleic acid to media, in general, tended to decrease wild type and DeltaodeA sclerotial mass and sclerotial number. CONCLUSIONS: Linoleic acid stimulates conidial production but has an inhibitory effect on sclerotial development. The relationship between the two processes in A. parasiticus is complex and affected by multiple factors, such as fatty acid composition and nitrogen source. SIGNIFICANCE AND IMPACT OF STUDY: Conditions that promote sclerotial development differ from those required to promote maximum conidial production. Manipulation of content and availability of linoleic acid at different fungal growth phases might optimize conidial and sclerotial production hence increasing the efficacy of biocompetitive Aspergillus species.     

The effects of light and tyrosinase during sclerotium development in Sclerotium rolfsii Sacc.

Some effects of light on morphogenesis in Sclerotium rolfsii Sacc. were studied. Physiological competence to visible light developed during the first 120 h after inoculation, with an optimum sensitivity phase between 84 and 96 h that coincided with the leading hyphae reaching the edge of the Petri dish. Although sclerotial initials were produced in dark-grown cultures, light was necessary for the continuation of the developmental and maturation phases of sclerotial morphogenesis. Tyrosinase activity (o-diphenol: oxygen oxidoreductase, EC 1.10.3.1) was detected during sclerotial formation and the pH and temperature optima for his polyphenol oxidase in vitro were about 6.0 and 45 degrees C respectively. The enzyme was inhibited by cysteine. Similar activity levels of tyrosinase were obtained in blue and "white" light-grown cultures but in red light activity was comparable with that of dark-grown cultures. Laccase activity was not detected at any stage of development.     

药用真菌猪苓溶血素基因克隆和序列分析

利用3'-RACE-PCR方法首次从药用真菌猪苓中克隆得到与真菌形态发育相关的溶血素基因。结果表明,猪苓溶血素基因的全长cDNA为744bp,其中编码区占447bp,共编码148个氨基酸,推测其分子量约为15.79kDa,理论等电点为4.89。推定的猪苓溶血素蛋白具有与杨树菇溶血素类蛋白家族相同的结构域和功能位点,两者同源性为60%。系统进化树结果显示猪苓溶血素隶属于担子菌类群。实时荧光定量PCR分析结果表明在菌核形成初期猪苓溶血素基因表达量较高,且显著高于菌丝体中猪苓溶血素基因的转录水平,说明溶血素基因参与了猪苓菌核的形态发育。     

Immunolocalization and functional role of Sclerotium rolfsii lectin in development of fungus by interaction with its endogenous receptor

Many fungi are known to secrete lectins, but their functional roles are not clearly understood. Sclerotium rolfsii, a soilborne plant pathogenic fungus capable of forming fruiting bodies called sclerotial bodies, secrete a cell wall-associated Thomsen-Friedenreich antigen-specific lectin. To understand the functional role of this lectin, we examined its occurrence and expression during development of the fungus. Furthermore, putative endogenous receptors of the lectin were examined to substantiate the functional role of the lectin. Immunolocalization studies using FITC-labeled lectin antibodies revealed discrete distribution of lectin sites at the branching points of the developing mycelia and uniformly occurring lectin sites on the mature sclerotial bodies. During development of the fungus the lectin is expressed in small amounts on the vegetative mycelia and reaching very high levels in mature sclerotial bodies with a sudden spurt in secretion at the maturation stage. Capping of the lectin sites on the sclerotial bodies by lectin antibodies or haptens inhibit strongly the germination of these bodies, indicating functional significance of the lectin. At the maturation stage the lectin interacts with the cell wall-associated putative endogenous receptor leading to the aggregation of mycelium to form sclerotial bodies. The lectin-receptor complex probably acts as signaling molecule in the germination process of sclerotial bodies. Using biotinylated lectin, the receptors were identified by determining the specific lectin binding to lipid components, extracted from sclerotial bodies, and separated on thin-layer chromatograms. Preliminary characterization studies indicated that the receptors are glycosphingolipids and resemble inositolphosphoceramides. These findings together demonstrate the importance of lectin-receptor interactions to explain hitherto speculated functional role of the lectins and also the glycosphingolipids of fungi.     

Involvement of Ca2+ Channel Signalling in Sclerotial Formation of Polyporus umbellatus

Growth and morphogenesis transformation in Polyporus umbellatus were examined in the presence of various pharmacological compounds, to investigate signal transduction pathways that influence the development of sclerotia. Both the calcium channel blocker nifedipine and the calcium ionophor A23187 reduced sclerotial production in P. umbellatus; four classes of Ca²⁺ signal agent—including calcium chelators, calcium channel blockers, calcium ionophors and calmodulin inhibitors—were further studied. Among them, EGTA and BAPTA, as calcium chelators, exhibited a complete inhibitory effect on sclerotial formation, among the levels tested. Calcium channel blockers and calcium ionophors at the concentrations used in this study could not eliminate sclerotia formation completely, but did greatly reduce sclerotial production. Notoginsenoside in dosages >250 μg/ml produced a significant negative effect on mycelial growth, and it prevented sclerotial formation entirely at a dosage of 500 μg/ml; no other drug influenced vegetative growth at all. The calcium ionophor A23187 did not decrease sclerotial mean weight at low doses (20 nM); at higher doses (200 nM), however, sclerotial development was significantly reduced, albeit not completely halted. The CaM inhibitors (W-7 and chlorpromazine) could each completely stop sclerotial formation. Using Fluo-3/AM as the indicator of cytosolic free calcium, the Ca²⁺ content in the cytoplasm was found to have decreased significantly when hyphae were treated with different drugs, and there was no active Ca²⁺ signal in the sclerotial mycelium. In general, the results suggest that Ca²⁺ signal transduction may play an important role in sclerotial formation in P. umbellatus.     

Determination of optimal carbon source and pH value for sclerotial formation of Polyporus umbellatus under artificial conditions

Polyporus umbellatus is one of the precious medicinal fungi, with sclerotia used as a diuretic agent and antidote in China for many years. This has led to the present interest in producing sclerotia of P. umbellatus in the laboratory due to a decreased abundance in natural sources. Here, we investigated the determining factors for sclerotial formation in P. umbellatus. Five carbon sources, namely, maltose, fructose, glucose, sucrose and soluble starch with different initial pH values were evaluated for their effects on mycelial growth and sclerotial development of P. umbellatus. Maltose, fructose and glucose could induce sclerotial formation of P. umbellatus. Sucrose and soluble starch could stimulate growth of the fungus but had no effect on sclerotial formation. The most efficient sclerotial production occurred with maltose followed by fructose and a pH of 5. In addition, different macroscopically evident characteristics of sclerotial development of P. umbellatus induced by different carbon sources were also observed. Our findings could provide new insights into further research on sclerotial production in P. umbellatus under artificial cultivation.