Cytotoxic function of xylanase VdXyn4 in the plant vascular wilt pathogen Verticillium dahliae

Phytopathogen xylanases play critical roles in pathogenesis, likely due to their ability to degrade plant structural barriers and manipulate host immunity. As an invader of plant xylem vessels, the fungus Verticillium dahliae is thought to deploy complex cell wall degrading enzymes. Comparative genomics analyses revealed that the V. dahliae genome encodes a family of six xylanases, each possessing a glycosyl hydrolase 11 domain, but the functions of these enzymes are undetermined. Characterizing gene deletion mutants revealed that only V. dahliae xylanase 4 (VdXyn4) degraded the plant cell wall and contributed to the virulence of V. dahliae. VdXyn4 displayed cytotoxic activity and induced a necrosis phenotype during the late stages of infection, leading to vein and petiole collapse that depended on the enzyme simultaneously localizing to nuclei and chloroplasts. The internalization of VdXyn4 was in conjunction with that of the plasma membrane complexLeucine-rich repeat (LRR)-receptor-like kinase suppressor of BIR1-1 (SOBIR1)/LRR-RLK BRI1-associated kinase-1 (BAK1), but we could not rule out the possibility that VdXyn4 may also act as an apoplastic effector. Immune signaling (in the SA–JA pathways) induced by VdXyn4 relative to that induced by known immunity effectors was substantially delayed. While cytotoxic activity could be partially suppressed by known effectors, they failed to impede necrosis in Nicotiana benthamiana. Thus, unlike typical effectors, cytotoxicity of VdXyn4 plays a crucial intracellular role at the late stages of V. dahliae infection and colonization, especially following pathogen entry into the xylem; this cytotoxic activity is likely conserved in the corresponding enzyme families in plant vascular pathogens.

By virtue of its cytotoxic activity, Verticillium dahliae Xylanase induces necrosis, leading to vein and petiole collapse that depends on the enzyme simultaneously localizing to nuclei and chloroplasts.     

Electrophoretic karyotype and gene mapping of the vascular wilt fungus Verticillium dahliae

The karyotype profile of Verticillium dahliae was resolved by pulse-field gel electrophoresis. It revealed 6 chromosomal bands that corresponded to 7 chromosomes as shown by RFLP analysis using as probe the telomeric consensus sequence (AACCCT)(5). The number of chromosomes was further verified by the sensitivity of the hybridization signals to Bal31 digestion and the exclusion of interfering mitochondrial DNA signals. The corresponding sizes of the seven separated chromosomes were 6.7, 5.6, 4.1, 3.4, 3.1, 3.1 and 2.4Mb, raising the total genomic size of the fungus to approximately 28.4Mb. Twenty five homologous V. dahliae genes obtained either from randomly sequenced clones or PCR amplification were used as hybridization probes and were located onto the seven chromosomes.     

Proteomic analysis of the sea-island cotton roots infected by wilt pathogen Verticillium dahliae

Verticillium wilt of cotton is a vascular disease mainly caused by the soil-born filamentous fungus Verticillium dahliae. To study the mechanisms associated with defense responses in wilt-resistant sea-island cotton (Gossypium barbadense) upon V. dahliae infection, a comparative proteomic analysis between infected and mock-inoculated roots of G. barbadense var. Hai 7124 (a cultivar showing resistance against V. dahliae) was performed by 2-DE combined with local EST database-assisted PMF and MS/MS analysis. A total of 51 upregulated and 17 downregulated proteins were identified, and these proteins are mainly involved in defense and stress responses, primary and secondary metabolisms, lipid transport, and cytoskeleton organization. Three novel clues regarding wilt resistance of G. barbadense are gained from this study. First, ethylene signaling was significantly activated in the cotton roots attacked by V. dahliae as shown by the elevated expression of ethylene biosynthesis and signaling components. Second, the Bet v 1 family proteins may play an important role in the defense reaction against Verticillium wilt. Third, wilt resistance may implicate the redirection of carbohydrate flux from glycolysis to pentose phosphate pathway (PPP). To our knowledge, this study is the first root proteomic analysis on cotton wilt resistance and provides important insights for establishing strategies to control this disease.     

Characterization of the glyoxalase I gene from the vascular wilt fungus Verticillium dahliae

A glyoxalase I gene homologue (VdGLO1) was identified in the vascular wilt fungus Verticillium dahliae by sequence tag analysis of genes expressed during resting structure development. The results of the current study show that the gene encodes a putative 345 amino acid protein with high similarity to glyoxalase I, which produces S-D-lactoylglutathione from the toxic metabolic by-product methylglyoxal (MG). Disruption of the V. dahliae gene by Agrobacterium tumefaciens-mediated transformation resulted in enhanced sensitivity to MG. Mycelial growth of disruption mutants was severely reduced in the presence of 5 mmol/L MG. In contrast, spore production in liquid medium was abolished at 1 mmol/L MG, although not at physiologically relevant concentrations of 相似文献   

大丽轮枝菌微菌核的萌发条件及致死温度

微菌核是大丽轮枝菌在土壤中的主要存活结构和初侵染源,在土壤中可存活14年之久,其数量及存活状况直接影响着大丽轮枝菌型黄萎病的发生为害程度。以棉花黄萎病菌Verticillium dahliae XJ2008菌株为试材,研究了微菌核萌发的最佳条件、致死温度及土壤温度对微菌核存活的影响。结果表明,20℃、pH8.0是微菌核萌发的最佳条件。大丽轮枝菌微菌核具有很强的耐高温特性,随着处理时间的延长,微菌核的萌发率呈下降趋势,在55℃及以上处理时其萌发率下降迅速,而在50℃及以下处理时其萌发率下降相对较慢,在55℃处理360min可使微菌核完全致死,而在40℃、45℃和50℃处理1,440min,仍然有少量的微菌核存活,但其萌发率随着时间的推移呈下降趋势。土壤微菌核模拟试验结果表明,土壤温度对微菌核有很强的致死作用,40℃条件下处理4d后土壤中的微菌核已全部死亡。该研究结果为通过覆膜增温防治作物黄萎病提供了理论依据。     

iTRAQ-based proteomics analysis of autophagy-mediated immune responses against the vascular fungal pathogen Verticillium dahliae in Arabidopsis

The mechanisms underlying the functional link between autophagy and plant innate immunity remain largely unknown. In this study, we investigated the autophagy-mediated plant defense responses against Verticillium dahliae (V. dahliae) infection by comparative proteomics and cellular analyses. An assessment of the autophagy activity and disease development showed that autophagic processes were tightly related to the tolerance of Arabidopsis plant to Verticillium wilt. An isobaric tags for relative and absolute quantification (iTRAQ)-based proteomics analysis was performed, and we identified a total of 780 differentially accumulated proteins (DAPs) between wild-type and mutant atg10-1 Arabidopsis plants upon V. dahliae infection, of which, 193 ATG8-family-interacting proteins were identified in silico and their associations with autophagy were verified for several selected proteins. Three important aspects of autophagy-mediated defense against V. dahliae infection were revealed: 1) autophagy is required for the activation of upstream defense responses; 2) autophagy-mediated mitochondrial degradation (mitophagy) occurs and is an important player in the defense process; and 3) autophagy promotes the transdifferentiation of perivascular cells and the formation of xylem hyperplasia, which are crucial for protection against this vascular disease. Together, our results provide several novel insights for understanding the functional association between autophagy and plant immune responses.     

Rhamnose synthase activity is required for pathogenicity of the vascular wilt fungus Verticillium dahliae

The initial interaction of a pathogenic fungus with its host is complex and involves numerous metabolic pathways and regulatory proteins. Considerable attention has been devoted to proteins that play a crucial role in these interactions, with an emphasis on so‐called effector molecules that are secreted by the invading microbe to establish the symbiosis. However, the contribution of other types of molecules, such as glycans, is less well appreciated. Here, we present a random genetic screen that enabled us to identify 58 novel candidate genes that are involved in the pathogenic potential of the fungal pathogen Verticillium dahliae, which causes vascular wilt diseases in over 200 dicotyledonous plant species, including economically important crops. One of the candidate genes that was identified concerns a putative biosynthetic gene involved in nucleotide sugar precursor formation, as it encodes a putative nucleotide‐rhamnose synthase/epimerase‐reductase (NRS/ER). This enzyme has homology to bacterial enzymes involved in the biosynthesis of the nucleotide sugar deoxy‐thymidine diphosphate (dTDP)‐rhamnose, a precursor of L‐rhamnose, which has been shown to be required for virulence in several human pathogenic bacteria. Rhamnose is known to be a minor cell wall glycan in fungi and has therefore not been suspected as a crucial molecule in fungal–host interactions. Nevertheless, our study shows that deletion of the VdNRS/ER gene from the V. dahliae genome results in complete loss of pathogenicity on tomato and Nicotiana benthamiana plants, whereas vegetative growth and sporulation are not affected. We demonstrate that VdNRS/ER is a functional enzyme in the biosynthesis of uridine diphosphate (UDP)‐rhamnose, and further analysis has revealed that VdNRS/ER deletion strains are impaired in the colonization of tomato roots. Collectively, our results demonstrate that rhamnose, although only a minor cell wall component, is essential for the pathogenicity of V. dahliae.     

Soil inoculum density of Verticillium dahliae and Verticillium wilt of olive in Lebanon

In the Mediterranean basin, Verticillium Wilt of Olive (VWO) is diffused throughout its range of cultivation, causing severe yield losses and tree mortality. The disease was reported in almost all the Mediterranean and Middle East countries, and in Lebanon it is of increasing significance also on many valuable crops. The disease has already been reported on potato, peach and almond in the Bekaa valley; however, to date no information is available about the incidence of VWO and the inoculum density of Verticillium dahliae microsclerotia in soil of the main agricultural areas of Lebanon. Results from the present investigations demonstrate a high V. dahliae frequency in soils (75.3%), coupled with a mean soil inoculum density of 17.0 MS g^?1, clearly indicating a great impact on the production of susceptible hosts in Lebanon, mainly in Bekaa region. Molecular method to assess the microsclerotia inoculum density in soil allowed the detection of a higher frequency of infested soils, as compared with the traditional plating, thus confirming its higher sensitivity. The overall Verticillium wilt prevalence in the inspected olive orchards was 46.2%, and the frequency of V. dahliae‐infected trees was 25.7%. The widespread presence of V. dahliae in all olive growing areas of Lebanon enforces the adoption of measures aimed at reducing the soil inoculum density before any new olive plantation, and the use of strong phytosanitary regulations to improve the certification schemes of propagating material.     

Microsclerotia development in Verticillium dahliae: Regulation and differential expression of the hydrophobin gene VDH1

The vascular wilt fungus Verticillium dahliae produces persistent resting structures, known as microsclerotia, which are important for this plant pathogen's long-term survival. Previously, we identified a hydrophobin gene (VDH1) that is necessary for microsclerotial production. The current study of VDH1's expression, and its regulation, was undertaken to provide insight into the largely uncharacterized molecular mechanisms relevant to microsclerotial development. Reporter gene analysis showed that VDH1 is specifically expressed in developing microsclerotia, as well as in hyphal fusions and conidiophores, suggesting that VDH1 mediates the development of microsclerotia from conidiophores and other hyphal structures. We report also on the effects of nutrient availability on the regulation of microsclerotial development in V. dahliae; the gene's activity appears to be regulated in response to carbon availability. Lastly, constitutive expression of VDH1 results in delayed disease symptom development, but has no noticeable effect on in vitro microsclerotial development.     

Verticillium wilt of cacao in Uganda: the relationship between Verticillium dahliae and cacao roots

Isolates of Verticillium dahliae Kleb. from wilted cacao (Theobroma cacao L.), cotton (Gossypium hirsutum L.), and okra (Abelmoschus esculentus Medik.) penetrated all regions of living cacao tap and lateral roots and progressed intracellularly from the epidermis to the xylem in 4–6 days. The hypocotyl and tissues of the unerupted lateral roots beneath the epidermis resisted invasion. Host reactions included browning of extensively colonized cells, alteration (with apparent granulation) of the cytoplasm, and accumulation of materials in the lumina of endodermal cells. Resistance in the hypocotyl was associated with occasional thickening of inner tangential walls of colonized epidermal cells. The fungus formed conidia, microsclerotia, and narrow and wide hyphae within root tissues. The narrow hyphae predominated at the front of mycelial invasion of tissues while the broad hyphae developed behind this front. Limited studies under non-sterile conditions indicated that the apparent host-parasite interactions were similar to those observed with sterile roots and cultures of V. dahliae.     

Effects of Pratylenchus penetrans on development of strawberry wilt caused by Verticillium dahliae

The nematode Pratylenchus penetrans or the closely related P. fallax occurred in three out of four strawberry plantations infested with Verticillium dahliae surveyed in Kent. When plants of cv. Cambridge Vigour were inoculated with P. penetrans and V. dahliae together in field ‘micro-plots’ the nematode increased the rate of wilt development except when the concentration of V. dahliae microsclerotia in the soil was very low. In a pot experiment, under conditions not conducive to symptom expression, the incidence of infection was increased by nematodes in Cambridge Favourite, Cambridge Vigour and Redgauntlet; the incidence was least in Red-gauntlet, the most resistant cultivar. The nematode appeared to cause local changes in the root cortex which aided hyphal penetration of the adjacent tissues. Growth of strawberry plants in the absence of V. dahliae was not significantly affected even by large populations of the nematode, but growth was reduced by V. dahliae at all rates of inoculation in the field. Infection by Verticillium did not affect the total numbers of nematode per plant at the end of the experiments, although the number per g fresh weight was greater on the small amount of white root on severely diseased plants than on the larger amount on healthy or mildly diseased plants.     

大丽轮枝菌VdSCH9基因的功能研究

大丽轮枝菌是一种土传性植物病原真菌,可侵染多种植物并引发黄萎病。目前,人们关于大丽轮枝菌的侵染和致病机制的了解还很不深入。本文通过敲除大丽轮枝菌编码丝氨酸/苏氨酸的蛋白激酶基因VdSCH9,阐明了其在大丽轮枝菌生长发育及致病过程中的作用。SCH9基因在酵母中的表达与cAMP-PKA途径和TOR信号通路相关,对酵母的生长、压力响应和寿命等有重要作用。大丽轮枝菌VdSCH9敲除突变体的生长速率显著下降,菌落边缘菌丝更为稀疏,菌丝分枝减少,对棉花植株为害的平均病情指数为56.6,显著低于野生型和互补突变体的平均病情指数90.5和82.8,对茄子植株为害的平均病情指数为65.9,也显著低于野生型和互补突变体的平均病情指数91.1和89.8。另外,敲除突变体对于高渗透压、氧化还原压力、细胞膜和细胞壁完整性等压力条件的敏感性增强。因此,VdSCH9对于大丽轮枝菌的生长、压力响应及致病力均有重要作用。     

大丽轮枝菌 VdCPMO基因克隆与功能分析

大丽轮枝菌 Verticillium dahliae是一种典型的土传病原真菌,可侵染400多种植物引致黄萎病,造成巨大的经济损失。微菌核是大丽轮枝菌的特殊休眠结构,能够在土壤中存活14年之久,是病害的主要初侵染来源。本研究在前期微菌核萌发表达谱的基础上,选择上调倍数最高的环戊酮1,2-单加氧酶基因（ VDAG_03943）,进行克隆与功能分析。结果表明,该基因全长1 929bp,cDNA序列全长1 668bp,编码555个氨基酸组成的蛋白,命名为 VdCPMO。与野生型菌株JY相比,敲除突变体菌株的菌落生长减慢,微菌核萌发率显著降低,芽管平均长度明显较短,而互补突变体菌株与野生型菌株JY间无显著性差异。致病力测定结果显示,敲除突变体菌株的微菌核丧失了对棉花的致病力。     

甘肃省甜瓜黄萎病的病原鉴定

【背景】2013年11月在甘肃省兰州市皋兰县的日光温室秋冬茬甜瓜种植棚发现黄萎症状的甜瓜植株,病株率约为1%。【目的】明确甜瓜黄萎病的病原。【方法】采用组织分离法进行病原菌分离;通过科赫氏法则(Koch’s法则)明确分出病菌的致病性;采用形态学和分子生物学方法对病原菌进行种类鉴定。【结果】分离得到轮枝菌属真菌8株,轮枝菌属真菌的病株分出率达100%;2个代表性菌株GLTG-2和GLTG-5(显微特征相似但菌落形态和生长速率不同),在温度18-24℃及昼/夜光周期为11.5 h/12.5 h的试验条件下,人工接种可引起甜瓜苗矮化、枯萎;接种后40 d,枯死株率分别为70%和40%;BLASTn分析结果显示,菌株GLTG-2的rDNA-ITS序列与Verticillium dahliae菌株MRHf7的序列相似性达99.78%,菌株GLTG-5的rDNA-ITS序列与V.dahliae菌株MRHf7和Vd414的序列相似性达100.00%。【结论】引起甜瓜黄萎病的病原菌被鉴定为大丽轮枝菌(V. dahliae),这是大丽轮枝菌引起甜瓜黄萎病在我国和亚洲地区的首次报道。     

Quantitative assessment of the interaction between the antagonistic fungus Talaromyces flavus and the wilt pathogen Verticillium dahliae on eggplant roots

Quantitative aspects of the interaction between the antagonist Talaromyces flavus, the pathogen Verticillium dahliae and eggplant roots, were studied. When eggplant roots were inoculated with T. flavus, prior to the infection with the pathogen, the population density of T. flavus on V. dahliae-infected roots was at least 3 times higher than on healthy uninfected roots, and the proliferation of T. flavus on diseased eggplant roots was related to the severity of wilt symptoms, in the two levels of application of T. flavus studied. However, in all classes of disease severity tested (disease index, 0–3), the population density of T. Flavus on eggplant roots treated with 10⁶ ascospores g^–1 rooting mixture was significantly (p=0.05) higher than with 10⁵ ascospores g^–1. In roots treated with 10⁵ and 10⁶ T. flavus ascospores g^–1 rooting mixture, the population density of V. dahliae was reduced by 51% and 69%, respectively. When testing the relationships between the population density of V. dahliae in the roots and disease severity, no significant (p=0.05) difference was found between disease indexes 2 and 3. However, the density of V. dahliae on roots of plants with disease index 1 was significantly (p=0.05) lower than disease indexes 2 and 3. The positive relationship between the inoculum concentration of V. dahliae and the population density of T. flavus developed on eggplant roots was significant (p=0.001), linear, and highly correlated (r=0.945) on a logarithmic scale. In addition, the analysis of these data revealed a significant (p=0.05), high, negative and linear correlation (r=–0.985) between the log concentration of V. dahliae inoculum and the disease reduction achieved by T. flavus.     

A hydrophobin gene, VDH1, is involved in microsclerotial development and spore viability in the plant pathogen Verticillium dahliae

The wilt fungus Verticillium dahliae Kleb. produces desiccation- and cold-tolerant resting structures, known as microsclerotia, which are the primary source of disease inoculum in the field. In an exploration of the molecular mechanisms involved in the development of these important structures, we have identified in V. dahliae a differentially expressed, class II hydrophobin gene (VDH1). vdh1 mutants generated through targeted gene disruption show a severe reduction in microsclerotia production, indicating that the gene is important for this type of development. Although vdh1 mutants do produce normal conidiophores and spores, desiccation-tolerance of the spores is reduced. The VDH1 gene is not, however, needed for normal disease development in tomato. VDH1's functions are multi-faceted, and seem generally relevant to long-term survival in V. dahliae.     

Systemic fungicides in the control of strawberry wilt (Verticillium dahliae)

In a series of experiments between 1970 and 1973 the application of benomyl or thiophanate methyl to field-grown strawberries, planted on Verticillium-mtested land, gave control of wilt for up to 5 months, the duration of control being related to the amount of fungicide applied in the spring. Treatment of inoculated plants grown on in chloropicrin-fumigated soil was effective for at least two seasons. An autumn-planted multi-factorial experiment in heavily-infested soil showed that, to achieve maximum wilt control, it was advantageous to grow cv. Gorella rather than cv. Cambridge Vigour; to drench the runners at planting rather than to dip them in the fungicide suspension; and to use a high concentration (0–075 % a-i-) and large volume (600 ml per plant) for a supplementary treatment in May rather than a lower concentration (0.025 %) ^or smaller volume (400 ml). There were small but significant advantages in applying benomyl rather than thiophanate methyl, and in using 0–2% a.i. suspension at planting rather than 0–05%. No advantage was gained by dividing the spring application into two equal doses applied 2 wk apart. Extrapolation from the logarithmic relation between wilt index and total dose of fungicide applied in the spring suggested that I.I g/plant would have given almost complete control until October; such control had been achieved in an earlier experiment in which 1–2 g/plant was applied. Crop yield in the second year was determined by the treatment applied in the first year, but although these treatments had given significantly better control of wilt in Gorella than in Cambridge Vigour, the greater growth and yield potentials of the latter cultivar had an over-riding effect on crop production; Cambridge Vigour yielded more than Gorella under all chemical treatments, but in the absence of treatment Gorella gave a larger crop than Cambridge Vigour. A proposed regime, entailing spring and autumn applications, is aimed at minimizing the colonization of the plant throughout the year, thus reducing the production of new inoculum and, by limiting the quantity of the pathogen in contact with the systemic chemicals, minimizing the probability of selecting fungicide-resistant variants of V. dahliae.