Host‐induced gene silencing in the necrotrophic fungal pathogen Sclerotinia sclerotiorum

Sclerotinia sclerotiorum is a necrotrophic fungus that causes a devastating disease called white mould, infecting more than 450 plant species worldwide. Control of this disease with fungicides is limited, so host plant resistance is the preferred alternative for disease management. However, due to the nature of the disease, breeding programmes have had limited success. A potential alternative to developing necrotrophic fungal resistance is the use of host‐induced gene silencing (HIGS) methods, which involves host expression of dsRNA‐generating constructs directed against genes in the pathogen. In this study, the target gene chosen was chitin synthase (chs), which commands the synthesis of chitin, the polysaccharide that is a crucial structural component of the cell walls of many fungi. Tobacco plants were transformed with an interfering intron‐containing hairpin RNA construct for silencing the fungal chs gene. Seventy‐two hours after inoculation, five transgenic lines showed a reduction in disease severity ranging from 55·5 to 86·7% compared with the non‐transgenic lines. The lesion area did not show extensive progress over this time (up to 120 h). Disease resistance and silencing of the fungal chs gene was positively correlated with the presence of detectable siRNA in the transgenic lines. It was demonstrated that expression of endogenous genes from the very aggressive necrotrophic fungus S. sclerotiorum could be prevented by host induced silencing. HIGS of the fungal chitin synthase gene can generate white mould‐tolerant plants. From a biotechnological perspective, these results open new prospects for the development of transgenic plants resistant to necrotrophic fungal pathogens.     

The Effect of Nitrogen on Disease Development and Gene Expression in Bacterial and Fungal Plant Pathogens

Successful colonisation of plants by pathogens requires efficient utilisation of nutrient resources available in host tissues. Several bacterial and fungal genes are specifically induced during pathogenesis and under nitrogen-limiting conditions in vitro. This suggests that a nitrogen-limiting environment may be one of the cues for disease symptom development during growth of the pathogens in planta. Here we review recent literature on the effect of nitrogen and nitrogen-regulated genes on disease development, caused by phytopathogenic bacteria and fungi. Furthermore, the potential influence of nitrogen-limitation or general nutrient limitation on several in planta-induced bacterial and fungal pathogenicity, virulence and avirulence genes will be discussed.     

Victoria Blight,defense turned upside down

Genes that confer disease resistance to biotrophic pathogens typically encode nucleotide-binding, leucine-rich-repeat proteins (NB-LRRs). These proteins confer resistance by detecting the presence of virulence effectors secreted by biotrophic pathogens. Recognition triggers NB-LRR activation and subsequently, the defense response which often includes localized host cell death. The fungus, Cochliobolus victoriae, is a necrotrophic pathogen that causes a disease called Victoria Blight. Virulence of this fungus is dependent on its production of a peptide called “victorin” that has been traditionally described as a toxin. Only plants that respond to victorin are susceptible to Cochliobolus victoriae whereas those that do not are resistant to the fungus. Genetic and molecular analyses have revealed that victorin functions like a biotrophic effector recognized by a NB-LRR resistance protein in Arabidopsis. Further, numerous plant species express victorin sensitivity suggesting there are numerous NB-LRRs that recognize victorin. Thus, through expression of victorin, C. victoriae is able to exploit plant defense to cause disease and is capable of evoking this response in an array of different plants.     

高温处理西花蓟马若虫对其雌成虫寿命、繁殖力及后代发育的影响

温度是影响昆虫生长发育的重要生态因素之一,高温逆境作为一种绿色防控手段可以有效控制温室害虫种群发展。为了探究高温处理西花蓟马若虫对其种群发展的影响,本试验用41℃和43℃两个温度分别处理西花蓟马初孵若虫2、6、12、24和36h后,观察并记录其雌成虫寿命、繁殖力及后代发育指标的变化情况。结果表明,随着处理时间的延长,两个高温处理后西花蓟马雌成虫寿命,子代若虫总数、成虫总数和总存活率(若虫发育到成虫的存活率)均显著下降,后代雌雄性比呈总体下降趋势。41℃处理后,性比从2.30∶1降低到2.13∶1;43℃处理后从2.25∶1降低到2.07∶1,均明显低于对照的2.69∶1。另外,两性生殖种群相比于孤雌生殖种群更易遭受高温处理的影响。     

Class I hydrophobin BcHpb1 is important for adhesion but not for later infection of <Emphasis Type="Italic">Botrytis cinerea</Emphasis>

Hydrophobins are small secreted proteins unique to filamentous fungi. In this study, we cloned and characterized the class I hydrophobin gene BcHpb1 in the necrotrophic pathogen Botrytis cinerea. The BcHpb1 protein consisted of 117 amino acids. Similar to class I hydrophobins from other fungi, BcHpb1 contains eight conserved cysteine residues. The hydropathy plot of the BcHpb1 amino acid sequence was characteristic of a class I hydrophobin. These results indicated that the BcHpb1 gene encodes a class I hydrophobin. Vegetative growth of ΔBcHpb1 strains, null mutants of BcHpb1, was similar to that of the wild-type strain as were the conidiophores, conidia, appressoria and virulence on host plants. However, adherence of ΔBcHpb1 strains to hydrophobic surfaces was greatly reduced, implying that BcHpb1 is important for the hydrophobicity of conidia and that BcHpb1 may be required to adhere to plant surfaces under certain environmental conditions.     

Histopathology of Sclerotinia sclerotiorum infection and oxalic acid function in susceptible and resistant soybean

The success of the necrotrophic fungus Sclerotinia sclerotiorum is largely dependent on its major virulence factor, oxalic acid (OA). Virulence is lost in transgenic plants that express OA degrading enzymes, e.g. oxalate oxidase (OxO). The histopathology of S. sclerotiorum infection and OA accumulation was examined in a transgenic soybean line over‐expressing OxO (OxO‐OE) and its isogenic parent (WT). In situ flower inoculation showed that the OxO‐OE plants were highly resistant to the pathogen while the WT parents were susceptible. This difference in resistance was not apparent in the floral tissues, as aggressive hyphal activity was similar on both hosts, showing that high OxO activity and low OA accumulation in OxO‐OE was not a deterrent. However, the process of fungal infection on excised leaf tissue differed on the two hosts. Primary lesions developed and showed similar severe ultrastructural damage on both hosts but rapid lesion expansion (colonization) proceeded only on the WT, concomitant with OA accumulation. Oxalic acid rose in OxO‐OE 1 day post‐inoculation and did not change over the following 3 days, showing that colonization can be blocked by maintaining low levels of OA. However, OxO degradation of OA did not deter initial host penetration and primary lesion formation. This shows that OA, the major virulence factor of S. sclerotiorum, is critical for host colonization but may not be required during primary lesion formation, suggesting that other factors are contributing to the establishment of the primary lesion.     

灰黄青霉CF3对马铃薯土传病原真菌的拮抗性及其促生作用

为探索灰黄青霉Penicillium griseofulvum CF3对马铃薯土传病害病原真菌立枯丝核菌Rhizoctonia solani、茄病镰刀菌Fusariumsolani、硫色镰刀菌F.sulphureum及大丽轮枝菌Verticillium dahliae的拮抗性及对马铃薯的促生作用,采用菌丝生长速率法和甜瓜种子发芽法分别研究了CF3发酵液对病原菌菌丝的抑制作用、对立枯丝核菌微菌核形成的影响及其发酵液的促生作用,并采用盆栽试验法研究了CF3孢子粉对马铃薯植株的促生作用及对抗逆性的影响.CF3发酵滤液对4株病原真菌菌丝生长的抑菌率达53％～72.1％,对立枯丝核菌微菌核的抑制率达36.8％～100％,并显著促进甜瓜种子胚根、胚轴生长.灰黄青霉孢子粉拌土和包衣接种均能促进马铃薯植株生长并增强植株的抗逆性.其中,拌土接种使马铃薯地上植株鲜重和多酚氧化酶活性较对照分别增加38.3％和9％,丙二醛含量降低28.8％.研究表明灰黄青霉CF3对连作马铃薯常见土传真菌病害有较强的生防潜力,对马铃薯具有良好的促生作用.     

Pathogenicity and toxicity of Fusarium tucumaniae and Fusarium crassistipitatum to soybean and Arabidopsis thaliana

Sudden death syndrome (SDS) of soybean is a fungal disease caused by at least four distinct Fusarium species: F. tucumaniae, F. virguliforme, F. brasiliense, and F. crassistipitatum. All four species are present in Argentina. These fungi are soilborne pathogens that only colonize roots and cause root necrosis. However, damage also reaches the aboveground part of the plant, and foliar chlorosis and necrosis, followed by premature defoliation, can be observed. Although the pathogenicity and phytotoxicity of F. virguliforme has been well characterized, knowledge regarding disease development by other fungal species is scarce. In this study, two plant species, soybean (Glycine max) and Arabidopsis thaliana, and isolates from two fungal species, F. tucumaniae and F. crassistipitatum, were used to comparatively analyse the fungal pathogenicity and the phytotoxicity of volatile organic compounds (VOCs) and cell-free culture filtrates. Fungal inoculation had a significant effect on plant growth, regardless of the plant species. In addition, infected soybean plants showed disease incidence and foliar and root symptoms. Inhibition of A. thaliana growth was not due to VOCs emitted by fungi. Instead, both pathogens were shown to produce toxins that caused typical SDS foliar symptoms in soybean and root length reduction in A. thaliana. As far as we know, this is the first report that demonstrates that F. tucumaniae and F. crassistipitatum affect A. thaliana growth and emit VOCs, and that F. crassistipitatum produces toxins.     

Chitinase modifying proteins from phylogenetically distinct lineages of Brassica pathogens

Chitinase modifying proteins, cmps, are secreted fungal proteases that truncate specific plant class IV chitinases by cleaving peptide bonds in their amino termini. We recently identified a cmp from the Zea mays (maize) pathogen Fusarium verticillioides and found that it is a member of the fungalysin class of proteases. We also found that Alternaria brassicae, a pathogen of the mustard plant family Brassicaceae, secretes a protease with the same activity. To determine which pathogens of Brassicaceae plants secrete fungalysin cmps, we tested protein extracts from twenty fungi that had been isolated from diseased plants. Each fungal isolate was grown saprotrophically on maize and canola seeds. Secreted fungal proteins were extracted from cultures and incubated with three purified plant chitinases: ChitA and ChitB from maize, and AtchitIV3 from Arabidopsis thaliana. We found that fungalysin cmps were secreted by fungal pathogens distributed among five families in three major Ascomycota classes (Dothideomycetes, Leotiomycetes and Sordariomycetes). Of four fungal species that did not secrete fungalysin cmp activity, three secreted other cmps that truncated maize ChitA and ChitB by cleaving other peptide bonds. AtchitIV3 was only susceptible to truncation by fungalysin cmps. These results show that cmps are commonly secreted by fungal pathogens of Brassicaceae and suggest that interfering with fungalysin cmp activity may improve plant resistance to multiple fungal diseases.     

Absence of detectable yield penalty associated with insensitivity to Pleosporales necrotrophic effectors in wheat grown in the West Australian wheat belt

Genetic disease resistance is widely assumed, and occasionally proven, to cause host yield or fitness penalties due to inappropriate activation of defence response mechanisms or diversion of resources to surplus preformed defences. The study of resistance gene trade‐offs has so far been restricted to biotrophic pathogens. In some Pleosporales necrotrophic interactions, quantitative resistance is positively associated with insensitivity to effectors. Host lines that differ in sensitivity can easily be identified amongst current cultivars and advanced breeding lines. Large wheat cultivar trials were used to test whether lines sensitive or insensitive to three necrotrophic effectors from Pyrenophora tritici‐repentis and Parastagonospora nodorum differed in yield when subjected to natural disease and stress pressures in the West Australian wheat belt. There was no significant yield penalty associated with insensitivity to the fungal effectors ToxA, SnTox1 and SnTox3. Some yield gains were associated with insensitivity and some of these gains could be attributed to increased disease resistance. It is concluded that insensitivity to these effectors does not render such plants more vulnerable to any relevant biotic or abiotic stress present in these trials. These results suggest that the elimination of sensitivity alleles for necrotrophic effectors is a safe and facile strategy for improving disease resistance whilst maintaining or improving other desirable traits.     

Comparative resistance to foliar fungal pathogens in transgenic carrot plants expressing genes encoding for chitinase, β-1,3-glucanase and peroxidise

Genes encoding an acidic wheat class IV chitinase (383), an acidic wheat β 1,3-glucanase (638) and a rice cationic peroxidase (POC1) were introduced into ‘Nantes Coreless’ carrot (Daucus carota) by Agrobacterium-mediated transformation. The genes were introduced singly or in various combinations followed by selection imposed by the herbicide phosphinothricin. Regenerated plantlets were screened for presence and expression of the three transgenes using PCR, Southern and Northern hybridisations. Eighteen transgenic lines expressing a single transgene and 2 lines each co-expressing 638/383 and 383/POC1 were assessed for resistance to the necrotrophic fungal pathogens Botrytis cinerea and Sclerotinia sclerotiorum. Percentage leaf area diseased was measured 4 and 7 days after inoculation (dai) and compared to non-transformed control plants. Six lines expressing β-1,3-glucanase 638 alone had no enhanced resistance to B. cinerea at 4 dai and only slight resistance to S. sclerotiorum; there was no effect at 7 dai. Two out of the six lines expressing 383 alone had enhanced tolerance to both pathogens with a 20–50% reduction in disease development at 7 dai. Two lines co-expressing 638/383 had slight reductions in disease by (10–20%) similar to that of the lines expressing chitinase 383 alone. Highest levels of disease resistance were seen in transgenic lines expressing POC1, alone or in combination with chitinase 383. Disease symptoms were slower to develop and symptoms were reduced by up to 90% for B. cinerea and 70% for S. sclerotiorum. The 383/POC1 co-expressing plants developed disease at levels similar to that of POC1 alone. Petioles of plants over-expressing POC1 had higher levels of lignin accumulation constitutively compared to control plants, which was greatly enhanced following inoculation with S. sclerotiorum. These results indicate that peroxidase over-expression can lead to significant disease reduction against necrotrophic pathogens in transgenic carrot plants.     

Production of hydrogen peroxide and expression of ROS‐generating genes in peach flower petals in response to host and non‐host fungal pathogens

Reactive oxygen species (ROS) play dual roles in plant–microbe interactions in that they can either stimulate host resistance or enhance pathogen virulence. Innate resistance in peach (Prunus persica) to the brown rot fungal pathogen Monilinia fructicola is very limited, and knowledge of the mechanism of virulence is rudimentary. In this study, production of hydrogen peroxide, a major component of ROS, was determined in peach flower petals in response to M. fructicola (a host pathogen) and Penicillium digitatum (a non‐host pathogen). Monilinia fructicola was able to infect flower petals while P. digitatum was not. During the host‐specific interaction, M. fructicola induced hydrogen peroxide accumulation in flower petals. Application of exogenous antioxidants significantly reduced hydrogen peroxide accumulation as well as the incidence of brown rot disease. Application of M. fructicola spores to the surface of intact flower petals induced gene expression and increased enzyme activity of NADPH oxidase and cell wall peroxidase in host tissues, resulting in the production of hydrogen peroxide. Petals inoculated with M. fructicola exhibited high levels of protein carbonylation and lipid peroxidation. No significant response in gene expression, enzyme activity or hydrogen peroxide levels was observed in peach flower petals treated with P. digitatum. These results suggest that M. fructicola, as with other necrotrophic fungi, uses the strong oxidative response as part of a virulence mechanism.     

Evaluating the importance of the tan spot ToxA–Tsn1 interaction in Australian wheat varieties

The necrotrophic fungal pathogen Pyrenophora tritici‐repentis (Ptr) causes the major wheat disease tan spot, and produces multiple necrotrophic effectors that contribute to virulence. The proteinaceous effector ToxA induces necrosis in wheat genotypes possessing the Tsn1 gene, although the importance of the ToxA–Tsn1 interaction itself in varietal disease development has not been well studied. Here, 40 Australian spring wheat varieties were assessed for ToxA sensitivity and disease response to a race 1 wildtype Ptr isolate and ToxA‐deleted strain at both seedling and tillering growth stages. ToxA sensitivity was generally associated with disease susceptibility, but did not always predict spreading necrotic symptoms. Whilst the majority of Tsn1 varieties exhibited lower disease scores following toxa mutant infection, several exhibited no distinct differences between wildtype and toxa symptoms. This implies that ToxA is not the major determinant in tan spot disease development in some host backgrounds and indicates the presence of additional effectors. Unexpectedly, several tsn1 varieties exhibited a reduction in disease severity following toxa mutant inoculation, which may suggest an indirect role for ToxA in pathogen fitness. Additionally, increased chlorosis was observed following toxa mutant infection in three varieties, and further work is required to determine whether this is likely to be due to ToxA epistasis of ToxC symptoms. Taken together, these observations demonstrate that Ptr interacts with the host in a complex and intricate manner, leading to a variety of disease reactions that are dependent or independent of the ToxA–Tsn1 interaction.     

Maceration of plant tissue by fungi is inhibited by recombinant antipectinase antibodies

Polyclonal antiserum from mice immunized with extracellular proteins from Rhizoctonia solani inhibited pectinase and cellulase activities in cell free culture supernatants of Rhizoctonia solani. Spleen mRNA from these mice was used to construct a cDNA library from which antipectinase ScFv antibodies were isolated using phage display techniques. Soluble ScFv antibodies produced by individual clones in Escherichia coli inhibited polygalacturonase in the culture supernatants of a range of fungal pathogens, including ascomycetes, basidiomycetes, and oomycetes. The soluble antibodies also inhibited maceration of potato tissue by these pathogens.     

草莓胶孢炭疽菌CFEM候选效应子的生物信息学鉴定及其侵染过程中的转录分析

病原真菌通常分泌效应子到寄主组织中调控寄主的生理过程,从而有利于其侵染。CFEM(common in several fungal extracellular membrane)蛋白是真菌所独有的,且与致病性密切相关。本研究利用Pfam数据库对草莓胶孢炭疽菌全基因组进行搜索,鉴定获得22个CFEM蛋白。对CFEM蛋白的信号肽、跨膜结构域和亚细胞定位进行分析,结果表明仅有8个CFEM蛋白为分泌蛋白。对CFEM分泌蛋白在不同侵染阶段的转录情况进行转录组学及RT-PCR分析,结果显示8个CFEM蛋白在侵染后不同时期均有表达。其中,1个CFEM分泌蛋白于附着胞形成期特异表达,2个于活体寄生阶段特异表达,2个于死体寄生阶段特异表达。综合上述分析结果,预测这8个分泌蛋白可能为草莓胶孢炭疽菌的效应子。本研究为深入解析植物病原真菌CFEM效应子提供了理论依据。     

Pathogenicity and virulence factors of Pseudomonas syringae

In 1994, Oku reported that plant pathogens, mainly fungal pathogens, require three essential abilities to infect plants: to enter plants, to overcome host resistance, and to evoke disease. Because the infectious process of phytopathogenic bacteria differs from that of fungal pathogens, we have attempted to characterize pathogenicity, the ability of a pathogen to cause disease, using the phytopathogenic bacterium Pseudomonas syringae as a representative pathogen. To establish infection and incite disease development, bacteria first have to enter a plant. This process requires flagella- and type IV pili-mediated motility, and active taxis is probably necessary for effective infection. After bacteria enter a plant’s apoplastic spaces, they need to overcome host plant resistance. To do this, they secrete a wide variety of hypersensitive response and pathogenicity (Hrp) effector proteins into the plant cytoplasm to interfere with pathogen/microbe-associated molecular pattern- and effector-triggered immunity, produce phytohormones and/or phytotoxins to suppress plant defense responses and extracellular polysaccharides to prevent access by antibiotics and to chelate Ca²⁺, and activate the multidrug resistance efflux pump to extrude antimicrobial compounds for successful colonization. Furthermore, to evoke disease, bacteria produce toxins and Hrp effectors that compromise a plant’s homeostasis and injure plant cells. The expression of these virulence factors depends on the infection processes and environmental conditions. Thus, the expression and function of virulence factors interact with each other, creating complex networks in the regulation of bacterial virulence-related genes.     

Evolution of Virulence in Natural Populations of the Satellite RNA of Cucumber mosaic virus

From 1986 to 1992, an epidemic of tomato necrosis caused by Cucumber mosaic virus (CMV) plus CMV satellite RNAs (satRNAs) occurred in eastern Spain. From 1989 onward, the frequency of tomato necrosis di-minshed, and it almost completely disappeared after 1991. Analyses of plants infected with CMV and with CMV satRNA and of the phenotype (necrogenic or nonnecrogenic for tomato) induced by some CMV satRNA variants, showed that the disappearance of tomato necrosis was due to changes in the genetic composition of the satRNA population (i.e., to its evolution toward decreased virulence). Analysis of components of the fitness of satRNA variants, necrogenic or nonnecrogenic for tomato, showed that necrogenic and nonnecrogenic variants did not differ in infectivity or in their accumulation level in tomato and that they represented the same fraction of encapsidated RNA. Other fitness components were positively correlated with the greater virulence of necrogenic variants, in that they were favored in mixed infections with nonnecrogenic variants and were more effectively passed into CMV progeny than were nonnecrogenic variants. On the other hand, necrogenic CMV satRNA variants caused a more pronounced depression in the accumulation of CMV than did nonnecro-genic variants, which could affect the efficiency of aphid transmission. Thus, the evolution of virulence in the CMV satRNA population can be explained by trade-offs between factors that determine virulence and factors that affect transmission, as predicted by theoretical models on the evolution of virulence in parasites.