Putative virulence factors of Botrytis cinerea acting as a wound pathogen

Abstract The grey mold fungus, Botrytis cinerea , is a wound pathogen of worldwide distribution, and causes rots of almost all fruits and vegetables. The fungus can also penetrate directly from appressoria to cause severe losses to growers of flowers. B. cinerea secretes a number of inducible attack enzymes which can degrade host cell walls to widen the infection, including β-glucosidase, pectin methylesterase, the polygalacturonases, and aspartate proteinase; laccase and benzyl alcohol oxidase appear to have roles of detoxifying compounds derived from the host during pathogenesis, a function that we believe enhances the virulence of the pathogen. With additional research, several oxidases may also become a part of the virulence group. Much more work is needed, in particular the analysis of mutants, to assign formally the roles suggested here.     

Potential use and mode of action of the new strain Bacillus thuringiensis UM96 for the biological control of the grey mould phytopathogen Botrytis cinerea

The potential use of Bacillus thuringiensis UM96 as a biocontrol agent for the grey mould phytopathogen Botrytis cinerea was evaluated. In order to dissect the mode of action of this UM96 strain, we also examined the role of lytic activities in the antagonism. First, B. thuringiensis UM96 was characterised based on 16S rRNA and gyrA gene sequencing and phenotypic traits. Petri dish biocontrol assays demonstrated that when strain UM96 was inoculated 24 h previous to B. cinerea, the mycelial growth was inhibited by up to 70%. Test for lytic enzymes activities of cellulase and glucanase was negative. Chitinase was the only positive enzyme activity in two different culture media. PCR detection of the chiB gene was also positive. Chitinolytic supernatants, obtained from rich and minimal media supplemented with colloidal chitin as the sole carbon source, from B. thuringiensis UM96 showed a strong inhibitory effect of B. cinerea that was not observed with heat-treated supernatant. Interestingly, when the supernatant was supplemented with 100 µM allosamidin, a chitinase specific inhibitor, the antagonistic activity was suppressed significantly. A lack of chitinase activity was also observed in allosamidin-treated supernatants. Our pathogenic B. cinerea strain also exhibited susceptibility to pure Streptomyces griseus chitinase. Finally, the chitinolytic strain B. thuringiensis UM96 was able to protect Medicago truncatula plants in vitro from B. cinerea infection and significantly reduced the necrotic zones and root browning of the plants. Together, these results suggest a potential use of B. thuringiensis UM96 for the biological control of B. cinerea and a role for chitinases during the antagonism displayed.     

Effects of long-term storage at different temperatures on conidia of Botrytis cinerea Pers.: Fr.

Survival of Botrytis cinerea conidia was studied after storage without pretreatments at different temperatures (-80 degrees C, -20 degrees C, 4 degrees C and 21 degrees C). Germination tests performed during 3 years showed that viability at 21 degrees C was completely lost after 1 month. Conidia stored for 30 months at -80 degrees C, -20 degrees C and 4 degrees C were able to germinate, respectively, at 79%, 8% and 0.2%. Changes in adenylate level, energy charge and respiration (O(2) consumption) made on each set of conidia were correlated to the germination rate. The 30-month-old stored conidia showed differences in pathogenicity tests on apples. While the pathogenic aggressiveness of conidia stored at -80 degrees C was almost the same as for fresh conidia, it decreased with increasing temperature of storage. An ultrastructural study made on conidia stored for 30 months at -80 degrees C has shown the emergence of a new wall layer in a retraction zone of the cytoplasm by comparison to fresh conidia. However, the integrity of the cytoplasmic content was maintained. The effects of low temperature storage, maintenance of cell integrity and pathogenicity of conidia of B. cinerea are discussed.     

抗灰葡萄孢霉菌乳酸菌的筛选

从80株乳酸菌中筛选出45株具有抗灰葡萄孢霉菌活性的乳酸菌菌株,其中10株具有较强抗灰葡萄孢霉菌活性。对这10株乳酸菌菌株的抗植物致病真菌谱进行了研究,这10株乳酸菌对番茄早疫病菌,甜瓜疫霉菌,甜瓜枯萎病菌,苹果炭疽病菌的生长均有较强的抑制作用。其中1株具有广谱抗植物致病真菌活性的乳酸菌菌株BX6-4为植物乳杆菌。经番茄离体叶片接种试验发现,植物乳杆菌BX6-4的发酵液能够在体外强烈地抑制灰葡萄孢霉菌的生长。     

Fine-scale genetic structure and dispersal in cooperatively breeding apostlebirds

In cooperatively breeding species, restricted dispersal of offspring leads to clustering of closely related individuals, increasing the potential both for indirect genetic benefits and inbreeding costs. In apostlebirds (Struthidea cinerea), philopatry by both sexes results in the formation of large (up to 17 birds), predominantly sedentary breeding groups that remain stable throughout the year. We examined patterns of relatedness and fine-scale genetic structure within a population of apostlebirds using six polymorphic microsatellite loci. We found evidence of fine-scale genetic structure within the study population that is consistent with behavioural observations of short-distance dispersal, natal philopatry by both sexes and restricted movement of breeding groups between seasons. Global F(ST) values among breeding groups were significantly positive, and the average level of pairwise relatedness was significantly higher for individuals within groups than between groups. For individuals from different breeding groups, geographical distance was negatively correlated with pairwise relatedness and positively correlated with pairwise F(ST). However, when each sex was examined separately, this pattern was significant only among males, suggesting that females may disperse over longer distances. We discuss the potential for kin selection to influence the evolution and maintenance of cooperative breeding in apostlebirds. Our results demonstrate that spatial genetic structural analysis offers a useful alternative to field observations in examining dispersal patterns of cooperative breeders.     

The Arabidopsis LECTIN RECEPTOR KINASE-VI.2 is a functional protein kinase and is dispensable for basal resistance to Botrytis cinerea

Sensing of microbial pathogens by pathogen-associated molecular patterns (PAMPs) through pattern recognition receptors (PRRs) elicits a defense program known as PAMP-triggered immunity (PTI). Recently, we have shown that the Arabidopsis thaliana L-TYPE LECTIN RECEPTOR KINASE-VI.2 (LecRK-VI.2) positively regulates bacterial PTI. In this report, we suggest by in silico analysis that the kinase domain of LecRK-VI.2 is functional. LecRK-VI.2 also demonstrated auto-phosphorylation activity in vitro in the presence of divalent metal cations indicating that LecRK-VI.2 has the ability to auto-phosphorylate. We further investigate the role of LecRK-VI.2 in Arabidopsis resistance to the necrotrophic fungal pathogen Botrytis cinerea. Disruption of LecRK-VI.2 did not affect Arabidopsis resistance to B. cinerea. Accordingly, wild-type upregulation levels of PTI-responsive WRKY53, FRK1, NHL10, CYP81F2 and CBP60 g after treatment with the fungal PAMP chitin were observed in lecrk-VI.2-1. These data provide evidences that the kinase domain of LecRK-VI.2 is active and show that LecRK-VI.2 is not critical for resistance to the fungal pathogen B. cinerea.     

2-epi-Botcinin A and 3-O-Acetylbotcineric Acid from Botrytis cinerea

Two metabolites, 2-epi-botcinin A and 3-O-acetylbotcineric acid, were isolated from Botrytis cinerea (AEM211). The former compound was new, and the latter was known but structurally revised by us. In a test for antifungal activity against Magnaporthe grisea, a pathogen of rice blast disease, 2-epi-botcinin A was 8 times less active than botcinin A (MIC 100 μM), and the MIC value for 3-O-acetylbotcineric acid being 100 μM.     

Freezing and freeze-drying of the bacterium Rahnella aquatilis BNM 0523: study of protecting agents, rehydration media and freezing temperatures

Aims: The aim of the present study was to evaluate and compare freezing and freeze‐drying treatments for conserving Rahnella aquatilis (BNM 0523) with the goal to achieve an adequate commercial formulation of this biocontrol agent. Methods and Results: The effect of several protective agents, rehydration media and freezing temperatures on the viability and functional activity of the R. aquatilis was investigated. The storage stability at 3 months and 4 years was determined by checking the viability of the cells and their biocontrol capability against Botrytis cinerea by measuring the percentage of reduction of disease severity on apple. The best results were obtained by the freeze‐drying of the cells using a mixture of skimmed nonfat milk 10%, yeast extract 0·5% and glucose 1% as the protecting and rehydrating medium, and a quickly freezing (?70°C) before the freeze‐drying. In this case, the viability of the cells after 4 years was 98%, and their antagonistic ability showed a little decrease with respect fresh cells. Conclusions: The studies showed that R. aquatilis was resistant to freezing and freeze‐drying when it was used a mixture of cryoprotectants and that it was possible to obtain inoculums with high viability and good effectiveness for reduction of decay caused by B. cinerea. Significance and Impact of the study: This study is probably the first report about the resistance of R. aquatilis to freezing and freeze‐drying treatments and shows that these operations could be useful for obtaining a commercial formulation of this biocontrol agent.     

In vitro and in vivo antimicrobial activity of Xenorhabdus bovienii YL002 against Phytophthora capsici and Botrytis cinerea

Aims: Developing new bio‐agents to control plant disease is desirable. Entomopathogenic bacteria Xenorhabdus spp. have potential antimicrobial activity in agriculture. This work was conducted to evaluate the antimicrobial activity of Xenorhabdus bovienii YL002 on plant pathogenic fungi and oomycete in vitro and the efficiency of this strain to reduce the in vivo incidence of grey mould rot on tomato plants caused by Botrytis cinerea and leaf scorch on pepper plants caused by Phytophthora capsici. Methods and Results: The antimicrobial activity of X. bovienii YL002 was firstly determined on in vitro plant pathogenic fungi and oomycete and then on tomato fruits and plants infected with B. cinerea and pepper plants infected with P. capsici. The cell‐free filtrate of X. bovienii YL002 exhibited highest inhibition effects (>98%) on mycelia growth of P. capsici and B. cinerea. The 50% inhibition concentration (EC₅₀) of the methanol‐extracted bioactive compounds (methanol extract) of the cell‐free filtrate against P. capsici and B. cinerea were 164·83 and 42·16 μg ml^?1. The methanol extract also had a strong effect on the spore germination of P. capsici and B. cinerea, with a EC₅₀ of 70·38 and 69·33 μg ml^?1, respectively. At 1000 μg ml^?1, the methanol extract showed a therapeutic effect of 70·82% and a protective effect of 77·4% against B. cinerea on tomato plants compared with the control. The methanol extract also showed potent effect against P. capsici, with a therapeutic effect of 68·14% and a protective effect of 65·46% on pepper plants compared with the control. Conclusions: Xenorhabdus bovienii YL002 produces antimicrobial compounds with strong activity on plant pathogenic fungi and oomycete and has the potential for controlling grey mould rot of tomato plants and leaf scorch of pepper and could be useful in integrated control against diverse plant pathogenic fungi and oomycete. Significance and Impact of the Study: This study showed the potential that X. bovienii YL002 can be used to control the grey mould rot caused by B. cinerea on tomato plants and leaf scorch caused by P. capsici on pepper plants with the objective to reduce treatments with chemical fungicides.