Morphological and molecular identification of Leptosphaeria maculans in canola seeds and flowers collected from the North Iran

Blackleg disease, caused by Leptosphaeria maculans, is one of the most important diseases of rapeseed Brassica napus in Iran as in other regions of the world. The samples including canola petals and seeds were collected during 2014–2015 from canola field in North Iran. Isolates characteristics of fungus were assessed based on the colony growth rate and pycnidia in Potato Dextrose Agar. The pycnidia of the fungus were black, globose to subglobose in shape, the single-celled conidia, hyaline and fusiform with diameters of 4–5 × 1.5–2 μm. Most of the isolates were produced pigment in the liquid culture in variable color brown to black. Thirteen isolates were then separated into pathogenicity groups based on the interactions on B. napus differential cultivars. For the direct detection of seed contamination with L. maculans, PCR was developed using specific primers pair (LmacF, LmacR) which can amplify ITS1 and ITS2 along with the 5.8S rRNA region of L. maculans genome. Based on the followed information and sequence analysis, the fungal isolates from these samples were identified as L. maculans. The findings of this research showed that the disease was aggressive and highly distributed from infested seeds to oilseed rape fields.     

Epigenetic Control of Effector Gene Expression in the Plant Pathogenic Fungus Leptosphaeria maculans

Plant pathogens secrete an arsenal of small secreted proteins (SSPs) acting as effectors that modulate host immunity to facilitate infection. SSP-encoding genes are often located in particular genomic environments and show waves of concerted expression at diverse stages of plant infection. To date, little is known about the regulation of their expression. The genome of the Ascomycete Leptosphaeria maculans comprises alternating gene-rich GC-isochores and gene-poor AT-isochores. The AT-isochores harbor mosaics of transposable elements, encompassing one-third of the genome, and are enriched in putative effector genes that present similar expression patterns, namely no expression or low-level expression during axenic cultures compared to strong induction of expression during primary infection of oilseed rape (Brassica napus). Here, we investigated the involvement of one specific histone modification, histone H3 lysine 9 methylation (H3K9me3), in epigenetic regulation of concerted effector gene expression in L. maculans. For this purpose, we silenced the expression of two key players in heterochromatin assembly and maintenance, HP1 and DIM-5 by RNAi. By using HP1-GFP as a heterochromatin marker, we observed that almost no chromatin condensation is visible in strains in which LmDIM5 was silenced by RNAi. By whole genome oligoarrays we observed overexpression of 369 or 390 genes, respectively, in the silenced-LmHP1 and -LmDIM5 transformants during growth in axenic culture, clearly favouring expression of SSP-encoding genes within AT-isochores. The ectopic integration of four effector genes in GC-isochores led to their overexpression during growth in axenic culture. These data strongly suggest that epigenetic control, mediated by HP1 and DIM-5, represses the expression of at least part of the effector genes located in AT-isochores during growth in axenic culture. Our hypothesis is that changes of lifestyle and a switch toward pathogenesis lift chromatin-mediated repression, allowing a rapid response to new environmental conditions.     

Efficient Detection of Leptosphaeria maculans from Infected Seed lots of Oilseed Rape

An efficient DNA extraction protocol and polymerase chain reaction (PCR) assay for detecting Leptosphaeria maculans from infected seed lots of oilseed rape were developed. L. maculans, the causal agent of blackleg, a damaging disease in oilseeds rape/canola worldwide, was listed as a quarantine disease by China in 2009. China imports several millions of tons of oilseeds every year. So there is a high risk that this pathogen will be introduced to China via contaminated seeds. Seed contamination is one of the most significant factors in the global spread of phytopathogens. Detection of L. maculans in infected seed lots by PCR assay is difficult due to the low level of pathogen mycelium/spores on seeds and PCR inhibitors associated with the seeds of oilseed rape. In our study, these two major obstacles were overcome by the development of a two‐step extraction protocol combined with a nested PCR. This extraction protocol (kit extraction after CTAB method) can efficiently extract high‐quality DNA for PCR. Amplification results showed that the detection threshold for conventional PCR and nested PCR was, respectively, 1 ng and 10 fg of DNA per μl in mycelia samples. On contaminated seed lots of oilseed rape, the detection threshold of conventional and nested PCR was 709 fg/μl and 709 ag/μl of DNA, respectively. The DNA extraction protocol and PCR assay developed in this study can be used for rapid and reliable detection of L. maculans from infected seeds of oilseed rape .     

The roles of ascospores and conidia of Pyrenopeziza brassicae in light leaf spot epidemics on winter oilseed rape (Brassica napus) in the UK

Ascospores of Pyrenopeziza brassicae were produced in apothecia (cup‐shaped ascomata) on oilseed rape debris. The conidia, which were morphologically identical to the ascospores, were produced in acervular conidiomata was greater than for lesions caused by ascospores. In June 2000, on the ground under a crop with light on the surface of living oilseed rape tissues. Ascospores were more infective than conidia on oilseed rape leaves. The proportion of lesions caused by conidia located on leaf veins leaf spot, numbers of petioles with apothecia decreased with increasing distance into the crop from the edge of pathways. Air‐borne ascospores of P. brassicae were first collected above debris of oilseed rape affected with light leaf spot on 5 October 1998 and 18 September 1999,12 or 23 days, respectively, after the debris had been exposed outdoors. P. brassicae conidia were first observed on leaves of winter oilseed rape on 6 January 1999 and 15 February 2000, respectively, after plots had been inoculated with debris in November 1998 and October 1999. In 1991/92, numbers of ascospores above a naturally infected crop were small from January to April and increased in June and July. P. brassicae conidia were first observed in February and the percentage plants with leaves, stems or pods with light leaf spot increased greatly in May and June. In 1992/93, in a crop inoculated with debris, numbers of airborne ascospores were small from October to January and increased from April to June. P. brassicae conidia were first observed on leaves in late November and light leaf spot was seen on stems and pods in March and June 1993, respectively.     

The Use of Ergosterol as a Quantitative Measure of the Resistance of Cultured Tissues of Brassica napus ssp. oleifera to Leptosphaeria maculans

A simplified method for the quantitative assessment of the fungal lipid ergosterol was used to assess the levels of infection in tissue cultures of oilseed rape (Brassica napus ssp. oleifera) inoculated with Leptosphaeria maculans. The growth of L. maculans in liquid culture throughout a 36-day period correlated well (r = 0·92) with the amount of ergosterol extracted from the mycelium. There were significant differences (P < 0·05) in the amount of ergosterol extracted from infected thin cell layer (TCL) explants and callus tissue of two resistant and three susceptible cultivars of oilseed rape. Amounts of ergosterol extracted from resistant cultivars were < 100 (g and from susceptible > 100 (g. The mean amounts of ergosterol extracted from shoot cultures of two resistant and four susceptible cultivars were similar to those for TCL explants and callus tissue, although the values obtained were variable. This technique can be used in in vitro breeding programmes to accurately assess the resistance of tissue cultures of B. napus to L. maculans and could also have value in conventional breeding programmes.     

Differential Reactions Between the Genus Brassica and Aggressive Single Spore Isolates of Leptosphaeria maculans

Based on sirodesmin production and pathogenicity tests with Brassica cotyledons, strains of Leptosphaeria maculans were classified as aggressive (pathotype group A), or non-aggressive (pathotype group NA). NA strains caused no differential reactions. However, the pathotype group A could be divided into 5 sub-groups. AO isolates caused non-sporulating lesions with dark margins while Al isolates sporulated on cotyledons of most Brassica hosts tested. Only the cv. Erfurter Zwerg (B. oleracea var. botrytis) reacted resistant against AO and Al strains. A2 isolates caused resistance reactions on cotyledons of the cvs. Quinta (B. napus var. oleifera) and Runde (B. rapa var. rapa). A3 and A4 isolates were not detectable in our material. Isolates of these pathotype groups, supplied by Dr. P. H. Williams, Madison, USA, caused differential reactions on the oilseed rape cvs. Glacier, Quinta and Jet Neuf. In glasshouse and field experiments strains of pathotype groups Al, A2 and NA were tested on true leaves and hypocotyls of different oilseed rape cultivars. The low aggressiveness of NA isolates was evident under all experimental conditions. A2 strains caused resistance reactions not only on cotyledons but also on true leaves and hypocotyls of Quinta. Moreover, compared with Al, pathotype group A2 was more aggressive on hypocotyls of Jet Neuf. The resistance of this cultivar against Al isolates was clearly visible on hypocotyls and true leaves but not on cotyledons.     

Quantitative PCR analysis of abundance of airborne propagules of Leptosphaeria species in air samples from different regions of Poland

When airborne propagules of Leptosphaeria maculans and L. biglobosa were collected in Poland at three ecologically different sites from 1 September to 30 November in 2004 to 2008, using a Hirst-type seven-day volumetric spore trap, there were fluctuations in timing of ascospore release and diverse ratios between airborne propagules of both species depending on season, field location and weather conditions. The detection was done using the microscope as well as quantitative PCR with species-specific primers targeted against fragments of β-tubulin genes and quantified with a dual-labelled fluorescent probe approach. This detection chemistry is described for the first time for L. maculans and L. biglobosa. Its advantage over the previous ITS-based SYBR-Green chemistry resides in improved sensitivity and the virtual absence of false positives in the detection of these fungi. There were significant, positive correlations between data obtained using visual assessment of ascospore numbers and DNA concentrations that were measured by qPCR. Climatic differences between the oilseed rape growing regions could have significantly affected the biological processes of pseudothecial maturation and ascospore development of the pathogens. The data suggest that regular rain events of intermediate intensity recorded in the Maritime region favoured the maturation of the pathogen more than the drier weather recorded in the Silesia or Pomerania regions. It was observed that the number of rainy days was of greater importance than the cumulative rainfall to obtain the generative sporulation of the pathogen. Accurate detection of airborne inoculum of pathogenic Leptosphaeria spp. facilitates improved targeting of disease management decisions for oilseed rape protection against phoma stem canker and stem necrosis diseases.     

The Lmpma1 gene of Leptosphaeria maculans encodes a plasma membrane H+-ATPase isoform essential for pathogenicity towards oilseed rape

Following Agrobacterium tumefaciens-mediated mutagenesis in Leptosphaeria maculans, we identified the mutant 210, displaying total loss of pathogenicity towards its host plant (Brassica napus). Microscopic observations showed that m210 is unable to germinate on the host leaf surface and is thus blocked at the pre-penetration stage. The pathogenicity phenotype is linked with a single T-DNA insertion into the promoter region of a typical plasma membrane H⁺-ATPase-encoding gene, termed Lmpma1, thus leading to a twofold reduction in Lmpma1 expression. Since LmPMA1 is involved in intracellular pH homeostasis, we postulate that reduction in LmPMA1 activity disturbs the electrochemical transmembrane gradient in m210, thus leading to conidia defective in turgor pressure generation on leaf surface. Whole genome survey showed that L. maculans possesses a second plasma membrane H⁺-ATPase-encoding gene, termed Lmpma2. Silencing experiments, expression analyses and phylogenetic studies allowed us to highlight the essential role assumed by the Lmpma1 isoform in L. maculans pathogenicity.     

The Botrytis cinerea PAK kinase BcCla4 mediates morphogenesis,growth and cell cycle regulating processes downstream of BcRac

Rac proteins are involved in a variety of cellular processes. Effector proteins that interact with active Rac convey the GTPase‐generated signal to downstream developmental cascades and processes. Here we report on the analysis of the main effector and signal cascade downstream of BcRac, the Rac homolog of the grey mold fungus Botrytis cinerea. Several lines of evidence highlighted the p21‐activated kinase Cla4 as an important effector of Rac in fungi. Analysis of Δbccla4 strains revealed that the BcCla4 protein was sufficient to mediate all of the examined BcRac‐driven processes, including hyphal growth and morphogenesis, conidia production and pathogenicity. In addition, the Δbccla4 strains had altered nuclei content, a phenomenon that was previously observed in Δbcrac isolates, thus connecting the BcRac/BcCla4 module with cell cycle control. Further analyses revealed that BcRac/BcCla4 control mitotic entry through changes in phosphorylation status of the cyclin dependent kinase BcCdk1. The complete cascade includes the kinase BcWee1, which is downstream of BcCla4 and upstream of BcCdk1. These results provide a mechanistic insight on the connection of cell cycle, morphogenesis and pathogenicity in fungi, and position BcCla4 as the most essential effector and central regulator of all of these processes downstream of BcRac.     

Production of Phytotoxic Sirodesmins by Aggressive Strains of Leptosphaeria maculans Differing in Interactions with Oil Seed Rape Genotypes

Sirodesmins were extracted from culture filtrates of 3 aggressive strains of Leptosphaeria maculans which showed different specific interactions with the oilseed rape cultivars Quinta and Jet Neuf. Up to 8 compounds were detectable showing reactions on thin layer plates which are characteristic for sirodesmins. Sirodesmin PL, sirodesmin C, deacetylsirodesmin PL and deacetyl-sirodesmin C were identified on the basis of their UV-spectra, by various conversion reactions and by cochromatography with known standards. Two further compounds were tentatively identified as sirodesmin B and deacetylsirodesmin B on the basis of conversion reactions only. In the cultures of all strains sirodesmin PL was the main component, followed by deacetylsirodesmin PL, sirodesmin C, and deacetylsirodesmin C. These 4 metabolities were mainly responsible for the phytotoxic activity of all culture filtrates. They were systemically transported to leaves of root treated rape seedlings. No correlation was found between the production of the 4 main sirodesmins and the differential host parasite interactions of the 3 aggressive strains of Leptosphaeria maculans.     

黑胫病菌侵染过程中油菜响应基因的表达分析

油菜黑胫病是造成油菜产量损失的病害之一,致病菌为Leptosphaeria biglobosa。该研究采用形态学观察和转录组测序技术,分析油菜接种病原菌Leptosphaeria biglobosa 4、12、24、36、48和96 h后的表型及基因表达变化情况,以探讨响应死体营养型真菌L.biglobosa侵染时油菜的防御反应及抗病机理,为揭示油菜与L.biglobosa互作的分子机制提供理论依据,并为培育油菜抗病品种积累了基因资源信息。结果显示:(1)接种4~96 h,叶片病斑逐渐扩大,病原菌侵染48~96 h后形成菌丝网。(2)通过RNA-Seq测序,在L.biglobosa侵染油菜的不同时间点(4、12、24、36、48和96 h)分别得到3384、2270、3802、5811、6155和7153个差异表达基因。(3)15个油菜差异表达基因的qRT-PCR检测表达水平与转录组测序结果基本一致。(4)利用短时间序列聚类和KEGG富集分析差异表达基因,结果发现植物病原菌互作、蛋白激酶、茉莉酸/乙烯/水杨酸和芥子油苷合成途径中的基因被强烈诱导表达,而且基因表达呈动态变化趋势。     

A Detached Cotyledon Test for the Isolation of Mutants of Pyrenopeziza brassicae Defective in Pathogenicity Determinants

A detached cotyledon pathogenicity test was devised for the isolation of UV-induced mutants of the hemibiotrophie ascomycete pathogen of Brassica spp., Pyrenopeziza brassicae defective in pathogenicity determinants. At least 95 % of cotyledons of suitable susceptible cultivars of oilseed rape (Brassica napus L. ssp. oleifera cvs Shogun or Bolko) showed symptoms of disease (white spore pustules [conidiomata] on the surface of the cotyledon) within three weeks of inoculation of cotyledons with 10⁴ conidia of P. brassicae. The test allowed rapid screening of UV-induced mutants with a low frequency of false negatives. From 1,700 survivors of UV mutagenesis tested, 20 non-pathogenic mutants were obtained.     

Presence of Leptosphaeria maculans Group A and Group B Isolates in Sweden

Leptosphaeria maculans isolates have been assigned to one of two groups, A or B, on the basis of differences in their characteristics. Group A can further be divided into pathogenicity groups (PG) 2, 3 and 4 and group B into PG1. To determine if isolates belonging to the aggressive canker forming group A are present in Sweden, physiological and genetic characterisation of 120 isolates collected in the year 2000 were performed. Thirty‐seven isolates were classified as belonging to pathogenicity group PG3 and 63 isolates as PG4, based on a cotyledon assay. Twenty isolates did not cause any symptoms at all, and were classified as PG1. When comparing two geographical regions, Skåne and Östergötland, equal numbers of PG3 and PG4 isolates were found. By analysing the isolates by PCR, the collection was further classified into 100 group A isolates and 20 group B isolates. A corresponding classification of the isolates was observed when the ability to produce pigments in Czapek Dox broth was examined. The results showed a clear predominance of group A. This was also the case for the isolate collection from 2001. In a detailed survey of disease development in a L. maculans infected winter oilseed rape field in southern Sweden (Skåne), basal stem canker was not observed until early June Although the disease index value increased from 8.4 in June to 18.0 in July, few severely damaged plants were observed before harvest in mid‐July, despite infection with group A isolates.     

Analysis of leaf appearance,leaf death and phoma leaf spot,caused by Leptosphaeria maculans,on oilseed rape (Brassica napus) cultivars

Development of phoma leaf spot (caused by Leptosphaeria maculans) on winter oilseed rape (canola, Brassica napus) was assessed in two experiments at Rothamsted in successive years (2003–04 and 2004–05 growing seasons). Both experiments compared oilseed rape cultivars Eurol, Darmor, Canberra and Lipton, which differ in their resistance to L. maculans. Data were analysed to describe disease development in terms of increasing numbers of leaves affected over thermal time from sowing. The cultivars showed similar patterns of leaf spot development in the 2003–04 experiment when inoculum concentration was relatively low (up to 133 ascospores m⁻³ air), Darmor developing 5.3 diseased leaves per plant by 5 May 2004, Canberra 6.6, Eurol 6.8 and Lipton 7.5. Inoculum concentration was up to sevenfold greater in 2004–05, with Eurol and Darmor developing 2.4 diseased leaves per plant by 16 February 2005, whereas Lipton and Canberra developed 2.8 and 3.0 diseased leaves, respectively. Based on three defined periods of crop development, a piece-wise linear statistical model was applied to the progress of the leaf spot disease (cumulative diseased leaves) in relation to appearance (‘birth’) and death of leaves for individual plants of each cultivar. Estimates of the thermal time from sowing until appearance of the first leaf or death of the first leaf, the rate of increase in number of diseased leaves and the area under the disease progress line (AUDPL) for the first time period were made. In 2004–05, Canberra (1025 leaves ×°C days) and Lipton (879) had greater AUDPL values than Eurol (427) and Darmor (598). For Darmor and Lipton, the severity of leaf spotting could be related to the severity of stem canker at harvest. Eurol had less leaf spotting but severe stem canker, whereas Canberra had more leaf spotting but less severe canker.     

A new avirulence gene of Leptosphaeria maculans,AvrLm14, identifies a resistance source in American broccoli (Brassica oleracea) genotypes

In many cultivated crops, sources of resistance to diseases are sparse and rely on introgression from wild relatives. Agricultural crops often are allopolyploids resulting from interspecific crosses between related species, which are sources of diversity for resistance genes. This is the case for Brassica napus (oilseed rape, canola), an interspecific hybrid between Brassica rapa (turnip) and Brassica oleracea (cabbage). B. napus has a narrow genetic basis and few effective resistance genes against stem canker (blackleg) disease, caused by the fungus Leptosphaeria maculans, are currently available. B. rapa diversity has proven to be a valuable source of resistance (Rlm, LepR) genes, while B. oleracea genotypes were mostly considered susceptible. Here we identified a new resistance source in B. oleracea genotypes from America, potentially effective against French L. maculans isolates under both controlled and field conditions. Genetic analysis of fungal avirulence and subsequent cloning and validation identified a new avirulence gene termed AvrLm14 and suggested a typical gene-for-gene interaction between AvrLm14 and the postulated Rlm14 gene. AvrLm14 shares all the usual characteristics of L. maculans avirulence genes: it is hosted in a genomic region enriched in transposable elements and heterochromatin marks H3K9me3, its expression is repressed during vegetative growth but shows a strong overexpression 5–9 days following cotyledon infection, and it encodes a small secreted protein enriched in cysteine residues with few matches in databases. Similar to the previously cloned AvrLm10-A, AvrLm14 contributes to reduce lesion size on susceptible cotyledons, pointing to a complex interplay between effectors promoting or reducing lesion development.