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辽宁花生主栽品种(系)对褐斑病和网斑病抗性鉴定 总被引:2,自引:0,他引:2
本研究旨在明确辽宁花生主栽品种(系)对花生褐斑病和网斑病的抗性,以期为抗病育种及田间病害防治提供理论依据。试验采用田间自然病圃法,对辽宁主栽的16个花生品种(系)进行了褐斑病和网斑病田间抗性鉴定。结果表明,供试花生品种(系)对两种叶部病害抗性存在显著差异,但缺乏免疫和高抗品种。对花生褐斑病抗性鉴定结果表明,‘阜花17’属抗病类型,‘鲁花11’、‘铁引花2号’、‘良青8号’、‘新花2号’和‘锦花15’属中抗类型,其余属高感或感病类型。对花生网斑病抗性鉴定结果显示:‘鲁花11’、‘铁引花2号’和‘白花生’属抗病类型,‘黑花生’、‘新花2号’、‘花育20’、‘锦花14’、‘新花1号’、‘锦花15’和‘良青8号’属中抗类型,其余属高感或感病类型。多数花生品种(系)对花生叶斑病综合抗性较差。 相似文献
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Single-lesion isolates ofCercospora beticola (n=150) were collected in 1998 from sugar beet fields in the area of Serres, N. Greece. In this area, sterol demethylation-inhibiting
(DMI) fungicides have been used for almost 20 years to control sugar beet leaf spot. The sensitivity of these isolates to
the DMI fungicides flutriafol and difenoconazole (EC50 values) was determined on the basis of inhibition of mycelial growth at several fungicide concentrations. The relative growth
(RG) of isolates was correlated at all tested concentrations with the respective EC50 values, indicating that RG provides a reliable estimate for the sensitivity of the isolates. The highest correlation coefficients
were obtained for concentrations of 1 μg ml−1 flutriafol and of 0.05 μg ml−1 difenoconazole, respectively. Consequently, they are proposed for monitoring of DMI sensitivity inC. beticola populations, as single discriminatory concentrations in a simplified test method. Based on the RG values at the discriminatory
concentration of 1 μg ml−1 flutriafol,C. beticola isolates were classified as either resistant or sensitive. The efficacy of flutriafol, applied at the commercially recommended
dose, in controlling Cercospora leaf spot was examined in field experiments conducted during 1999 and 2000. Disease incidence
in plots artificially inoculated with resistant isolates and treated with flutriafol was significantly higher than in similar
plots inoculated with sensitive strains. These results suggest that poor disease control after application of flutriafol may
be based on the presence of resistant strains within the pathogen population in northern Greece. This emphasizes the risk
of the development of practical resistance if there is increased frequency of such strains within the population.
http://www.phytoparasitica.org posting July 13, 2003. 相似文献
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Helena Olczak-Woltman Małgorzata Schollenberger Wiesław Mądry Katarzyna Niemirowicz-Szczytt 《European journal of plant pathology / European Foundation for Plant Pathology》2008,122(3):385-393
Increased occurrence of cucumber angular leaf spot, Pseudomonas syringae pv. lachrymans, has caused significant losses in cucumber, Cucumis sativus, yield in Poland in recent years. These losses necessitated evaluation of the level of resistance in cucumber cultivars of
mainly Polish breeding, cultivated in Eastern Europe, and initiation of a breeding programme for resistance to this disease.
Screening for resistance was performed on 84 cucumber accessions under growth chamber conditions using a highly aggressive
strain of P. syringae pv. lachrymans. Most of the screened accessions were either susceptible or displayed intermediate resistance. The screening resulted in
the identification of five F1 hybrid cultivars moderately resistant to angular leaf spot. The identified F1 hybrids were self-pollinated up to the F4 generation. Individuals resistant to angular leaf spot were identified. These individuals can be used as a source of resistance
to angular leaf spot in future breeding efforts. 相似文献
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Loop‐mediated isothermal amplification (LAMP) assays for rapid detection of Pyrenopeziza brassicae (light leaf spot of brassicas) 下载免费PDF全文
K. M. King V. Krivova G. G. M. Canning N. J. Hawkins A. M. Kaczmarek S. A. M. Perryman P. S. Dyer B. A. Fraaije J. S. West 《Plant pathology》2018,67(1):167-174
Pyrenopeziza brassicae (anamorph Cylindrosporium concentricum) is an ascomycete fungus that causes light leaf spot (LLS) disease of brassicas. It has recently become the most important pathogen of winter oilseed rape (Brassica napus) crops in the UK. The pathogen is spread by both asexual splash‐dispersed conidia and sexual wind‐dispersed ascospores. Such inoculum can be detected with existing qualitative and quantitative PCR diagnostics, but these require time‐consuming laboratory‐based processing. This study describes two loop‐mediated isothermal amplification (LAMP) assays, targeting internal transcribed spacer (ITS) or β‐tubulin DNA sequences, for fast and specific detection of P. brassicae isolates from a broad geographical range (throughout Europe and Oceania) and multiple brassica host species (B. napus, B. oleracea and B. rapa). Neither assay detected closely related Oculimacula or Rhynchosporium isolates, or other commonly occurring oilseed rape fungal pathogens. Both LAMP assays could consistently detect DNA amounts equivalent to 100 P. brassicae conidia per sample within 30 minutes, although the β‐tubulin assay was more rapid. Reproducible standard curves were obtained using a P. brassicae DNA dilution series (100 ng–10 pg), enabling quantitative estimation of amounts of pathogen DNA in environmental samples. In planta application of the β‐tubulin sequence‐based LAMP assay to individual oilseed rape leaves collected from the field found no statistically significant difference in the amount of pathogen DNA present in parts of leaves either with or without visible LLS symptoms. The P. brassicae LAMP assays described here could have multiple applications, including detection of symptomless host infection and automated real‐time monitoring of pathogen inoculum. 相似文献
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Ramularia collo‐cygni (Rcc) is becoming an increasing problem for barley growers across Europe. However, the life cycle of the pathogen is only slowly being elucidated. In this study, Rcc DNA was detected in a number of harvested seed samples from 1999 to 2010, with mean levels peaking in winter barley samples in 2009. A number of experiments were carried out to determine whether the pathogen could move from barley seed to seedlings, and also from seed through the developing plant and into the subsequent generation of seed, both in controlled experiments and in field trials. Results from testing of seed indicated that the fungus is widespread at the end of the growing season in harvested grain samples and can be transmitted to developing plants from infected seed stock. Examination of infected seedlings did not reveal the presence of spores but fungal structures were found within the leaf. The location of the fungus within seed was examined, with Rcc DNA found in both embryo and non‐embryo tissue. The implications for barley production of the pathogen being seedborne are discussed. 相似文献
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Green fluorescent protein (GFP)‐expressing transformants were used to investigate the effects of strobilurin fungicide azoxystrobin on Mycosphaerella graminicola infection. Azoxystrobin treatments (125 or 250 g AI ha?1) were applied at various stages of the infection process under controlled conditions. GFP transformants showed conserved in vitro sensitivity to azoxystrobin and pathogenicity. Azoxystrobin controlled over 90% of M graminicola infections when applied before or during penetration of the pathogen (15% of the incubation phase). Azoxystrobin also impaired the growth of intercellular hyphae in M graminicola post‐penetration infection stages when applied at up to 50% of the incubation phase. Incubating infections observed in treated leaves were viable, but their growth was impaired and they did not induce necrosis under controlled conditions. Reduction by half of azoxystrobin dosage had little or no effect on azoxystrobin efficiency in controlling M graminicola. The contribution of post‐penetration fungistatic effect to azoxystrobin curative properties toward M graminicola in a field situation is discussed. © 2001 Society of Chemical Industry 相似文献
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The phenotype of the R gene‐mediated resistance derived from oilseed rape (Brassica napus) cv. Imola against the light leaf spot plant pathogen, Pyrenopeziza brassicae, was characterized. Using a doubled haploid B. napus mapping population that segregated for resistance against P. brassicae, development of visual symptoms was characterized and symptomless growth was followed using quantitative PCR and scanning electron microscopy on leaves of resistant/susceptible lines inoculated with suspensions of P. brassicae conidia. Initially, in controlled‐environment experiments, growth of P. brassicae was unaffected; then from 8 days post‐inoculation (dpi) some epidermal cells collapsed (‘black flecking’) in green living tissue of cv. Imola and from 13 to 36 dpi there was no increase in the amount of P. brassicae DNA and no asexual sporulation (acervuli/pustules). By contrast, during this period there was a 300‐fold increase in P. brassicae DNA and extensive asexual sporulation in leaves of the susceptible cv. Apex. However, when leaf tissue senesced, the amount of P. brassicae DNA increased rapidly in the resistant but not in the susceptible cultivar and sexual sporulation (apothecia) was abundant on senescent tissues of both. These results were consistent with observations from both controlled condition and field experiments with lines from the mapping population that segregated for this resistance. Analysis of results of both controlled‐environment and field experiments suggested that the resistance was mediated by a single R gene located on chromosome A1. 相似文献
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Expression of defence‐related genes in stems and leaves of resistant and susceptible field pea (Pisum sativum) during infection by Phoma koolunga 下载免费PDF全文
The differential expression of 13 defence‐related genes during Phoma koolunga infection of stems and leaves of susceptible versus resistant field pea (Pisum sativum) was determined using qRT‐PCR. Expression, in terms of relative mRNA level ratios, of genes encoding ferredoxin NADP oxidoreductase, 6a‐hydroxymaackiain methyltransferase (hmm6), chalcone synthase (PSCHS3) and ascorbate peroxidase in leaves and stems differed during 6–72 hours post‐inoculation (hpi) and reflected known host resistance levels in leaves versus stems. In comparison to the susceptible genotype, at 24, 48 and 72 hpi, two genes, hmm6 (122.43‐, 206.99‐ and 32.25‐fold, respectively) and PSCHS3 (175.00‐, 250.13‐ and 216.24‐fold, respectively), were strongly up‐regulated in leaves of the resistant genotype, highlighting that resistance against P. koolunga in field pea is governed by the early synthesis of pisatin. At 24 hpi, leaves infected by P. koolunga showed clear differences in expression of target genes. For example, the gene encoding a precursor of the defensin ‘disease resistance response protein 39’ was substantially down‐regulated in leaves of both the susceptible and the resistant genotypes inoculated with P. koolunga. This contrasts with other studies on another pea black spot pathogen, Didymella pinodes, where this same gene is strongly up‐regulated in leaves of resistant and susceptible genotypes. The current study provides the first understanding of defence‐related genes involved in the resistance against P. koolunga, opening novel avenues to engineer new field pea cultivars with improved leaf and stem black spot disease resistance as the basis for developing more effective and sustainable management strategies. 相似文献