共查询到20条相似文献,搜索用时 875 毫秒
1.
Zhongna Hao Lianping Wang Jiangen Liang Rongxiang Tao 《European journal of plant pathology / European Foundation for Plant Pathology》2011,131(2):269-275
The rice japonica variety Nipponbare and the indica variety 93-11, the genomic DNA sequences of which are known, were used to analyze the response of the panicles exserted from
the caulis and from various effective tillers at four stages of panicle development to neck blast. Disease incidence in the
necks (DIN), disease incidence in the rachis nodes (DIRN), lesion length in the necks (LLN), and number of conidia in the
necks (NCN) were measured after inoculating the panicles in vitro of two rice varieties with Magnaporthe oryzae. Both Nipponbare and 93-11 were susceptible, DIN and DIRN of all panicles being 100% in both the varieties except DIRN in
several panicles at stage 1 (the panicle fully exserted) in Nipponbare. Both LLN and NCN of panicles decreased as the panicles
continued to develop. However, the patterns of this decrease in the panicles from the caulis and from various effective tillers
were substantially different in the two varieties. In Nipponbare, neck blast became progressively severe in the order of emergence
of the panicles from the caulis and from six effective tillers: values of LLN and NCN were the lowest in the panicles from
the caulis, intermediate in those from first-class tillers, and the highest in those from second-class tillers. In 93-11,
however, the source of panicles had no significant influence on LLN and NCN. 相似文献
2.
Ya-Li Fang Yao-Yao Zhou Xin Li Yue Gao De-Long Wang Min-Jie Liu Zhi-Jia Zhang 《Plant pathology》2022,71(2):251-261
Northern corn leaf blight (NCLB) caused by Setosphaeria turcica is a major foliar disease of maize. The early-stage infection events of this pathogen on maize leaves are unclear. We investigated the optimum temperature for conidial germination and appressorium formation, and characterized penetration and growth of S. turcica in maize leaf sheath and onion epidermis cells, including use of histological staining to assess plant cell viability. The results showed that the optimum temperature for conidial germination and appressorium formation was 20°C. On the maize leaf sheath, the appressoria were formed by germinated conidia, and penetration on the epidermal cells occurred at 8 h postinoculation (hpi). Round vesicles developed beneath the appressoria. Between 16 and 24 hpi, the branched invasive hyphae invaded three to five adjacent cells at most infection sites. The invasive hyphae tended to move along the cell wall and crossed from one cell to another. In the onion epidermis cells, the appressoria formed at 8 hpi, and in most cases the epidermal cells were penetrated through the juncture of the cell walls. At 16–24 hpi, the primary hyphal terminus swelled to a vesicle. The maize leaf sheath cells died at 8 hpi, whereas the onion cells did not. Our findings documented in detail the penetration and invasive hyphal growth in maize leaf sheath and onion epidermis, as well as viability of plant cells, at the early stages of infection, and provide a foundation for elucidating the underlying mechanism of S. turcica–maize interactions. 相似文献
3.
4.
A better understanding of weed seed production is a key element for any long‐term management allowing some weeds to shed seeds. The challenge with measuring seed production in weeds is the large effort required in terms of time and labour. For the weed species Echinochloa crus‐galli, it was tested whether the number of seeds per panicle dry weight or per panicle length can be used to estimate seed production. Experiments were conducted in three maize fields in north‐eastern Germany. The effect of factors that could influence this relationship, such as the time of seedling emergence, the density of E. crus‐galli, the control intensity of other weeds, seed predation and field, was included. A few days before maize harvest, all panicles were removed and weighed, panicle length was measured, and for a subsample of 178 panicles, the number of seeds was counted manually. Panicle dry weight predicted the number of seeds per panicle better (R2 = 0.92) than did panicle length (R2 = 0.69). The other factors except for ‘field’ and ‘seed predation’ had no effect on these relationships. The relationships between seed number and panicle dry weight found in this study closely resembled those reported in an earlier study. Based on our results, we conclude that both plant traits are appropriate for the estimatation of seed production, depending on required level of precision and availablilty of resources for the evaluation of sustainable weed management strategies. 相似文献
5.
Botrytis cinerea infects waxflower (Chamelaucium spp.) flowers and can induce them to abscise from their petioles before disease becomes evident. Botrytis cinerea infection of flowers was studied on two waxflower cultivars by light and electron microscopy. Pot‐grown waxflower flowers were harvested, inoculated with aqueous suspensions of B. cinerea conidia, incubated at 20–22°C and >95% RH and examined within 96 h post‐inoculation (hpi). Conidial germination on petals started 4 hpi, penetration via germ tube tips was 6 hpi and protoappressoria were formed 8 hpi. Germination on petals approximately doubled every 4–6 h to 18 hpi. Conidial germination was ca. 50% at 22–24 hpi. Botrytis cinerea infected most waxflower flower organs, including petals, anthers and filaments, stigma and hypanthium, within 24 hpi. Hyaline and lobate appressoria were observed 36 hpi. Infection cushions on stamen bases were formed 36 hpi by saprophytic hyphae that originated from anthers. This infection process can give rise to tan‐coloured symptoms typical of botrytis disease that radiate from this part of the flower. Subcuticular hyphae were present at high density near stamen bases and evidently resulted from multiple penetrations from single infection cushions. The subcuticular hyphae grew within the hypanthium and towards the centre of the floral tube. When flower abscission occurred, floral tube tissues close to the abscission zone remained uninfected. This observation infers possible transmission of a signal (e.g. ethylene) upon B. cinerea infection. Thus, B. cinerea causes flower abscission apparently as a defence response. 相似文献
6.
Yoshio Kurahashi Shinji Sakawa Haruhiko Sakuma Keiko Tanaka Gerd Haenssler Isamu Yamaguchi 《Pest management science》1999,55(1):31-37
Carpropamid (WIN™, KTU 3616) provides good control of leaf and panicle blast by ‘one-shot’ nursery-box treatment. It inhibits melanin biosynthesis in appressorial cells of Pyricularia oryzae, making them hyaline. Penetration by infection hyphae from the hyaline appressoria into rice epidermal cells is substantially hindered. In addition, the spread of rice blast spores from primary lesions to the other parts of the plant leading to secondary infection is largely prevented when the plants are treated with carpropamid by spray or water surface application. Secondary infection was simulated in a glass chamber fitted with an ultrasonic humidifier. On treated plants, many blast spores formed in the lesions, but the number of air spora that were dispersed from the lesions decreased significantly. A similar suppression of the spore liberation was observed in vitro when lesions on rice leaf segments, or discs from Pyricularia cultures on oatmeal agar were treated with the chemical. Spores from treated lesions or from the cultures on oatmeal agar amended with the chemical germinated normally and produced well-melanized appressoria on cellophane membranes. In addition, the spores proved to be fully pathogenic towards rice seedlings, producing normal disease symptoms. These results strongly suggest that carpropamid reduces the secondary infection of rice by Pyricularia by specifically hindering spore liberation. © 1999 Society of Chemical Industry 相似文献
7.
Northern leaf blight is a lethal foliar disease of maize caused by the fungus Exserohilum turcicum. The aim of this study was to elucidate the infection strategy of the fungus in maize leaves using modern microscopy techniques and to understand better the hemibiotrophic lifestyle of E. turcicum. Leaf samples were collected from inoculated B73 maize plants at 1, 4, 9, 11, 14 and 18 days post-inoculation (dpi). Samples were prepared according to standard microscopy procedures and analysed using light microscopy as well as scanning (SEM) and transmission electron microscopy (TEM). Microscopic observations were preceded by macroscopic observations for each time point. The fungus penetrated the leaf epidermal cells at 1 dpi and the disease was characterized by chlorotic leaf flecks. At 4 dpi the chlorotic flecks enlarged to form spots, and at 9 dpi hyphae were seen in the epidermal cells surrounding the infection site. At 11 dpi lesions started to form on the leaves and SEM revealed the presence of hyphae in the vascular bundles. At 14 dpi the xylem was almost completely blocked by hyphal growth. Hyphae spread into the adjacent bundle sheath cells causing cellular damage, characterized by plasmolysis, at 18 dpi and conidiophores formed through the stomata. Morphologically, lesions started to enlarge and coalesce leading to wilting of leaves. This study provides an updated, detailed view of the infection strategy of E. turcicum in maize and supports previous findings that E. turcicum follows a hemibiotrophic lifestyle. 相似文献
8.
9.
Hua Zhao Qingmei Han Jie Wang Xiaoning Gao Chang-Lin Xiao Jing Liu Lili Huang 《European journal of plant pathology / European Foundation for Plant Pathology》2013,136(1):41-49
Diplocarpon mali, the causal agent of Marssonina leaf blotch of apple, causes severe defoliation during the growing season. Little information is available on the mode of infection and the infection process. In this study, the infection strategies of D. mali in apple leaves were investigated using fluorescence and electron microscopy. Conidia attached to leaf surface apparently by mucilage and germinated on both sides of leaves 6 h post-inoculation (hpi). The pathogen penetrated the cuticle by infection pegs formed either in germ tubes or appressoria in 6 hpi, and then formed haustoria in host epidermal and mesophyll cells accompanied by extension of subcuticular and intercellular hyphae. Five days post-inoculation (dpi), the intracellular hyphae were observed. At the same time, the subcuticular hyphal strands (SHS) were produced as a means for fast expansion and reproduction. About 7 dpi, acervuli formed on inoculated leaves. This was the first observation that D. mali formed haustoria and SHS as infection strategies. Our results suggest that D. mali may behave like a hemibiotroph, which can use both biotrophic and necrotrophic strategies to establish infections on apple leaves. 相似文献
10.
Maolin Hu Laixin Luo Shu Wang Yongfeng Liu Jianqiang Li 《European journal of plant pathology / European Foundation for Plant Pathology》2014,139(1):67-77
Ustilaginoidea virens is a ubiquitous plant pathogen that causes rice false smut disease, one of the most destructive diseases of rice (Oryza sativa L.) production. However, data concerning the effect of inoculation on disease development and the infection process of this pathogen are not comprehensive. In this study, the developmental processes of U. virens in rice panicles were characterized using an enhanced green fluorescent protein (EGFP) labelled strain. A mixture of hyphae and conidia of U. virens was used to inoculate rice panicles by leaf sheath injection during the booting stage of rice plants grown in a greenhouse. The panicles were assessed to determine the relationship between artificial inoculation and disease occurrence. Increasing volumes of inocula (0.2, 0.5, 1, and 2 ml of a mixture of hyphae-fragment and 2?×?106 conidia/ml suspension) caused more severe infections, and small differences were also observed for the different inoculation sites at the base, apex and mid-point of rice panicles. The optimum inoculation condition was 1–2 ml inoculum injected into the mid-point of rice panicles. Spikelet samples were collected as the disease progressed and observed by confocal laser scanning microscopy and scanning electron microscopy. The images collected showed that the primary site of U. virens colonization was at the base of the filaments with the inner spikelets becoming infected by hyphae at 24 h post inoculation (hpi). The accumulation of hyphae reached its highest level at 168 hpi, before the rice heading stage, as the infection extended upward from basal filaments to the anther apex, and then enclosed all the floral organs to produce a velvety smut ball. 相似文献
11.
Rice blast, caused by the fungal pathogen Magnaporthe oryzae, is a serious threat to rice production worldwide. In temperate regions, where rice is not cultivated for several months each year, little is known about the initial onset of the disease in the field. The main overwintering and primary inoculum sources reported are infested residues and seeds, but the subsequent steps of the disease cycle are largely unknown, even though a systemic infection has been proposed but not demonstrated. The present work follows rice blast progression in infected seeds from germination to seedling stage, with direct and detailed microscopic observations under both aerobic conditions and water seeding. With the use of GFP‐marked M. oryzae strains, it was shown that spores are produced from contaminated seeds, infect emerging seedling tissues (coleoptile and primary root) and produce mycelium that colonizes the newly formed primary leaf and secondary roots. Using different rice cultivars exhibiting distinct levels of resistance/susceptibility to M. oryzae at the 2/4‐leaf stage, it was observed that resistance or susceptibility of a considered genotype is already established at the seedling stage. The results also showed that when plants are inoculated either at ripening stage (mature panicles), heading stage (flowering/immature panicles) or even before heading (flag leaf fully developed), they produce infested seeds. These seeds produce contaminated seedlings that mostly die and serve as an inoculum source for healthy neighbouring plants, which gradually develop disease symptoms on leaves. The possible rice blast disease cycle was reconstructed on irrigated rice in temperate regions. 相似文献
12.
In this study, an isolate of Magnaporthe oryzae expressing the green fluorescent protein gene (gfp) was used to monitor early events in the interaction of M. oryzae with resistant rice cultivars harbouring a blast resistance (R) gene. In the resistant cultivars Saber and TeQing (Pib gene), M. oryzae spores germinated normally on the leaf surface but produced morphologically abnormal germ tubes. Germling growth and development were markedly and adversely affected in leaves of these resistant cultivars. Penetration of host cells was never seen, supporting the idea that disruption of germling development on the leaf surface might be one of the resistance mechanisms associated with Pib function. Thus, this particular R gene appeared to function in the absence of host penetration by the fungal pathogen. Confocal laser scanning microscopy of M. oryzae‐infected susceptible rice cultivars showed the dimorphic growth pattern that is typically observed during the biotrophic and necrotrophic stages of leaf colonization in susceptible cultivars. The suitability of the gfp‐expressing M. oryzae isolate for further research on R‐gene function and identification of resistant genotypes in rice germplasm collections is discussed. 相似文献
13.
C. Eynck B. Koopmann G. Grunewaldt-Stoecker P. Karlovsky A. von Tiedemann 《European journal of plant pathology / European Foundation for Plant Pathology》2007,118(3):259-274
The differential interactions of V. longisporum (VL) and V. dahliae (VD) on the root surface and in the root and shoot vascular system of Brassica napus were studied by confocal laser scanning microscopy (CLSM), using GFP tagging and conventional fluorescence dyes, acid fuchsin
and acridin orange. VL and VD transformants expressing sGFP were generated by Agrobacterium-mediated transformation. GFP signals were less homogenous and GFP tagging performed less satisfactory than the conventional
fluorescence staining when both were studied with CLSM. Interactions of both pathogens were largely restricted to the root
hair zone. At 24 h post-inoculation (hpi), hyphae of VL and VD were found intensely interwoven with the root hairs. Hyphae
of VL followed the root hairs towards the root surface. At 36 hpi, VL hyphae started to cover the roots with a hyphal net
strictly following the grooves of the junctions of the epidermal cells. VL started to penetrate the root epidermal cells without
any conspicuous infection structures. Subsequently, hyphae grew intracellularly and intercellularly through the root cortex
towards the central cylinder, without inducing any visible plant responses. Colonisation of the xylem vessels in the shoot
with VL was restricted to individual vessels entirely filled with mycelium and conidia, while adjacent vessels remained completely
unaffected. This may explain why no wilt symptoms occur in B. napus infected with VL. Elevated amounts of fungal DNA were detectable in the hypocotyls 14 days post-inoculation (dpi) and in
the leaves 35 dpi. Root penetration was also observed for VD, however, with no directed root surface growth and mainly an
intercellular invasion of the root tissue. In contrast to VL, VD started ample formation of conidia on the roots, and was
unable to spread systemically into the shoots. VD did not form microsclerotia in the root tissue as widely observed for VL.
This study confirms that VD is non-pathogenic on B. napus and demonstrates that non-host resistance against this fungus materializes in restriction of systemic spread rather than
inhibition of penetration. 相似文献
14.
Hui Yin Jian-Bo Zhou Ya-Lei Chen Lu Ren Nan Qin Yan-Li Xing Xiao-Jun Zhao 《Plant pathology》2022,71(2):344-360
Quinoa panicle rot (QPR) is a novel disease that poses a significant threat to quinoa production in China. Typical symptoms on panicles include a film of pale pink, grey-white, or dark brown mould on the grains during the grain-filling stage. Furthermore, QPR causes quinoa grain discolouration, unfilling, and malformation. In total, 37 isolates were identified as belonging to three species: Trichothecium roseum (nine isolates), Alternaria alternata (12), and Fusarium citri (16) based on morphology, and phylogenetic and pathogenicity characterization. The present study shows for the first time that T. roseum, A. alternata, and F. citri are the pathogens responsible for QPR. An evaluation of the growth and germination rates revealed a significant difference among the three species, with T. roseum and F. citri isolates having higher fitness in warmer (25–30℃) and humid conditions (water activity ≥0.98). However, A. alternata preferred cooler (20–25℃) and more arid conditions, and germinated in a wide range of water activities (water activity of 0.90–1.00). Among the three species, T. roseum and F. citri are probably responsible for the pink and grey diseased grains in humid regions, and A. alternata for the black-brown diseased grains in arid regions. Pathogenicity tests showed that all three species could infect the quinoa panicles. The results of this study provide a basis for the recognition and management of QPR. 相似文献
15.
Akira Shinjo Yuko Araki Ko Hirano Tsutomu Arie Masashi Ugaki Tohru Teraoka 《Journal of General Plant Pathology》2011,77(2):85-92
Mannose-binding rice lectin (MRL), which is almost identical to the salt-induced protein SalT, binds to mannose and glucose
residues. Expression of the MRL gene in response to infection with Magnaporthe oryzae, the rice blast fungus, was stronger in the incompatible interaction than in the compatible. Transgenic rice plants that
constitutively over-expressed MRL strongly suppressed the growth of invasive hyphae of the fungus on leaf sheaths and the
development of typical susceptible-type lesions on leaf blades, but did not affect penetration by the fungus in comparison
with the wild-type. On a polycarbonate plate, purified recombinant MRL inhibited conidial attachment and appressorium formation
but not conidial germination. These results suggest that MRL may play an essential role in disease resistance by suppressing
development of M. oryzae in situ. 相似文献
16.
Y. Gao X. D. Zeng B. Ren J. R. Zeng T. Xu Y. Z. Yang X. C. Hu Z. Y. Zhu L. M. Shi G. Y. Zhou Q. Zhou X. M. Liu Y. H. Zhu 《Plant pathology》2020,69(2):259-271
Rice blast, caused by the fungus Magnaporthe oryzae, can result in notable yield losses in rice production. The objective of this study was to investigate the potential of a rice endophytic isolate, Streptomyces albidoflavus OsiLf-2, on the control of rice blast and the possible mechanisms involved. In vitro assays displayed a variety of antagonistic effects of OsiLf-2 against different physiological races of M. oryzae, with peak mycelial growth inhibition ranging from 74.1% to 83.0%. In vivo tests of OsiLf-2 showed 18.0% and 19.6% reduction in disease index in greenhouse and field conditions, respectively. The stable active metabolites in its cell-free culture filtrate inhibited the mycelial growth, spore germination and appressorial formation of M. oryzae in a dose-dependent manner. They also possessed strong antifungal capacities toward various phytopathogens in vitro. OsiLf-2 secreted multiple antimicrobial compounds, cell wall degradation enzymes, siderophore, plant hormones, and 1-aminocyclopropane-1-carboxylate deaminase, which might function in direct or indirect resistance to M. oryzae. In addition, a variety of defence responses were induced in OsiLf-2-treated rice, including hydrogen peroxide (H2O2) accumulation, callose deposition, defence-related enzymes activation, and elevated expression of salicylic acid (SA) and jasmonic acid (JA) pathways genes, which might contribute in resisting pathogen attack. The significant biological control activity and host defence-stimulation ability of OsiLf-2 suggest that this endophytic actinobacterial strain could be a promising candidate in the management of rice blast disease. 相似文献
17.
Long‐term survival of blast pathogen in infected rice residues as major source of primary inoculum in high altitude upland ecology 
下载免费PDF全文
下载免费PDF全文 Magnaporthe oryzae is the fungal plant pathogen that causes rice blast. The sources of primary inoculum and overwintering mode of the fungus remain largely unknown. The effect of rice residues on the onset of blast epidemics and the potential for survival of M. oryzae in the residues were studied in upland conditions in Madagascar. Blast disease was observed in a 3‐year field experiment in three treatments: with either infected or uninfected rice residues on the soil surface, or without rice residues. Leaf blast incidence was significantly higher in the treatment with infected rice residues than in the two other treatments at the early stages of the epidemic. In a second set of trials, the survival of M. oryzae on rice residues was monitored. Infected rice stems were placed by lots in three places: on the mulch of rice residues, under the mulch, and buried at a depth of 10 cm in the soil. Each month, samples were taken from the field and tested for sporulation. The survival of the blast fungus decreased rapidly on the stems buried in the soil but remained high for the other conditions. Sporulation of the fungus was observed on stems left on the mulch for up to 18 months. It is concluded that under field conditions, the presence of infected rice residues could initiate an epidemic of blast. The results of this study may help in designing effective management strategies for rice residues infected by M. oryzae. 相似文献
18.
19.
为了解黑龙江省水稻穗褐变病主要病原菌侵染时期及致病性情况,分别于水稻破口期、扬花期、乳熟初期采用禾谷镰孢Fusarium graminearum、链格孢Alternaria alternata、稻黑孢Nigrospora oryzae、黑附球霉Epicoccum nigrum对水稻穗进行注射和喷雾接种。结果表明,4种病原菌在水稻破口后即可侵染稻穗使谷粒颖壳变褐。注射接种稻穗谷粒褐变重于喷雾接种。4种病原菌的致病力存在明显差异,禾谷镰孢致病力最强,链格孢的致病力弱于禾谷镰孢。 相似文献
20.
Shengping Shang Xiaofei Liang Guangli Liu Song Zhang Zhongxin Lu Rong Zhang Mark L. Gleason Guangyu Sun 《Plant pathology》2020,69(3):538-548
Glomerella leaf spot (GLS), characterized by black necrotic spots and severe defoliation, is a destructive foliar disease of apple. Widely grown cultivars such as Gala and Golden Delicious are highly susceptible to GLS. Currently, the infection biology of the causal pathogen, Colletotrichum fructicola, on apple leaves is unclear. In the present study, the penetration and colonization processes of C. fructicola were characterized on apple (cv. Gala) leaves using light and transmission electron microscopy. C. fructicola conidia produced germ tubes 4 hours post-inoculation (hpi) and appressoria at 8 hpi. In melanized appressoria, funnel-shaped appressorial cones formed around the penetration pore. At 12 hpi, C. fructicola produced secondary conidia. After penetration, C. fructicola began to develop infection vesicles at 36 hpi. At 48 hpi, the primary hyphae of C. fructicola were produced from infection vesicles within host epidermal cells; the host epidermal cell plasma membrane remained intact, indicating a biotrophic association. Subsequently, secondary hyphae penetrated epidermal cells and destroyed cell components, initiating necrotrophic colonization. C. fructicola also produced biotrophic subcuticular infection vesicles and hyphae. Together, these results demonstrate that C. fructicola forms special infection structures and colonizes apple leaves in a hemibiotrophic manner, involving intracellular as well as subcuticular colonization strategies. Detailed characterization of the infection process of C. fructicola on apple leaves will assist in the development of disease management strategies and provide a foundation for studies of the molecular mechanism of the C. fructicola–apple leaf interaction. 相似文献