应用免疫胶体金技术定位感病大麦细胞中的大麦和性花叶病毒

本文报道免疫胶体金标记技术的建立,并用此技术定位大麦叶和根组织超薄切片中大麦和性花叶病毒(BaMMV)。在感染病毒的大麦叶和根细胞中,病毒束、游离病毒颗粒和病毒外壳蛋白多分布于细胞质丰富的细胞中,且以液泡和叶绿体(仅叶组织)周围较多。在细胞器已解体的病根表皮细胞中,有时也可检测到大量游离病毒粒子。少数风轮体或板状集结体上也存在病毒或病毒外壳蛋白。细胞核、叶绿体、线粒体、细胞膜以及其他细胞器上都未见有特异性金颗粒标记。     

Confirmation of the transmission of barley yellow mosaic virus (BaYMV) by the fungus Polymyxa graminis

Resting spores (cystosori) of Polymyxa graminis, selected from roots of barley plants infected with barley yellow mosaic virus (BaYMV), were used to start mono-fungal sand cultures. Out of 20 attempts using over 800 cystosori, P. graminis became established in 12, and in two of these BaYMV symptoms also occurred. BaYMV was detected by ELISA in extracts of dried roots heavily infected with cystosori and in zoospores of P. graminis. Calculations suggested that, on average, each zoospore carried less than 100 virus particles. In two virus acquisition experiments, non-viruliferous isolates of P. graminis failed to acquire BaYMV from roots of mechanically-inoculated plants. In two further experiments, non-viruliferous isolates were grown on rooted tillers produced from healthy plants and those infected with BaYMV by either vector or mechanical inoculation. Zoospores and cystosori of P. graminis subsequently transmitted the virus, but only from plants where it had been introduced by the vector. Repeated mechanical transmission appeared to have selected a strain of virus that could not be acquired and/or transmitted by the vector. The results provide convincing evidence that P. graminis is a vector of BaYMV but suggest that, in natural populations, only a small proportion of spores may be viruliferous.     

The susceptibility of barley cultivars to barley yellow mosaic virus (BaYMV) and its fungal vector, Polymyxa graminis

In glasshouse experiments, barley seedlings were inoculated with barley yellow mosaic virus (BaYMV) either mechanically or by using zoospores or cystosori of a viruliferous isolate of the vector, Polymyxa graminis, maintained on barley in sand culture. Experiments using mechanical inoculation showed that seedlings became more resistant with age. Consistent cultivar differences were obtained: cvs Maris Otter and Halcyon were very susceptible and cv. Athene seemed immune. Symptoms developed more rapidly at 23 than at 17 or 11 ^oC. After vector inoculation, symptoms developed more slowly than after mechanical inoculation but cultivar ranking was similar. Cultivars did not differ in susceptibility to the vector, as measured by zoospore production on their roots. Spring barley cultivars supported the growth of the vector which remained viruliferous and some showed symptoms although, in the field, symptoms do not appear on spring-sown crops.     

The effect of the weight of the seedling-derived tuber on subsequent clonal generations in a potato breeding programme

Cultures of Polymyxa graminis were maintained in roots of barley plants grown in sand at different temperatures using Wisconsin soil temperature tanks. At 17 – 20°C, the minimum time from inoculation with cystosori to the production of zoospores from the inoculated roots was 2 – 3 wk. At 11 – 20°C many zoospores were produced but the incubation period was longer at the lower temperatures. Above 20°C little fungal development occurred. The duration of motility of zoospores ranged from c. 1 h to > 24 h. Bovine serum albumen (BSA) prolonged motility but glycine and glucose had no effect or, at higher concentrations, were toxic. Zoospores were rapidly immobilised by zinc ions in solution at or above 10μg/ml. In some experiments BSA added to the zoospore suspension greatly increased transmission of barley yellow mosaic virus (BaYMV) while glucose, glycine and ovalbumen decreased it. When seedlings were incubated with zoospore suspensions for 24 h at different temperatures, BaYMV transmission was high (> 60%) at 10, 15 and 20°C but there was little at 5 or 25°C. In experiments to determine the time taken for zoospore penetration, seedlings were incubated in suspension for different periods of time and then rinsed in zinc sulphate solution to kill free zoospores. Between 3 and 3·5 h was needed for zoospores to establish infection. Transmission occurred equally to plants of various ages between 3 days and 7·5 wk.     

The effect of cultivar used as host for Polymyxa gmminis on the multiplication and transmission of barley yellow mosaic virus (BaYMV)

A viruliferous isolate of the fungal vector Polymyxa graminis was grown on roots of barley cultivars immune or susceptible to barley yellow mosaic virus (BaYMV). Zoospores or resting spores of the vector produced on different cultivars were then inoculated to a virus-susceptible test cultivar. Although the vector established in all treatments, transmission of BaYMV was rare and usually nil from immune cultivars; amounts of virus detected serologically in their roots were very low, thus showing that resistance was to virus multiplication. If immune cultivars decrease the virus content of vector populations in the field, this would have important implications for disease control.     

Immunolocalization of 1,3‐β‐Glucanases Secreted by Gaeumannomyces graminis var. tritici in Infected Wheat Roots

The distribution of extracellular 1,3‐β‐glucanase secreted by Gaeumannomyces graminis var. tritici (Ggt) was investigated in situ in inoculated wheat roots by immunogold labelling and transmission electron microscopy. Antiserum was prepared by subcutaneously injecting rabbits with purified 1,3‐β‐glucanase secreted by the pathogenic fungus. A specific antibody of 1,3‐β‐glucanase, anti‐GluGgt, was purified and characterized. Double immunodiffusion tests revealed that the antiserum was specific for 1,3‐β‐glucanase of Ggt, but not for 1,3‐β‐glucanase from wheat plants. Native polyacrylamide gel electrophoresis of the purified and crude enzyme extract and immunoblotting showed that the antibody was monospecific for 1,3‐β‐glucanase in fungal extracellular protein populations. After incubation of ultrathin sections of pathogen‐infected wheat roots with anti‐1,3‐β‐glucanase antibody and the secondary antibody, deposition of gold particles occurred over hyphal cells and the host tissue. Hyphal cell walls and septa as well as membranous structures showed regular labelling with gold particles, while few gold particles were detected over the cytoplasm and other organelles such as mitochondria and vacuoles. In host tissues, cell walls in contact with the hyphae usually exhibited a few gold particles, whereas host cytoplasm and cell walls distant from the hyphae were free of labelling. Furthermore, over lignitubers in the infected host cells labelling with gold particles was detected. No gold particles were found over sections of non‐inoculated wheat roots. The results indicate that 1,3‐β‐glucanase secreted by Ggt may be involved in pathogenesis of the take‐all fungus through degradation of callose in postinfectionally formed cell wall appositions, such as lignitubers.     

Acquisition and transmission of potato mop-to furovirus by a culture of Spongospora subterranea f.sp. subterranea derived from a single cystosorus

Potato mop-top virus (PMTV) was detected by ELISA in primary zoospores from four out of six isolates of Spongospora subterranea f.sp. subterranea. One virus-free isolate (N) of S. subterranea was used to acquire PMTV from potato roots and to transmit the virus to healthy plants. A mono-fungal culture of S. subterranea (isolate N) was derived by infecting tomato plant roots with a single cystosorus. The culture was used successfully to acquire PMTV from the roots of infected Nicotiana debneyi plants that had been manually inoculated with virus isolates, and subsequently to transmit the virus to healthy bait plants. These experiments confirm that S. subterranea is a vector of PMTV. Two PMTV isolates that had been maintained by manual inoculation for 19 and 21 passages were also acquired and transmitted by the fungus culture.     

Localization of the beet mild yellowing virus inSinapis alba L.

Virus particles of isometric shape with a diameter of 26 nm were found in the sieve tubes and accompanying phloem cells in ultrathin sections prepared from the nerves of white mustard (Sinapis alba L.) leaves and roots infected with the beet mild yellowing virus (BMYV). BMYV particles were much more frequent in the roots ofSinapis alba plants. Isometric particles were not found in the leaves and roots of healthy mustard plants.     

Quantitative assay of resting spores of Polymyxa graminis on barley roots

A procedure was developed to examine amounts of Polymyxa graminis on eleven barley cultivars from a field experiment on a site infested with barley yellow mosaic virus (BaYMV) and which differed in field response to the virus. Powder produced from dried barley roots infected with P. graminis was soaked overnight at 4°C in a solution of 1 % sodium metaphosphate and 0.25% Tween 20. This was followed by high speed homogenisation, filtering, ultrasonic treatment of the residue and differential centrifugation. A suspension of individual resting spores free from other recognisable fungi was obtained, which ranged in concentration from 0.4 to 7.3 × 10⁷spores per g root. Repeated extraction of the residues suggested that most spores were liberated by the first cycle of treatment. The cultivar with the greatest incidence of BaYMV also had the most P. graminis; some cultivars resistant to BaYMV had less P. graminis but there was no general correlation between the incidences of virus and vector.     

Augusta disease in tulip - a reassessment

In an experiment in which the roots of field-grown tulip were commonly infected with tobacco necrosis virus (TNV), Augusta disease did not develop in the year of infection or when progeny bulbs were grown in the field or glass-house. When tulip bulbs of other stocks, including grades of 11 and 12 cm circumference, were forced, the disease developed sporadically, in some instances as the result of infection with TNV from the soil in which they were planted and in others as a result of infection by bulb-borne virus. The incidence of disease produced by current year infection was increased by warming the plunge bed. Different strains of TNV were obtained from field-grown plants with Augusta disease and different strains of the virus produced the disease when inoculated to tulip. Some, but not all, naturally diseased plants contained satellite virus, which therefore does not cause or prevent disease development. The disease was produced in some plants by TNV transmitted by Olpidium brassicae, but neither a vector nor a non-vector isolate of O. brassicae completed its life cycle in tulip. However, Olpidium-like zoospores were observed in some washings of tulip roots from TNV-infested soils. TNV was not obtained from all tulip plants with necrotic leaf symptoms resembling Augusta disease. Some were infected with tomato bushy stunt virus or cucumber mosaic virus, or with another agent that was transmitted by inoculation of sap to Nicotiana clevelandii and Chenopodium quinoa, and carried by bulbs of up to 11 cm circumference.     

Virus-like particles in phloem tissue of chervil (Anthriscus cerefolium) infected with carrot red leaf virus

Isometric virus-like particles c. 22–25 nm in diameter were found in ultrathin sections of chervil leaves infected with carrot red leaf virus (CRLV). The particles were confined to the phloem and occurred in less than 5% of the cells in the vascular bundles. They were commonest in companion cells, occurred frequently in sieve elements and were also found in phloem parenchyma cells. The observations support other evidence that CRLV should be classified in the luteovirus group.     

Transmission of plant viruses by fungi

The evidence for the mechanisms involved in virus transmission by fungi is reviewed in relation to the non-persistent and persistent categories usually recognised. Non-persistent transmission by Olpidium spp. has been little studied in the last 20 years, but appears to depend on adsorption of virus to the outside of the fungal zoospores. This seems to be under the genetic control of both the virus (via its coat protein) and the vector. Such viruses are not transmitted in the fungal resting spores. The route by which the virus is transferred from the vector to the host may involve uptake into the zoospore but this deserves further study. Persistent transmission by Olpidium, Polymyxa and Spongospora spp. is less well characterised. Some of the evidence used for its support is inconclusive. The viruses are probably always carried inside zoospores, and they also persist in the fungal resting spores. Transmission depends on the genome of the vector and the virus, but not exclusively on the virus coat protein.     

感染大麦黄花叶病毒(BaYMV)的大麦细胞质内含体及细胞器病变的研究

超薄切片电镜观察表明,在感染大麦黄花叶病毒(BaYMV)的大麦(品种“早熟3号”)叶肉细胞中,液泡周围偶而可看到病毒颗粒束,在发病后期黄化或坏死的叶肉细胞中,可见到散布的病毒颗粒。在所有表现症状的病叶叶肉细胞,表皮细胞和木质部薄壁细胞中均可观察到风轮体、束状体、板状集结体以及膜状体等细胞质内含体,未见 卷简体和细胞核内含体。感病初期细胞中,细胞质丰富,核糖体数量增加,内质网肥大,随着病毒症状发喂,叶绿体、线粒体等细胞器逐渐肿大,外膜破裂直至解体。     

The location of raspberry ringspot and tomato black ring viruses in the nematode vector, Longidorus elongatus (de Man)

Electron microscopy of thin sections of Longidorus elongatus (de Man) fed on plants infected with raspberry ringspot and tomato black ring viruses showed virus-like particles in the lumen of the buccal capsule and in the space between the stylet and the guiding sheath. In sections of L. elongatus fed on plants infected with arabis mosaic virus, which it does not normally transmit, a few virus particles were seen in the buccal capsule but none was associated with the stylet guiding sheath. It is suggested that the association of virus particles with the cuticular guiding sheath is an explanation of the specificity of virus transmission evident in L. elongatus.     

Further properties of peanut clump virus and studies on its natural transmission

Purified preparations of particles of peanut clump virus (PCV) had A₂₆₀/A₂₈₀ values (corrected for light scattering) of 1.00. They contained rod-shaped particles with sedimentation coefficients of 183 S and 224 S, and a density in CsCl of 1.32 g/ml. PCV infected 36 species in 8 plant families. No serological relationship was detected between PCV and barley stripe mosaic, beet necrotic yellow vein, Nicotiana velutina mosaic and tobacco mosaic viruses. PCV was seed-borne for two generations in groundnut (Arachis hypogaea) but was not seed-borne in great millet (Sorghum arundinaceum), Phaseolus mungo or Nicotiana benthamiana. Seedlings of groundnut, great millet and wheat (Triticum aestivum) became infected when grown in soil from groundnut fields with outbreaks of clump disease, and the infectivity of soil survived air-drying at 25°C for 3 months. Groundnut seedlings became infected when grown in sterilised soil contaminated with washed roots of naturally-infected S. arundinaceum but not in soil to which roots of naturally infected groundnut or shoots of infected groundnut were added, or in which mechanically inoculated groundnut seedlings were grown at the same time. The patchy distribution of PCV in a crop was related to the infectivity of the soil for groundnut and to the presence of Polymyxa graminis resting spores which could be detected in the roots of S. arundinaceum bait seedlings, but not in those of groundnut. The results indicate that PCV is transmitted by a vector that is resistant to air-drying and closely associated with S. arundinaceum roots. For these reasons P. graminis is thought to be the vector of PCV.     

Calcium Enhanced Zoospore Production of Pythium myriotylum in vitro

Pythium myriotylum is the causal organism of Cocoyam Root Rot Disease (CRRD). Significant numbers of zoospores were induced within 1.5 h in cultures in Petri dishes containing P. myriotylum soaked in 0.01 M Ca⁺⁺ and sterile deionized distilled water. Soaking solutions # 2 and # 3 inhibited the production of zoospores of P. myriotylum. This may be due to the delay in maturation of sporangia and the release of zoospores when the soaking solutions contain sucrose. Significant necrosis of detached cocoyam plantlet roots in 100 ml beakers confirmed the infection of zoospores of two `local white' cocoyam genotypes. Detached `yellow' cocoyam roots in 100 ml beakers of genotype RO3015 resisted infection of P. myriotylum with no necrosis of the inoculated roots, which may indicate resistance. This provides a quick and reliable pathogenicity test of P. myriotylum on susceptible cocoyam detached roots. Necrosis of inoculated detached cocoyam roots could be reliably used to screen cocoyam germplasm for resistance to P. myriotylum.     

Cytopathology of Anthers and Pollen From Lettuce Plants Infected by Lettuce Mosaic Virus

Thin sections of mature anthers and pollen grains from three lettuce (Lactuca sativa) plants infected with lettuce mosaic potyvirus (LMV) were studied by immunogold labelling. Labelled LMV particles were present externally on the exine of pollen grains from all plants, but were observed internally in the pollen grains from only one plant. Within mature pollen grains the virus particles were associated with the cytoplasmic bundle inclusions typical of infection by potyviruses. The tapetal plasmodium and the epidermal and endothecial layers of mature anthers from all infected plants also contained labelled virus particles, together with pinwheel and bundle inclusions.     

Fat distribution in the skin of bottlenose dolphins (Tursiops truncatus and Tursiops gilli)

Frozen sections stained with Oil-red-O and semithin (0.5 μm) plastic sections stained with toluidine blue revealed an abundance of fat globules of various sizes in all strata of the epidermis of bottlenose dolphins (Tursiops truncatus and T. gilli). The fat was rather evenly distributed but sometimes appeared as circumscribed areas of heavier concentration involving hundreds of cells (as seen in a single plane). Occasionally, there were smaller groups of epidermal cells heavily loaded with lipid. The dermis presented a unique phenomenon in the presence of abundant extracellular fat distributed among the collagen bundles as droplets of various sizes or as larger, irregularly shaped lipid particles that seemed to conform to the spaces between collagen bundles. These lipid particles were sometimes seen to be closely applied to the dermal surface of the stratum basale. Equally unusual was the presence of lipid particles of various sizes and shapes in the lumen of some of the vessels of the dermal papillae. Granular cells resembling mast cells were commonly seen in the papillary dermis and some were closely associated with lipid particles. Blood vessels of the reticular dermis tended to have collections of lipid droplets in the loose connective tissue often found adjacent to the tunica adventitia. It is postulated that the extracellular dermal lipids (probably mainly triglycerides) are broken down to free fatty acids that diffuse into the basal layer of the epidermis and are there resynthesized into triglycerides. Possible uses for the epidermal lipids are discussed.     

Studies on melon necrotic spot virus disease of cucumber and on the control of the fungus vector (Olpidium radicale)

Melon necrotic leaf spot virus (MNSV) caused a major outbreak of a leaf necrosis disease of hydroponically-grown cucumber plants at Humberside in 1983. The virus had c. 33 nm diam. particles which reacted serologically with MNSV antiserum of Dutch or American origin. Virus particles, which contained a single polypeptide (mol. wt 45 × 10³) and a presumed RNA species (mol. wt 1.5 × 10⁶), had a sedimentation coefficient (s_20.w) of 134 S and a buoyant density in caesium chloride of 1.35 g/cm³. The virus was mechanically transmissible, confined to species of Cucurbitaceae, transmitted by zoospores of Olpidium radicale and retained in the resting spores of the fungus. MNSV is thus both water-borne and soil-borne. O. radicale zoospores were killed in <5 min in suspensions containing 20 μg/ml of the surfactant Agral (alkyl phenol ethylene oxide). The disease did not reappear in 1984 when the cucumber crops were fed with nutrients containing 20μg/ml Agral.