Factors Affecting Germination of Oospores of Phytophthora infestans

When oospores from the pairing between A¹ and A² mating types of Phytophthora infestans were treated with 0.25 % KMnO₄ solution for 15 min and incubated at 19 °C under light on a modified S+L medium, germination commenced within 4 days and reached about 70 % after 20 days. Under these conditions, more than 25 % of oospores obtained from a 4-day-old culture germinated. To obtain a high germination rate of P. infestans oospores, light was essential during germination but not during growth and oospore formation. The optimum time for activation of oospores with 0.25 % KMnO₄ was 15 to 30 min and a suitable concentration of KMnO₄ for 15 min activation was 0.25 to 0.45 %.     

Propagule bank buildup of Chara aspera and its significance for colonization of a shallow lake

Several aspects of the propagule bank dynamics including germination, burial and storage characteristics, and the relationship between the distribution of the propagule bank and cover of an expanding Chara vegetation (dominated by C. asperaDeth. ex Willd.) was studied in the shallow lake Veluwemeer. The density of oospores in the sediment was positively correlated with the number of years that Chara was present at that particular site. After six years of Chara presence, at least 1.7 × 10⁶ oospores m^–2 had accumulated in the sediment. Oospores in sediment were evenly distributed in the 15 cm top layer, which was very similar to the foraging depth of Bewick's Swans (Cygnus columbianus bewickii Yarr). Burial in the sediment may be an important mechanism by which oospores are stored. On the other hand, at shallow areas about 50% of the biomass was consumed enhancing the potential dispersal of oospores by water birds. In a laboratory experiment, 100% of the tested bulbils of C. aspera emerged and thus may be important for short time survival of established vegetation. In contrast, oospore germination varied between 1 and 15% depending on light level and burial depth. The low germination and the high accumulation of oospores suggest that oospores are adapted to long time survival in a dormant state. Charophytes colonized Veluwemeer step by step in the course of about nine years. Not all the sites with suitable light conditions were colonized at the same speed. C. aspera established a dense vegetation only at sites with high oospores densities (> c. 1 × 10⁴ m^–2). The results indicate that the high density of oospores needed for attaining complete vegetation cover may be an important limiting factor during colonization.     

Agarose Medium for Germination of Oospores of Phytophthora cactorum

When oospores of Phytophthora caetorum from 30-day-old culture were treated with 0.25% KMnO₄ for 20 min and incubated at 24°C under light for 10 days, 65–75% germinated on water agar and water agarose but only 1–21% germinated on V-8 agar and S+L agar. Water agarose was selected because germinated oospores formed restrieted colonies on this medium that could be isolated easily. KMnO₄ treatment killed sporangia, chlamydospores and mycelial fragments present in oospore suspensions. Under the above conditions, approximately 44% of oospores from 10-day-old culture germinated and the optimum germination rate of about 75% was obtained when oospores reached about 20 days old.     

Survival, Germinability and Infectivity of Oospores of Peronospora viciae f.sp. fabae

A series of experiments was conducted to germinate oospores of Peronospora viciae f.sp. fabae. With rare exceptions, dry-stored oospores did not germinate in water nor did they infect faba bean seedlings in soil. Long-term storage, pre-treatment with KMnO₄ or addition of nutrients to the medium did not induce germination. Survival and infectivity of dry-stored oospores were compared to those of oospores incorporated in a silt loam and a loamy sand soil in the field during 21–22 months. Under dry conditions, the percentage of living oospores did not change as determined by the vital stain tetrazolium bromide. In soil, less than 2% of the oospores had survived after 21 months. Infectivity of oospores was determined by a bioassay 17 and 21 months after oospores had been incorporated in soil. Diseased seedlings were obtained after inoculation of faba bean seeds with oospores extracted from the soil but not with the drystored ones. Soil samples from two field plots naturally infested with oospores 2 and 3 years before the bioassay were infective. Oospores collected with diseased plant material on one of these plots and subsequently stored dry for 3 years were not infective. The results suggested that oospores need a period of natural weathering to become germinable and infective.     

Testing of life history traits of a soilborne pathogen in vitro: Do characteristics of oospores change according the strains of Aphanomyces euteiches and the host plant infected by the pathogen?

Aphanomyces euteiches is a polyphagous, homothallic soilborne pathogen producing asexual (zoospores) and sexual (oospores) spores. Even if oospores are essential for disease development and survival, to date, no study has focused on the production rates of oospores or the quality of the offspring produced by oospores. In this study, a nonabrasive oospore extraction method from infected roots of leguminous species (pea, faba bean and vetch) was developed. This methodology includes steps of grinding and filtration. The quality of oospores (viable, dormant and dead) was assessed with tetrazolium bromide staining, and germination of oospores was tested using exudates of peas, faba bean and vetch. The average yield of the extraction method was approximately 21%. Staining revealed some differences between strains and between leguminous species. The germination percentage of oospores extracted from pea, faba bean and vetch was 25%, 62% and 70%, respectively, and a significant difference was observed according to the origin of A. euteiches‐inoculated strains. Application of exudates seems to stimulate the germination of oospores (2% for the control, 18% for pea exudates and 1% for vetch exudates). Differences observed between A. euteiches strains and leguminous species indicate that more knowledge concerning the biology of oospores is needed. This will help to better estimate evolution process of the pathogen and manage resistance and crop successions.     

Biological Control of Phoma and Pythium Damping-Off of Sugar-Beet with Pythium oligandrum

Flooding freshly harvested oospores in sterile distilled water (SDW) for several days enhanced germination in 3 out of 4 isolates of Phythium oligandrum. Treatment of SDW-flooded oospores with myo-inositol increased germinability during the first 20 days of storage at 15°C. Seed dressing with oospores of P. oligandrum controlled pre- and post-emergence damping-off of sugar-beet caused by soil-borne P. ultimum and seed-borne Phoma betae. For some isolates, flooded oospores in SDW and treatment with myo-inositol increased efficacy of the seed dressing. However, no significant control of damping-off caused by Rhizoctonia solani was observed. On corn-meal agar, P. oligandrum coiled around and penetrated hyphae of P. ultimum and R. solani, but did not interfere with Ph. betae.     

Effect of Flavin Inhibitors on Photoactivation of Oospores of Phytophthora cactorum

When dark-grown mature oospores of Phytophthora cactorum were activated to germinate by exposure to 5 uW cm^-2nm^-1 of fluorescent light at 20–22°C in the presence of certain flavin inhibitors such as KI, salicylhydroxamic acid and phenylaceric acid at 40. 1. and 0.1 mM respectively, photoactivation and hence subsequent germination of oospores were inhibited without appreciable irreversible effect on oospore viability. Likewise, when applied during the light period, NaN₃ and KCN at 1 mM reduced photoactivation but had a minimal effect on dark reactions. Diphenylamine, an inhibitor of certain carotenoids, had no effect on photoactivation of oospores. The data suggest that the photoreceptor pigment for activation of oospore germination is a flavin.     

Inhibition of Chara vulgaris oospore germination by sulfidic sediments

The germinability of Chara vulgaris oospores collected from the sediments of four Ontario lakes varies considerably, ranging in germination percentage from 7% to 54%. Chemical analysis of the interstitial water of the sediments indicated that oospores with low germination occurred in lakes which have high acid volatile sulfides (H₂S, FeS, HS⁻) and high soluble Fe²⁺. The inhibitory effects of sediment on oospore germination were demonstrated by transplant experiments, and suggested that sulfide was the toxic agent. Exposure of high-germinating sedimentary oospores to free sulfide concentrations greater than 2.0 mM caused a greater than 30% reduction in oospore germination. The presence of sulfide in sediments was shown to result from sulfate reduction by bacteria in sediment pore water of those lakes where oospore viability was lowest. Differences in oospore germination percentage appear, therefore, to be due to the toxicity of H₂S produced in the sediment, either by a direct effect on the oospore, or on the parent plants.     

Effect of Bacterial Antagonist on Phytopthora cactorum and Apple Crown Rot

Bacterial antagonist B8 produced an inhibition zone with each of four Phytophthora cactorum isolates on corn meal agar (CMA) plates. Infections with three P. cactorum isolates were significantly reduced when the soil was simultaneously inoculated with B8. Growth of P. cactorum was completely inhibited on CMA amended with 40–100 per cent 10 fold concentrated B8 extract. Percent oospore germination of P. cactorum was significantly reduced when B8 was present in suspension for 9, 12 and 15 days from inoculation. Survival of oospores was significantly reduced at 60 and 90 mm depths in soil. Bacterial antagonist B8 significantly reduced the population of viable P. cactorum oospores in the top 30 mm of soil where oospores generally survive.     

Germination of Chara vulgaris and Nitella flexilis oospores: What are the relevant factors triggering germination?

Factors governing the germination of Chara vulgaris L. and Nitella flexilis L. were investigated in a series of three experiments. Temperature, light regimes, drying, and changes in oxidation–reduction potential are postulated to be possible triggers working in isolation or in combination on dormant oospores originating in sediments with different physical/chemical characteristics.In Experiment 1, none of the N. flexilis oospores inoculated into Petri plates and culture tubes containing either agar or water and then exposed to ‘normal’ 12 h daylight 12 h dark germinated when the redox of the media remained relatively constant over the 20-day observation period, while all of the oospores in a tube in which the redox of the agar declined to below 200 mV, germinated. Similarly no germination occurred in the dark without a decrease in redox. When redox fell to below 200 mV, 11% of the inoculated oospores germinated.In Experiment 2, N. flexilis and C. vulgaris oospores were subjected to cold pre-treatments and inoculated into either water or agar in both plates and tubes. Of the N. flexilis oospores 53% germinated in the dark, and 31% under normal lighting. Of the C. vulgaris, 3% germinated in the dark and 53% under normal lighting. The stimulation of germination with the decrease in redox in the media did not re-occur.Experiment 3 compared the germination of C. vulgaris oospores from four ponds contaminated by mining wastes and from a comparatively clean wetland. The oospores were again subjected (or not) to cold pre-treatments, and were drawn from both freshly concentrated sediments and air-dried sediments that had been held in storage for either 97 or 376 days. Notably, a consistent reduction in oospore viability occurred in oospores from a particular mine pond, contaminated by nickel tailings.     

Location of Oospores in Buckwheat Seed and Probable Roles of Oospores and Conidia of Peronospora ducometi in the Disease Cycle on Buchwheat

Oospores of Peronospora ducometi, the causal agent of downy mildew of buckwheat (Fagopyrum esculentum), were found in the calyx remnant attached to the seed, on the inside of the seedcoat and in the spermoderm layer between the seedcoat and the endosperm. This constitutes a first report documenting the location of oospores in buckwheat seed. Systemic infection of seedlings occurred from oospore-infested seed. Conidial germination was greater at 14°C than 25°C. Systemic infection also occurred as the result of conidial infection of leaves. It is proposed that primary infection of buckwheat occurs by the germination of seed-borne oospores resulting in systemic invasion of the seedling by the germtubes, and followed by conidial formation on the cotyledons. Secondary infection occurs initially from conidia produced on the cotyledons as a result of the systemic infection from seed and subsequently as the result of repeated infections by conidia produced on leaf lesions as the disease progresses up the plant.     

马铃薯晚疫病菌卵孢子萌发的初步研究

描述了马铃薯晚疫病菌卵孢子萌发的方式并研究了菌株组合、卵孢子形成时间、在琼脂培养基上培养时间及光照对卵孢子萌发的影响,结果表明不同菌株组合卵孢子萌发率为0—7.2%,对峙培养20天后形成的卵孢子的萌发率最高达8.7%,在琼脂培养基上培养25-30d 萌发率最高达11.4%,卵孢子形成时黑暗及在琼脂培养基上萌发时光照萌发率最高达11.8%。     

Production of Phytophthora infestans oospores in planta and inoculum potential of in vitro produced oospores under temperate highlands and subtropical plains of India

High moisture content of the host tissue ( 88%) and low ambient r.h. (50-54%) favoured oospore formation under controlled environments. It took 14–16 days for oospores to develop; thereafter the number of oospores increased with time and decreased with moisture content of host tissue. High ambient r.h. (> 80%) did not favour oospore formation under field or controlled conditions. Oospore formation was detected in inoculated plants grown in the field when the ambient r.h. declined to 74% and moisture content of host tissue decreased to 83.7–85.6%. It took 8 days (cv. Kufri Chandramukhi) to 13 days (cv. Kufri Jyoti and Kufri Badshah) for oospores to develop. Cultivars also differed in their response to oospore production, cv. Kufri Chandramukhi being more responsive (4800 oospores g⁻¹ f wt) than cv. Kufri Jyoti and Kufri Badshah (1320 and 390 oospores g⁻¹ f wt respectively). Oospores produced in vitro remained viable when buried in soil in the temperate highlands of Himachal Pradesh and sub-tropical plains of Uttar Pradesh, India for more than 150 days, i.e. beginning of the next crop season. The oospores germinated and initiated late blight infection at the base of the stems after 21–30 days of incubation of the potato plants raised in oospore-infested soil. It took 2 days for newly formed oospores to germinate and this delay time increased to 75–77 days after 180-days burial. It took 15 days for their germination (47%) in soil extract as compared to 50 days in sterilised distilled water.     

Vertical structure of seed banks and the impact of depth of burial on recruitment in two temporary marshes

The structure of the seed bank (including Chara oospores), in relation to depth within the sediment and disturbance, was studied in two Rhône delta temporary marshes for two years. The seeds of all species were concentrated in the top 2 cm of sediment with very low numbers beeing found below 4 cm. When an exclosure eliminated disturbances of the sediment by animals, the vertical repartition of seeds at site 2 was more pronounced than outside the exclosure.In experiment 1, the emergence capacity of seeds from different depths and buried under layers of sterile equivalent to those in the field was measured. Depending of the species, 22 to 98% of the seeds germinated from unburied seeds in the top 2 cm. Only 1% of the oospores of Chara (from site 2) at 2 to 4 cm depth in the sediment emerged.In experiment 2, surface seed bank samples were placed under 0, 2 or 4 cm sterile sediment depth. The samples contained numerous recent seeds and the emergence percentage reached 41% (for Ruppia maritima). Only the seeds of Zannichellia spp failed to germinate from a depth of 2 cm or more. The emergence percentage from 2 cm depth or more was always lower than at the surface. These experiments showed that both burial and ageing of seeds decrease germination capacity.The majority of the active seeds located at the surface germinate when the marsh is flooded. Seeds located between 2 and 4 cm can be brought back to the surface by disturbances and play the role of a reserve involved in maintenance of populations that go without seed production for one or some years.     

Phytochrome-mediated germination of very sensitive oospores

The light receptor and its mode of operation were studied in photosensitive oospores of Nitella furcata subsp. megacarpa (Allen emend. Wood). Brief pulses of light activated maximal germination of post-secondary dormant oospores removed from lake sediments. Fluence response data at 12 wavelengths were used to construct an action spectrum for germination. The shape of the action spectrum with its maximum at 669 nm provides evidence for the involvement of phytochrome. Germination was induced with photon fluences that established as little as 0.01% of the phytochrome in the far red-absorbing form, which suggests that phytochrome was operating in the very low-fluence response mode. The functioning of phytochrome in the very low-fluence response mode in Nitella is similar to that in higher plants.     

In planta selfing and oospore production of Phytophthora cinnamomi in the presence of Acacia pulchella

This paper provides the first evidence of A2 type 1 and type 2 isolates of Phytophthora cinnamomi producing selfed oospores in planta in an Australian soil and in a potting mix. Oospores were observed in infected lupin (Lupinus angustifolius) roots incubated for 7 d either in the substrate under potted Acacia pulchella plants, or in soils collected from under and near varieties of A. pulchella in jarrah (Eucalyptus marginata) forest. The A2 type isolates varied in their ability to produce selfed oospores and none were produced by A1 isolates. The gametangial association was amphigynous and spores were predominantly spherical with diameters from 13–40 μm. The oospores were viable but dormant. Two A2 type isolates produced small numbers of selfed oospores with amphigynous antheridia axenically in Ribeiro's liquid medium within 30 d, and one A2 type 2 isolate produced oospores after mating with an A1 strain. Evidence is presented that the presence of roots of Acacia pulchella, and particularly A. pulchella var. glaberrima and var. goadbyi, enhances the production of oospores.     

Isolation of Oospores of Sunflower Downy Mildew, Plasmopara halstedii, and Microscopical Studies on Oospore Germination

A method was elaborated to isolate oospores of Plasmopara halstedii from tissue of its host, Helianthus annuus . Isolated oospores were studied microscopically and germination was documented with respect to the time course and the mode of germination. Formation of primary sporangia was similarly observed in oospores, harvested from 4- to 6-week-old systemically infected sunflower plants, grown under constant conditions at 16°C, as well as from field plants, harvested late in the season. Pretreatment of oospores with cold temperatures, previously assumed to stimulate the rate and to accelerate the speed of oospore germination, did not result in such effects. Germination usually occurred within 10–30 days of incubation at a highly variable rate of about 1 to 17% (average 6.7%) in deionized water.     

Dormancy and growth-inhibitor levels in oospores of Chara contraria A. Braun ex Kütz. (Charophyta)

Experiments on oospores of Chara contraria A. Braun ex Kutz. studied the correlation between dormancy and plant growth inhibitors. Fresh oospores, harvested from a drainage channel, showed a germination rate in vitro of 44–85%. Extracts from oospores harvested at the end of the summer contained inhibitory activity, which co-chromatographed with abscisic acid, but no inhibitors were detected in harvests from the beginning of the summer nor in oospores which lay dormant at the botton of the channel. No correlation between inhibitory activity and dormancy was detected. Our results support the hypothesis that the inhibitors detected play a role in the abscission of oospores from the mother plant.     

Oospores of <Emphasis Type="Italic">Chara tomentosa</Emphasis> from Holocene sediments of Lake Zeribar (Iran)

Biometric measurements were performed on oospores of Chara tomentosa from Core 63-J from Lake Zeribar in Iran. The partially fossilized oospores examined did not differ significantly in dimensional measurements, number of ridges, or colour from oospores of modern specimens of C. tomentosa.     

TAXONOMY OF CHARA BRAUNII: AN EXPERIMENTAL APPROACH1

Results from the present study suggest that Chara braunii encompasses a complex of geographical races or incipient species that although morphologically similar, are isolated to varying degrees ranging from partial interfertility to complete reproductive incompatibility. Most of the 6 clones studied were interfertile to the extent that fertilization was followed by the development of black oospores, but subsequent germination tests disclosed that many of these either failed to germinate or gave rise to offspring that were partially or completely sterile. No support was encountered for the suggestion that C. braunii is of recent development or that it has been distributed rapidly throughout the world.