Production of Zoospores, Mode of Infection, and Inoculum Potential of Pythium myriotylum Propagules on Cocoyam

Zoospores of Pythium myriotylum were consistently produced from sporangia of detached mycelia in vitro in deionized water at pH 7.0 with 0.001 M sucrose in 24 h of continuous fluorescent light at 31°C. The oblong-to-pea shaped zoospores measured from 2.5–7.5 μm in diameter and remained motile for more than 48 h. The lengths of flagella were 1–1.5 times the diameter of the zoospores. Contaminated cultures of P. myriotylum were revived to pure isolates by the use of zoospores. The penetration of P. myriotylum propagules took from 6 to 7 h following contact of the inoculum with the roots, and the invasion was inter- and intracellular. At the minimum concentrations of 200 zoospores/ml or 180 mycelial strands/ml, P. myriotylum caused symptoms of CRRD within 3 to 6 days after inoculation of the roots of cocoyam plantlets, results indicating that the pathogen is very destructive in cocoyam.     

A PCR-RFLP assay for identification and detection of Pythium myriotylum, causal agent of the cocoyam root rot disease

Aim: Development of a PCR‐RFLP assay that could reliably distinguish strains of Pythium myriotylum that are pathogenic to cocoyam from nonpathogens, as well as in planta detection of the pathogen. Methods and Results: Sequences of the internal transcribed spacer regions of nuclear ribosomal DNA (rDNA‐ITS) containing ITS1 and ITS2 of P. myriotylum isolates from cocoyam and other hosts were aligned and a restriction map was generated. rDNA‐ITS alignment report revealed a new single nucleotide polymorphism (SNP; thymine/cytosine) downstream to previously published SNP (guanine/adenine) between isolates of P. myriotylum that are pathogenic to cocoyam and nonpathogenic strains. This new SNP is within the restriction site of the endonuclease AarI. Based on this SNP, a PCR‐RFLP assay was developed for specific detection of P. myriotylum. The PCR amplicons of all isolates of P. myriotylum that infect cocoyam were cleaved by AarI, resulting to two bands (600/400 bp); but those from other hosts showed a single band (1000 bp), confirming the presence and specificity of the AarI restriction site. Also, the assay was effective in in planta detection of the pathogen on infected cocoyam roots without prior isolation of a pure culture. Conclusion: A PCR‐RFLP method was developed that differentiates isolates of P. myriotylum that are pathogenic to cocoyam from nonpathogens as well as from other fungi commonly found in the cocoyam rhizosphere. Significance and Impact of the Study: Early and rapid detection of the pathogen could be of great importance in certifying planting materials as disease‐free, enhancing sustainable management practices and limiting economic losses.     

Intraspecific variability of Pythium myriotylum isolated from cocoyam and other host crops

Intraspecific variability within 51 isolates of Pythium myriotylum from cocoyam (Xanthosoma sagittifolium) and other host crops was analysed using optimum growth temperature, esterase banding patterns, AFLPs, rDNA–ITS sequencing, and virulence to cocoyam. P. myriotylum isolates virulent to cocoyam could easily be differentiated from other isolates of P. myriotylum by their optimum growth temperature. Isolates from cocoyam grew best at 28 °C with no growth at 37 °C, while P. myriotylum isolates from other host crops had their optimum growth temperature at 37 °C. Esterases produced consistent zymograms with 18 discrete esterase markers, but no monomorphic markers were produced for isolates virulent to cocoyam. Isozyme profiles based on esterase analysis showed that isolates that infect cocoyam plantlets formed a related group, irrespective of their geographic origin. P. myriotylum isolates from other host plants also grouped together, but could clearly be distinguished from the cocoyam cluster. AFLPs produced 189 scorable bands for the cocoyam isolates, of which 77 % are monomorphic. Phenetic analysis of AFLP data grouped all isolates originating from cocoyam together except for the isolates C103-04, CMR17, CMR22, and CMR25. These isolates regrouped with isolates of Pythium myriotylum from other host crops or the outgroup and were found not to be pathogenic for cocoyam. ITS sequences of isolates of P. myriotylum from cocoyam were 99.1–99.7 % identical to sequences deposited in GenBank. However, alignments of ITS sequences revealed a base transition at position 824 from adenine in typical isolates of P. myriotylum to guanine in isolates that could infect cocoyam plantlets. In a limited pathogenicity test, all isolates from cocoyam having guanine at position 824 were able to infect tissue culture derived cocoyam but not those exhibiting adenine. This study demonstrates for the first time, molecular evidence that isolates of P. myriotylum that infect cocoyam are distinct from P. myriotylum isolates from other crops and have developed a certain degree of host adaptation.     

Isolation and Pathogenicity of Rhizosphere Fungi of Cocoyam in Relation to Cocoyam Root Rot Disease

Cocoyam is the second most important staple crop of Cameroon and root rot is a destructive disease of this plant. Pythium myriotylum (Pm), Fusarium solani (Fs), and Rhizoctonia solani (Rs) were isolated from the rhizosphere of root rot affected cocoyams and from the soil of a cocoyam experimental field plot temporarily devoid of same in Mamu, Cameroon. Pm was isolated from the above soil by the cocoyam leaf disc baits. Fs and Rs were also isolated from the same soils by the water dilution method and from the roots of diseased cocoyams but were always associated with mycelial growth of Pm. Pathogenicity of Pm and in combinations with Fs or Rs or Fs + Rs all developed cocoyam root rot disease (CRRD) symptoms on 3– and 7–month old cocoyam plantlets 2–7 days after inoculation. Symptoms included rotted roots and wilting with general chlorosis of inoculated plantlets. No symptoms of CRRD were noted on cocoyam plantlets inoculated with Fs, Rs, Fs + Rs, and distilled water. Results indicated that CRRD is not caused by several pathogens but only by Pm. Pm isolates from the soils and roots of diseased cocoyams and those maintained in the ROTREP laboratory have significantly bigger diameter of mycelial colony growth in 24 h–period at 31 °C on lima bean sucrose agar, V–8 juice sucrose agar, and potato sucrose agar than on potato dextrose agar and 2 % water agar. The cocoyam plantlets were raised axenically from tissue culture of explants in the laboratory.     

Fluorescent Pseudomonas and cyclic lipopeptide diversity in the rhizosphere of cocoyam (Xanthosoma sagittifolium)

Cocoyam (Xanthosoma sagittifolium (L.)), an important tuber crop in the tropics, is severely affected by the cocoyam root rot disease (CRRD) caused by Pythium myriotylum. The white cocoyam genotype is very susceptible while the red cocoyam has some field tolerance to CRRD. Fluorescent Pseudomonas isolates obtained from the rhizosphere of healthy red and white cocoyams from three different fields in Cameroon were taxonomically characterized. The cocoyam rhizosphere was enriched with P. fluorescens complex and P. putida isolates independent of the plant genotype. LC–MS and NMR analyses revealed that 50% of the Pseudomonas isolates produced cyclic lipopeptides (CLPs) including entolysin, lokisin, WLIP, putisolvin and xantholysin together with eight novel CLPs. In general, CLP types were linked to specific taxonomic groups within the fluorescent pseudomonads. Representative CLP-producing bacteria showed effective control against CRRD while purified CLPs caused hyphal branching or hyphal leakage in P. myriotylum. The structure of cocoyamide A, a CLP which is predominantly produced by P. koreensis group isolates within the P. fluorescens complex is described. Compared with the white cocoyam, the red cocoyam rhizosphere appeared to support a more diverse CLP spectrum. It remains to be investigated whether this contributes to the field tolerance displayed by the red cocoyam.     

Variations in the Phenolic Contents of Cocoyam Clones in Correlation to Resistance to Pythium Myriotylum

Phenolic compounds from leaves and roots of infected and healthy cocoyam clones resistant (RO1075), tolerant (RO1043), and susceptible (RO1157) to Pythium myriotylum were quantified and tested for their in vitro fungitoxicity on the causal agent of the cocoyam root rot disease. All clones, infected or not, have phenolic compounds showing fungitoxic activity. The phenolic content of the tolerant and susceptible clones is less than that observed in the resistant one meanwhile in the resistant clone RO1075, a large increase in phenolic content is observed particularly in the roots during attack by pathogen.     

Phytophthora Root Rot of Pepper Influence of Host Genotype and Pathogen Strain on the Inoculum Density-Disease Severity Relationships

The relationship between inoculum density and mortality or infection was studied for various pepper varieties (Capsicum annuum L.) inoculated with zoospores of two P. capsici isolates. The inoculum concentrations required for 50% mortality (LD 50) varied greatly between pepper varieties and P. capsici isolates: with one isolate, LD 50 was 40 zoospores/ml for a susceptible variety and reached 4,380 to 97,300 zoospores/ml for resistant varieties. For another isolate, LD 50 for the, same varieties ranged from 26 to 800 zoospores/ml. Comparisons between LD 50 and inoculum doses required for 50 % Infection (ID 50) also revealed differences between varieties but not between isolates. After multiple infection correction, regression slopes of infections/inoculum concentration were low for resistant varieties (0.28 to 0.50) but higher for susceptible varieties (0.72 to 0.94), indicating strong competition between spores for infection of resistant plants, but not for infection of susceptible plants. This analysis provided many criteria which can be used to differentiate susceptible from resistant varieties and to evaluate with precision the resistance level of the different resistance genitors used in our breeding program.     

Root Rot and Wilt of Kangaroo Paw (Anigozanthos manglesii) Caused by Pythium myriotylum (Drechs.) in Israel

A root rot and wilt disease of Anigozanthos manglesii (Kangaroo Paw) grown in greenhouses in Israel, for exporting as cut flowers to Europe, was characterized. Pythium myriotylum (Drechs.) and Rhizoctonia solani (Kühn) were the prevalent pathogens in diseased plants collected from commercial greenhouses. Fusarium oxysporum, Fusarium spp. and Myrothecium sp. were also isolated, but P. myriotylum or R. solani were not detected in samples from symptomless plants in tissue cultures (Australian origin) or plants at different stages in the nursery; non‐pathogenic F. oxysporum and Fusarium spp. were detected in several samples. In pathogenicity tests carried out in pots, plant mortality occurred 7 days after inoculation with P. myriotylum. In a field experiment carried out in methyl bromide‐fumigated soil, the incidence of dead plants following inoculation with P. myriotylum alone was 22% 10 days after inoculation, increasing to 78% after an additional 25 days. The incidence of dead plants following inoculation with R. solani alone was only 5% and in plants inoculated simultaneously with both pathogens, disease incidence was 88% 35 days after inoculation. Mortality reached 90–100% in plants inoculated with P. myriotylum, either singly or combined with R. solani 60 days after inoculation, whereas in plants inoculated with R. solani it was 5%. The maximum mortality in plants inoculated with R. solani was 25%, 76 days after inoculation. These results clearly demonstrate that P. myriotylum was the dominant pathogen in the root rot and wilt of A. manglesii.     

Barley Root Morphology Affects the Zoospore Production Rate by the Obligate Root Parasite and Soil-borne Virus Vector Polymyxa graminis

Plasmodiophorid parasites in the genus Polymyxa infect roots by means of zoospores and transmit more than 15 soil-borne viruses in a wide range of arable crops. Barley mutants, selected for variations in root hair formation and morphology, were used to demonstrate that root hairs were important but not essential for infection by zoospores of Polymyxa graminis . The relative rates of parasite establishment in roots were determined indirectly as the relative number of zoospores released by roots inoculated with P. graminis in wild-type and mutant plants. The number of P. graminis zoospores released per gram root fresh weight was significantly reduced in brb and rhl1 . b mutants, both of which have no root hairs. This is an important result because there are no natural sources of resistance to P. graminis. Reducing infection levels of viruliferous P. graminis will slow the build up of virus inoculum in the soil and the selection of strains able to overcome the virus resistance in current cereal cultivars.     

Variation in the sensitivity to metalaxyl of Pythium spp. isolated from carrot and other sources

Over a 3-yr period 261 isolates of 17 species of Pythium were tested for sensitivity to metalaxyl at concentrations of 5, 50 or 100 μ/ml. A wide range of responses was observed, from isolates where growth ceased at 5 μg/ml to those where growth at 100 μg/ml was similar to that of the untreated controls. In further tests isolates of 11 different species had ED50's < 1 μg/ml. A lower sensitivity was detected in isolates of six Pythium spp. where values in the range 1–10 μg/ml were obtained. This lower sensitivity was not related to previous known use of metalaxyl. Three isolates of Pythium dissotocum from sites where the fungicide had been used repeatedly had ED50's > 100 μg/ml and were considered resistant. The resistance was stable over a 2-yr period and isolates were cross-resistant to furalaxyl, benalaxyl, ofurace, cyprofuram and oxadixyl. Increasing concentrations of metalaxyl reduced or prevented the production of zoospores by four species of Pythium, although when zoospores were produced, this was followed by the normal processes of encystment and germination. Culturing P. dissotocum on different sub-lethal concentrations of metalaxyl for 18 wk did not induce a high level of resistance to the fungicide.     

Life Cycle of <Emphasis Type="Italic">Plasmodiophora brassicae</Emphasis>

Plasmodiphora brassicae is a soil-borne obligate parasite. The pathogen has three stages in its life cycle: survival in soil, root hair infection, and cortical infection. Resting spores of P. brassicae have a great ability to survive in soil. These resting spores release primary zoospores. When a zoospore reaches the surface of a root hair, it penetrates through the cell wall. This stage is termed the root hair infection stage. Inside root hairs the pathogen forms primary plasmodia. A number of nuclear divisions occur synchronously in the plasmodia, followed by cleavage into zoosporangia. Later, 4–16 secondary zoospores are formed in each zoosporangium and released into the soil. Secondary zoospores penetrate the cortical tissues of the main roots, a process called cortical infection. Inside invaded roots cells, the pathogen develops into secondary plasmodia which are associated with cellular hypertrophy, followed by gall formation in the tissues. The plasmodia finally develop into a new generation of resting spores, followed by their release back into soil as survival structures. In vitro dual cultures of P. brassicae with hairy root culture and suspension cultures have been developed to provide a way to nondestructively observe the growth of this pathogen within host cells. The development of P. brassicae in the hairy roots was similar to that found in intact plants. The observations of the cortical infection stage suggest that swelling of P. brassicae-infected cells and abnormal cell division of P. brassicae-infected and adjacent cells will induce hypertrophy and that movement of plasmodia by cytoplasmic streaming increases the number of P. brassicae-infected cells during cell division.     

Inoculum Density Relationships for Infection of Some Eastern US Forest Species by Phytophthora ramorum

Our objectives were to establish inoculum density relationships between P. ramorum and selected hosts using detached leaf and whole‐plant inoculations. Young plants and detached leaves of Quercus prinus (Chestnut oak), Q. rubra (Northern red oak), Acer rubrum (red maple), Kalmia latifolia (mountain laurel) and Rhododendron ‘Cunningham's White’ were dip‐inoculated with varying numbers of P. ramorum sporangia, and the total number of diseased and healthy leaves recorded following incubation at 20°C and 100% relative humidity. Calibration threshold estimates for obtaining 50% infected leaves based on linear analysis ranged from 36 to 750 sporangia/ml for the five hosts. Half‐life (LD50) estimates (the number of spores for which the per cent of diseased leaves reaches 50% of its total) from asymptotic regression analysis ranged from 94 to 319 sporangia/ml. Statistically significant differences (P = 0.0076) were observed among hosts in per cent infection in response to increased inoculum density. Inoculum threshold estimates based on studies with detached leaves were comparable to those obtained using whole plants. The results provide estimates of inoculum levels necessary to cause disease on these five P. ramorum hosts and will be useful in disease prediction and for development of pest risk assessments.     

Forecasting infections of the red rot disease on Porphyra yezoensis Ueda (Rhodophyta) cultivation farms

Pythium porphyrae is a fungal pathogen responsible for red rot disease of the seaweed Porphyra (Rhodophyta). Infection forecasts of Porphyra by P. porphyrae were estimated from the epidemiological observations of Porphyra thalli and numbers of zoospore of P. porphyrae in laboratory and cultivation areas. Four features of forecasting infections were determined by relating zoospore concentrations to the incidence of thallus infection; infection (in more than 1000 zoospores L⁻¹), microscopic infection [less than 2 mm in diameter of lesion (in from 2000 to 3000 zoospores L⁻¹)], macroscopic infection [more than 2 mm in diameter of lesion (in from 3000 to 4000 zoospores L⁻¹), and thallus disintegration (in more than 4000 zoospores L⁻¹). High zoospore concentrations led to more infection. The tendency that zoospore concentration of P. porphyrae increased with the rate of infection of Porphyra thalli was generally observed in forecasting infections in both the laboratory and in cultivation areas. Based on the Porphyra cultivation areas, the accuracy and consistency of forecasting infections suggest that this method could be employed to manage and control red rot disease.     

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.     

Survival of inoculum of the leaf blight fungus Phytophthora colocasiae infecting taro, Colocasia esculenta in the Solomon Islands

Phytophthora colocasiae was successfully isolated by baiting with detergent-treated taro leaf discs 8 cm diameter placed on water slurries of soil, on suspensions of macerated infected leaf lesions or on the washings from petioles of harvested plants. Taro root tips, detached or left on corms, were not susceptible to zoospores of P. colocasiae nor were detached root tips of Lupinus angustifolius. Cubes of taro corm used as baits, and agar selective for Phycomycetes which was inoculated directly with soil, both became too heavily overrun by Phythium splendens to allow detection of P. colocasiae. Investigations indicated that inoculum on lesions of detached leaves and in soil remains viable for only a few days. Petiole bases which comprise the bulk of the ‘tops’ used for vegetative propagation, lost detectable natural inoculum rapidly (2 days) if stored dry, but less rapidly (14 days) if planted immediately in the field. Artifically augmenting surface inoculum with naturally produced sporangia considerably extended the periods of detectability, probably by increasing the chances that a few propagules would survive, especially during dry storage. Incubation of inoculated tops in high humidity led to active infection and sporulation on petioles, especially on cut ends, a situation that might be paralleled under suitable moisture conditions in the field. Of several aroid species tested by artificial inoculation only Alocasia macrorrhiza was susceptible. Natural infection of this plant has not been seen, making it an unlikely alternate host of P. colocasiae under field conditions. Thus perennation between taro crops is effected by shortlived surface propagules and possibly also by mycelium within lesions on petioles. Reduction of the former and prevention of the latter might be achieved by dry storage of tops for 2 to 3 wk.     

Microassay for biological and chemical control of infection of tobacco byPhytophthora parasitica var.nicotianae

We developed a simple, rapid, small-scale assay for infection of tobacco seedlings byPhytophthora parasitica var.nicotianae. One 7-day-old tobacco seedling was placed in each well of a 96-well microtiter plate and inoculated with 500 zoospores ofP. parasitica var.nicotianae. After 72 h all of the inoculated seedlings of the susceptible cultivar, KY14, were infected, and the pathogen had produced sporangia that were visible on the surfaces of the seedlings. Sporangia did not develop on seedlings that were inoculated simultaneously with zoospores and either 1 µg/mL of the chemical fungicide metalaxyl or 5 µL of filtrate of a sporulated culture of the biocontrol agent,Bacillus cereus UW85. Seedlings of tobacco cultivar KY17 were infected byP. parasitica var.nicotianae, although mature plants of this variety are resistant to the pathogen. This microassay may facilitate the rapid screening of potential biological and chemical control agents and may be useful for studying mechanisms of infection and control ofPhytophthora spp. under hydroponic conditions.     

Race cultivar-specific differences in callose deposition in soybean roots following infection with Phytophthora megasperma f.sp. glycinea

Primary roots of soybean (Glycine max (L.), Merrill, cv. Harosoy 63) seedlings were inoculated with zoospores from either race 1 (incompatible, host resistant) or race 3 (compatible, host susceptible) of Phytophthora megasperma f.sp. glycinea and total callose was determined at various times after inoculation. From 4 h onward, total callose was significantly higher in roots showing the resistant rather than the susceptible response. Local callose deposition in relation to location of fungal hyphae was determined in microtome sections by its specific fluorescence with sirofluor and was quantified on paper prints with an image-analysis system. Callose deposition, which occurs adjacent to hyphae, was found soon after inoculation (2, 3 and 4 h post inoculation) only in roots displaying the resistant response, and was also higher at 5 and 6 h after inoculation in these resistant roots than in susceptible roots. Early callose deposition in the incompatible root-fungus reaction could be a factor in resistance of soybean against P. megasperma.Abbreviation pi post inoculation     

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.     

拟南芥与大豆疫霉菌的非寄主互作及一个感病突变体的遗传分析

非寄主抗病性是一种普遍的自然现象, 该文通过建立拟南芥-大豆疫霉菌(Arabidopsis thaliana-Phytophthora sojae)非寄主互作系统, 筛选对大豆疫霉菌感病的拟南芥突变体, 为研究植物对卵菌的非寄主抗病性遗传机制奠定基础。以大豆疫霉菌游动孢子接种拟南芥T-DNA插入突变体离体叶片, 从代表12 000个独立转化株系的40 000株T₃代T-DNA插入拟南芥突变体中获得一系列对大豆疫霉菌感病的突变体。其中突变体581-51感病性状表现稳定, 离体叶片接菌后3天内出现明显的水渍状病斑, 4–5天后产生大量卵孢子和/或孢子囊。细胞学观察发现有典型的吸器形成。Southern杂交和遗传分析结果表明, 581-51突变体含有4个T-DNA插入事件, 其感病性状可能由隐性单基因控制。