Arabidopsis thaliana, a new tool to investigate Polymyxa betae-host interactions

Little is known about the genome of Polymyxa betae and its interactions with sugar beet, due partly to the obligate nature of the protist and the patents on Beta vulgaris sequences. The identification of an ecotype of Arabidopsis thaliana compatible with the protist would help to improve this knowledge. The infection and development of P. betae in 14 worldwide ecotypes of A. thaliana were studied. The detection of plasmodia and resting spores and the production of zoospores in the roots of A. thaliana were obtained in three bioassays, using automatic immersion systems and individual glass tubes. Detection was done using molecular detection and microscopy. Compatible interactions were established between 13 A. thaliana ecotypes of the 14 that were tested and the monosporosoric Belgian strain of P. betae, A26-41. The ecotype Cvi-0 (N1096), from the Cape Verde Islands, was the most compatible with the protist. This ecotype is also susceptible to Plasmodiophora brassicae, another plasmodiophorid. Polymyxa betae infection in A. thaliana was relatively very low compared with B. vulgaris, but every stage of the life cycle of the protist was present. The spore-forming phase was promoted at the expense of the sporangial phase, probably caused by the stress of this new environment. In addition, the protist revealed a new phenotype. This new model study will allow molecular tools available for A. thaliana to be used in order to gain a better understanding of the P. betae-plant interaction during the spore-forming phase.     

甜菜多粘菌形态发育过程研究

甜菜多粘菌(Polymyxa betae)是一种专性寄生于甜菜根部的低等真菌,可作为甜菜坏死黄脉病毒(BNYVV)的传播介体并与甜菜丛根病的产生有关。对甜菜多粘菌的研究有助于了解其与所传病毒的生物学关系及其在引致甜菜丛根病中所起的作用。本文观察记录了甜菜多粘菌侵染甜菜根系及其在甜菜根细胞中的发育过程,对甜菜多粘菌各主要发育阶段进行了显微镜观察并发现在其游动孢子中有BNYVV粒体存在。根据观察结果并提出了甜菜多粘菌生活史模式图。     

In vitro dual culture of Polymyxa betae in Agrobacterium rhizogenes transformed sugar beet hairy roots in liquid media

Polymyxa betae is a soil-borne protist and an obligate parasite of sugar beet that transmits the beet necrotic yellow vein virus. Sugar beet hairy roots, transformed by Agrobacterium rhizogenes, were inoculated with surface-sterilized root fragments infected by P. betae. After 10 wk in a liquid medium, typical structures of P. betae were observed in this in vitro system. This first in vitro culture of P. betae in liquid medium will contribute to a better understanding of this protist's biology through providing a way to conserve and produce purified isolates of the protist.     

甜菜多粘菌基因组片段的克隆及PCR检测

根据资料报导设计引物,扩增Ｐｏｌｙｍｙｘａ　ｂｅｔａｅ的基因组片段,将其克隆在ｐＧＥＭ－３Ｚｆ（＋）质粒载体上,并通过双酶切、ＰＣＲ扩增和部分序列测定,证明克隆片段为Ｐ．ｂｅｔａｅ基因组片段。用扩增Ｐ．ｂｅｔａｅ基因组片段的引物对由Ｐ．ｇｒａｍｉｎｉｓ侵染小麦和Ｏ．ｂｒａｓｓｉｃａｅ侵染豇豆根系抽提的总ＤＮＡ进行ＰＣＲ扩增,均未获得任何ＤＮＡ产物,进一步证实了上述结果。对移入病土２、３．５天的甜菜苗单株根系进行ＤＮＡ粗提,移入病土３．５天的甜菜苗ＰＣＲ检测其已被Ｐ．ｂｅｔａｅ侵染,对确定Ｐ．ｂｅｔａｅ的早期侵染有重要意义。     

Evaluation of Polymyxa betae Keskin Contaminated by Beet Necrotic Yellow Vein Virus in Soil

The fungus Polymyxa betae Keskin belongs to the family Plasmodiophoraceae and lives in the soil as an obligatory parasite of the roots of the Chenopodiaceae. When contaminated by beet necrotic yellow vein virus, this viruliferous fungus causes a serious disease of sugar beet known as rhizomania, whereas the infection by the fungus alone (aviruliferous fungus) causes only slight damage to the plant with little economic consequence. The manifestation of rhizomania in sugar beet is directly related to the concentration of infecting units of viruliferous P. betae present in the soil. (One infecting unit is a group of one or more sporosori that liberate zoospores capable of visibly infecting a plant.) By using current methods of analysis, it is possible to estimate the total quantity of P. betae present in the soil, but one cannot distinguish quantitatively the infecting units of aviruliferous from viruliferous P. betae. A new method has been developed based on the technique of the most probable number and enzyme-linked immunosorbent assay to estimate the concentration of infecting units of viruliferous P. betae in soil. The method is suitable for the routine analysis of numerous soil samples and allows one to estimate the concentration of viable forms of the fungus P. betae, whether or not contaminated by beet necrotic yellow vein virus, present in a soil affected by rhizomania or presumed healthy. The analyses performed with this method are economical and use a reagent kit and equipment in wide use.     

Barley mild mosaic virus inside its fungal vector, Polymyxa graminis

In an electron microscope study to investigate the association of barley mild mosaic virus (BaMMV) with its fungal vector, Polymyxa graminis, thin sections were made of zoospores of the vector and of barley roots containing different stages in the life cycle of the fungus. Immunogold labelling was used to identify the virus in sections. Labelled bundles of presumed virus particles were seen in c. 1% of zoospores liberated from plant roots and in zoospores inside zoosporangia. A few zoosporangial plasmodia had localised labelling but no bundles were seen. No virus particles were seen in sections of resting spores.     

Characteristics of Serially Produced Zoospore Suspensions of Polymyxa betae for Transmission of Beet Necrotic Yellow Vein Virus

Zoospore suspensions of Polymyxa betae were analysed for their potential as inocula to infect sugar beet plants with beet necrotic yellow vein furovirus. The infectivity could be maintained when zoospore suspensions were serially transferred. When zoospore-producing seedlings were individually transferred some of these seedlings lost their infectivity after several passages. Infectivity was first detected in suspensions within I day after inoculation of the plant by zoospores. The suspensions remained infectious for at least 10 h after removal of the plants producing viruliferous zoospores. Both the number of test plants infected and the concentration of virus that developed were greater at 25 C than at 20 C.     

Changes in Ribonuclease and Glucose-6-Phosphate Dehydrogenase Activities Induced by Beet Necrotic Yellow Vein Virus in Sugar Beet

Activities of host ribonucleases and glucose-6-phosphate dehydrogenase were studied in three cultivars (Monosvalof, Steffi and Rimini) of sugar beet differing in their resistance to beet necrotic yellow vein virus (BNYVV). No differences were found in the susceptibility of cultivars to BNYVV between mechanically inoculated and Polymyxa betae (a natural fungal vector of the virus) infected plants, but the culmination of reproduction curves of BNYVV in mechanically inoculated plants was observed one week earlier than in plants inoculated by means of P. betae. The activities of ribonucleases corresponded with virus multiplication. In roots, activities of ribonucleases reached a maximum at day 7; in leaves, maximum activity was found at day 21 in cv. Monosvalof, and at day 14 in cv. Steffi. The relatively resistant cultivar Rimini showed much lower activities. The activity of glucose-6-phosphate dehydrogenase was only slightly increased at the time of culmination of the BNYVV reproduction curve in cvs. Monosvalof and Steffi. This revised version was published online in June 2006 with corrections to the Cover Date.     

Life cycle and ultrastructure ofDucellieria chodati (Oomycetes)

Ducellieria chodati forms colourless, evidently plastid-lacking aggregates. For the first time, details of the reproduction cycle are reported: Biflagellate zoospores, released from the aggregates, infest coniferous pollen grains drifting on lake surfaces. The unicellular thallus growing inside the pollen grain develops into a sporangium. 10 to c. 60 spores are discharged, gather at the mouth of the discharge tube, and form new aggregates. After more than 30 cycles, the formation of aggregates ceases in favour of the direct production of zoospores which again infest pollen grains. If several zoospores infest the same grain, a resting spore can be produced, probably by a sexual process. It is evident from this complex life cycle thatDucellieria chodati is misplaced inChlorophyceae orXanthophyceae and needs to be grouped within theOomycetes. Dedicated to Prof. DrLothar Geitler on the occasion of his 90th birthday.     

Some observations on assessing Phoma betae infection of sugar-beet seed

Near-ultraviolet or ‘black’ light applied continuously from the start of incubation, facilitates tests for Phoma betae on sugar-beet seed by stimulating the production of pycnidia and restricting mycelial growth of P. betae and other fungi. Pretreatment of the seed with dilute sodium hypochlorite decreases the number of seeds with P. betae by removing superficial infection, but some of this is of significance in the field. Rubbing beet seed also decreased counts of P. betae in the laboratory and increased field emergence, primarily by removing the fungus. Griseofulvin sprayed on beet-seed plants either 2 wk or 2 days before harvest significantly decreased seed infection with P. betae, but not to a level at which further seed treatment could be omitted.     

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.     

Synchytrium solstitiale: reclassification based on the function and role of resting spores

Studies were made about resting spores of Synchytrium solstitiale, a chytrid that causes false rust disease of yellow starthistle (YST). During evaluation of this fungus for biological control of YST, a protocol for resting spore germination was developed. Details of resting spore germination and study of long-term survival of the fungus were documented. Resting spores from dried leaves germinated after incubating them on water agar at least 7 d at 10-15 C. Resting spores were viable after storage in air-dried leaves more than 2 y at room temperature, suggesting they have a role in off-season and long-term survival of the fungus. Each resting spore produced a single sorus that contained a single sporangium, which on germination released zoospores through a pore. YST inoculated with germinated resting spores developed symptoms typical of false rust disease. All spore forms of S. solstitiale have been found to be functional, and the life cycle of S. solstitiale has been completed under controlled laboratory and greenhouse conditions. Resting spore galls differ from sporangial galls both morphologically and biologically, and in comparison, each sporangial gall cleaves into several sori and each sorus produces 5-25 sporangia that rupture during release of zoospores. For this reason S. solstitiale should be reclassified as diheterogallic sensu Karling (Am J Bot 42:540-545). Because resting spores function as prosori and produce an external sorus, S. solstitiale is best placed in into the subgenus Exosynchytrium.     

Evidence that RNA silencing-mediated resistance to beet necrotic yellow vein virus is less effective in roots than in leaves

In plants, RNA silencing is part of a defense mechanism against virus infection but there is little information as to whether RNA silencing-mediated resistance functions similarly in roots and leaves. We have obtained transgenic Nicotiana benthamiana plants encoding the coat protein readthrough domain open reading frame (54 kDa) of Beet necrotic yellow vein virus (BNYVV), which either showed a highly resistant or a recovery phenotype following foliar rub-inoculation with BNYVV. These phenotypes were associated with an RNA silencing mechanism. Roots of the resistant plants that were immune to foliar rub-inoculation with BNYVV could be infected by viruliferous zoospores of the vector fungus Polymyxa betae, although virus multiplication was greatly limited. In addition, virus titer was reduced in symptomless leaves of the plants showing the recovery phenotype, but it was high in roots of the same plants. Compared with leaves of silenced plants, higher levels of transgene mRNAs and lower levels of transgene-derived small interfering RNAs (siRNAs) accumulated in roots. Similarly, in nontransgenic plants inoculated with BNYVV, accumulation level of viral RNA-derived siRNAs in roots was lower than in leaves. These results indicate that the RNA silencing-mediated resistance to BNYVV is less effective in roots than in leaves.     

In vitro production of zoospores by the mosquito pathogen Lagenidium giganteum (Oomycetes: Lagenidiales) on solid media

Reliable, large-scale production of Lagenidium giganteum zoospores was obtained on solid media. The fungus was grown for 7 days in a liquid medium of wheat germ, hemp seed, yeast extract, and glucose, then placed onto hemp-seed agar. Zoosporogenesis was induced on agar by immersing the fungal cultures into water. Zoospore production began 10 hr postimmersion, peaked at 18 hr, and ceased by 36 hr. A single, 10-cm Petri dish of fungus on hemp-seed agar produced 1.7?3.8 × 10⁷ zoospores during the 26 hr of zoosporogenesis. Optimal zoospore production occurred with 4- to 7-day-old cultures; cultures older than 10 days produced few zoospores. The temperature range for zoosporogenesis was 15–35°C. The extent of zoosporogenesis was directly related to the volume of water used to induce zoospore formation and inversely proportional to agar thickness. Bioassay of zoospores against second instar Culex quinquefasciatus larvae yielded an LD₅₀ of 400 zoospores/ml.     

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.     

Life cycle and mode of infection of Leptolegnia chapmanii (Oomycetes) parasitizing Aedes aegypti

The life cycle and mode of infection of mosquito larvae by Leptolegnia chapmanii (Oomycetes: Saprolegniales) were determined. The life cycle is typical of saprolegniaceous fungi, as the species is dimorphic producing diplanetic biflagellate zoospores. Sexual reproduction is by means of gametangial contact and results in the production of a characteristic papillate oogonium containing a subcentric or eccentric oospore. L. chapmanii is capable of infecting Aedes aegypti larvae both by germination of encysted secondary zoospores on the exterior cuticle and by germination of ingested zoospore cysts in the larval midgut. Once the fungus is established in the host, the disease, a coelomomycosis, is fatal. The encystment pattern of secondary zoospores on the larval cuticle appcars preferential. Scanning electron microscopy indicates that mechanical pressure is not the sole force utilized by the fungus for cuticle penetration.