Germination of surface-disinfected resting spores ofPlasmodiophora brassicae and their root hair infection in turnip hairy roots

Germination of surface-disinfected resting spores ofPlasmodiophora brassicae and its infection of turnip hairy root hairs were studied. Surface-disinfected resting spores showed higher germination than non-disinfected resting spores. Root hair infection was most frequent in the section of root formed 1 d before inoculation. Root hair infection began 4 d after inoculation, increased up to 6 d, and continued to increase more slowly until 10 to 12 d after inoculation. Growth ofP. brassicae in the root hair of hairy roots was observed serially. Most primary plasmodia differentiated to mature zoosporangia 8–10 d after inoculation. The secondary zoospores were initially released 6 d after inoculation.     

Plasmodiophora brassicae-induced Cell Death and Medium Alkalization in Clubroot-resistant Cultured Roots of Brassica rapa

Plasmodiophora brassicae causes clubroot in the turnip, Brassica rapa L. We used organ cultures of adventitious roots from B. rapa seedlings to investigate the initial response of resistant and susceptible cultivars to P. brassicae infection. Primary plasmodia of P. brassicae were observed in root hairs of both susceptible and resistant cultured roots. On the other hand, secondary plasmodia were able to proliferate only in the susceptible root culture but not in the resistant one. Root cultures from the susceptible cultivar all developed clubroot 4 weeks after treatment with 10⁴, 10⁵ or 10⁶ spores/ml, but roots from the resistant cultivar did not develop clubroot under the same conditions. Cell death, as measured by Evans blue and TTC dye methods, was observed in cultured roots from the resistant cultivar but did not occur in roots from the susceptible cultivar after exposure to P. brassicae spores. Cell death was inhibited almost completely by EGTA and verapamil but not by the calmodulin antagonist W7. These results suggest the involvement of Ca²⁺ in P. brassicae‐induced cell death. Alkalization of the root culture medium of the resistant cultivar was observed 2 days after treatment with P. brassicae spores but was not observed in root culture medium from the susceptible strain. We conclude that our root culture system must be a useful tool for further studies of the molecular mechanism of clubroot resistance.     

Cytology of infection,development and expression of resistance to Plasmodiophora brassicae in canola

The timing and expression of resistance to four isolates of Plasmodiophora brassicae, collected from research sites where pathotypes 2, 3, 5 and 6 (Williams' system) had been dominant when characterised in 2006, were assessed in four new commercial cultivars of canola (Brassica napus) with resistance to clubroot. Each of the resistant cultivars was highly resistant to all four of the isolates, and there was no difference in their response to infection. Root hair infection occurred at high levels, but pathogen development occurred more slowly than in a susceptible cultivar (control). Secondary infection and development in cortical cells was severely inhibited in each of the resistant cultivars; only a few bi‐nucleated plasmodia were observed at 12 days after inoculation (DAI), and plasmodia were rarely observed at 18 and 24 DAI. In contrast, development in the susceptible cultivar had progressed to resting spores by 24 DAI. A dense ring of accumulated reactive oxygen species (ROS) was observed in the endodermis, pericycle and vascular cambium of non‐inoculated controls and inoculated plants of the resistant cultivars. However, the ROS ring disappeared rapidly in infected plants of the susceptible cultivar. Plasmodia invaded the stele of susceptible roots by preferentially colonising the xylem parenchyma cells. Expansion and enlargement of lignified xylem cells was observed by 35 DAI. The absence of any specific points of ROS accumulation or lignification of epidermal or cortical cells in the resistant cultivars indicates that a hypersensitive response is not the main mechanism of resistance in these lines. The uniform response of these resistant cultivars to the four isolates of P. brassicae indicates that the resistance in each cultivar may be conditioned by a gene(s) from a single source that confers broad resistance, because most sources of resistance to P. brassicae are pathotype specific.     

Mechanisms of the biofungicide Serenade (Bacillus subtilis QST713) in suppressing clubroot

Clubroot is a serious threat to canola production in western Canada. The biofungicide Serenade® (Bacillus subtilis QST713) reduced the disease substantially in controlled environment, but showed variable efficacy in field trials. To better understand how this biofungicide works, two of the product components, i.e., B. subtilis and its metabolites (product filtrate), were assessed under controlled conditions for their relative contribution to clubroot control. The information may be used to optimize the product formulation. The bacterium or product filtrate alone was only partially effective against clubroot, reducing disease severity by about 60% relative to untreated controls. In contrast, Serenade controlled the disease by over 90%. This pattern of response was mirrored in quantitative PCR assessment on P. brassicae DNA within canola roots; the lowest and highest amounts of pathogen DNA were found in roots of Serenade treatment (0.02 and 0.01 ng/g) and controls (0.52 and 13.35 ng/g), respectively, at 2 and 3 weeks after treatment. During this period, the amount of DNA changed little in Serenade-treated roots but increased by almost 30-fold in the control. The product filtrate or B. subtilis also reduced the pathogen DNA substantially (0.03–1.16 ng/g). Serenade decreased the germination and viability of P. brassicae resting spores only marginally. It is suggested that biofungicide Serenade controls clubroot largely via suppressing root-hair and cortical infection by P. brassicae zoospores. The bacterial metabolites in the product formulation possibly assist B. subtilis in rhizosphere colonization and clubroot control by minimizing the competition from other soil microbes.     

STUDIES ON THE LIFE CYCLE AND TAXONOMY OF LIGNIERA VERRUCOSA

Miller , Charles E. (A. and M. College of Texas, College Station.) Studies on the life cycle and taxonomy of Ligniera verrucosa. Amer. Jour. Bot. 46(10): 725–729. Illus. 1959.—A study of the roots of Veronica persica Poir. and V. hederaefolia L. plants infected with Sorosphaera veronicae Schroeter revealed intracellular cystosori and zoosporangial sori of Ligniera verrucosa. The zoosporangial phase of this species has been heretofore unknown. The plasmodia of L. verrucosa occur in root hairs, and other epidermal and sub-epidermal cells of the roots. Zoosporangial and cystosoral plasmodia are indistinguishable until cleavage has started. It is thought that plasmodia produced during early infection develop into zoosporangia, while those produced later develop into resting spores. Zoospores discharged from zoosporangia may reinfect host cells developing there into zoosporangial or cystosoral plasmodia. No evidence for any sexual process was observed. The spherical zoosporangia making up a single zoosporangial sorus may be interconnected; a single discharge pore may serve to liberate zoospores from different zoosporangia. In the Plasmodiophorales the classical basis for generic distinction has been the arrangement of the resting spores in the sorus. Ligniera, because of the supposedly uncharacteristic nature of its cystosori, has been suggested as a host-variety of Sorosphaera. A comparative study of the cystosori and zoosporangia of Ligniera and Sorosphaera growing in a single host has led to the conclusion that these genera should be considered distinct.     

Detection and Measurement of <Emphasis Type="Italic">Plasmodiophora brassicae</Emphasis>

Clubroot, caused by Plasmodiophora brassicae, is one of the most important diseases of brassicas. Management of clubroot is difficult, and the best means of avoiding the disease include planting in areas where P. brassicae is not present and using plants and growing media free from pathogen inoculum. As P. brassicae is not culturable, its detection has traditionally relied on plant bioassays, which are time-consuming and require large amounts of glasshouse space. More recently, fluorescence microscopy, serology, and DNA-based methods have all been used to test soil, water, or plant samples for clubroot. The use of fluorescence microscopy to detect and count pathogen spores in the soil requires significant operator skill and is unlikely to serve as the basis for a routine diagnostic test. By contrast, serologic assays are inexpensive and amenable to high-throughput screening but need to be based on monoclonal antibodies because polyclonal antisera cannot be reproduced and are therefore of limited quantity. Several polymerase chain reaction (PCR)-based assays have also been developed; these are highly specific for P. brassicae and have been well-correlated with disease severity. As such, PCR-based diagnostic tests have been adopted to varying extents in Canada and Australia, but wide implementation has been restricted by sample processing costs. Efforts are underway to develop inexpensive serologic on-farm diagnostic kits and to improve quantification of pathogen inoculum levels through real-time PCR. Proper detection and quantification of P. brassicae will likely play an increasingly important role in the development of effective clubroot management strategies.     

Agrobacterium tumefaciens-mediated hairy root production from seedlings of Chinese cabbage

Cruciferous hairy roots are often used for improving drought adaptability, peroxidase production, andin vitro subculturing ofPlasmodiophora brassicae. For metabolic engineering,Agrobacterium tumefaciens-mediated systems have previously been developed for hairy root production in other plant species. Here, we used therolABC gene binary construct inA. tumefaciens strain GV3101 to establish cultures of Chinese cabbage hairy roots. On both solid and liquid media, therolABC hairy root lines exhibited a wild-type hairy root syndrome in terms of their growth and morphology. This demonstrates that those three genes are sufficient to induce high-quality hairy roots in Chinese cabbage. Such a system could be useful for the stable production of secondary metabolites in that species.     

Plasmodiophora brassicae: a review of an emerging pathogen of the Canadian canola (Brassica napus) crop

Plasmodiophora brassicae causes clubroot disease in cruciferous plants, and is an emerging threat to Canadian canola (Brassica napus) production. This review focuses on recent studies into the pathogenic diversity of P. brassicae populations, mechanisms of pathogenesis and resistance, and the development of diagnostic tests for pathogen detection and quantification. TAXONOMY: Plasmodiophora brassicae is a soil-borne, obligate parasite within the class Phytomyxea (plasmodiophorids) of the protist supergroup Rhizaria. DISEASE SYMPTOMS: Clubroot development is characterized by the formation of club-shaped galls on the roots of affected plants. Above-ground symptoms include wilting, stunting, yellowing and premature senescence. DISEASE CYCLE: Plasmodiophora brassicae first infects the root hairs, producing motile zoospores that invade the cortical tissue. Secondary plasmodia form within the root cortex and, by triggering the expression of genes involved in the production of auxins, cytokinins and other plant growth regulators, divert a substantial proportion of plant resources into hypertrophic growth of the root tissues, resulting in the formation of galls. The secondary plasmodia are cleaved into millions of resting spores and the root galls quickly disintegrate, releasing long-lived resting spores into the soil. A serine protease, PRO1, has been shown to trigger resting spore germination. PHYSIOLOGICAL SPECIALIZATION: Physiological specialization occurs in populations of P. brassicae, and various host differential sets, consisting of different collections of Brassica genotypes, are used to distinguish among pathotypes of the parasite. DETECTION AND QUANTIFICATION: As P. brassicae cannot be cultured, bioassays with bait plants were traditionally used to detect the pathogen in the soil. More recent innovations for the detection and quantification of P. brassicae include the use of antibodies, quantitative polymerase chain reaction (qPCR) and qPCR in conjunction with signature fatty acid analysis, all of which are more sensitive than bioassays. RESISTANCE IN CANOLA: Clubroot-resistant canola hybrids, recently introduced into the Canadian market, represent an important new tool for clubroot management in this crop. Genetic resistance must be carefully managed, however, as it has been quickly overcome in other regions. At least three resistance genes and one or two quantitative trait loci are involved in conferring resistance to P. brassicae. Root hair infection still occurs in resistant cultivars, but secondary plasmodia often remain immature and unable to produce resting spores. Fewer cell wall breakages occur in resistant hosts, and spread of the plasmodium through cortical tissue is restricted. More information on the genetics of clubroot resistance in canola is needed to ensure more effective resistance stewardship. USEFUL WEBSITES: http://www.canolacouncil.org/clubroot/resources.aspx, http://tu-dresden.de/die_tu_dresden/fakultaeten/fakultaet_mathematik_und_naturwissenschaften/fachrichtung_biologie/botanik/pflanzenphysiologie/clubroot, http://www.ohio.edu/people/braselto/plasmos/     

<Emphasis Type="Italic">Plasmodiophora brassicae</Emphasis> in its Environment

Plasmodiophora brassicae Wor. is viewed in this article from the standpoint of a highly evolved and successful organism, well fitted for the ecological niche that it occupies. Physical, chemical, and biological components of the soil environment are discussed in relation to their effects on the survival, growth, and reproduction of this microbe. It is evident that P. brassicae is well equipped by virtue of its robust resting spores for survival through many seasonal cycles. Germination is probably triggered as a result of signals initiated by root exudates. The resultant motile zoospore moves rapidly to the root hair surface and penetration and colonization follow. The short period between germination and penetration is one of greatest vulnerability for P. brassicae. In this phase survival is affected at the very least by soil texture and structure; its moisture; pH; calcium, boron, and nitrogen content; and the presence of active microbial antagonists. These factors influence the inoculum potential (sensu Garrett, 1956) and its viability and invasive capacity. There is evidence that these effects may also influence differentially the survival of some physiologic races of P. brassicae. Considering the interaction of P. brassicae with the soil environment from the perspective of its biological fitness is an unusual approach; most authors consider only the opportunities to destroy this organism. The approach adopted here is borne of several decades spent studying P. brassicae and the respect that has been engendered for it as a biological entity. This review stops at the point of penetration, although some of the implications of the environment for successful colonization are included because they form a continuum. Interactions with the molecular and biochemical cellular environment are considered in other sections in this special edition.

MORPHOLOGY AND THERMAL DEATH POINT OF OLPIDIUM BRASSICAE

The morphology of single-sporangial isolates of lettuce, tomato, mustard, and oat Olpidium brassicae (Wor.) Dang. growing in their respective hosts as well as in cowpea were compared in situ and after extraction from the roots. The sporangia, zoospores, and resting spores of all isolates were within the established limits of the species. Single exit tubes or pores predominated which means that these isolates should not be transferred to the genus Pleotrachelus. A satisfactory assay for the presence of resting spores was developed by air-drying of the roots for a week or longer. This treatment killed zoospores and vegetative sporangia, but not resting spores. Factors affecting resting spore formation were investigated unsuccessfully. The thermal death point of zoospores of mustard isolates that did not form resting spores was between 40 and 45 C for 10 min.     

<Emphasis Type="Italic">Agrobacterium rhizogenes</Emphasis>: recent developments and promising applications

Agrobacterium rhizogenes is the etiological agent for hairy-root disease (also known as root-mat disease). This bacterium induces the neoplastic growth of plant cells that differentiate to form “hairy roots.” Morphologically, A. rhizogenes-induced hairy roots are very similar in structure to wild-type roots with a few notable exceptions: Root hairs are longer, more numerous, and root systems are more branched and exhibit an agravitropic phenotype. Hairy roots are induced by the incorporation of a bacterial-derived segment of DNA transferred (T-DNA) into the chromosome of the plant cell. The expression of genes encoded within the T-DNA promotes the development and production of roots at the site of infection on most dicotyledonous plants. A key characteristic of hairy roots is their ability to grow quickly in the absence of exogenous plant growth regulators. As a result, hairy roots are widely used as a transgenic tool for the production of metabolites and for the study of gene function in plants. Researchers have utilized this tool to study root development and root–biotic interactions, to overexpress proteins and secondary metabolites, to detoxify environmental pollutants, and to increase drought tolerance. In this review, we provide an up-to-date overview of the current knowledge of how A. rhizogenes induces root formation, on the new uses for A. rhizogenes in tissue culture and composite plant production (wild-type shoots with transgenic roots), and the recent development of a disarmed version of A. rhizogenes for stable transgenic plant production.     

Role of root hairs in phosphorus depletion from a macrostructured soil

One rape (Brassica napus cv. Wesroona) plant and four cotton (Gossypium hirsutum cv. Sicot 3) plants were grown in plastic cells containing soil labelled with 407 kBq of³³P g⁻¹ soil. After 5–8 days of growth, the³³P depletion zones of all plants were autoradiographed and³³P uptake by plants was measured. The autoradiographs were scanned with a microdensitometer and the optical densities at several places within the³³P depletion zones of roots were obtained. The volume of soil explored by root hairs was estimated from measurements of root diameters and lengths of roots and root hairs. About half of the total³³P depleted by cotion roots came from outside the root hair cylinder whereas most of³³P taken up by rape was from within the root hair cylinder. Plants grown in a macrostructured soil may have roots growing in voids, within aggregates or on the surfaces of aggregates. The results of this study demonstrate that root hairs have a strong influence on the accessibility of phosphorus to roots in such a soil, and thus on the phosphorus nutrition of plants.     

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.     

Metabolism and Plant Hormone Action During Clubroot Disease

Infection of Brassicaceae with the obligate biotrophic pathogen Plasmodiophora brassicae results in the development of root galls (clubroots). During the transformation of a healthy root to a root gall a plethora of changes in primary and secondary metabolism occur. The upper part of an infected plant is retarded in growth due to redirection of assimilates from the shoot to the root. In addition, changes in the levels of plant growth regulators, especially auxins and cytokinins, contribute to the hypertrophy of infected roots. Also, defense reactions are manipulated after inoculation of suitable host plants with P. brassicae. This review summarizes our current knowledge on the changes in these parameters. A model is presented for how primary metabolism and secondary metabolism, including plant hormones, interact to induce clubroot formation.     

The inhibition of infection thread development in the cultivar-specific interaction ofRhizobium and subterranean clover is not caused by a hypersensitive response

Summary The cultivar specific interaction ofTrifolium subterranean cv. Woogenellup andRhizobium leguminosarum bv.trifolii strain ANU 794 was examined to establish the basis for nodulation failure on this cultivar. Infections were initiated by strain ANU 794 on cv. Woogenellup. Root hair curling, the initiation of infection threads, and cortical cell divisions were evident on the tap root and appeared normal after microscopic observation. However, in most cases, the infection threads stayed confined to the root hairs. No evidence was found for a hypersensitive response by the plant. The progress of infections on the tap roots was different from that on the lateral roots. This was confirmed by the differential tap and lateral root nodulation patterns of the mutants derived from strain ANU 794, which show enhanced nodulation on cv. Woogenellup. On the lateral roots, cortical cell divisions progressed further than those on the tap root and formed macroscopically visible swellings, which could be divided into two morphological classes. In some cases infection threads developed into these primordia but successful nodules were not established. The inhibition of infection appeared to be manifested at two levels: first, on the tap roots in the root hairs, where many of the infection threads are contained and secondly, in the primordia induced on the lateral roots, where the infection threads sometimes penetrate further than the root hair cell but stop in the primordial cells. It appears that an essential factor or trigger in the communication between plant and bacteria is missing or altered, resulting in an array of primordia-structures, which cease to develop.Abbreviations bv biovar - cv cultivar - Fix⁺ nitrogen fixing - GUS -glucuronidase - Nod⁺ nodulating - HR hypersensitive response - Km kanamycin - LOSs lipo-oligosaccharides - Sm streptomycin - Sp spectinomycin - X-Gluc 5-bromo-4-chloro-3-indonyl--glucuronic acid     

Coculture of Pachyrhizus erosus (L.) hairy roots with Rhizobium spp.

Summary We have established an in vitro system for the induction and study of nodulation in Pachyrhizus erosus (jicama) via a hairy root-Rhizobium coculture. In vitro-grown P. erosus plantlets were infected with Agrobacterium rhizogenes (ATCC No. 15834) and two hairy root lines were established. Hairy roots were grown in a split-plate system in which compartment I (CI) contained MS medium with nitrogen and different sucrose levels (0–6%), while CII held MS medium without nitrogen and sucrose. Nodule-like structures developed in transformed roots grown in CI with 2–3% surcose, inoculated with Rhizobium sp. and transferred to CII. Nodule-like structures that developed from hairy roots lacked the rigid protective cover observed in nodules from plants grown in soil. Western blot analysis of nodules from hairy roots and untransformed roots (of greenhouse-grown jicama) showed expression of glutamine synthetase leghemoglobin and nodulins. Leghemoglobin was expressed at low levels in hairy root nodules.     

Agrobacterium rhizogenes-mediated transformation of Picrorhiza kurroa Royle ex Benth.: establishment and selection of superior hairy root clone

A protocol for induction and establishment of Agrobacterium rhizogenes-mediated hairy root cultures of Picrorhiza kurroa was developed through optimization of the explant type and the most suitable bacterial strain. The infection of leaf explants with the LBA9402 strain resulted in the emergence of hairy roots at 66.7% relative transformation frequency. Nine independent, opine and TL-positive hairy root clones were studied for their growth and specific glycoside (i.e., kutkoside and picroside I) productivities at different growth phases. Biosynthetic potentials for the commercially desirable active constituents have been expressed by all the tested hairy root clones, although distinct inter-clonal variations could be noted in terms of their quantity. The yield potentials of the 14-P clone, both in terms of biomass as well as individual glycoside contents (i.e., kutkoside and picroside I), superseded that of all other hairy root clones along with the non-transformed, in vitro-grown control roots of P. kurroa. The present communication reports the first successful establishment, maintenance, growth and selection of superior hairy root clone of Picrorhiza kurroa with desired phyto-molecule production potential, which can serve as an effective substitute to its roots and thereby prevent the indiscriminate up-rooting and exploitation of this commercially important, endangered medicinal plant species. CIMAP Publication No.: 2007-28J     

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.