A molecular marker for the specific detection of new pathotype 5‐like strains of Plasmodiophora brassicae in canola

Clubroot of crucifers, caused by Plasmodiophora brassicae, is managed in canola (Brassica napus) by the deployment of resistant cultivars. Recently, however, new strains of P. brassicae have been detected in Alberta, Canada, that can overcome this resistance. Some of these strains are classified as pathotype 5 on the differential system of Williams, but are distinguished by their ability to overcome host resistance. In order to expedite the identification of these new pathotype 5‐like strains, three primer sets were developed based on the 18S‐ITS region of the pathogen. With primers P5XF3 and P5XR3, a 127 bp product was amplified from all new pathotype 5‐like strains following optimized PCR analysis. A TaqMan probe‐based quantitative assay was also developed. These protocols could be used to detect as little as 0.5 pg P. brassicae DNA, and as few as 10⁴ mL^?1 pathogen resting spores; infection of host tissues could be detected as soon as 4 days after inoculation. The PCR and qPCR assays described in this study represent useful tools for the rapid and reliable diagnosis and quantification of new pathotype 5‐like strains of P. brassicae.     

基于根肿菌早期侵染量的白菜抗性分析

为探究不同抗性白菜品种对根肿菌侵染量的影响,通过水培法观测4个白菜品种接种根肿菌后其在寄主根内的发展动态,实时荧光定量PCR检测技术对同期根内含菌量进行分析,并结合温室盆栽试验获得的各品种发病数据进行相关性分析。结果表明,早熟长江5号根肿病的发病率和病情指数分别为82.5%和36.2,华良早五号为66.7%和37.5,CR-春美为68.9%和36.0,可归为感病品种,而CR-英雄为52.5%和16.5,可归为抗病品种;水培法接种观测和PCR定量结果显示,根毛侵染率、皮层侵染数以及根内含菌量均表现为CR-英雄最低,显著低于其它3个品种。根毛侵染率、皮层侵染数、根内含菌量、发病率四者间呈显著相关,其R2最大值变幅为0.84~0.98,且根毛侵染率与根内含菌量、发病率与根内含菌量的最大相关系数均出现在第6天,说明根肿菌早期侵染量直接影响白菜根肿病的发生程度。表明根内早期侵染是根肿菌致病的关键环节,通过水培法观测并结合实时荧光定量PCR检测可以评价品种的抗性,可作为根肿病抗性评价的一种方法。     

Effect of host and non‐host crops on Plasmodiophora brassicae resting spore concentrations and clubroot of canola

Plasmodiophora brassicae, causal agent of clubroot of crucifers, poses a serious threat to Canadian canola production. The effects of fallow (F) periods and bait crops (clubroot‐susceptible canola (B) and perennial ryegrass (R)) on clubroot severity and P. brassicae resting spore populations were evaluated in five sequences: R–B, B–R, R–F, B–F and F–F. Both host and non‐host bait crops reduced clubroot severity in a subsequent crop of a susceptible canola cultivar compared with fallow. Resting spore and P. brassicae DNA concentrations decreased in all treatments, but were lowest for the R–B and B–R bait crop sequences. In addition, two studies were conducted in mini‐plots under field conditions to assess the effect of rotation of susceptible or resistant canola cultivars on clubroot severity and P. brassicae resting spore populations. One study included three crops of susceptible canola compared with a 2‐year break of oat–pea, barley–pea, wheat–wheat or fallow–fallow. The other study assessed three crops of resistant canola, two crops of resistant canola with a 1‐year break, one crop of resistant canola and a 2‐year break, and a 3‐year break with barley followed by a susceptible canola. The rotations that included non‐host crops of barley, pea or oat reduced clubroot severity and resting spore concentrations, and increased yield, compared with continuous cropping of either resistant or susceptible canola. Growing of a susceptible canola cultivar contributed 23–250‐fold greater gall mass compared with resistant cultivars.     

Effects of R gene‐mediated resistance in Brassica napus (oilseed rape) on asexual and sexual sporulation of Pyrenopeziza brassicae (light leaf spot)

The phenotype of the R gene‐mediated resistance derived from oilseed rape (Brassica napus) cv. Imola against the light leaf spot plant pathogen, Pyrenopeziza brassicae, was characterized. Using a doubled haploid B. napus mapping population that segregated for resistance against P. brassicae, development of visual symptoms was characterized and symptomless growth was followed using quantitative PCR and scanning electron microscopy on leaves of resistant/susceptible lines inoculated with suspensions of P. brassicae conidia. Initially, in controlled‐environment experiments, growth of P. brassicae was unaffected; then from 8 days post‐inoculation (dpi) some epidermal cells collapsed (‘black flecking’) in green living tissue of cv. Imola and from 13 to 36 dpi there was no increase in the amount of P. brassicae DNA and no asexual sporulation (acervuli/pustules). By contrast, during this period there was a 300‐fold increase in P. brassicae DNA and extensive asexual sporulation in leaves of the susceptible cv. Apex. However, when leaf tissue senesced, the amount of P. brassicae DNA increased rapidly in the resistant but not in the susceptible cultivar and sexual sporulation (apothecia) was abundant on senescent tissues of both. These results were consistent with observations from both controlled condition and field experiments with lines from the mapping population that segregated for this resistance. Analysis of results of both controlled‐environment and field experiments suggested that the resistance was mediated by a single R gene located on chromosome A1.     

Plasmodiophora brassicae resting spore dynamics in clubroot resistant canola (Brassica napus) cropping systems

The soilborne pathogen Plasmodiophora brassicae, causal agent of clubroot of canola (Brassica napus), is difficult to manage due to the longevity of its resting spores, ability to produce large amounts of inoculum, and the lack of effective fungicides. The cropping of clubroot resistant (CR) canola cultivars is one of the few effective strategies for clubroot management. This study evaluated the impact of the cultivation of CR canola on P. brassicae resting spore concentrations in commercial cropping systems in Alberta, Canada. Soil was sampled pre-seeding and post-harvest at multiple georeferenced locations within 17 P. brassicae-infested fields over periods of up to 4 years in length. Resting spore concentrations were measured by quantitative PCR analysis, with a subset of samples also evaluated in greenhouse bioassays with a susceptible host. The cultivation of CR canola in soil with quantifiable levels of P. brassicae DNA resulted in increased inoculum loads. There was a notable lag in the release of inoculum after harvest, and quantifiable P. brassicae inoculum peaked in the year following cultivation of CR canola. Rotations that included a ≥2-year break from P. brassicae hosts resulted in significant declines in soil resting spore concentrations. A strong positive relationship was found between the bioassays and qPCR-based estimates of soil infestation. Results suggest that CR canola should not be used to reduce soil inoculum loads, and crop rotations in P. brassicae infested fields should include breaks of at least 2 years away from B. napus, otherwise the risk of selecting for virulent pathotypes may increase.     

Reducing the build‐up of Plasmodiophora brassicae inoculum by early management of oilseed rape volunteers

Clubroot of oilseed rape (OSR), caused by Plasmodiophora brassicae, is a disease of increasing economic importance worldwide. Previous studies indicated that OSR volunteers, Brassica crops and weeds play a critical role in the predisposition of the disease. To determine the effect of timing of foliar application of the herbicide glyphosate or mechanical destruction of OSR volunteers in reduction of clubroot severity and resting spore production, a series of studies was conducted under controlled conditions with a susceptible OSR cultivar and an isolate of P. brassicae. Plants were inoculated by injecting a spore suspension beside the root hairs at growth stage 11–12 (BBCH scale) and were terminated at 7 (early) or 21 (late) days post‐inoculation (dpi). Under controlled conditions, the first symptoms on roots were observed as early as 7 dpi. The early application of glyphosate as well as early mechanical destruction resulted in significant (P ≤ 0.05) reduction in the development of clubroot symptoms, root fresh weight and the number of resting spores?g root. Furthermore, the effect of volunteer management on clubroot severity in the succeeding OSR was studied by inoculating plants with the resting spores obtained from treated clubbed roots. Inoculated OSR exhibited root clubs similar to the initial symptoms after 35 dpi. Plants that were inoculated with spore suspension from early treated roots resulted in significant reductions in clubroot incidence and severity. Conversely, plants inoculated with the spore suspension from the late treated roots displayed levels of clubroot similar to the plants inoculated with the spore solutions of positive controls.     

Virulence and inoculum density‐dependent interactions between clubroot resistant canola (Brassica napus) and Plasmodiophora brassicae

To mitigate the impact and dissemination of clubroot in western Canada, canola (Brassica napus) producers have relied on clubroot resistance traits. However, in 2013 and 2014, new strains of the clubroot pathogen, Plasmodiophora brassicae, emerged that are virulent on most clubroot‐resistant (CR) canola genotypes. Novel strains of the pathogen were inoculated onto two susceptible canola cultivars, one resistant line and six CR cultivars. Although all cultivars/lines showed a susceptible response to inoculation with the new strains of P. brassicae, the severity of disease reaction, root hair infection rates and the amount of P. brassicae DNA present in each canola genotype varied depending on the strain. In addition, the effect of inoculum density on disease severity and gall formation was recorded for one of these new strains on a universally susceptible Chinese cabbage cultivar and one susceptible and 10 resistant canola genotypes. Although root galls were observed at an inoculum density of 10³ spores per mL of soil, clear differentiation of susceptible and resistant reactions among canola cultivars/lines was not observed until the inoculum density reached 10⁵ spores mL^?1. At a spore density of 10⁶ spores mL^?1 and above, all cultivars/lines developed susceptible reactions, although there was some differentiation in the degree of reaction. This study shows the potential to develop a unique disease profile for emergent clubroot pathotypes and shows a useful range of spore densities at which to study new P. brassicae strains.     

Potential loss of clubroot resistance genes from donor parent Brassica rapa subsp. rapifera (ECD 04) during doubled haploid production

Clubroot resistance derived from the oilseed rape/canola Brassica napus ‘Mendel’ has been overcome in some fields in Alberta, Canada, by the emergence of ‘new’ strains of the protist Plasmodiophora brassicae. Resistance to the pathogen was assessed in 112 doubled haploid (DH) lines, derived from B. rapa subsp. rapifera (European clubroot differential (ECD) 04). The lines were evaluated against five single‐spore isolates representing the ‘old’ pathotypes 2, 3, 5, 6 and 8, and 15 field populations representing new strains of P. brassicae. The disease severity index (ID%) data revealed that none of the DH lines were resistant or moderately resistant to the new pathotype 5X (field populations L‐G1, L‐G2, L‐G3) and D‐G3, while 3–42% were resistant or moderately resistant to the other 11 new strains. Using the mean ID induced by the old pathotype 3 (approx. 13.5%) as the baseline, clubroot severity increased by 300–600% when inoculated with the new pathotypes. A significant finding of this study was the fact that ECD 04 showed absolute resistance to all of the old and new P. brassicae strains while the B. napus ‘Mendel’, although resistant to all of the old pathotypes, was resistant to only about 50% of the new strains. Similarly, all of the selected clubroot‐resistant commercial canola cultivars evaluated in this study were susceptible to 87% of the new P. brassicae strains. The molecular data revealed that the breakdown of clubroot resistance in Mendel and the canola cultivars was in part due to the non‐inheritance of the Crr1 gene on the A08 chromosome from ECD 04.     

Dissemination of Plasmodiophora brassicae in livestock manure detected by qPCR

The present study was performed to investigate whether Plasmodiophora brassicae can be disseminated by livestock manure. A quantitative PCR (qPCR) assay was developed and used to detect and quantify P. brassicae in manure samples from naturally and artificially infested chickens and pigs. In naturally infested manure, quantifiable levels of infestation were observed in 7 out of the 28 samples, ranging from 10³ to 10⁷ resting spores per g of manure. The vast majority of the resting spores (76–91%) were viable, as determined by a dual fluorescence viability assay. Clubroot symptoms developed on plants inoculated with P. brassicae resting spores isolated from all seven qPCR‐positive samples. Artificially infested manure samples were produced by feeding chickens and pigs on P. brassicae‐contaminated feed. The levels of infestation were 10³ resting spores per g of manure for both chicken and pig manure sampled 24 and 48 h after feeding, respectively. Spore viability was >80% for both samples, and the disease severity indices were both >40 as indicated by bioassay. This showed that resting spores can survive the digestive tracts of chickens and pigs, and retain strong pathogenicity. The findings indicate that manure dissemination is possible for P. brassicae. Farmers should avoid feeding livestock on P. brassicae‐contaminated feed or applying infested manure as fertilizer on land intended for crucifer crops.     

Loop‐mediated isothermal amplification (LAMP) assays for rapid detection of Pyrenopeziza brassicae (light leaf spot of brassicas)

Pyrenopeziza brassicae (anamorph Cylindrosporium concentricum) is an ascomycete fungus that causes light leaf spot (LLS) disease of brassicas. It has recently become the most important pathogen of winter oilseed rape (Brassica napus) crops in the UK. The pathogen is spread by both asexual splash‐dispersed conidia and sexual wind‐dispersed ascospores. Such inoculum can be detected with existing qualitative and quantitative PCR diagnostics, but these require time‐consuming laboratory‐based processing. This study describes two loop‐mediated isothermal amplification (LAMP) assays, targeting internal transcribed spacer (ITS) or β‐tubulin DNA sequences, for fast and specific detection of P. brassicae isolates from a broad geographical range (throughout Europe and Oceania) and multiple brassica host species (B. napus, B. oleracea and B. rapa). Neither assay detected closely related Oculimacula or Rhynchosporium isolates, or other commonly occurring oilseed rape fungal pathogens. Both LAMP assays could consistently detect DNA amounts equivalent to 100 P. brassicae conidia per sample within 30 minutes, although the β‐tubulin assay was more rapid. Reproducible standard curves were obtained using a P. brassicae DNA dilution series (100 ng–10 pg), enabling quantitative estimation of amounts of pathogen DNA in environmental samples. In planta application of the β‐tubulin sequence‐based LAMP assay to individual oilseed rape leaves collected from the field found no statistically significant difference in the amount of pathogen DNA present in parts of leaves either with or without visible LLS symptoms. The P. brassicae LAMP assays described here could have multiple applications, including detection of symptomless host infection and automated real‐time monitoring of pathogen inoculum.     

In‐field distribution of Plasmodiophora brassicae measured using quantitative real‐time PCR

A protocol using real‐time polymerase chain reaction (PCR) for the direct detection and quantification of Plasmodiophora brassicae in soil samples was developed and used on naturally and artificially infested soil samples containing different concentrations of P. brassicae. Species‐specific primers and a TaqMan fluorogenic probe were designed to amplify a small region of P. brassicae ribosomal DNA. Total genomic DNA was extracted and purified from soil samples using commercial kits. The amount of pathogen DNA was quantified using a standard curve generated by including reactions containing different amounts of a plasmid carrying the P. brassicae target sequence. The PCR assay was optimized to give high amplification efficiency and three to four copies of the target DNA sequence were detected. Regression analysis showed that the standard curve was linear over at least six orders of magnitude (R² > 0·99) and that the amplification efficiency was >92%. The detection limit in soil samples corresponded to 500 resting spores g^?1 soil. The intersample reproducibility was similar to, or higher than, that of assays for other pathogens quantified in soil samples. Bait plants were used to validate the real‐time PCR assay. The protocol developed was used to investigate the spatial distribution of P. brassicae DNA in different fields and a significant difference was found between in‐field sampling points. The reproducibility of soil sampling was evaluated and showed no significant differences for samples with low levels of inoculum, whereas at higher levels differences occurred. Indicator kriging was used for mapping the probability of detecting P. brassicae within a 2‐ha area of a field. A threshold level of 5 fg plasmid DNA g^?1 soil, corresponding to approximately 3 × 10³P. brassicae resting spores g^?1 soil, is suggested for growing resistant cultivars. The results provide a robust and reliable technique for predicting the risk of disease development and for assessing the distribution of disease within fields.     

Reduction of Spore Density of Plasmodiophora brassicae in Soil by Decoy Plants

The severity of clubroot (Plasmodiophora brassicae) on Chinese cabbage was reduced by growing plants such as oats, spinach and leafy daikon prior to Chinese cabbage in pot experiments. Resting spore densities of P. brassicae in the soil were 29–62%, depending on the pervious crop, as compared to unplanted control plot after ploughing under the previously cultivated plants. Root hairs of the preceding plants were infected with P. brassicae, but clubbed roots were not formed on these plants. The results indicate that these plants functioned as decoy plants reducing the resting-spore density in soil and thereby suppressing disease severity. Received 21 February 2000/ Accepted in revised form 5 September 2000     

Detection of Plasmodiophora Brassicae By PCR in Naturally Infested Soils

A nested polymerase chain reaction (PCR) method was developed for detection of DNA from Plasmodiophora brassicae in naturally infested field soil samples. The target sequences 389 bp and 507 bp were amplified from Swedish populations of P. brassicae. The protocols described enabled detection of DNA in various soil classes with an inoculum level of P. brassicae corresponding to a disease severity index (DSI) higher than 21 in a greenhouse bioassay. Three sequenced Swedish P. brassicae isolates had identical sequence in the 18S/ITS 1 region, but differed by a few nucleotides from an isolate sequenced in the UK. The results indicate that the primers used are general for P. brassicae, and consequently the nested PCR assay has a potential to be developed as a routine diagnostic test.     

Comparison of techniques for estimation of resting spores of Plasmodiophora brassicae in soil

Clubroot (Plasmodiophora brassicae) is an important disease of canola (Brassica napus) and other brassica crops. Accurate estimation of inoculum load in soil is important for evaluating producer risk in planting a susceptible crop, but also for evaluation of management practices such as crop rotation. This study compared five molecular techniques for estimating P. brassicae resting spores in soil: quantitative polymerase chain reaction (qPCR), competitive positive internal control PCR (CPIC-PCR), propidium monoazide PCR (PMA-PCR), droplet digital PCR (ddPCR) and loop-mediated isothermal DNA amplification (LAMP). For ddPCR and LAMP, calibrations were developed using spiked soil samples. The comparison was carried out using soil samples collected from a long-term rotation study at Normandin, Québec, with replicated plots representing 0-, 1-, 2-, 3-, 5- and 6-year breaks following susceptible canola infested with clubroot. CPIC-PCR and ddPCR provided repeatable estimates of resting spore numbers in soil compared with estimates from qPCR or LAMP alone. CPIC-PCR provided the most robust measurement of spore concentration, especially in the 2 years following a crop of susceptible canola, because it corrected for effects of PCR inhibitors. PMA-PCR demonstrated that a large proportion of the DNA of P. brassicae detected in soil after the susceptible canola crop was derived from spores that were immature or otherwise not viable. Each assay provided a similar pattern of spore concentration in soil, which supported the conclusion of a previous study at this site that resting spore numbers declined rapidly in the first 2 years after a susceptible crop, but much more slowly subsequently.     

Assessment of the impact of resistant and susceptible canola on Plasmodiophora brassicae inoculum potential

The impact on clubroot severity of growing susceptible canola or mixtures of resistant and susceptible canola genotypes was examined. Bioassays revealed greater clubroot severity and incidence, and reduced plant height, where 100% of a susceptible cultivar had been grown. A higher proportion of susceptible plants within a resistant canola crop increased root hair and secondary infections. Regression analysis of root hair infection and the amount of Plasmodiophora brassicae DNA (as determined by quantitative PCR) revealed strong linear relationships between the two parameters. The linear relationships between root hair infection and P. brassicae DNA were stronger for the resistant cultivar than for the susceptible cultivar when regression analysis was conducted by cultivar over the sampling dates. In conclusion, the cropping of a resistant cultivar reduced clubroot severity, while the presence of susceptible volunteer canola increased inoculum potential. Quantitative PCR was a reliable tool for the quantification of root hair infection.     

Susceptibility of hairy root lines of Brassica species to Plasmodiophora brassicae and in an in vitro subculture system

To investigate the susceptibility of hairy root lines of Brassica species to Plasmodiophora brassicae, hairy roots were induced in a number of Brassica species with Agrobacterium rhizogenes. Turnip hairy root was highly susceptible to P. brassicae; infection rates were high and large galls formed. In contrast, the rates of root hair infection and gall formation on intact Brassica plants did not differ significantly from the control. To induce resting spore formation, turnip hairy roots were incubated at 15°, 20°, or 25°C after 3 weeks of incubation at 25°C. The number and fresh mass of the galls per hairy root were higher and formation of resting spores was greatest after a 7-week incubation at 20°C. To subculture P. brassicae using turnip hairy root, turnip hairy roots were reinoculated with resting spores and gall with resting spores then formed on the hairy roots. In this way, P. brassicae using hairy roots could be subcultured in vitro two or three times on three single-spore isolates of P. brassicae. This is the first report of in vitro subculture of P. brassicae using hairy root.     

Effect of susceptible and resistant canola plants on Plasmodiophora brassicae resting spore populations in the soil

Clubroot, caused by Plasmodiophora brassicae, has become a serious threat to canola (Brassica napus) production in western Canada. Experiments were conducted to assess the effect of growing resistant and susceptible canola genotypes on P. brassicae soil resting spore populations under greenhouse, mini‐plot and field conditions. One crop of susceptible canola contributed 1·4 × 10⁸ spores mL^?1 soil in mini‐plot experiments, and 1 × 10¹⁰ spores g^?1 gall under field conditions. Repeated cropping of susceptible canola resulted in greater gall mass compared to resistant canola lines. It also resulted in reduced plant height, increased clubroot severity in susceptible canola, and increased numbers of resting spores in the soil mix.     

Identification of Brassica accessions resistant to ‘old’ and ‘new’ pathotypes of Plasmodiophora brassicae from Canada

Genetic resistance is the main tool used to manage clubroot of canola (Brassica napus) in Canada. However, the emergence of new virulent strains of the clubroot pathogen, Plasmodiophora brassicae, has complicated canola breeding efforts. In this study, 386 Brassica accessions were screened against five single-spore isolates (represented by pathotypes 2F, 3H, 5I, 6M and 8N on the Canadian Clubroot Differential Set) and 17 field isolates (represented by 12 unique pathotypes: 2B, 3A, 3D, 3O, 5C, 5G, 5K, 5L, 5X, 8E, 8J and 8P) of P. brassicae to identify resistance sources effective against these strains. The results showed that one B. rapa accession (CDCNFG-046, mean index of disease (ID) = 3.3%) and two B. nigra accessions (CDCNFG-263, mean ID = 3.1%; and CDCNFG-262, mean ID = 4.7%) possessed excellent resistance to all 22 of the isolates evaluated. Fifty other accessions showed differential clubroot reactions (resistant, moderately resistant or susceptible), including 27 (one B. napus, two B. rapa, four B. oleracea and 20 B. nigra) accessions that were each resistant to 8–21 P. brassicae isolates, but developed mean IDs in the range of 5.3–29.6%. The remaining 23 accessions (two B. napus, one B. rapa, five B. oleracea and 15 B. nigra) were each resistant to 3–13 isolates, but developed mean IDs in the range of 30.3–47.0%. The three accessions that showed absolute resistance and the 50 accessions that showed differential clubroot reactions could be used to breed for resistance to the new P. brassicae strains.     

Spongospora subterranea root infection assessed in two potato cultivars differing in susceptibility to tuber powdery scab

Infection by Spongospora subterranea of roots of two potato (Solanum tuberosum) cultivars, either very resistant or very susceptible to powdery scab on their tubers, was studied in a glasshouse experiment. Plants grown in sand/nutrient solution culture were inoculated with S. subterranea sporosori 2 weeks after planting. Plant parameters, the intensity of zoosporangium infection in roots, numbers of Spongospora root galls and amounts of Spongospora DNA in roots, measured using quantitative PCR (qPCR), were assessed at sequential harvests. Inoculation with S. subterranea reduced water use (56 days after planting) by 26% in the tuber resistant cultivar compared with uninoculated plants, and by 60% in the susceptible cultivar. Inoculation did not affect growth of the resistant cultivar, nor shoot mass of the susceptible cultivar, but caused a 38% reduction in root mass of the susceptible cultivar. The intensities of zoosporangium development in both cultivars were similar. The susceptible cultivar had approximately four times more Spongospora root galls g^?1 root mass than the resistant cultivar. Quantitative PCR detected S. subterranea DNA in roots 1 week after inoculation, and indicated a twofold greater amount of pathogen DNA in roots of the susceptible than the resistant cultivar. This study suggests that the S. subterranea zoosporangium stage in host roots is affected differently by host resistance factors than the sporosorus (root gall and tuber scab) stages. The study has also demonstrated the usefulness of qPCR for sensitive and consistent detection of S. subterranea across the duration of potato root infection.     

Histological methods to detect the clubroot pathogen Plasmodiophora brassicae during its complex life cycle

The clubroot pathogen Plasmodiophora brassicae is an obligate biotrophic protist that lives in close relationship with its host cell. The roots of the host plants are colonized and the plant growth is altered upon infection. While shoots can be stunted and show wilt symptoms after longer infection periods, the root system is converted to a tumorous root tissue, called ‘clubroot’, by alterations of the plant growth promoting hormones auxin, cytokinin and brassinosteroid. Because the life cycle occurs largely within the host cells, this leads to dramatic changes in host root morphology and anatomy. Thus, the identification of the respective protist structures in the host tissue by microscopy is challenging. Different staining methods as well as fluorescence and electron microscopy of thin sections can reveal specific life stages of P. brassicae and can yield additional information on the changes in the host tissues concerning, for example, cell wall properties. In addition, promoter–reporter fusions, immunostaining methods and in situ hybridization techniques can be used to gain additional information on the changes in the host roots.