Pathogenic Variability of Isolates of Pseudocercospora griseola, the Cause of Common Bean Angular Leaf Spot, and its Implications for Resistance Breeding

The pathogenic variability was evaluated of 48 Pseudocercospora griseola isolates collected in the State of Minas Gerais, Brazil. Isolates were inoculated to a set of 12 international differential cultivars in a greenhouse. Ten pathotypes (55-15, 63-7, 63-15, 63-23, 63-25, 63-27, 63-31, 63-47, 63-55 and 63-63) were identified, showing the great pathogenic variability of this fungus in Minas Gerais State. Pathotypes 55-15, 63-15, 63-25 and 63-27 had not previously been reported in the State. Of the 48 isolates, all except pathotype 55-1547 induced a compatible reaction with all cultivars from the Andean group. Isolates were highly pathogenic in both Andean and Mesoamerican cultivars, thus being classified as Mesoamerican pathotypes. Pathotype 63-63 was the most widespread, and overcame the resistance genes present in all differential cultivars.     

Genetic Diversity of Phaeoisariopsis griseola in Kenya as Revealed by AFLP and Group-specific Primers

Genetic diversity of 50 Phaeoisariopsis griseola isolates collected from different agroecological zones in Kenya was studied using group‐specific primers and amplified fragment length polymorphism (AFLP) markers. Group‐specific primers differentiated the isolates into Andean and Mesoamerican groups, corresponding to the two common‐bean gene pools. Significant polymorphisms were observed with all the AFLP primer combinations used, reflecting a wide genetic diversity in the P. griseola population. A total of 207 fingerprints was generated, of which 178 were polymorphic. Cluster analysis of the polymorphic bands also separated the isolates into the two groups defined by group‐specific primers. All the isolates examined were grouped into three virulence populations; Andean, Afro‐Andean and Mesoamerican, and their genetic diversity measured. On average, greater diversity (91%) was detected within populations than between populations (9%). The genetic distance between Andean and Mesoamerican populations was higher (D = 0.0269) than between Andean and Afro‐Andean (D = 0.0095). The wide genetic diversity reported here has significant implications in breeding for resistance to angular leaf spot and should be taken into consideration when screening and deploying resistant bean genotypes.     

Pathotypes of Colletotrichum sublineolum in Response to Sorghum Populations with Different Levels of Genetic Diversity in Sete Lagoas‐MG

Sorghum anthracnose is one of the most important and destructive diseases of sorghum. Genetic resistance has been the most efficient strategy to control the disease, but the high variability of the pathogen population in Brazil has resulted in only modest efficacy. Accordingly, we investigated the variability of Colletotrichum sublineolum in response to sorghum populations with three levels of genetic diversity: pure stand, three‐way hybrids and physical mixtures of three‐way hybrids. Six plots of each treatment were planted in different areas and at different dates. A total of 480 isolates, that is 40 single‐conidium isolates per plot, were collected from the field experiment to characterize the variability of the pathogen in each host population. Isolates were inoculated in a greenhouse on a differential line set composed of eight sorghum inbred lines. Our results reveal that the pathogen populations derived from three‐way combinations had higher pathotype diversity than did those derived from pure stand host populations. More complexly, virulent phenotypes were also developed in genetically diverse stands compared to pure stand host populations. The diversification of the host population limits pathogen adaptation, thus resulting in a significantly higher number of pathotypes. The results of this study will improve the management of sorghum anthracnose in the field by helping sorghum breeders maintain disease resistance.     

Genetic diversity of Puccinia kuehnii,the causal agent of orange rust of sugarcane,from Brazil

The use of resistant genotypes is the preferred method to control orange rust of sugarcane (Saccharum spp) caused by Puccinia kuehnii. This approach has been adopted in Brazil but outbreaks of the disease on previously resistant varieties showed that the efficacy of this method is limited and requires a better understanding of pathogen diversity. Nevertheless, adequate molecular markers for examining pathogen diversity at population level are not available, which limits the success of orange rust control by genetic resistance. Therefore, two independent investigations were conducted to examine genetic diversity of P. kuehnii from São Paulo state, the most important sugarcane growing state of Brazil. First, simple-sequence repeat (SSR) markers were developed in the present work and genotypic diversity of orange rust isolates from different locations investigated. Second, phenotypic diversity was examined by the single-pustule inoculation technique on P. kuehnii isolates retrieved from three susceptible commercial sugarcane cultivars. A total of 96 SSR markers were generated and tested for this species. Subsequently, 29 isolates of P. kuehnii were fingerprinted with nine SSR markers to estimate the genotypic diversity by neighbour-joining and 3D principal coordinates. The 29 isolates of the pathogen clustered into four main groups, which were identified by three SSR markers (NPRL_PK_108a, NPRL_PK_162_spka and NPRL_PK_221_spka). Phenotypic data at 21 days after the single-pustule inoculation showed that P. kuehnii from highly susceptible commercial cultivars harboured a small proportion of variants capable of causing disease on resistant cultivars. A differential reaction was demonstrated for the most virulent variant in a repeated experiment confirming the existence of races within P. kuehnii in Brazil.     

Characterization of Colletotrichum lindemuthianum Isolates from the State of Minas Gerais, Brazil

Anthracnose disease of common bean (Phaseolus vulgaris), caused by Colletotrichum lindemuthianum, is responsible for extensive yield losses worldwide. This pathogen is known to vary greatly in its pathogenicity. Control strategies include chemical control and, mainly, the development of resistant cultivars, taking into account the population structure of C. lindemuthianum. The objective of this study was to investigate the pathogenic and genetic diversity and population structure among C. lindemuthianum isolates collected in Minas Gerais state, Brazil. When these isolates were inoculated on 12 differential cultivars, a total of 10 races were identified within a series of 48 isolates collected in Minas Gerais, Brazil. Races 65, 81 and 73 were the most frequent races and occurred in most of the regions. This study also detected race 337, which had not been reported previously in the literature. Random amplified polymorphic DNA (RAPD) analysis performed on the same 48 isolates revealed great genetic diversity, clustering the series into five groups at a maximum similarity value of 89.6%. There was no clear relationship between the loci sampled by RAPD markers and the pathogenic characterization. Analysis of molecular variance showed that 96.06% of the variability was contained within regions and 3.94% among regions, indicating a high exchange of genetic material among the regions of the State. Most of the variability was detected within races (75.24%). The pathogenicity and RAPD assays corroborated the broad genetic diversity of the pathogen and the results have been useful in breeding for resistance to anthracnose.     

Aggressiveness and diversity of Phytophthora capsici on vegetable crops in Georgia

Phytophthora blight induced by Phytophthora capsici causes significant yield loss in a number of vegetable crops. It is imperative to understand the diversity and aggressiveness of the pathogen to design more efficient disease management programs. A collection of P. capsici strains isolated from different vegetable crops in Georgia, USA, were characterised in this study. Of the 49 isolates tested, 24 were A1 and 25 were A2 mating type, respectively, with both mating types found in the same fields. Variability of the isolates was assessed in terms of their aggressiveness on six pepper genotypes. The isolates differed in their aggressiveness on different pepper cultivars with 10 pathotypes identified. No correlation between aggressiveness of the isolates and their host origin or geographical location of isolation was observed. Randomly amplified polymorphic DNA (RAPD) analysis was used to evaluate genetic variability among P. capsici populations. RAPD analysis using 15 random primers resulted in 133 reproducible bands and cluster analysis separated the isolates into 5 groups. Analysis of molecular variance showed that there was moderate genetic differentiation associated with host origin and geographical location of the isolates. No correlation was found between RAPD groups and pathotypes or mating types. These results indicate that P. capsici populations infecting vegetable crops in Georgia were genetically diverse, which should be taken into account in developing resistant cultivars or other disease management programmes.     

Population Structure of Puccinia recondita in Western Europe During 1995, as Assessed by Variability in Pathogenicity and Molecular Markers

The population structure of Puccinia recondita f. sp. tritici (Prt) in western Europe was examined by assessing variability in pathogenicity and in randomly amplified polymorphic DNA (RAPD) among 61 single uredinial isolates. The isolates were chosen to represent pathotypes detected in a previous survey of pathogenic variability in the fungus in western Europe in 1995. Thirty‐five pathotypes were identified by assessing infection types produced by the 61 isolates on 24 differential lines, each with a single gene for resistance to Prt. In contrast, only 18 RAPD phenotypes were identified by scoring 19 polymorphic RAPD bands generated with eight RAPD primers. When analysed by cluster and bootstrap analyses, the pathogenicity and RAPD results revealed little evidence for robust distinct clusters among the isolates. Multiple isolates of several pathotypes collected from widely separated locations such as Belgium, Germany, France, Italy and Switzerland had the same RAPD phenotype, providing evidence of clonal migration over considerable distances in western Europe. Some variability (one or two band differences) was observed in RAPD phenotype within several pathotypes, indicating the possible occurrence of genetic changes independent of pathogenicity, and/or the independent development of pathotypes with different genetic backgrounds. Two groups of isolates identified in the 1995 survey, differentiated by pathogenicity for genes Lr3a, Lr3bg, Lr3ka and Lr30, were not distinguished by RAPD phenotype, indicating that the groups probably do not constitute separate lineages within the pathogen population. Little correlation was apparent between the polymorphisms observed in pathogenicity and RAPD phenotypes. The similarity in the genetic backgrounds of the isolates, as assessed by RAPD markers, suggest that the observed differences in pathogenicity may have arisen by selection for specific virulences corresponding to genes for resistance in wheat cultivars grown in the region. Three isolates of pathotype 3, restricted in its distribution to southern France during 1995, were distinct from all other isolates in RAPD phenotype. Circumstantial evidence suggests that this pathotype originated from northern Africa, and that it belongs to a group of leaf rust pathogens specialized to durum wheats.     

Genetic Similarity among Isolates of Pyrenophora tritici-repentis, Causal Agent of Tan Spot of Wheat

Tan spot, a foliar disease of wheat, is caused by the fungus Pyrenophora tritici‐repentis. On susceptible wheat cultivars, P. tritici‐repentis induces two distinct symptoms: tan necrosis and extensive chlorosis. Presently isolates of P. tritici‐repentis are classified into 11 races based on their virulence on a set of wheat differential genotypes. In nature, this pathogen reproduces both sexually and asexually, but the extent of genetic variability in the P. tritici‐repentis population of western Canada is unknown. This study was conducted to assess the genetic variability among different isolates of P. tritici‐repentis and to determine if similarities among isolates are correlated with race classification or geographic origin of the isolates. Thirty‐three isolates of P. tritici‐repentis and one isolate each of P. teres f. sp. teres, P. teres f. sp. maculata, P. graminea, Helminthosporium sativum and an uncharacterized isolate were studied with 30 random amplified polymorphic DNA (RAPD) primers. Cluster analysis showed that all isolates had unique banding patterns and that clustering of isolates was independent of their race designation or geographic origin. Analysis of molecular variation (amova ) showed that 96.8% of variability occurred among isolates and among race variability accounted for only 3.2% of the total variability.     

Comparative virulence of Pyrenophora teres f. teres from Syria and Tunisia and screening for resistance sources in barley: implications for breeding

Aims: The aim of this study is to investigate the pathogenic diversity and virulence groups among Pyrenophora teres f. teres isolates, sampled from Syria and Tunisia, and to identify the most effective source of resistance in barley that could be used in breeding programmes to control net blotch in both countries. Methods and Results: One hundred and four isolates of P. teres f. teres were collected from barley in different agroecological zones of Tunisia and Syria. Their virulence was evaluated using 14 barley genotypes as differential hosts. The upgma clustering identified high pathogenic variability; the isolates were clustered onto 20 pathotypes that were sheltered under three virulence groups, with high, intermediate and low disease scores. According to susceptibility/resistance frequencies and mean disease ratings, CI05401 cultivar ranked as the best differential when inoculated with the Syrian isolates. However, CI09214 cultivar was classified as the best effective source of resistance in Tunisia. Conclusions: All P. teres f. teres isolates were differentially pathogenic. CI09214 and CI05401 cultivars were released as the most effective sources of resistance in Syria and Tunisia. Significance and Impact of the Study: National and international barley breeding programmes that seek to develop resistance against P. teres f. teres in barley should strongly benefit from this study. This resistance cannot be achieved without the proper knowledge of the pathogen virulence spectrum and the sources of host resistance.     

Morphological, Pathological and Molecular Variability in Colletotrichum capsici, the Cause of Fruit Rot of Chillies in the Subtropical Region of North-western India

Fruit rot of chillies (Capsicum annuum L.), caused by Colletotrichum capsici under tropical and subtropical conditions, results in qualitative and quantitative yield losses. Based on variation in cultural and morphological traits of C. capsici populations, 37 isolates were categorized into five groups designated, respectively, as Cc‐I, Cc‐II, Cc‐III, Cc‐IV and Cc‐V. In culture, most of the isolates produced cottony, fluffy or suppressed colonies. However, no significant differences were noticed in shape and size of conidia. The reaction of the 37 isolates on an indigenously developed differential set of Capsicum cultivars indicated the existence of different virulences in Himachal Pradesh (HP) chilli populations. Fifteen pathotypes of the pathogen were characterized from various chilli‐growing regions of HP. Pathotype CCP‐1 was most virulent and attacked all the differential cultivars. The genetic relationship between five morphological groups recognized within C. capsici was investigated using random amplified polymorphic DNA (RAPD) analysis. Molecular polymorphism generated by RAPD confirmed the variation in virulences of C. capsici and different isolates were grouped into five clusters. However, four isolates (Cc‐5, Cc‐33, Cc‐29 and Cc‐37) exhibited identical RAPD haplotypes. The pathological and RAPD grouping of isolates suggested no correlation among the test isolates.     

Race Profiling and Molecular Diversity Analysis of Fusarium oxysporum f.sp. ciceris Causing Wilt in Chickpea

Seventy isolates of Fusarium oxysporum f.sp. ciceris (Foc) causing chickpea wilt representing 13 states and four crop cultivation zones of India were analysed for their virulence and genetic diversity. The isolates of the pathogen showed high variability in causing wilt incidence on a new set of differential cultivars of chickpea, namely C104, JG74, CPS1, BG212, WR315, KWR108, GPF2, DCP92‐3, Chaffa and JG62. New differential cultivars for each race were identified, and based on differential responses, the isolates were characterized into eight races of the pathogen. The same set of isolates was used for molecular characterization with four different molecular markers, namely random amplified polymorphic DNA, universal rice primers, simple sequence repeats and intersimple sequence repeats. All the four sets of markers gave 100% polymorphism. Unweighted paired group method with arithmetic average analysis grouped the isolates into eight categories at genetic similarities ranging from 37 to 40%. The molecular groups partially corresponded to the states of origin/chickpea‐growing region of the isolates as well as races of the pathogen characterized in this study. The majority of southern, northern and central Indian populations representing specific races of the pathogen were grouped separately into distinct clusters along with some other isolates, indicating the existence of variability in population predominated by a single race of the pathogen. The present race profiling for the Indian population of the pathogen and its distribution pattern is entirely new. The knowledge generated in this study could be utilized in resistance breeding programme. The existence of more than one race, predominated by a single one, in a chickpea cultivation zone as supported by the present molecular findings is also a new information.     

Characterization of Colletotrichum kahawae Isolates Causing Coffee Berry Disease in Angola

Coffee Berry Disease, caused by Colletotrichum kahawae, is a major limitation for Arabica coffee cultivation in Africa and for which genetic control is only partially effective. As part of the effort to re‐launch coffee cultivation in Angola, our aim was to study the diversity of this pathogen and so contribute to more effective breeding for disease resistance. A collection of 30 C. kahawae isolates showed limited diversity in genetic and colony characters. However, some isolates are distinct, suggesting that breeding for disease resistance in Angola should be dependent on an adequate knowledge of the diversity of local and neighbouring C. kahawae isolates. Analysis of C. kahawae nrDNA nucleotide sequences showed distinct lineages clustering within the broad diversity of C. gloeosporioides, prompting further studies aimed at understanding the origin and pathogenic specialization of C. kahawae.     

Virulence Structure of the Powdery Mildew (Blumeria graminis) Population Occurring on Triticale (x Triticosecale) in Poland

Powdery mildew, caused by Blumeria graminis is an important disease of cereals in many production regions. Until end of the last century triticale had been regarded as a species characterized by high level of resistance for this disease. However, after several years of intensive production on a big area in Poland, Germany and other European countries it start to be susceptible for many pathogens including B. graminis. Because of this, virulence structure of this pathogen population on triticale in Poland was evaluated across 2008–2010. Leaf samples with symptoms of the powdery mildew disease were collected randomly from nineteen localities. As a total, 1402 B. graminis isolates were collected: 23–25 isolates per locality in each year. Standard differential set of 28 genotypes was used: twenty‐one wheat with known resistance genes and seven triticale. Based on the obtained results it was possible to observe significant differences in virulence structure between years and localities. No virulence's against Pm21 (Yangmai5), and Pm3d + 4b (Kadett) were found in any year. All tested isolates were virulent on Moreno and Lamberto cultivars. In a total, 36% of tested isolates possessed 9, 11 or 12 virulence's per genotypes. Twenty five percent of tested isolates were virulent to 5 triticale cultivars. Correlation between pathotypes frequency and sampling region were not found what suggest that local epidemics play the most important role in triticale growing regions in Poland.     

Genetic Diversity of Magnaporthe grisea in China as Revealed by DNA Fingerprint Haplotypes and Pathotypes

We determined DNA fingerprint haplotypes and pathotypes of the rice‐blast fungus Magnaporthe grisea collected from 13 areas in China. This DNA fingerprinting analysis, using rep‐PCR, of 381 haplotypes (482 isolates) from China indicated that the M. grisea populations cannot be delineated into region‐specific groups. Analyses of the number of alleles (na), Nei's gene diversity, unbiased genetic distance, and Shannon's Information index among 13 populations showed that clusters were not related to the geographic distance between populations with the exception of the Ningxia (NX) and Jilin (JL) cluster. Among northern populations, NX and JL were more similar to one another than to other populations. Pathogen populations consisting of 121 isolates from China were grouped into 53 pathotypes on the basis of disease reaction in differential rice lines. Isolates assayed for pathotypes were detected based on disease reactions. No correlation was observed between fingerprint groups and pathotypes of the pathogen. High frequency of virulence was found on the rice line Shin2 (Pi‐k^s and Pi‐sh) followed by PiNo.4 (Pi‐ta² and Pi‐sh) and K1 (Pi‐ta), while it was low on Kanto 51 (Pi‐k + ?), K3 (Pi‐k^h), and Fujisaka (Pi‐i and Pi‐sh). Virulence was rare on Toride 1 (Pi‐z^t and Pi‐sh). Tetep (Pi‐k^h + ?) was predicted to be a highly effective, as none of the isolates infected this line. These blast‐resistant rice lines can be used in resistance breeding for the effective management of rice blast in the respective regions of China.     

Resistance of roses to pathotypes of Diplocarpon rosae

Colonies of Diplocarpon rosae derived from single conidia were isolated on malt extract agar, multiplied (at 23°C) and stored (at ?20°C) on surface‐sterilised leaf discs of a universally susceptible rose, ‘Frensham’. The resistance of 16 species and cultivars of Rosa to different isolates of D. rosae was assessed using surface‐sterilised leaf discs. Four pathotypes of D. rosae were distinguished on the basis of host range. One species and one hybrid were resistant to all pathotypes. Two species and two cultivars were susceptible to all pathotypes. Four species and six cultivars were interpreted as having vertical resistance because they were strongly resistant to some but not all pathotypes. Only species and hybrids of the section Cinnamomeae were resistant to the pathotype identified as CW1 whereas only roses of other origins were resistant to the pathotype DA2.     

Status and Perspectives of Clubroot Resistance Breeding in Crucifer Crops

Clubroot disease is a major threat to crops belonging to the Brassicaceae. It is controlled most effectively by the use of resistant cultivars. Plasmodiophora brassicae, the causal agent, shows a wide variation for pathogenicity, which can be displayed by using differential host sets. Except for Brassica juncea and B. carinata, resistant accessions can be found in all major crops. Most resistance sources are race-specific, despite some race-independent resistant accessions which can be found in B. oleracea. European field isolates from P. brassicae display great variation and show a tendency to overcome different resistance sources from either B. rapa or B. oleracea. At present, resistance genes from stubble turnips (B. rapa) are most effective and most widely used in resistance breeding of different Brassica crops. Resistance to P. brassicae from turnips was introduced into Chinese cabbage, oilseed rape, and B. oleracea. Although most turnips carry more than one resistance gene, the resistant cultivars from other crops received primarily a single, dominant resistance gene having a race-specific effect. Populations of P. brassicae that are compatible against most of the used resistance sources have been present in certain European areas for many decades. Such pathogen populations appeared in Japanese Chinese cabbage crops only a few years after the introduction of resistant cultivars. As the spread of virulent P. brassicae pathotypes seems to be slow, resistant cultivars are still a very effective method of control in many cropping areas. Mapping studies have revealed the presence of several clubroot-resistance genes in the Brassica A and C genomes; most of these genes are showing race specificity. Only in B. oleracea was one broad-spectrum locus detected. Two loci from the A genome confer resistance to more than one pathotype, but not to all isolates. Progress made in the determination of resistance loci should be used to formulate and introduce an improved differential set. Future efforts for breeding P. brassicae resistance will focus on durability by broadening the genetic basis of clubroot resistance by using either natural variation or transgenic strategies.     

Pathogenic divergence of Central European and Australian populations of Blumeria graminis f. sp. hordei

Hosts and pathogens have adapted their response to each other through genetic changes that have arisen during the course of their co‐evolution. In developed countries the longevity of varieties is often short; new varieties frequently possess novel genes with specific resistance to pathogens. The latter must adapt to the resistance genes to maintain pathogenicity. To study this adaptation, 50 Central European and 50 Australian isolates of Blumeria graminis f. sp. hordei (Bgh) were tested on 50 barley differential varieties with different specific resistance genes. All the Central European isolates differed from each other in their virulence combinations and belonged to 50 various pathotypes, whereas Australian isolates comprised 37 pathotypes. None of the pathotypes detected in Central Europe was identical or similar to any of those in Australia. This can be attributed to the much higher number of virulences in Central European isolates that developed over a long period of contact with a range of host varieties containing specific resistance genes. This has led to a gradual divergence of the Australian and the European Bgh populations. In Europe, unlike Australia, new specific resistance genes are still widely used in breeding barley varieties and the divergence of both populations will continue.     

Analysis of Genetic Diversity of Fusarium oxysporum f. sp. phaseoli Isolates, Pathogenic and Non-pathogenic to Common Bean (Phaseolus vulgaris L.)

Twenty isolates of Fusarium oxysporum from Brazil, pathogenic and non‐pathogenic to common bean, were analysed using random amplified polymorphic DNA (RAPDs) to study the genetic diversity. RAPD analysis using 23 oligonucleotides resulted in the amplification of 229 polymorphic and 7 monomorphic DNA fragments ranging from 234 to 2590 bp. High genetic variability was observed among the isolates, with the distances varying between 8% and 76% among pathogenic, 2% and 63% among the non‐pathogenic and 45% and 76% between pathogenic and non‐pathogenic isolates. The analysis of genetic distance data showed that the pathogenic isolates tended to group in one group and the non‐pathogenic in another. The genetic distance values of 30% among the pathogenic isolates in cluster A are compatible with the genetic distance values observed within the physiological races, but the distance values among the pathogenic isolates in clusters B and G are not compatible with the distance values observed within the race. Although our results are preliminary, it was not possible to exclude the existence of more than one race of this fungus in Brazil.     

Genetic Characterization and Pathogenicity of Rhizoctonia solani Associated with Common Bean Web Blight in the Main Bean Growing area of Argentina

Common bean web blight (WB), caused by the fungus Rhizoctonia solani (teleomorph Thanatephorus cucumeris), is among the endemic fungal diseases of major impact in north‐western Argentina (NWA). This study aimed to analyse the genetic and pathogenic diversity of R. solani in Salta, NWA, where 97 isolates were recovered from commercial bean cultivars and wild beans showing WB symptoms in a major bean production area. The isolates were characterized on the basis of specific primers, rDNA‐ITS sequences and morphological characteristics. All the isolates were identified as R. solani AG 2‐2WB, and they exhibited considerable intragroup variation. The phylogenetic tree generated with the ITS sequences confirmed the isolates identification. Aggressiveness of the isolates towards bean seedlings was assessed in the greenhouse. A great variability in virulence was observed among the isolates analysed. On the basis of the disease reaction on foliar tissues, the isolates were grouped into three virulence categories as follows: weakly virulent (30%), moderately virulent (38%) and highly virulent (32%). However, no correlation between virulence and geographical origin was detected. The information generated in this study provides initial data on the population variability of the WB pathogen in north‐western Argentina and represents a valuable contribution to regional breeding programmes aimed to obtain cultivars with durable 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.