A set of near-isogenic lines of Indica-type rice variety CO 39 as differential varieties for blast resistance

Twenty-seven near-isogenic lines (NILs) with the genetic background of a blast-susceptible variety, CO 39, were developed by repeated backcrossing as a first set of a large number of differential varieties (DVs) with Indica-type genetic background. The NILs included 14 resistance genes—Pish, Pib, Piz-5, Piz-t, Pi5(t), Pik-s, Pik, Pik-h, Pik-m, Pik-p, Pi1, Pi7(t), Pita, and Pita-2—derived from 26 donor varieties. The reaction patterns of NILs against 20 standard isolates from the Philippines were similar to those of blast monogenic lines with the same resistance gene, except for those against two isolates that are avirulent to Pia in the genetic background of CO 39. A genome-wide DNA marker survey revealed that chromosome segments were introgressed in the regions where each resistance gene was previously mapped and most of the other chromosome regions in each NIL were CO 39 type. Segregation analysis of resistance and co-segregation analysis between resistance and DNA markers using F3 populations derived from the crosses between each NIL and the recurrent parent, CO 39, revealed a single-gene control of resistance and association between resistance and target introgressed segments. The morphological characters of each NIL were almost the same as those of the recurrent parent except for some lines, suggesting that these NILs can be used even under tropical conditions where Japonica-type DVs are not suitable for cropping. Thus, these NILs are useful not only as genetic tools for blast resistance study but also as sources of genes for breeding of Indica-type rice varieties.     

Conventional Breeding and Molecular Markers for Blast Disease Resistance in Rice (<i>Oryza sativa</i> L.)

Monogenic lines, which carried 23 genes for blast resistance were tested and used donors to transfer resistance genes by crossing method. The results under blast nursery revealed that 9 genes from 23 genes were susceptible to highly susceptible under the three locations (Sakha, Gemmeza, and Zarzoura in Egypt); Pia, Pik, Pik-p, Piz-t, Pita, Pi b, Pi, Pi 19 and Pi 20. While, the genes Pii, Pik-s, Pik-h, Pi z, Piz-5, Pi sh, Pi 3, Pi 1, Pi 5, Pi 7, Pi 9, Pi 12, Pikm and Pita-2 were highly resistant at the same locations. Clustering analysis confirmed the results, which divided into two groups; the first one included all the susceptible genes, while the second one included the resistance genes. In the greenhouse test, the reaction pattern of five races produced 100% resistance under artificial inoculation with eight genes showing complete resistance to all isolates. The completely resistant genes: Pii, Pik-s, Piz, Piz-5 (=bi2) (t), Pita (=Pi4) (t), Pita, Pi b and Pi1 as well as clustering analysis confirmed the results. In the F₁ crosses, the results showed all the 25 crosses were resistant for leaf blast disease under field conditions. While, the results in F₂ population showed seven crosses with segregation ratio of 15 (R):1 (S), two cross gave segregated ratio of 3 R:1 S and one gave 13:3. For the identi- fication of blast resistance genes in the parental lines, the marker K3959, linked to Pik-s gene and the variety IRBLKS-F5 carry this gene, which was from the monogenic line. The results showed that four genotypes; Sakha 105, Sakha 103, Sakha 106 and IRBLKS-F5 were carrying Pik-s gene, while was absent in the Sakha 101, Sakha 104, IRBL5-M, IRBL9-W, IRBLTACP1 and IRBL9-W(R) genotypes. As for Pi 5 gene, the results showed that it was present in Sakha 103 and Sakha 104 varieties and absent in the rest of the genotypes. In addition, Pita-Pita- 2 gene was found in the three Egyptian genotypes (Sakha 105, Sakha 101 and Sakha 104) plus IRBLTACP1 monogenetic. In F2 generation, six populations were used to study the inheritance of blast resistance and specific primers to confirm the ratio and identify the resistance genes. However, the ratios in molecular markers were the same of the ratio under field evaluation in the most population studies. These findings would facilitate in breeding programs for gene pyramiding and gene accumulation to produce durable resistance for blast using those genotypes.     

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.     

Identification of Two Blast Resistance Genes in a Rice Variety, Digu

Blast, caused by Magnaporthe grisea is one of most serious diseases of rice worldwide. A Chinese local rice variety, Digu, with durable blast resistance, is one of the important resources for rice breeding for resistance to blast (M. grisea) in China. The objectives of the current study were to assess the identity of the resistance genes in Digu and to determine the chromosomal location by molecular marker tagging. Two susceptible varieties to blast, Lijiangxintuanheigu (LTH) and Jiangnanxiangnuo (JNXN), a number of different varieties, each containing one blast resistance gene, Pik^s, Pia, Pik, Pi‐b, Pi‐k^p, Pi‐ta², Pi‐ta, Pi‐z, Pi‐i, Pi‐k^m, Pi‐z^t, Pi‐t and Pi‐11, and the progeny populations from the crosses between Digu and each of these varieties were analysed with Chinese blast isolates. We found that the resistance of Digu to each of the two Chinese blast isolates, ZB13 and ZB15, were controlled by two single dominant genes, separately. The two genes are different from the known blast resistance genes and, therefore, designated as Pi‐d(t)1 and Pi‐d(t)2. By using bulked segregation method and molecular marker analysis in corresponding F₂ populations, Pi‐d(t)1 was located on chromosome 2 with a distance of 1.2 and 10.6 cM to restriction fragment length polymorphism (RFLP) markers G1314A and G45, respectively. And Pi‐d(t)2 was located on chromosome 6 with a distance of 3.2 and 3.4 cM to simple sequence repeat markers RM527 and RM3, respectively. We also developed a novel strategy of resistance gene analogue (RGA) assay with uneven polymerase chain reaction (PCR) to further tag the two genes and successfully identified two RGA markers, SPO01 and SPO03, which were co‐segregated toPi‐d(t)1 and Pi‐d(t)2, respectively, in their corresponding F₂ populations. These results provide essential information for further utilization of the Digu's blast resistance genes in rice disease resistance breeding and positional cloning of these genes.     

A novel gene, <Emphasis Type="Italic">Pi40(t)</Emphasis>, linked to the DNA markers derived from NBS-LRR motifs confers broad spectrum of blast resistance in rice

Rice blast disease caused by Magnaporthe grisea is a continuous threat to stable rice production worldwide. In a modernized agricultural system, the development of varieties with broad-spectrum and durable resistance to blast disease is essential for increased rice production and sustainability. In this study, a new gene is identified in the introgression line IR65482-4-136-2-2 that has inherited the resistance gene from an EE genome wild Oryza species, O. australiensis (Acc. 100882). Genetic and molecular analysis localized a major resistance gene, Pi40(t), on the short arm of chromosome 6, where four blast resistance genes (Piz, Piz-5, Piz-t, and Pi9) were also identified, flanked by the markers S2539 and RM3330. Through e-Landing, 14 BAC/PAC clones within the 1.81-Mb equivalent virtual contig were identified on Rice Pseudomolecule3. Highly stringent primer sets designed for 6 NBS-LRR motifs located within PAC clone P0649C11 facilitated high-resolution mapping of the new resistance gene, Pi40(t). Following association analysis and detailed haplotyping approaches, a DNA marker, 9871.T7E2b, was identified to be linked to the Pi40(t) gene at the 70 Kb chromosomal region, and differentiated the Pi40(t) gene from the LTH monogenic differential lines possessing genes Piz, Piz-5, Piz-t, and Pi-9. Pi40(t) was validated using the most virulent isolates of Korea as well as the Philippines, suggesting a broad spectrum for the resistance gene. Marker-assisted selection (MAS) and pathotyping of BC progenies having two japonica cultivar genetic backgrounds further supported the potential of the resistance gene in rice breeding. Our study based on new gene identification strategies provides insight into novel genetic resources for blast resistance as well as future studies on cloning and functional analysis of a blast resistance gene useful for rice improvement.     

Polymorphism analysis of genomic regions associated with broad-spectrum effective blast resistance genes for marker development in rice

Cultivated European rice germplasm is generally characterized by moderate to high sensitivity to blast, and blast resistance is therefore one of the most important traits to improve in rice breeding. We collected a panel of 25 rice genotypes containing 13 broad range rice resistance genes that are commonly used in breeding programs around the world: Pi1, Pi2, Pi5, Pi7, Pi9, Pi33, Pib, Pik, Pik-p, Pita, Pita ² , Piz and Piz-t. The efficiency of the selected Pi genes towards Italian blast pathotypes was tested via artificial inoculation and under natural field infection conditions. To characterize haplotypes present in the chromosomal regions of the blast resistance genes, a polymorphism search was conducted in the sequence regions adjacent to the blast resistance by examining DNA from the Pi gene donors with a panel of 5–7 potential receivers (cultivated European rice genotypes). Seven InDel and 8 presence/absence polymorphisms were directly detected by gel analysis after DNA amplification, while sequencing of 12.870 bp through 32 loci in different genotypes revealed 85 SNP (one SNP every 151 bp). Seven SSRs were additionally tested revealing 5 polymorphic markers between donors and receivers. Polymorphisms were used to develop 35 PCR-based molecular markers suitable for introgressing of Pi genes into a set of the European rice germplasm. For this last purpose, allelic molecular marker variation was evaluated within a representative collection of about 95 rice genotypes. Polymorphic combinations allowing introgression of the broad spectrum resistance genes into a susceptible genetic background have been identified, thus confirming the potential of the identified markers for molecular-assisted breeding.     

Identification and fine mapping of a resistance gene to <Emphasis Type="Italic">Magnaporthe oryzae</Emphasis> in a space-induced rice mutant

Finding novel sources of resistance (R) to rice blast disease should facilitate breeding for improved resistance. The objectives of the present study were to evaluate reactions to blast and identify in a space-induced mutant an R gene to a representative isolate of rice blast pathogen. The mutant H4, its parent and twelve monogenic lines were evaluated for their responses to 35 isolates collected from Guangdong Province, China. H4 was found to be resistant to more isolates than its parent and the twelve monogenic lines, suggesting newly acquired resistance may be a function of one or more R genes. A representative isolate GD0193 was used to identify and map the R gene from H4. Genetic analysis revealed that resistance to the isolate GD0193 was controlled by a single dominant gene, designated Pi46(t). Linkage analysis using susceptible F2 individuals showed that Pi46(t) was mapped between the markers RM224 and RM27360 within 1.04 and 1.2 cM on the long arm of chromosome 11. Subsequently, Pi46(t) was delimited to an interval of approximately 183.7 kb flanked by the markers K67 and T94. These results provide essential information for the cloning of the Pi46(t) gene and will facilitate marker-assisted selection in rice breeding.     

Evaluation of North American isolates of Soybean mosaic virus for gain of virulence on Rsv‐genotype soybeans with special emphasis on resistance‐breaking determinants on Rsv4

Resistance to Soybean mosaic virus (SMV) in soybean is conferred by three dominant genes: Rsv1, Rsv3 and Rsv4. Over the years, scientists in the USA have utilized a set of standard pathotypes, SMV‐G1 to SMV‐G7, to study interaction with Rsv‐genotype soybeans. However, these pathotypes were isolated from a collection of imported soybean germplasm over 30 years ago. In this study, 35 SMV field isolates collected in recent years from 11 states were evaluated for gain of virulence on soybean genotypes containing individual Rsv genes. All isolates were avirulent on L78‐379 (Rsv1), whereas 19 were virulent on L29 (Rsv3). On PI88788 (Rsv4), 14 of 15 isolates tested were virulent; however, only one was capable of systemically infecting all of the inoculated V94‐5152 (Rsv4). Nevertheless, virulent variants from 11 other field isolates were rapidly selected on initial inoculation onto V94‐5152 (Rsv4). The P3 cistrons of the original isolates and their variants on Rsv4‐genotype soybeans were sequenced. Analysis showed that virulence on PI88788 (Rsv4) was not associated, in general, with selection of any new amino acid, whereas Q1033K and G1054R substitutions were consistently selected on V94‐5152 (Rsv4). The role of Q1033K and G1054R substitutions, individually or in combination, in virulence on V94‐5152 (Rsv4) was confirmed on reconstruction in the P3 cistron of avirulent SMV‐N, followed by biolistic inoculation. Collectively, our data demonstrate that SMV has evolved virulence towards Rsv3 and Rsv4, but not Rsv1, in the USA. Furthermore, they confirm that SMV virulence determinants on V94‐5152 (Rsv4) reside on P3.     

Arms race co‐evolution of Magnaporthe oryzae AVR‐Pik and rice Pik genes driven by their physical interactions

Attack and counter‐attack impose strong reciprocal selection on pathogens and hosts, leading to development of arms race evolutionary dynamics. Here we show that Magnaporthe oryzae avirulence gene AVR‐Pik and the cognate rice resistance (R) gene Pik are highly variable, with multiple alleles in which DNA replacements cause amino acid changes. There is tight recognition specificity of the AVR‐Pik alleles by the various Pik alleles. We found that AVR‐Pik physically binds the N‐terminal coiled‐coil domain of Pik in a yeast two‐hybrid assay as well as in an in planta co‐immunoprecipitation assay. This binding specificity correlates with the recognition specificity between AVR and R genes. We propose that AVR‐Pik and Pik are locked into arms race co‐evolution driven by their direct physical interactions.     

Identification of SSR markers for a broad-spectrum blast resistance gene Pi20(t) for marker-assisted breeding

The Pi20(t) gene was determined to confer a broad-spectrum resistance against diverse blast pathotypes (races) in China based on inoculation experiments utilizing 160 Chinese Magnaporthe oryzae (formerly Magnaporthe grisea) isolates, among which isolate 98095 can specifically differentiate the Pi20(t) gene present in cv. IR24. Two flanking and three co-segregating simple sequence repeat (SSR) markers for Pi20(t), located near the centromere region of chromosome 12, were identified using 526 extremely susceptible F₂ plants derived from a cross of Asominori, an extremely susceptible cultivar, with resistant cultivar IR24. The SSR OSR32 was mapped at a distance of 0.2 cM from Pi20(t), and the SSR RM28050 was mapped to the other side of Pi20(t) at a distance of 0.4 cM. The other three SSR markers, RM1337, RM5364 and RM7102, co-segregated with Pi20(t). RM1337 and RM5364 were found to be reliable markers of resistance conditioned by Pi20(t) in a wide range of elite rice germplasm in China. As such, they are useful tags in marker-assisted rice breeding programs aimed at incorporating Pi20(t) into advanced rice breeding lines and, ultimately, at obtaining a durable and broad spectrum of resistance to M. oryaze. Wei Li and Cailin Lei contributed equally to this work.     

Characterization of the rice blast resistance gene Pik cloned from Kanto51

To study similar, but distinct, plant disease resistance (R) specificities exhibited by allelic genes at the rice blast resistance locus Pik/Pikm, we cloned the Pik gene from rice cultivar Kanto51 and compared its molecular features with those of Pikm and of another Pik gene cloned from cv. Kusabue. Like Pikm, Pik is composed of two adjacent NBS-LRR (nucleotide-binding site, leucine-rich repeat) genes: the first gene, Pik1-KA, and the second gene, Pik2-KA. Pik from Kanto51 and Pik from Kusabue were not identical; although the predicted protein sequences of the second genes were identical, the sequences differed by three amino acids within the NBS domain of the first genes. The Pik proteins from Kanto51 and Kusabue differed from Pikm in eight and seven amino acids, respectively. Most of these substituted amino acids were within the coiled-coil (CC) and NBS domains encoded by the first gene. Of these substitutions, all within the CC domain were conserved between the two Pik proteins, whereas all within the NBS domain differed between them. Comparison of the two Pik proteins and Pikm suggests the importance of the CC domain in determining the resistance specificities of Pik and Pikm. This feature contrasts with that of most allelic or homologous NBS-LRR genes characterized to date, in which the major specificity determinant is believed to lie in the highly diverged LRR domain. In addition, our study revealed high evolutionary flexibility in the genome at the Pik locus, which may be relevant to the generation of new R specificities at this locus.     

Use of high resolution melting analysis to genotype the avirulence AvrLm4‐7 gene of Leptosphaeria maculans,a fungal pathogen of Brassica napus

The oilseed rape (Brassica napus) stem canker disease, due to the fungal pathogen Leptosphaeria maculans, is mainly controlled by host genetic resistance. Since 2004, the specific resistance gene Rlm7 is widely used in France. Specific resistance is effective when fungal populations are mainly composed of avirulent isolates. The development of molecular tools for the identification of virulent isolates towards Rlm7 was needed to undertake large‐scale surveys and to monitor the emergence of virulent populations in fields. Previous studies have described a large diversity of molecular events leading to virulence towards Rlm7, rendering conventional polymerase chain reaction (PCR) methods inapplicable to identify virulent isolates. Interestingly, a very limited nucleotide polymorphism was observed for avirulent, AvrLm7, alleles. Such characteristics were exploited here to develop a diagnostic method based on high resolution melting (HRM) analysis of the AvrLm4‐7 gene. High resolution melting analysis of a collection of 206 reference isolates revealed only four different profiles within 100 avirulent isolates and 87% of virulent isolates showed either no amplification or HRM curves distinct from those of avirulent isolates. The reliability of the method was confirmed using a second set of 119 unknown isolates, for which biological phenotyping and HRM genotyping were in agreement for 93% of the isolates. HRM combined with the PCR amplification of a larger fragment encompassing AvrLm4‐7 led to a correct diagnostic for 97.5% of the isolates.     

Identification and fine mapping of a major R gene to Magnaporthe oryzae in a broad-spectrum resistant germplasm in rice

Identification of R genes and development of associated molecular markers will facilitate their application in the development of crop cultivars resistant to disease. We evaluated the resistance of a resistant germplasm ??D69??, 10 monogenic lines, and model cultivar ??Nipponbare?? to 56 M. oryzae isolates of blast disease in rice. The results demonstrated that only D69 exhibited full-spectrum resistance among the 12 investigated materials. Resistance inheritance in D69 was analyzed using a stable isolate GD08T13 with strong pathogenicity, collected from diseased panicles. A single dominant R gene was revealed and designated as Pi51(t). Through linkage analysis and the development of new markers, Pi51(t) was subsequently delimited to an interval of ~100.8?kb flanked by markers Ind306 and RM19818, where Pi2, Pi9, Piz, Piz-t, Pigm(t), and Pi40(t) reside. Different genotypes identified by linked markers pB8, Pi9-2, zt56591, and T845, and different pathotypes to the same set of isolates, distinguished Pi51(t) from Pi2, Pi9, Piz, and Piz-t. The origin of Pi40(t) in wild rice suggests that Pi51(t) and Pi40(t) are different. Comparison of resistance spectra suggests multiple R genes in D69, making its resistance durable and valuable in breeding programs. The results of this work will facilitate future studies on cloning and functional analysis of blast resistance genes for rice improvement.     

Detection of novel blast resistance genes, Pi58(t) and Pi59(t), in a Myanmar rice landrace based on a standard differential system

The use of broad-spectrum R genes is an effective way to achieve durable resistance against rice blast (Magnaporthe oryzae Couch, anamorph: Pyricularia oryzae Cavara) in rice (Oryza sativa L.). We previously surveyed the diversity of blast resistance in 948 rice varieties and found a Myanmar rice landrace, Haoru (International Rice Research Institute genebank acc. no. IRGC33090), with broad-spectrum resistance against the standard differential blast isolates. Here, we examined the genetic basis of Haoru’s broad-spectrum resistance by using the standard blast differential system consisting of the standard isolates and differential varieties. For genetic analysis, we used a BC1F1 population and BC1F2 lines derived from crosses of Haoru with a susceptible variety, US-2. Co-segregation analysis of the reaction pattern in the BC1F1 population against the 20 standard isolates suggested that Haoru harbors three R genes. By using bulk-segregant and linkage analysis, we mapped two of the three R genes on chromosomes 12 and 6, and designated them as Pi58(t) and Pi59(t), respectively. Pi58(t) and Pi59(t) were differentiated from other reported R genes using the standard differential system. The estimated resistance spectrum of Pi58(t) corresponded with that of Haoru, suggesting that Pi58(t) is primarily responsible for Haoru’s broad-spectrum resistance. In addition, Pi59(t) and the third gene were also proven to be new and useful genetic resources for studying and improving blast resistance in rice.     

Fine mapping and identification of tightly linked DNA markers of blast resistance gene <Emphasis Type="Italic">Pia</Emphasis> by using an introgression line

An introgression line (INL) for a major rice blast resistance gene, Pia, was developed, with the genetic background of a blast susceptible variety, US-2. The reaction pattern of the INL was characterized by using 20 standard blast isolates from the Philippines. The introgression of the Pia gene was confirmed by DNA markers on the short arm of chromosome 11 where Pia was previously mapped. A genome-wide DNA marker survey revealed that most of the chromosomal regions were US-2 type. By using an F2 population derived from a cross between the INL and US-2, the chromosomal location of the Pia locus was mapped between RM26281 and RM3701. For fine mapping of the Pia locus, five additional markers were developed based on the genomic sequence of the corresponding region of a japonica-type variety, Nipponbare. The candidate region of Pia was delimited between two DNA markers, RM26281 and 82N19365, corresponding to a 140 kb region on the Nipponbare genome sequence. We obtained three DNA markers within this region. The developed INL, information on the map position of Pia, and DNA markers developed in the candidate region of the Pia locus are useful tools for blast resistance studies and a marker-aided breeding strategy.     

Relationship Between Ralstonia solanacearum Diversity and Severity of Bacterial Wilt Disease in Tomato Fields in China

A field survey was conducted to determine the relationship between Ralstonia solanacearum diversity and severity of bacterial wilt disease in tomato plants grown in plastic greenhouses. Both vegetative and reproductive stages of the plants were surveyed, and the symptoms were empirically categorized into five scales: 0 (asymptomatic): 1st, 2nd, 3rd and 4th. The bacterial wilt pathogen was isolated from infected plants at each disease scale; pathogenic characteristics and population densities of the bacterial strains were assessed. Two hundred and eighty‐two isolates were identified as R. solanacearum, which were divided into three pathogenic types, virulent, avirulent and interim, using the attenuation index (AI) method and a plant inoculation bioassay. Ralstonia solanacearum was detected in all asymptomatic and symptomatic tomato plants, with population numbers, ranging from 10.5 to 86.7 × 105 cfu/g. However, asymptomatic plants harboured only avirulent or interim R. solanacearum, whereas tomato plants displaying 1st or 2nd disease degree contained interim and virulent strains. Additionally, 3rd and 4th degree plants harboured only virulent strains. The disease was more severe in vegetative‐stage plants (disease severity index (DSI) 0.20) with higher total numbers of interim and virulent R. solanacearum strains than those in reproductive‐stage plants (DSI 0.12). Three pathotypes of R. solanacearum coexisted in a competitive growth system in the tomato field, and their distribution closely correlated with the severity of tomato bacterial wilt.     

Virulent Coxiella burnetii pathotypes productively infect primary human alveolar macrophages

The intracellular bacterial pathogen Coxiella burnetii is a category B select agent that causes human Q fever. In vivo, C. burnetii targets alveolar macrophages wherein the pathogen replicates in a lysosome‐like parasitophorous vacuole (PV). In vitro, C. burnetii infects a variety of cultured cell lines that have collectively been used to model the pathogen's infectious cycle. However, differences in the cellular response to infection have been observed, and virulent C. burnetii isolate infection of host cells has not been well defined. Because alveolar macrophages are routinely implicated in disease, we established primary human alveolar macrophages (hAMs) as an in vitro model of C. burnetii–host cell interactions. C. burnetii pathotypes, including acute disease and endocarditis isolates, replicated in hAMs, albeit with unique PV properties. Each isolate replicated in large, typical PV and small, non‐fused vacuoles, and lipid droplets were present in avirulent C. burnetii PV. Interestingly, a subset of small vacuoles harboured single organisms undergoing degradation. Prototypical PV formation and bacterial growth in hAMs required a functional type IV secretion system, indicating C. burnetii secretes effector proteins that control macrophage functions. Avirulent C. burnetii promoted sustained activation of Akt and Erk1/2 pro‐survival kinases and short‐termphosphorylation of stress‐related p38. Avirulent organisms also triggered a robust, early pro‐inflammatory response characterized by increased secretion of TNF‐α and IL‐6, while virulent isolates elicited substantially reduced secretion of these cytokines. A corresponding increase in pro‐ and mature IL‐1β occurred in hAMs infected with avirulent C. burnetii, while little accumulation was observed following infection with virulent isolates. Finally, treatment of hAMs with IFN‐γ controlled intracellular replication, supporting a role for this antibacterial insult in the host response to C. burnetii. Collectively, the current results demonstrate the hAM model is a human disease‐relevant platform for defining novel innate immune responses to C. burnetii.     

Virulence Frequences of Puccinia triticina in Germany and the European Regions of the Russian Federation

From 2001 to 2003, leaf rust was collected in different regions of Germany and the Russian Federation to generate single spore isolates and to study the structure of the pathogen populations by analyses of virulence. The virulence of isolates was tested with 38 near‐isogenic lines each carrying a different resistance gene. The analyses of variance revealed significant effects for the frequency of virulent isolates, the regions and most interactions with years and regions, but no significance was found for the effects of years. In Germany, an increase of virulence frequencies was detected for Lr1 and Lr2a while a decrease was found for Lr3a, Lr3bg and Lr3ka. Such clear trends did not occur in Russia which may be due to the great agroclimatic differences between regions. The variance of the frequency of virulent isolates was used to estimate adequate sample sizes for the analysis of regional populations of leaf rust. This procedure resulted in more reliable information about the dynamic processes within the pathogen populations. In 2002 and 2003, all pathotypes in Germany had a combined virulence to Lr1, Lr2a, Lr2b, Lr15, Lr17 and Lr20 supplemented by a few other genes. The complexity of virulence was lower in the most frequent pathotypes. In Russia virulence to the alleles at locus Lr3 was very common. Using detached leaf segments in Germany and Russia it turned out that the most virulent pathotypes carry 34 and 32 virulence genes, respectively. Virulence to Lr9, Lr19, Lr24 and Lr38 was rare or even absent. The use of major genes, not overcome by corresponding virulent pathotypes, may contribute to more durable types of resistance in case they are combined with genes having different effects, e.g. adult plant 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.     

The isolation of Pi1, an allele at the Pik locus which confers broad spectrum resistance to rice blast

We report the isolation of Pi1, a gene conferring broad-spectrum resistance to rice blast (Magnaporthe oryzae). Using loss- and gain-of-function approaches, we demonstrate that Pi1 is an allele at the Pik locus. Like other alleles at this locus, Pi1 consists of two genes. A functional nucleotide polymorphism (FNP) was identified that allows differentiation of Pi1 from other Pik alleles and other non-Pik genes. A extensive germplasm survey using this FNP reveals that Pi1 is a rare allele in germplasm collections and one that has conferred durable resistance to a broad spectrum of pathogen isolates.