QTLs for tomato powdery mildew resistance (Oidium lycopersici) in Lycopersicon parviflorum G1.1601 co-localize with two qualitative powdery mildew resistance genes

Tomato (Lycopersicon esculentum) is susceptible to the powdery mildew Oidium lycopersici, but several wild relatives such as Lycopersicon parviflorum G1.1601 are completely resistant. An F2 population from a cross of Lycopersicon esculentum cv. Moneymaker x Lycopersicon parviflorum G1.1601 was used to map the O. lycopersici resistance by using amplified fragment length polymorphism markers. The resistance was controlled by three quantitative trait loci (QTLs). Ol-qtl1 is on chromosome 6 in the same region as the Ol-1 locus, which is involved in a hypersensitive resistance response to O. lycopersici. Ol-qtl2 and Ol-qtl3 are located on chromosome 12, separated by 25 cM, in the vicinity of the Lv locus conferring resistance to another powdery mildew species, Leveillula taurica. The three QTLs, jointly explaining 68% of the phenotypic variation, were confirmed by testing F3 progenies. A set of polymerase chain reaction-based cleaved amplified polymorphic sequence and sequence characterized amplified region markers was generated for efficient monitoring of the target QTL genomic regions in marker assisted selection. The possible relationship between genes underlying major and partial resistance for tomato powdery mildew is discussed.     

Linked, if not the same, Mi-1 homologues confer resistance to tomato powdery mildew and root-knot nematodes

On the short arm of tomato chromosome 6, a cluster of disease resistance (R) genes have evolved harboring the Mi-1 and Cf genes. The Mi-1 gene confers resistance to root-knot nematodes, aphids, and whiteflies. Previously, we mapped two genes, Ol-4 and Ol-6, for resistance to tomato powdery mildew in this cluster. The aim of this study was to investigate whether Ol-4 and Ol-6 are homologues of the R genes located in this cluster. We show that near-isogenic lines (NIL) harboring Ol-4 (NIL-Ol-4) and Ol-6 (NIL-Ol-6) are also resistant to nematodes and aphids. Genetically, the resistance to nematodes cosegregates with Ol-4 and Ol-6, which are further fine-mapped to the Mi-1 cluster. We provide evidence that the composition of Mi-1 homologues in NIL-Ol-4 and NIL-Ol-6 is different from other nematode-resistant tomato lines, Motelle and VFNT, harboring the Mi-1 gene. Furthermore, we demonstrate that the resistance to both nematodes and tomato powdery mildew in these two NIL is governed by linked (if not the same) Mi-1 homologues in the Mi-1 gene cluster. Finally, we discuss how Solanum crops exploit Mi-1 homologues to defend themselves against distinct pathogens.     

Naturally occurring broad-spectrum powdery mildew resistance in a Central American tomato accession is caused by loss of mlo function

The resistant cherry tomato (Solanum lycopersicum var. cerasiforme) line LC-95, derived from an accession collected in Ecuador, harbors a natural allele (ol-2) that confers broad-spectrum and recessively inherited resistance to powdery mildew (Oidium neolycopersici). As both the genetic and phytopathological characteristics of ol-2-mediated resistance are reminiscent of powdery mildew immunity conferred by loss-of-function mlo alleles in barley and Arabidopsis, we initiated a candidate-gene approach to clone Ol-2. A tomato Mlo gene (SlMlo1) with high sequence-relatedness to barley Mlo and Arabidopsis AtMLO2 mapped to the chromosomal region harboring the Ol-2 locus. Complementation experiments using transgenic tomato lines as well as virus-induced gene silencing assays suggested that loss of SlMlo1 function is responsible for powdery mildew resistance conferred by ol-2. In progeny of a cross between a resistant line bearing ol-2 and the susceptible tomato cultivar Moneymaker, a 19-bp deletion disrupting the SlMlo1 coding region cosegregated with resistance. This polymorphism results in a frameshift and, thus, a truncated nonfunctional SlMlo1 protein. Our findings reveal the second example of a natural mlo mutant that possibly arose post-domestication, suggesting that natural mlo alleles might be evolutionarily short-lived due to fitness costs related to loss of mlo function.     

Development of diagnostic PCR markers closely linked to the tomato powdery mildew resistance gene Ol-1 on chromosome 6 of tomato

Lycopersicon hirsutum G1.1560 is a wild accession of tomato that shows resistance to Oidium lycopersicum, a frequently occurring tomato powdery mildew. This resistance is largely controlled by an incompletely dominant gene Ol-1 near the Aps-1 locus in the vicinity of the resistance genes Mi and Cf-2/Cf-5. Using a new F₂ population (n=150) segregating for resistance, we mapped the Ol-1 gene more accurately to a location between the RFLP markers TG153 and TG164. Furthermore, in saturating the Ol-1 region with more molecular markers using bulked segregant analysis, we were able to identify five RAPDs associated with the resistance. These RAPDs were then sequenced and converted into SCAR markers: SCAB01 and SCAF10 were L. hirsutum-specific; SCAE16, SCAG11 and SCAK16 were L. esculentum-specific. By linkage analysis a dense integrated map comprising RFLP and SCAR markers near Ol-1 was obtained. This will facilitate a map-based cloning approach for Ol-1 and marker-assisted selection for powdery mildew resistance in tomato breeding. Received: 21 June 1999 / Accepted: 1 December 1999     

Polymorphic change of appressoria by the tomato powdery mildew Oidium neolycopersici on host tomato leaves reflects multiple unsuccessful penetration attempts

The appressorial shapes of the powdery mildews are an important clue to the taxonomy of the powdery mildew fungi, but the conidia of the tomato powdery mildew Oidium neolycopersici KTP-01 develop non-lobed, nipple-shaped, and moderately lobed or multilobed appressoria on the same leaves. To remove this ambiguity, we performed consecutive observations of sequential appressorial development of KTP-01 conidia with a high-fidelity digital microscope. Highly germinative conidia of KTP-01, collected from conidial pseudochains formed on the tomato leaves, were inoculated into host tomato and nonhost barley leaves or an artificial hydrophobic membrane (Parafilm). Events from germination initiation to appressorium formation were synchronous in all conidia on all materials used for inoculation, but post-appressorial behaviors varied among the materials. Appressoria on the membrane-stuck glass slide formed several projections at different portions of the appressoria to repeat unsuccessful penetration attempts. Similar unsuccessful penetration behavior by KTP-01 conidia was observed in the inoculations into leaves of barley plants, wild tomato species Lycopersicon peruvianum LA2172 (carrying the Ol-4 gene for powdery mildew resistance), and a susceptible host tomato (Lycopersicon esculentum) that had been inoculated with the barley powdery mildew (Blumeria graminis f. sp. hordei, race 1) conidia. On the barley leaves, all penetrations of KTP-01 were impeded by the papillae formed beneath the sites of the appressorial projections. On both the wild tomato and the race 1-inoculated cultivated tomato plants, KTP-01 conidia were prevented from forming functional haustoria by hypersensitive epidermal cell death; this hypersensitive reaction involved the Ol-4 gene in the wild tomato plants or the 'induced resistance' acquired by the nonpathogenic conidia previously inoculated into the cultivated tomato plants. All these KTP-01 conidia produced several projections on the appressoria during the repeated unsuccessful penetration attempts and eventually exhibited multilobed appressoria. On the host tomato leaves inoculated singly with KTP-01 conidia, fewer than 20% of the conidia located appressoria on the central part of target epidermal cells and succeeded in forming functional haustoria at the first penetration attempt without forming an appressorial projection. These conidia exhibited non-lobed appressoria. The remaining conidia, however, whose appressoria were located on/near the border of the target epidermal cells, were more likely to fail to penetrate at the first penetration, and then to develop additional projections for subsequent penetrations. Most conidia succeeded in forming functional haustoria at the second to fourth penetration attempts, but a few conidia failed to produce haustoria at all attempted penetrations. Eventually, the conidia that succeeded at the second penetration possessed a single appressorial projection (exhibiting the nipple-shaped appressoria), whereas the remaining conidia exhibited moderately lobed appressoria with two to four appressorial projections and multilobed appressoria, with more projections. Thus, the present study revealed that the basic shape of appressoria of KTP-01 was the non-lobed type, and that polymorphic changes of the appressoria occurred as a result of successive production of projections during repeated unsuccessful penetration attempts.     

Variation in Response of Wild Lycopersicon and Solanum spp. against Tomato Powdery Mildew (Oidium lycopersici)

A set of 154 accessions of nine wild Lycopersicon spp. and five accessions of three closely related Solanum spp. were tested for resistance to tomato powdery mildew ( Oidium lycopersici ). Screening revealed valuable sources of resistance, mainly among L. hirsutum, L. pennellii, L. cheesmanii, L. chilense, L. peruvianum and L. parviflorum. L. esculentum (all ssp.) and L. pimpinellifolium expressed high susceptibility to O. lycopersici inoculation. Results of variance and cluster analysis of responses to O. lycopersici coincide with recent taxonomic classification and genetic relationships within genus Lycopersicon .     

Local and systemic production of nitric oxide in tomato responses to powdery mildew infection

Various genetic and physiological aspects of resistance of Lycopersicon spp. to Oidium neolycopersici have been reported, but limited information is available on the molecular background of the plant–pathogen interaction. This article reports the changes in nitric oxide (NO) production in three Lycopersicon spp. genotypes which show different levels of resistance to tomato powdery mildew. NO production was determined in plant leaf extracts of L. esculentum cv. Amateur (susceptible), L. chmielewskii (moderately resistant) and L. hirsutum f. glabratum (highly resistant) by the oxyhaemoglobin method during 216 h post-inoculation. A specific, two-phase increase in NO production was observed in the extracts of infected leaves of moderately and highly resistant genotypes. Moreover, transmission of a systemic response throughout the plant was observed as an increase in NO production within tissues of uninoculated leaves. The results suggest that arginine-dependent enzyme activity was probably the main source of NO in tomato tissues, which was inhibited by competitive reversible and irreversible inhibitors of animal NO synthase, but not by a plant nitrate reductase inhibitor. In resistant tomato genotypes, increased NO production was localized in infected tissues by confocal laser scanning microscopy using the fluorescent probe 4-amino-5-methylamino-2',7'-difluorofluorescein diacetate. NO production observed in the extracts from pathogen conidia, together with elevated NO production localized in developing pathogen hyphae, demonstrates a complex role of NO in plant–pathogen interactions. Our results are discussed with regard to a possible role of increased NO production in pathogens during pathogenesis, as well as local and systemic plant defence mechanisms.     

Mapping <Emphasis Type="Italic">Ol-4</Emphasis>, a gene conferring resistance to <Emphasis Type="Italic">Oidium neolycopersici</Emphasis> and originating from <Emphasis Type="Italic">Lycopersicon peruvianum</Emphasis> LA2172, requires multi-allelic,single-locus markers

Lycopersicon peruvianum LA2172 is completely resistant to Oidium neolycopersici, the causal agent of tomato powdery mildew. Despite the large genetic distance between the cultivated tomato and L. peruvianum, fertile F₁ hybrids of L. esculentum cv. Moneymaker × L. peruvianum LA2172 were produced, and a pseudo-F₂ population was generated by mating F₁ half-sibs. The disease tests on the pseudo-F₂ population and two BC₁ families showed that the resistance in LA2172 is governed by one dominant gene, designated as Ol-4. In the pseudo-F₂ population, distorted segregation was observed, and multi-allelic, single-locus markers were used to display different marker-allele configurations per locus. Parameters for both distortion and linkage between genetic loci were determined by maximum likelihood estimation, and the necessity of using multi-allelic, single-locus markers was illustrated. Finally, a genetic linkage map of chromosome 6 around the Ol-4 locus was constructed by using the pseudo-F₂ population.     

The Arabidopsis genes RPW8.1 and RPW8.2 confer induced resistance to powdery mildew diseases in tobacco

Plant disease resistance (R) gene products recognize pathogen avirulence (Avr) gene products and induce defense responses. It is not known if an R gene can function in different plant families, however. The Arabidopsis thaliana R genes RPW8.1 and RPW8.2 confer resistance to the powdery mildew pathogens Erysiphe orontii, E. cichoracearum, and Oidium lycopersici, which also infect plants from other families. We produced transgenic Nicotiana tabacum, N. benthamiana, and Lycopersicon esculentum plants containing RPW8.1 and RPW8.2. Transgenic N. tabacum plants had increased resistance to E. orontii and O. lycopersici, transgenic N. benthamiana plants had increased resistance to E. cichoracearum, but transgenic L. esculentum plants remained susceptible to these pathogens. The defense responses induced in transgenic N. tabacum and N. benthamiana were similar to those mediated by RPW8.1 and RPW8.2 in Arabidopsis. Apparently, RPW8.1 and RPW8.2 could be used to control powdery mildew diseases of plants from other families.     

Mapping of five resistance genes to sugar-beet powdery mildew using AFLP and anchored SNP markers

Sugar-beet powdery mildew, caused by the fungus Erysiphe betae, now occurs in all sugar-beet growing areas and can reduce sugar yield by up to 30%. Powdery mildew resistant plants from three novel sources were crossed with sugar beet to generate segregating populations. Evaluation of resistance was carried out in artificially inoculated field and controlled environment tests. The resistance level in two of the sources was found to be significantly higher than that in currently available sugar-beet cultivars. AFLP analysis was used in combination with bulked segregant analysis to develop markers linked to the resistant phenotype in each population. Five dominant major resistance genes were identified and assigned the proposed symbols Pm2 to Pm6. Pm3 conferred complete resistance to powdery mildew; the other genes conferred high levels of partial resistance. From the use of anchoring SNP markers, two genes were located to chromosome II and three to chromosome IV. Two of the genes on chromosome IV mapped to the same location and one of the genes on chromosome II mapped to the same region as the previously identified Pm1 gene. With the availability of these genes there is now excellent potential for achieving durable resistance to sugar-beet powdery mildew, thus reducing or obviating the need for chemical control.     

The resistance to Oidium lycopersici conferred by ol-2 gene in tomato

The powdery mildew caused by Oidium lycopersici is one of the most destructive diseases in glass-house-grown tomato and is widespreading all over the world. A high level of resistance to O. lycopersici was found in an accession of Lycopersicon esculentum var. cerasiforme at the Department of Biology and Plant Pathology, University of Bari. The genetic analysis of F1, F2 and BC plants indicated that the resistance is conferred by a single recessive gene, designed as ol-2. Studies on the infection process of O. lycopersici on susceptible and ol-2 gene resistant tomatoes were carried out at 24 °C and 90 % relative humidity. Light microscope observations on conidia germination, formation of primary appressoria, elongation of hyphae and sporulation were made on artificially inoculated basal, intermediate and apical leaves. Inoculation was made by shaking mildewed tomato leaves over each test plant. Disease development were assessed by removing the fungal structure from the leaf surface with the ceroidin film technique and by direct observations of stained inoculated leaves. The rate of conidial germination and the appressoria formation was not affected by host genotype. Mycelia growth and sporulation on leaf surface of resistant plant was strongly restricted and influenced by the leaf age. The results indicated that the resistance in ol-2 tomato is postinfectional and is not associated with a hypersensitive response. This work was supported by the MURST and CNR (Paper no. 331)     

Towards the introducing of resistance to powdery mildew from Lycopersicon hirsutum into L. esculentum

Genes of resistance to Oidium lycopersicum from Lycopersicon hirsutum LA 1775 were introduced to L. esculentum. Breeding procedures were based on a one-way programme up to the F2 generation and then four different methods were adopted to obtain F4 and BC4 populations. Screening tests among those hybrid populations were performed in a greenhouse and showed segregation for resistance to powdery mildew due to different genetic backgrounds of the families derived from four breeding methods that changed the status of the gene/genes responsible for resistance to powdery mildew. F4 and BC4 populations varied in relation to morphological traits (fruit size and weight, seed and fruit productivity, number of locules). There was a significant progress in breeding in comparison to L. hirsutum regarding fruit size and weight, and the number of locules. Values of two other traits: seed and fruit productivity, that are correlated with self- and cross-compatibility, were low and similar to L. hirsutum. Therefore, another one or two backcrosses will probably improve seed and fruit productivity.     

Microsatellite markers linked to 2 powdery mildew resistance genes introgressed from Triticum carthlicum accession PS5 into common wheat.

Two dominant powdery mildew resistance genes introduced from Triticum carthlicum accession PS5 to common wheat were identified and tagged using microsatellite markers. The gene designated PmPS5A was placed on wheat chromosome 2AL and linked to the microsatellite marker Xgwm356 at a genetic distance of 10.2 cM. Based on the information of its origin, chromosome location, and reactions to 5 powdery mildew isolates, this gene could be a member of the complex Pm4 locus. The 2nd gene designated PmPS5B was located on wheat chromosome 2BL with 3 microsatellite markers mapping proximally to the gene: Xwmc317 at 1.1 cM; Xgwm111 at 2.2 cM; and Xgwm382 at 4.0 cM; and 1 marker, Xgwm526, mapping distally to the gene at a distance of 18.1 cM. Since this gene showed no linkage to the other 2 known powdery mildew resistance genes on wheat chromosome 2B, Pm6 and Pm26, we believe it is a novel powdery mildew resistance gene and propose to designate this gene as Pm33.     

Resistance to powdery mildew (Oidium lycopersicum) in Lycopersicon hirsutum is controlled by an incompletely-dominant gene Ol-1 on chromosome 6

The inheritance of resistance to powdery mildew (Oidium lycopersicum) in Lycopersicon hirsutum was investigated by disease tests in segregating populations obtained by hybridising tomato (L. esculentum) cv Moneymaker with the wild relative L. hirsutum G1.1560. One incompletely dominant gene Ol-1 was found to largely control resistance to the disease. To map Ol-1, DNA pools from seven resistant and ten susceptible F₂ plants were analyzed for random amplified polymorphic DNA (RAPD). With 32 primers tested, one RAPD, primed with the sequence 5-GACGTGGTGA-3, was observed between the susceptible and the resistant bulks, which cosegregated with resistance in the F₂ population of L. esculentum × L. hirsutum G1.1560. This RAPD was mapped on chromosome 6 by using an F₂ (L. esculentum × L. pennellii) already mapped for 49 RFLPs. RFLP analysis of the F₂ from L. esculentum cv Moneymaker × L. hirsutum G1.1560 demonstrated that Ol-1 maps near the Aps-1 region on chromosome 6, in the vicinity of the resistance genes to Meloidogyne spp. (Mi) and to Cladosporium fulvum (Cf-2/Cf-5).     

Molecular detection of a gene effective against powdery mildew in the wheat cultivar Liangxing 66

Since it was commercialized in 2008, Liangxing 66 is one of the most widely grown cultivars of wheat (Triticum aestivum L.) in winter and facultative wheat-producing regions in northern China. This cultivar displays broad-spectrum resistance to isolates of powdery mildew. To identify the powdery mildew resistance gene in Liangxing 66, genetic analysis and molecular mapping were conducted using the F₂ populations and F_2:3 families derived from the reciprocal crosses of Liangxing 66 and the susceptible cultivar Jingshuang 16. A single dominant gene, tentatively designated PmLX66, conferred resistance in Liangxing 66 to the powdery mildew isolate E09. The results of molecular mapping indicated that this gene was located on the short arm of chromosome 5D and flanked by SCAR203 and Xcfd81 at genetic distances of 0.4 and 2.8?cM, respectively, which is similar to the position of locus Pm2. However, PmLX66 and Pm2 showed different reactions to five of the 42 isolates of powdery mildew tested. Together, these results indicated that PmLX66 was most likely an allele of Pm2. Based on its superior yield and agronomic performance, in combination with powdery mildew resistance, Liangxing 66 is useful as a promising parent for control of powdery mildew and for the development of new disease-resistant cultivars.     

mlo-based powdery mildew immunity: silver bullet or simply non-host resistance?

Durability and effectiveness against all genetic variants of a microbial species are hallmarks of so-called plant 'non-host' resistance. Highly effective immunity of monocotyledonous barley against the fungal powdery mildew pathogen, which is conferred by loss-of-function mutant alleles of the barley Mlo locus, likewise is a durable and broad-spectrum type of resistance. Although this was long considered as being a barley-specific phenomenon, recent findings indicate that mlo resistance can also occur in the distantly related dicotyledonous species Arabidopsis thaliana . Shared histological and phytopathological characteristics plus a conserved requirement for a set of genes in Arabidopsis mlo and non-host powdery mildew resistance indicate a potential common mechanism for these two seemingly distinct types of immunity.     

The root-knot nematode resistance gene (Mi) in tomato: construction of a molecular linkage map and identification of dominant cDNA markers in resistant genotypes

A dominant allele at the Mi locus on chromosome 6 of tomato (Lycopersicon esculentum Mill) confers resistance to three species of root-knot nematodes (Meloidogyne). The resistance, which is associated with a localized necrotic response, was originally introduced into tomato from the wild species Lycopersicon peruvianum. As a step towards the molecular cloning of Mi, we have identified closely linked DNA markers from both cDNA and genomic DNA libraries as restriction fragment length polymorphisms (RFLPs). DNA from tomato populations segregating for nematode resistance was analyzed to generate a high-resolution genetic map of this region. Additional information on gene order was obtained by comparing the size of the introgressed L. peruvianum chromosomal segment within a collection of nematode-resistant tomato lines. Among the four cDNA markers that are tightly linked to Mi, three are dominant, i.e. L. peruvianum-specific. One cDNA marker corresponds to a gene family comprising 20-30 members, one of which is diagnostic for all nematode-resistant genotypes tested. The presence of non-homologous sequences around the Mi gene may contribute to the suppression of recombination in this region of the genome in crosses heterozygous for Mi. The potential of 'walking' from closely linked markers to Mi is discussed.     

硬粒小麦-粗山羊草双二倍体白粉病抗性的遗传分析与基因推导

对99份硬粒小麦-粗山羊双二倍体用北京地区流行的5号白粉菌生理小种进行了白粉病抗性鉴定,筛选出11个苗期抗病的双二倍体材料和2个全生育期抗病的材料M53和M81。对M53和M81及其硬粒小麦和粗山羊草亲本进行的抗白粉病鉴定结果表明,其抗性来源于粗山羊草。与M53和M81具有相同硬粒小麦亲本、不同粗山羊草亲本双二倍体的抗性结果也表明抗性基因来源于粗山羊草。对M53和M81的抗性遗传分析表明,它们均携带1个单显性抗病基因。用14个白粉菌生理小种对已知抗病基因品系与M53和M81两份待测材料进行接种鉴定,结果表明,M53和M81与已知基因的抗菌谱均不相同,M53与M81的抗菌谱也不相同,说明M53和M81各自分别携带1个新的显性抗白粉病基因。