Pathogenicity of fungi associated with melon vine decline and selection strategies for breeding resistant cultivars

Melone Vine Decline is a severe rot root disease of increasing world‐wide importance. In Eastern Spain it is related to the presence of Acremonium cucurbitacearum and Monosporascus cannonballus. The strong influence of environmental conditions on the progress of this disease has made its study difficult. A field screening of Cucumis melo accessions has been conducted over four years. Simultaneously, the pathogenicity of isolates of the two fungi recovered from the screening field was studied. These were more aggressive than other Spanish and American isolates. Percentage of vine decay was scored, togeter with root damage, the latter being evaluated by using four scoring systems based on root characteristics and disease severity. Root inspection alowed the selection of resistance sources, even when aboveground symptoms did not appear, due to the lack of environmental stresses at time of fruit maturity. The root damage scoring if environmental stresses occur during fruit maturity. The accession C. melo var. agrestis Pat 81 consistently exhibited high field resistance level, expressed as a higher percentage of symptomeless plants, together with a significant delay in symptoms appearance. The F₁ hybrids derived from the cross Pat 81 ×C. melo susceptible varienties showed an intermediate level of resistance between the parents, suggesting a partial dominance gene action. The high resistance level found in Pat 81, and also in its derived hybrids, against the aggressive isolates found in this area, makes it promissing for breeding melon verieties resistant to melon vine decline.     

Reaction of Melon (Cucumis melo L.) Cultivars to Monosporascus cannonballus (Pollack & Uecker) and their Effect on Total Phenol,Total Protein and Peroxidase Activities

Eighteen melon cultivars were screened for resistance to Monosporascus cannonballus under greenhouse conditions. The melon cultivars were grown in pasteurized sand, which had been inoculated with a high level (60 CFUs/g of soil) of M. cannonballus mycelium from culture. Cultivars Nabijani, Sfidak khatdar, Sfidak bekhat, Ghandak, Mollamosai, Chappat, Hajmashallahi and Shadgan were moderately resistant to M. cannonballus but all other melon cultivars were moderately to highly susceptible (HS) to this pathogen. A second screening was performed for resistance to M. cannonballus under greenhouse conditions. In the second screening, cultivars Nabijani, Sfidak khatdar, Sfidak bekhat, Ghandak, Mollamosai, Chappat, Hajmashallahi and Shadgan were moderately resistant to M. cannonballus. To examine the melon resistance mechanism against M. cannonballus, the activities of total phenol, total protein and peroxidase in two melon cultivars Nabijani (as resistant) and Khaghani (as susceptible) were determined at 0, 24, 48 and 72 h after inoculation. Inoculated resistant cultivar roots had always higher content of total phenol, total protein and peroxidase than the corresponding inoculated susceptible cultivar roots. The results indicated that there was a relationship between resistance in Nabijani and accumulation of total phenol, total protein and peroxidase.     

Effects of Preconditioning Through Mycorrhizal Inoculation on the Control of Melon Root Rot and Vine Decline Caused by Monosporascus cannonballus

The use of inoculum of arbuscular mycorrhizal fungi (AMF) in nursery represents a promising field in horticulture because of its known benefits in terms of plant growth and bioprotection. The present work was undertaken to determine the effect of mycorrhizal inoculation with Rhizophagus irregularis in a nursery medium on the containment of melon root rot and vine decline (MRRVD) caused by the soil‐borne pathogen Monosporascus cannonballus. The percentage of mycorrhization, biomass and yield following mycorrhizal inoculation were also evaluated. Biocontrol activity was assessed in greenhouse pot experiments upon artificial inoculation of M. cannonballus and in a two‐season field experiment under production conditions in an unheated greenhouse with a history of MRRVD. On the basis of the mycorrhization parameters, the interaction appeared to be established within 30 days after inoculation. The total shoot growth in the mycorrhized plants was significantly higher when compared to the control, while the root growth was unaffected. Upon artificial inoculation of M. cannonballus, mycorrhization provided complete protection against the pathogen. Greenhouse experiments under production conditions during spring cropping season showed that pretransplanting inoculation with R. irregularis significantly decreased the severity of the disease. Also, the average fruit weight of mycorrhized plants was significantly higher than the untreated control. Nevertheless, in summer crop, the bioprotection activity of AMF failed. Present results indicate that the use of AMF in a nursery setting can contribute to the prevention of the onset of this problematic soil‐borne disease within a sustainable and integrated soil‐borne disease management.     

Cotton,cowpea and sesame are alternative crops to cucurbits in soils naturally infested with Monosporascus cannonballus

Monosporascus cannonballus is an important cucurbit root pathogen, which has been reported in the main production areas of melon and watermelon in Brazil and worldwide and potentially capable to colonize roots of different species. Crop rotation is considered an effective management strategy to prevent this disease. The aim of this study was to evaluate the response of different crops, pumpkin, cotton, cowpea, sesame, watermelon, melon, corn, cucumber, sorghum and tomato, to the infection of this pathogen. Seedlings were transplanted into plastic containers with an inoculum concentration of 20 colony‐forming units (CFU) g^?1 of M. cannonballus. Fifty days after transplanting, the variables analysed were the degree of disease severity on the root system and the frequency of reisolation. On cucurbits, the results demonstrated different degrees of susceptibility among crops and cultivars, being melon and watermelon the most sensitive species. In contrast, Cucurbita cultivars were the most tolerant. Regarding non‐cucurbit crops, maize, sorghum and tomato presented root discoloration and M. cannonballus was reisolated from roots. Cotton, cowpea and sesame cultivars were not affected by the pathogen, so they can be considered as alternative crops to be cultivated, or in rotation with cucurbits, in M. cannonballus infested soils.     

Plant Growth‐Promoting Bacteria from Solarized Soil with the Ability to Protect Melon Against Root Rot and Vine Decline Caused by Monosporascus cannonballus

This study was undertaken to isolate indigenous plant growth‐promoting (PGP) bacteria from solarized soil effective in the biocontrol of Monosporascus cannonballus, the cause of root rot and vine decline of melon, which is one of the most destructive soilborne diseases of this crop worldwide. The screening strategy resulted in the selection of two interesting PGP bacteria as biocontrol candidates against M. cannonballus belonging to the same microbial community. The two bacterial species, identified according to phenotypic, physiological tests and analysis of the 16S rDNA sequence as Bacillus subtilis/amyloliquefaciens (BsCR) and Pseudomonas putida (PpF4), showed PGP traits and in vitro antagonistic activity towards M. cannonballus. Antagonism by BsCR was characterized by a consistent inhibition of the pathogen in vitro growth; PpF4 strongly inhibited the development of perithecia of the pathogen. Under greenhouse conditions, the selected bacteria were tested for their biocontrol activity in the pathosystem melon‐M. cannonballus. BsCR alone and in combination with PpF4 determined a consistent decrease in the disease symptoms. BsCR and the combination of the bacterial strains significantly increased root biomass in both inoculated and un‐inoculated plant. Upon seed treatment with BsCR, the accumulation and isoenzyme induction of peroxidase in roots as biochemical marker for induction of resistance were found, thus indicating that BsCR may reduce the disease severity also by the activation of the plant defence responses. The study highlights the synergistic biocontrol potential of B. subtilis BsCR and P. putida PpF4 in the integrated management of root rot and vine decline of melon caused by M. cannonballus.     

Phylogenetic relationships among Cucumis species based on the ribosomal internal transcribed spacer sequence and microsatellite markers

The phylogenetic relationships within the genus Cucumis (a total of 25 accessions belonging to 17 species) were studied using the nuclear ribosomal DNA internal transcribed spacer (ITS) region. The analysis included commercially important species such as melon (C. melo L.) and cucumber (C. sativus). Two additional cucurbit species, watermelon and zucchini, were also included as outgroups. The data obtained reflected the clustering of Cucumis species in four main groups, comprising accessions from cucumber, melon, C. metuliferus and the wild African species. Some of the species clustered in different positions from those reported in classifications previously described by other authors. The data obtained clearly identify a division between the 2n=2x = 14 species (C. sativus) and the 2n = 2x = 24 ones (C. melo and wild species). Within the wild species we identified a subgroup that included C. sagittatus and C. globosus. Oreosyce africana, also classified as Cucumis membranifolius, was shown to be nested within Cucumis. Three accessions previously classified as independent species were shown to be genotypes of Cucumis melo. A set of melon and cucumber SSRs were also used to analyse the Cucumis species and the results were compared with the ITS data. The differential amplification of the SSRs among the accessions made it possible to distinguish three main groups: melon, cucumber and the wild species, though with less detail than applying ITS. Some SSRs were shown to be specific for melon, but other SSRs were useful for producing PCR fragments in all species of the genus.We are grateful to NCRPIS, IPK in Gatersleben, Semillas Fitó S.A., Michel Pitrat and Fernando Nuez for providing seeds. We would also like to thank Vanessa Alfaro, Trinidad Martínez and Núria Galofré for their excellent technical assistance. This work was financed by project AGL2000-0360 of Spains Ministerio de Ciencia y Tecnología (MCYT). AJMs work was supported by a postdoctoral contract from Spains MCYT.     

Prevalent weeds collected from cucurbit fields in Northeastern Brazil reveal new species diversity in the genus Monosporascus

Fungal species belonging to the ascomycete genus Monosporascus have no known asexual morph and the ascocarp is a globose perithecium where asci develop, containing from 1 to 6 spherical ascospores, depending on the species. Monosporascus cannonballus is the most well‐known species of the genus, and an important root pathogen associated with the vine decline of melon and watermelon crops worldwide. The aim of the present study was to characterise a collection of 35 Monosporascus‐like isolates recovered from roots of two weed species prevalent in cucurbit growing fields in Northeastern Brazil: Boerhavia diffusa and Trianthema portulacastrum. These isolates were identified based on DNA sequences of the Internal Transcribed Spacer regions (ITS) of the nuclear rDNA, part of the translation elongation factor gene (tef‐1α), part of the β‐tubulin gene (tub), part of the nuclear small subunit (SSU) rDNA and part of the large subunit (LSU) rDNA. Five Monosporascus species, namely Monosporascus brasiliensis, Monosporascus caatinguensis, Monosporascus mossoroensis, Monosporascus nordestinus and Monosporascus semiaridus, are newly described. Monosporascus brasiliensis, M. nordestinus and M. semiaridus were isolated from both weed species, while M. caatinguensis only from T. portulacastrum and M. mossoroensis only from B. diffusa. The present study confirms that Monosporascus spp. can colonise roots of very diverse hosts, even without causing noticeable disease symptoms, and reveals that the diversity of species in the genus Monosporascus is potentially greater than previously expected.     

Association between Aphis gossypii genotype and phenotype on melon accessions

Development of molecular markers has allowed the characterization of several host–aphid interactions. We investigated the usefulness of microsatellite markers to characterize the plant resistance interaction in the model Aphis gossypii/Cucumis melo. Six aphid clones, collected in different localities and years and belonging to two multilocus genotypes (MLGs) based on eight microsatellite markers, were phenotyped on a set of 33 melon accessions, some of them known to carry the Vat gene. Three parameters were used: acceptance of plant, ability to colonize the plant and resistance to virus when inoculated by aphids. Concordance and correlation analyses showed that aphid clones sharing a same MLG exhibited a very agreeable phenotype on the set of accessions for acceptance of plant and resistance to virus when inoculated by aphids. From host point of view, melon accessions were grouped into four clear categories, resistant to aphids of both MLGs, only resistant to the NM1 MLG, only resistant to the C9 MLG, susceptible to both MLGs and another group of unclear characteristics. The four categories revealed different patterns of virulence for NM1 and C9 MLGs that are likely controlled by a single avirulence gene in accordance with a gene for gene interaction. In contrast, the ability to colonize the plant appeared slightly variable among clones sharing a same MLG. We hypothesize it is due to the putative polygenic control of this aphid trait. Because the phenotypic variability of A. gossypii matched the genetic variability revealed by eight microsatellite markers, these markers could be used to infer the frequency of biotypes in field experiments and help to elucidate the allele diversity of melon resistance genes.     

Molecular authentication of three Italian melon accessions by ARMS-PCR and ITS1 (internal transcribed spacer 1) secondary structure prediction

Genetic assessment was carried out on three Italian melon accessions by sequence and structural analysis of the internal transcribed spacer 1 (ITS1) from three populations belonging to two Cucumis melo L. varieties (madras and tendral). Alignment of the 18S-5.8S-26S sequences from three melon accessions showed that there were three single-nucleotide polymorphisms (SNPs) and one short insertion-deletion (indel) at the 5'end ITS1. An amplification refractory mutation system (ARMS)-PCR-based analysis was successfully applied to the SNP markers of the ITS1 sequences for the fingerprinting analysis of three melon populations. Secondary structure models for each ITS1 were derived. The prediction of ITS1 RNA secondary structure from each accession was improved by detecting key functional elements shared by all sequences in the alignments. Our results demonstrated that the ITS1secondary structure models can be used to improve the preliminary genetic assessment of the three melon accessions, suggesting a new tool in plant fingerprinting analysis.     

Five independent loci each control monogenic resistance to gummy stem blight in melon (<Emphasis Type="Italic">Cucumis melo</Emphasis> L.)

Inheritance and segregation analysis demonstrated that five independent genes in melon confer monogenic resistance to foliar infection by the fungal pathogen Didymella bryoniae, resulting in the disease known as gummy stem blight (GSB). In this study, two new monogenic sources of GSB resistance were characterized. Resistance in Cucumis melo PI 482398 was monogenic dominant based on segregation analysis of F₁, F₂ and backcross populations, while resistance in C. melo PI 482399 showed monogenic recessive inheritance. Four accessions, PI 482398, PI 157082, PI 511890, and PI 140471, each previously known to carry monogenic dominant resistance to GSB, were intercrossed to determine genetic relationships among these resistance sources. Recovery of susceptible individuals in F₂ populations confirmed that these accessions possess different resistance genes. Resistance loci were designated Gsb-1 (formerly Mc, monogenic dominant resistance from PI 140471), Gsb-2 (monogenic dominant resistance from PI 157082), Gsb-3 (monogenic dominant resistance from PI 511890), Gsb-4 (monogenic dominant resistance from PI 482398) and gsb-5 (monogenic recessive resistance from PI 482399).Communicated by J. Dvorak     

Genetic analysis of Spanish melon (<Emphasis Type="Italic">Cucumis melo</Emphasis> L.) germplasm using a standardized molecular-marker array and geographically diverse reference accessions

Genetic relationships among 125 Spanish melon (Cucumis melo L.) accessions from a Spanish germplasm collection were assessed using a standard molecular-marker array consisting of 34 random amplified polymorphic DNA (RAPD) markers bands (19 primers) and 72 reference accessions drawn from previous studies. The reference accession array consisted of a broad range [Japanese (19) Crete (17), African (15), and USA and Europe (US/EU, 21)] of horticultural groupings (Group Cantalupensis, Group Conomon, Group Inodorus, Group Flexuosus, and Group Chito), and of melon market classes (e.g., Charentais, U.S. Western and European Shipper types, Ogen, and Galia, Honeydew, and Casaba). Spanish melon accessions (largely Casaba, Group Inodorus) were genetically distinct from the reference accessions and other Group Inodorus melons of different origins. Most African accessions showed common genetic affinities, and grouped with the Group Chito and the Group Conomon accessions examined. Those accession groupings were distinct from all other accessions belonging to Group Cantalupensis, Flexuosus, and Inodorus accessions originating from Crete, Japan, Europe, and the U.S. Genetic diversity was highest in accessions of African origin and lowest in accessions of Spanish origin. Additional RAPD markers (49 primers, 141 bands) and 22 selected agronomic traits (quantitative and qualitative) were then used to assess the genetic diversity among Spanish accessions. While cluster analysis using fruit characteristics grouped accessions into cultivars, RAPD-based genetic-distance estimate did not provide consistent accession groupings either by cultivar or geographic origin. While the highest level of polymorphism was detected among melons originating from the central region of Spain, and in the Rochet cultivar, accessions from the Andalucía region and Green cultivars were comparatively less diverse. These results indicate that the Spanish melon accessions could be used to broaden the genetic base of local and foreign Casaba germplasm, to enhance the genetic diversity of U.S and European commercial melon germplasm, and to delineate collection strategies for acquisition of additional Spanish landraces.Communicated by C. MöllersMention of trade name, proprietary product, or specific equipment does not constitute a guarantee or warranty by the USDA and does not imply its approval to the exclusion of other products that may be suitable.     

Genetic diversity of cucumber estimated by morpho-physiological and EST-SSR markers

In the present study, genetic variation among 40 cucumber genotypes was analyzed by means of morpho-physiological traits and 21 EST-SSR markers. Diversity was observed for morpho-physiological characters like days to 50% female flowering (37–46.9, number of fruits/plant (1.33–5.80), average fruit weight (41–333), vine length (36–364), relative water content (58.5–92.7), electrolyte leakage (15.9–37.1), photosynthetic efficiency (0.40–0.75) and chlorophyll concentration index (11.1–28.6). The pair wise Jaccard similarity coefficient ranged from 0.00 to 0.27 for quantitative traits and 0.24 to 0.96 for EST-SSR markers indicating that the accessions represent genetically diverse populations. With twenty-one EST-SSR markers, polymorphism revealed among 40 cucumber genotypes, number of alleles varied 2–6 with an average 3.05. Polymorphism information content varied from 0.002 to 0.989 (mean = 0.308). The number of effective allele (Ne), expected heterozygosity (He) and unbiased expected heterozygosity (uHe) of these EST-SSRs were 1.079–1.753, 0.074–0.428 and 0.074–0.434, respectively. Same 21 EST-SSR markers transferability checked in four other Cucumis species: snapmelon (Cucumis melo var. momordica), muskmelon (Cucumis melo L.), pickling melon (Cucumis melo var. conomon) and wild muskmelon (Cucumis melo var. agrestis) with frequency of 61.9, 95.2, 76.2, and 76.2%, respectively. Present study provides useful information on variability, which can assist geneticists with desirable traits for cucumber germplasm utilization. Observed physiological parameters may assists in selection of genotype for abiotic stress tolerance also, EST-SSR markers may be useful for genetic studies in related species.     

Intraspecific classification of melons (Cucumis melo L.) in view of their phenotypic and molecular variation

Cucumis melo L. (melon) genotypes differ widely in morphological and biochemical traits. Intraspecific classification of such variability has been difficult, and most taxonomists still rely on the work of Naudin (1859). A collection of 54 accessions representing diverse genotypes from 23 countries was surveyed. Morphological traits related to the vegetative and flowering stages and mature fruit morphology and quality parameters, e.g., taste, aroma, sugar composition and pH, were scored. These were used to construct a botanical-morphological dendrogram that generally reflected the classification ofCucumis melo into several horticultural varieties. DNA polymorphism among the accessions was assessed using the Inter-SSR-PCR and RAPD techniques that detected abundant DNA polymorphism among melon genotypes. Cluster analysis indicated that the largest divergence was between North American and Europeancantalupensis andinodorus cultivars as one group, and the more exotic varieties:conomon, chito, dudaim, agrestis andmomordica, as a second group. The molecular phylogeny agreed, broadly, with the classification of melon into two subspecies, and did not contradict the division into horticultural varieties. It was apparent, however, that the infra-specific division is rather loose, molecular variation being distributed continuously between and within cultivar groups. We suggest that despite the morphological diversity, separation between varietal-groups may be based on a too small number of genes to enable unambiguous infra-specific classification based on DNA diversity.     

Occurrence of Monosporascus cannonballus in Watermelon Fields in Tunisia and Factors Associated with Ascospore Density in Soil

Surveys of 11 watermelon fields throughout production areas of this crop in southern and central regions in Tunisia were conducted in 2007 to determine the aetiology and distribution of watermelon vine decline. Monosporascus cannonballus was isolated from diseased roots in all surveyed fields. All the isolates were identified according to morphological features and confirmed by amplification of a fragment of the ITS region with specific primers. Ascospores of M. cannonballus were recovered from soil in all watermelon fields surveyed and the average population densities ranged from 3.65 to 10.14 ascospores per g of soil. Multiple linear regression analysis revealed that only four of the crop and soil factors evaluated had a significant correlation with ascospore density at the end of the growing season: vertisol vs. other soils, disease incidence, percentage of clay and pH. The pH of the soil showed a strong significant negative linear relationship with ascospore density, while the other three factors correlated positively.     

Evaluation of Streptomyces spp. for biocontrol of gummy stem blight (Didymella bryoniae) and growth promotion of Cucumis melo L.

Gummy stem blight of Cucumis melo L. (melon) caused by Didymella bryoniae is a serious disease in the major production area of northwest China. Two Streptomyces isolates (Streptomyces pactum A12 and S. globisporus subsp. globisporus C28) previously isolated from the Qinghai-Tibet Plateau were investigated regarding their biocontrol of gummy stem blight and growth promotion of melon under controlled conditions. Streptomyces A12 and C28 indicated obvious antagonistic activity against D. bryoniae in vitro. Both A12 and C28 significantly decreased disease severity and AUDPC (area under the disease progress curve) of melon gummy stem blight in vivo (P < 0.05). Ten-fold dilution of C28 culture filtrate was more effective in controlling the disease compared with other treatments, the disease reduction effects were 41.0–64.2%. The mean fresh weights were increased by 40.4% for plants, 44.2% for roots, and 40.3% for aerial parts, when A12 was applied in both nursery soil and transplanted soil. Streptomyces C28 also increased the mean fresh weights of melon plants by 18.4–49.0% compared with the control in pot trial. Streptomyces A12 and C28 showed substantial colonization abilities in the rhizosphere and on the rhizoplane of melon plants. Results demonstrated that Streptomyces A12 and C28 were of positive effect on the biocontrol of gummy stem blight and growth promotion of Cucumis melo L.     

Performance of Galia-type melons grafted on to Cucurbita rootstock in Monosporascus cannonballus-infested and non-infested soils

Galia‐type melons grafted on to the Cucurbita rootstock‘TZ 148’and non‐grafted controls were evaluated for vegetative development under greenhouse conditions. In general, the development of grafted and non‐grafted plants was similar within a cultivar. The horticultural and pathological performances of the Galia‐type melons ‘Carrera’, ‘NUN‐5554’, ‘6003’ and ‘Arava’ were evaluated in experiments conducted in non‐infested and Monosporascus‐infested soils. In non‐infested soil, grafted and non‐grafted ‘Carrera’, ‘NUN‐5554’ and ‘Arava’ had the same yields. The yield of grafted ‘6003’ was significantly higher than that of its non‐grafted control. Responses of grafted and non‐grafted Galia‐type melons to Monosporascus cannonballus were evaluated and compared in the spring and autumn growing seasons. Significant differences in disease incidence were found among cultivars, between grafted and non‐grafted plants, and between growing seasons. Disease reduction and the beneficial effect of grafting on yield were more pronounced in the spring. The results indicate that Galia‐type melons can be grafted successfully, but the cultivation of the grafted plants should be adapted to each growing area and season.     

Fine genetic mapping of a locus controlling short internode length in melon (Cucumis melo L.)

Compact and dwarfing vining habits in melon (Cucumis melo L.; 2n = 2x = 24) may have commercial importance since they can contribute to the promotion of concentrated fruit set and can be planted in higher plant densities than standard vining types. A study was designed to determine the genetics of dwarfism associated with a diminutive (short internodes) melon mutant line PNU-D1 (C. melo ssp. cantalupensis). PNU-D1 was crossed with inbred wild-type melon line PNU-WT1 (C. melo ssp. agrestis), and resultant F₁ progeny were then self-pollinated to produce an F₂ population that segregated as dwarf and vining plant types. Primary stem length of F₂ progeny assessed under greenhouse conditions indicated that a single recessive gene, designated mdw1, controlled dwarfism in this population. To identify the chromosomal location associated with mdw1, an simple sequence repeat (SSR)-based genetic linkage map was constructed using 94 F₂ progeny. Using 76 SSR markers positioned on 15 linkage groups spanning 462.84 cM, the location of mdw1 was localized to Chromosome 7. Using the putative dwarfing-associated genes, fine genetic mapping of the mdw1 genomic region was facilitated with 1,194 F₂ progeny that defined the genetic distance between mdw1 and cytokinin oxidase gene, a candidate gene for compact growth habit (cp) in cucumber, to be 1.7 cM. The candidate gene ERECTA (serin/threonine kinase) and UBI (ubiquitin) were also mapped to genomic regions flanking mdw1 at distances of 0.6 and 1.2 cM, respectively.     

Autotoxic potential of cucurbit crops

Soil sickness is often observed in cucurbit crops such as Citrullus lanatus, Cucumis melo and Cucumis sativus, but not in cucurbit crops such as Cucurbita moschata, Lagenaria leucantha and Luffa cylindrica. Results showed that root aqueous extracts of Citrullus lanatus, Cucumis melo and Cucumis sativus were autotoxic, but those of Cucurbita moschata, Momordica charantia and Luffa cylindrica were less autotoxic to the radicle elongation of respective species. Plant growth of Citrullus lanatus, Cucumis melo and Cucumis sativus were greatly inhibited by autotoxic substances released from powered root tissue at a rate of 1 g per seedling. Root exudates of Citrullus lanatus, Cucumis melo and Cucumis sativus were autotoxic to radicle elongation and seedling growth of respective species. However, root exudates of Citrullus lanatus did not inhibit radicle elongation of Cucurbita ficifolia, which is commonly used as rootstock for the grafting of Citrullus lanatus, Cucumis melo and Cucumis sativus to decrease soil-borne diseases in commercial production. It seems possible to overcome autotoxicity in cucurbit crops by grafting on Cucurbita ficifolia. This revised version was published online in June 2006 with corrections to the Cover Date.     

Development of novel chloroplast microsatellite markers for Cucumis from sequence database

The development of chloroplast microsatellite (cpSSR) markers in Cucumis species and analysis of their polymorphism and transferability were reported. Fifteen microsatellite markers, represented by mononucleotide repeats, were developed from the complete sequence of Cucumis sativus chloroplast genome. Intraspecific variation was successfully detected in C. sativus and C. melo and revealed mean 1.6 and 1.9 alleles per cpSSR locus, respectively. With the exception of two exon region-located cpSSR markers being monomorphic, each of the others amplified polymorphic fragments in C. sativus or C. melo. A total of 34 polymorphic loci were detected with these cpSSR markers in the two species. Transferability of the newly developed cpSSR markers was checked on an additional set of 41 Cucurbitaceae accessions (belonging to 12 different species), and except for two markers with no amplification in Cucurbita maxima, the others could be transferable to all the accessions tested. Of the 15 cpSSR markers, 14 markers generated fragments with expected band sizes and 13 markers detected interspecific polymorphism among the accessions. Intraspecific polymorphism was also observed within four Cucurbitaceae species excluding C. sativus and C. melo.     

Comparative transient expression analyses on two conserved effectors of Colletotrichum orbiculare reveal their distinct cell death-inducing activities between Nicotiana benthamiana and melon

Colletotrichum orbiculare infects cucurbits, such as cucumber and melon (Cucumis melo), as well as the model Solanaceae plant Nicotiana benthamiana, by secreting an arsenal of effectors that suppress the immunity of these distinct plants. Two conserved effectors of C. orbiculare, called NLP1 and NIS1, induce cell death responses in N. benthamiana, but it is unclear whether they exhibit the same activity in Cucurbitaceae plants. In this study, we established a new Agrobacterium-mediated transient expression system to investigate the cell death-inducing activity of NLP1 and NIS1 in melon. NLP1 strongly induced cell death in melon but, in contrast to the effects seen in N. benthamiana, mutations either in the heptapeptide motif or in the putative glycosylinositol phosphorylceramide-binding site did not cancel its cell death-inducing activity in melon. Furthermore, NLP1 lacking the signal peptide caused cell death in melon but not in N. benthamiana. Study of the transient expression of NIS1 also revealed that, unlike in N. benthamiana, NIS1 did not induce cell death in melon. In contrast, NIS1 suppressed flg22-induced reactive oxygen species generation in melon, as seen in N. benthamiana. These findings indicate distinct cell death-inducing activities of NLP1 and NIS1 in these two plant species that C. orbiculare infects.