Electrophoretic protein patterns of three species ofPhytophthora associated with black pod disease of cocoa (Theobroma cacao L.)

When electrophoretic profiles of native proteins from vegetative mycelia ofPhytophthora palmivora, Phytophthora capsici and Phytophthora citrophthora causing black pod disease of cocoa in India were compared on a single Polyacrylamide gel, the isolates of same species were readily distinguished both qualitatively by visual similarity in banding patterns and quantitatively by calculating similarity coefficients. Similarity coefficients were generally much higher between isolates within a species than between isolates of different species. The dendrograms obtained after unweighted pair grouping with arithmetic averaging cluster analysis, revealed that all the isolates ofPhytophthora capsici were highly homogenous and formed a single cluster. The isolates ofPhytophthora citrophthora were resolved into two electrophoretic types which were clustered into two distinct sub groups.Phytophthora palmivora formed a separate group. Thus, the results reveal that polyacrylamide gel electrophoresis can be used successfully in distinguishing species and sub groups within a species ofPhytophthora encountered on cocoa. CPCRl contribution No. 914.     

Behaviour of Phytophthora citrophthora and P. nicotianae var. in soil, and Differences in Their Tolerance to Antimicrobial Components of Selective Media Used for Isolation of Phytophthora spp.

Phytophthora citrophthora was inhibited to a greater extent than P. nicotianac var. parasitica by chloramphenicol, hymexazol, PCNB and pimaricin at concentrations used in selective media for the isolation of Phytophthora spp. Reduced concentrations of the antimicrobial components of the selective media to tolerant levels for P. citrophthora markedly increased the recovery of the two brown rot pathogens from soil. Mycelium of both Phytophthora spp. survived in air-dried soil for at least 5 months while mycelium of most Phytophthora spp. do not survive in dry soil. In moist soil, P. nicotianae var. parasitica produced hyphal swellings, sporangia and chlamydospores. P. citrophthora produced hyphal swellings and sporangia, but no chlamydospores. No oospores were produced, even in pairing cultures on agar plates with isolates obtained from several locations of citrus groves andfruits by both species. Sporania were obtained in both species in citrus groves on mycelium mats, in the rhizosphere, in infected leaves and fruits buried at soil depths of 5–35 cm. Numbers of propagules declined during the incubation period, but conside, rable numbers survived throughout the experimental period (6 months). Although P. nicotianae var. parasitica produced chlamydospores while P. citrophthora did not, numbers of surviving propagules recovered from soil after 6 months were comparable with both species. The brown rot pathogens survived in soil both as colonizers of detached leaves and fruits and as parasites in living root tissues.     

The Phytophthora diseases of stone fruit trees in Greece

Phytophthora collar and crown rots are serious soilborne diseases which for a long time have caused considerable losses in stone fruit orchards in Greece. A number of Phytophthora species are notorious for being the cause of crown and root rots in Greek stone trees, including P. cactorum, P. citricola, P. cryptogea, P. drechsleri, P. nicotianae, P. citrophthora, P. syringae and P. megasperma. The most important Phytophthora species is P. cactorum, while P. syringae and P. citrophthora may be locally significant. The economic consequences from death of peach trees and yield losses caused by this disease in Imathia County are serious.     

Occurrence of Pythium spp. and Phytophthora spp. in Norwegian Greenhouses and their Pathogenicity on Cucumber Seedlings

Samples of tomato, lettuce and cucumber submitted for diagnosis to the Plant Protection Centre at the Norwegian Crop Research Institute and samples of soil, water and cucumber collected from greenhouses employing hydroponic cultures were examined for the occurrence of Pythium spp. and Phytophthora spp. Two species of Phytophthora and 16 species of Pythium were identified. Phytophthora cryptogea was found on tomato and lettuce. Phytophthora nicotianae was found on tomato fruit. Phytophthora was not found on cucumbers. Pythium irregulare and Pythium group F were the two most commonly found Pythium species in hydroponically cultivated cucumbers. A pathogenicity test with 56 isolates was performed on cucumber seedlings. The most aggressive species were Pythium aphanidermatum, P. irregulare, Pythium paroecandrum and Pythium ultimum.     

Phytophthora Species Infecting Hardy Ornamentals in Nurseries and the Managed Environment in Scotland

Between 2002 and the end of 2009, more than 4000 samples from hardy ornamental plants, collected in surveys for Phytophthora ramorum, were examined to establish the occurrence and diversity of Phytophthora species in Scotland. The samples were gathered from more than 77 plant genera in nurseries, gardens and amenity landscapes. Fifteen different Phytophthora spp. were isolated and identified either by polymerase chain reaction (PCR) or by sequencing of the ITS1, 5.8S subunit and ITS2 region of the ribosomal RNA gene. The most widespread Phytophthora spp. were P. ramorum and P. syringae, followed by P. cactorum, P. kernoviae, P. plurivora, P. cambivora, P. citrophthora, P. taxon ‘Pgchlamydo’, P. pseudosyringae and some single isolates of P. cinnamomi, P. cryptogea, P. gonapodyides, P. nicotianae and P. hibernalis. One isolate did not match any known species. In relation to the number of samples, Phytophthora was found more frequently in trade premises than in gardens or amenity landscapes and the species diversity was higher, highlighting the risks involved in plant trade.     

Evaluation of Resistance of Stone Fruit Rootstocks to Phytophthora Crown Rot*

The pathogenicity of Phytophthora citrophthora, Phy‐tophthora cactorum and Phytophthora megasperma strains was confirmed on 2‐year‐old stone fruit rootstocks artificially inoculated in the field. Phytophthora mega‐sperma was not virulent or less virulent than P. cactorum or P. citrophthora. The rootstocks Damas and AN 1/7 were resistant whereas the rootstocks Jl, Titan x Nemaguard 5/1, GF 677, Myrandier 613, Italian x Nemaguard 1 and Myrandier 617 were susceptible to P. citrophthora. The rootstocks Tsukuba 9, Tit‐an x Nemaguard 4/7, AN 1/2, AN 1/3, St. Mien 655/2 and Bl showed medium susceptibility to this species. The isolates of P. cactorum induced more extensive necrosis in Myrandier 617 and Italian x Nemaguard than in Myr‐andier 613, GF 677, Jl (ADAFUEL), Tsukuba 9 and St. Julien 655/2. Among seven rootstocks, Tsukuba 5 and St. Julien 655/2 were more resistant than Myrandier 613, Myrandier 617, Jl (ADAFUEL), Tsukuba 9 and St. Julien 655/2.     

Distribution of Phytophthora citrophthora R.E. Sm. and E.H. Sm. and P. parasitica Dastur within citrus orchards in Kerman province,Iran

In this research, distribution of Phytophthora species were determined in Kerman Province (Bam, Shahdad and Arzuiyeh) during 2004–2007. The Phytophthora species were isolated from infected root, crown and soil. Root and crown pieces were washed and cultured on a CMA-PARPH medium. The isolation from infected soil was performed by bating method using citrus leaves. It was identified by morphological and several physiological characteristics. Distribution of species was determined by recording the number of isolates recovered from samples from each city. In this study, from 220 soil samples collected from 52 citrus orchards, 80 isolates of Phytophthora were recovered. Among of all isolates of Phytophthora, P. parasitica and P. citrophthora were the most important species of causal agent of gummosis on Citrus sp. Distribution of P. citrophthora was highest in Arzuiyeh and lowest in Bam and Shahdad cities, while distribution of P. parasitica was highest in Bam and Shahdad cities. The majority of soil samples contained only P. parasitica, but a few of percentage samples containing P. citrophthora alone and both of fungi in cites samples.     

Antagonism of Chaetomium globosum, Gliocladium virens and Trichoderma viride to four soil-borne Phytophthora species

Chaetomium globosum, Gliocladium virens and Trichoderma viride, isolated from soil samples from the Kivu-region of Zaire, are antagonistic and mycoparasitic to four soil-borne Phytophthora spp. Radial growth of Phytophthora cinnamomi, P. cactorum, P. fragariae or P. nicotianae mycelia was inhibited in all antagonist-pathogen combinations; mycelial mats of Phytophthora colonies were overgrown by the antagonists and hyphae lysed. Samples of mycoparasited mycelium, plated on benlateamended PDA to inhibit the development of antagonists, showed severely reduced vitality after 77 days of dual culture.     

Developing a taxonomic identification system of Phytophthora species based on microsatellites

BackgroundPhytophthora is the most important genus of the Oomycete plant pathogens. Nowadays, there are 117 described species in this genus, most of them being primary invaders of plant tissues. The different species are causal agents of diseases in a wide range of crops and plants in natural environments. In order to develop control strategies against Phytophthoraspecies, it is important to know the biology, ecology and evolutionary processes of these important pathogens.AimsThe aim of this study was to propose and validate a low cost identification system for Phytophthora species based on a set of polymorphic microsatellite (SSRs) markers.MethodsThirty-three isolates representing Phytophthora infestans, Phytophthora andina, Phytophthora sojae, Phytophthora cryptogea, Phytophthora nicotianae, Phytophthora capsici and Phytophthora cinnamomi species were obtained, and 13 SSRs were selected as potentially transferable markers between these species. Amplification conditions, including annealing temperatures, were standardized for several markers.ResultsA subset of these markers amplified in all species, showing species-specific alleles.ConclusionsThe adaptability and impact of the identification system in Colombia, an Andean agricultural country where different Phytophthora species co-exist in the same or in several hosts grown together, are discussed.     

Rapid detection of Phytophthora nicotianae by simple DNA extraction and real‐time loop‐mediated isothermal amplification assay

Phytophthora nicotianae is a phytopathogenic oomycete with a wide host range and worldwide distribution. Rapid detection and diagnosis at the early stages of disease development are important for the effective control of P. nicotianae. In this study, we designed a simple and rapid loop‐mediated isothermal amplification (LAMP)‐based detection method for P. nicotianae. We tested three DNA extraction methods and selected the Kaneka Easy DNA Extraction Kit version 2, which is rapid and robust for LAMP‐based detection. The designed primers were tested using mycelial DNA from 35 species (81 isolates) of Phytophthora, 12 species (12 isolates) of Pythium, one isolate of Phytopythium and one isolate each from seven other soil‐borne pathogens. All of the 42 P. nicotianae isolates were detected by these primers, and no other isolates gave positive results. Three isolates were tested for the sensitivity of the reaction, and the lowest amounts of template DNA that could be detected were 10 fg for two isolates and 1 fg for the third. The target was detected within 25 min in all tested samples, including DNA extracted from both inoculated and naturally infected plants. In contrast, PCR assays with P. nicotianae‐specific primers failed or showed weakened detection in several samples. Thus, we found that the rapid DNA extraction and LAMP assay methods developed in this study can be used to detect P. nicotianae with high sensitivity, specificity and stability.     

Occurrence of Phytophthora Root and Stem Rot of Kiwifruit in Turkey

Vine decline of kiwifruit was observed in an orchard in Bart?n province of Turkey. Affected vines exhibited poor terminal growth, leaf discoloration and various degrees of dieback, including complete vine death. Symptoms were observed in the field on roots, crowns and stems. Two Phytophthora species were isolated from decayed cortical roots and lower stems of kiwifruits. They were identified as Phytophthora cryptogea and Phytophthora megasperma by their morphological characteristics and the analysis of sequences of the internal transcribed spacer (ITS) region of the rDNA. Pathogenicity of the isolates was tested by stem inoculation on kiwifruit seedlings. After 4 weeks, cankers developed in the plants inoculated with P. cryptogea, while no cankers formed in those inoculated with P. megasperma and in control plants. This is the first report of P. cryptogea causing root and stem rot of kiwifruit in Turkey.     

Phylogenetic relationship of Phytophthora cryptogea Pethybr. & Laff and P. drechsleri Tucker

The phylogeny and taxonomy of Phytophthora cryptogea and Phytophthora drechsleri has long been a matter of controversy. To re-evaluate this, a worldwide collection of 117 isolates assigned to either P. cryptogea, P. drechsleri or their sister taxon, Phytophthora erythroseptica were assessed for morphological, physiological (pathological, cultural, temperature relations, mating) and molecular traits. Multiple gene phylogenetic analysis was performed on DNA sequences of nuclear (internal transcribed spacers (ITS), ß-tubulin, translation elongation factor 1α, elicitin) and mitochondrial (cytochrome c oxidase subunit I) genes. Congruence was observed between the different phylogenetic data sets and established that P. drechsleri and P. cryptogea are distinct species. Isolates of P. drechsleri form a monophyletic grouping with low levels of intraspecific diversity whereas P. cryptogea is more variable. Three distinct phylogenetic groups were noted within P. cryptogea with an intermediate group providing strong evidence for introgression of previously isolated lineages. This evidence suggests that P. cryptogea is an operational taxonomic unit and should remain a single species. Of all the morphological and physiological traits only growth rate at higher temperatures reliably discriminated isolates of P. drechsleri and P. cryptogea. As a homothallic taxon, P. erythroseptica, considered the cause of potato pink rot, is clearly different in mating behaviour from the other two species. Pathogenicity, however, was not a reliable characteristic as all isolates of the three species formed pink rot in potato tubers. The phylogenetic evidence suggests P. erythroseptica has evolved from P. cryptogea more recently than the split from the most recent common ancestor of all three species. However, more data and more isolates of authentic P. erythroseptica are needed to fully evaluate the taxonomic position of this species.     

Characterization of Phytophthora cinnamomi populations from ornamental plants in South Carolina,USA

Abstract

Fifty-one isolates of Phytophthora cinnamomi isolated from ornamental plants in South Carolina, USA, between 1995 and 2000 were characterized by sporangium morphology, mating type, sensitivity to the fungicide mefenoxam, fatty acid methyl ester (FAME) profile analysis, and amplified fragment length polymorphism (AFLP) analysis. Sporangium shapes were predominantly ovoid to ellipsoid, and size averaged 65.5×40.3 μm (length×breadth) with average length/breadth ratio of 1.6. Forty-nine isolates were the A2 mating type with only two A1 isolates found. This is the first report of the A1 mating type of P. cinnamomi in South Carolina. All isolates were sensitive to mefenoxam and EC₅₀ values for all isolates were less than 0.2 μg ml^?1. FAMEs of each isolate were analysed by gas chromatography and revealed five major fatty acids: myristic (14:0), palmitic (16:0), linoleic (18:2ω6c), oleic (18:1ω9c), and eicosapentaenoic (20:5ω3c) acids. These five fatty acids accounted for more than 80% of FAME profiles. Cluster analysis of FAME profiles showed that individual isolates had unique pattern that could be divided into four major clusters. AFLP analysis based on 200 informative loci also separated isolates into four major clusters. A1 isolates were different from all A2 isolates. The percentage of polymorphic loci (10.5%) and Nei's gene diversity (0.0435) were much higher for the two A1 isolates than for any cluster of A2 isolates even though A2 isolates had more isolates within a cluster. A2 isolates exhibited relatively little genetic variation overall, which suggests that these isolates may have come from a common source.     

Effects of extracts of Alnus glutinosa seeds on growth of Frankia strain ArI3 under static and fermentor culture conditions

The amount of root mortality caused by root pathogens such as Phytophthora nicotianae (syn. Phytophthora parasitica) has typically been inferred from the net change in root length density in sequential soil cores. Because such measurements give information only on net changes in root populations, the actual rate of root turnover is often underestimated. We used minirhizotrons to track the fate of a large number of individual fine roots of mature field-grown citrus trees over a 6-month period. This method enabled us to examine the effect of P. nicotianae population levels on fine-root mortality. Seasonal and genotypic variation in patterns of citrus fine root mortality were associated with variation in population levels of P. nicotianae. Fine root lifespans were shorter when populations of P. nicotianae were high. Fine roots of the Phytophthora-susceptible rootstock, rough lemon (Citrus jamibhiri), had shorter median lifespans and supported larger populations of P. nicotianae than the fine roots of the more tolerant rootstock, Volkamer lemon (Citrus volkameriana). Rates of root mortality were either relatively constant for roots of all ages, or increased with age; the latter pattern was most pronounced for Volkamer lemon roots. Differences in the age-dependence of root mortality may, therefore, play a role in genotypic differences in tolerance of Phytophthora root rot by these two rootstocks. H Lambers Section editor     

PCR Amplification of Ribosomal DNA for Species Identification in the Plant Pathogen Genus Phytophthora

We have developed a PCR procedure to amplify DNA for quick identification of the economically important species from each of the six taxonomic groups in the plant pathogen genus Phytophthora. This procedure involves amplification of the 5.8S ribosomal DNA gene and internal transcribed spacers (ITS) with the ITS primers ITS 5 and ITS 4. Restriction digests of the amplified DNA products were conducted with the restriction enzymes RsaI, MspI, and HaeIII. Restriction fragment patterns were similar after digestions with RsaI for the following species: P. capsici and P. citricola; P. infestans, P. cactorum, and P. mirabilis; P. fragariae, P. cinnamomi, and P. megasperma from peach; P. palmivora, P. citrophthora, P. erythroseptica, and P. cryptogea; and P. megasperma from raspberry and P. sojae. Restriction digests with MspI separated P. capsici from P. citricola and separated P. cactorum from P. infestans and P. mirabilis. Restriction digests with HaeIII separated P. citrophthora from P. cryptogea, P. cinnamomi from P. fragariae and P. megasperma on peach, P. palmivora from P. citrophthora, and P. megasperma on raspberry from P. sojae. P. infestans and P. mirabilis digests were identical and P. cryptogea and P. erythroseptica digests were identical with all restriction enzymes tested. A unique DNA sequence from the ITS region I in P. capsici was used to develop a primer called PCAP. The PCAP primer was used in PCRs with ITS 1 and amplified only isolates of P. capsici, P. citricola, and P. citrophthora and not 13 other species in the genus. Restriction digests with MspI separated P. capsici from the other two species. PCR was superior to traditional isolation methods for detection of P. capsici in infected bell pepper tissue in field samples. The techniques described will provide a powerful tool for identification of the major species in the genus Phytophthora.     

Phytophthora parsiana sp. nov., a new high-temperature tolerant species

As part of a study to examine the phylogenetic history of the taxonomically challenging species Phytophthora cryptogea and P. drechsleri, a distinct monophyletic group of isolates, previously described as P. drechsleri or P. cryptogea, were characterised. Analysis of their rDNA ITS sequences indicated that these isolates were distinct from P. drechsleri, P. cryptogea, and all members of Phytophthora ITS clades 1–8, clustering instead alongside basal groups previously described as clades 9 and 10. This group comprised six isolates all of which were isolated from woody plants, such as pistachio (Pistacia vera, Iran and USA), fig (Ficus carica, Iran), and almond (Prunus dulcis, Greece). Analysis of sequence data from nuclear (β-tubulin and translation elongation factor 1α) and mitochondrial (cytochrome c oxidase subunit I) genes confirmed the ITS-based analysis as these isolates formed a distinct monophyletic group in all NJ trees. The isolates were fast growing with a relatively high optimum growth temperature of 30 °C and, in most cases, rapid colony growth even at 37 °C. The isolates produced complex colony patterns on almost all media, especially corn meal agar (CMA). Phylogenetic analysis and examination of all the other morphological and physiological data lead us to infer that this taxon has not been described previously. As this taxon was first isolated and described from Iran we propose that this taxon be formally designated as Phytophthora parsiana.     

Viral diversity in Phytophthora cactorum population infecting strawberry

Eighty-eight Phytophthora cactorum strains isolated from crown or leather rot of strawberry in 1971–2019 were screened for viruses using RNA-seq and RT-PCR. Remarkably, all but one isolate were virus-infected, most of them harbouring more than one virus of different genera or species. The most common virus occurring in 94% of the isolates was the Phytophthora cactorum RNA virus 1 (PcRV1) resembling members of Totiviridae. Novel viruses related to members of Endornaviridae, named Phytophthora cactorum alphaendornaviruses 1-3 (PcAEV1-3), were found in 57% of the isolates. Four isolates hosted viruses with affinities to Bunyaviridae, named Phytophthora cactorum bunyaviruses 1-3 (PcBV1-3), and a virus resembling members of the proposed genus ‘Ustivirus’, named Phytophthora cactorum usti-like virus (PcUV1), was found in a single isolate. Most of the virus species were represented by several distinct strains sharing ≥81.4% aa sequence identity. We found no evidence of spatial differentiation but some temporal changes in the P. cactorum virus community were observed. Some isolates harboured two or more closely related strains of the same virus (PcAEV1 or PcRV1) sharing 86.6%–96.4% nt identity in their polymerase sequence. This was surprising as viruses with such a high similarity are typically mutually exclusive.     

Genetic characterization of Phytophthora nicotianae by the analysis of polymorphic regions of the mitochondrial DNA

A new method based on the analysis of mitochondrial intergenic regions characterized by intraspecific variation in DNA sequences was developed and applied to the study of the plant pathogen Phytophthora nicotianae. Two regions flanked by genes trnY and rns and trnW and cox2 were identified by comparing the whole mitochondrial genomes of Phytophthora infestans, Phytophthora ramorum, and Phytophthora sojae and amplified using primers designed from the flanking conserved genes. These regions were sequenced from 51 isolates of P. nicotianae of both A1 and A2 mating type recovered from different hosts and geographic regions. Amplicon length varied from 429 bp to 443 bp (trnY/rns) and 322 bp to 373 bp (trnW/cox2) with intraspecific variation due to single nucleotide polymorphisms and indels. Seventeen, seven and 20 different haplotypes were detected by individually analyzing regions trnY-rns, trnW-cox2 and the combined data set of sequences from both regions, respectively. Phylogenetic analysis inferred with three different methods enabled the grouping of isolates in five clades, each containing different mitochondrial haplotypes and revealed diversity in the mitochondrial genome of P. nicotianae. The majority of isolates from citrus grouped in a single clade indicating either movement of isolates on planting stock or an association of particular isolates with this host. Phylogenetic groups were not correlated with the radial growth rate of the isolates or the rapidity of apple flesh colonization. The method developed in the present study represents an innovative molecular tool for the characterization of natural populations of P. nicotianae and should be easily expanded to other species of Phytophthora as well as other plant pathogens. It can be used to track specific haplotypes and, thanks to its high genetic resolution, it could be standardized and applied in a DNA barcoding like strategy for the precise identification of sub-specific taxa. Compared to alternative molecular methods, a major advantage is that results are unbiased (a list of nucleotides) and highly reproducible, thus enabling the comparison of data from different laboratories and time periods. Furthermore, the method could be further enhanced by the identification of additional variable mitochondrial and/or nuclear genomic regions.     

Molecular Distinctions Between Phytophthora capsici and Ph. tropicalis Based on ITS Sequences of Ribosomal DNA

Among four species of Phytophthora tested, only Ph. capsici and Ph. tropicalis showed the same length for DNA sequence for both internal transcribed spacer (ITS)1 and ITS2 of ribosomal DNA. Phytophthora palmivora and P. nicotianae have lengths different from each other, and from the other two species. Although A1 and A2 types of Ph. capsici differ from each other by only one nucleotide, there are 10 different nucleotides between A1 and A2 types of Ph. tropicalis. Phylogenetic analysis of combined ITS sequences identified four clades each consisting A1 and A2 mating types of same species. The neighbor‐joining and maximum parsimony trees show that Ph. tropicalis (A2) is clustered with the clade of two isolates of Ph. capsici before joining the clade of A1 and two other isolates of Ph. tropicalis from GenBank. Our results support the separation of Ph. tropicalis and demonstrate the need to sequence more than a single isolate of a species in the study of molecular phylogeny of Phytophthora. The phylogenetic trees also suggest that Ph. tropicalis (A2) may represent a transitional isolate in the process of species evolution.