Trichoderma from Aceh Sumatra reduce Phytophthora lesions on pods and cacao seedlings

The cocoa tree, Theobroma cacao L., suffers large yield losses in Aceh Indonesia due to the disease black pod rot, caused by Phytophthora spp. Despite having the largest area under cacao production in Sumatra, farmers in the Aceh region have low overall production because of losses to insect pests and black pod rot. Trichoderma spp. were isolated from the roots and leaves of cacao trees and screened as potential biological control agents. Isolates used in the study were Trichoderma asperellum isolates T2 and T4, Trichoderma longibrachiatum isolates T15 and T16, and Trichoderma virens isolates T1 and Tv. T1, T2, T4, and Tv completely colonized and destroyed Phytophthora tropicalis and Phytophthora palmivora mycelium in precolonized plate assays. All six isolates reduced P. tropicalis, but none reduced the growth of P. palmivora in dual plate assays. Phytophthora growth was suppressed on MIN media amended with sterile heat inactivated Trichoderma culture filtrates, with Tv best suppressing growth of both Phytophthora spp. T. virens isolate Tv was the only isolate observed coiling around P. tropicalis mycelium and disrupted the formation of P. palmivora sporangia. Of all six isolates, only Tv reduced P. palmivora lesion expansion in a detached pod assay, reducing severity by 71%. Tv also reduced P. palmivora infection on seedlings when applied aerially at 1 × 10⁶ and 1 × 10⁸ conidia/ml, by 19% and 59%, respectively. T. virens isolate Tv is a mycoparasite, antagonizes Phytophthora in a dual plate assay, and shows antibiosis against Phytophthora spp., suggesting that multiple modes of action contribute to its ability to limit Phytophthora lesion expansion on cacao pods and seedlings.     

Identification of QTLs related to cocoa resistance to three species of<Emphasis Type="Italic"> Phytophthora</Emphasis>

This study aimed to compare the genetic control of cacao resistance to three species of Phytophthora: Phytophthora palmivora, Phytophthora megakarya and Phytophthora capsici. The study was conducted on 151 hybrid progenies created in Côte d'Ivoire and grown in a green-house in Montpellier. Phytophthora resistance was screened by leaf-test inoculation with two different strains per species. Selection of the best individuals for resistance to P. palmivora at a 10% selection rate, would lead to a genetic progress of 47% in the disease evaluation for this species and a genetic progress of 42% and 21% for the two other species. A genetic map with a total length of 682 cM was built with 213 markers, 190 AFLPs and 23 microsatellites. QTLs were identified using composite interval mapping. QTLs were found located in six genomic regions. One of these was detected with five strains belonging to the three Phytophthora species. Two other regions were detected with two or three strains of two different species. Three additional QTLs were detected for only one species of Phytophthora. Each QTL explained between 8 to 12% of the phenotypic variation. For each strain, between 11.5% to 27.5% of the total phenotypic variation could be explained by the QTLs identified. The identification of multiple QTLs involved in resistance to Phytophthora offers the possibility to improve durability of resistance in cocoa by a possible cumulation of many different resistance genes located in different chromosome regions using marker-aided selection.Communicated by H.F. Linskens     

An in vitro investigation of Malaysian Phytophthora palmivora isolates and pathogenicity study on oil palm

Bud rot disease affecting oil palm in South American countries is reported to be caused by Phytophthora palmivora. P. palmivora is a local pathogen affecting various crops in Malaysia, and this finding caused an alarm, which prompted an investigation of pathogenicity using Malaysian P. palmivora to assess the potentials of this Oomycete to infect oil palm in Malaysia. A total of 11 P. palmivora isolates were obtained from cocoa and durian for the study. Leaf bioassays via artificial inoculation using 50,000 zoospores/ml and mycelial agar disc showed severe necrotic lesions on the infection spot of oil palm (DxP) spear leaves. Mild infection was observed in oil palm spear leaves of OxG hybrids indicating lower susceptibility against P. palmivora infection. Phylogenetic analysis using internal transcribed spacer (ITS) data revealed that Malaysian isolates were genetically similar to Colombian isolates supported by significant bootstrap values. The leaf bioassay results revealed that Malaysian oil palm materials are susceptible towards local P. palmivora infection. The Colombian P. palmivora isolates causing bud rot incidence may have evolved over a long period of time, undergone sequential genetic shift to become more virulent towards Colombian oil palm planting materials.     

First Report of Phytophthora Foliar Blight on Florida Hopbush (Dodonaea viscosa) in Italy

During 2010, a new foliar blight was detected on potted Dodonaea viscosa cv. Purpurea plants in two nurseries in Catania (Italy). On the basis of morphological and cultural features, the pathogen was identified as Phytophthora palmivora. The internal transcribed spacer (ITS)‐rDNA sequence of a representative Phytophthora isolate from hopbush showed 99% identity with other ITS sequences of different P. palmivora isolates available in GenBank, thus confirming the morpho‐cultural identification. Koch’s postulates were fulfilled by pathogenicity tests on potted D. viscosa cv. Purpurea seedlings. To our knowledge, this is the first report of P. palmivora foliar blight disease on D. viscosa.     

Phytophthora Crown and Root Rot of Apricot Caused by Phytophthora palmivora in Turkey

Forty‐nine Phytophthora isolates were obtained from roots and crown of apricot trees with symptoms of decline grown in commercial orchards in Malatya, Elaz?? and Diyarbak?r provinces, Turkey, in 2011 and 2013. All of the recovered isolates were identified as Phytophthora palmivora on the basis of morphological characteristics. Blast analysis of ITS region sequences of rDNA of 5 isolates revealed 100% identity with a reference isolates of P. palmivora from GenBank. Isolates of P. palmivora were pathogenic on 12‐month‐old wild apricot rootstock ‘Zerdali’ plants that were wound inoculated on the roots and on the crown. This study demonstrated that P. palmivora is the cause of the crown and root rot found on apricot in Turkey. To our knowledge, this is the first report of P. palmivora on this host plant.     

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.     

Ectopic expression of <Emphasis Type="Italic">Dahlia merckii</Emphasis> defensin <Emphasis Type="Italic">DmAMP</Emphasis>1 improves papaya resistance to <Emphasis Type="Italic">Phytophthora palmivora</Emphasis> by reducing pathogen vigor

Phytophthora spp., some of the more important casual agents of plant diseases, are responsible for heavy economic losses worldwide. Plant defensins have been introduced as transgenes into a range of species to increase host resistance to pathogens to which they were originally susceptible. However, the effectiveness and mechanism of interaction of the defensins with Phytophthora spp. have not been clearly characterized in planta. In this study, we expressed the Dahlia merckii defensin, DmAMP1, in papaya (Carica papaya L.), a plant highly susceptible to a root, stem, and fruit rot disease caused by Phytophthora palmivora. Extracts of total leaf proteins from transformed plants inhibited growth of Phytophthora in vitro and discs cut from the leaves of transformed plants inhibited growth of Phytophthora in a bioassay. Results from our greenhouse inoculation experiments demonstrate that expressing the DmAMP1 gene in papaya plants increased resistance against P. palmivora and that this increased resistance was associated with reduced hyphae growth of P. palmivora at the infection sites. The inhibitory effects of DmAMP1 expression in papaya suggest this approach has good potential to impart transgenic resistance against Phytophthora in papaya.     

Phenotypic differences among single-oospore cultures of Phytophthora palmivora and P. botryosa from Heavea brasiliensis

Oospores ofPhytophthora palmivora andP. botryosa fromHevea brasiliensis were produced when complementary strains of the same species were incubated on V-8 juice agar in continuous darkness, with or without a subsequent period of continuous light. The oospores germinated at a rate of 15–30 % in demineralised water at 26 °C in normal daylight conditions. Other substrates did not improve the germination rate. Single-zoospore colonies derived from sporangia formed by a single oospore were similar to each other in morphology and in pathogenicity toHevea leaves. Over 400 single-oospore isolates from four intraspecific matings ofP. palmivora, and 102 from one pairing ofP. botryosa, were examined. The progeny differed in morphological appearance, mating behaviour, temperature-growth relations, pathogenicity toHevea leaf petioles and cacao pods, rate of production, shape and size of sporangia and in the abundance of chlamydospores. The progeny from an intraspecific cross ofP. botryosa was more variable, with a few isolates being similar in appearance toP. palmivora, having permanently lost their parental characteristic of producing small oval sporangia in clumps. One isolate in particular was indistinguishable fromP. palmivora in morphology and in its ability to produce functional oospores when mated withP. palmivora. Oospores formed by interspecific crosses could not be germinated. With both species, many progeny was less pathogenic than the parents, and many completely non-infective isolates with respect toHevea, cacao and other host plants were produced. Sexual reproduction resulted in a diversity of phenotypes, and both parental types and recombinants were recovered.     

Characterization and pathogenicity of three Phytophthora spp. recovered from rivers in Bulgaria

Many Phytophthora species are pathogens on fruit trees and may cause destructive diseases. In the current study, we examined six Phytophthora isolates recovered from rivers in Bulgaria, representatives of the following three species: Phytophthora chlamydospora, P. pseudocryptogea and P. syringae. Morphological traits, cardinal temperatures and growth rates of the isolates were described. We found considerable variation in the size of sporangia and significant difference in the mycelial growth rates of the two P. pseudocryptogea isolates, along with multiple polymorphic sites in the ITS region of one of them. In the cases of the other two Phytophthora species, no such differences were found between the isolates. Both P. chlamydospora isolates had a lower optimum growth temperature compared with the reported in the literature for this species. In pathogenicity tests against leaves and fruits of apple, pear, cherry, apricot and plum, the isolates proved to be capable of causing infections with varying severity. P. chlamydospora showed to be the most aggressive towards the leaves, while P. pseudocryptogea isolates induced the highest percentage of decay on the fruits of all tested tree species, which may suggest partial organ or tissue specificity. The demonstrated infection capacity of the described isolates points out the investigated Phytophthora species as a potential threat for the orchards in Bulgaria, if favourable conditions are available.     

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.     

Evaluation of fatty acid methyl ester profile and amplified fragment length polymorphism analyses to distinguish five species of Phytophthora associated with ornamental plants

Fatty acid methyl ester (FAME) profiles and amplified fragment length polymorphisms (AFLPs) were evaluated as tools for identifying species of Phytophthora. Five isolates of each of Phytophthora cactorum, Phytophthora citrophthora, Phytophthora cinnamomi, Phytophthora nicotianae and Phytophthora cryptogea were subjected to both analyses to examine variation among and within species. In FAME analysis, isolates of P. cactorum, P. cinnamomi and P.nicotianae were clustered by species, but isolates of P. citrophthora and P.cryptogea were divided into multiple clusters based on greater variations within these two species. The AFLP analysis differentiated all five species of Phytophthora. The five isolates of each species were grouped in a separate terminal cluster, but diversity within a species cluster varied considerably with variation greater in P. cryptogea and P. citrophthora. Comparing the dendrograms based on FAME and AFLP analyses, the overall patterns of both were similar. The P. cactorum cluster was distinct from clusters of the other four species, which formed one large cluster. The higher values of percentages of polymorphic loci and gene diversity in AFLP analysis substantiated diversity observed among isolates of P. citrophthora and P. cryptogea in FAME and AFLP dendrograms. Both FAME and AFLP appear to be useful tools for identifying species of Phytophthora, but only AFLP analysis has potential to study genetic and phylogenetic relationships within and among species in this genus.     

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.     

Isolation of anti-fungal phenolic compounds from petioles of two Hevea brasiliensis (rubber) genotypes and their effect on Phytophthora meadii

Phenolic compounds were present in greater amounts in non‐infected petioles of genotypes of Hevea brasiliensis that are resistant to Phytophthora leaf disease than in genotypes that are susceptible. Phenolic compounds extracted from petioles of either susceptible (PB86) or resistant (RRIC100) genotypes, before or after infection with Phytophthora meadii, had anti‐fungal properties. Artificially infected petioles of PB86 had phenolic acids, triterpenoids or flavonoids, whereas healthy petioles contained only triterpenoids or flavonoids. However, healthy or infected petioles of RRIC100 contained only trace amounts of the above compounds and of vanillin (3‐methoxy‐4‐hydroxybenzaldehyde). Vanillin and umbelliferone (7‐hydroxycoumarin) were shown to suppress zoospore germination of P. meadii on glass slides and to inhibit its growth in pea broth and V‐8 juice agar. Vanillin was slightly more active than umbelliferone. Resistance of RRIC100 to Phytophthora was suspected as being related to the polymerisation of phenolic compounds to form lignin, which may suppress further spread of the pathogen's mycelium into healthy tissues. Formation of lignin from phenolic aldehydes as a barrier to disease spread may be a critical factor in resistance.     

Intra-racial variation in Phytophthora infestans and adaptation to field resistance for potato blight

Strains of Phytophthora infestans of the same race (P₄) isolated from a range of R₀ potato varieties differed markedly in their rate of growth on agar but differences in growth rate were not related to variety of origin. Two isolates from each of the varieties Duke of York, Majestic and Arran Consul were grown for six successive subcultures on tubers of these three varieties. The six isolates differed in aggressiveness as shown by their growth on individual varieties. There was a marked difference in growth rate between alternate subcultures which is attributed to the use of too long an incubation period. Analysis of the data for subcultures 1, 3 and 5 revealed a significant interaction between isolates and varieties which reflected the enhanced growth of five of the isolates on the variety from which they had been obtained. Serial subculture on potato tubers of the same variety had no general or specific effect on the aggressiveness of the isolates. It is concluded that strains of P. infestans of the same race may be differentially adapted to the variety on which they are growing in the field. Differential interactions between pathogen biotypes and non-immune hosts are considered to be widespread in host-pathogen systems.     

Biological Control of Phytophthora Root Rots on Alfalfa and Soybean with Streptomyces

A collection of 53 antibiotic-producing Streptomyces isolated from soils from Minnesota, Nebraska, and Washington were evaluated for their ability to inhibit plant pathogenic Phytophthora medicaginis and Phytophthora sojae in vitro. Eight isolates having the greatest pathogen-inhibitory capabilities were subsequently tested for their ability to control Phytophthora root rots on alfalfa and soybean in sterilized vermiculite and naturally infested field soil. The Streptomyces isolates tested significantly reduced root rot severity in alfalfa and soybean caused by P. medicaginis and P. sojae, respectively (P < 0.05). On alfalfa, isolates varied in their effect on plant disease severity, percentage dead plants, and plant biomass in the presence of the pathogen. The same eight isolates of Streptomyces were also tested for inhibitory activities against each other and against three strains of Bradyrhizobium japonicum and two strains of Sinorhizobium meliloti isolated from soybean and alfalfa, respectively. Streptomyces isolates clustered into two major compatibility groups: isolates within the same group were noninhibitory toward one another in vitro. The compatibility groups corresponded with groupings obtained based upon inhibition of B. japonicum and S. meliloti strains.     

Influence of temperature upon growth and sporulation in two species of Phytophthora

The paper deals with the influence of temperature on the growth and sporulation of two species ofPhytophthora, viz.,P. palmivora Butl. andP. parasitica Dast. var.macrospora Ashby, the causal agents of fruit rots ofAchras sapota L. andAnona squamosa L. respectively. Germination of sporangia at different temperatures were also undertaken. There was marked variation in growth and sporulation of these two organisms. Isolate C (Phytophthora palmivora) showed no growth at 5° and 35°C, scanty growth at 10° and 32.5° with an optimum temperature between 26–28°C. On the other hand, Isolate S (Phytophthora parasitica var.macroscora) showed no growth at 10°C, but slight growth even at 37°C. Eight days exposure at 37°C completely stopped the growth of this Isolate. It showed best growth at 30°C and hence this was its optimum temperature. In general, Isolate C sporulated abundantly at all temperatures tested but reached its maximum at 25°C. On the other hand Isolate S showed best growth but failed to sporulate at any of the temperatures in 98 hours growth, although it sporulated freely when the incubation period extended up to two weeks. On the basis of temperature toleration the twoPhytophthora isolates are distinguished from each other as two different species. This confirms the earlier observations and nomenclature criterion as emphasized and formulated byTucker (1931). In the germination studies, it was observed that the indirect germination with the formation of abundant zoospores started from 5° and continued even up to 35°C, reaching maximum at 20°C. High temperature was not favourable for indirect germination. As the temperature proceeded increasing, the percentage of direct germination by formation of germ tubes also increased. Direct germination was observed from 10° which continued up to 37°C, with a maximum reach at 30°C. This confirms the epidemic of fruit rots in nature during monsoon season which is prevalent with the persistence of high humidity and rainfall.Taken from a thesis submitted by the author for the degree of Master of Science in the Faculty of Agriculture, Poona University, India.     

Some physiological studies in two species of phytophthora

Summary The paper deals with some physiological studies viz., (1) Production of enzymes (2) Effect of chemicals and sugar solutions and (3) Utilization of amino acids, by two species ofPhytophthora i.e.,Phytophthora palmivora Butler andP. parasitica Dast. var.macrospora Ashby., isolated from rotten fruits ofAchras sapota andAnona squamosa respectively.In the study of production of extra-cellular enzymes, it was found that both the isolates ofPhytophthora produced enzymes like inulase, amidase, emulsin and diastase in small quantity.Among the various chemicals and salt solutions used to study their effects in the formation of sporangia; it was observed that these were remarkably produced in abundance by both the species ofPhytophthora specially in the chemical solutions like sodium chloride, potassium nitrate, sodium thiosulphate and potassium permanganate. On the other hand, chemical solutions like strontium sulphate, potassium chromate, ammonium oxalate, zinc sulphate, copper sulphate, potassium sulphate, strontium nitrate and ferrous sulphate completely ceased the sporangial development. Among the various sugar solutions tried, dextrose, galactose, glucose, laevulose and fructose accelerated sporangial formation.An attempt was also made to study the effect of various amino acids singly or in combination on growth and sporulation. Both the isolates under study, utilized L-Arganine monohydrochloride and DL-Aspartic acid, hence these were growth promoters. It is interesting to note that the growth of the isolates was good, only when DL-Norleucine and DL-Methionine (both growth inhibitors) were provided in combination.Forms a part of Senior author's M.Sc. (Agriculture) Thesis, University of Poona, (Poona) India.Respectively, Ex-Jr. Res. Fellow, I.C.A.R. New Delhi; Professor of Plant Pathology and Principal, College of Agriculture, Junagad (Gujarat); and Plant Pathologist, Wheat Rust Research Station, Mahabaleshwar (Poona), India.     

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.     

Phytophthora chrysanthemi sp. nov., a new species causing root rot of chrysanthemum in Japan

A new species of Phytophthora was isolated from stem and root rot of chrysanthemum in the Gifu and Toyama prefectures of Japan. The species differs from other Phytophthora species morphologically, and is characterized by nonpapillate, noncaducous sporangia with internal proliferation, formation of both hyphal swellings and chlamydospores, homothallic nature, distinctive intercalary antheridia, and funnel-shaped oogonia. The new species can grow even at 35°C, with an optimum growth temperature of 30°C in V8 juice agar medium. In phylogenetic analyses based on five nuclear regions (LSU rDNA; genes for translation elongation factor 1α, β-tubulin, 60 S ribosomal protein L10, and heat shock protein 90), the isolates formed a monophyletic clade. Although the rDNA ITS region shows a high resolution and has proven particularly useful for the separation of Phytophthora species, it was difficult to align the sequences for phylogenetic analysis. Therefore, ITS region analysis using related species as defined by the multigene phylogeny was performed, and the topology of the resulting tree also revealed a monophyletic clade formed by the isolates of the species. The morphological characteristics and phylogenetic relationships indicate that the isolates represent a new species, Phytophthora chrysanthemi sp. nov. In pathogenicity tests, chrysanthemum plants inoculated with the isolates developed lesions on stems and roots within 3 days, and the symptoms resembled the ones originally observed. Finally, the pathogen’s identity was confirmed by re-isolation from lesions of infected plants.     

Genetic Variability in Phytophthora palmivora (Butl.) Using RAPD Markers

Phytophthora palmivora causes bud rot, fruit and immature nut fall in India, and causes significant coconut yield losses. Genetic variability was estimated in 70 isolates representing seven populations from the Kerala and Karnataka regions using random amplified polymorphic DNA (RAPD) markers. RAPDs generated a total of 163 markers with 15 decamer primers, of which 92% were found to be polymorphic. The number of polymorphic loci within a single population varied from 45 to 92 with estimated hetrozygosities ranging from 0.08 to 0.23. The majority of the genetic diversity was distributed within populations (68.25%) and only 31.75% were among populations. Genetic relationships estimated by the unweighted pair‐group method with arithmatic averaging (UPGMA) revealed clear separation of Kerala and Karnataka populations.