Identification of Ganoderma, the causal agent of basal stem rot disease in oil palm using a molecular method.

From comparison of the alignments of the internally transcribed spacers (ITS) of ribosomal DNA from Ganoderma associated with oil palm basal stem rot (BSR) and other Ganoderma species, two specific primer pairs were selected to provide a specific DNA amplification of pathogenic Ganoderma in oil palm. Each primer pair produced a single PCR product of about 450 bp (for primer pair IT1-IT2) and 334 bp (for primer pair IT1-IT3) when oil palm Ganoderma DNA was used. No PCR amplification product was observed when other Ganoderma species DNA was used in PCR amplification with these primer pairs. Three specific restriction enzyme sites were identified in the ITS and intergenic spacer (IGS1) regions. The restriction enzymes MluI, SacI and HinfI were used to digest the ITS-PCR product and restriction enzymes TfiI, ScaI and HincII were used to digest the IGS1-PCR product. Of the three restriction enzymes used in each rDNA region, MluI specifically digested the ITS regions, and TfiI specifically digested the IGS1 region of oil palm Ganoderma. Analysis of the published ITS nucleotide sequences of 31 Ganoderma species showed that the MluI restriction site was not present in other Ganoderma species. The use of both specific primers and restriction enzyme analysis can be applied as a standard protocol to identify pathogenic Ganoderma in oil palm. In this study, the use of specific primers and PCR-RFLP analyses of the rDNA gave consistent results for the characterisation of pathogenic Ganoderma, and indicated that Ganoderma strains associated with BSR disease in oil palms belong to a single species.

Evaluation of phenotypic and molecular typing techniques for determining diversity in Erwinia carotovora subspp. atroseptica.

A number of phenotypic and molecular fingerprinting techniques, including physiological profiling (Biolog), restriction fragment length polymorphism (RFLP), enterobacterial repetitive intergenic consensus (ERIC) and a phage typing system, were evaluated for their ability to differentiate between 60 strains of Erwinia carotovora ssp. atroseptica (Eca) from eight west European countries. These techniques were compared with other fingerprinting techniques, random amplified polymorphic DNA (RAPD) and Ouchterlony double diffusion (ODD), previously used to type this pathogen. Where possible, data were represented as dendrograms and groups/subgroups of strains identified. Simpson's index of diversity (Simpson's D) was used to compare groupings obtained with the different techniques which, with the exception of Biolog, gave values of 0.46 (RFLP), 0. 39 (ERIC), 0.83 (phage typing), 0.82 (RAPD) and 0.26 (ODD). Of the techniques tested, phage typing showed the highest level of diversity within Eca, and this technique will now form the basis of studies into the epidemiology of blackleg disease.

Application of the PCR technique to detect Phytophthora infestans in potato tubers and leaves.

A characterized repetitive sequence from Phytophthora infestans (P. infestans) was used to perform a PCR with the DNA from the four races 1, 3, 4, and 1-11. To obtain amplifiable DNA, all extractions had to be purified by DNA adsorbing spin columns. Only two out of four tested primers were well suited and gave an DNA amplificate of the same size for all four races. After optimization the detection limit of the PCR corresponded to 100 ng of freeze-dried mycelia per ml, specificity was established when testing a collection of the most important potato pathogenic fungi and bacteria. Using P. infestans zoospores to infect tuber slices, the detection threshold was determined to be two days post infection when 3 to 6 zoospores were applied. After infiltrating the tenfold concentration into potato leaves a visible PCR signal was obtained one day post infection. Further improvements of the sensitivity threshold in detecting P. infestans for breeding and prognosis purposes are discussed.

Cloning determinants of pathogenesis from Pseudomonas syringae pathovar syringae.

Transposon mutagenesis and a cosmid genomic library of DNA from the bean pathogen Pseudomonas syringae pathovar syringae were used to identify and isolate sequences essential for pathogenesis. Strain PS9021, derived by Tn5 mutagenesis, was determined to be nonpathogenic on Phaseolus vulgaris cultivar Red Mexican and incapable of inducing a hypersensitive response in Nicotiana tabacum. This mutant also produced fluidal rather than firm colonies on selected agar media. A Tn5-containing EcoRI fragment from PS9021 was cloned and used to probe 1500 members of a genomic library constructed with DNA from the pathogenic parent strain and the wide host range cosmid pVK102. One member that hybridized to the probe contained a cosmid with a 30-kilobase-pair insert (pOSU3101) that complemented the mutant phenotypes when mobilized into PS9021. A restriction endonuclease cleavage site map of pOSU3101 was constructed and sequences essential for pathogenesis were determined by subcloning. Approximately 8.5 kilobase pairs of the insert were essential for restoration by complementation of pathogenesis and hypersensitive response and wild-type colony morphology in strain PS9021.

Evaluation of the efficiency of extraction for the quantitative estimation of hydrogen bacteria in soil.

The efficiency of extraction of hydrogen bacteria from soil for plate counting was evaluated by using pure cultures adsorbed to sterilized soil. The utilization of model materials which interact with bacteria by adhesive, capillary or electrostatic forces and the use of extraction fluids with buffering, detergent or chelating activity demonstrated the major importance of capillary forces for the retention of hydrogen bacteria. Utilization of Tris buffer (pH 7.5) as extraction fluid and separation of extracted bacteria from soil particles by sedimentation for 15 min resulted in the highest recovery. A second extraction step including sonication did not increase the efficiency. The extraction efficiency of 8 different strains of hydrogen bacteria adsorbed to 3 different soils demonstrated a high degree of variation wih respect to bacterial strains, but not to soil types. The recovery was inversely related to cell parameters such as size, motility and slime formation.