Hans-Volker Tichy

Impact of 2,4-Diacetylphloroglucinol-Producing Biocontrol Strain Pseudomonas fluorescens F113 on Intraspecific Diversity of Resident Culturable Fluorescent Pseudomonads Associated with the Roots of Field-Grown Sugar Beet Seedlings

ABSTRACT The impact of the 2,4-diacetylphloroglucinol-producing biocontrol agent Pseudomonas fluorescens F113Rif on the diversity of the resident community of culturable fluorescent pseudomonads associated with the roots of field-grown sugar beet seedlings was evaluated. At 19 days after sowing, the seed inoculant F113Rif had replaced some of the resident culturable fluorescent pseudomonads at the rhizoplane but had no effect on the number of these bacteria in the rhizosphere. A total of 498 isolates of resident fluorescent pseudomonads were obtained and characterized by molecular means at the level of broad phylogenetic groups (by amplified ribosomal DNA restriction analysis) and at the strain level (with random amplified polymorphic DNA markers) as well as phenotypically (55 physiological tests). The introduced pseudomonad induced a major shift in the composition of the resident culturable fluorescentPseudomonas community, as the percentage of rhizoplane isolates capable of growing on three carbon substrates (erythritol, adonitol, and l-tryptophan) not assimilated by the inoculant was increased from less than 10% to more than 40%. However, the pseudomonads selected did not display enhanced resistance to 2,4-diacetylphloroglucinol. The shift in the resident populations, which was spatially limited to the surface of the root (i.e., the rhizoplane), took place without affecting the relative proportions of phylogenetic groups or the high level of strain diversity of the resident culturable fluorescent Pseudomonas community. These results suggest that the root-associatedPseudomonas community of sugar beet seedlings is resilient to the perturbation that may be caused by a taxonomically related inoculant.

A polyphasic taxonomy of Daldinia (Xylariaceae)

For a monograph based on a polythetic concept, several thousands of herbarium specimens, and several hundreds of freshly collected and cultured specimens of Daldinia and allied Xylariaceae, originating from around the world, were studied for morphological traits, including by SEM, and chemically by HPLC profiles using UV-visible and mass spectrometric detection. Emphasis was given to tropical material, and importantly, ancient specimens, including as many types as possible, were tracked and studied to review earlier taxonomic concepts. An epitype of D. eschscholtzii was selected as representative of the morphochemotype that is most widely distributed in the tropics. Six new species of Daldinia from the tropics and the southern Hemisphere are described. Daldinia asphalatum is resurrected, and D. cudonia is regarded as its synonym. In addition, the following binomials are epi-, iso-, neo- and/or lectotypified: Daldinia asphalatum, D. caldariorum, D. clavata, D. cuprea, D. durissima, D. eschscholtzii, D. grandis, D. loculata, and D. vernicosa. Annellosporium and Versiomyces are regarded as synonyms of Daldinia. Many new synonymies in Daldinia are proposed, and some previously published names are rejected. In total, 47 taxa in Daldinia are recognised and a key is provided. Their biogeography, chorology, and ecology, as well as the importance of their secondary metabolites, are also discussed. The previous definition of the genus is emended. The species concept is based mainly on morphological and other phenotype-derived characters because, despite diligent search, no molecular data or cultures of several of the accepted species could be obtained. Daldinia is segregated into five major groups, based on phenotypic characteristics. Some unnamed but aberrant specimens were not found in good condition and are therefore not formally described as new species. However, they are illustrated in detail in a hope that this will facilitate the discovery of fresh material in future. A preliminary molecular phylogeny based on 5.8S/ITS nrDNA including numerous representatives of all hitherto described taxa for which cultures are extant, was found basically in agreement with the above mentioned segregation of the genus, based on morphological and chemotaxonomic evidence. In the rDNA based phylogenetic tree, Daldinia appears clearly distinct from members of the genera Annulohypoxylon and Hypoxylon; nevertheless, representatives of small genera of predominantly tropical origin (Entonaema, Phylacia, Ruwenzoria, Rhopalostroma, Thamnomyces) appear to have evolved from daldinioid ancestors and are nested inside the Daldinia clade. Interestingly, these findings correlate with chemotaxonomic characters to a great extent, especially regarding the distribution of marker metabolites in their mycelial cultures. Hence, the current study revealed for the first time that fungal secondary metabolite profiles can have taxonomic value beyond the species rank and even coincide with phylogenetic data. Taxonomic novelties: Daldinia andina sp. nov., D. australis sp. nov., D. hausknechtii sp. nov., D. rehmii sp. nov., D. starbaeckii sp. nov., D. theissenii sp. nov., D. cahuchosa comb. nov., D. nemorosa comb. nov.

Molecular chemotaxonomy of Daldinia and other Xylariaceae

In a polyphasic classification approach, stromata and cultures of Daldinia and allied Xylariaceae from around the world were studied for: (1) morphology of teleomorphs and anamorphs; (2) metabolite patterns in stromata and cultures, employing analytical HPLC-UV-visible (diode array) detection and mass spectrometric detection; (3) amplified 18S rDNA restriction patterns (ARDRA); and (4) PCR amplified minisatellite regions. Comparison of type material, herbarium specimens, cultures, and freshly collected material revealed new evidence on their geographic distribution. Several Daldinia spp. were identified in Europe and other locations for the first time. The results point towards the existence of further undescribed species. Stromata of a given species never contained the same major metabolites as corresponding cultures. Most cultures of Daldinia spp. produced naphthalene and chromane derivatives, differing from allied genera by the absence of mellein. Stromata of Daldinia spp. did not produce mitorubrin, but generally contained binaphthyls. Metabolite profiles were correlated with colours of KOH-extractable stromatal pigments. The yellow azaphilones and benzophenones found in D. childiae were lacking in species with purple stromatal pigments. Cytochalasins were found in stromata of D. eschscholzii. Genetic fingerprints helped to distinguish morphologically closely related taxa. ARDRA gave specific results for species whose 18S rDNA contained insertions, while minisatellite PCR provided specific genetic fingerprints. A combination of both PCR based techniques provided a fair resolution of genetic subtypes, reflecting the intrageneric variance in Daldinia as established from morphological data and secondary metabolite profiles.

Chemotaxonomy of Pochonia and other conidial fungi with Verticillium-like anamorphs

Pochonins are antiviral and antiparasitic resorcylic acid lactones (RAL) structurally related to monorden. They were found in the invertebrate-associated fungus Pochonia chlamydosporia. Their production and distribution was studied by means of High Performance Liquid Chromatography with UV-visual and mass spectrometric detection (HPLC-UV/Vis and HPLCMS) in cultures of Pochonia species and further conidial fungi with Verticillium-like anamorphs that had until recently been included in Verticillium sect. Prostrata. The results support the recent generic segregation by Gams, Zare and co-workers because pochonins were found to occur exclusively in species of the genus Pochonia. With few exceptions, the production of RAL appeared to be a rather constant feature in cultures of P. chlamydosporia from around the world. According to preliminary results, secondary metabolite profiles in strains of allied genera such as Lecanicillium, Haptocillium and Rotiferophthora are different from those encountered in Pochonia. The alkaloid pseurotin A was found as main metabolite in several of the P. chlamydosporia isolates examined. As inferred from HPLC profiling data, strains of P. suchlasporia clustered into at least three chemotypes. The ex-type strain of P. suchlasporia var. catenata produced monorden, while several other strains produced metabolites whose HPLC-UV and HPLC-MS characteristics were similar to the mycotoxins, aurovertin B and citreoviridin A. Yet different metabolites were detected in a third chemotype of P. suchlasporia. Differences in secondary metabolite profiles were also found in two strains of P. bulbillosa. While the ex-type strain was found devoid of all aforementioned compounds, CBS 247.68 contained the aurovertin-related metabolites detected in part of the P. suchlasporia isolates. The sequence of the ITS nrDNA of CBS 247.68 was different from that of the type strain but identical to the sequences of P. suchlasporia var. catenata. Several strains of the latter variety showed identical sequences, despite considerable variations in their HPLC metabolite profiles. Minisatellite PCR fingerprinting was found useful to segregate Pochonia at species and strain level, pointing toward the existence of further, cryptic species. The possible chemotaxonomical importance and ecological functions of secondary metabolites in these fungi is discussed.

Recognition of hypoxyloid and xylarioid Entonaema species and allied Xylaria species from a comparison of holomorphic morphology, HPLC profiles, and ribosomal DNA sequences

The genus Entonaema comprises Xylariaceae with hollow, gelatinous stromata that accumulate liquid. Some of its species, including the type species, appear related to Daldinia from a polyphasic approach, comprising morphological studies, comparisons of ribosomal DNA sequences, and high performance liquid chromatography (HPLC) profiles with diode array and mass spectrometric detection (HPLC-DAD-MS). This methodology was used to study Entonaema pallidum. Its major stromatal constituent was identified as xylaral, a secondary metabolite known from Xylaria polymorpha. This compound was detected in several Xylaria spp., including the tropical X. telfairii and morphologically similar taxa, whose stromata may also become hollow and filled with liquid. Cultures of E. pallidum resembled those of Xylaria, substantially differing from other Entonaema spp., in their morphology, 5.8S/ITS nrDNA sequences, and HPLC profiles. The type specimen of E. mesentericum was located in the spirit collection of the herbarium B and found to agree morphologically with the nomenclatorily younger E. pallidum. Traces of xylaral were even detected by HPLC-DAD-MS in the spirit in which the fungus had been preserved. Entonaema pallidum is thus regarded as a later synonym of E. mesentericum. Therefore, the latter name is transferred to Xylaria. A key to entonaemoid Xylariaceae is provided. Colour reactions (NH3, KOH) of the ectostroma were applied to a limited number of Xylaria spp., but metabolite profiles of cultures appear more promising as chemotaxonomic traits to segregate this genus. As xylaral was also found in Nemania and Stilbohypoxylon spp., while being apparently absent in Hypoxylon and allied genera, it may be a chemotaxonomic marker for Xylariaceae with Geniculosporium-like anamorphs.

Residual Impact of the Biocontrol Inoculant Pseudomonas fluorescens F113 on the Resident Population of Rhizobia Nodulating a Red Clover Rotation Crop

A field trial was previously conducted in which sugarbeet seeds were either untreated, inoculated with the biocontrol strain Pseudomonas fluorescens F113Rif, or treated with chemical fungicides. Following harvest of sugarbeet, the field site was sown with uninoculated red clover. The aim of this study was to assess the residual impact of the microbial inoculant (and the fungicide treatment) on the diversity of resident rhizobia nodulating the red clover rotation crop. The percentage of nodules yielding rhizobial isolates after surface disinfection was 67% in the control and 70% in the P. fluorescens F113Rif treatment, but only 23% in the chemical treatment. Isolates were characterized by RAPD analysis. The main RAPD cluster (arbitrarily defined at 70% similarity) was prevalent in all three treatments. In addition, the distribution of RAPD clusters followed a log series model, regardless of the treatment applied, indicating that neither the microbial inoculant nor the fungicide treatment had caused a strong perturbation of the rhizobial population. When the P. fluorescens F113Rif and control treatments were compared using diversity indices, however, it appeared that the genetic diversity of rhizobia was significantly less in the inoculated treatment. The percentage of rhizobia sensitive to 2,4-diacetylphloroglucinol (Phl; the antimicrobial metabolite produced by P. fluorescens F113Rif) fluctuated according to field site heterogeneity, and treatments had no effect on this percentage. Yet, the proportion of Phl-sensitive isolates in the main RAPD cluster was lower in the P. fluorescens F113Rif treatment compared with the control, raising the possibility that the residual impact of the inoculant could have been partly mediated by production of Phl. This impact on the rhizobial population took place without affecting the functioning of the Rhizobium–clover symbiosis.

Cryptic species related to Daldinia concentrica and D. eschscholzii, with notes on D. bakeri.

Daldinia macaronesica (from the Canary Islands and Madeira), D. palmensis (from the Canary Islands), D. martinii and D. raimundi (from Sicily), and D. vanderguchtiae (from Jersey, Channel Islands) spp. nov., are described, based on new combinations of teleomorphic and anamorphic characters. They all resemble the pantropical D. eschscholzii and/or the European D. concentrica with regard to teleomorphic characters and secondary metabolite profiles generated by analytical HPLC. The status of the newly described taxa was established by SEM of ascospores and microscopic studies of their anamorphs in comparison with various materials of the aforementioned known species. HPLC and SEM studies on the holotype of D. bakeri confirmed its relationships to D. fissa and D. loculata. Yellowish pigments contained in the type specimen of D. bakeri are probably artificial.

Comparative strain typing of Rhizobium leguminosarum bv. viciae natural populations

372 natural isolates of Rhizobium leguminosarum bv. viciae, rescued from nodules of pea plants grown in an agricultural field in northern Italy, were analyzed by different methods. Three DNA-based fingerprinting techniques were lined up to compare their relative degree of resolution and possible advantages of each approach. The methods included (i) Eckhardt gel plasmid profiles, (ii) pulsed-field gel electrophoresis (PFGE) of genomic large fragment digests, and (iii) random amplified polymorphic DNA (RAPD) profiles, generated with arbitrary primers. The scheme also involved the isolation of a number of different isolates per nodule to estimate the level of intra-nodular variability. It was therefore possible to evaluate the frequency of double and multiple occupancies, and the proportion of the alternative profiles sharing the same nodule, generally resulting in a numerically dominant, main representative accompanied by a secondary one with a slightly different fingerprint. This finding revealed that the different profiles within a nodule are normally due to bacteria derived from the same single invader following genetic alterations possibly occurred during infection, e.g., by plasmid loss. The analysis of 31 nodules revealed 16 different patterns, representing the most frequently occurring nodulation-proficient isolates of the natural soil examined, five of which were found with frequencies around 15%. The sensitivity of the methods in differentiating isolates was compared. The relatedness of the different natural rhizobial isolates was investigated by densitometrical gel analysis of the fingerprints, allowing a comparison of the results. One of the most interesting conclusions was that the degree of information yielded by the plasmid gel profiling alone, carried out by simple visual inspection without software-aided analyses, was surprisingly high, as it enabled a placement of the isolates, whose accuracy, in terms of relatedness, was subsequently confirmed by each of the two genomic methods.