Temperature-respiration relationships differ in mycorrhizal and non-mycorrhizal root systems of Picea abies (L.) Karst.

Root respiration has been shown to increase with temperature, but less is known about how this relationship is affected by the fungal partner in mycorrhizal root systems. In order to test respiratory temperature dependence, in particular Q (10) of mycorrhizal and non-mycorrhizal root systems, seedlings of PICEA ABIES (L.) Karst. (Norway spruce) were inoculated with the ectomycorrhizal fungus PILODERMA CROCEUM (Eriksson and Hjortstam, SR430; synonym: PILODERMA FALLAX: [Libert] Stalpers) and planted in soil respiration cuvettes (mycocosms). Temperature dependence of hyphal respiration in sterile cultures was determined and compared with respiration of mycorrhizal roots. Respiration rates of mycorrhizal and non-mycorrhizal root systems as well as sterile cultures were sensitive to temperature. Q (10) of mycorrhizal root systems of 3.0 +/- 0.1 was significantly higher than that of non-mycorrhizal systems (2.5 +/- 0.2). Q (10) of P. CROCEUM in sterile cultures (older than 2 months) was similar to that of mycorrhizal root systems, suggesting that mycorrhizae may have a large influence on the temperature sensitivity of roots in spite of their small biomass. Our results stress the importance of considering mycorrhization when modeling the temperature sensitivity of spruce roots.

An overview on bioaerosols viewed by scanning electron microscopy.

Bioaerosols suspended in ambient air were collected with single-stage impactors at a semiurban site in southern Germany during late summer and early autumn. Sampling was mostly carried out at a nozzle velocity of 35 m/s, corresponding to a minimum aerodynamic diameter (cut-off diameter) of aerosol particles of 0.8 mum. The collected particles, sampled for short periods ( approximately 15 min) to avoid pile-up, were characterized by scanning electron microscopy (SEM). The observed bioaerosols include brochosomes, fungal spores, hyphae, insect scales, hairs of plants and, less commonly, bacteria and epicuticular wax. Brochosomes, which serve as a highly water repellent body coating of leafhoppers, are hollow spheroids with diameters around 400 nm, resembling C(60) or footballs (soccer balls). They are usually airborne not as individuals but in the form of large clusters containing up to 10,000 individual species or even more. Various types of spores and scales were observed, but assignment turned out be difficult due to the large number of fungi and insects from which they may have originated. Pollens were observed only once. The absence these presumably elastic particles suggests that they are frequently lost, at the comparatively high velocities, due to bounce-off from the nonadhesive impaction surfaces.

The plant's capacity in regulating resource demand.

Regulation of resource allocation in plants is the key to integrate understanding of metabolism and resource flux across the whole plant. The challenge is to understand trade-offs as plants balance allocation between different and conflicting demands, e.g., for staying competitive with neighbours and ensuring defence against parasites. Related hypothesis evaluation can, however, produce equivocal results. Overcoming deficits in understanding underlying mechanisms is achieved through integrated experimentation and modelling the various spatio-temporal scaling levels, from genetic control and cell metabolism towards resource flux at the stand level. An integrated, interdisciplinary research concept on herbaceous and woody plants and its outcome to date are used, while drawing attention to currently available knowledge. This assessment is based on resource allocation as driven through plant-pathogen and plant-mycorrhizosphere interaction, as well as competition with neighbouring plants in stands, conceiving such biotic interactions as a "unity" in the control of allocation. Biotic interaction may diminish or foster effects of abiotic stress on allocation, as changes in allocation do not necessarily result from metabolic re-adjustment but may obey allometric rules during ontogeny. Focus is required on host-pathogen interaction under variable resource supply and disturbance, including effects of competition and mycorrhization. Cost/benefit relationships in balancing resource investments versus gains turned out to be fundamental in quantifying competitiveness when related to the space, which is subject to competitive resource exploitation. A space-related view of defence as a form of prevention of decline in competitiveness may promote conversion of resource turnover across the different kinds of biotic interaction, given their capacity in jointly controlling whole plant resource allocation.

Calibration of quantitative real-time TaqMan PCR by correlation with hyphal biomass and ITS copies in mycelia of Piloderma croceum.

DNA-based quantification methods such as real-time TaqMan PCR allow a rapid and highly sensitive species-specific quantification of isolated fungal DNA material, but most quantification systems are only able to measure relative amounts of biomass or biomass changes during different treatments. In this experiment, an already established DNA quantification system for the ectomycorrhizal fungus Piloderma croceum, based on the ITS region of ribosomal DNA, was calibrated to absolute biomass to obtain a direct correlation between mycelial biomass and isolated ITS copies. Thin layers of sterile mycelia were cultured on slides. The mycelial biomass was calculated from measurements of the total hyphal length using image analysis, followed by determination of the mycelial volume, and multiplied by the specific weight of hyphae obtained from literature data. Using the very same mycelium, the number of ITS copies was quantified by TaqMan PCR. The mean value of 1047 (+/- 185) copies per mm hypha results in possible data for a direct conversion: one billion (10 (9)) ITS copies corresponded to 0.79 mg hyphal dry weight. For the ribosomal ITS multi-copy genes, the number of ITS copies could be calculated to approx. 152 (+/- 26) copies per dikaryotic cell. These conversion data now allow determination of the mycelial biomass of Piloderma croceum using real-time TaqMan PCR, a prerequisite for competition experiments with Piloderma croceum.

Morphological-anatomical characterization and molecular identification of Tomentella stuposa ectomycorrhizae and related anatomotypes.

Species in the genus Tomentella (Thelephoraceae) belong to the most frequent and widespread ectomycorrhizal (EM) fungi found in temperate and boreal forests. Although several unidentified tomentelloid morphotypes have been presented as common members of EM communities in coniferous and broad-leaved forests, few tomentelloid EM have been identified and described in detail. In this study, ten tomentelloid EM isolates collected from Populus alba, Quercus cerris and Picea abies stands in Hungary and Germany are characterized and documented by morphological-anatomical methods using light microscopy. The investigated ectomycorrhizae belong to the same brown-black tomentelloid morphotype but form two different anatomotype groups (At I and At II). Molecular taxonomical identification was accomplished using phylogenetic analysis (neighbor joining method) of 49 Tomentella nrDNA-ITS nucleotide sequences including the 10 new and 39 GenBank sequences. The EM isolates clustered into two adjoining clades identical with the two anatomotypes. At II clustered with Tomentella stuposa while At I could not be identified to species. Based on the morphological similarity and the low genetic difference it must be a closely related taxon. A comparison of the recently known tomentelloid EM to T. stuposa is presented. Ecological questions involving abundance and host relationships are discussed.

A rapid and highly sensitive method for measuring enzyme activities in single mycorrhizal tips using 4-methylumbelliferone-labelled fluorogenic substrates in a microplate system.

A microplate fluorimetric assay was developed for measuring potential activities of extracellular enzymes of individual ectomycorrhizal (EM) roots using methylumbelliferone (MU)-labelled fluorescent substrate analogues and microsieves to minimise damage due to manipulation of excised mycorrhizal roots. Control experiments revealed that enzyme activities remained stable over the whole time of the experiment suggesting a strong affinity of the studied enzymes to the fungal cell walls. The same mycorrhizal tips thus could be used repeatedly for enzyme detection and subsequently analysed for the projection area by automated image analysis. The developed system was evaluated on four different EM species measuring pH optimum and substrate saturation of phosphatase, chitinase and beta-glucosidase. The four EM species studied were Lactarius subdulcis, Russula ochroleuca, Cortinarius obtusus and Xerocomus cf. chrysenteron. Depending upon the enzyme, each species exhibited different levels of enzymatic activities as well as enzyme kinetics and showed also differences in pH optima.

[Classification of Fungi in modern view]. / Das System der Pilze aus neuerer Sicht.

Fungi are a heterogeneous jumble coming together from three kingdoms of organisms. The True Fungi represent a kingdom of its own and are positioned closer to the Animalia than to the Plantae. At present the Fungi are divided into five Divisions. Species pathogenic for humans are found in the Divisions Zygomycota, Ascomycota and Basidiomycota. The Pneumocystidales are now classified in the Ascomycota. The Malasseziales are included in the Class Ustilaginomycetes. Essential characteristics for the classification of Fungi are derived from ultrastructure, chemistry, and more recently also from molecular biology of these organisms. None of these methods can stand for its own, all characteristics must be included.