Determination of mannitol in ectomycorrhizal fungi and ectomycorrhizas by enzymatic micro-assays

Two sensitive methods for the enzymatic determination of mannitol are described which were applied to fungal and mycorrhizal extracts. Both methods are based on the oxidation of mannitol by mannitol dehydrogenase from Agaricus hortensis and the fluorometric determination of the NADPH produced in this reaction. The detection limits are 125 pmol for the direct fluorometric assay and 100 fmol, when enzymatic cycling of NADPH is included. The levels of mannitol detected were 123 pmol/g dry wt (mycelia from Cenococcum geophilum, cultivated on malt medium), below 0.3 or about 2.4 pmol/g dry wt (mycelia from Amanita muscaria, dependent on carbon source in the cultivation medium), and between 1.9 and 5.2 pmol/g dry wt in mycorrhizal short roots of Picea abies/Amanita muscaria.     

Carbon and nitrogen fluxes between beech and their ectomycorrhizal assemblage

To determine the exchange of nitrogen and carbon between ectomycorrhiza and host plant, young beech (Fagus sylvatica) trees from natural regeneration in intact soil cores were labelled for one growing season in a greenhouse with ¹³CO₂ and ¹⁵NO₃ ¹⁵NH₄. The specific enrichments of ¹⁵N and ¹³C were higher in ectomycorrhizas (EMs) than in any other tissue. The enrichments of ¹³C and ¹⁵N were also higher in the fine-root segments directly connected with the EM (mainly second-order roots) than that in bulk fine or coarse roots. A strict, positive correlation was found between the specific ¹⁵N enrichment in EM and the attached second-order roots. This finding indicates that strong N accumulators provide more N to their host than low N accumulators. A significant correlation was also found for the specific ¹³C enrichment in EM and the attached second-order roots. However, the specific enrichments for ¹⁵N and ¹³C in EM were unrelated showing that under long-term conditions, C and N exchange between host and EMs are uncoupled. These findings suggest that EM-mediated N flux to the plant is not the main control on carbon flux to the fungus, probably because EMs provide many different services to their hosts in addition to N provision in their natural assemblages.     

Acclimation to temperature and temperature sensitivity of metabolism by ectomycorrhizal fungi

Ectomycorrhizal (ECM) fungi contribute significantly to ecosystem respiration, but little research has addressed the effect of temperature on ECM fungal respiration. Some plants have the ability to acclimate to temperature such that long‐term exposure to warmer conditions slows respiration at a given measurement temperature and long‐term exposure to cooler conditions increases respiration at a given measurement temperature. We examined acclimation to temperature and temperature sensitivity (Q₁₀) of respiration by ECM fungi by incubating them for a week at one of three temperatures and measuring respiration over a range of temperatures. Among the 12 ECM fungal isolates that were tested, Suillus intermedius, Cenococcum geophilum, and Lactarius cf. pubescens exhibited significant acclimation to temperature, exhibiting an average reduction in respiration of 20–45% when incubated at 23 °C compared with when incubated at 11 or 17 °C. The isolates differed significantly in their Q₁₀ values, which ranged from 1.67 to 2.56. We also found that half of the isolates significantly increased Q₁₀ with an increase in incubator temperature by an average of 15%. We conclude that substantial variation exists among ECM fungal isolates in their ability to acclimate to temperature and in their sensitivity to temperature. As soil temperatures increase, ECM fungi that acclimate may require less carbon from their host plants than fungi that do not acclimate. The ability of some ECM fungi to acclimate may partially ameliorate the anticipated positive feedback between soil respiration and temperature.     

Tissue density and growth response of ectomycorrhizal fungi to nitrogen source and concentration

 Amanita rubescens Pers., Lactarius affinis Pk., Leccinum aurantiacum (Fr.) S.F. Gray, Tylopilus felleus (Bull. ex Fe.) Karsten, and two isolates of Suillus intermedius (Smith & Thiers) Smith & Thiers collected from an approximately 55-year-old Pinus resinosa Ait. plantation, and Pisolithus tinctorius (Pers.) Coker & Couch obtained from another source, were tested for their abilities to grow with protein as the primary source of nitrogen. Protein plates contained 63 mg l^–1 N as bovine serum albumen and 7 mg l^–1 N as arginine. Control plates contained only 7 mg l^–1 N as arginine. All isolates except Leccinum aurantiacum and one isolate of S. intermedius attained greater dry weight with protein as the primary source of N. Lactarius affinis, Leccinum aurantiacum, P. tinctorius, and both isolates of S. intermedius had higher tissue densities on protein medium. Amanita rubescens had lower tissue density. To determine if increase in tissue density was an effect of total N concentration or an effect of N source (protein versus arginine), we performed a second experiment in which arginine concentration was increased (7 mg l^–1 N versus 70 mg l^–1 N). The second experiment also included Cenococcum geophilum Fr. but excluded T. felleus. Higher tissue densities with increased nutrients were found in C. geophilum, Lactarius affinis, Leccinum aurantiacum, and both isolates of S. intermedius. Only A. rubescens and P. tinctorius did not have increased densities. The results suggest that these ectomycorrhizal fungi alter their growth forms according to N concentration. At low N concentrations, a growth form likely to promote exploitation of a large volume of medium for a given biomass is produced. At high concentrations, a growth form likely to promote exploitation of a rich source of N is produced. Whether ectomycorrhizal fungi growing in association with roots would act in a similar fashion is not known. Accepted: 30 July 1998     

Plasticity and constraint in growth and protein mineralization of ectomycorrhizal fungi under simulated nitrogen deposition

Ectomycorrhizal fungi allow their host plants access to organic forms of N through enzymatic mineralization of the substrate and enhanced absorption of amino acids and mineral N. The cost to the plant is carbohydrates that support fungal growth and metabolism. Enrichment of soils with mineral N, as through atmospheric deposition, may affect the growth and function of these fungi by direct effects of increased N availability on fungi and indirect effects through reduced plant C allocation to roots. We tested the potential of N enrichment and altered carbohydrate supply to affect the growth and protein mineralization activity of 10 ectomycorrhizal fungi in sterile liquid media. Nitrogen treatments consisted of organic N only vs organic plus mineral N. Carbon treatments consisted of 5 g per liter glucose vs. no glucose added. Fungi differed widely in their growth and mineralization responses to these variables. Seven of 10 fungi had at least 20% reduced growth with reduced carbohydrates. Only 2 of 10 increased growth by 20% or more with increased mineral N. Carbohydrates affected growth more in a purely organic N environment suggesting an energy limitation to mineralization. Protein mineralization activity tended to be depressed by reductions in carbohydrates and increased by increased mineral N. The high sensitivity of fungal growth to carbohydrates suggests important indirect effects of N enrichment via altered C allocation in host trees. Principal Components analysis separated most fungal species along an axis representing a gradient from high protein mineralization efficiency to high intrinsic growth rate. Those fungi with slow growth and efficient mineralization activity corresponded closely to fungi often cited as late successional species, while fungi with high growth rates and low mineralization efficiency are often categorized as early successional. One fungus, Cenococcum geophillum, separated from others on an axis representing strong N dependence in growth. Nitrogen enrichment has the potential to alter the composition and function of the ectomycorrhizal fungus community. Physiological differences among species provide a starting point for predicting community responses and anticipating ecosystem consequences.     

Insights into nitrogen and carbon dynamics of ectomycorrhizal and saprotrophic fungi from isotopic evidence

The successful use of natural abundances of carbon (C) and nitrogen (N) isotopes in the study of ecosystem dynamics suggests that isotopic measurements could yield new insights into the role of fungi in nitrogen and carbon cycling. Sporocarps of mycorrhizal and saprotrophic fungi, vegetation, and soils were collected in young, deciduous-dominated sites and older, coniferous-dominated sites along a successional sequence at Glacier Bay National Park, Alaska. Mycorrhizal fungi had consistently higher δ¹⁵N and lower δ¹³C values than saprotrophic fungi. Foliar δ¹³C values were always isotopically depleted relative to both fungal types. Foliar δ¹⁵N values were usually, but not always, more depleted than those in saprotrophic fungi, and were consistently more depleted than in mycorrhizal fungi. We hypothesize that an apparent isotopic fractionation by mycorrhizal fungi during the transfer of nitrogen to plants may be attributed to enzymatic reactions within the fungi producing isotopically depleted amino acids, which are subsequently passed on to plant symbionts. An increasing difference between soil mineral nitrogen δ¹⁵N and foliar δ¹⁵N in later succession might therefore be a consequence of greater reliance on mycorrhizal symbionts for nitrogen supply under nitrogen-limited conditions. Carbon signatures of mycorrhizal fungi may be more enriched than those of foliage because the fungi use isotopically enriched photosynthate such as simple sugars, in contrast to the mixture of compounds present in leaves. In addition, some ¹³C fractionation may occur during transport processes from leaves to roots, and during fungal chitin biosynthesis. Stable isotopes have the potential to help clarify the role of fungi in ecosystem processes. Received: 7 January 1998 / Accepted: 9 November 1998     

Ammonium and methylamine transport by the ectomycorrhizal fungus Paxillus involutus and ectomycorrhizas

Using [(14)C]methylamine as an analogue of ammonium, the kinetics and the energetics of NH(4)(+) transport were studied in the ectomycorrhizal fungus, Paxillus involutus (Batsch) Fr. The apparent half-saturation constant (K(m)) and the maximum uptake rate (V(max)) for the carrier-mediated transport derived from the Eadie-Hofstee transformation were 180 μM and 380 nmol (mg dry wt)(-1) min(-1,) respectively. Both pH dependence and inhibition by protonophores indicate that methylamine transport in P. involutus was dependent on the electrochemical H(+) gradient. Both long-term and short-term uptake experiments were consistent with regulation of ammonium/methylamine transport processes by the presence of an organic nitrogen source. Analysis of methylamine uptake by different P. involutus isolates revealed no obvious trend in the uptake capacities in relation to N deposition at the collection site. Kinetic parameters were determined in P. involutus/Betula pendula (Roth.) axenic association and in detached mycorrhizal roots isolated from forest sites. Enhanced methylamine uptake in the presence of the fungal symbiont was demonstrated. Homogeneous V(max) values were found for axenic and detached mycorrhizas, whereas K(m) values showed greater variations.     

Phosphorus-31 nuclear magnetic resonance study of polyphosphate metabolism in intact ectomycorrhizal fungi

Summary Phosphorus-31 nuclear magnetic resonance spectra at 36.4 MHz are presented for intact ectomycorrhizal fungi grown in pure culture. Resonances from polyphosphates and intracellular orthophosphate are identified inCenococcum graniforme, Hebeloma cylindrosporum, andH. crustuliniforme. Comparison of the NMR spectra with phosphorus fractionation of the fungi extracts leads to the statement that the NMR-observed polyphosphaes is a good part of the accumulated polyphosphates. In actively growing mycelia, this fraction account for up to 17% of total P.     

Interactions between mammals and ectomycorrhizal fungi

Many ectomycorrhizal (ECM) fungi produce fruit-bodies below ground and rely on animals, especially mammals, for dispersal of spores. Mammals may therefore play an important role in the maintenance of mycorrhizal symbiosis and biodiversity of ECM fungi in many forest ecosystems. Given the pivotal role played by mycorrhizal fungi In the nutrition of their plant hosts and, possibly, in the determination of plant community structure, the ecological significance of mycophagous mammals may extend to the productivity and diversity of plant communities. Mycologists and mammalogists have been aware of the interaction between their study organisms for many years, but recent research has produced new insights Into the evolution of mammal-vectored spore dispersal among ECM fungi, the ecological importance of mycophagy to small mammals, and the effectiveness of mammals as spore-dispersal agents.     

Pelagic Sargassum community metabolism: Carbon and nitrogen

The production, nitrogen fixation, and release rates and fate of dissolved organic matter of a pelagic Sargassum community have been investigated at eight stations in the Gulf Stream and the Sargasso Sea. Net production and gross nitrogen fixation rates of Sargassum and epiphytes varied significantly between stations, 328 ± 114μg C (g dry wt)^?1h^?1 and 18 ± 7.4μg N g^?1h^?1, respectively. The net release rates of dissolved organic carbon (287 ± 150μg DOC g^?1h^?1) also showed the same variability between stations. On the other hand, the community carbon and nitrogen content, 268 ± 4.8 and 16.9 ± 2.4 mg g dry wt^?1, respectively, remained constant at all stations. The results of chemical measurements indicate that ≈ 0–50 % of the gross production was lost as a result of photosynthate release. From ¹⁴C-tracer experiments it was found that the planktonic and epiphytic heterotrophs mineralized 50–70 % of the photosynthate released by Sargassum and epiphytic algae. Based on the community gross production and fixation rates, carbon and nitrogen content, the amount of nitrogen required for the observed production rates, the Sargassum community appears to obtain a substantial part (40%) of its nitrogen from nitrogen fixation.     

Effect of ectomycorrhizal fungi on nitrogen mineralisation and the growth of Scots pine seedlings in natural peat

The aim of this study was to investigate the potential of different isolates of ectomycorrhizal (EM) fungi to enhance the growth of Pinus sylvestris seedlings in five natural peat substrates with different nitrogen concentrations, and the effect of the Scots pine seedlings and fungal inoculum on the formation of dissolved inorganic and organic nitrogen in peat. Utilization of different organic nitrogen compounds by microbial community in the peat was also investigated using Biolog MT MicroPlates. Inoculation of the seedlings with EM fungi enhanced seedling growth. Piloderma croceum increased root growth especially, whereas Lactarius rufus increased needle growth and Suillus variegatus I, II and III improved both root and needle growth. All the EM fungi also significantly affected stem growth. Nitrogen concentration of the peat did not affect seedling growth as much as the EM fungi. At the lowest peat N concentration (1.17%) NH ₄ ⁺ mineralisation was lower and DON (dissolved organic nitrogen) accumulation higher than at higher peat N concentrations. The EM fungal isolates had different effects on NH ₄ ⁺ and DON accumulation/degradation in peat. The EM fungal isolates significantly increased NH ₄ ⁺ formation in the peat, whereas L. rufus and P. croceum had an opposite effect on DON accumulation. S. variegatus I significantly decreased the DON concentrations during peat incubation. The N concentration of the peat slightly affected the utilization of amino acids and polyamines by the microbial community, whereas inoculation with S. variegatus I, II or III had no effect.     

Effect of organic and inorganic nitrogen sources on endogenous polyamines and growth of ectomycorrhizal fungi in pure culture

 The abilities of three ectomycorrhizal fungi, Paxillus involutus, Suillus variegatus and Lactarius rufus, to utilize organic and inorganic nitrogen sources were determined by measuring the growth and endogenous free polyamines (putrescine, spermidine and spermine) of pure culture mycelium. Differences were found in the utilization of the nitrogen sources and in the polyamine concentrations between the fungal species and between isolates of L. rufus. All the fungi grew well on ammonium and on several amino acids. Endogenous polyamine levels varied with the nitrogen source. Spermidine was commonly the most abundant polyamine; however, more putrescine than spermidine was found in P. involutus growing on inorganic nitrogen or arginine. Low amounts of spermine were found in S. variegatus and some samples of L. rufus. None or only a trace of spermine was found in P. involutus mycelium. In all fungi, putrescine concentrations were higher with ammonium than with the nitrate treatment. The total nitrogen content of peat did not determine the ability of L. rufus strains isolated from peatland forest sites to utilize organic nitrogen. Accepted: 27 November 1998     

Towards management of invasive ectomycorrhizal fungi

Ectomycorrhizal fungi are increasingly recognized as invasive species. Invasive ectomycorrhizal fungi can be toxic to humans, may compete with native, edible or otherwise valuable fungi, facilitate the co-invasion of trees, and cause major changes in soil ecosystems, but also have positive effects, enabling plantation forestry and, in some cases, becoming a valuable food source. Land-managers are interested in controlling and removing invasive fungi, but there are few available strategies for management and none are based on robust scientific evidence. Nonetheless, despite the absence of relevant experiments, we suggest that knowledge of the fundamental ecology of fungi can help guide strategies. We review the literature and suggest potential strategies for prevention, for slowing the spread of invasive fungi, for eradication, and for long-term management. In many cases the most appropriate strategy will be species and context (including country) specific. In order to effectively address the problems posed by invasive ectomycorrhizal fungi, land managers and scientists need to work together to develop and robustly test control and management strategies.     

Carbon and nitrogen metabolism regulated by the ubiquitin-proteasome system

The ubiquitin-proteasome system (UPS) is a unique protein degradation mechanism conserved in the eukaryotic cell. In addition to the control of protein quality, UPS regulates diverse cellular signal transduction via the fine-tuning of target protein degradation. Protein ubiquitylation and subsequent degradation by the 26S proteasome are involved in almost all aspects of plant growth and development and response to biotic and abiotic stresses. Recent studies reveal that the UPS plays an essential role in adaptation to carbon and nitrogen availability in plants. Here we highlight ubiquitin ligase ATL31 and the homologue ATL6 target 14-3-3 proteins for ubiquitylation to be degraded, which control signaling for carbon and nitrogen metabolisms and C/N balance response. We also give an overview of the UPS function involved in carbon and nitrogen metabolisms.