Solveig Tosi

Fungi isolated from Antarctic mosses

Abstract. Microfungi were isolated from different moss species in Victoria Land. Twenty-eight taxa belonging to 18 genera were identified. New records for continental Antarctica were: Arthrobotrys superba, Conidiobolus sp., Penicillium minioluteum, Verticillium psalliotae and V. lamellicola. The most frequently isolated fungal species were: Cladosporium cladosporioides, Cryptococcus albidus, Cryptococcus laurentii, Geomyces pannorum var. pannorum, G. pannorum var. vinaceus, Mortierella antarctica, Cadophora malorum, Phoma herbarum and V. lecanii. Bryum pseudotriquetrum was the moss richest in fungal species. Within the Antarctic environment, moss is one of the microhabitats richest in microfungi, particularly in psychrophilic indigenous species.

In vitro evaluation of nematophagous activity of fungal isolates

Four filamentous fungi associated with nematodes were isolated and identified from litter samples collected in the Integral Natural Reserve “Bosco Siro Negri” (PV, Italy): Arthrobotrys dactyloides, Arthrobotrys oligospora var. oligospora, Pochonia bulbillosa, and Pochonia chlamydosporia var. catenulata. Their capacity to break down the nematode population was evaluated in vitro by means of simple and reproducible multiwell plates method. All fungal strains were able to cause a death‐rate significantly different from the controls (p < 0.05). Precisely, A. dactyloides caused, on average, a 26% death rate increase in the nematode population compared to the control, A. oligospora var. oligospora 25%, P. bulbillosa 12%, and P. chlamidosporia var. catenulata 17%. The method has also allowed to determine the more active fungi as regards the preys life cycle stage. The most active strains against nematodes (adults) were A. dactyloides and A. oligospora var. oligospora, known to attack adults or larval stages by means of tridimensional traps. On the contrary P. bulbillosa and P. chlamydosporia, known to attack mainly the nematode life stage of cysts, showed lower activity against adult nematodes.

Growth temperature preferences of fungal strains from Victoria Land, Antarctica

Thirty-five strains of microfungi, isolated from various sites in Victoria Land, Antarctica, were grown at eight temperatures ranging from 0 to 45°C. Only 1 strain (Chaetomium sp. from hot soil) was a thermotolerant mesophile; other strains were psychrophilic (2 strains) or psychrotrophic (32 strains). The fitness of different species to thermal instability is discussed, based on the width of the growth rate curves.

Response of Antarctic soil fungal assemblages to experimental warming and reduction of UV radiation

This paper reports the effects of nutrient availability, UV radiation and temperature on the taxa composition and abundance of Antarctic soil mycobiota. Two sites at Edmonson Point were studied: the first was poor in nutrients, near the glacier, and the second was close to bird nesting sites. The highest abundance of soil fungi was recorded at the site adjacent to the bird nesting sites. Phoma herbarum was the most abundant taxon. Lecytophora lignicola and Ascotricha erinacea are new records for continental Antarctica. The fungal assemblage from the nutrient-deficient site was characterized by a dominance-diversity curve approaching the broken-stick model, the assemblage from the soil influenced by birds was characterized by a lognormal distribution. Plastic cloches were used in experiments designed to assess differences in fungal assemblages subjected to altered temperature and/or UV exposure. Dominance-diversity curves and diversity values of soil fungal mycobiota were compared in their natural condition as compared with manipulated conditions. Under the walled cloches, at both sites, artificial warming led to stress on Antarctic soil fungal assemblages. In contrast, UV protection led to a higher equilibrium in the assemblage structure. On the basis of the results obtained, it could be proposed that UV radiation is the most important limiting ecological factor for soil mycobiota in continental Antarctica.

Evaluating the survival and environmental fate of the biocontrol agent Trichoderma atroviride SC1 in vineyards in northern Italy.

Aims:  To study the survival in the soil and the dispersion in the environment of Trichoderma atroviride SC1 after soil applications in a vineyard.

Biodiversity, evolution and adaptation of fungi in extreme environments

Fungi play irreplaceable roles for ecosystem functioning. They may adopt different lifestyles, for example saprotrophs, symbionts or parasites: some species are cosmopolitan with a wide distribution and others, thanks to their ecological plasticity, may adapt to harsh environments precluded to most of life forms. In stressing conditions, their role is even more crucial for the recycling of organic matter or favoring nutrients uptake. When the conditions become really extreme and competition is low, fungi focus on extremotolerance and evolve peculiar competences to exploit natural or xenobiotic resources in the particular constrains imposed by the environment. This paper focuses on three different cases of fungal life in the extremes: hydrocarbon-polluted sites, extremely acidic substrates, and littoral dunes, aiming to give few but significant examples of the role of these fascinating organisms in peculiar habitats and the valuable biotechnological potentialities of the abilities they have evolved in response to such constrains.

Ecophysiological requirements and survival of a Trichoderma atroviride isolate with biocontrol potential.

Trichoderma atroviride SC1, isolated from decayed hazelnut wood in northern Italy in 2000, is a promising fungal agent for biological control of soil‐borne plant pathogens. The objective of this research was to characterize the biology and ecology of this fungus, in order to determine its environmental parameter tolerance levels and its behavior in the phylloplane and soil systems. To better characterize T. atroviride SC1, the influences of pH, temperature, water activity and different nitrogen and carbon sources on its in vitro growth were evaluated. T. atroviride SC1 survival was assessed on strawberry leaves under controlled conditions in a greenhouse and in sterilized and non‐sterilized soil samples kept at room temperature. Results showed that isolate SC1 is mesophilic and grows best at 25 °C. The fungus tolerates a wide range of pH levels, but growth was reduced on alkaline media (pH ≥ 8). The nitrogen and carbon sources peptone, tryptone, nitrate, mannose, galactose and sucrose were associated with the highest mycelial biomass production, as compared with other potential sources of nitrogen and carbon. The fungus survived on strawberry leaves under greenhouse conditions (25 ± 2 °C, RH = 60 ± 10%) and grew in sterilized soils at room temperature (23 ± 2 °C) for 45 d. However, no increase in mycelial dry weight was observed in non‐sterilized soils. T. atroviride SC1 survived under the test conditions, showing a good potential for use in soil and foliar biocontrol applications. (© 2008 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

Ecology and biology of microfungi from Antarctic rocks and soils

Abstract Cryptoendolithic microbial communities, living in porous sandstone rocks in the McMurdo Dry Valleys (Ross Desert) of Southern Victoria Land, Antarctica, were found within weathered pegmatite rocks in Northern Victoria Land, and the first endemic Antarctic fungal genus Friedmanniomyces endolithicus anam.‐gen. and sp. nov. was isolated from this community. Selected microfungi from these communities and from soil were examined for the production of extracellular enzymes and antibiotic substances. The cryptoendolithic strain CCFEE 5001 was particularly remarkable for consistent glycosidase activity, coupled with barely detectable growth. Chitinase activity was highest in the soil mi‐crofungus Verticillium cfr. lecanii (CCFEE 5003). This strain and its purified chitinase were active on Mucor plumbeus, Cladospori‐um cladosporioides, Aspergillus versicolor, and Penicillium verrucosum, producing mycelial damage and cell lysis. The strain CCFEE 5020, isolated from rocks, showed antibiotic activity against Pseudomonas putida, Sarcina sp., Bacillus subtilis, and Escherichia coli, under the test conditions. Good antibiotic activity was produced in the temperature range of 5° to 25° C, pH 4.0, agitation at 700 rpm, and areation at 1.0 vvm, in media containing 0.5% substrate sugar, though this supported only minimal growth. The investigation of soil microfungi in contrasting sites at the BIOTAS area at Edmonson Point indicated that both the presence of bird colonies and changes in temperature and UV exposure obtained by using plastic cloches influenced species composition and density. A ‘Culture Collection of Fungi from Extreme Environments’ (CCFEE) has been established at the University of Tuscia, housing fungal strains from Antarctica.

Temperature downshift induces antioxidant response in fungi isolated from Antarctica

Although investigators have been studying the cold-shock response in a variety of organisms for the last two decades or more, comparatively little is known about the difference between antioxidant cell response to cold stress in Antarctic and temperate microorganisms. The change of environmental temperature, which is one of the most common stresses, could be crucial for their use in the biotechnological industry and in ecological research. We compared the effect of short-term temperature downshift on antioxidant cell response in Antarctic and temperate fungi belonging to the genus Penicillium. Our study showed that downshift from an optimal temperature to 15° or 6°C led to a cell response typical of oxidative stress: significant reduction of biomass production; increase in the levels of oxidative damaged proteins and accumulation of storage carbohydrates (glycogen and trehalose) in comparison to growth at optimal temperature. Cell response against cold stress includes also increase in the activities of SOD and CAT, which are key enzymes for directly scavenging reactive oxygen species. This response is more species-dependent than dependent on the degree of cold-shock. Antarctic psychrotolerant strain Penicilliumolsonii p14 that is adapted to life in extremely cold conditions demonstrated enhanced tolerance to temperature downshift in comparison with both mesophilic strains (Antarctic Penicilliumwaksmanii m12 and temperate Penicillium sp. t35).

Antioxidant enzyme activity of filamentous fungi isolated from Livingston Island, Maritime Antarctica

From 18 soil samples taken in the vicinity of the permanent Bulgarian Antarctic base “St. Kliment Ohridski” (62°38′29″S, 60°21′53″W) on Livingston Island, 109 filamentous fungi were isolated on selective media. The most widespread fungal species were members of the genera Cladosporium, Geomyces, Penicillium and Aspergillus. Other species, already recorded in Antarctic environment, were also isolated: Lecanicillium muscarium, Epicoccum nigrum and Alternaria alternata. Thirty strains demonstrating good growth were screened for antioxidant enzymes superoxide dismutase (SOD) and catalase (CAT) that play an important role in the defense of aerobic organisms against oxidative stress, by converting reactive oxygen species into nontoxic molecules. Six of them showed high enzyme activity. The tested strains produced SOD with statistically significant higher activity at 15°C than at 30°C suggesting that this enzyme is cold-active. Such SOD could be useful in medicine and cosmetics. The best producer of cold-active SOD, Aspergillus glaucus 363, cultivated in bioreactors, demonstrated optimal growth temperature at 25°C and maximum enzyme activities at 25 and 30°C for SOD and CAT, respectively. The electrophoretical analysis showed that the fungus possesses Cu/Zn-SOD.