Claudio Altomare

Production of type A trichothecenes and enniatin B byFusarium sambucinum Fuckel sensu lato

Twenty-nineFusarium isolates, representing three new taxa originated by Nirenberg fromF. sambucinum Fuckel sensu lato, namely:F. sambucinum Fuckel sensu stricto,F. venenotum Nirenb., andF. torulosum (Berk. & Curt.) Nirenb., were tested for in vitro production of toxic secondary metabolites on autoclaved corn kernels.F. sambucinum sensu stricto was able to produce type A trichothecenes and enniatin B (EB). In particular, amongst the 14 isolates tested, 5 produced only diacetoxyscirpenol (DAS) (up to 700 µg/g); 1 produced only neosolaniol (NEOS) (250 µg/g); 2 produced T-2 toxin (T-2) + NEOS (up to 175 and 150 µg/g, respectively); 1 produced NEOS + DAS (300 and 100 µg/g, respectively); and 5 produced DAS + EB (up to 500 and 140 µg/g, respectively). All six isolates ofF. venenotum were able to produce only DAS (up to 100 µg/g).F. torulosum produced no trichothecenes, but four out of nine tested isolates were able to produce EB (up to 140 µg/g). Zearalenones and type B trichothecenes were not found. The toxicity of the culture extracts towardsArtemia salina L. was correlated in general with the occurrence of the above toxins, except for someF. torulosum strains. However, the lack of correlation between the amounts of toxins recovered and toxic activity observed in theGeotrichum candidum Link ex Pers. andA. salina assays suggested the presence of unknown toxic compounds.

Investigations of fungal secondary metabolites with potential anticancer activity.

Fourteen metabolites, isolated from phytopathogenic and toxigenic fungi, were evaluated for their in vitro antigrowth activity for six distinct cancer cell lines, using the MTT colorimetric assay. Bislongiquinolide (1) and dihydrotrichodimerol (5), which belong to the bisorbicillinoid structural class, displayed significant growth inhibitory activity against the six cancer cell lines studied, while the remaining compounds displayed weak or no activity. The data show that 1 and 5 have similar growth inhibitory activities with respect to those cancer cell lines that display certain levels of resistance to pro-apoptotic stimuli or those that are sensitive to apoptosis. Quantitative videomicroscopy analysis revealed that 1 and 5 exert their antiproliferative effect through cytostatic and not cytotoxic activity. The preliminary results from the current study have stimulated further structure-activity investigations with respect to the growth inhibitory activity of compounds belonging to the bisorbicillinoid group.

Beneficial Soil Microorganisms, an Ecological Alternative for Soil Fertility Management

The new challenges that will be faced by agriculture in the twenty-first century impose the adoption of strategies able to increase food production without further increase the area of arable land and with low environmental impact. Soil microorganisms are a major component of the natural fertility of soils. They can promote plant growth, increase crop productivity and contribute significantly to the mineral nutrition of crop plants. This review examines the up-to-date knowledge about the potential and existing uses of beneficial microbes as biofertilizers and gives an outline of their modes of action. Plant growth promoting microorganisms (PGPM) influence plant nutrition and growth through various mechanisms including nitrogen fixation, breakdown of organic matter, solubilization of sparingly soluble minerals, release of chelating compounds and biologically active substances such as phytohormones, vitamins and enzymes, and increase of the root system efficiency in nutrient uptake. Non symbiotic soil- or endophytic bacteria belonging to the genera Azospirillum, Azotobacter, Acetobacter, Gluconacetobacter, Azoarcus, Bacillus, Paenibacillus, Burkholderia, Herbaspirillum, Clostridium, Klebsiella, Enterobacter, Citrobacter, and Pseudomonas are able to fix atmospheric N2 and have been found to be responsible for supply of biologically fixed nitrogen to crop plants. They may also improve plant growth through production of bioactive metabolites and indirect mechanisms, such as suppression of phytopathogens or induction of resistance to pathogens in plants. Numerous species of soil and rhizosphere microorganisms may solubilize insoluble mineral phosphates, mainly through acidification and production of organic acids, and thus mobilize the enormous reserves of phosphorus (P) that are stored in most soils and are otherwise unavailable to plants. Generally, fungi exhibit greater P-solubilizing ability than bacteria. Members of the genera Aspergillus, Penicillium, and Trichoderma are particularly efficient P-solubilizers. Among bacteria, good results have been obtained with Bacillus spp. and Pseudomonas spp., especially in combination with P-solubilizing fungi and arbuscular mycorrhizal fungi (AMF). Under field conditions, the combined use of P-solubilizing microorganisms with mineral fertilizers such as rock-phosphate has often given successful results. Also, the biological activities of microorganisms in the rhizosphere can mediate the solubility, and hence the availability at root surface of micro-nutrients, of which most soils are defective due to the fast depletion resulting from intensive farming. While other elements are also involved, Fe, Mn and Zn deficiencies have the greatest impact on the yields and quality of agricultural produce. PGPM and AMF have the capability to alter soil pH and modify the equilibrium of many chemical and biochemical reactions, such as precipitation/dissolution, adsorption/desorption, complexation/dissociation, and oxidation/reduction of metal cations and thus regulate the plant uptake. Beside enhancing plant nutrition under limited or deficient conditions, they may also reduce detrimental effects of excess of micronutrients, which may occur in acid or polluted soils. In conclusion, in order to reduce the environmental and economic costs of the massive use of synthetic fertilizers and to obtain safer food, the use of PGPM as biofertilizers appears to be a concrete perspective. All the evidence summarized in this review clearly shows that beneficial soil microorganisms, either alone or in combination with mineral or organic fertilizers, may be utilized to increase crop productivity and maintain the fertility of soils without threatening the environment. These multifunctional agents are a renewable resource with low environmental impact. Therefore, beneficial soil microbes should be further studied and exploited for the development of sustainable agriculture.

Citrantifidiene and citrantifidiol: bioactive metabolites produced by Trichoderma citrinoviride with potential antifeedant activity toward aphids.

Two novel metabolites with potential antifeedant activity were isolated from cultures of the fungus Trichoderma citrinoviride strain ITEM 4484 grown in solid-state fermentation on sterile rice kernels. The producing strain was identified at species level by sequence analysis of the internal transcribed spacer regions ITS-1 and ITS-2 of the nuclear rDNA and a fragment of the translation elongation factor gene TEF-1alpha. Fractionation by column chromatography and TLC of the culture organic extract, followed by feeding preference tests on the aphid pest Schizaphis graminum (Rondani), allowed the purification of 5.8 and 8.9 mg/kg of culture of two bioactive metabolites, which were named citrantifidiene and citrantifidiol ( 1 and 2). Citrantifidiene and citrantifidiol, whose structures were determined by spectroscopic methods (NMR and MS) are a symmetrical disubstituted hexa-1,3-dienyl ester of acetic acid and a tetrasubstituted cyclohexane-1,3-diol, respectively. The pure metabolites influenced the feeding preference of S. graminum restraining individuals from feeding on wheat leaves dipped in 5% aqueous methanol solution containing 0.57 mg/mL of citrantifidiene or 0.91 mg/mL of citrantifidiol.

Bisorbicillinoids produced by the fungus Trichoderma citrinoviride affect feeding preference of the aphid Schizaphis graminum.

We report the effects of some bisorbicillinoids isolated from biomass of the fungus Trichoderma citrinoviride on settling and feeding preference of the aphid Schizaphis graminum. Purification of the fungal metabolites was carried out by a combination of column chromatography and thin-layer chromatography using direct and reverse phases. Chemical identification was performed by spectroscopic methods including nuclear magnetic resonance and mass spectrometry. The identified bisorbicillinoids appeared to be bislongiquinolide, its 16,17-dihydro derivative, trichodimerol, and dihydrotrichodimerol. A feeding preference test with alate morphs of S. graminum was used to identify the active fractions. Among the four bisorbicillinoids, dihydrotrichodimerol and bislongiquinolide influenced aphid feeding preference, restraining specimens from settling on leaves treated with metabolites. Taste neurons sensitive to these compounds, particularly to bislongiquinolide, were located on tarsi of the S. graminum alate morphs.

Detection of fungal metabolites of various Trichoderma species by the aphid Schizaphis graminum

The feeding preferences of alate and apterous morphs of the aphid Schizaphis graminum (Rondani) (Homoptera: Aphididae) were evaluated using leaves treated with powdered rice cultures of four fungal isolates belonging to different species of the genus Trichoderma (Deuteromycotina: Hyphomycetes). All of the fungal isolates restrained alate morphs of S. graminum from visiting treated leaves, but only Trichoderma citrinoviride Bisset also influenced the preference of apterous morphs. Trials carried out with supernatants obtained by centrifuging aqueous suspensions of the fungal cultures showed that the feeding preference of aphids was maintained in the absence of fungal spores and mycelia, supporting the hypothesis that at least part of the fungal metabolites responsible for this effect were water‐soluble compounds. Electrophysiological studies showed that the structures involved in the perception of the fungal metabolites are located on the aphid tarsomeres.

Inhibition of Species of the Aspergillus Section Nigri and Ochratoxin A Production in Grapes by Fusapyrone

ABSTRACT Fusapyrone (FP), an antifungal natural compound, was tested against the three main ochratoxigenic species of the Aspergillus section Nigri. The MICs at 24 h were 6.0, 11.6, and 9.9 μg/ml for Aspergillus carbonarius, Aspergillus tubingensis, and Aspergillus niger, respectively. Strong inhibition of growth and morphological changes were still observed at half the MIC after 7 days. The application of a 100 μg/ml FP solution in a laboratory assay on artificially inoculated grapes resulted in a significant reduction (up to 6 orders of magnitude) of A. carbonarius CFU counts. Dramatic reductions of the ochratoxin A (OTA) content, compared to the content of the positive control (average amount of OTA, 112.5 ng/g of grape; three experiments), were obtained with the application of either 100 or 50 μg/ml of FP (0.6 or 5.1 ng/g of grape, respectively).

High performance liquid chromatography for the analysis of fusapyrone and deoxyfusapyrone, two antifungal α-pyrones from Fusarium semitectum

A simple, very sensitive and rapid HPLC method was developed for the simultaneous quantitative analysis of both fusapyrone (FP) and deoxyfusapyrone (DFP), the two antifungal 3-substituted-4-hydroxy-6-alkyl-2-pyrones isolated from rice culture of Fusarium semitectum, in crude extracts. Such method was optimized on C-18 reverse phase column, using the isolated metabolites as standards, with a sequence of linear elution steps with a MeOH-H(2)O mixture and using an ultraviolet detector fixed at 285 nm, where both alpha-pyrones showed a characteristic absorption maximum. This method was used to quantify the bioactive metabolites in crude organic extracts from two F. semitectum strains. The recovery of FP and DFP was measured in a crude extract from a poor metabolite producer F. semitectum strain. The recovery values ranged from 84% to 99% for FP and from 99% to 101% for DFP, indicating that the method was close to quantitative recovery. Furthermore, an efficient medium pressure column chromatography and TLC combined method was developed for the isolation and purification of FP and DFP from fungal culture extracts.

Production of neosolaniol byFusarium tumidum

Extracts from autoclaved maize culture ofFusarium tumidum strain R-5823 were toxic towardsArtemia salina. Bioassay-guided fractionation of the organic extract led to the isolation of the toxic compound that was identified as the trichothecene toxin neosolaniol (NEOS) by1H,13C nuclear magnetic resonance spectroscopy and low-resolution electronic impact mass spectrometry. The amount of NEOS produced by the strain R-5823 was 300 mg/kg maize culture. NEOS was also detected by HPLC in cultures of four out of seven additional strains ofF. tumidum andGibberella tumida with different origin, in amounts ranging from 1 to 311 mg/kg. This is the first report on the production of a trichothecene toxin byF. tumidum.

Long Chain Alcohols Produced by Trichoderma citrinoviride Have Phagodeterrent Activity against the Bird Cherry-Oat Aphid Rhopalosiphum padi

In this study we report the effects of fungal metabolites isolated from cultures of the fungus Trichoderma citrinoviride ITEM 4484 on the feeding preference of the aphid Rhopalosiphum padi, a major pest of cereal crops. Different phagodeterrent metabolites were purified by a combination of direct and reverse phase column chromatography and thin-layer chromatography. Chemical investigations, by spectroscopic and chemical methods, led to the identification of different long chain primary alcohols (LCOHs) of the general formula R-OH, wherein R is a long, unbranched, unsubstituted, linear aliphatic group. LCOHs have been reported as components of lepidopteran pheromone blends, but their phagodeterrent effect to aphids is herein reported for the first time. The effects of LCOHs on R. padi were studied by behavioral and electrophysiological bioassays. Feeding preference tests that were carried out with winged and wingless morphs of R. padi showed that LCOHs had high phagodeterrent activity and restrained aphids from settling on treated leaves at a concentration as low as 0.15 mM (0.036 g/l). The results of different electrophysiological analyses indicated that taste receptor neurons located on the aphid tarsomeres were involved in the LCOHs perception. Behavioral assays carried out with some commercial agrochemicals, including azadirachtin A, pyrethrum and a mineral oil-based product, in combination with 1-hexadecanol, the LCOH most abundantly produced by T. citrinoviride ITEM 4484, showed that these different active principles could be applied together, resulting in a useful increase of the phagodeterrent effect. The data shown indicate that these compounds can be profitably utilized for novel applications in biotechnical control of aphid pests. Furthermore, the tested LCOHs have no chiral centers and therefore can be obtained with good yield and at low cost through chemical synthesis, as well as from natural sources.