Effects of Phytotoxic Nonenolides, Stagonolide A and Herbarumin I, on Physiological and Biochemical Processes in Leaves and Roots of Sensitive Plants.

Phytotoxic macrolides attract attention as prototypes of new herbicides. However, their mechanisms of action (MOA) on plants have not yet been elucidated. This study addresses the effects of two ten-membered lactones, stagonolide A (STA) and herbarumin I (HBI) produced by the fungus Stagonospora cirsii, on Cirsium arvense, Arabidopsis thaliana and Allium cepa. Bioassay of STA and HBI on punctured leaf discs of C. arvense and A. thaliana was conducted at a concentration of 2 mg/mL to evaluate phenotypic responses, the content of pigments, electrolyte leakage from leaf discs, the level of reactive oxygen species, Hill reaction rate, and the relative rise in chlorophyll a fluorescence. The toxin treatments resulted in necrotic and bleached leaf lesions in the dark and in the light, respectively. In the light, HBI treatment caused the drop of carotenoids content in leaves on both plants. The electrolyte leakage caused by HBI was light-dependent, in contrast with that caused by STA. Both compounds induced light-independent peroxide generation in leaf cells but did not affect photosynthesis 6 h after treatment. STA (10 µg/mL) caused strong disorders in root cells of A. thaliana leading to the complete dissipation of the mitochondrial membrane potential one hour post treatment, as well as DNA fragmentation and disappearance of acidic vesicles in the division zone after 8 h; the effects of HBI (50 µg/mL) were much milder. Furthermore, STA was found to inhibit mitosis but did not affect the cytoskeleton in cells of root tips of A. cepa and C. arvense, respectively. Finally, STA was supposed to inhibit the intracellular vesicular traffic from the endoplasmic reticulum to the Golgi apparatus, thus interfering with mitosis. HBI is likely to have another main MOA, probably inhibiting the biosynthesis of carotenoids.

Expression of spider toxin in entomopathogenic fungus Lecanicillium muscarium and selection of the strain showing efficient secretion of the recombinant protein.

Beta/delta-agatoxin-1 of spider Agelena orientalis was expressed in entomopathogenic fungus Lecanicillium muscarium. To ensure secretion of the recombinant product by the fungus, the signal secretory peptide of the Metarhizium anisopliae Mcl1 protein was inserted into the sequence. For detection of the recombinant product and selection of transformants, the toxin sequence was also fused with eGFP at the C-terminus. The gene encoding the A. orientalis toxin with the Mcl1 protein signal peptide was commercially synthesized, amplified and cloned into the vector pBARGPE1 designed for heterologous expression under the control of the PgpdA promoter and the trpC terminator of Aspergillus nidulans. A double selection on selective medium and microscopic analysis of transformants allowed obtaining a mitotically stable recombinant strain of L. muscarium. The recognition of the Mcl1 derived signal peptide in the cells of transformants and effective secretion of the hybrid product was confirmed by immunoblotting.

Multilocus genotyping based species identification of entomopathogenic fungi of the genus Lecanicillium (=Verticillium lecanii s.l.).

Mitochondrial gene NADH dehydrogenase subunit 1 (nad1), ß-tubulin gene, and elongation factor 1-alpha (tef) were used to characterize and to identify 42 Lecanicillum spp. isolates (former complex species Verticillium lecanii Zimm. Viegas) and to study the phylogenetic relationships in this group. Within the isolates under investigation, Lecanicillium muscarium was the most common species (about 70% of all isolates, collected on the different hosts, predominantly on the insects from the order Hemiptera). Based on nad1 sequencing four main molecular haplotypes were revealed. All four haplotypes have Holarctic origin. Most of them were isolated in the Central part of Russia. One haplotype showed a specific association with the certain geographical area, limited to southwest Georgia and the Krasnodar Territory. For most strains their affiliation to species L. muscarium, L. longisporum, L. psalliotae, L. pissodes were confirmed by the phylogenetic tree, based on the combined sequences of nad1, ß-tub, and tef genes. Only five strains of haplotype C and strain F-2643 could not be identified to any present Lecanicillium species and their position remains ambiguous. Thus, the use of multilocus molecular approach based on these genes was useful to identify the Lecanicillium species. Inter-simple sequence repeat (ISSR) study evaluated a high diversity among the L. muscarium strains. The topology of the NJ-tree based on the ISSR-PCR markers has shown the genetic relationships with the support values 62-91% between L. muscarium isolates.

Prevalence of Beauveria pseudobassiana among entomopathogenic fungi isolated from the hard tick, Ixodes ricinus.

Human and animal disease-transmitting hard ticks (Acari: Ixodidae) are of great concern for public health and animal farming. Alternatives to tick control by chemical acaricides are urgently needed, and one intensively evaluated biocontrol strategy is based on the use of tick-pathogenic filamentous fungi. An indispensable prerequisite for the development of tick-derived fungal isolates into registered myco-acaricides is their sound taxonomic characterisation. A set of fungal strains isolated from ixodid ticks in the Republic of Moldova was genetically characterised at the genus and species level together with further tick-derived fungal isolates from different geographic locations in Europe and North America. In a previous study, the same isolates had been assigned to the species Beauveria bassiana. Using a recent molecular taxonomic approach based on phylogenetic reconstruction from both internal transcribed spacer (ITS) and protein-encoding gene sequences, all fungi investigated were conclusively assigned to one of the two "hyphomycete" genera, Beauveria or Isaria (Ascomycota; Hypocreales; Cordycipitaceae). Within the genus Isaria, two species, Isaria farinosa and Isaria fumosorosea, were equally represented. Within the genus Beauveria, the comparatively rare species Beauveria pseudobassiana was found to strongly prevail among the isolates from Moldova, and one of the two tick-derived Beauveria strains from North America could be assigned to this species as well. In particular, the previous classification as B. bassiana could not be confirmed for any of the characterised tick pathogens from Europe and North America. The data presented here lend support to the hypothesis that within the genus Beauveria specific adaptation to ticks might have occurred within the species B. pseudobassiana. To test this hypothesis, a more extensive molecular taxonomic survey carefully reconsidering previous taxonomic assignments of tick-derived fungal isolates is needed.

Stagonolides B-F, nonenolides produced by Stagonospora cirsii, a potential mycoherbicide of Cirsium arvense.

Stagonospora cirsii, a fungal pathogen isolated from Cirsium arvense and proposed as a potential mycoherbicide of this perennial noxious weed, produces phytotoxic metabolites in liquid and solid cultures. Recently, the main metabolite, stagonolide (1), with interesting phytotoxic properties, was isolated from a liquid culture and characterized as a new nonenolide. In the present work this same fungus, grown in solid culture, exhibited an increased capacity to produce nonenolides. Five new nonenolides, named stagonolides B-F (2-6), were isolated and characterized using spectroscopic methods. When tested by a leaf disk puncture assay at a concentration of 1 mg/mL, these compounds showed no toxicity to C. arvense and Sonchus arvensis, whereas stagonolide (1) was highly toxic. Stagonolide (1) and stagonolide C (3) were weakly toxic to Colpoda steinii, a protozoan, when tested at 0.05 mg/mL, with the other stagonolides nontoxic. A number of structure-activity relationship observations were made.

Nonenolides and cytochalasins with phytotoxic activity against Cirsium arvense and Sonchus arvensis: a structure-activity relationships study.

A structure-activity relationships study was conducted assaying 15 natural analogues and derivatives belonging to two groups of organic compounds, nonenolides and cytochalasins, for their toxicity against the composite perennial weeds Cirsium arvense and Sonchus arvensis occurring through the temperate region of world. The toxic nonenolides (stagonolide, putaminoxin, pinolidoxin) and cytochalasins (deoxaphomin, cytochalasins A, B, F, T, Z2 and Z3) were isolated from phytopathogenic Stagonospora, Phoma and Ascochyta spp. The pinolidoxin (7,8-O,O'-diacetyl- and 7,8-O,O'-isopropylidene-pinolidoxin) and cytochalasins B (21,22-dihydro-, 7-O-acetyl- and 7,20-O,O'-diacetyl-cytochalasin B) derivatives were obtained by chemical modifications of the corresponding toxins. Among the 15 compounds tested, stagonolide and deoxaphomin proved to be the most phytotoxic to C. arvense and S. arvensis leaves, respectively. The tested phytotoxic nonenolides were stronger inhibitors of photosynthesis in C. arvense leaves than cytochalasines A and B. Stagonolide had less effect on membrane permeability in C. arvense leaves than cytochalasin B. Significant changes of light absorption by C. arvense leaves in visible and infrared spectra were caused by stagonolide. The functional groups and the conformational freedom of the ring, appear to be important structural features for the nonenolides toxicity, whereas and the presence of the hydroxy group at C-7, the functional group at C-20 and the conformational freedom of the macrocyclic ring are important for the cytochalasins toxicity.

Herbicidal potential of stagonolide, a new phytotoxic nonenolide from Stagonospora cirsii.

Stagonospora cirsii is a pathogen of Cirsium arvense, causing necrotic lesions on leaves of this noxious weed. The fungus produced toxic metabolites when grown in liquid culture. A new phytotoxin, named stagonolide, was isolated and characterized as (8R,9R)-8-hydroxy-7-oxo-9-propyl-5-nonen-9-olide by spectroscopic methods. Stagonolide was shown to be a nonhost-specific but selective phytotoxin. Leaves of C. arvense were most sensitive and leaves of tomato and pepper (both Solanaceae) were less sensitive to stagonolide, which was assayed at 5 x 10(-3) M, than other plants. Stagonolide assayed at 5 x 10(-6) M was demonstrated to be a strong inhibitor of root growth in seedlings of C. arvense and some other Asteraceae species. Seedlings growth in wheat and radish was much less affected by the toxin, and seedlings of cucumber were insensitive to it.

Agrobacterium-mediated insertional mutagenesis (AIM) of the entomopathogenic fungus Beauveria bassiana.

Agrobacterium tumefaciens was used to stably transform the entomopathogenic deuteromycete Beauveria bassiana to hygromycin B resistance by integration of the hph gene of Escherichia coli into the fungal genome. The transformation protocol was optimized to generate a library of insertion mutants of Beauveria. Transformation frequencies around 10(-4) and suppression of background growth were achieved. Over 90% of the AIM mutants investigated contained single-copy T-DNA integrations at different chromosomal locations. Integrated T-DNAs were re-isolated from ten transformants by a marker rescue approach. When the sequences flanking these T-DNAs were compared with the corresponding locations of the wild-type genome, truncations of T-DNA borders were found to be common, while none of the sites of integration had suffered deletion or rearrangement. Thus, AIM can be considered a promising tool for insertional mutagenesis studies of entomopathogenic filamentous fungi.