Bacterial strains from floodplain soils perform different plant-growth promoting processes and enhance cowpea growth

ABSTRACT Certain nodulating nitrogen-fixing bacteria in legumes and other nodule endophytes perform different plant-growth promoting processes. The objective of this study was to evaluate 26 bacterial strains isolated from cowpea nodules grown in floodplain soils in the Brazilian savannas, regarding performance of plant-growth promoting processes and ability to enhance cowpea growth. We also identified these strains by 16S rRNA sequencing. The following processes were evaluated: free-living biological nitrogen fixation (BNF), solubilization of calcium, aluminum and iron phosphates and production of indole-3-acetic acid (IAA). The abilities to nodulate and promote cowpea growth were evaluated in Leonard jars. Partial sequencing of the 16S rRNA gene identified 60 % of the strains as belonging to genus Paenibacillus. The following four genera were also identified: Bacillus, Bradyrhizobium, Enterobacter and Pseudomonas. None of the strains fixed N2 free-living. Among the strains, 80 % solubilized Ca phosphate and one solubilized Al phosphate and none solubilized Fe phosphate. The highest IAA concentrations (52.37, 51.52 and 51.00 μg mL−1) were obtained in the 79 medium with tryptophan by Enterobacter strains UFPI B5-7A, UFPI B5-4 and UFPI B5-6, respectively. Only eight strains nodulated cowpea, however, all increased production of total dry matter. The fact that the strains evaluated perform different biological processes to promote plant growth indicates that these strains have potential use in agricultural crops to increase production and environmental sustainability

Resveratrol acts as a natural profungicide and induces self-intoxication by a specific laccase

The grapevine (Vitis) secondary metabolite resveratrol is considered a phytoalexin, which protects the plant from Botrytis cinerea infection. Laccase activity displayed by the fungus is assumed to detoxify resveratrol and to facilitate colonization of grape. We initiated a functional molecular genetic analysis of B. cinerea laccases by characterizing laccase genes and evaluating the phenotype of targeted gene replacement mutants. Two different laccase genes from B. cinerea were characterized, Bclcc1 and Bclcc2. Only Bclcc2 was strongly expressed in liquid cultures in the presence of either resveratrol or tannins. This suggested that Bclcc2, but not Bclcc1, plays an active role in the oxidation of both resveratrol and tannins. Gene replacement mutants in the Bclcc1 and Bclcc2 gene were made to perform a functional analysis. Only Bclcc2 replacement mutants were incapable of converting both resveratrol and tannins. When grown on resveratrol, both the wild type and the Bclcc1 replacement mutant showed inhibited growth, whereas Bclcc2 replacement mutants were unaffected. Thus, contrary to the current theory, BcLCC2 does not detoxify resveratrol but, rather, converts it into compounds that are more toxic for the fungus itself. The Bclcc2 gene was expressed during infection of B. cinerea on a resveratrol-producing host plant, but Bclcc2 replacement mutants were as virulent as the wild-type strain on various hosts. The activation of a plant secondary metabolite by a pathogen introduces a new dimension to plant-pathogen interactions and the phytoalexin concept

Fungal glyoxal oxidases

The invention relates to methods for identifying fungicides, nucleic acids coding for polypeptides of fungi having the biological activity of glyoxal oxidases, the polypeptides coded thereby, and the use of the same as targets for fungicides and for identifying novel fungicidally active compounds. The invention also relates to methods for detecting modulators of said polypeptides, and transgenic organisms containing said polypeptide