Vigna spp. Root-Nodules Harbor Potentially Pathogenic Fungi Controlled By Co-habiting Bacteria.

This study aimed to isolate, identify, and evaluate the pathogenicity of nodule-borne fungi of asymptomatic Vigna spp. plants, grown in soils from preserved tropical dry forests (Caatinga) areas and identify the occurrence of co-habiting bacteria from these plants, and which have potential to control the co-occurring pathogenic fungi. Fungi and bacteria were isolated from three Vigna species (V. unguiculata, V. radiata, and V. mungo), grown in soil samples collected in five preserved Caatinga areas (Northeastern, Brazil). All fungi and selected bacteria were phylogenetically characterized by the sequencing of ITS1-5.8S-ITS2, and the 16S rRNA gene, respectively. The pathogenicity of fungi in cowpea seeds germination was evaluated throughout the inoculation experiment in Petri dishes and pots containing sterile substrate. The potential of nodule-borne bacteria to control pathogenic fungi in cowpea was assessed in a pot experiment with a sterilized substrate by the co-inoculation of fungi and bacteria isolated from the respective individual plants and soils. The 23 fungal isolates recovered were classified within the genera Fusarium, Macrophomina, Aspergillus, Cladosporium, and Nigrospora. The inoculation of fungi in cowpea seeds reduced the emergence of seeds in Petri dishes and pots. Twenty-four bacteria (Agrobacterium sp., Bradyrhizobium sp., Bacillus sp., Enterobacter sp., Pseudomonas sp., Paraburkholderia sp., and Rhizobium sp.) inhibited the harmful effects of Macrophomina sp. and Fusarium sp., increasing the germination and emergency of potted cowpea plants, highlighting the strains Agrobacterium sp. ESA 686 and Pseudomonas sp. ESA 732 that controlled, respectively, the Fusarium sp. ESA 771 and Macrophomina sp. ESA 786 by 100 and 84.6% of efficiency.

Co-inoculation of two symbiotically efficient Bradyrhizobium strains improves cowpea development better than a single bacterium application.

The co-inoculation of Bradyrhizobium with other non-bradyrhizobial strains was already assessed on cowpea, but the co-inoculation of two Bradyrhizobium strains was not tested up to now. This study aimed to evaluate the cowpea growth, N accumulation, and Bradyrhizobium competitiveness of the elite strain B. pachyrhizi BR 3262 when co-inoculated with other efficient Bradyrhizobium from the Brazilian semiarid region. Three potted-plant experiments were carried out. In the first assay, 35 efficient Bradyrhizobium isolates obtained from the semiarid region of Brazil were co-inoculated with the elite strains B. pachyrhizi BR 3262. The experiment was conducted in gnotobiotic conditions. The plant growth, nodulation, N nutritional variables, and nodular occupation were assessed. Under gnotobiotic and non-sterile soil conditions, ten selected bacteria plus the elite strain B. yuanmingense BR 3267 were used at the second and third experiments, respectively. The cowpea was inoculated with the 11 bacteria individually or co-inoculated with BR 3262. The plant growth and N nutritional variables were assessed. A double-layer medium spot method experiment was conducted to evaluate the interaction among the co-inoculated strains in standard and diluted YMA media. The co-inoculation treatments showed the best efficiency when compared to the treatments inoculated solely with BR 3262. This strain occupied a low amount of cowpea nodules ranging from 5 to 67.5%. The treatments with lower BR 3262 nodule occupancy showed the best results for the shoot nitrogen accumulation. The culture experiment showed that four bacteria inhibited the growth of BR 3262. In contrast, seven strains from the soils of Brazilian semiarid region were benefited by the previous inoculation of this strain. In the second and third experiments, the results indicated that all 11 co-inoculated treatments were more efficient than the single inoculation, proofing the best performance of the dual inoculation of Bradyrhizobium on cowpea.