Characterization of the Culturable Sporobiota of Spanish Olive Groves and Its Tolerance toward Environmental Challenges.

Olive agriculture presents an integral economic and social pillar of the Mediterranean region with 95% of the world's olive tree population concentrated in this area. A diverse ecosystem consisting of fungi, archaea, viruses, protozoa, and microbial communities-the soil microbiome-plays a central role in maintaining healthy soils while keeping up productivity. Spore-forming organisms (i.e., the sporobiota) have been identified as one of the predominant communities of the soil microbiome and are known for the wide variety of antimicrobial properties and extraordinary resistance. Hence, the aim of this work was to determine the culturable sporobiota of Spanish olive orchards and characterize its phenotypic properties toward common environmental challenges. A collection of 417 heat-resistant bacteria were isolated from five Spanish olive orchards. This collective was termed the "olive sporobiota." Rep-PCR clustering of representative isolates revealed that they all belonged to the group of Bacillus spp., or closely related species, showing a great variety of species and strains. Representative isolates showed susceptibility to common antibiotics, as well as good resistance to heavy metal exposure, with an order of metal tolerance determined as iron > copper > nickel > manganese > zinc > cadmium. Finally, we showed that the application of mineral fertilizer can in several cases enhance bacterial growth and thus potentially increase the relative proportion of the sporobiota in the olive grove ecosystem. In summary, the identification of the culturable olive sporobiota increases our understanding of the microbial diversity in Spanish olive groves, while tolerance and resistance profiles provide important insights into the phenotypic characteristics of the microbial community. Microbial communities are a key component of healthy soils. Spore-forming microorganisms represent a large fraction of this community-termed the "sporobiota"-and play a central role in creating a conducive environment for plant growth and food production. In addition, given their unique features, such as extraordinary stability and antimicrobial properties, members of the sporobiota present interesting candidates for biotechnological applications, such as sustainable plant protection products or in a clinical setting. For this, however, more information is needed on the spore-forming community of agricultural installations, ultimately promoting a transition toward a more sustainable agriculture.