Abstract
Copiotrophic Bacillus and related taxa grow rapidly and are commonly isolated from soil. Despite their growth rate, Bacillus sensu lato (BSL) constitute less than one percent of soil bacterial communities, and the nutrient-enriched rhizosphere contains even fewer. Amendment of bulk soil with synthetic root exudate did not lead to increase in Bacillus culturable counts. We hypothesized that BSL populations in soil enriched with growth-supporting carbon are suppressed by various soil microbes. A screen using B. pseudomycoides as tester strain yielded 124 growth inhibiting isolates, aligning by 16S rRNA genes to 3 Alphaproteobacteria, 6 Betaproteobacteria, 5 Gammaproteobacteria, 3 Streptomyces, and 19 Bacillaceae. Most antagonists also suppressed four other BSL, and over 70% of the BSL isolates suppressed each other. The 11 sequenced BSL genomes encoded between 2 and 10 antibiotic biosynthetic gene clusters. Incubation of multiple isolates in artificial soil microcosms resulted in population growth restraint through a high percentage of endospores formed. This indicated that growth suppression by antagonists was due primarily to induction of sporulation. These results support our hypothesis that Bacillus populations in soil enriched with growth-supporting carbon are suppressed by various soil microbes.