A nitrogen assimilation bottleneck can limit Bacillus subtilis growth in plant culture media
Cabales, A.; Warthen, R.; Bais, H.; Kunjapur, A.
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Microbial engineering offers potential for improving the sustainability of agriculture by providing greater control of desired microbial functions. However, successful control of engineered functions requires greater understanding of their robustness under diverse conditions including those used for plant hydroponics. Here, we studied biomass accumulation and surfactin biosynthesis by an engineered derivative of Bacillus subtilis PY79 in common plant culture media as a model system for interrogating metabolic robustness. We report the observation that PY79 and all other B. subtilis strains that we tested, including natural isolates, exhibited difficulty growing under shaking incubation in defined media where the only nitrogen sources were inorganic. In contrast, assimilation of inorganic nitrogen sources functioned relatively robustly under static incubation in these same media. Our findings may offer some guidance for use of B. subtilis in controlled environment agriculture and could aid future efforts to identify the molecular basis for the agitation-dependent effect on nitrogen assimilation.
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