Tackling against spreading of antimicrobial resistance, which is an intimidating global problem, must focus on undiscovered systems, that may have a potential to discover new antimicrobial compounds. Rhizosphere has enormous potential and can be described as nutrient-rich environment that offers optimal growth conditions for soil-dwelling bacteria such as PGPR (Plant Growth Promoting Rhizobacteria), a specialised group of bacteria that promote plant growth and yield. Bacillus subtilis, an improtant member of the PGPR group, is used in our master's thesis, where we constructed B. subtilis mutants with deletions in specific genes involved in the bacillaene or surfactin biosynthesis. According to the findings, secondary metabolism is energy consuming, and master's thesis focused mainly on the assumption that the deletion of one gene in surfactin or bacillaene biosynthesis affects the production of the other. Therefore, srfAA or pksC gene promoter was fused with a gene encoding for yellow fluorescent protein (yfp), which enabled us to measure the yellow fluorescence intensity on spectrofluorimeter or observe cells under confocal laser scanning microscope. We hypothesised that deletion of pks or srfAA gene reduces energetic burden, resulting in higher levels of pksC promoter expression after deleting surfactin (srfAA) pathway as well as in higher levels of srfAA promoter expression, when deleting bacillaene pathway (pks). Based on yellow fluorescence intensity measurements our hypothesis was confirmed. In addition, surfactin dropplet test was performed to assess the amount of surfactin produced by B. subtilis wild type strain or bacillaene mutant. We found that the bacillaene mutant produces quantitatively more surfactin compared to the wild type and therefore confirmed our third hypothesis, where we inffered on positive correlation between surfactin transcriptional and translational level. The expression of the pksC promoter in the population is heterogenous, confirming our second hypothesis. We have demonstrated by confocal laser scanning microscopy that only a specialised B. subtilis sub-population is responsible for higher levels of pksC promoter expression.