MacRS controls morphological differentiation and natamycin biosynthesis in Streptomyces gilvosporeus F607

Abstract

Streptomyces gilvosporeus F607 produces large amounts of natamycin in a process regulated by multiple networks, including two-component systems (TCSs). The macR and macS genes, which are annotated as rs12540 and rs12545, respectively, in S. gilvosporeus F607, affect natamycin biosynthesis and sporulation. The findings of this study indicate that deletion of macRS from S. gilvosporeus F607 prevents the production of natamycin, delays spore formation (according to scanning electron microscopy), and results in aerial hyphae lacking compartments separated by septa (according to transmission electron microscopy). Real-time quantitative polymerase chain reaction (RT-qPCR) analyses revealed that the expression levels of natamycin biosynthesis-related genes and genes essential for septum formation during sporulation were affected in the ΔmacRS mutant strain. Molecular simulations and electrophoretic mobility shift assays (EMSAs) suggested MacR not only interacted with the intergenic region of sgnM and sgnR, but also with the promoter of penicillin-binding protein gene ftsL required for cell division. sgnR promoter was presumed to be the binding target of MacR based on the RT-qPCR results. MacR had different affinity with two binding sites: one was located at ftsL promoter region with a perfect inverted repeats ‘TGAGTACGCGTACTCA’, the other was located at the presumed sgnR promoter with an imperfect inverted repeats ‘TGAAGGTGCTGGACTCA’. We propose a hypothesis of a three-level regulatory pathway based on pleiotropic transcriptional regulator MacR and its target genes sgnR and ftsL; the pathway activates natamycin biosynthesis and influences septum development via direct and indirect effects in S. gilvosporeus F607.