Transcriptional regulation of the fidaxomicin gene cluster and cellular development in Actinoplanes deccanensis YP-1 by the pleiotropic regulator MtrA

ABSTRACT Fidaxomicin is an 18-membered glycosidic macrolide polyketide that was clinically used in the treatment of Clostridium difficile infection in 2011. Although the biosynthetic mechanism and pathway-specific regulator of fidaxomicin were well elaborated, little is known about the pleiotropic regulators outside the fidaxomicin gene cluster. To further reveal the transcriptional regulatory mechanism of fidaxomicin biosynthesis in Actinoplanes deccanensis YP-1, we used the 5′-biotin-labeled fadR1 promoter ( fadS5R1p ) as a probe to affinity isolate the fadS5R1p -interactive protein MtrA, a response regulator of the two-component system MtrAB, from the proteome of mycelia. MtrA is bound directly to fadS5R1p to positively regulate gene cluster expression and fidaxomicin production. Fidaxomicin production was improved by 37% in the mtrA overexpressed strain. Furthermore, we revealed that MtrA tends to bind GTKAYS motifs and influence genes involved in secondary metabolites, phosphate transport, methionine transport, nitrogen metabolism, drug transport, membrane properties, etc. Overall, for the first time at the transcriptional level, we comprehensively revealed a pleiotropic regulator, MtrA, that not only directly mediates the FadR1-specific pathway to regulate the proper production of fidaxomicin but also participates in bacterial growth and development. IMPORTANCE Cascade regulation networks are almost present in various kinds of microorganisms, but locating and systematically elucidating specific pleiotropic regulators related to a certain gene cluster can be a tricky problem. Here, based on the promoter of the fidaxomicin pathway-specific regulator FadR1, we utilized a “DNA to Proteins” affinity purification method and captured a global regulator MtrA, which positively regulates fidaxomicin biosynthesis. In the mtrA overexpressed strain, the production of fidaxomicin was improved by 37% compared to the native strain. Then, we combined the “Protein to DNAs” affinity purification method (DAP-seq) with the results of RNA-seq and systematically elucidated the primary and secondary metabolic processes in which MtrA directly or indirectly participates. Thus, our work brought up a new way to improve fidaxomicin production from the perspective of global regulation and analyzed the regulatory mechanism of MtrA. Meanwhile, we provided a novel methodology for the research of cascade regulation networks and vital secondary metabolites.