Abstract
Small molecules are able to regulate numerous cellular processes through binding to various bacterial receptor proteins, but the mechanisms and functions by which these chemicals coordinate and execute remain poorly understood. 4-hydroxybenzoic acid (4-HBA) and cyclic di-GMP (c-di-GMP) are two such molecules with distinct structures that are produced in Lysobacter enzymogenes to synergistically affect the secretion of an antifungal antibiotic, known as heat-stable antifungal factor (HSAF). In our earlier studies, we showed that CdgL, a YajQ-like protein without DNA-binding domain, was able to physically interact with LysR, a transcription factor, to enhance its binding affinity toward the upstream region of the HSAF biosynthesis operon promoter, hence increasing the HSAF biosynthesis. Interestingly, 4-HBA or c-di-GMP can bind to its cognate receptor of LysR or CdgL, respectively, to regulate the HSAF biosynthesis. Further, c-di-GMP acts by binding to CdgL to induce the dissociation of the CdgL-LysR complex, leading to decreased downstream expression. We now showed that CdgL controlled the transcription of lenB2, which encodes an oxygenase to convert chorismate to 4-HBA. Notably, overexpression of cdgL was found to stimulate lenB2 transcription, which likely increased the intracellular 4-HBA content. Also, 4-HBA could bind to LysR to interrupt the LysR-CdgL complex formation and release of CdgL, which caused a lower affinity of LysR toward DNA and hence decreased HSAF operon expression. These findings, along with our earlier report, allow us to propose a coordination mechanism demonstrating how the HSAF biosynthesis is co-regulated by 4-HBA and c-di-GMP through interactions with their cognate receptors. This new mechanism shall shed light on improving the HSAF yield for practical usage.
Highlights
Bacteria of the genus Lysobacter is gradually recognized as a rich source of crop protecting agents, due to their great ability to produce abundant extracellular lytic enzymes and antimicrobial secondary metabolites (Folman et al 2003; Kobayashi et al 2005; Qian et al 2009; Xie et al 2012)
The biosynthesis of heat-stable antifungal factor (HSAF) in L. enzymogenes is controlled by a gene cluster known as HSAF biosynthesis gene operon (Lou et al 2011; Wang et al 2017), whose transcription is influenced by multiple factors, including small molecules and transcription factors
The direct 4-hydroxybenzoic acid (4-HBA)-LysR binding (Kd, 5 μM) was confirmed by an in vitro assay (Su et al 2017). It remains unclear whether the binding of 4-HBA with LysR could strengthen the transcription of the HSAF biosynthesis operon under the in vivo condition or not
Summary
Bacteria of the genus Lysobacter is gradually recognized as a rich source of crop protecting agents, due to their great ability to produce abundant extracellular lytic enzymes and antimicrobial secondary metabolites (Folman et al 2003; Kobayashi et al 2005; Qian et al 2009; Xie et al 2012). The biosynthesis of HSAF in L. enzymogenes is controlled by a gene cluster known as HSAF biosynthesis gene operon (Lou et al 2011; Wang et al 2017), whose transcription is influenced by multiple factors, including small molecules and transcription factors We showed that the L. enzymogenes LenB2, a petridinedependent dioxygenase-like protein, can convert chorismate, the end-product of the shikimate pathway, to 4-HBA (Su et al 2017). The direct 4-HBA-LysR binding (Kd, 5 μM) was confirmed by an in vitro assay (Su et al 2017). It remains unclear whether the binding of 4-HBA with LysR could strengthen the transcription of the HSAF biosynthesis operon under the in vivo condition or not
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