Affiliation:
1. Michael DeGroote Institute for Infectious Diseases Research, Department of Biochemistry and Biomedical Sciences, McMaster University, Hamilton, Ontario, Canada
Abstract
ABSTRACT
Many microorganisms produce secondary metabolites that have antibiotic activity. To avoid self-inhibition, the producing cells often encode cognate export and/or resistance mechanisms in the biosynthetic gene clusters for these molecules. Actinorhodin is a blue-pigmented antibiotic produced by
Streptomyces coelicolor
. The
actAB
operon, carried in the actinorhodin biosynthetic gene cluster, encodes two putative export pumps and is regulated by the transcriptional repressor protein ActR. In this work, we show that normal actinorhodin yields require
actAB
expression. Consistent with previous
in vitro
work, we show that both actinorhodin and its 3-ring biosynthetic intermediates [e.g., (
S
)-DNPA] can relieve repression of
actAB
by ActR
in vivo
. Importantly, an ActR mutant that interacts productively with (
S
)-DNPA but not with actinorhodin responds to the actinorhodin biosynthetic pathway with the induction of
actAB
and normal yields of actinorhodin. This suggests that the intermediates are sufficient to trigger the export genes in actinorhodin-producing cells. We further show that actinorhodin-producing cells can induce
actAB
expression in nonproducing cells; however, in this case actinorhodin is the most important signal. Finally, while the “intermediate-only” ActR mutant permits sufficient
actAB
expression for normal actinorhodin yields, this expression is short-lived. Sustained culture-wide expression requires a subsequent actinorhodin-mediated signaling step, and the defect in this response causes widespread cell death. These results are consistent with a two-step model for actinorhodin export and resistance where intermediates trigger initial expression for export from producing cells and actinorhodin then triggers sustained export gene expression that confers culture-wide resistance.
IMPORTANCE
Understanding the links between antibiotic resistance and biosynthesis is important for our efforts to manipulate secondary metabolism. For example, many secondary metabolites are produced at low levels; our work suggests that manipulating export might be one way to enhance yields of these molecules. It also suggests that understanding resistance will be relevant to the generation of novel secondary metabolites through the creation of synthetic secondary metabolic gene clusters. Finally, these cognate resistance mechanisms are related to mechanisms that arise in pathogenic bacteria, and understanding them is relevant to our ability to control microbial infections clinically.
Publisher
American Society for Microbiology
Cited by
51 articles.
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