Abstract
Generation of many useful microbe-derived secondary metabolites, including the red pigment prodigiosin of the bacterium Serratia marcescens, is inhibited by glucose. In a previous report, a genetic approach was used to determine that glucose dehydrogenase activity (GDH) is required for inhibiting prodigiosin production and transcription of the prodigiosin biosynthetic operon (pigA-N). However, the transcription factor(s) that regulate this process were not characterized. Here we tested the hypothesis that HexS, a LysR-family transcription factor similar to LrhA of Escherichia coli, is required for inhibition of prodigiosin by growth in glucose. We observed that mutation of the hexS gene in S. marcescens allowed the precocious production of prodigiosin in glucose-rich medium conditions that completely inhibited prodigiosin production by the wild type. Unlike previously described mutants able to generate prodigiosin in glucose-rich medium, hexS mutants exhibited GDH activity and medium acidification similar to the wild type. Glucose inhibittion of pigA expression was shown to be dependent upon HexS, suggesting that HexS is a key transcription factor in secondary metabolite regulation in response to medium pH. These data give insight into the prodigiosin regulatory pathway and could be used to enhance the production of secondary metabolites.
Highlights
The production of many secondary metabolites by microorganisms, such as antibiotics, is inhibited by growth in glucose-rich medium [1,2]
We observed that mutation of the hexS gene in S. marcescens allowed the precocious production of prodigiosin in glucose-rich medium conditions that completely inhibited prodigiosin production by the wild type
In a recently reported genetic screen, we identified mutants that produced prodigiosin on lysogeny broth (LB) glucose-supplemented agar plates (LBG) unlike the parental strain that was pigmentless on LBG [5]
Summary
The production of many secondary metabolites by microorganisms, such as antibiotics, is inhibited by growth in glucose-rich medium [1,2]. This is unfortunate as glucose is an ideal carbon source for growth of many microorganisms. Glucose inhibits prodigiosin production by S. marcescens [4] due to acidification of the medium [1,2], but the mechanism of this inhibition is incompletely understood. Et al, recently identified genes required for glucose dehydrogenase (GDH)-dependent inhibition of prodigiosin by medium acidification [5]. It was demonstrated that GDH activity in glucose rich medium is necessary for the rapid culture pH reduction, resulting in a complete inhibition of prodigiosin production. Expression of the prodigiosin biosynthetic operon, pigA-N [6,7] was inhibited by glucose-induced acidification, suggest-
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