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Abstract
ABSTRACTStaphylococcus aureus is responsible for a significant amount of devastating disease. Its ability to colonize the host and cause infection is supported by a variety of proteins that are dependent on the cofactor heme. Heme is a porphyrin used broadly across kingdoms and is synthesized de novo from common cellular precursors and iron. While heme is critical to bacterial physiology, it is also toxic in high concentrations, requiring that organisms encode regulatory processes to control heme homeostasis. In this work, we describe a posttranscriptional regulatory strategy in S. aureus heme biosynthesis. The first committed enzyme in the S. aureus heme biosynthetic pathway, glutamyl-tRNA reductase (GtrR), is regulated by heme abundance and the integral membrane protein HemX. GtrR abundance increases dramatically in response to heme deficiency, suggesting a mechanism by which S. aureus responds to the need to increase heme synthesis. Additionally, HemX is required to maintain low levels of GtrR in heme-proficient cells, and inactivation of hemX leads to increased heme synthesis. Excess heme synthesis in a ΔhemX mutant activates the staphylococcal heme stress response, suggesting that regulation of heme synthesis is critical to reduce self-imposed heme toxicity. Analysis of diverse organisms indicates that HemX is widely conserved among heme-synthesizing bacteria, suggesting that HemX is a common factor involved in the regulation of GtrR abundance. Together, this work demonstrates that S. aureus regulates heme synthesis by modulating GtrR abundance in response to heme deficiency and through the activity of the broadly conserved HemX.
Highlights
Staphylococcus aureus is responsible for a significant amount of devastating disease
We hypothesized that comparing the S. aureus wild type (WT) to a strain incapable of synthesizing heme (Fig. 1A and B) would allow the identification of specific steps in heme synthesis that respond to cellular heme content, directly or mbio.asm.org 3 indirectly
We sought to determine whether the increase in glutamyl-tRNA reductase (GtrR) abundance in the pbgS mutant was the result of heme deficiency or a general defect in respiration
Summary
Staphylococcus aureus is responsible for a significant amount of devastating disease. This work demonstrates that S. aureus regulates heme synthesis by modulating GtrR abundance in response to heme deficiency and through the activity of the broadly conserved HemX. S. aureus encodes the newly appreciated coproporphyrin-dependent heme synthesis pathway to populate its hemoproteins [5, 6] These include the terminal oxidases, catalase, and bacterial nitric oxide synthase, all of which contribute to growth, protection from host defenses, and pathogenesis [3, 7,8,9]. Under conditions of excess exogenous heme, the heme stress response in S. aureus is activated by the hemesensing two-component system HssRS, which regulates the transcription of a putative efflux pump, HrtAB This system is critical for growth and survival in toxic concentrations of heme and modulates pathogenesis in a murine model of disease [10]. Sensing or regulatory pathways that connect heme synthesis with heme availability, hemoprotein abundance, or HssRS activation have not been identified
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