RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization.
To survive diverse host environments, the human pathogen Streptococcus pneumoniae must prevent its self-produced, extremely high levels of peroxide from reacting with intracellular iron. However, the regulatory mechanism(s) by which the pneumococcus accomplishes this balance remains largely enigmati...
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Public Library of Science (PLoS)
2018-05-01
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| Series: | PLoS Pathogens |
| Online Access: | https://doi.org/10.1371/journal.ppat.1007052 |
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doaj-6e71c3ba02764d75bcc64dfb36ff03c72021-04-21T17:54:25ZengPublic Library of Science (PLoS)PLoS Pathogens1553-73661553-73742018-05-01145e100705210.1371/journal.ppat.1007052RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization.David G GlanvilleLanlan HanAndrew F MauleAlexandra WoodacreDevsaagar ThankiIman Tajer AbdullahIman Tajer AbdullahJulie A MorrisseyThomas B ClarkeHasan YesilkayaNicholas R SilvaggiAndrew T UlijaszTo survive diverse host environments, the human pathogen Streptococcus pneumoniae must prevent its self-produced, extremely high levels of peroxide from reacting with intracellular iron. However, the regulatory mechanism(s) by which the pneumococcus accomplishes this balance remains largely enigmatic, as this pathogen and other related streptococci lack all known redox-sensing transcription factors. Here we describe a two-component-derived response regulator, RitR, as the archetype for a novel family of redox sensors in a subset of streptococcal species. We show that RitR works to both repress iron transport and enable nasopharyngeal colonization through a mechanism that exploits a single cysteine (Cys128) redox switch located within its linker domain. Biochemical experiments and phylogenetics reveal that RitR has diverged from the canonical two-component virulence regulator CovR to instead dimerize and bind DNA only upon Cys128 oxidation in air-rich environments. Atomic structures show that Cys128 oxidation initiates a "helical unravelling" of the RitR linker region, suggesting a mechanism by which the DNA-binding domain is then released to interact with its cognate regulatory DNA. Expanded computational studies indicate this mechanism could be shared by many microbial species outside the streptococcus genus.https://doi.org/10.1371/journal.ppat.1007052 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
David G Glanville Lanlan Han Andrew F Maule Alexandra Woodacre Devsaagar Thanki Iman Tajer Abdullah Iman Tajer Abdullah Julie A Morrissey Thomas B Clarke Hasan Yesilkaya Nicholas R Silvaggi Andrew T Ulijasz |
| spellingShingle |
David G Glanville Lanlan Han Andrew F Maule Alexandra Woodacre Devsaagar Thanki Iman Tajer Abdullah Iman Tajer Abdullah Julie A Morrissey Thomas B Clarke Hasan Yesilkaya Nicholas R Silvaggi Andrew T Ulijasz RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization. PLoS Pathogens |
| author_facet |
David G Glanville Lanlan Han Andrew F Maule Alexandra Woodacre Devsaagar Thanki Iman Tajer Abdullah Iman Tajer Abdullah Julie A Morrissey Thomas B Clarke Hasan Yesilkaya Nicholas R Silvaggi Andrew T Ulijasz |
| author_sort |
David G Glanville |
| title |
RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization. |
| title_short |
RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization. |
| title_full |
RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization. |
| title_fullStr |
RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization. |
| title_full_unstemmed |
RitR is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization. |
| title_sort |
ritr is an archetype for a novel family of redox sensors in the streptococci that has evolved from two-component response regulators and is required for pneumococcal colonization. |
| publisher |
Public Library of Science (PLoS) |
| series |
PLoS Pathogens |
| issn |
1553-7366 1553-7374 |
| publishDate |
2018-05-01 |
| description |
To survive diverse host environments, the human pathogen Streptococcus pneumoniae must prevent its self-produced, extremely high levels of peroxide from reacting with intracellular iron. However, the regulatory mechanism(s) by which the pneumococcus accomplishes this balance remains largely enigmatic, as this pathogen and other related streptococci lack all known redox-sensing transcription factors. Here we describe a two-component-derived response regulator, RitR, as the archetype for a novel family of redox sensors in a subset of streptococcal species. We show that RitR works to both repress iron transport and enable nasopharyngeal colonization through a mechanism that exploits a single cysteine (Cys128) redox switch located within its linker domain. Biochemical experiments and phylogenetics reveal that RitR has diverged from the canonical two-component virulence regulator CovR to instead dimerize and bind DNA only upon Cys128 oxidation in air-rich environments. Atomic structures show that Cys128 oxidation initiates a "helical unravelling" of the RitR linker region, suggesting a mechanism by which the DNA-binding domain is then released to interact with its cognate regulatory DNA. Expanded computational studies indicate this mechanism could be shared by many microbial species outside the streptococcus genus. |
| url |
https://doi.org/10.1371/journal.ppat.1007052 |
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