Sulfide-responsive transcriptional repressor SqrR functions as a master regulator of sulfide-dependent photosynthesis

Shimizu, Takayuki; Shen, Jianzhao; Fang, Mingxu; Zhang, Yixiang; Hori, Koichi; Trinidad, Jonathan C.; Bauer, Carl E.; Giedroc, David P.; Masuda, Shinji

doi:10.1073/pnas.1614133114

Cited by 70 publications

(104 citation statements)

References 56 publications

Supporting

Mentioning

103

Contrasting

Order By: Relevance

“…Ensemble models of allostery provide a solution to this problem (1,19). For example, in the ArsR superfamily (25), CzrA senses Zn in the α5 ligand-binding site, CadC and CmtR sense Cd and Pb in the α4 and α3 sites, respectively, while sensing of reactive oxygen, sulfur (53) and electrophilic species (54) occurs in the α2 and α1 sites (Fig. 5C and Fig.…”

Section: Discussionmentioning

confidence: 99%

Entropy redistribution controls allostery in a metalloregulatory protein

Capdevila

Braymer

Edmonds

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

140

View full text Add to dashboard Cite

Allosteric communication between two ligand-binding sites in a protein is a central aspect of biological regulation that remains mechanistically unclear. Here we show that perturbations in equilibrium picosecond-nanosecond motions impact zinc (Zn)-induced allosteric inhibition of DNA binding by the Zn efflux repressor CzrA (chromosomal zinc-regulated repressor). DNA binding leads to an unanticipated increase in methyl side-chain flexibility and thus stabilizes the complex entropically; Zn binding redistributes these motions, inhibiting formation of the DNA complex by restricting coupled fast motions and concerted slower motions. Allosterically impaired CzrA mutants are characterized by distinct nonnative fast internal dynamics "fingerprints" upon Zn binding, and DNA binding is weakly regulated. We demonstrate the predictive power of the wild-type dynamics fingerprint to identify key residues in dynamics-driven allostery. We propose that driving forces arising from dynamics can be harnessed by nature to evolve new allosteric ligand specificities in a compact molecular scaffold. Technological advances in structural biology have permitted insights (3-5) into how changes in protein structure and flexibility contribute to allostery (6-9). Allostery likely employs a continuum of mechanisms, from domain or subunit rearrangements to predominantly side-chain and backbone dynamics (6-8, 10, 11), to affect biological regulation (1). Although these motions clearly impact site-site communication via defined molecular pathways (9) or energy level perturbations at distant sites (12), an allosteric effect without conformational change remains largely a theoretical postulate (10,13,14). In this context, changes in dynamics upon ligand binding (8,(15)(16)(17)(18)(19)(20) have long been predicted to impact allostery (5, 14, 17, 21); however, obtaining a quantitative experimental demonstration of the role of conformational entropy in allosteric systems remains challenging. Here we test these ideas in the context of heterotropic linkage and pinpoint fast internal dynamics as a primary contributor to functional, structure-encoded dynamics. We report an example of allostery where side-chain rotamer degeneracy is largely responsible for coupling two ligand-binding events through perturbations in a dynamic network that is required for both entropic and enthalpic driving forces.Our model system for studying heterotropic allostery is the transcriptional regulator CzrA (chromosomal zinc-regulated repressor) from the bacterial pathogen Staphylococcus aureus (22-25) ( Fig. 1 and Fig. S1A). Zinc homeostasis is critical to the virulence of S. aureus (26) and of many other microbial pathogens, and allows the organism to adapt to host-imposed zinc toxicity or limitation (27, 28). CzrA is a member of the ubiquitous arsenic repressor (ArsR) family of metalloregulatory proteins (25, 29), individual members of which are capable of sensing a wide array of metal, metalloid, and nonmetal inducers on distinct sites on a relatively simple, homodimeric wi...

show abstract

Section: Discussionmentioning

confidence: 99%

Entropy redistribution controls allostery in a metalloregulatory protein

Capdevila

Braymer

Edmonds

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

140

View full text Add to dashboard Cite

show abstract

“…The C-terminal α5 site in ArsR repressors, represented by S. aureus CzrA [88], is composed of an all N/O-donor ligand set used to coordinate harder metals such as Zn II ; in some cases, the α5 site is further elaborated to bind Ni II and Co II with octahedral coordination geometries, achieved by the recruitment of N/O donors from the extreme N-terminal tail [89]. It is becoming increasingly clear that ArsRs are not restricted to metal sensing [90–98], with individual members now known to have evolved to sense ROS [93,94,98,99] and RSS [90,92] via a conserved cysteine pair in the α2 and α5 helices, while RES appear to be sensed by a cysteine in α1 helix [91]. It is important to point out here that redox-sensing ArsR family members are often misannotated as MarR family members due to known or anticipated functional similarities ( vide infra ).…”

Section: Metal Efflux Regulatorsmentioning

confidence: 99%

“…This will not, however, be discussed further here and we direct the reader instead to a number of recent reviews on this subject [17,21–23]. We provide sufficient mechanistic detail to pique the interest of the reader, while drawing general conclusions from recent findings in this rapidly expanding field [3,20,90,101]. …”

Section: Introductionmentioning

confidence: 99%

Metallochaperones and metalloregulation in bacteria

Capdevila

Edmonds

Giedroc

2017

Essays in Biochemistry

115

View full text Add to dashboard Cite

Bacterial transition metal homoeostasis or simply ‘metallostasis’ describes the process by which cells control the intracellular availability of functionally required metal cofactors, from manganese (Mn) to zinc (Zn), avoiding bothmetal deprivation and toxicity. Metallostasis is an emerging aspect of the vertebrate host–pathogen interface that is defined by a ‘tug-of-war’ for biologically essential metals and provides the motivation for much recent work in this area. The host employs a number of strategies to starve the microbial pathogen of essential metals, while for others attempts to limit bacterial infections by leveraging highly competitive metals. Bacteria must be capable of adapting to these efforts to remodel the transition metal landscape and employ highly specialized metal sensing transcriptional regulators, termed metalloregulatory proteins, and metallochaperones, that allocate metals to specific destinations, to mediate this adaptive response. In this essay, we discuss recent progress in our understanding of the structural mechanisms and metal specificity of this adaptive response, focusing on energy-requiring metallochaperones that play roles in the metallocofactor active site assembly in metalloenzymes and metallosensors, which govern the systems-level response to metal limitation and intoxication.

show abstract

“…The fact that three Cys are functionally required and conserved in most FisRs suggests the possibility of thiol‐disulfide exchange after initial formation of a non‐native disulfide, as pointed out by the authors (Li et al ., ). In fact, R. capsulatus SqrR harbors a third cysteine, which although not required in cells for RSS sensing, changes the scope of oxidative reaction products obtained upon incubation with glutathione persulfide (Shimizu et al ., ). Do organic or inorganic per‐ and polysulfide species (see Fig.…”

Section: Introductionmentioning

confidence: 97%

“…This ‘action at a distance’ is mediated by integration host factor (IHF), which introduces a bend in the DNA, positioning bound FisR in close proximity to the promotor‐bound RNA polymerase, with ATP hydrolysis stimulating open complex formation and transcription initiation (Hartman et al ., ). The striking similarity to previous work (Luebke et al ., ; Shimizu et al ., ) is that FisR contains three conserved Cys residues (C53, C64 and C71) in the R domain and reduced FisR is activated by exposure to glutathione persulfide and inorganic polysulfide RSS (see Fig. C).…”

Section: Introductionmentioning

confidence: 99%

A new player in bacterial sulfide‐inducible transcriptional regulation

Giedroc

2017

Molecular Microbiology

Self Cite

View full text Add to dashboard Cite

Summary Although hydrogen sulfide (H2S) is perhaps best known as a toxic gas, the electron-rich H2S functions as an energy source and electron donor for chemolithotrophic and photosynthetic bacteria, via sulfide oxidation, and is a universal substrate for cysteine biosynthesis. These distinct harmful and beneficial roles of H2S suggest the need to “sense” prevailing concentrations of sulfide and downstream reactive sulfur species (RSS) and regulate the expression of genes mediating sulfide homeostasis. The paper by Li et al. in this issue of Molecular Microbiology adds Cupriavidus FisR to an expanding repertoire of regulatory mechanisms that bacteria have evolved to sense cellular RSS and mitigate their deleterious effects.

show abstract

Sulfide-responsive transcriptional repressor SqrR functions as a master regulator of sulfide-dependent photosynthesis

Cited by 70 publications

References 56 publications

Entropy redistribution controls allostery in a metalloregulatory protein

Entropy redistribution controls allostery in a metalloregulatory protein

Metallochaperones and metalloregulation in bacteria

A new player in bacterial sulfide‐inducible transcriptional regulation

Contact Info

Product

Resources

About