Bacterial Mg<sup>2+</sup>Homeostasis, Transport, and Virulence

Groisman, Eduardo A.; Hollands, Kerry; Kriner, Michelle; Lee, Eun Jin; Park, Sun Yang; Pontes, Mauricio H.

doi:10.1146/annurev-genet-051313-051025

Cited by 211 publications

(212 citation statements)

References 127 publications

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“…2B, [105-125]). The modest decrease in affinity displayed by the RNA with mutations in a rut in the mgtCBR leader is in contrast to the effect of mutation of a rut site in the mgtA leader region (15,25), which decreased affinity for Rho eightfold [ , and Δ51-60), suggesting that this region serves as a genuine rut site. Cumulatively, our findings revealed two distinctive features of Rho interaction with the mgtCBR RNA.…”

Section: Rho Binds Normally To Mgtcbr Leader Variants With Rare Singlementioning

confidence: 89%

An RNA motif advances transcription by preventing Rho-dependent termination

Sevostyanova

Groisman

2015

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

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The transcription termination factor Rho associates with most nascent bacterial RNAs as they emerge from RNA polymerase. However, pharmacological inhibition of Rho derepresses only a small fraction of these transcripts. What, then, determines the specificity of Rho-dependent transcription termination? We now report the identification of a Rho-antagonizing RNA element (RARE) that hinders Rho-dependent transcription termination. We establish that RARE traps Rho in an inactive complex but does not prevent Rho binding to its recruitment sites. Although translating ribosomes normally block Rho access to an mRNA, inefficient translation of an open reading frame in the leader region of the Salmonella mgtCBR operon actually enables transcription of its associated coding region by favoring an RNA conformation that sequesters RARE. The discovery of an RNA element that inactivates Rho signifies that the specificity of nucleic-acid binding proteins is defined not only by the sequences that recruit these proteins but also by sequences that antagonize their activity.T ranscription factors recognize sequence and structural elements in DNA and RNA to turn genes on or off. The transcription termination factor Rho is responsible for the majority of factor-dependent termination events in enteric bacterial species (1). Rho prevents the production of dysfunctional, and potentially dangerous, RNAs (2). For instance, Rho implements transcriptional polarity, a process whereby compromised translation of a promoter-proximal gene reduces transcription of downstream genes in an operon (3-5).Rho is a hexameric helicase that binds RNA and translocates in the 5′-to-3′ direction using the energy derived from ATP hydrolysis. Initially, RNA is anchored to Rho primary binding sites on the surface of the hexamer. Rho recruitment sites tend to be rich in Cs and Us and free of strong secondary structures (6-8). Interaction with a recruitment site causes the Rho hexamer to open briefly, allowing the RNA 3′ region to pass through the center, where secondary binding sites are located (9, 10). Further contact between the RNA and the secondary binding sites stimulates Rho's ATPase activity (11). Using the energy derived from ATP hydrolysis, Rho translocates along an RNA until it reaches a paused RNA polymerase (RNAP) and promotes transcription termination (12).The specificity of Rho-dependent transcription termination has remained enigmatic because Rho associates with many newly transcribed RNAs in Escherichia coli (13), but only a portion of these messages is affected when bacteria are treated with bicyclomycin (BCM) (1), a Rho-specific inhibitor (14). In other words, binding of Rho to a particular RNA is not sufficient for subsequent transcription termination.Rho-dependent terminators are typically found at the end of operons; however, they can also be present in the leader region of mRNAs, where they perform regulatory functions (15)(16)(17)). This appears to be the case for the 296-nt-long leader region of the mgtCBR transcript from Salmonella enteri...

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Section: Rho Binds Normally To Mgtcbr Leader Variants With Rare Singlementioning

confidence: 89%

An RNA motif advances transcription by preventing Rho-dependent termination

Sevostyanova

Groisman

2015

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

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“…Mg 2+ cannot diffuse freely through membranes and therefore has to be imported through dedicated channels, using the electrochemical gradient of this ion (Payandeh et al, 2013). On the molecular level this transport is best understood in prokaryotes, where import of Mg 2+ has been linked to four classes of transporters: CorA, MgtA/B, MgtE, and a recently described Nramp-related transporter (Kehres and Maguire, 2002; Groisman et al, 2013; Shin et al, 2014). Most bacteria possess several Mg 2+ transporters and sometimes several from one class.…”

Section: Introductionmentioning

confidence: 99%

An Essential Factor for High Mg2+ Tolerance of Staphylococcus aureus

et al. 2016

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Internal bacterial concentration of Mg2+, the most abundant divalent cation in living cells, is estimated to be in the single millimolar range. However, many bacteria will thrive in media with only micromolars of Mg2+, by using a range of intensely studied and highly efficient import mechanisms, as well as in media with very high magnesium concentration, presumably mediated by currently unknown export mechanisms. Staphylococcus aureus has a particularly high Mg2+ tolerance for a pathogen, growing unimpaired in up to 770 mM Mg2+, and we here identify SA0657, a key factor in this tolerance. The predicted domain structure of SA0657 is shared with a large number of proteins in bacteria, archaea and even eukarya, for example CorB from Salmonella and the human CNNM protein family. One of the shared domains, a CBS pair potentially involved in Mg2+ sensing, contains the conserved Glycine326 which we establish to be a key residue for SA0657 function. In light of our findings, we propose the name MpfA, Magnesium Protection Factor A, for SA0657.

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“…And fourth, the PhoP/PhoQ system governs expression of genes responsible for a variety of chemical modifications of the phosphate residues in the lipopolysaccharide (LPS) portion of the outer membrane [28,61-64]. These modifications would make the Mg 2+ ions normally neutralizing the phosphate residues available for other Mg 2+ -dependent functions [65]. …”

Section: Introductionmentioning

confidence: 99%

“…That the expression of the mgtA , mgtCBR and mgtE Mg 2+ transporter genes responds to cytosolic Mg 2+ suggests that the corresponding gene products help bacteria cope with low cytosolic Mg 2+ . In this context, the PhoP-dependent modification of the LPS is proposed to make the Mg 2+ ions that normally neutralize the LPS available for transport into the cytoplasm by the PhoP-dependent Mg 2+ transporter(s) [65]. It has been estimated that about one third of the total Mg 2+ content of E. coli is bound to the LPS, suggesting that the LPS serves as a Mg 2+ reservoir [28].…”

Section: Introductionmentioning

confidence: 99%

When Too Much ATP Is Bad for Protein Synthesis

Pontes

Sevostyanova

Groisman

2015

Journal of Molecular Biology

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Adenosine triphosphate (ATP) is the energy currency of living cells. Even though ATP powers virtually all energy-dependent activity, most cellular ATP is utilized in protein synthesis via tRNA aminoacylation and GTP regeneration. Magnesium (Mg2+), the most common divalent cation in living cells, plays crucial roles in protein synthesis by maintaining the structure of ribosomes, participating in the biochemistry of translation initiation and functioning as a counter-ion for ATP. A non-physiological increase in ATP levels hinders growth in cells experiencing Mg2+ limitation because ATP is the most abundant nucleotide triphosphate in the cell and Mg2+ is also required for the stabilization of the cytoplasmic membrane and as a cofactor for essential enzymes. We propose that organisms cope with Mg2+ limitation by decreasing ATP levels and ribosome production, thereby reallocating Mg2+ to indispensable cellular processes.

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Bacterial Mg²⁺Homeostasis, Transport, and Virulence

Cited by 211 publications

References 127 publications

An RNA motif advances transcription by preventing Rho-dependent termination

An RNA motif advances transcription by preventing Rho-dependent termination

An Essential Factor for High Mg2+ Tolerance of Staphylococcus aureus

When Too Much ATP Is Bad for Protein Synthesis

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Bacterial Mg2+Homeostasis, Transport, and Virulence

Cited by 211 publications

References 127 publications

An RNA motif advances transcription by preventing Rho-dependent termination

An RNA motif advances transcription by preventing Rho-dependent termination

An Essential Factor for High Mg2+ Tolerance of Staphylococcus aureus

When Too Much ATP Is Bad for Protein Synthesis

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Bacterial Mg²⁺Homeostasis, Transport, and Virulence