Behind the Shield of Czc: ZntR Controls Expression of the Gene for the Zinc-exporting P-type ATPase ZntA in

Overview

Journal J Bacteriol

Publisher American Society for Microbiology

Specialty Microbiology

Date 2021 Mar 9

PMID 33685972

Citations 14

Authors

Vladislava Schulz

Christopher Schmidt-Vogler

Phillip Strohmeyer

Stefanie Weber

Daniel Kleemann

Dietrich H Nies

Martin Herzberg

Affiliations

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Abstract

In the metallophilic beta-proteobacterium , the plasmid-encoded Czc metal homeostasis system adjusts the periplasmic zinc, cobalt and cadmium concentration, which influences subsequent uptake of these metals into the cytoplasm. Behind this shield, the P-type APTase ZntA is responsible for removal of surplus cytoplasmic zinc ions, thereby providing a second level of defense against toxic zinc concentrations. ZntA is the counterpart to the Zur-regulated zinc uptake system ZupT and other import systems; however, the regulator of expression was unknown. The chromid-encoded gene is adjacent to the genes , which are located on the complementary DNA strand and transcribed from a common promoter region. These genes encode homologs of plasmid pMOL30-encoded Czc components. Candidates for possible regulators of were identified and subsequently tested: CzcI, CzcI, and the MerR-type gene products of the locus tags Rmet_2302, Rmet_0102, Rmet_3456. This led to the identification of Rmet_3456 as ZntR, the main regulator of expression. Moreover, both CzcIs decreased Czc-mediated metal resistance, possibly to avoid "over-excretion" of periplasmic zinc ions, which could result in zinc starvation due to diminished zinc uptake into the cytoplasm. Rmet_2302 was identified as CadR, the regulator of the gene for an important cadmium-exporting P-type ATPase, which provides another system for removal of cytoplasmic zinc and cadmium. Rmet_0102 was not involved in regulation of the metal resistance systems examined here. Thus, ZntR forms a complex regulatory network with CadR, Zur and the CzcIs. Moreover, these discriminating regulatory proteins assign the efflux systems to their particular function.Zinc is an essential metal for numerous organisms from humans to bacteria. The transportome of zinc uptake and efflux systems controls the overall cellular composition and zinc content in a double feed-back loop. Zinc starvation mediates, via the Zur regulator, an up-regulation of the zinc import capacity via the ZIP-type zinc importer ZupT and an amplification of zinc storage capacity, which together raise the cellular zinc content again. On the other hand, an increasing zinc content leads to ZntR-mediated up-regulation of the zinc efflux system ZntA, which decreases the zinc content. Together, the Zur regulon components and ZntR/ZntA balance the cellular zinc content under both high external zinc concentrations and zinc starvation conditions.

Citing Articles

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Galea D, Herzberg M, Dobritzsch D, Fuszard M, Nies D Metallomics. 2024; 16(12).

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The efflux system CdfX exports zinc that cannot be transported by ZntA in .

Schulz V, Galea D, Schleuder G, Strohmeyer P, Grosse C, Herzberg M J Bacteriol. 2024; 206(11):e0029924.

PMID: 39475293 PMC: 11580412. DOI: 10.1128/jb.00299-24.

The metal-binding GTPases CobW2 and CobW3 are at the crossroads of zinc and cobalt homeostasis in .

Galea D, Herzberg M, Nies D J Bacteriol. 2024; 206(8):e0022624.

PMID: 39041725 PMC: 11340326. DOI: 10.1128/jb.00226-24.

The genes and are involved in zinc tolerance of .

Schurmann J, Fischer M, Herzberg M, Reemtsma T, Strommenger B, Werner G Appl Environ Microbiol. 2024; 90(6):e0045324.

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In a state of flux: new insight into the transport processes that maintain bacterial metal homeostasis.

Kwiatos N, Waldron K J Bacteriol. 2024; 206(5):e0014624.

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