Regulation of the
 cnr
 Cobalt and Nickel Resistance Determinant of
 Ralstonia eutropha
 (
 Alcaligenes eutrophus
 ) CH34

Tibazarwa, Caritas; Wuertz, Stefan; Mergeay, M.; Wyns, Lode; Lelie, Daniël van der

doi:10.1128/jb.182.5.1399-1409.2000

Cited by 107 publications

(97 citation statements)

References 30 publications

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“…The sequence of the insertion in the cnrY1(Con) mutant gene contains a nearly complete duplication of the sequence CGCGACGCGTgGCG tGC (nonidentical base pairs are shown in lowercase) located directly downstream of the 14-bp insertion. Although the site of this putative target duplication is different from that of the insertion of IS1087 reported in the accompanying study (38), this duplication is a strong hint that an insertion sequence element was also responsible for the cnrY1(Con) mutation in strain DN195(pMOL28-4). The mutation leads to a frameshift resulting in the expression of a 134-amino-acid (aa) mutant protein which is identical in its amino-terminal 46 aa to CnrY but continues in another reading frame thereafter (15,38).…”

Section: Fig 2 Rt-pcr Of the Cnrc Regionmentioning

confidence: 61%

“…Although the site of this putative target duplication is different from that of the insertion of IS1087 reported in the accompanying study (38), this duplication is a strong hint that an insertion sequence element was also responsible for the cnrY1(Con) mutation in strain DN195(pMOL28-4). The mutation leads to a frameshift resulting in the expression of a 134-amino-acid (aa) mutant protein which is identical in its amino-terminal 46 aa to CnrY but continues in another reading frame thereafter (15,38). In contrast to CnrY, the mutant protein does not contain a possible transmembrane ␣-helix.…”

Section: Fig 2 Rt-pcr Of the Cnrc Regionmentioning

confidence: 61%

“…The PhoA data clearly demonstrate that the carboxy termini of CnrX and CnrY are in the periplasm. CnrH is indeed a sigma factor as shown by gel retardation assays (38) and runoff transcription (G. Grass, S. Kühnemund, and D. H. Nies, unpublished data). Thus, it is possible that CnrH is controlled by a CnrYX transmembrane anti-sigma factor complex which binds CnrH in the absence of Ni 2ϩ .…”

Section: Discussionmentioning

confidence: 99%

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Regulation of the cnr Cobalt and Nickel Resistance Determinant from Ralstonia sp. Strain CH34

2000

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Ralstonia sp. strain CH34 is resistant to nickel and cobalt cations. Resistance is mediated by the cnr determinant located on plasmid pMOL28. The cnr genes are organized in two clusters, cnrYXH and cnrCBA. As revealed by reverse transcriptase PCR and primer extension, transcription from these operons is initiated from promoters located upstream of the cnrY and cnrC genes. These two promoters exhibit conserved sequences at the ؊10 (CCGTATA) and ؊35 (CRAGGGGRAG) regions. The CnrH gene product, which is required for expression of both operons, is a sigma factor belonging to the sigma L family, whose activity seems to be governed by the membrane-bound CnrY and CnrX gene products in response to Ni 2؉. Half-maximal activation from the cnrCBA operon was determined by using appropriate lacZ gene fusions and was shown to occur at an Ni 2؉ concentration of about 50 M.Ralstonia sp. strain CH34 (formerly Alcaligenes eutrophus strain CH34 [3]) contains at least seven determinants encoding resistances to toxic heavy metals, located either on the bacterial chromosome or on one of the two indigenous plasmids pMOL28 (180 kb [37]) and pMOL30 (238 kb [7,20]). The cnr determinant of plasmid pMOL28 mediates inducible resistance to Co 2ϩ and Ni 2ϩ in Ralstonia sp. strain CH34 (15). The cnr determinant is similar to ncc (nickel-cobalt-cadmium resistance) of Alcaligenes xylosoxidans 31A (34) and czc (cobaltzinc-cadmium resistance) on plasmid pMOL30 of Ralstonia sp. strain CH34 (28). All three resistances are based on cation efflux, which is best characterized for Czc (13,24,29). In analogy to Czc (9, 25, 28, 32), the products of the genes cnrA, cnrB, and cnrC are likely to form a membrane-bound protein complex catalyzing an energy-dependent efflux of Ni 2ϩ and Co 2ϩ , and the mechanism of action of the CnrCBA complex may be that of a proton/cation antiporter.Three regulators seem to control Cnr, an extracellular function (ECF) sigma factor (CnrH) and the products of two additional genes with unknown precise functions (CnrX and CnrY products, respectively) (15, 16). The genes cnrYXH are located upstream of cnrCBA and have the same direction of transcription. Transposon Tn5 insertion upstream of cnrH led to a constitutive expression of nickel resistance and to low zinc resistance as well (4, 15). However, this may be a polar effect and, additionally, a readthrough from a transposon promoter. As shown with Tn5-lacZ fusions (31), cnr is best induced by 128 M Ni 2ϩ . Other metals serve as less efficient inducers; however, this experiment was done with nickel-sensitive cnr-lacZ transposon-insertion mutants. In this study an improved cnrCBA-lacZ operon fusion was constructed, which mediates full nickel resistance and which was used to evaluate the physiology of cnr regulation.

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Section: Fig 2 Rt-pcr Of the Cnrc Regionmentioning

confidence: 61%

Section: Fig 2 Rt-pcr Of the Cnrc Regionmentioning

confidence: 61%

Section: Discussionmentioning

confidence: 99%

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Regulation of the cnr Cobalt and Nickel Resistance Determinant from Ralstonia sp. Strain CH34

2000

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“…1). Previously characterized ECF-type factors control a variety of functions including expression of heat-shock genes in E. coli (67); biosynthesis of alginates (exopolysaccharides containing D-mannuronic and L-guluronic acids) in Pseudomonas aeruginosa (68); iron uptake in E. coli (69); nickel and cobalt efflux in Alcaligenes europhus (70); outer membrane protein synthesis in response to variations in osmolarity, barometric pressure, and temperature in Photobacterium spp. (71); and cellular responses to disulphide stress in Streptomyces coelicolor (72).…”

Section: B Thetaiotaomicron: Sense and Sensibility (And Factors)mentioning

confidence: 99%

Honor thy symbionts

Gordon

2003

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

775

413

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Our intestine is the site of an extraordinarily complex and dynamic environmentally transmitted consortial symbiosis. The molecular foundations of beneficial symbiotic host-bacterial relationships in the gut are being revealed in part from studies of simplified models of this ecosystem, where germ-free mice are colonized with specified members of the microbial community, and in part from comparisons of the genomes of members of the intestinal microbiota. The results emphasize the contributions of symbionts to postnatal gut development and host physiology, as well as the remarkable strategies these microorganisms have evolved to sustain their alliances. These points are illustrated by the humanBacteroides thetaiotaomicron symbiosis. Interdisciplinary studies of the effects of the intestinal environment on genome structure and function should provide important new insights about how microbes and humans have coevolved mutually beneficial relationships and new perspectives about the foundations of our health.gut microbial ecology ͉ gnotobiotic mice ͉ glycobiome ͉ ecogenomics ͉ environmental sensing

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“…Well-studied examples include Ralstonia metallidurans CH34 and Achromobacter xylosoxidans 31A (8,24). The determinant responsible for nickel resistance in R. metallidurans CH34, cnr (cobalt-nickel resistance), encodes three regulatory genes (cnrY, cnrX, and cnrH) and three structural genes encoding the subunits of the Co-Ni efflux pump (cnrC, cnrB, and cnrA) (8,26). The cnr determinant is similar to the ncc determinant (nickel-cobalt-cadmium resistance) of A. xylosoxidans 31A.…”

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confidence: 99%

NreB from Achromobacter xylosoxidans 31A Is a Nickel-Induced Transporter Conferring Nickel Resistance

et al. 2001

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There are two distinct nickel resistance loci on plasmid pTOM9 from Achromobacter xylosoxidans 31A, ncc and nre. Expression of the nreB gene was specifically induced by nickel and conferred nickel resistance on both A. xylosoxidans 31A and Escherichia coli. E. coli cells expressing nreB showed reduced accumulation of Ni 2؉ , suggesting that NreB mediated nickel efflux. The histidine-rich C-terminal region of NreB was not essential but contributed to maximal Ni 2؉ resistance.Nickel is the 24th most abundant element in the earth's crust and has been detected in different media in all parts of the biosphere. Nickel is classified as a borderline metal ion because it has both soft and hard metal properties and can bind to sulfur, nitrogen, and oxygen groups (3). In many bacteria, nickel is required for enzymes such as urease, CO dehydrogenase, and hydrogenase (5, 10). However, excess nickel is toxic. Nickel binds to proteins and nucleic acids and frequently inhibits enzymatic activity, DNA replication, transcription, and translation (1). Several nickel-resistant bacteria have been isolated from heavy-metal-contaminated sites. Well-studied examples include Ralstonia metallidurans CH34 and Achromobacter xylosoxidans 31A (8, 24). The determinant responsible for nickel resistance in R. metallidurans CH34, cnr (cobalt-nickel resistance), encodes three regulatory genes (cnrY, cnrX, and cnrH) and three structural genes encoding the subunits of the Co-Ni efflux pump (cnrC, cnrB, and cnrA) (8,26). The cnr determinant is similar to the ncc determinant (nickel-cobalt-cadmium resistance) of A. xylosoxidans 31A. The proposed gene products for the efflux system CnrCBA and NccCBA are largely homologous to the gene products for the three subunits of the better-characterized CzcCBA cation-proton antiporter and probably have a similar function (16,17,27). In addition to the ncc locus, A. xylosoxidans 31A contains another distinct nickel resistance locus, nre, located on plasmid pTOM9. The nre locus confers low-level nickel resistance on both Ralstonia and Escherichia coli strains (24). The closest homologue of the deduced nreB gene product is NrsD from Synechocystis sp. strain PCC 6803 (6). Both NreB and NrsD belong to the major facilitator superfamily (MFS), and computer analysis indicates 12 putative transmembrane helices in each (11,20). Additionally, both proteins possess histidine-rich C termini possibly implicated in metal binding (6).In this study, we characterized the nre locus of A. xylosoxidans 31A and showed that only nreB is required for nickel resistance. In A. xylosoxidans, nreB was specifically induced by nickel but not by cobalt or zinc. The histidine-rich C terminus was not essential for NreB function but was necessary for maximum nickel resistance. E. coli cells harboring nreB showed reduced uptake of nickel compared to that of wild-type cells. The data support our hypothesis that NreB is a Ni 2ϩ transporter responsible for Ni 2ϩ efflux and resistance in A. xylosoxidans 31A and E. coli. MATERIALS AND METHODSBacterial...

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Regulation of the cnr Cobalt and Nickel Resistance Determinant of Ralstonia eutropha ( Alcaligenes eutrophus ) CH34

Cited by 107 publications

References 30 publications

Regulation of the cnr Cobalt and Nickel Resistance Determinant from Ralstonia sp. Strain CH34

Regulation of the cnr Cobalt and Nickel Resistance Determinant from Ralstonia sp. Strain CH34

Honor thy symbionts

NreB from Achromobacter xylosoxidans 31A Is a Nickel-Induced Transporter Conferring Nickel Resistance

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