Previous Article | Next Article 
Journal of Bacteriology, March 2000, p. 1390-1398, Vol. 182, No. 5
Institut für Mikrobiologie,
Martin-Luther-Universität Halle-Wittenberg, D-06099 Halle,
Germany
Received 19 July 1999/Accepted 16 November 1999
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 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 Co2+ and Ni2+ in
Ralstonia sp. strain CH34 (15). The
cnr determinant is similar to ncc
(nickel-cobalt-cadmium resistance) of Alcaligenes
xylosoxidans 31A (34) and czc
(cobalt-zinc-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 Ni2+ and
Co2+, 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 µM Ni2+. 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.
Bacterial strains and growth conditions.
Tris-buffered
mineral salts medium (20) containing 2 g of sodium
gluconate/liter was used to cultivate Ralstonia strains (Table 1). Solid Tris-buffered medium
contained 20 g of agar/liter.
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Regulation of the cnr Cobalt and Nickel
Resistance Determinant from Ralstonia sp. Strain
CH34
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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 Ni2+. Half-maximal activation from the cnrCBA
operon was determined by using appropriate lacZ gene
fusions and was shown to occur at an Ni2+ concentration of
about 50 µM.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-Galactosidase activity in
permeabilized cells was determined as published previously
(26), with 1 U defined as the activity forming 1 nmol of
o-nitrophenol per min at 30°C.
TABLE 1.
Bacterial strains and plasmids
Genetic techniques. Standard molecular genetic techniques were used (24, 33). For conjugative gene transfer, overnight cultures of donor strain Escherichia coli S17/1 (35) and of the Ralstonia recipient strains grown at 30°C in complex medium were mixed (1:1) and plated onto nutrient broth agar. After overnight growth, the bacteria were suspended in saline (9 g of NaCl/liter), diluted, and plated onto selective medium as previously described (24). DNA sequences were obtained with an A.L.F. sequencer (Pharmacia, Uppsala, Sweden). Total RNA of Ralstonia strains was isolated as described previously (11, 30).
Reporter protein fusions. The complete cnrY and cnrX genes were cloned into fusion vector pECD500 (phoA fusions) (32) in E. coli CC118 (17). Specific activity of alkaline phosphatase (17) was determined in triplicate as described previously (27).
Construction of a 
(cnrCBA-lacZ) transcriptional
fusion.
To construct the lacZ reporter strain
DN177(pMOL28-2), the 300 bp upstream of the cnrA stop codon
were PCR amplified as a PstI-XbaI fragment from
megaplasmid DNA of Ralstonia sp. strain AE126(pMOL28).
Similarly, the 300 bp downstream of the cnrA stop codon were
amplified as an XbaI-PstI fragment. These
fragments were digested with XbaI, but not with
PstI, and both fragments were cloned into vector plasmid
pGEM T-Easy (Promega, Madison, Wis.) in one step. As confirmed by
control sequencing, this led to a plasmid harboring a 600-bp
cnr fragment with an XbaI site located directly
downstream of the stop codon of cnrA, mutating the sequence
TGA8025GTTTGCGA (the TGA stop codon
of cnrA is in boldface) to
TGAGTTTCTAGA (numbering is according to
reference 15). The promoterless lacZ gene
of plasmid pMC1871 (Pharmacia, Freiburg, Germany) was inserted into the
XbaI site of this plasmid, and the fragment containing
cnr-lacZ was cloned as a PstI fragment into
plasmid pLO2 (14). Finally, the pLO2 hybrid plasmid with
(cnrCBA-lacZ) was used in a double-recombination event to
insert the lacZ gene downstream of cnrA on
megaplasmid pMOL28 as described previously (11). The correct
insertion and orientation of lacZ in strain DN177(pMOL28-2)
was verified by PCR and restriction endonuclease digestion (Fig.
1).
|
Construction of other bacterial strains.
The control region
cnrYXH was deleted from megaplasmid pMOL28-2 as previously
described (11), leading to strain DN190(pMOL28-3), which is
(cnrCBA-lacZ) 
cnrYXH (Fig. 1). Briefly, PCR
was used to amplify a 600-bp fragment from plasmid pMOL28. This
fragment contains the 300 bp upstream of cnrY, including the
first 24 bases of this gene (up to position G1006), and the
300 bp downstream of cnrH starting from C2261,
with the last 24 bases of that gene. Both fragments were joined using a
MunI site. With double recombination using a pLO2
derivative, the wild-type fragment on plasmid pMOL28-2 was exchanged
for this mutated fragment.
(2100 bp::pECD581)
(cnrCBA-lacZ) (Fig. 1). (Note that the region between bp
2100 and 2400 is duplicated and flanks the integrated vector plasmid
pLO2 on megaplasmid pMOL28-5 [Fig. 1].)
When plasmids used for complementation assays were generated, the
respective cnr genes were amplified from plasmid pMOL28 by
PCR (which introduced suitable restriction sites), cloned into pGEM
T-Easy (Promega), sequenced, and subcloned into the broad-host-range vector pVDZ'2 (6). To measure the activity of the
cnr promoters, cnrYp (bp 698 to 1284),
cnrHp (bp 1516 to 1740), and cnrCp (bp 2250 to
2360) were fused upstream to a promoterless lacZ gene and
into plasmid pVDZ'2 in the orientation opposite to that of the
lac promoter located on this vector plasmid (Table 1).
Primer extension and RT-PCR experiments. Primer extension analysis was performed with a modification of a standard protocol (33) using fluorescein-labeled oligonucleotides and an automated A.L.F. DNA Sequencer (Pharmacia, Uppsala, Sweden) as described previously (11, 39). The fluorescein-labeled 3' antisense primers (5'-GGCGCAGCAGATGGCACG for cnrYp and 5'-GGCTCAACGCAACGGG for cnrCp) were complementary to the corresponding gene regions. After phenol-chloroform extraction, the cDNA was precipitated with ethanol, vacuum dried, and suspended in 4 µl of H2O and 4 µl of A.L.F. stop solution (Pharmacia, Uppsala, Sweden). Following heat denaturation, the sample was loaded on a 7% polyacrylamide sequencing gel. In parallel, a sequencing reaction was performed with the same fluorescein-labeled primer and a DNA fragment containing the respective gene region. The transcription start site was determined by comparison of the retention time of the primer extension reaction with that of the sequencing reaction. Primer extension experiments with total RNA from plasmid-free AE104 cells and a control reaction carried out without reverse transcriptase were used as negative controls. Reverse transcriptase PCR (RT-PCR) was carried out as described previously (11) using various primer pairs (Fig. 1) and a variety of negative control reactions, such as those with RNA isolated from the plasmid-free strain AE104, with no RNA template, and with no reverse transcriptase, as described previously (11).
| |
RESULTS |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
Structures of the cnr mRNAs and the cnr
promoters.
After induction with 300 µM Ni2+ (10 min,
30°C, Tris-buffered mineral salts medium), total RNA was isolated
from cells of strain AE126(pMOL28). Northern mRNA-DNA hybridization
experiments with cnr-specific probes did not yield clear
signals, probably due to highly unstable cnr messages (data
not shown). Using RT-PCR, however, signals in the regions of
cnrA (the RT-PCR product contained bp 7734 to 8028 of
cnr [Fig. 1]), cnrC (bp 2360 to 2610 [Fig. 2]), and cnrH (bp 2086 to
2393 and 1934 to 2393 [Fig. 1]) indicated the presence of
transcripts. Additionally, RT-PCR revealed continuous transcripts from
cnrA into the incomplete orf104ff following
cnrA (bp 7736 to 8333) but no continuous transcript upstream
of cnrY (bp 698 to 1059 and 698 to 1204 [Fig. 1]). There
were no signals in the negative controls (RNA from the plasmid-free
strain AE104, given for cnrC in Fig. 2, lane B).
|
|
|
Activities of the cnr promoters cnrYp and
cnrCp.
The lacZ gene was cloned together with the
respective cnr promoter regions upstream into plasmid pVDZ'2
(6), leading to plasmid pDNA300 (cnrYp-lacZ),
pDNA299 (cnrCp-lacZ), or pDNA298 (cnrHp-lacZ). The last plasmid contained a possible ECF
sigma factor recognition site upstream of cnrH, but no
nickel induction of -galactosidase activity could be observed in
strain AE126(pMOL28) with plasmid pDNA298 (cnrHp-lacZ) in
trans (Table 2; Fig.
5). None of the three plasmids expressed
nickel-inducible -galactosidase activity in the megaplasmid-free
strain AE104 (data not shown). However, the plasmids with the
cnrYp and cnrCp promoters were nickel inducible
in AE126(pMOL28) (Fig. 5). The activity of cnrYp was about
twofold that of cnrCp, and there was also some induction when the cells started to grow in fresh medium without nickel (Table
2).
|
|
and 
), pDNA299
and 
), or pDNA298
and 
) were diluted
15-fold to a cell density of 30 Klett units into fresh medium
containing no added heavy metal (Induction of a (cnrCBA-lacZ) operon fusion by heavy
metal cations.
To study induction of cnr in a fully
nickel-resistant bacterial cell, the lacZ gene was inserted
immediately downstream of cnrCBA on plasmid pMOL28, leading
to lacZ reporter strain DN177(pMOL28-2). The metal
resistance of this strain was identical to the resistance of
AE126(pMOL28) as shown by determination of the MICs of Ni2+
and Co2+ on agar plates (Table
3) and in liquid medium (data not shown).
|
-galactosidase activity in DN177(pMOL28-2). Co2+ (0.5 mM), Zn2+ (0.3 mM), and chromate (0.1 mM) induced only
slightly (Fig. 6); due to the toxic
effects on AE126 strains, zinc and chromate concentrations lower than
the nickel concentration had to be used for induction. The increase in
-galactosidase activity after nickel induction was linear for at
least 4 h. At up to 0.5 mM Ni2+, the slope of this
increase was a function of the nickel concentration (data not shown).
The increase in -galactosidase activity could be described using
saturation kinetics in a Lineweaver-Burk plot (data not shown). The
regression coefficient was 1.00, the maximum increase in
-galactosidase activity after nickel induction was 94.8 U/h · mg (dry weight), and the nickel concentration required for half-maximal
induction was 49 µM. Induction of (cnr-lacZ) expression
with 2 mM Ni2+, however, was significantly lower than
induction with all of the other Ni2+ concentrations used,
probably due to the toxic effect of a nickel concentration close to the
MIC.
|
-galactosidase level
before induction was slightly higher in DN410(pMOL28-5) (103 U/mg [dry weight]) than in the control DN177(pMOL28-2) (64 U/mg
[dry weight]), probably due to some initiation of transcription from
unknown promoters located on plasmid pLO2, e.g., that of the kanamycin
resistance gene. After induction with 0.5 mM Ni2+, the
increase in the -galactosidase activity of
(cnrCBA-lacZ) in pMOL28-5 was 90.7 U/h · mg (dry
weight), which was similar to the control value with plasmid pMOL28-2
(86.4 U/h · mg [dry weight] [Table 2]). Thus, the activity
of cnrCp is sufficient to explain the observed induction of
(cnrCBA-lacZ) by nickel.
Deletion of cnrYXH almost abolishes cnr
induction by nickel.
To study the influence of cnrXYH
on cnr induction, these three genes were deleted from
pMOL28-2, leading to strain DN190(pMOL28-3) (cnrCBA-lacZ)
cnrYXH (Fig. 1). Both promoters, cnrYp and
cnrCp, were still present on plasmid pMOL28-3. Strain
DN190(pMOL28-3) showed a drastic reduction in nickel resistance when
compared to strain DN177(pMOL28-2) and to strain AE126(pMOL28);
however, DN190(pMOL28-3) was slightly more nickel resistant than the
plasmid-free strain AE104 (Table 3).
-galactosidase activity in the
cnrYXH deletion strain DN190(pMOL28-3) (Fig.
7) by 0.5 mM Ni2+, a level
similar to the induction level reached by DN177(pMOL28-2) after
induction with low concentrations of Co2+ (Fig. 6). To test
if cobalt resistance encoded by cnr is limited by
insufficient induction of cnrCBA, strain DN177(pMOL28-2)
was incubated in the presence of Co2+ and inducing
concentrations of Ni2+ (Table 3), and indeed, the MIC of
cobalt increased when Ni2+ induced Cnr. The MICs of
Zn2+ and Cd2+, however, did not change with
Ni2+ induction (data not shown).
|
(cnrCBA-lacZ) fusion in this strain (Fig. 7); however, the time-dependent increase in
-galactosidase activity was no longer linear. Thus, a strain carrying a deletion of cnrYXH had lost the nickel-specific
induction of Cnr, and this mutation could be complemented in
trans.
A variety of DN190(pMOL28-3) derivatives were constructed which
contained all combinations of cnrY, cnrX, and
cnrH in trans on the pVDZ'2 vector (6)
(Table 2). In these strains, any complementing plasmid harboring
cnrH (cnrH alone or the combination cnrXH or cnrYH) led to expression of
-galactosidase activity at a high constitutive level.
Complementation with cnrYH yielded the highest levels of
cnrCBA-lacZ expression observed in all experiments. All
strains without cnrH (cnrX alone,
cnrY, or cnrYX) were not inducible and remained
at a constitutive low level of -galactosidase expression. Thus, CnrH
alone is able to activate cnr expression, and both CnrY and
CnrX are needed for nickel control of CnrH.
Constitutive expression of cnr.
To learn more about the
interaction of the Cnr regulators, a mutant of strain AE126(pMOL28)
which expressed Cnr constitutively was isolated. This strain,
DN176(pMOL28-1), was isolated by a published procedure as a AE126
derivative able to grow in the presence of 1 mM Zn2+
(4), leading to DN176(pMOL28-1) cnrY1(Con). Into
pMOL28-1, lacZ was inserted downstream of
cnrCBA, leading to DN195(pMOL28-4) cnrY1(Con) (cnrCBA-lacZ). Strain
DN195(pMOL28-4) was resistant to a higher level of Ni2+
than DN177(pMOL28-2) and reached the same level of
Co2+ resistance as nickel-induced cells of
DN177(pMOL28-2) (Table 3).
(cnrCBA-lacZ) operon was expressed at a high
constitutive level in DN195(pMOL28-4) (Table 2). Again, nickel induced (cnrCBA-lacZ) when cnrYXH was supplied in
trans in strain DN195(pMOL28-4, pDNA191) (Table 2). However,
this strain did not loose its higher metal resistance (Table 3). The
cnrY1(Con) cnrXH region, PCR cloned from plasmid
pMOL28-4, led to constitutive expression of -galactosidase when
located in trans to cnrYXH in strain
DN190(pMOL28-3) (Table 2). Thus, the mutation leading to the
constitutive phenotype must be located in one of the three regulator
genes. When strain DN195(pMOL28-4) was complemented with single
regulator genes or combinations thereof, cnrX,
cnrH, or cnrXH did not restore nickel regulation
of cnr, but cnrY did (Table 2). However, for a
full complementation, cnrH and cnrX had to be
present; cnrYX repressed induction of cnr but did
not yield inducibility, while cnrYH did not complement at all.
DNA sequence analysis (data not shown) indicated an insertion of the
sequence CGCGACGCGTCGCGCGC at position 1111 of the
cnr sequence (15). Moreover, the wild-type
sequence as published (15) has to be corrected. The
published sequence is 1108-CGCCGCCGC-1117, but here the sequence was
determined to be only CGCCGC. The sequence of the insertion
in the cnrY1(Con) mutant gene contains a nearly complete
duplication of the sequence CGCGACGCGTgGCGtGC (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). In contrast to CnrY, the mutant protein does not contain a
possible transmembrane 
-helix.
The carboxy-terminal parts of CnrY and CnrX are located in the
periplasm.
With phoA fusions of the genes
cnrY and cnrX, specific activities of 32.4 ± 3.3 U/mg (dry weight) for cnrY and of 57.6 ± 2.2 U/mg (dry weight) for cnrX were determined. As a control,
the leader sequence of the -lactamase gene of plasmid pUC19
(40) was cloned upstream of the phoA gene in
plasmid pECD500 (32; T. Pribyl and D. H. Nies,
unpublished data), which leads to a specific PhoA activity of 41.6 ± 7.6 U/mg (dry weight). When the leader sequence of the -lactamase
gene was deleted (Pribyl and Nies, unpublished data), the specific
activity decreased to 1.4 ± 1.3 U/mg (dry weight) (all data are
triplicate determinations done twice independently and are not shown).
Thus, since the complete genes were cloned into plasmid pECD500, the
carboxy termini of both proteins are located in the periplasm.
Interaction between NccYXH and CnrYXH.
To study a possible
interaction between cnr and the highly related
nickel-cobalt-cadmium resistance determinant ncc
(34), the regulatory regions nccYXH and
nccN were PCR cloned from A. xylosoxidans 31A
into pVDZ'2 (6). In the cnrYXH strain
DN190(pMOL28-3), expression of nccYXH in trans
did not mediate nickel-inducible expression of cnr (Table
2). Thus, NccYXH did not activate cnr promoters. NccN did
not have any influence on nickel resistance in DN177(pMOL28-2) (data
not shown).
| |
DISCUSSION |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
The cnr and the chr resistance determinants on megaplasmid pMOL28 of Ralstonia sp. strain CH34 might be required for survival against combined nickel, cobalt, and chromate toxicities, e.g., in serpentine-like soils (1; S. Juhnke, N. Peitzsch, and D. H. Nies, unpublished data). The cnr determinant is composed of at least six genes, encoding products with regulatory functions (cnrY, cnrX, and cnrH) or the subunits of the Co2+/Ni2+ efflux pump (cnrC, cnrB, and cnrA). Downstream of cnrA (Fig. 1) starts an open reading frame (orf104ff) which is not complete in the published DNA sequence (15). The predicted 104-aa product shows homology to MTH841, a 343-aa transporter-like protein from Methanobacterium thermoautotrophicum with unknown function (36). It is not clear if orf104ff, which was not disturbed by the insertion of lacZ downstream of cnrA in plasmid pMOL28-2, is involved in nickel resistance. It was not essential in the initial cloning experiments (15), but transcription from cnrCBA may continue into this open reading frame (Fig. 1).
Translation of cnrYXH and translation of cnrCBA seem to be closely coupled. The stop codons of the respective upstream genes overlap with the start codons of the following genes: ATGATGA for cnrYX, GTGA for cnrXH, ATGATGA for cnrCB, and ATGA for cnrBA. A comparable tight translational coupling has been shown to be important for regulation of other ECF sigma factor-controlled operons, e.g., the car operon from Myxococcus xanthus (10). This fact, the positions of the two identified promoters cnrYp and cnrCp, and the RT-PCR experiments indicate two possible tricistronic mRNAs as transcripts of cnrYXH and cnrCBA.
Deletion and complementation results indicate that CnrY, CnrX, and CnrH are essential as well as sufficient for cnr regulation, which is based on regulation of transcription. High-level constitutive expression of cnr was observed when CnrH was present in Ralstonia cells but CnrY and CnrX were not. Thus, nickel-dependent regulation of cnr depends on the presence of CnrY and CnrX. These data fit the fact that CnrH is a sigma factor (16) of the ECF family. In many examples from gram-negative and gram-positive bacteria (5, 10, 12, 18, 21), ECF sigma factors control operons encoding products which deal with environmental stimuli. Most of these ECF sigma factors are regulated by membrane-bound anti-sigma factors. If a stress condition is sensed by this anti-sigma factor, which might interact with a sensing protein, the sigma factor is released and is free to initiate transcription.
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
Ni2+. If Ni2+ appears in the periplasm, it may
be bound by CnrX; the signal then would be transmitted by CnrY into the
cytoplasm and CnrH would be released. Since periplasmic nickel is
probably the inducer of Cnr, this explains why induction of Cnr, as
judged by the increase in -galactosidase activity, continues for at
least 4 h, although the CnrCBA complex, which detoxifies the
cytoplasm, should have been synthesized in the meantime.
The MIC for the cnr-free derivatives of Ralstonia sp. is 300 µM Ni2+. Thus, with half-maximum induction of cnr at about 50 µM, cnr is strongly expressed at toxic Ni2+ concentrations. On the other hand, Ni2+ is an essential trace element for Ralstonia, at least required for synthesis of hydrogenases (2, 20) at a concentration of about 10 nM. At this concentration, synthesis of CnrCBA-LacZ is slower than dilution of these proteins by cell doubling. Thus, regulation of Cnr guarantees a sufficient supply of Ni2+ as a trace element and at the same time efficient detoxification at higher concentrations.
The Ncc system mediates resistance to Ni2+,
Co2+, and Cd2+ and is composed of seven
proteins. Three are the subunits of the efflux pump, NccCBA, and three
are the regulators NccY, NccX, and NccH. NccN is related to CzcN;
however, no function has been assigned to these proteins yet (11,
34). Homology between the Cnr and the Ncc proteins indicates that
ncc is also regulated by an NccYX sensory complex and the
ECF sigma factor NccH. Upstream of nccY and nccC,
sequences with strong similarity to the consensus sequences of the
CnrH-dependent promoters (Fig. 4B) were found. The common consensus
motifs for both systems are CGAGGGGGAG (35) and
CCGTAT (10). The 35 motifs lack an AAC motif, which was
proposed to be a consensus motif for all EFC sigma factors
(19). In other ECF sigma factor-dependent promoters (Fig. 4,
MtP2), however, AAC is also lacking.
Despite the similarity between the two systems, the Ncc regulators were
not able to complement a cnrYXH mutant. On the contrary, NccYXH repressed induction of Cnr by Ni2+, even in the
constitutive mutant. One possible explanation could be complete
sequestration of NccH and, if present, CnrH by a putative NccYX complex
and no release of a sigma factor in the presence of Ni2+.
However, a better explanation of the tight repression observed is that
NccH-RNA polymerase holoenzyme might form tight closed complexes at the
cnr promoters but is not able to convert into the open
complex for transcription initiation. This explanation fits the
differences between the conserved motifs of the cnr and the
ncc promoters; however, further studies are required to
solve this question.
The assumption of the existence of the two Cnr promoters
cnrYp and cnrCp is based on (i) the homology
between the cnrY-nccY and the cnrC-nccC upstream
regions (Fig. 4), (ii) primer extension data (Fig. 4), (iii) induction
of (cnrYp-lacZ) and (cnrCp-lacZ) constructs
by nickel (Fig. 5), and (iv) induction of (cnrCBA-lacZ) by nickel under conditions when cnrYXH and
(cnrCBA-lacZ) were separated by insertion of plasmid
pECD581 (Table 2). We found only evidence for the absence of the
proposed promoter cnrHp (38); there were no
results in the primer extension experiments (Fig. 3), no induction of
(cnrHp-lacZ) by nickel (Table 2), and no similarity
between the upstream regions of cnrH and nccH
with respect to an ECF promoter motif. The assumption of
cnrHp is based on binding of the CnrH-containing RNA
polymerase holoenzyme to a DNA sequence upstream of cnrH and
on the loss of induction in a strain carrying a mutation in the
cnrHp promoter region (38). However, mutation of
the cnrHp promoter region may have changed the activity or
expression level of CnrX, which would also explain the observed loss of
induction. Binding of the CnrH-RNA polymerase to a region upstream of
cnrH may be another element of Cnr regulation; e.g., it may
be required to prevent too-high expression levels of CnrH.
Since the (cnrCBA-lacZ) fusion located on plasmid
pMOL28-5 can still be induced by nickel but cnrYXH and
cnrCBA are separated by the insertion of plasmid pECD581
into plasmid pMOL28-5, cnrHp has no influence on the
expression of (cnrCBA-lacZ). Moreover, the reporter
system used in this study is an insertion of lacZ directly
downstream of cnrA. Thus, expression of cnrCBA
was studied in a fully metal-resistant bacterial strain and with a
cnrCBA copy number identical to the copy number in the
wild-type situation. In contrast, the accompanying study has used the
luciferase reporter system situated on vector plasmids which probably
were present in higher copy numbers. Although both studies agree on the
existence of promoter cnrYp, no induction of
(cnrYp-lux) was observed (38). Thus, the fact
that no induction was measured with (cnrHp-lux) and
(cnrCp-lux) is no evidence against the existence of
cnrHp or cnrCp.
Despite these differences, both studies outline the following model of Cnr regulation. A periplasmic protein complex composed of CnrX and the carboxy-terminal part of CnrY senses nickel. This information is probably transmitted by the transmembrane protein CnrY to the ECF sigma factor CnrH, perhaps by release of CnrH from the amino-terminal part of CnrY when nickel is bound to CnrX. CnrH binds to RNA polymerase core, and transcription is initiated from the cnrYp promoter and at least a second promoter which is located upstream or downstream of cnrH.
| |
ACKNOWLEDGMENTS |
|---|
We thank Grit Schleuder and Ute Lindenstrauß for skillful technical assistance. Niels van der Lelie is acknowledged for fruitful and cooperative discussion.
This work was supported by Forschungsmittel des Landes Sachsen-Anhalt and by Fonds der Chemischen Industrie.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: Institut für Mikrobiologie, Martin-Luther-Universität Halle-Wittenberg, Kurt-Mothes-Str. 3, 06099 Halle, Germany. Phone: (49)-345-5526352. Fax: (49)-345-5527010. E-mail: d.nies{at}mikrobiologie.uni-halle.de.
This publication is dedicated to Hans G. Schlegel, who started the
cnr work, on his 75th birthday.
| |
REFERENCES |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
| 1. | Baker, A. J. M. 1987. Metal tolerance in plants. New Phytol. 106:93-111. |
| 2. |
Bartha, R., and E. J. Ordal.
1965.
Nickel-dependent chemolithotrophic growth of two Hydrogenomonas strains.
J. Bacteriol.
89:1015-1019 |
| 3. | Brim, H., M. Heyndrickx, P. de Vos, A. Wilmotte, D. Springael, H. G. Schlegel, and M. Mergeay. 1999. Amplified rDNA restriction analysis and further genotypic characterisation of metal-resistant soil bacteria and related facultative hydrogenotrophs. Syst. Appl. Microbiol. 22:258-268[Medline]. |
| 4. |
Collard, J.-M.,
A. Provoost,
S. Taghavi, and M. Mergeay.
1993.
A new type of Alcaligenes eutrophus CH34 zinc resistance generated by mutations affecting regulation of the cnr cobalt-nickel resistance system.
J. Bacteriol.
175:779-784 |
| 5. | De Las Penas, A., L. Connolly, and C. A. Gross. 1997. The sigmaE-mediated response to extracytoplasmic stress in Escherichia coli is transduced by RseA and RseB, two negative regulators of sigmaE. Mol. Microbiol. 24:373-385[CrossRef][Medline]. |
| 6. | Deretic, V., S. Chandrasekharappa, J. F. Gill, D. K. Chatterjee, and A. Chakrabarty. 1987. A set of cassettes and improved vectors for genetic and biochemical characterization of Pseudomonas genes. Gene 57:61-72[CrossRef][Medline]. |
| 7. |
Dressler, C.,
U. Kües,
D. H. Nies, and B. Friedrich.
1991.
Determinants encoding multiple metal resistance in newly isolated copper-resistant bacteria.
Appl. Environ. Microbiol.
57:3079-3085 |
| 8. |
Fernandes, N. D.,
Q.-L. Wu,
D. KOng,
X. Puyang,
S. Garg, and R. N. Husson.
1999.
A mycobacterial extracytoplasmic sigma factor involved in survival following heat shock and oxidative stress.
J. Bacteriol.
181:4266-4274 |
| 9. |
Goldberg, M.,
T. Pribyl,
S. Juhnke, and D. H. Nies.
1999.
Energetics and topology of CzcA, a cation/proton antiporter of the RND protein family.
J. Biol. Chem.
274:26065-26070 |
| 10. | Gorham, H. C., S. J. McGowan, P. R. H. Robson, and D. A. Hodgson. 1996. Light-induced carotenogenesis in Myxococcus xanthus: light-dependent membrane sequestration of EFC sigma factor CarQ by anti-sigma factor CarR. Mol. Microbiol. 19:171-186[CrossRef][Medline]. |
| 11. |
Große, C.,
G. Grass,
A. Anton,
S. Franke,
A. Navarrete Santos,
B. Lawley,
N. L. Brown, and D. H. Nies.
1999.
Transcriptional organization of the czc heavy metal homoeostasis determinant from Alcaligenes eutrophus.
J. Bacteriol.
181:2385-2393 |
| 12. |
Huang, X.,
A. Gaballa,
M. Cao, and J. D. Helmann.
1999.
Identification of target promoters for the Bacillus subtilis extracytoplasmic function  factor, W.
Mol. Microbiol.
31:361-371[CrossRef][Medline].
|
| 13. | Kunito, T., T. Kusano, H. Oyaizu, K. Senoo, S. Kanazawa, and S. Matsumoto. 1996. Cloning and sequence analysis of czc genes in Alcaligenes sp. strain CT14. Biosci. Biotechnol. Biochem. 60:699-704[Medline]. |
| 14. |
Lenz, O.,
E. Schwartz,
J. Dernedde,
T. Eitinger, and B. Friedrich.
1994.
The Alcaligenes eutrophus H16 hoxX gene participates in hydrogenase regulation.
J. Bacteriol.
176:4385-4393 |
| 15. |
Liesegang, H.,
K. Lemke,
R. A. Siddiqui, and H.-G. Schlegel.
1993.
Characterization of the inducible nickel and cobalt resistance determinant cnr from pMOL28 of Alcaligenes eutrophus CH34.
J. Bacteriol.
175:767-778 |
| 16. |
Lonetto, M. A.,
K. L. Brown,
K. E. Rudd, and M. J. Buttner.
1994.
Analysis of the Streptomyces coelicolor sigF gene reveals the existence of a subfamily of eubacterial RNA polymerase factors involved in the regulation of extracytoplasmic functions.
Proc. Natl. Acad. Sci. USA
91:7573-7577 |
| 17. |
Manoil, C.
1990.
Analysis of protein localization by use of gene fusions with complementary properties.
J. Bacteriol.
172:1035-1042 |
| 18. |
Martin, D. W.,
M. J. Schurr, and V. Deretic.
1994.
Analysis of promoters controlled by the putative sigma factor AlgU regulating conversion to mucoidy in Pseudomonas aeruginosa: relationship to E and stress response.
J. Bacteriol.
176:6688-6696 |
| 19. |
Martinéz-Argudo, I.,
R. M. Ruiz-Vázquez, and F. J. Murillo.
1998.
The structure of an ECF--dependent, light-inducible promoter from the bacterium Myxococcus xanthus.
Mol. Microbiol.
30:883-893[CrossRef][Medline].
|
| 20. |
Mergeay, M.,
D. Nies,
H. G. Schlegel,
J. Gerits,
P. Charles, and F. van Gijsegem.
1985.
Alcaligenes eutrophus CH34 is a facultative chemolithotroph with plasmid-bound resistance to heavy metals.
J. Bacteriol.
162:328-334 |
| 21. | Missiakas, D., and S. Raina. 1998. The extracytoplasmic function sigma factors: role and regulation. Mol. Microbiol. 28:1059-1066[CrossRef][Medline]. |
| 22. |
Nies, A.,
D. H. Nies, and S. Silver.
1989.
Cloning and expression of plasmid genes encoding resistances to chromate and cobalt in Alcaligenes eutrophus.
J. Bacteriol.
171:5065-5070 |
| 23. |
Nies, A.,
D. H. Nies, and S. Silver.
1990.
Nucleotide sequence and expression of a plasmid-encoded chromate resistance determinant from Alcaligenes eutrophus.
J. Biol. Chem.
265:5648-5653 |
| 24. |
Nies, D.,
M. Mergeay,
B. Friedrich, and H. G. Schlegel.
1987.
Cloning of plasmid genes encoding resistance to cadmium, zinc, and cobalt in Alcaligenes eutrophus CH34.
J. Bacteriol.
169:4865-4868 |
| 25. |
Nies, D. H.
1995.
The cobalt, zinc, and cadmium efflux system CzcABC from Alcaligenes eutrophus functions as a cation-proton antiporter in Escherichia coli.
J. Bacteriol.
177:2707-2712 |
| 26. |
Nies, D. H.
1992.
CzcR and CzcD, gene products affecting regulation of resistance to cobalt, zinc, and cadmium (czc system) in Alcaligenes eutrophus.
J. Bacteriol.
174:8102-8110 |
| 27. |
Nies, D. H.,
S. Koch,
S. Wachi,
N. Peitzsch, and M. H. J. Saier.
1998.
CHR, a novel family of prokaryotic proton motive force-driven transporters probably containing chromate/sulfate transporters.
J. Bacteriol.
180:5799-5802 |
| 28. |
Nies, D. H.,
A. Nies,
L. Chu, and S. Silver.
1989.
Expression and nucleotide sequence of a plasmid-determined divalent cation efflux system from Alcaligenes eutrophus.
Proc. Natl. Acad. Sci. USA
86:7351-7355 |
| 29. |
Nies, D. H., and S. Silver.
1989.
Plasmid-determined inducible efflux is responsible for resistance to cadmium, zinc, and cobalt in Alcaligenes eutrophus.
J. Bacteriol.
171:896-900 |
| 30. | Oelmüller, U., N. Krüger, A. Steinbüchel, and C. G. Friedrich. 1990. Isolation of prokaryotic RNA and detection of specific mRNA with biotinylated probes. J. Microbiol. Methods 11:73-84. |
| 31. |
Peitzsch, N.,
G. Eberz, and D. H. Nies.
1998.
Alcaligenes eutrophus as a bacterial chromate sensor.
Appl. Environ. Microbiol.
64:453-458 |
| 32. |
Rensing, C.,
T. Pribyl, and D. H. Nies.
1997.
New functions for the three subunits of the CzcCBA cation-proton antiporter.
J. Bacteriol.
179:6871-6879 |
| 33. | Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y. |
| 34. |
Schmidt, T., and H. G. Schlegel.
1994.
Combined nickel-cobalt-cadmium resistance encoded by the ncc locus of Alcaligenes xylosoxidans 31A.
J. Bacteriol.
176:7045-7054 |
| 35. | Simon, R., U. Priefer, and A. Pühler. 1983. A broad host range mobilization system for in vivo genetic engineering: transposon mutagenesis in Gram-negative bacteria. Bio/Technology 1:784-791[CrossRef]. |
| 36. |
Smith, D. R.,
L. A. Doucette-Stamm,
C. Deloughery,
H. Lee,
J. Dubois,
T. Aldredge,
R. Bashirzadeh,
D. Blakely,
R. Cook,
K. Gilbert,
D. Harrison,
L. Hoang,
P. Keagle,
W. Lumm,
B. Pothier,
D. Qiu,
R. Spadafora,
R. Vicaire,
Y. Wang,
J. Wierzbowski,
R. Gibson,
N. Jiwani,
A. Caruso,
D. Bush,
J. N. Reeve, et al.
1997.
Complete genome sequence of Methanobacterium thermoautotrophicum.
J. Bacteriol.
179:7135-7155 |
| 37. | Taghavi, S., M. Mergeay, and D. van der Lelie. 1997. Genetic and physical map of the Alcaligenes eutrophus CH34 megaplasmid pMOL28 and it derivative pMOL50 obtained after temperature induced mutagenesis and mortality. Plasmid 37:22-34[CrossRef][Medline]. |
| 38. |
Tibazarwa, C.,
S. Wuertz,
M. Mergeay,
L. Wyns, and D. van der Lelie.
2000.
Regulation of the cnr cobalt and nickel resistance determinant of Ralstonia eutropha (Alcaligenes eutrophus) CH34.
J. Bacteriol.
182:1399-1409 |
| 39. |
Voss, H.,
U. Wirkner,
R. Jakobi,
N. A. Hewitt,
C. Schwager,
J. Zimmermann,
W. Ansorge, and W. Pyerin.
1991.
Structure of the gene encoding human casein kinase II subunit .
J. Biol. Chem.
266:13706-13711 |
| 40. | Yanisch-Perron, C., J. Vieira, and J. Messing. 1985. Improved M13 phage cloning vectors and host strains: nucleotide sequences of the M13mp18 and pUC19 vectors. Gene 33:103-119[CrossRef][Medline]. |
Journal of Bacteriology, March 2000, p. 1390-1398, Vol. 182, No. 5
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Chaintreuil, C., Rigault, F., Moulin, L., Jaffre, T., Fardoux, J., Giraud, E., Dreyfus, B., Bailly, X.
(2007). Nickel Resistance Determinants in Bradyrhizobium Strains from Nodules of the Endemic New Caledonia Legume Serianthes calycina. Appl. Environ. Microbiol.
73: 8018-8022
[Abstract] [Full Text] -
Tian, J., Wu, N., Li, J., Liu, Y., Guo, J., Yao, B., Fan, Y.
(2007). Nickel-Resistant Determinant from Leptospirillum ferriphilum. Appl. Environ. Microbiol.
73: 2364-2368
[Abstract] [Full Text] -
Posadas, D. M., Martin, F. A., Sabio y Garcia, J. V., Spera, J. M., Delpino, M. V., Baldi, P., Campos, E., Cravero, S. L., Zorreguieta, A.
(2007). The TolC Homologue of Brucella suis Is Involved in Resistance to Antimicrobial Compounds and Virulence. Infect. Immun.
75: 379-389
[Abstract] [Full Text] -
Monchy, S., Benotmane, M. A., Wattiez, R., van Aelst, S., Auquier, V., Borremans, B., Mergeay, M., Taghavi, S., van der Lelie, D., Vallaeys, T.
(2006). Transcriptomic and proteomic analyses of the pMOL30-encoded copper resistance in Cupriavidus metallidurans strain CH34. Microbiology
152: 1765-1776
[Abstract] [Full Text] -
Wolfram, L., Haas, E., Bauerfeind, P.
(2006). Nickel Represses the Synthesis of the Nickel Permease NixA of Helicobacter pylori. J. Bacteriol.
188: 1245-1250
[Abstract] [Full Text] -
Grass, G., Schierhorn, A., Sorkau, E., Muller, H., Rucknagel, P., Nies, D. H., Fricke, B.
(2004). Camelysin Is a Novel Surface Metalloproteinase from Bacillus cereus. Infect. Immun.
72: 219-228
[Abstract] [Full Text] -
van Vliet, A. H. M., Kuipers, E. J., Waidner, B., Davies, B. J., de Vries, N., Penn, C. W., Vandenbroucke-Grauls, C. M. J. E., Kist, M., Bereswill, S., Kusters, J. G.
(2001). Nickel-Responsive Induction of Urease Expression in Helicobacter pylori Is Mediated at the Transcriptional Level. Infect. Immun.
69: 4891-4897
[Abstract] [Full Text] -
Grass, G., Fan, B., Rosen, B. P., Franke, S., Nies, D. H., Rensing, C.
(2001). ZitB (YbgR), a Member of the Cation Diffusion Facilitator Family, Is an Additional Zinc Transporter in Escherichia coli. J. Bacteriol.
183: 4664-4667
[Abstract] [Full Text] -
Grass, G., Fan, B., Rosen, B. P., Lemke, K., Schlegel, H.-G., Rensing, C.
(2001). NreB from Achromobacter xylosoxidans 31A Is a Nickel-Induced Transporter Conferring Nickel Resistance. J. Bacteriol.
183: 2803-2807
[Abstract] [Full Text] -
Tibazarwa, C., Wuertz, S., Mergeay, M., Wyns, L., van der Lelie, D.
(2000). Regulation of the cnr Cobalt and Nickel Resistance Determinant of Ralstonia eutropha (Alcaligenes eutrophus) CH34. J. Bacteriol.
182: 1399-1409
[Abstract] [Full Text]
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Copyright © 2009 by the American Society for Microbiology. For an alternate route to Journals.ASM.org, visit: http://intl-journals.asm.org | More Info»