Plasmid-linked protection of [14C]-glutamate transport and its oxidation against Cd2+ in Staphylococcus aureus

The effect of Cd2+ on [14C]-glutamate transport energized by endogenous respiration and on glutamate oxidation was studied in the Cd2+-resistant and -sensitive Staphylococcus aureus strains. The results indicate that these processes are protected against 10 microM Cd2+ in the Cd2+ resistant strain 17810R by the 2H+/Cd2+ antiporter encoded by the cadA determinant located on a penicillinase plasmid p II17810. Even at 100 microM Cd2+, glutamate oxidation was only partially inhibited in this organism and this inhibition appeared to be reversible. In the plasmidless variant strain 17810S, which lacks the 2H+/Cd2+ antiporter, both [14C]-glutamate transport and its oxidation was blocked by Cd2+ at 10 or 100 microM. In this strain, Cd2+-mediated inhibition of glutamate oxidation was irreversible. Energetics of glutamate transport in both strains was analyzed.     

Effect of Cd2+ on ATP synthesis coupled to electron transfer in cadmium-resistant and -sensitive Staphylococcus aureus

In the Cd2(+)-resistant Staphylococcus aureus 17810R which contains the plasmid-coded Cd2+ efflux system, accumulation of Cd2+ was highly reduced. Consequently, neither respiration nor ATP synthesis coupled to electron transfer were inhibited. The plasmidless S. aureus strain 17810S accumulated Cd2+ via the Mn2+ porter down the membrane potential (delta phi) which resulted in inhibition of respiration and of ATP synthesis.     

Anaerobic 109Cd accumulation by cadmium-resistant and -sensitive Staphylococcus aureus

Washed cells of the cadmium-sensitive Staphylococcus aureus 17810S accumulated 109Cd under anaerobic conditions via the Mn2+ porter down delta psi in 1 or 100 mM phosphate buffer, pH 7; in washed cells of the cadmium-resistant S. aureus 17810R 109Cd accumulation was highly reduced. Nigericin did not stimulate anaerobic Cd2+ accumulation by strain 17810R in 100 mM phosphate buffer, suggesting that delta psi could energize Cd2+ efflux. In 1 mM phosphate buffer nigericin restored Cd2+ accumulation via the Mn2+ porter down delta psi in strain 17810R, indicating involvement of delta pH in Cd2+ extrusion. Increase of phosphate buffer concentration from 1 to 100 mM and addition of energy source at steady-state caused delta psi-dependent Cd2+ efflux from the nigericin-pretreated cells of strain 17810R. This suggests that the Cd2+ efflux system in S. aureus may require energy of both ATP and delta mu H+.     

Energy donor-dependent effect of Cd2+ on [14C]glutamate transport in Staphylococcus aureus

In starved cells of Cd2(+)-sensitive Staphylococcus aureus 17810S preloaded with either glutamate or pyruvate, [14C]glutamate transport was blocked by 10 microM Cd2+, whereas in cells preloaded with lactate, [14C]glutamate transport was not affected. This differential effect of Cd2+ could be due to the presence or absence of dithiols in the substrate oxidizing systems. In starved cells of Cd2(+)-resistant strain 17810R preloaded with either of the three substrates, [14C]glutamate transport was insensitive to 10 microM Cd2+.     

Energy-dependent efflux of cadmium coded by a plasmid resistance determinant in Staphylococcus aureus.

Resistance of Staphylococcus aureus strain 17810R to Cd2+ appears to be due to a plasmid-coded Cd2+ efflux system. Complete efflux of Cd2+ after transfer of preloaded cells into Cd2+-free medium occurred in the resistant strain 17810R, but not in the plasmidless derivative strain 17810S. Net efflux was blocked by 2,4-dinitrophenol, N,N,-dicyclohexylcarbodiimide (DCCD), and incubation at 4 degrees C. The inhibition of Cd2+ efflux by DCCD paralleled a stimulation of net uptake in the resistant cells by this agent. Cd2+ efflux by the resistant strain was accompanied by a reversal of inhibition of respiration, whereas in the sensitive strain, inhibition of respiration was not reversed after transfer to Cd2+-free medium. Net Cd2+ uptake by strain 17810R was inhibited by p-chloromercuribenzoate. In Cd2+ contrast, Cd2+ uptake by the plasmidless strain 17810S was affected neither by p-chloromercuribenzoate nor by DCCD when added alone, but was blocked by a combination of these two agents. Valinomycin had no effect on the reduced Cd2+ uptake by the resistant strain, whereas nigericin stimulated uptake to values comparable to those of the untreated sensitive cells. With sensitive cells, valinomycin reduced Cd2+ uptake by about 50%, whereas nigericin was without effect. A possible mechanism of Cd2+ movements in both strains is discussed.     

Effect of Cd2+ on phosphate uptake by cadmium-resistant and cadmium-sensitive Staphylococcus aureus.

The effect of Cd2+ on phosphate (Pi) uptake was investigated in the growing cells of Cd(2+)-resistant Staphylococcus aureus 1781OR and Cd(2+)-sensitive S. aureus 17810S. Inhibitor and ionophore studies showed that 32Pi uptake in the two strains occurred via the Pi porter down pH gradient (delta pH) generated by the respiratory chain. Cd2+ inhibited 32Pi uptake in the cadmium-sensitive strain 1781OS at all concentrations used (10 microM-1 mM). In strain 1781OR, possessing the plasmid-coded Cd2+ efflux system, 10-100 microM Cd2+ did not inhibit 32Pi uptake. Even at 1 mM Cd2+, inhibition of 32Pi uptake in strain 1781OR was reversed when the external Cd2+ was chelated with cysteine and activity of Cd2+ efflux system was restored. Cd2+ efflux induced by cysteine was energized either by membrane potential (delta psi) or by delta pH, which indicated that electrochemical gradient of protons (delta mu H+) was required for this efflux.     

Reduced cadmium transport determined by a resistance plasmid in Staphylococcus aureus.

The presence of a plasmid harboring a gene for Cd2+ resistance led to markedly reduced Cd2+ uptake via the energy-dependent Mn2+ transport system in Staphylococcus aureus strain 17810R. Cd2+ uptake by the resistant strain via this high-affinity system was seen only at very low Cd2+ concentrations. At high concentrations, Cd2+ was taken up by the resistant strain via a different low-affinity uptake system. Cd2+ uptake via this system was energy dependent but was not blocked by Mn2+. Loss of the plasmid from the resistant strain resulted in Cd2+ sensitivity and unblocking of Cd2+ transport via the Mn2+ carrier in the plasmidless derivative strain 17810S. The energy-dependent Cd2+ uptake by the sensitive strain was inhibited by Mn2+ with kinetics indicating competitive inhibition. It is suggested that the second, low-affinity uptake system for Cd2+ in the resistant strain is the energy-dependent cadmium/proton antiporter, which at low Cd2+ concentrations functions in net Cd2+ efflux.     

2-Oxoglutarate transport system in Staphylococcus aureus

2-[(14)C]oxoglutarate uptake in resting cells of Staphylococcus aureus 17810S occurs via two kinetically different systems: (1) a secondary, electrogenic 2-oxoglutarate:H(+) symporter (K(m)=0.105 mM), energized by an electrochemical proton potential (Delta mu H(+)) that is generated by the oxidation of endogenous amino acids and sensitive to ionophores, and (2) a Delta mu H(+)-independent facilitated diffusion system (K(m)=1.31 mM). The 2-oxoglutarate transport system of S. aureus 17810S can be classified as a new member of the MHS (metabolite:H(+) symporter) family. This transporter takes up various dicarboxylic acids in the order of affinity: succinate = malate > fumarate > 2-oxoglutarate > glutamate. Energy conservation with 2-oxoglutarate was studied in starved cells of strain 17810S. Initial transport of 2-oxoglutarate in these cells is energized by Delta mu H(+) generated via hydrolysis of residual ATP. Subsequent oxidation of the accumulated 2-oxoglutarate generates Delta mu H(+) for further, autoenergized transport of this 2-oxoacid and also for Delta mu H(+)-linked resynthesis of ATP. In the cadmium-sensitive S. aureus 17810S, Cd(2+) accumulation strongly inhibits energy conservation with 2-oxoglutarate at the level of Delta mu H(+) generation, without direct blocking of the 2-oxoglutarate transport system or ATP synthase complex. In the cadmium-resistant S. aureus 17810R, Cd(2+) does not affect energy conservation due to its extrusion by the Cd(2+) efflux system (Cd(2+)-ATPase of P-type), which prevents Cd(2+) accumulation.     

Effect of cadmium on C-14-glucose uptake by Staphylococcus aureus

The aim of the study was to evaluate an influence of Cd++ on 14C-glucose uptake by two strains of S. aureus resistant and sensitive to cadmium in 0.1 M phosphate buffer, pH 7.0. Uptake of this sugar in both strains is an active process in which energy comes from oxidation of endogenous substrates, what was shown in aerobic condition, anaerobic condition at temperatures of 37 degrees C and 4 degrees C, and with p-CMB and CCCP. In the resistant strains Cd++ at 10 microM concentration did not inhibit endogenous respiration, 14C-glucose uptake and its oxidation. This is due to presence of energy-dependent system of 2H+/Cd++ antiport coded by cadA genes located on penicillinase pII17810 plasmid, which eliminated Cd++ from bacterial cell. In the case of plasmid free variant deprived of this system, Cd++ is retained in cytoplasm and blocks endogenous respiration uptake, and oxidation of glucose.     

The cadC gene product of alkaliphilic Bacillus firmus OF4 partially restores Na+ resistance to an Escherichia coli strain lacking an Na+/H+ antiporter (NhaA).

A 5.6-kb fragment of alkaliphilic Bacillus firmus OF4 DNA was isolated by screening a library of total genomic DNA constructed in pGEM3Zf(+) for clones that reversed the Na+ sensitivity of Escherichia coli NM81, in which the gene encoding an Na+/H+ antiporter (NhaA) is deleted (E. Padan, N. Maisler, D. Taglicht, R. Karpel, and S. Schuldiner, J. Biol. Chem. 264:20297-20302, 1989). The plasmid, designated pJB22, contained two genes that apparently encode transposition functions and two genes that are apparent homologs of the cadA and cadC genes of cadmium resistance-conferring plasmid pI258 of Staphylococcus aureus. E. coli NM81 transformed with pJB22 had enhanced membrane Na+/H+ antiporter activity that was cold labile and that decreased very rapidly following isolation of everted vesicles. Subclones of pJB22 containing cadC as the only intact gene showed identical complementation patterns in vivo and in vitro. The cadC gene product of S. aureus has been proposed to act as an accessory protein for the Cd2+ efflux ATPase (CadA) (K. P. Yoon and S. Silver, J. Bacteriol. 173:7636-7642, 1991); perhaps the alkaliphile CadC also binds Na+ and enhances antiporter activity by delivering a substrate to an integral membrane antiporter. A 6.0-kb fragment overlapping the pJB22 insert was isolated to complete the sequence of the cadA homolog. A partial sequence of a region approximately 2 kb downstream of the cadA locus shares sequence similarity with plasmids from several gram-positive bacteria. These results suggest that the region of alkaliphile DNA containing the cadCA locus is present on a transposon that could reside on a heretofore-undetected endogenous plasmid.     

A second gene in the Staphylococcus aureus cadA cadmium resistance determinant of plasmid pI258.

Two open reading frames on a 3.7-kb BglII-XbaI fragment which encodes the Staphylococcus aureus cadA cadmium (and zinc) resistance determinant of plasmid pI258 were identified (G. Nucifora, L. Chu, T. K. Misra, and S. Silver, Proc. Natl. Acad. Sci. USA 86:3544-3548, 1989). The [35S]methionine-labelled protein products of the 727-amino-acid CadA ATPase and of the 122-amino-acid CadC polypeptide in Escherichia coli were identified by using the T7 RNA polymerase-promoter expression system. A truncated CadA polypeptide (402 amino acids) did not confer resistance in S. aureus but was expressed in E. coli under control of the T7 RNA polymerase-promoter. Removal of 678 nucleotides from the 5' end of the published sequence (which includes the cadA promoter) abolished resistance to cadmium, whereas a 146-nucleotide-shorter deletion was without effect. The cadC gene is needed in addition to cadA for full resistance to cadmium in S. aureus and Bacillus subtilis. cadC functions both in cis and in trans.     

Interplay of different transporters in the mediation of divalent heavy metal resistance in Pseudomonas putida KT2440

According to in silico analysis, the genome of Pseudomonas putida KT2440 encodes at least four Zn/Cd/Pb efflux transporters-two P-type ATPases (CadA1 and CadA2) and two czc chemiosmotic transporters (CzcCBA1 and CzcCBA2). In this study we showed that all these transporters are functional, but under laboratory conditions only two of them were involved in the mediation of heavy metal resistance in P. putida KT2440. CadA2 conferred Cd(2+) and Pb(2+) resistance, whereas CzcCBA1 was involved in export of Zn(2+), Cd(2+), and possibly Pb(2+). CadA1, although nonfunctional in P. putida, improved Zn(2+) resistance and slightly improved Cd(2+) resistance when it was expressed in Escherichia coli. CzcCBA2 contributed to Zn resistance of a czcA1-defective P. putida strain or when the CzcA2 subunit was overexpressed in a transporter-deficient strain. It seemed that CzcA2 could complex with CzcC1 and CzcB1 subunits and therefore complement the loss of CzcA1. The CzcCBA2 transporter itself, however, did not function. Expression of cadA1, cadA2, and czcCBA1 was induced by heavy metals, and the expression levels were dependent on the growth medium and growth phase. Expression of cadA2 and czcCBA1 was nonspecific; both genes were induced by Zn(2+), Cd(2+), Pb(2+), Ni(2+), Co(2+), and Hg(2+). On the other hand, remarkably, expression of cadA1 was induced only by Zn(2+). Possible roles of distinct but simultaneously functioning transporters are discussed.     

Plasmid-borne cadmium resistance genes in Listeria monocytogenes are similar to cadA and cadC of Staphylococcus aureus and are induced by cadmium.

pLm74 is the smallest known plasmid in Listeria monocytogenes. It confers resistance to the toxic divalent cation cadmium. It contains a 3.1-kb EcoRI fragment which hybridizes with the cadAC genes of plasmid pI258 of Staphylococcus aureus. When introduced into cadmium-sensitive L. monocytogenes or Bacillus subtilis strains, this fragment conferred cadmium resistance. The DNA sequence of the 3.1-kb EcoRI fragment contains two open reading frames, cadA and cadC. The deduced amino acid sequences are similar to those of the cad operon of plasmid pI258 of S. aureus, known to prevent accumulation of Cd2+ in the bacteria by an ATPase efflux mechanism. The cadmium resistance determinant of L. monocytogenes does not confer zinc resistance, in contrast to the cadAC determinant of S. aureus, suggesting that the two resistance mechanisms are slightly different. Slot blot DNA-RNA hybridization analysis showed cadmium-inducible synthesis of L. monocytogenes cadAC RNA.     

Cadmium transport by a Cd2+-sensitive and a Cd2+-resistant strain of Bacillus subtilis

Cadmium uptake by a Cd2+-sensitive (1A1) and a Cd2+-resistant mutant (1A1r) strain of Bacillus subtilis was investigated. Uptake of 109Cd2+ was determined for cells of both strains grown in tryptone broth and in broth containing tryptone, yeast extract, and glucose (TYG). The extent of 109Cd2+ uptake by cells of 1A1r was less than by cells of 1A1 under both growth conditions. In both growth media, 109Cd2+ uptake by 1A1 cells demonstrated saturation kinetics and was energy dependent. In both TYG and tryptone broth, 109Cd2+ uptake by 1A1 cells was inhibited by the addition of unlabeled Mn2+. Although lower in magnitude, the kinetics of 109Cd2+ uptake by 1A1r cells were similar to those of 1A1 cells when grown in tryptone broth. However, no obvious saturation kinetics, energy dependence, temperature sensitivity, or inhibition of 109Cd2+ uptake by the addition of unlabeled Mn2+ was observed in 1A1r cells grown in TYG. Differential Mn2+ accumulation by 1A1r cells in TYG and tryptone broth correlated with differential 109Cd2+ uptake by 1A1r cells in these media.     

Cadmium-resistant mutant of Bacillus subtilis 168 with reduced cadmium transport.

Cd2+ and Mn2+ accumulation was studied with wild-type Bacillus subtilis 168 and a Cd2+-resistant mutant. After 5 min of incubation in the presence of 0.1 microM 109Cd2+ or 54Mn2+, both strains accumulated comparable amounts of 54Mn2+, while the sensitive cells accumulated three times more 109Cd2+ than the Cd2+-resistant cells did. Both 54Mn2+ and 109Cd2+ uptake, which apparently occur by the same transport system, demonstrated cation specificity; 20 microM Mn2+ or Cd2+ (but not Zn2+) inhibited the uptake of 0.1 microM 109Cd2+ or 54Mn2+. 54Mn2+ and 109Cd2+ uptake was energy dependent and temperature sensitive, but 109Cd2+ uptake in the Cd2+-resistant strain was only partially inhibited by an uncoupler or by a decrease in temperature. 109Cd2+ uptake in the sensitive strain followed Michaelis-Menten kinetics with a Km of 1.8 microM Cd2+ and a Vmax of 1.5 mumol/min X g (dry weight); 109Cd2+ uptake in the Cd2+-resistant strain was not saturable. The apparent Km value for the saturable component of 109Cd2+ uptake by the Cd2+-resistant strain was very similar to that of the sensitive strain, but the Vmax was 25 times lower than the Vmax for the sensitive strain. The Km and Vmax for 54Mn2+ uptake by both strains were very similar. Cd2+ inhibition of 54Mn2+ uptake had an apparent Ki of 3.4 and 21.5 microM Cd2+ for the sensitive and Cd2+-resistant strains, respectively. Mn2+ had an apparent Ki of 1.2 microM Mn2+ for inhibition of 109Cd2+ uptake by the sensitive strain, but the Cd2+-resistant strain had no defined Ki value for inhibition of Cd2+ uptake by Mn2+.     

Cadmium uptake by growing cells of gram-positive and gram-negative bacteria

The present study evaluates the effect of the cadmium (Cd2+) on the growth and protein synthesis of some Gram-positive (Staphylococcus aureus, Bacillus subtilis and Streptococcus faecium) and Gram-negative (Escherichia coli and Pseudomonas aeruginosa) bacteria and the cadmium uptake by the same micro-organisms. The Gram-negative bacteria tested were less sensitive to metal ions than the Gram-positive, and P. aeruginosa was the most resistant. The Gram-negative bacteria were also able to accumulate higher amounts of cadmium during growth than the Gram-positive bacteria. The maximum values of specific metal uptake (microgram of Cd2+ incorporated per mg of protein) were: 0.52 for S. aureus, 0.65 for S. faecium, 0.79 for B. subtilis, 2.79 for E. coli and 24.15 for P. aeruginosa, respectively. The differences in the ability to accumulate metal found between Gram-negative and Gram-positive bacteria seems to account for different mechanisms of metal resistance.     

Helicobacter pylori cadA encodes an essential Cd(II)–Zn(II)–Co(II) resistance factor influencing urease activity

Inactivation of Helicobacter pylori cadA, encoding a putative transition metal ATPase, was only possible in one of four natural competent H. pylori strains, designated 69A. All tested cadA mutants showed increased growth sensitivity to Cd(II) and Zn(II). In addition, some of them showed both reduced 63Ni accumulation during growth and no or impaired urease activity, which was not due to lack of urease enzyme subunits. Gene complementation experiments with plasmid (pY178)-derived H. pylori cadA failed to correct the deficiencies, whereas resistance to Cd(II) and Zn(II) was restored. Moreover, pY178 conferred increased Co(II) resistance to both the cadA mutants and the wild-type strain 69A. Heterologous expression of H. pylori cadA in an Escherichia coli zntA mutant resulted in an elevated resistance to Cd(II) and Zn(II). Expression of cadA in E. coli SE5000 harbouring H. pylori nixA, which encodes a divalent cation importer along with the H. pylori urease gene cluster, led to about a threefold increase in urease activity compared with E. coli control cells lacking the H. pylori cadA gene. These results suggest that H. pylori CadA is an essential resistance pump with ion specificity towards Cd(II), Zn(II) and Co(II). They also point to a possible role of H. pylori CadA in high-level activity of H. pylori urease, an enzyme sensitive to a variety of metal ions.     

Cadmium and manganese transport in Staphylococcus aureus membrane vesicles.

The presence of plasmid gene cadB did not affect Cd2+ accumulation, whereas plasmid gene cadA reduced Cd2+ accumulation by whole cells but not by membrane vesicles. Membrane vesicle studies indicated that Cd2+ uptake occurred via the Mn2+ transport system which was energized by the membrane electrical potential. Mn2+ and Cd2+ were competitive inhibitors of each other's transport, with Km's of 0.95 microM Mn2+ and 0.2 microM Cd2+. The kinetic parameters were nearly identical with vesicles prepared from sensitive and resistant cells, indicating that the cadA-encoded Cd2+ efflux system was inoperative in membrane vesicle preparations. Experiments with energy-inhibited cells indicated that the cadB gene product may bind Cd2+.     

ATP-dependent cadmium transport by the cadA cadmium resistance determinant in everted membrane vesicles of Bacillus subtilis.

Resistance to cadmium conferred by the staphylococcal plasmid pI258 occurs by means of energy-dependent efflux, resulting in decreased intracellular accumulation of cadmium. Recent sequence information suggested that efflux is mediated by a P-type ATPase. The cadA gene was previously expressed in Bacillus subtilis, conferring resistance to cadmium. Everted membrane vesicles were prepared from B. subtilis cells harboring either a plasmid containing the cadA system or the vector plasmid alone. 109Cd2+ transport into the everted membranes was measured in the presence of various energy sources. Cadmium transport was detected only in the presence of ATP as an energy source. The production of an electrochemical proton gradient (delta mu H+) by using NADH or phenazine methosulfate plus ascorbate was not able to drive transport. Reagents which dissipate delta pH abolished calcium transport due to the Ca2+/H+ antiporter but only partially inhibited cadmium transport. Inhibition of transport by the antibiotic bafilomycin A1 occurred at concentrations comparable to those which inhibit P-type ATPases. A band corresponding to the cadA gene product was identified on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and antibodies to the protein were prepared.