Environmental significance of the potential for mer(Tn21)-mediated reduction of Hg2+ to Hg0 in natural waters.

The role of mer(Tn21) in the adaptation of aquatic microbial communities to Hg2+ was investigated. Elemental mercury was the sole product of Hg2+ volatilization by freshwater and saline water microbial communities. Bacterial activity was responsible for biotransformation because most microeucaryotes did not survive the exposure conditions, and removal of larger microbes (greater than 1 micromole) from adapted communities did not significantly (P greater than 0.01) reduce Hg2+ volatilization rates. DNA sequences homologous to mer(Tn21) were found in 50% of Hg2+-resistant bacterial strains representing two freshwater communities, but in only 12% of strains representing two saline communities (the difference was highly significant; P less than 0.001). Thus, mer(Tn21) played a significant role in Hg2+ resistance among strains isolated from fresh waters, in which microbial activity had a limited role in Hg2+ volatilization. In saline water environments in which microbially mediated volatilization was the major mechanism of Hg2+ loss, other bacterial genes coded for this biotransformation.     

Role of Na+ in transport of Hg2+ and induction of the Tn21 mer operon.

The effects of sodium ions on the uptake of Hg2+ and induction of the Tn21 mer operon were studied by using Escherichia coli HMS174 harboring the reporter plasmids pRB28 and pOS14. Plasmid pRB28 carries merRT', and pOS14 carries merRTPC of the mer operon, both cloned upstream of a promoterless luciferase gene cassette in pUCD615. The bioluminescent response to 1 microM Hg2+ was significantly inhibited in E. coli HMS174(pRB28) in minimal medium supplemented with sodium ions at 10 to 140 mM. After initial acceleration, light emission declined at 50 nM Hg2+ in the presence of Na+. The mer-lux assay with resting cells carrying pRB28 and 203Hg2+ uptake experiments showed increased induction and enhanced mercury uptake, respectively, in media supplemented with sodium ions. The presence of Na+ facilitated maintenance of bioluminescence in resting HMS174(pRB28) cells induced with 50 nM Hg2+. External K+ stimulated bioluminescent response in HMS174(pRB28) and HMS174(pOS14) grown in sodium phosphate minimal medium devoid of potassium ions. Sodium ions appear to facilitate mercury transport. We propose that sodium-coupled transport of mercuric ions can be one of the mechanisms for mercury uptake by E. coli and that the Na+ gradient may energize the transport of Hg2+.     

The distribution and divergence of DNA sequences related to the Tn21 and Tn501 mer operons

The mercury resistance (mer) operons of the Gram-negative bacterial transposons, Tn21 and Tn501, are phenotypically indistinguishable and have extensive DNA identity. However, Tn21 mer has an additional coding region (merC) in the middle of the operon which is lacking in Tn501 and there is also a discrete region of the mercuric ion reductase gene (merA) which differs markedly between the two operons. DNA fragment probes were used to determine the distribution of specific mer coding regions in two distinct collections of mercury-resistant (Hgr) Gram-negative bacteria. Colony blot hybridization analysis showed that merC-positive operons occur almost exclusively in Escherichia, although merC-negative operons can also be found in this genus. The merC-negative operons were found in Citrobacter, Klebsiella, and Enterobacter and in some Pseudomonas. Most of the Pseudomonas did not hybridize detectably with either of the two operons studied, indicating that they harbor an unrelated or more distantly related class of mercury resistance locus. Southern hybridization patterns demonstrated that the merC-positive mer operon is well conserved at the DNA level, whereas the merC-negative operons are much less conserved. The presence of merC also correlated with conservation of a specific variant region of the merA gene and with an antibiotic resistance pattern similar to that of Tn21. Tn501 appears to be an atypical example of the merC-negative subgroup of Hgr loci.     

Genetic engineering of bacteria and their potential for Hg2+ bioremediation

Ion exchange or biosorptive processes for metalremoval generally lack specificity in metal bindingand are sensitive to ambient conditions, e.g. pH,ionic strength and the presence of metal chelators. Inthis study, cells of a genetically engineered Escherichia coli strain, JM109, which expressesmetallothionein and a Hg²⁺ transport system afterinduction were evaluated for their selectivity forHg²⁺ accumulation in the presence of sodium,magnesium, or cadmium ions and their sensitivity to pHor the presence of metal chelators during Hg²⁺bioaccumulation. The genetically engineered E.coli cells in suspension accumulated Hg²⁺effectively at low concentrations (0-20 µM) overa broad range of pH (3 to 11). The presence of 400 mMsodium chloride, 200 mM magnesium chloride, or100 µM cadmium ions did not have a significanteffect on the bioaccumulation of 5 µm Hg²⁺,indicating that this process is not sensitive to highionic strength and is highly selective against sodium,magnesium, or cadmium ions. Metal chelators usuallyinterfere with ion exchange or biosorptive processes.However, two common metal chelators, EDTA and citrate,had no significant effect on Hg²⁺ bioaccumulationby the genetically engineered strain. These resultssuggest that this E. coli strain could be usedfor selective removal of Hg²⁺ from waste water orfrom contaminated solutions which are resistant tocommon treatments. A second potential applicationwould be to remove Hg²⁺ from Hg²⁺-contaminated soil, sediment, or particulates bywashing them with a Hg²⁺ chelator andregenerating the chelator by passing the solutionthrough a reactor containing the strain.     

Reduction of Hg(II) to Hg(0) by Biogenic Magnetite from two Magnetotactic Bacteria

Understanding the biogeochemical cycle of the highly toxic element mercury (Hg) is necessary to predict its fate and transport. In this study, we determined that biogenic magnetite isolated from Magnetospirillum gryphiswaldense MSR-1 and Magnetospirillum magnetotacticum MS-1 was capable of reducing inorganic mercury [Hg(II)] to elemental mercury [Hg(0)]. These two magnetotactic bacteria (MTB) lacked mercuric resistance operons in the genomes. However, they revealed high resistance to Hg(II) under atmospheric conditions and an even higher resistance under microaerobic conditions (1% O₂ and 99% N₂). Neither strain reduced Hg(II) to Hg(0) under atmospheric conditions. However, a slow rate (0.05–0.21 µM·d^?1) of Hg(II) loss occurred from late log phase to stationary phase in two MTBs' culture media under microaerobic conditions. Increased Hg(II) entered both cells under microaerobic conditions relative to atmospheric conditions. The majority of Hg(II) was still blocked by the cell membrane. Hg(II) reduction was more effective when biogenic magnetite was extracted out, with or without the magnetosome membrane envelope. When magnetosome membrane was present, 8.55–13.53% of 250 nM Hg(II) was reduced to Hg(0) by 250 mg/L biogenic magnetite suspension within 2 hours. This ratio increased to 55.07–64.70% while magnetosome membrane was removed. We concluded that two MTBs contributed to the reduction of Hg(II) to Hg(0) at a slow rate in vivo. Such reduction was more favorable to occur when biogenic magnetite is released from dead cells. It proposed a new biotic pathway for the formation of Hg(0) in aquatic systems.     

Different effects of Hg2+ and Cu2+ on mussel (Mytilus galloprovincialis) plasma membrane Ca2+-ATPase: Hg2+ induction of protein expression

Deregulation of Ca2+ homeostasis can produce serious effects on cell functioning due to an alteration of Ca2+ signaling. The aim of this study was to evaluate variations in plasma membrane Ca2+-ATPase (PMCA) induced in mussels by in vivo exposure to Cu2+ or Hg2+. PMCA activity was assayed using a cytochemical method allowing localization and in situ quantification of Ca2+-ATPase on cryostat tissue sections. The effects of fixed concentrations of Cu2+ (0.6 microM) or Hg2+ (1.3 microM) were evaluated after different times of exposure (1, 4, 6 days), while those of increasing amounts of Cu2+ (0.3, 0.6, 1.3 microM) or of Hg2+ (0.6, 1.3, 2.4 microM) were evaluated after 4 days. Cu2+ produces dose-dependent inhibition of PMCA in the digestive gland, with a minimum at the fourth day of treatment and a recovery at the sixth day. Conversely, Hg2+ induces a significant rise of PMCA activity, with a maximum at the fourth day. Similar results have been found after biochemical assay of PMCA, using plasma membranes obtained from density-gradient separation of gill homogenates. PMCA expression has been assessed by immunoprecipitation and Western immunoblotting on digestive gland homogenates, showing an induction after exposure to Hg2+ but not to Cu2+. In conclusion, Cu2+ does not vary PMCA expression but reduces PMCA activity, indicating PMCA inhibition; conversely, Hg2+ increases PMCA expression more than PMCA activity, suggesting that it also produces PMCA inhibition, but the induction of PMCA expression leads to a net increase in enzyme activity.     

Hybridization of DNA probes with whole-community genome for detection of genes that encode microbial responses to pollutants: mer genes and Hg2+ resistance

Nucleic acids extracted from microbial biomass without prior culturing were hybridized with probes representing four mer operons to detect genes encoding adaptation to Hg2+ in whole-community genomes. A 29-fold enrichment in sequences similar to the mer genes of transposon Tn501 occurred during adaptation in a freshwater community. In an estuarine community, all four mer genes were only slightly enriched (by three- to fivefold), suggesting that additional, yet uncharacterized, mer genes encoded adaptation to Hg2+.     

Hybridization of DNA probes with whole-community genome for detection of genes that encode microbial responses to pollutants: mer genes and Hg2+ resistance.

Nucleic acids extracted from microbial biomass without prior culturing were hybridized with probes representing four mer operons to detect genes encoding adaptation to Hg2+ in whole-community genomes. A 29-fold enrichment in sequences similar to the mer genes of transposon Tn501 occurred during adaptation in a freshwater community. In an estuarine community, all four mer genes were only slightly enriched (by three- to fivefold), suggesting that additional, yet uncharacterized, mer genes encoded adaptation to Hg2+.     

Hg2+ signaling in trout hepatoma (RTH-149) cells: involvement of Ca2+-induced Ca2+ release

Mercury is a non-essential heavy metal affecting intracellular Ca2+ dynamics. We studied the effects of Hg2+ on [Ca2+]i in trout hepatoma cells (RTH-149). Confocal imaging of fluo-3-loaded cells showed that Hg2+ induced dose-dependent, sustained [Ca2+]i transient, triggered intracellular Ca2+ waves, stimulated Ca2+-ATPase activity, and promoted InsP3 production. The effect of Hg2+ was reduced by the Ca2+ channel blocker verapamil and totally abolished by extracellular GSH, but was almost unaffected by cell loading with the heavy metal chelator TPEN or esterified GSH. In a Ca2+-free medium, Hg2+ induced a smaller [Ca2+]i transient, that was unaffected by TPEN, but was abolished by U73122, a PLC inhibitor, and by cell loading with GDP-betaS, a G protein inhibitor, or heparin, a blocker of intracellular Ca2+ release. Data indicate that Hg2+ induces Ca2+ entry through verapamil-sensitive channels, and intracellular Ca2+ release via a G protein-PLC-InsP3 mechanism. However, in cells loaded with heparin and exposed to Hg2+ in the presence of external Ca2+, the [Ca2+]i rise was maximally reduced, indicating that the global effect of Hg2+ is not a mere sum of Ca2+ entry plus Ca2+ release, but involves an amplification of Ca2+ release operated by Ca2+ entry through a CICR mechanism.     

Characterization of Two-pore Channel 2 (TPCN2)-mediated Ca2+ Currents in Isolated Lysosomes

Two-pore channels (TPCNs) have been proposed to form lysosomal Ca²⁺ release channels that are activated by nicotinic acid adenine dinucleotide phosphate. Here, we employ a glass chip-based method to record for the first time nicotinic acid adenine dinucleotide phosphate -dependent currents through a two-pore channel (TPCN2) from intact lysosomes. We show that TPCN2 is a highly selective Ca²⁺ channel that is regulated by intralysosomal pH. Using site-directed mutagenesis, we identify an amino acid residue in the putative pore region that is crucial for conferring high Ca²⁺ selectivity. Our glass chip-based method will provide electrophysiological access not only to lysosomal TPCN channels but also to a broad range of other intracellular ion channels.     

Acclimation of aquatic microbial communities to Hg(II) and CH3Hg+ in polluted freshwater ponds

The relationship of mercury resistance to the concentration and chemical speciation of mercurial compounds was evaluated for microbial communities of mercury-polluted and control waters. Methodologies based on the direct viable counting (DVC) method were adapted to enumerate mercury-resistant communities. Elevated tolerance to Hg(II) was observed for the microbial community of one mercury-polluted pond as compared to the community of control waters. These results suggest an in situ acclimation to Hg(II). The results of the methylmercury resistance-DVC assay suggested that minimal acclimation to CH₃Hg⁺ occurred since similar concentrations of CH₃HgCl inhibited growth of 50% of organisms in both the control and polluted communities. Analyses of different mercury species in pond waters suggested that total mercury, but not CH₃Hg⁺ concentrations, approached toxic levels in the polluted ponds. Thus, microbial acclimation was specific to the chemical species of mercury present in the water at concentrations high enough to cause toxic effects to nonacclimated bacterial communities.     

Abundance of Tn3, Tn21, and Tn501 transposase (tnpA) sequences in bacterial community DNA from marine environments.

The occurrence of the tnpA genes of the transposons Tn3, Tn21, and Tn501 was assessed in total bacterial community DNA isolated from different marine environments. The PCR technique was employed, together with most probable number statistics, to determine the abundance of the target tnpA genes. All three genes could be detected, and the Tn21 tnpA sequences predominated in all samples. The smallest amount of total community DNA in which the Tn21 tnpA sequence could be detected was 0.037 ng, and on the basis of our results, we estimated that this sequence was present in 1 of 1,000 to 10,000 bacteria. Hybridization of the PCR products with the respective tnpA probes verified the Tn21 and Tn501 tnpA sequences but only some of the Tn3 tnpA amplification products. The distribution and dissemination of transposons in natural bacterial communities are discussed.     

Evidence for NQO2-mediated reduction of the carcinogenic estrogen ortho-quinones

The physiological function of NAD(P)H:quinone oxidoreductase (NQO1, DT-diaphorase) is to detoxify potentially reactive quinones by direct transfer of two electrons. A similar detoxification role has not been established for its homologue NRH:quinone oxidoreductase 2 (NQO2). Estrogen quinones, including estradiol(E(2))-3,4-Q, generated by estrogen metabolism, are thought to be responsible for estrogen-initiated carcinogenesis. In this investigation, we have shown for the first time that NQO2 catalyzes the reduction of electrophilic estrogen quinones and thereby may act as a detoxification enzyme. ESI and MALDI mass spectrometric binding studies involving E(2)-3,4-Q with NQO2 clearly support the formation of an enzyme-substrate physical complex. The problem of spontaneous reduction of substrate by cofactor, benzyldihydronicotinamide riboside (BNAH), was successfully overcome by taking advantage of the ping-pong mechanism of NQO2 catalysis. The involvement of the enzyme in the reduction of E(2)-3,4-Q was further supported by addition of the inhibitor quercetin to the assay mixture. NQO2 is a newly discovered binding site (MT3) of melatonin. However, addition of melatonin to the assay mixture did not affect the catalytic activity of NQO2. Preliminary kinetic studies show that NQO2 is faster in reducing estrogen quinones than its homologue NQO1. Both UV and liquid chromatography-tandem mass spectrometry assays unequivocally corroborate the reduction of estrogen ortho-quinones by NQO2, indicating that it could be a novel target for prevention of breast cancer initiation.     

Interaction of Tn501 mercuric reductase and dihydroflavin adenine dinucleotide anion with metal ions: implications for the mechanism of mercuric reductase mediated Hg(II) reduction.

The flavoprotein Tn501 mercuric reductase (MerA) catalyzes the reduction of Hg(II) to Hg(0) through the intermediacy of the tightly bound two-electron-reduced cofactor FADH-. To gain insight into the MerA mechanism, the interaction of the holoenzyme or free FADH- with various metal ions was investigated. The free two-electron-reduced FAD cofactor, FADH-, readily reduces a variety of metal ions, provided they have suitably high redox potentials. For Hg(II) with various ligands, the rate of reduction is inversely proportional to the stability of the Hg(II)-ligand complex. These results are consistent with the free cofactor reducing metal ions by an outer-sphere electron transfer mechanism. In contrast, MerA can tightly bind several redox labile metal ions, but only Hg(II) is reduced. The inability of MerA to reduce these bound metal ions may suggest that MerA differs from free FADH- and utilizes an inner-sphere electron transfer mechanism in Hg(II) reduction.     

Characterization of the transposons Tn1822 (Tc) and Tn1824 (TpSm) and the light they throw on the natural spread of resistance genes

The transposons Tn1822 (Tc) and Tn1824 (TpSm) described in this paper are very similar or identical to the transposons Tn1771 and Tn1721 (Tc), and Tn7 (TpSm), respectively. They were isolated from different sources and replicons, however, suggesting a wide distribution of these types of transposons. The method used to isolate and characterize the transposons, involving a temperature-sensitive P1 phage as their transient vehicle, is particularly suitable for epidemiological studies on transposon distribution.     

On the evolution of Tn21-like multiresistance transposons: sequence analysis of the gene (aacC1) for gentamicin acetyltransferase-3-I(AAC(3)-I), another member of the Tn21-based expression cassette

Summary The aminoglycoside-3-O-acetyltransferase-I gene (aacC1) from R plasmids of two incompatibility groups (R1033 [Tn1696], and R135) was cloned and sequenced. In the case of R1033, it was shown that theaacC gene is coded by a precise insertion of 833 bp between theaadA promoter and its structural gene in a Tn21 related transposon (Tn1696). This insertion occurs at the same target sequence as that of the OXA-1 β-lactamase gene insertion in Tn2603. Upstream of theaacC gene, we found an open reading frame (ORF) which is probably implicated in the site-specific recombinational events involved in the evolution of this family of genetic elements. These results provide additional confirmation of the role of Tn21 elements as naturally occurring interspecific transposition and expression casssettes.     

Identification of metal binding motifs in protein frameworks to develop novel remediation strategies for Hg2+ and Cr(VI)

BioMetals - Amino acid sequences in metal-binding proteins with chelating properties offer exciting applications in biotechnology and medical research. To enhance their application in...     

Influence of cations on the blue to purple transition of bacteriorhodopsin. Comparison of Ca2+ and Hg2+ binding and their effect on the surface potential

We have investigated the effect of Ca2+ and Hg2+ binding on various properties of the blue membrane prepared by deionization of the Halobacterium halobium purple membrane. Binding of radioactive 45Ca2+ and 203Hg2+ was monitored by a filtration technique. Five high and medium affinity sites for Ca2+ and seven low affinity sites for Hg2+ were found per bacteriorhodopsin. Competitive binding was observed only for three Ca2+ and three Hg2+. Visible absorption studies indicated that Ca2+ binding could restore the purple color of bacteriorhodopsin while Hg2+ was inefficient. Hg2- could partially reverse to blue the Ca2+-regenerated purple membrane in parallel with the displacement of three Ca2+. Effects of cation binding on the surface potential of the membrane were measured by Electron Spin Resonance spectroscopy using a cationic spin-labeled amphiphile. Cations such as La3+, Ca2+, Mg2+, or Na+ strongly increased (i.e. rendered less negative) the surface potential. An univocal correlation was found between the cation-induced variation of surface potential and the extent of regeneration of the purple color. Hg2+ induced a smaller increase in surface potential than that corresponding to the effective divalent cations. This lower effect appears to be due to binding to sites not related to those of other cations.