Vanillin-coumarin hybrid molecule as an efficient fluorescent probe for trace level determination of Hg(II) and its application in cell imaging.

An efficient Hg(2+) selective fluorescent probe (vanillin azo coumarin, VAC) was synthesized by blending vanillin with coumarin. VAC and its Hg(2+) complex were well characterized by different spectroscopic techniques like (1)H NMR, QTOF-MS ES(+), FTIR and elemental analysis as well. VAC could detect up to 1.25 µM Hg(2+) in aqueous methanol solution through fluorescence enhancement. The method was linear up to 16 µM of Hg(2+). Negative interferences from Cu(2+), Ni(2+), Fe(3+), and Zn(2+) were eliminated using EDTA as a masking agent. VAC showed a strong binding to Hg(2+) ion as evident from its binding constant value (2.2×10(5)), estimated using Benesi-Hildebrand equation. Mercuration assisted restricted rotation of the vanillin moiety and inhibited photoinduced electron transfer from the O, N-donor sites to the coumarin unit are responsible for the enhancement of fluorescence upon mercuration of VAC. VAC was used for imaging the accumulation of Hg(2+) ions in Candida albicans cells.

Zn²+ chelation improves recovery by delaying spreading depression-like events.

We earlier reported that Zn²+ chelation improved recovery of synaptic potentials after transient oxygen and glucose deprivation in brain slices. Such an effect could be because of reduced accumulation of Zn²+ in postsynaptic neurons, or could also be due to prevention of the onset of spreading depression-like events. A combination of optical and electrical recording was used here to show that Zn²+ chelation is effective because it delays spreading depression-like events. If the duration of oxygen/glucose deprivation was sufficient to generate a spreading depression-like event, irrecoverable Ca²+-dependent loss of synaptic potentials occurred, regardless of Zn²+ availability. These results identify a key mechanism underlying protective effects of Zn²+ chelation, and emphasize the importance of evaluating spreading depression-like events in studies of neuroprotection.

Zinc availability regulates exit from meiosis in maturing mammalian oocytes.

Cellular metal ion fluxes are known in alkali and alkaline earth metals but are not well documented in transition metals. Here we describe major changes in the zinc physiology of the mammalian oocyte as it matures and initiates embryonic development. Single-cell elemental analysis of mouse oocytes by synchrotron-based X-ray fluorescence microscopy (XFM) revealed a 50% increase in total zinc content within the 12-14-h period of meiotic maturation. Perturbation of zinc homeostasis with a cell-permeable small-molecule chelator blocked meiotic progression past telophase I. Zinc supplementation rescued this phenotype when administered before this meiotic block. However, after telophase arrest, zinc triggered parthenogenesis, suggesting that exit from this meiotic step is tightly regulated by the availability of a zinc-dependent signal. These results implicate the zinc bolus acquired during meiotic maturation as an important part of the maternal legacy to the embryo.

The lipophilic zinc chelator DP-b99 prevents zinc induced neuronal death.

Zinc plays a key pathophysiological role in major neurological disorders as well as diabetes, while being essential for the activity of numerous zinc binding proteins. A major challenge in chelation based therapy must take into consideration these apparently conflicting effects of zinc. One approach is to limit the activity of the chelator to regions and levels of zinc pathology, making normal zinc-dependent processes invisible to the chelator. Combining fluorescent zinc imaging with cytotoxicity assays we studied the zinc chelation efficacy and neuroprotective effect of the lipophilic divalent transition metal chelator DP-b99 (1,2-Bis(2-amino-phenoxy)ethane-N,N,N',N'-tetraacetic acid-N-N'-di[2-(octyloxy)ethyl ester],-N,N'-disodium salt). The affinity of DP-b99 to Zn(2+) and Ca(2+) ions is moderate in water and enhanced significantly in the lipid milieu. Application of DP-b99 to MIN6 beta-cells that were preloaded with zinc was followed by a decrease in fluorescence of the intracellular Zn(2+) sensitive dye, ZnAF-2DA, to resting levels. Preloading of MIN6 cells with DP-b99 was also effective in attenuating subsequent cellular zinc rise. Concentration-dependence analysis of zinc accumulation indicated that DP-b99 acts as a zinc chelator with moderate affinity. DP-b99 preapplication attenuated both Zn(2+) and Ca(2+) rise in neuronal cultures and also Zn(2+) rise in brain slices. Finally, DP-b99 attenuated Zn(2+)-induced neuronal death. Our results indicate that DP-b99 is effective in attenuating Zn(2+) and Ca(2+) surges and protecting neurons against a toxic Zn(2+)-rise. This may underlie the efficacy of DP-b99 in stroke treatment.

Zinc induces expression of the BH3-only protein PUMA through p53 and ERK pathways in SH-SY5Y neuroblastoma cells.

Accumulating evidence suggests that zinc (Zn2+) contributes to neuronal death in pathologic states such as ischemia. p53-upregulated modulator of apoptosis (PUMA), which is a BH3-only protein, is known to promote apoptosis through a tumor suppressor p53-dependent and -independent mechanism. In this study, we examined the effect of Zn2+ on the induction of the PUMA gene in human neuroblastoma SH-SY5Y cells. The expression of PUMA was induced by Zn2+ in a dose- and time-dependent manner. A reporter assay revealed that Zn2+ activated the PUMA promoter. In addition, the mutation of the p53 binding site in the PUMA promoter region reduced promoter activation by Zn2+. These findings suggest that p53 participates in Zn2+-induced PUMA expression. Furthermore, we also demonstrated here that Zn2+ stimulates the phosphorylation of ERK and that the MEK-ERK pathway inhibitor, U0126, suppressed Zn2+-induced PUMA expression. Taken together, these results indicate that Zn2+ regulates the induction of PUMA through p53 and ERK pathways.

Attenuation of Zn-induced acute pancreatitis in Wistar rat fed on Cu- and Mg- enriched modified poultry egg Psi.

Zinc (Zn) consumption has increased in many populations either due to the increased intake of Zn-fortified foods as in the USA or in agricultural food stuffs as in some Indian states during the last decade. Its excessive intake has been reported to induce acute pancreatitis (AP) in many studies due to increase in oxidative stress that was further reported to cause Cu and Mg deficiencies. This led us to design a modified poultry egg (ME(Psi)) enriched with Cu and Mg along with other antioxidants, and its efficacy on Zn-induced AP was studied in male Wistar rats. In one set, the rats were fed on equacaloric semi-synthetic basal diet containing 20 mg Zn/kg diet (control, group I), and Zn-induced AP-I diet and AP-II diet containing 40 and 80 mg Zn/kg diet (groups II and III) for 180 days, respectively. In another set, the rats were initially fed on Zn-induced AP-I and AP-II diets for 90 days and then shifted to ME(Psi)-mixed Zn-induced AP-I and AP-II diets in groups IIME and IIIME for another 90 days. At the end of the experiment, data displayed increased serum and urinary Zn, Cu, and Mg levels in groups II and III rats, which were reduced and approached closer to control group I after ME(Psi) feeding in groups IIME and IIIME rats. Transmission electron microscopic studies of acinar cells revealed progressive dilation, vesicularization, and degeneration of endoplasmic reticulum (ER), and decrease in zymogen granules (ZG) in groups II and III rats in contrast to their curvilinear or concentric long parallel running cisternal profile of ER in control group I. The treatment of ME(Psi) helped in the restoration of the ER profile and ZG number, approaching closer to the control group I. The degree of recovery was dependent upon the degree of toxicity caused by the amount of Zn given in the diet. The results of this study suggest that ME(Psi)-mixed diet can protect the acinar cells from the deleterious effects of Zn by decreasing the oxidative stress.

Chelation of neurotoxic zinc levels does not improve neurobehavioral outcome after traumatic brain injury.

Increases of synaptically released zinc and intracellular accumulation of zinc in hippocampal neurons after traumatic or ischemic brain injury is neurotoxic and chelation of zinc has been shown to reduce neurodegeneration. Although our previous studies showed that zinc chelation in traumatically brain-injured rats correlated with an increase in whole-brain expression of several neuroprotective genes and reduced numbers of apoptotic neurons, the effect on functional outcome has not been determined, and the question of whether this treatment may actually be clinically relevant has not been answered. In the present study, we show that treatment of TBI rats with the zinc chelator calcium EDTA reduces the numbers of injured, Fluoro-Jade-positive neurons in the rat hippocampus 24 h after injury but does not improve neurobehavioral outcome (spatial memory deficits) 2 weeks post-injury. Our data suggest that zinc chelation, despite providing short-term histological neuroprotection, fails to improve long-term functional outcome, perhaps because long-term disruptions in homeostatic levels of zinc adversely influence hippocampus-dependent spatial memory.

Mechanism and inhibition of LpxC: an essential zinc-dependent deacetylase of bacterial lipid A synthesis.

Multi-drug resistant (MDR), pathogenic Gram-negative bacteria pose a serious health threat, and novel antibiotic targets must be identified to combat MDR infections. One promising target is the zinc-dependent metalloamidase UDP-3-O-(R-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase (LpxC), which catalyzes the committed step of lipid A (endotoxin) biosynthesis. LpxC is an essential, single copy gene that is conserved in virtually all Gram-negative bacteria. LpxC structures, revealed by NMR and X-ray crystallography, demonstrate that LpxC adopts a novel 'beta-alpha-alpha-beta sandwich' fold and encapsulates the acyl chain of the substrate with a unique hydrophobic passage. Kinetic analysis revealed that LpxC functions by a general acid-base mechanism, with a glutamate serving as the general base. Many potent LpxC inhibitors have been identified, and most contain a hydroxamate group targeting the catalytic zinc ion. Although early LpxC-inhibitors were either narrow-spectrum antibiotics or broad-spectrum in vitro LpxC inhibitors with limited antibiotic properties, the recently discovered compound CHIR-090 is a powerful antibiotic that controls the growth of Escherichia coli and Pseudomonas aeruginosa, with an efficacy rivaling that of the FDA-approved antibiotic ciprofloxacin. CHIR-090 inhibits a wide range of LpxC enzymes with sub-nanomolar affinity in vitro, and is a two-step, slow, tight-binding inhibitor of Aquifex aeolicus and E. coli LpxC. The success of CHIR-090 suggests that potent LpxC-targeting antibiotics may be developed to control a broad range of Gram-negative bacteria.

D-serine, a selective glycine/N-methyl-D-aspartate receptor agonist, antagonizes the antidepressant-like effects of magnesium and zinc in mice.

Zinc and magnesium are potent inhibitors of the N-methyl-D-aspartate (NMDA) receptor complex. Recent data demonstrate that both zinc and magnesium, like other NMDA receptor antagonists, exhibit antidepressant-like activity in rodent screening tests and depression models. In the present study, we investigated the effect of D-serine (agonist for the glycine(B) site of the NMDA receptor complex; 100 nmol/mouse, icv) on magnesium (30 mg/kg, ip)- and zinc (5 mg/kg, ip)-induced activity during a forced swim test (FST) in mice. The antidepressant-like effect observed during FST for both ions was abolished by D-serine co-treatment. The present study indicates that the NMDA receptor complex, especially the glycine(B) site, plays a role in the antidepressant-like activity of magnesium and zinc in the FST in mice.

Pyruvate protects against kainate-induced epileptic brain damage in rats.

Although the majority of epileptic seizures can be effectively controlled with antiepileptic drugs and/or surgery, a significant number progress to status epilepticus of sufficient duration to cause permanent brain damage. Combined treatment with antiepileptic drugs and neuroprotective agents, however, may help protect these individuals from permanent brain damage. Since toxicity induced by endogenous zinc contributes to epileptic brain injury, and since pyruvate is effective in reducing zinc-triggered neuronal death in cortical culture as well as ischemic neuronal death in vivo, we examined whether systemic pyruvate administration reduces seizure-induced brain damage. Na pyruvate (500 mg/kg) or osmolarity-matched saline (265 mg/kg NaCl, i.p.) were given to adult SD rats 30 or 150 min after 10 mg/kg kainite injection (i.p.), and there was no significant difference in the time course or severity of seizures between these groups. Zinc accumulation in neuronal cell bodies in the hippocampus, however, was much lower in the pyruvate than in the saline group. There was a close correlation between zinc accumulation and cell death, as assessed by acid-fuchsin and TUNEL staining. Pyruvate treatment markedly reduced neuronal death in the hippocampus, neocortex and thalamus. Pyruvate increased HSP-70 expression in hippocampal neurons. These results suggest that pyruvate, a natural glucose metabolite, may be useful as adjunct treatment in status epilepticus to reduce permanent brain damage.

Zinc inhibits astrocyte glutamate uptake by activation of poly(ADP-ribose) polymerase-1.

Several processes by which astrocytes protect neurons during ischemia are now well established. However, less is known about how neurons themselves may influence these processes. Neurons release zinc (Zn2+) from presynaptic terminals during ischemia, seizure, head trauma, and hypoglycemia, and modulate postsynaptic neuronal function. Peak extracellular zinc may reach concentrations as high as 400 microM. Excessive levels of free, ionic zinc can initiate DNA damage and the subsequent activation of poly(ADP-ribose) polymerase 1 (PARP-1), which in turn lead to NAD+ and ATP depletion when DNA damage is extensive. In this study, cultured cortical astrocytes were used to explore the effects of zinc on astrocyte glutamate uptake, an energy-dependent process that is critical for neuron survival. Astrocytes incubated with 100 or 400 microM of zinc for 30 min showed significant decreases in ATP levels and glutamate uptake capacity. These changes were prevented by the PARP inhibitors benzamide or DPQ (3,4-dihydro-5-[4-(1-piperidinyl)butoxyl]-1(2H)-isoquinolinone) or PARP-1 gene deletion (PARP-1 KO). These findings suggest that release of Zn2+ from neurons during brain insults could induce PARP-1 activation in astrocytes, leading to impaired glutamate uptake and exacerbation of neuronal injury.

Differential gene expression after zinc supplementation and deprivation in human leukocyte subsets.

An individual's zinc status has a significant impact on the immune system, and zinc deficiency, as well as supplementation, modulates immune function. To investigate the effects of zinc on different leukocyte subsets, we used microarray technology to analyze and compare the changes in mRNA expression in cell culture models of monocytes (THP-1), T cells (Jurkat), and B cells (Raji), in response to supplementation for 40 h with 50 microM zinc or 2.5 microM of the membrane-permeant zinc chelator TPEN [N,N,N',N'-tetrakis-(2-pyridyl-methyl)ethylenediamine], respectively. In each cell type, several hundred genes were identified to be zinc sensitive, but only a total of seven genes were commonly regulated in all three cell lines. The majority of those genes were involved in zinc homeostasis, and none in immune function. Nevertheless, further analysis revealed that zinc affects entire functional networks of genes that are related to proinflammatory cytokines and cellular survival. Although the zinc-regulated activities are similar throughout the gene networks, the specific genes that are affected vary significantly between different cell types, a situation that helps to elucidate the disparity of the effects that zinc has on different leukocyte populations.

Extracellular chelation of zinc does not affect hippocampal excitability and seizure-induced cell death in rats.

In the nervous system, zinc can influence synaptic responses and at extreme concentrations contributes to epileptic and ischaemic neuronal injury. Zinc can originate from synaptic vesicles, the extracellular space and from intracellular stores. In this study, we aimed to determine which of these zinc pools is responsible for the increased hippocampal excitability observed in zinc-depleted animals or following zinc chelation. Also, we investigated the source of intracellularly accumulating zinc in vulnerable neurons. Our data show that membrane-permeable and membrane-impermeable zinc chelators had little or no effect on seizure activity in the CA3 region. Furthermore, extracellular zinc chelation could not prevent the accumulation of lethal concentrations of zinc in dying neurons following epileptic seizures. At the electron microscopic level, zinc staining significantly increased at the presynaptic membrane of mossy fibre terminals in kainic acid-treated animals. These data indicate that intracellular but not extracellular zinc chelators could influence neuronal excitability and seizure-induced zinc accumulation observed in the cytosol of vulnerable neurons.

Kinetic analysis of the effects of monovalent cations and divalent metals on the activity of Mycobacterium tuberculosis alpha-isopropylmalate synthase.

Mycobacterium tuberculosis alpha-isopropylmalate synthase (MtIPMS) is a member of the family of enzymes that catalyze a Claisen-type condensation. In this work we characterized the monovalent and divalent specificity of MtIPMS using steady-state kinetics. The monovalent cation dependence of the kinetic parameters of substrates and divalent metals indicates that K+ is the likely physiological activator. K+ acts most likely as an allosteric activator, and exerts part of its effect through the catalytic divalent metal. The divalent metal specificity of MtIPMS is broad, and Mg2+ and Mn2+ are the metals that cause the highest activation. Interestingly, Zn2+, first assigned as the catalytic metal, inhibits the enzyme with submicromolar affinity. The features of monovalent cation and divalent metal activation, as well as the inhibition by Zn2+ and Cd2+, are discussed in light of the kinetic and structural information available for MtIPMS and other relevant enzymes.

Absorption of zinc and retention of calcium: dose-dependent inhibition by phytate.

The dose-dependent inhibitory effect of sodium phytate (myo-inositol-hexaphosphate) on absorption of zinc and retention of calcium was studied in man. No systematic study of this dose-response effect has been reported to this time. Forty subjects were served meals containing white wheat rolls without/with additions of phytate. Ten subjects were given test meals containing one or two of the studied levels of phytate and in addition all subjects were served meals to which no phytate was added. The zinc content was 3.1 mg (47 micromol) and the calcium content 266 mg (6.6 mmol). The rolls were labelled extrinsically with radioisotopes, 65Zn and 47Ca, and whole-body retention of both minerals was measured. Totally 105 meals were served, 36 meals in which no phytate was added and 9-10 meals on each level of phytate. The zinc absorption in meals to which either 0, 25, 50, 75, 100, 140, 175 or 250 mg of phytate-P (0, 134, 269, 403, 538, 753, 941 or 1344 micromol phytate) had been added was 22%, 16%, 14%, 11%, 7%, 7%, 7% and 6%, respectively (mean values). The addition of 50 mg phytate-P or more significantly decreased zinc absorption (p=0.01) as compared to absorption from the test meals with no added phytate. The calcium retention at day 7 in the same meals was 31%, 28%, 27%, 26%, 22%, 19%, 14% and 11% (mean values). The addition of 100 mg phytate-P or more significantly decreased calcium retention (p=0.03) compared to the test meals with no added phytate. It was concluded that the inhibitory effect of phytate on the absorption of zinc and the retention of calcium was dose dependent.

Direct visualization of mitochondrial zinc accumulation reveals uniporter-dependent and -independent transport mechanisms.

Current evidence suggests that zinc kills neurons by disrupting energy production, specifically by inhibiting mitochondrial function. However it is unclear if the inhibitory effect requires zinc accumulation, and if so, precisely how zinc enters mitochondria. Here, using fluorescence microscopy to visualize individual rat brain mitochondria, we detected matrix zinc uptake using the fluorophore FluoZin-3. Fluorescence increased rapidly in mitochondria treated with micromolar free zinc, and was quickly returned to baseline by membrane permeant chelation. Zinc uptake occurred through the calcium uniporter, because depolarization or uniporter blockade reduced fluorescence changes. However, increased fluorescence under these conditions suggests that zinc can enter through a uniporter-independent pathway. Fluorescence steadily declined over time and was unaffected by acidification or phosphate depletion, suggesting that zinc precipitation is not a mechanism for reducing matrix zinc. Uniporter blockade with ruthenium red also did not change the rate of zinc loss. Instead, zinc appears to exit the matrix through a novel efflux pathway not yet identified. Interestingly, dye-loaded mitochondria showed no fluorescence increase after treatment with strong oxidants, arguing against oxidant-labile intra-mitochondrial zinc pools. This study is the first to directly demonstrate zinc accumulation in individual mitochondria and provides insight about mechanisms mediating mitochondrial zinc uptake and efflux.

Inhibition of pea ferredoxin-NADP(H) reductase by Zn-ferrocyanide.

Ferredoxin-NADP(H) reductases (FNRs) represent a prototype of enzymes involved in numerous metabolic pathways. We found that pea FNR ferricyanide diaphorase activity was inhibited by Zn2+ (Ki 1.57 microM). Dichlorophenolindophenol diaphorase activity was also inhibited by Zn2+ (Ki 1.80 microM), but the addition of ferrocyanide was required, indicating that the inhibitor is an arrangement of both ions. Escherichia coli FNR was also inhibited by Zn-ferrocyanide, suggesting that inhibition is a consequence of common structural features of these flavoenzymes. The inhibitor behaves in a noncompetitive manner for NADPH and for artificial electron acceptors. Analysis of the oxidation state of the flavin during catalysis in the presence of the inhibitor suggests that the electron-transfer process between NADPH and the flavin is not significantly altered, and that the transfer between the flavin and the second substrate is mainly affected. Zn-ferrocyanide interacts with the reductase, probably increasing the accessibility of the prosthetic group to the solvent. Ferredoxin reduction was also inhibited by Zn-ferrocyanide in a noncompetitive manner, but the observed Ki was about nine times higher than those for the diaphorase reactions. The electron transfer to Anabaena flavodoxin was not affected by Zn-ferrocyanide. Binding of the apoflavodoxin to the reductase was sufficient to overcome the inhibition by Zn-ferrocyanide, suggesting that the interaction of FNRs with their proteinaceous electron partners may induce a conformational change in the reductase that alters or completely prevents the inhibitory effect.

Infarct reduction in rats following intraventricular administration of either tissue plasminogen activator (tPA) or its non-protease mutant S478A-tPA.

In addition to its thrombolytic effect, human recombinant tissue plasminogen activator (tPA) may have parenchymal effects such as protease-dependent neurotoxic and protease-independent neuroprotective effects. The purpose of this study was to examine parenchymal effects of tPA and its non-protease mutant S478A-tPA in permanent focal cerebral ischemia in rats. However, before doing in vivo experiments, effects of tPA and S478A-tPA on zinc or NMDA toxicity were first studied in cortical cultures. Like tPA, which has protease-independent cytoprotective effects, the non-protease mutant S478A-tPA blocked zinc toxicity in cortical cell cultures, but did not affect calcium-mediated NMDA toxicity. Then, effects of tPA and S478A-tPA on infarcts induced by permanent occlusion of middle cerebral artery (MCA) were investigated. tPA and S478A-tPA were administered into the cerebral ventricle 15 min or 1 h after MCA occlusion. Both tPA and its non-protease mutant S478A-tPA, when given 15 min after ischemia, substantially reduced infarcts and ameliorated motor deficits in the MCA occlusion model of focal cerebral ischemia. However, when administered 1 h after MCA occlusion, neither showed protective effects. The protective effects of tPA or S478A-tPA remained unchanged at 7 days after MCA occlusion. Indicating that the native protein conformation is necessary for the protective effect of tPA and S478A-tPA, heat-denatured tPA did not exhibit any protective effect. Since S478A-tPA lacks protease activity, which has been implicated in causing cerebral hemorrhage or aggravating excitotoxicity, its parenchymal neuroprotective effect may be useful in treatment of ischemic stroke.

Attenuation of zinc-induced neuronal death by the interaction of growth inhibitory factor with Rab3A in rat hippocampal neurons.

We examined the protective effect of growth inhibitory factor (GIF) against zinc-induced neuronal death in rat hippocampal neurons. In an in vitro cell culture system, 300 microM Zn(2+) readily induced death of hippocampal neuronal cells, which was characterized by massive necrosis and a minor degree of apoptosis. Neither the addition of recombinant GIF nor Rab3A alone could rescue these cells from death. However, the combination of GIF with Rab3A could significantly enhance the survival of the hippocampal neurons. This result was supported by both Annexin -V FITC/propidium dual staining and chromosomal DNA analysis. These findings suggest that GIF may inhibit Zn(2+)-induced neuronal death via its interaction with Rab3A.