The Klotho protein supports redox balance and metabolic functions of cardiomyocytes during ischemia/reperfusion injury.

BACKGROUND: Acute heart ischemia followed by reperfusion leads to overproduction of reactive oxygen/ /nitrogen species (ROS/RNS), disrupted expression of nitric oxide synthase (NOS) and unbalanced glucose metabolism. Klotho is a membrane-bound or soluble protein that exerts protective activity in many organs. While Klotho is produced mainly in the kidneys and brain, it has been recently proven that Klotho is expressed in the cardiomyocytes as well. This study aimed to show the influence of the Klotho protein on oxidative/nitrosative stress and metabolic function of the cardiomyocytes subjected to ischemia/reperfusion (I/R) injury. METHODS: Human cardiac myocytes underwent in vitro chemical I/R (with sodium cyanide and 2-deoxyglucose), in the presence or absence of the recombinant human Klotho protein. The present study included an investigation of cell injury markers, level of nicotinamide adenine dinucleotide phosphate (NADPH) oxidase (NOX), level of oxidative/nitrosative stress and metabolic processes of the cardiomyocytes. RESULTS: Administration of Klotho protein resulted in mitigation of injury, decreased level of NOX2 and NOX4, reduced generation of ROS/RNS and hydrogen peroxide (H2O2), decreased expression of inducible NOS and limited production of nitrates/nitrites in cells under I/R. Glucose uptake and lactate production in the cardiomyocytes subjected to I/R were normalized after Klotho supplementation. CONCLUSIONS: The Klotho protein participates in the regulation of redox balance and supports metabolic homeostasis of the cardiomyocytes and hence, contributes to protection against I/R injury.

Cardiovascular responses to putative chemoreceptor stimulation of embryonic common snapping turtles (Chelydra serpentina) chronically incubated in hypoxia (10% O2).

Developmental hypoxia has been shown to result in significant changes in cardiovascular development of American alligators and common snapping turtles. These include similar effects on cardiac mass and aspects of cardiovascular function. However, given the distant phylogenetic relationship between crocodilians and chelonians, we hypothesized that snapping turtles would also exhibit differences in the effects of developmental hypoxia on cardiovascular regulation. This hypothesis was based in part on prior studies that documented differences in plasticity of vagal tone on the heart between alligators and snapping turtles incubated in hypoxic conditions. To test this hypothesis, we investigated how 10% O2 exposure over final 80% of incubation altered the heart rate and blood pressure response to two chemical manipulations of the "chemoreflex" in common snapping turtles at 70% and 90% of incubation. NaCN injections produced a dose dependent bradycardia that was mediated by cholinergic receptor stimulation. This reflex was relatively unaffected by hypoxic incubation conditions in snapping turtle embryos. Injections of the 5-HT3 agonist phenylbiguanide (PBG) caused a pronounced bradycardia that decreased in intensity at 90% of incubation in embryos from the normoxic group while the heart rate response was unchanged in the hypoxic group. This differs from the previously reported diminished heart rate response of embryonic alligators incubated in 10% O2, suggesting plasticity in this chemoreflex response differs between the species. Our data also indicate the cardiovascular response is mediated by a secondary cholinergic receptor stimulation however the inability of ganglionic blockade to inhibit the PBG response leaves the location of the receptors antagonized by PBG in question in embryonic snapping turtles. Primarily, our findings refute the hypothesis that hypoxic incubation decreases the "chemoreflex' response of snapping turtle embryos.

Behavioral toxicity of sodium cyanide following oral ingestion in rats: Dose-dependent onset, severity, survival, and recovery.

Sodium cyanide (NaCN) is a commonly and widely used industrial and laboratory chemical reagent that is highly toxic. Its availability and rapid harmful/lethal effects combine to make cyanide a potential foodborne/waterborne intentional-poisoning hazard. Thus, laboratory studies are needed to understand the dose-dependent progression of toxicity/lethality following ingestion of cyanide-poisoned foods/liquids. We developed an oral-dosing method in which a standard pipette was used to dispense a sodium cyanide solution into the cheek, and the rat then swallowed the solution. Following poisoning (4-128 mg/kg), overt toxic signs were recorded and survival was evaluated periodically up to 30 hours thereafter. Toxic signs for NaCN doses higher than 16 mg/kg progressed quickly from head burial and mastication, to lethargy, convulsions, gasping/respiratory distress, and death. In a follow-on study, trained operant-behavioral performance was assessed immediately following cyanide exposure (4-64 mg/kg) continuously for 5 h and again the following day. Onset of behavioral intoxication (i.e., behavioral suppression) occurred more rapidly and lasted longer as the NaCN dose increased. This oral-consumption method with concomitant operantbehavioral assessment allowed for accurate dosing and quantification of intoxication onset, severity, and recovery, and will also be valuable in characterizing similar outcomes following varying medical countermeasure drugs and doses.

Zymography Methods to Simultaneously Analyze Superoxide Dismutase and Catalase Activities: Novel Application for Yeast Species Identification.

We provide an optimized protocol for a double staining technique to analyze superoxide dismutase enzymatic isoforms Cu-Zn SOD (Sod1) and Mn-SOD (Sod2) and catalase in the same polyacrylamide gel. The use of NaCN, which specifically inhibits yeast Sod1 isoform, allows the analysis of Sod2 isoform while the use of H2O2 allows the analysis of catalase. The identification of a different zymography profiling of SOD and catalase isoforms in different yeast species allowed us to propose this technique as a novel yeast identification and classification strategy.

Effect of exposure to sublethal concentrations of sodium cyanide on the carbohydrate metabolism of the Indian Major Carp Labeo rohita (Hamilton, 1822)

Experiments were designed to study in-vivo effects of sodium cyanide on biochemical endpoints in the freshwater fish Labeo rohita. Fish were exposed to two sublethal concentrations (0.106 and 0.064mg/L) for a period of 15 days. Levels of glycogen, pyruvate, lactate and the enzymatic activities of lactate dehydrogenase (LDH), succinate dehydrogenase (SDH), glucose-6-phosphate dehydrogenase (G6PDH), phosphorylase, alkaline phosphatase (ALP), acid phosphatase (AcP) were assessed in different tissues (liver, muscle and gills). Result indicated a steady decrease in glycogen, pyruvate, SDH, ALP and AcP activity with a concomitant increase in the lactate, phosphorylase, LDH and G6PD activity in all selected tissues. The alterations in all the above biochemical parameters were significantly (p<0.05) time and dose dependent. In all the above parameters, liver pointing out the intensity of cyanide intoxication compare to muscle and gills. Study revealed change in the metabolic energy by means of altered metabolic profile of the fish. Further, these observations indicated that even sublethal concentrations of sodium cyanide might not be fully devoid of deleterious influence on metabolism in L. rohita.

High efficiency of energy flux controls within mitochondrial interactosome in cardiac intracellular energetic units.

The aim of our study was to analyze a distribution of metabolic flux controls of all mitochondrial complexes of ATP-Synthasome and mitochondrial creatine kinase (MtCK) in situ in permeabilized cardiac cells. For this we used their specific inhibitors to measure flux control coefficients (C(vi)(JATP)) in two different systems: A) direct stimulation of respiration by ADP and B) activation of respiration by coupled MtCK reaction in the presence of MgATP and creatine. In isolated mitochondria the C(vi)(JATP) were for system A: Complex I - 0.19, Complex III - 0.06, Complex IV 0.18, adenine nucleotide translocase (ANT) - 0.11, ATP synthase - 0.01, Pi carrier - 0.20, and the sum of C(vi)(JATP) was 0.75. In the presence of 10mM creatine (system B) the C(vi)(JATP) were 0.38 for ANT and 0.80 for MtCK. In the permeabilized cardiomyocytes inhibitors had to be added in much higher final concentration, and the following values of C(vi)(JATP) were determined for condition A and B, respectively: Complex I - 0.20 and 0.64, Complex III - 0.41 and 0.40, Complex IV - 0.40 and 0.49, ANT - 0.20 and 0.92, ATP synthase - 0.065 and 0.38, Pi carrier - 0.06 and 0.06, MtCK 0.95. The sum of C(vi)(JATP) was 1.33 and 3.84, respectively. Thus, C(vi)(JATP) were specifically increased under conditions B only for steps involved in ADP turnover and for Complex I in permeabilized cardiomyocytes within Mitochondrial Interactosome, a supercomplex consisting of MtCK, ATP-Synthasome, voltage dependent anion channel associated with tubulin ßII which restricts permeability of the mitochondrial outer membrane.

Respiratory distress and behavioral changes induced by sodium cyanide in the fresh water TELEOST, Cyprinus carpio (Linnaeus).

An acute toxicity (LC50) test using a static renewal bioassay method was conducted to determine the toxicity of sodium cyanide in freshwater exotic carp, Cyprinus carpio exposed for 96 h to different concentrations of sodium cyanide. The acute toxicity value was found to be 1 mg/L; one third of the LC50 (0.33 mg/L) was selected as the sublethal concentration for subacute studies. Behavioral patterns were observed in lethal (1, 2, 3, and 4 d) and sublethal concentrations (1, 5, 10, and 15 d). Cyprinus carpio in toxic media exhibited irregular, erratic, and darting swimming movements, hyperexcitability, loss of equilibrium, and sinking to the bottom, which might be due to inhibition of cytochrome c oxidase activity and decreased blood pH. The combination of cytotoxic hypoxia with lactate acidosis depresses the central nervous system and myocardium, the most sensitive critical sites for anoxia, resulting in respiratory arrest and death. A decrease in oxygen consumption (-28.36 to -78.28%; -14.22 to -47.25%) was observed at both lethal and sublethal concentrations of sodium cyanide respectively. Fish at the sublethal concentration were found under stress, but that was not fatal.

A trapping method for semi-quantitative assessment of reactive metabolite formation using [35S]cysteine and [14C]cyanide.

A trapping approach for semi-quantitative assessment of bioactivation potential has been established for new chemical entities by using [(35)S]cysteine and [(14)C]sodium cyanide as trapping reagents. Reactive metabolites were trapped as radioactive adducts with the trapping reagents to be analyzed by radio-LC(/MS). As a reference, hepatotoxic drugs (clozapine, diclofenac, R-(+)-pulegone and troglitazone) were tested in the [(35)S]cysteine trapping assay and the proposed structures of the cysteine adducts were consistent with glutathione adducts previously reported. The accuracy of this methodology to predict bioactivation potential of structurally diverse non-radiolabeled test compounds was evaluated by comparing the radiochromatographic peak area obtained in this assays with the extent of covalent binding to protein assessed by the conventional method using radiolabeled test compounds. The value obtained from the [(35)S]cysteine trapping assay in human liver microsomes predicted potential for covalent binding of the test compounds to proteins with reasonable accuracy. A combination of trapping reagents ([(35)S]cysteine and [(14)C]cyanide) improved the accuracy for prediction of bioactivation potential by simultaneously trapping both types of electrophilic reactive metabolites. This method is expected to be a useful to prioritize compounds for further development based on the bioactivation liability, especially at the lead optimization stage.

Chromate resistance, transport and bioreduction by Exiguobacterium sp. ZM-2 isolated from agricultural soil irrigated with tannery effluent.

Bacterial strain Exiguobacterium sp. ZM-2 isolated from agricultural soil irrigated with tannery effluents, was examined for its resistance to hexavalent chromium. Exiguobacterium sp. ZM-2 could resist 12.37 mM of potassium chromate. The isolate was also found resistant to other heavy metal ions. Exiguobacterium sp. ZM-2 was able to reduce 500 microM hexavalent chromium completely within 56 h under in vitro conditions. Chromate reduction was severely affected in presence of metabolic inhibitors, sodium cyanide and sodium azide. No chromate reduction was observed in presence of 1 mM sodium cyanide while only 17% of 250 microM chromate was reduced when medium contained 1 mM sodium azide. A 10 mM sodium sulphate inhibited hexavalent chromium reduction up to 35%. On the other hand, use of 1 mM 2, 4-dinitrophenol, an uncoupling agent, stimulated the chromate reduction, indicating that the respiratory-chain-linked electron transport to Cr (VI) was limited by the rate of dissipation of the proton motive force. Cell free extract of Exiguobacterium sp. ZM-2 readily reduce Cr (VI) to Cr (III). The kinetics of chromate reductase fit well in the linearized Lineweaver-Burk plot and showed a K(m) of 106.1 microM Cr (VI) and V(max) of 1.24 micromol/min per mg of protein.

Carotid chemoreceptor reflex modulation by arginine-vasopressin microinjected into the nucleus tractus solitarius in rats.

BACKGROUND: In addition to their role of sensing O2, pH, CO2, osmolarity and temperature, carotid body receptors (CBR) were proposed by us and others to have a glucose-sensing role in the blood entering the brain, integrating information about blood glucose and O2 levels essential for central nervous system (CNS) metabolism. The nucleus tractus solitarius (NTS) is an important relay station in central metabolic control and receives signals from peripheral glucose-sensitive hepatoportal afferences, from central glucose-responsive neurons in the brainstem and from CBR and arginine-vasopressin (AVP)-containing axons from hypothalamic nuclei. METHODS: In normal Wistar rats anesthetized with pentobarbital, permanent cannulas were placed stereotaxically in the NTS. Glucose changes were induced in vivo after CBR stimulation with sodium cyanide (NaCN-5 microg/100 g), preceded by an infusion of AVP [(10 or 40 pmol/100 nL of artificial cerebrospinal fluid) aCSF] or an antagonist for V1a receptors (anti-glycogenolytic vasopressin analogue-VP1-A) (100 pmol/100 nL of aCSF) into the NTS. RESULTS: CBR stimulation after an AVP infusion (larger dose) into the NTS resulted in a significantly higher arterial glucose and lower brain arterial-venous glucose difference. In the same way, VP1-A administration in the NTS significantly decreased the effects observed after AVP priming before CBR stimulation or preceding the CBR stimulation, alone. CONCLUSIONS: We propose that AVP in the NTS could participate in glucose homeostasis, modulating the information arising in CBR after histotoxic-anoxia stimulation.

Effects of bicarbonate buffer on acetylcholine-, adenosine 5'triphosphate-, and cyanide-induced responses in the cat petrosal ganglion in vitro.

Acetylcholine (ACh), adenosine 5'-triphosphate (ATP) and sodium cyanide (NaCN) activate petrosal ganglion (PG) neurons in vitro, and evoke ventilatory reflexes in situ, which are abolished after bilateral chemosensory denervation. Because in our previous experiments we superfused the isolated PG with solutions free of CO2/HCO3- buffer, we studied its effects on the PG responses evoked in vitro. PGs from adult cats were superfused at a constant pH, with HEPES-supplemented (5 mM) saline with or without CO2/HCO3- (5%/26.2 mM) buffer, and carotid (sinus) nerve frequency discharge (fCN) recorded. Increases in fCN evoked by ACh, ATP and NaCN in CO2- free saline were significantly reduced (P < 0.05, Wilcoxon test) when CO2/HCO3- was present in the superfusion medium. Thus, the presence of CO2/HCO3- buffer appears to reduce PG neurons sensitivity to ACh, ATP and NaCN, an effect that may underlie the lack of ventilatory reflexes after bilateral chemodenervation.

Azotobacter vinelandii nitrogenases with substitutions in the FeMo-cofactor environment of the MoFe protein: effects of acetylene or ethylene on interactions with H+, HCN, and CN-.

Wild-type and three altered Azotobacter vinelandii nitrogenase MoFe proteins, with substitutions either at alpha-195(His) (replaced by alpha-195(Asn) or alpha-195(Gln)) or at alpha-191(Gln) (replaced by alpha-191(Lys)), were used to probe the interactions of HCN and CN(-), both of which are present in NaCN solutions at pH 7.4, with nitrogenase. The first goal was to determine how added C(2)H(2) enhances the rate of CH(4) production from HCN reduction by wild-type nitrogenase. In the absence of C(2)H(2), wild-type Mo-nitrogenase showed a declining total electron flux, which is an overall measure of all products formed, as the NaCN concentration was increased from 1 to 5 mM, whereas the rates of both CH(4) and NH(3) production increased with increasing NaCN concentration. The NH(3) production rate exceeded the CH(4) production rate up to 5 mM NaCN, at which point they became equal. The "excess NH(3)" likely arises from the two-electron reduction of HCN to CH(2)=NH, some of which is released and hydrolyzed to HCHO plus NH(3). With added C(2)H(2), the rate of CH(4) production increased but only until it equaled that of NH(3) production, which remained unchanged. In addition, total electron flux was decreased even more at each NaCN concentration by C(2)H(2). The increased CH(4) production did not arise from the added C(2)H(2). The lowered total electron flux with C(2)H(2) present would decrease the affinity of the enzyme for HCN, making it a poorer competitor for the binding site. Thus, less CH(2)=NH would be displaced, more CH(2)=NH would undergo the full six-electron reduction, and the rate of CH(4) production would be enhanced. A second goal was to gain mechanistic insight into the roles of the amino acid residues in the alpha-subunit of the MoFe protein at positions alpha-191 and alpha-195 in substrate reduction. At 5 mM NaCN and in the presence of excess wild-type Fe protein, the specific activity for CH(4) production by the alpha-195(Asn), alpha-195(Gln), and alpha-191(Lys) MoFe proteins was 59%, 159%, and 6%, respectively, of that of wild type. For the alpha-195(Asn) MoFe protein, total electron flux decreased with increasing NaCN concentration like wild type. However, the rates of both CH(4) and NH(3) production were maximal at 1 mM NaCN, and they remained unequal even at 5 mM NaCN. With the alpha-195(Gln) MoFe protein, the rates of production of both CH(4) and NH(3) were equal at all NaCN concentrations, and total electron flux was hardly affected by changing the NaCN concentration. With the alpha-191(Lys) MoFe protein, the rates of both CH(4) and NH(3) production were very low, but the rate of NH(3) production was higher, and both rates slowly increased with increasing NaCN concentration. A hypothesis, which is based on the varying apparent affinities of the altered MoFe proteins for HCN and CN(-), is advanced to explain the higher rate of NH(3) production versus the rate of CH(4) production and the effect of increasing NaCN concentration on electron flux to products. A new method for CH(3)NH(2) quantification showed that all four MoFe proteins produced CH(3)NH(2). Added CO significantly inhibited both CH(4) and NH(3) production from HCN with all MoFe proteins except for the alpha-191(Lys) MoFe protein, which still manifested its very low rate of NH(3) production but without CH(4) production. All of the MoFe proteins responded differently to the addition of C(2)H(2) to reactions containing NaCN. With the alpha-195(Asn) MoFe protein, added C(2)H(2) decreased the rates of both CH(4) and NH(3) production, but the rate of NH(3) production decreased much less. C(2)H(2) also exacerbated the inhibition of electron flux. With the alpha-195(Gln) MoFe protein, added C(2)H(2) decreased the rates of both CH(4) and NH(3) production substantially and about equally. C(2)H(2) also eliminated the slight decrease in total electron flux that was caused by NaCN. Added C(2)H(2) hardly affected the alpha-191(Lys) MoFe protein. (ABSTRACT TRUNCA

Mechanism of covalent adduct formation of aucubin to proteins.

The iridoid glucoside aucubin can irreversibly bind to proteins through the formation of its aglycone. In view of a possible involvement of these protein adducts in the toxicity of aucubin, we investigated the mechanism of binding of aucubin to proteins. [3H]aucubin in itself did not result in binding to protein whereas it covalently bound to rat serum albumin as a function of exposure time and dose in the presence of beta-glucosidase. The rate and extent of protein binding were significantly increased in the presence of the imine-trapping agent sodium cyanide. Oral administration of [3H]aucubin to rats showed that the total radioactivity in plasma remained at a similar level for up to 6 h once peak level was reached, suggesting that a considerable amount of radioactivity might be covalently associated with plasma proteins. The levels of radioactivity in the liver and kidney after oral dosing were higher than those after i.v. dosing. These results indicate that the open-chain aglycone of aucubin can form an imine bond with a nucleophilic site of the protein and these irreversible bindings may partially contribute to its biological and toxic effects.

Mechanism of action of base release by Escherichia coli Fpg protein: role of lysine 155 in catalysis.

Fpg protein (formamidopyrimidine/8-oxoguanine DNA N-glycosylase) is a DNA repair enzyme that catalyzes the removal of oxidized purines, most notably the mutagenic 7-hydro-8-oxoguanine (8oxoGua) lesion, by an N-glycosylase action. Additionally, Fpg protein catalyzes beta and delta elimination reactions subsequent to removal of the base lesions, as well as the analogous chemistry at abasic sites (AP sites). In this report, we show that of the two lysines that are conserved among the various putative prokaryotic Fpg proteins, a site specific alteration in one of them (lysine 155 changed to alanine) displays meaningful changes in substrate activities. However, lysine 155 is not required for the postulated covalent enzyme-substrate imine intermediate as demonstrated by trapping of the mutant protein-oligonucleotide complexes with cyanide or cyanoborohydride. The K155A mutant shows a decrease in activity with the 8oxoGua-substrate of approximately 50-fold under both k(cat)/Km and k(cat) conditions. This mutant also displays a similar reduction in activity with an oligonucleotide substrate possessing a single 2'-deoxy-8-oxonebularine site. In contrast, activity for a site specific 7-methylformamidopyrimidine-modified oligonucleotide is reduced approximately 3-4-fold, a much more modest decrease in activity. Interestingly, there is a concomitant increase in AP lyase activity above wild-type for the K155A mutant (1.6-fold increase in k(cat), 32-fold increase in k(cat)/Km), demonstrating retention of functional beta and delta lyase activities. Together these observations are readily accommodated by a model requiring a direct interaction of lysine 155 with the C8 oxygen of 8-oxopurines. Thus, conservation of this amino acid residue during evolution appears to be essential for specific incision of the mutagenic 8oxoGua base lesion by Fpg protein.

Determination of cyanide using a microbial sensor.

A microbial cyanide sensor was prepared, consisting of immobilized Saccharomyces cerevisiae and an oxygen electrode. When the electrode was inserted into a solution containing glucose, the respiration activity of the microorganisms increased. The change in the respiration activity is monitored with the oxygen electrode. When cyanide is added to the sample solution, the electron transport chain reaction of the respiration system in the mitochondria is inhibited, resulting in a decrease in respiration. The inhibition is caused by cyanide binding with respiration enzymes such as the cytochrome oxidase complex in the mitochondrial inner membrane. Therefore, the cyanide concentration can be measured from the change in the respiration rate. When the sensor was applied to a batch system at pH 8.0 and 30 degrees C, the cyanide calibration curve showed linearity in the concentration range between 0.3 microM and 150 microM CN-.

Blood acidification in the swimbladder: mechanisms and metabolic pathways

The metabolism of gas gland cells of the swimbladder epithelium is specialized for the production of acidic metabolites that are released into the blood stream and provoke an increase in gas partial pressure by reducing the effective gas-carrying capacity of the blood. In a subsequent step this initial increase in gas partial pressure is multiplied by back-diffusion of gas molecules from the venous to the arterial side in the countercurrent system, the rete mirabile. Thus, gas partial pressures of up to several hundred atmospheres can be generated in the swimbladder. Measurements of metabolic end products and analysis of the formation of 14C02 from [1-14(superscription) C] glucose and [6-14(superscription) C] glucose revealed that the acidic metabolises are lactic acid, produced in the glycolytic pathway, and also C02, formed in the pentose phosphate shunt. C02 easily enters the blood stream by diffusion. The release of protons from isolated gas gland cells, however, is highly dependent on the extracellular sodium concentration. This sodium dependence can in part be blocked by addition of amiloride, indicating that a Na+/ H+ exchanger is involved in the release of protons. A significant decrease in the rate of proton secretion in the presence of the carbonic anhydrase inhibitor ethoxzolamide indicates that the second major route for the release of protons includes carbonic anhydrase activity and the diffusion of C02.

Blood acidification in the swimbladder: mechanisms and metabolic pathways.

The metabolism of gas gland cells of the swimbladder epithelium is specialized for the production of acidic metabolites that are released into the blood stream and provoke an increase in gas partial pressure by reducing the effective gas-carrying capacity of the blood. In a subsequent step this initial increase in gas partial pressure is multiplied by back-diffusion of gas molecules from the venous to the arterial side in the countercurrent system, the rete mirabile. Thus, gas partial pressures of up to several hundred atmospheres can be generated in the swimbladder. Measurements of metabolic end products and analysis of the formation of 14CO2 from [1-14C]glucose and [6-14C]glucose revealed that the acidic metabolites are lactic acid, produced in the glycolytic pathway, and also CO2, formed in the pentose phosphate shunt. CO2 easily enters the blood stream by diffusion. The release of protons from isolated gas gland cells, however, is highly dependent on the extracellular sodium concentration. This sodium dependence can in part be blocked by addition of amiloride, indicating that a Na+/H+ exchanger is involved in the release of protons. A significant decrease in the rate of proton secretion in the presence of the carbonic anhydrase inhibitor ethoxzolamide indicates that the second major route for the release of protons includes carbonic anhydrase activity and the diffusion of CO2.

Cyanide binding at the non-heme Fe2+ of the iron-quinone complex of photosystem II: at high concentrations, cyanide converts the Fe2+ from high (S = 2) to low (S = 0) spin.

The primary electron acceptor complex of photosystem II, QAFe2+, can bind a number of small molecules at the iron site, including cyanide [Koulougliotis, D., Kostopoulos, T., Petrouleas, V., & Diner, B. A. (1993) Biochim. Biophys. Acta 1141, 275-282)]. In the presence of NaCN (30-300 mM) at pH 6.5, the reduced state, QA-Fe2+, produced either by illumination at < or = 200 K or by reduction in the dark with sodium dithionite, is characterized by a g = 1.98 EPR signal. The light- or dithionite-induced g = 1.98 signal decays with increasing pH above 6.5 and is almost totally absent at pH 8.1 and NaCN concentrations above 300 mM. However, at high pH (8.1), the g = 1.98 signal still forms transiently before it decays with a t1/2 of approximately 30 min in spinach BBY preparations treated with 100 mM NaCN. Complementary to the disappearance of the g = 1.98 signal with increasing pH or incubation time, a new EPR signal develops at g = 2.0045. This signal has the characteristics of the semiquinone, QA-, uncoupled from its magnetic interaction with the iron. Prolonged incubation of a high pH, high cyanide treated sample in a cyanide-free medium at pH 6 restores the ability of the sample to develop the cyanide-induced g = 1.98 signal at pH 6.5. This indicates that the iron is not physically dissociated during the high pH cyanide treatment. The high pH, high cyanide effects are accompanied by the conversion of the characteristic Fe2+ (S = 2) Mössbauer doublet [isomer shift (Fe) = 1.19 mm/s, quadrupole splitting = 2.95 mm/s] to a new one with parameters (isomer shift = 0.26 mm/s, quadrupole splitting = 0.36 mm/s) characteristic of an Fe2+(S = 0) state.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence of dithionite contribution to the low-frequency resonance Raman spectrum of reduced and mixed-valence cytochrome c oxidase.

The resonance Raman spectra of deoxygenated solutions of mixed-valence cyanide-bound and fully reduced cytochrome oxidase derivatives that have been reduced in the presence of aqueous or solid sodium dithionite exhibit two new low-frequency lines centered at 474 and 590 cm-1. These lines were not observed when the reductant system was changed to a solution containing ascorbate and N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD). Under enzyme turnover conditions, the addition of dithionite to the reoxidized protein (the 428-nm or "oxygenated" form) increases the intensity of these lines, while reoxidation and rereduction of the enzyme in the presence of ascorbate/TMPD resulted in the absence of both lines. Our data suggest that both lines must have contributions from species formed from aqueous dithionite, presumably the SO2 species, since these two lines are also observed in the Raman spectrum of a solution of aqueous dithionite, but not in the spectrum of an ascorbate/TMPD solution. Since heme metal-ligand stretch vibrations are expected to appear in the low-frequency region from 215 to 670 cm-1, our results indicate that special care should be exercised during the interpretation of the cytochrome a3 resonance Raman spectrum.

Metabolism of cyanide by Phanerochaete chrysosporium.

The oxidation of veratryl alcohol (3,4-dimethoxybenzyl alcohol) by lignin peroxidase H2 (LiP H2) from the white rot fungus Phanerochaete chrysosporium was strongly inhibited by sodium cyanide. The I50 was estimated to be about 2-3 microM. In contrast, sodium cyanide binds to the native enzyme with an apparent sodium cyanide dissociation constant Kd of about 10 microM. Inhibition of the veratryl alcohol oxidase activity of LiP H2 by cyanide was reversible. Ligninolytic cultures of P. chrysosporium mineralized cyanide at a rate that was proportional to the concentration of cyanide to 2 mM. The N-tert-butyl-alpha-phenylnitrone-cyanyl radical adduct was observed by ESR spin trapping upon incubation of LiP H2 with H2O2 and sodium cyanide. The identity of the spin adduct was confirmed using 13C-labeled cyanide. Six-day-old cultures of the fungus were more tolerant to sodium cyanide toxicity than spores. Toxicity measurements were based on the effect of sodium cyanide on respiration of the fungus as determined by the metabolism of [14C]glucose to [14C]CO2. We propose that this tolerance of the mature fungus was due to its ability to mineralize cyanide and that this fungus might be effective in treating environmental pollution sites contaminated with cyanide.