Potassium cyanate modification of the toxic and mutagenic effects of gamma radiation and benzo(a)pyrene

In experiments with CHO-AT3-2 cell culture, a study was made of the effect of potassium cyanate (KNCO) on the effect of gamma radiation and benzo(a)pyrene (BP) by the following tests: cell viability, induction of cells with micronuclei and fragmented nuclei and mutations by thymidine kinase (TK) and Na+/K+-ATPase loci. Some tests have revealed the increase in the effect of gamma radiation and BP produced by potassium cyanate. It is suggested that the sensitizing effects are related to repair system inhibition and/or changes in the cell chromatin structure produced by KNCO.     

Role of the carbamoylation reaction in the biological activity of methyl nitrosourea

Study of the mutagenic action of methyl nitrosourea (MNU) on the CHO-AT3-2 Chinese hamster cell at 2 regimes of cell treatment (a short-term regime and prolonged 1-h treatment) revealed that increase in the duration of treatment enhanced both cell lethality and clastogenic and mutagenic effects at the TK locus and did not influence the mutation frequency at the OUAr locus. On the basis of kinetic considerations it can be concluded that the base-pair substitution-type mutants (e.g., OUAr) appear as a result of DNA alkylation and the mutants at loci with a wide spectrum of registered mutants (the TK locus) are related to a greater extent to the carbamoylating activity of MNU. This conclusion is confirmed by measurements of the effects of sequential treatment with MNU (7 min) and KNCO (1 h). A synergistic increase in lethality, clastogenicity and mutagenicity at the TK locus was found in experiments with the combined treatment of cells with ethyl methanesulfonate (EMS) and KNCO. Besides, pretreatment of cells with potassium cyanate and subsequent exposure to MNU, EMS and benzopyrene (BP) produced synergistic effects in all the tests: lethality, clastogenicity and mutation frequency at the OUAr and TK loci. Posttreatment of cells with KNCO also led to a synergistic increase in the effects of MNU, EMS and BP treatment in several tests, but not in the OUAr locus. The possible mechanism and levels of interactions between alkylation and carbamoylation and the possibility that potassium cyanate causes supramolecular lesions are discussed.     

Carbamylation of alkaline mesentericopeptidas.

The effects of carbamylation with potassium cyanate, and methylation with methyl p-nitrobenzene sulphonate on the mesentericopeptidase activity are studies. The treatment with potassium cyanate causes the enzyme to lose its activity towards ester substrates and casein. The specific reagent N-trans-cinnamoylimidazole does not acylate the active site in the carbamylated enzyme. The pH dependence of the rate of inactivation indicates that an ionizing group of pK = 7.3, probably the protonated imidazole group of the active site histidine, is involved in the reaction. The competitive inhibitor boric acid protects mesentericopeptidase against inactivation with potassium cyanate. These suggest that the active site residues are modified in the unprotected enzyme. Sixty per cent of the enzyme activity toward N-acetyl-L-tyrosine ethyl ester was restored after treatment of the carbamylated mesentericopeptidase with 1 M hydroxylamine hydrochloride. Circular dichroism spectra show that the carbamylation does not change markedly the native protein conformation.     

Release of mitochondrial respiratory control by cyanate salts

Mitochondrial respiration is stimulated by 5–40 mM potassium cyanate in the presence or absence of oligomycin. When the cyanate concentration is increased over 40 mM, the mitochondria respire at progressively lower rates. In these respects, although at relatively high concentrations, cyanate behaves as an uncoupler of oxidative phosphorylation.     

Cyanate modification of essential lysyl residues in the catalytic subunit of tobacco ribulosebisphosphate carboxylase

Crystalline ribulose-1,5-bisphosphate carboxylase (3-phospho-D-glycerate carboxy-lyase (dimerizing), EC 4.1.1.39) isolated from tobacco (Nicotiana tabacum L.) leaf homogenates is irreversibly inactivated by incubation with potassium cyanate at pH 7.4. The rate of inactivation is pseudo first-order and linearly dependent on reagent concentration. In the presence of ribulosebisphosphate or high levels of CO2 and Mg2+ the rate constant for inactivation is reduced, suggesting that chemical modification occurs in the active site region of the enzyme. In contrast, neither the effector NADPH nor the activator Mg2+ alone significantly affect the rate of inactivation by cyanate; however, NADPH markedly enhances the protective effect of CO2 and Mg2+. Incubation of the carboxylase with potassium [14C] cyanate in the absence or presence of ribulosebisphosphate revealed that the substrate specifically reduces cyanate incorporation into the large catalytic subunits of the enzyme. Analysis of acid hydrolysates of the radioactive carboxylase indicated that the reagent carbamylates both NH2-terminal groups and lysyl residues in the large and small subunits. Comparison of the substrate-protected enzyme with the inactivated carboxylase revealed that ribulosebisphosphate preferentially reduces lysyl modification within the large subunit. The data here presented indicate that inactivation of ribulosebisphosphate carboxylase by cyanate or its reactive tautomer, isocyanic acid, results from the modification of lysyl residues within the catalytic subunit, presumably at the activator and substrate CO2 binding sites on the enzyme.     

Cyanate modification of essential lysyl residues of the diphosphopyridine nucleotide-specific isocitrate dehydrogenase of pig heart.

The DPN-specific isocitrate dehydrogenase of pig heart is totally and irreversibly inactivated by 0.05 M potassium cyanate at pH 7.4 A plot of the rate constant versus cyanate concentration is not linear, but rather exhibits saturation kinetics, implying that cyanate may bind to the enzyme to give an enzyme-cyanate complex (K equal 0.125 M) prior to the covalent reaction. In the presence of manganous ion the addition of isocitrate protects the enzyme against cyanate inactivation, indicating that chemical modification occurs in the active site region of the enzyme. The dependence of the decrease of the rate constant for inactivation on the isocitrate concentration yields a dissociation constant for the enzyme-manganese-isocitrate complex which agrees with the Michaelis constant. The allosteric activator ADP, which lowers the Michaelis constant for isocitrate, does not itself significantly affect the cyanate reaction; however, it strikingly enhances the protection by isocitrate. The addition of the chelator EDTA essentially prevents protection by isocitrate and manganous ion, demonstrating the importance of the metal ion in this process. The substrate alpha-ketoglutarate and the coenzymes DPN and DPNH do not significantly affect the rate of modification of the enzymes by cyanate. Incubation of isocitrate dehydrogenase with 14C-labeled potassium cyanate leads to the incorporation of approximately 1 mol of radioactive cyanate per peptide chain concomitant with inactivation. Analysis of acid hydrolysates of the radioactive enzyme reveals that lysyl residues are the sole amino acids modified. These results suggest that cyanate, or isocyanic acid, may bind to the active site of this enzyme as an analogue of carbon dioxide and carbamylate a lysyl residue at the active site.     

Fate and transformation of thiocyanate and cyanate under methanogenic conditions

The fate of thiocyanate (SCN⁻) and cyanate (OCN⁻) under methanogenic conditions was investigated at 35 °C. Thiocyanate and cyanate were added to mixed methanogenic cultures along with an organic mixture. Thiocyanate was stable under these conditions, and had no adverse effect on methanogenesis at a concentration as high as 2.5 mM. In contrast, cyanate at a concentration as low as 0.3 mM initially inhibited methanogenesis but, after the complete removal of cyanate, methanogenesis gradually recovered. The inhibitory effect of cyanate on methanogenesis became more profound with repeated additions of cyanate. The transformation of cyanate followed the hydrolytic route to ammonia and bicarbonate under anaerobic conditions and its hydrolysis rate was enhanced by microbial activity. Cyanide was not detected as a cyanate transformation product under the methanogenic conditions of this study. Received: 13 June 1997 / Received revision: 29 August 1997 / Accepted: 15 September 1997     

Potassium activation and its relationship to a highly reactive cysteine residue in fructose 1,6-bisphosphatase

The specific chemical modification by sodium cyanate of highly reactive cysteine residues at pH 7.5 in pig kidney fructose 1,6-bisphosphatase results in the reversible loss of activation of the enzyme by monovalent cations. No loss of activation by potassium ions occurs when modification is carried out in the presence of fructose 2,6-bisphosphate. The effect of Mg2+ on native and cyanate-modified enzyme activities implicates the above cysteine residue as being directly linked to the inhibition by both the divalent cation and fructose 2,6-bisphosphate. Incorporation of [14C]cyanate to the enzyme shows that the blockage of two reactive residues per tetramer is sufficient to eliminate the activation of the enzyme by K+.     

ATP regeneration using immobilized carbamyl phosphokinase

A simple and efficient system for continuous ATP regeneration is described. The procedure is based on the enzyme-catalyzed reaction between carbamyl phosphate and ADP. The carbamyl phosphate was generated in situ by reaction between potassium cyanate and potassium phosphate. The enzyme, carbamyl phosphokinase, was isolated from extracts of Streptococcus faccalis and partially purified. Immobilization of the enzyme was achieved using glutaraldehyde-treated alkylamine glass giving 200–250 units of activity per gram of glass. A column of carbamyl phosphokinase on glass was used to form ATP continuously from ADP, phosphate, and cyanate and lost approximately 16% of the initial activity after 14 days operation at room temperature.     

Mutagenicity of cyanate, a decomposition product of MNU

Knox reported that the short-term effects of the carcinogen methylnitrosourea (MNU) were due to the formation of its decomposition product, the cyanate ion. He showed that cell survival and DNA synthesis decreased as the concentration of MNU and the cyanate ion (NCO-) increased in the medium. Further, the product of MNU decomposition comigrated with NCO- when added to his chromatographic test system. However, Knox did not study the mutagenicity of MNU or its breakdown products. We compared the mutagenicity of MNU and potassium cyanate (KNCO) in mammalian cells. Our results demonstrate that, although it is toxic to cells, KNCO does not induce ouabain-resistant mutants in cultured Chinese hamster cells (V79).     

Interrelationship between sodium cyanate and pH in the regulation of tumor cell division

Previous studies have suggested that the selective inhibitory effects of sodium cyanate on tumor metabolism in vivo may be related to a lower interstitial pH in tumors. In the present work, the influence of extracellular pH on the actions of sodium cyanate was studied with one rat hepatoma cell line (HTC) and two human colon tumor cell lines (HT29 and LS174T) and with rat hepatocytes to determine if the effects are accompanied by changes in intracellular pH. With some tumor cells, an inhibition of cell proliferation was observed when the cells were exposed to an acidic medium (pH 6.6). However, the LS174T line of human tumor cells divided at pH 6.6 essentially as fast as at pH 7.4. In the concentration range of 0.02-0.1 mg/ml, a greater inhibitory effect of cyanate on cell proliferation was observed at the lower pH. Intracellular pH was found to be influenced by the sodium ion concentration of the medium to a similar degree in the three tumor lines that were examined. The intracellular pH was found to be significantly affected by cyanate in rat hepatocytes and in two of the tumor cell lines (HT29 and LS174T). The data suggested that not only does extracellular pH influence the inhibitory effect of cyanate on tumor cell proliferation but also that cyanate can affect the regulation of intracellular pH in normal and neoplastic cells.     

Relaxation of DNA-protein interactions in mouse lymphoblastic leukemic cells exposed to antineoplastic agents

It has been demonstrated by nucleoproteid-celite chromatography that 1-nitroso-1-methylurea, potassium cyanate and prospidin reduce DNA-protein interactions in chromatin of cell cultures from LL mice with lymphoblastic leukemia.     

Divergent effects of cyanate on amino acid and phosphate uptake by liver and hepatoma.

The uptake of alpha-aminoiso[3H]butyric acid and 32Pi was observed to be inhibited by sodium cyanate in transplanted hepatomas but was increased in the livers of the tumor bearing rats. Incorporation of 32Pi into macromolecules in hepatomas was also inhibited by cyanate. Treatment with this drug did not influence circulating concentrations of isotope-labeled materials. There were relatively small effects on uptake of 36Cl- in cyanate-treated rats and the action was not tissue specific. The data were compatible with an inhibitory effect of cyanate on active transport in hepatomas which was not seen under the same conditions in host liver.     

Pseudo-halide derivatives of titanocene: synthesis and cytotoxicity studies

The well-known anticancer drug candidate bis-[(p-methoxybenzyl)cyclopentadienyl] titanium(IV) dichloride (Titanocene ) was reacted with sodium azide or potassium cyanate, thiocyanate or selenocyanate in order to give pseudo-halide analogues of Titanocene . and were characterised by single crystal X-ray diffraction, which confirmed the expected nitrogen binding of the cyanate and thiocyanate to the titanium centre. All four titanocenes had their cytotoxicity investigated through preliminary in vitro testing on the LLC-PK (pig kidney epithelial) cell line in an MTT based assay in order to determine their IC50 values. Titanocenes were found to have IC50 values of 24 (± 8) μM, 101 (± 14) μM, 54 (± 21) μM and 27 (± 4) μM respectively. All four titanocene derivatives show significant cytotoxicity improvement when compared to unsubstituted titanocene dichloride and and showed similiar cytotoxic behaviour to Titanocene in vitro.     

Cyanate specifically inhibits arginine biosynthesis in Escherichia coli K12: a case of by-product inhibition?

Growth of Escherichia coli K12 cultivated in minimal medium was strongly inhibited by 2 mM-cyanate. This inhibition could be specifically reversed by arginine. Citrulline (but not ornithine, N-alpha-acetylornithine or N-acetylglutamate) could also restore a normal growth rate. Since growth inhibition by cyanate was followed by an accumulation of ornithine within the cell it was concluded that cyanate specifically inhibits the formation of citrulline from ornithine. The effect of cyanate on the growth of defined strains was consistent with a specific inhibition of carbamoylphosphate synthase. A kinetic study of carbamoylphosphate synthase and ornithine carbamoyltransferase in vitro supported this conclusion. Since carbamoylphosphate is probably the only source of endogenous cyanate it is postulated that carbamoylphosphate synthase activity can be regulated by cyanate resulting from the dissociation of carbamoylphosphate in metabolic circumstances leading to its overproduction.     

Isolation and characterization of a cyanide-utilizing Burkholderia cepacia strain

A bacterium that utilizes cyanide as a nitrogen source was isolated from soil after enrichment in a liquid medium containing potassium cyanide (10mM) and glucose (1.0%, w/v). The strain could tolerate and grow in potassium cyanide at concentrations of up to 25mM. It could also utilize potassium cyanate, potassium thiocyanate, linamarin and a range of aliphatic and aromatic nitriles. The isolate was tentatively identified as Burkholderia cepacia strain C-3. Ammonia and formic acid were found in the culture supernatant of the strain grown on fructose and potassium cyanide, no formamide was detected, suggesting a hydrolytic pathway for the degradation of cyanide. The cyanide-degrading activity was higher in early and the stationary phase cells. Crude cell extracts of strain C-3 grown on nutrient broth exhibited cyanide-degrading activity. The characteristics of strain C-3 suggest that it would be useful in the bioremediation of cyanide-containing waste.     

Identification and characterization of a cyanate permease in Escherichia coli K-12.

Escherichia coli contains an inducible enzyme, cyanase, that catalyzes the decomposition of cyanate into ammonia and bicarbonate. The gene encoding cyanase, cynS, was cloned and found to be on a DNA fragment that contained the lac operon. Characterization of a plasmid encoding cyanase indicated that a 26-kilodalton (kDa) protein of unknown function was also induced by cyanate (Y-C. Sung, D. Parsell, P.M. Anderson, and J.A. Fuchs, J. Bacteriol. 169:2639-2642, 1987). The gene encoding the 26-kDa protein was located between cynS and its promoter, indicating the existence of a cyn operon. The 26-kDa protein was identified as a cyanate permease that transports exogenous cyanate by active transport. E. coli was shown to contain a cyanate transport system that is energy dependent and saturable by cyanate.     

Effect of chronic sodium cyanate administration on O2 transport and uptake in hypoxic and normoxic exercise.

Systemic O2 transport during maximal exercise at different inspired PO2 (PIO2) values was studied in sodium cyanate-treated (CY) and nontreated (NT) rats. CY rats exhibited increased O2 affinity of Hb (exercise O2 half-saturation pressure of Hb = 27.5 vs. 42.5 Torr), elevated blood Hb concentration, pulmonary hypertension, blunted hypoxic pulmonary vasoconstriction, and normal ventilatory response to exercise. Maximal rate of convective O2 transport was higher and tissue O2 extraction was lower in CY than in NT rats. The relative magnitude of these opposing changes, which determined the net effect of cyanate on maximal O2 uptake (VO2 max), varied at different PIO2: VO2 max (ml. min-1. kg-1) was lower in normoxia (72.8 +/- 1.9 vs. 81. 1 +/- 1.2), the same at 70 Torr PIO2 (55.4 +/- 1.4 vs. 54.1 +/- 1.4), and higher at 55 Torr PIO2 (48 +/- 0.7 vs. 40.4 +/- 1.9) in CY than in NT rats. The beneficial effect of cyanate on VO2 max at 55 Torr PIO2 disappeared when Hb concentration was lowered to normal. It is concluded that the effect of cyanate on VO2 max depends on the relative changes in blood O2 convection and tissue O2 extraction, which vary at different PIO2. Although uptake of O2 by the blood in the lungs is enhanced by cyanate, its release at the tissues is limited, probably because of a reduction in the capillary-to-tissue PO2 diffusion gradient secondary to the increased O2 affinity of Hb.     

The action of cyanate on human and pig kidney alkaline phosphatases

1. At concentrations of cyanate up to 0.2m there is an apparently reversible combination with alkaline phosphatase (EC 3.1.3.1), but higher concentrations inhibit alkaline phosphatase irreversibly by a process that is time-dependent. 2. The effect of 0.2m-cyanate on the enzymic reaction velocity depends on the substrate concentration. There is inhibition when the substrate concentration is 1.0mm or higher, but at lower substrate concentrations cyanate has an activating effect. 3. The pH-dependence of the reversible reaction suggests that cyanate may react with a thiol group at or near the active site of the enzyme, preventing a conformational change that is believed to be important in the mechanism of action of alkaline phosphatase. 4. Prolonged treatment with 0.6m-cyanate probably carbamoylates all free amino groups in the enzyme molecule and generates a new enzyme with decreased V(max.) and increased K(m).     

Cyanase-mediated utilization of cyanate in Pseudomonas fluorescens NCIB 11764.

Pseudomonas fluorescens NCIB 11764 was capable of utilizing cyanate (OCN-) as a sole nitrogen source for growth. Crude cell extracts from cells grown on cyanate, but not on ammonium sulfate, were induced for an enzyme catalyzing cyanate conversion to ammonia. Enzymatic activity was shown to be bicarbonate dependent and specific for cyanate as a substrate, suggesting that cyanate utilization in this organism is facilitated by an enzyme resembling cyanase (cyanate amidohydrolase; EC 3.5.5.3), as described previously in Escherichia coli and Flavobacterium sp.