The mutagenicity of hydrazine and some of its derivatives.

The mutagenic effect of ethylenethiourea (ETU), a degradation product and metabolite of ethylenebisdithiocarbamates, which are widely used as fungicides, was studied in different test systems.ETU induced mutations of the base-pair substitution type in Salmonella typhimurium TA 1530 in vitro as well as in the host-mediated assay. In the host-mediated assay, a dose of 6000 mg/kg (LD₅₀ = 5400 mg/kg) resulted in a slight but significant increase of the reversion frequency by a factor of 2.37.The results of the micronucleus test were negative after two-fold oral applications of 700, 1850 and 6000 mg/kg to Swiss albino mice. Thus it is concluded that ETU hardly induces any chromosomal anomality in the bone marrow.No dominant-lethal effect was observed after single oral doses of 500, 1000 and 3500 mg/kg given to male mice.     

Enzymatic activation of hydrazine derivatives. A spin-trapping study

The oxidative metabolism of hydralazine, isoniazid, iproniazid, and phenylhydrazine has been studied using spin-trapping techniques. The oxidation of these hydrazine derivatives, catalyzed by horseradish peroxidase and prostaglandin synthetase, produces reactive free radical intermediates. Enzymatic activation of hydralazine produce the nitrogen-centered hydralazyl radical (RNHNH); phenylhydrazine formed only the phenyl radical. Iproniazid, on the other hand, formed both the isopropyl radical and a hydroperoxy radical. The formation of the hydroperoxy radical was not inhibited by superoxide dismutase. The horseradish peroxidase-catalyzed oxidation of isoniazid produced two different carbon-centered radicals. The identity of these radicals is not clear; however, they may arise from an acyl (RCO) radical and an alkyl (R) radical.     

Lipase catalysed acylation of hydroxylamine and hydrazine derivatives

The lipase catalysed acylation of hydroxylamine-and hydrazine as well as their derivatives by octanoic acid is very efficient. Cross-linked crystals of Candida rugosa lipase (ChiroCLEC-CR) mediated the conversion of racemic ibuprofen into (S)-ibuproxam. A number of lipases also catalysed the condensation of hydrazine with an excess of octanoic acid giving N,N′-dioctanoylhydrazine. The hydrazide of 2-(4-isobutylphenyl)propanoic acid (ibuprofen), prepared by non-enzymatic reaction of ibuprofen methyl ester with hydrazine, acted as nucleophile towards several lipases that do not accept ibuprofen derivatives as acyl donor.     

Carbonyl scavenger and antiatherogenic effects of hydrazine derivatives

Reactive carbonyl compounds (RCC) generated by polyunsaturated fatty acid oxidation alter progressively cellular and tissular proteins by forming adducts on free amino groups and thiol residues (carbonyl stress). Carbonyl scavengers may neutralize RCC, but their protective effect in atherosclerosis has not been extensively studied. We report the carbonyl scavenger and antiatherogenic properties of hydrazine derivatives, namely hydralazine, an antihypertensive drug, isoniazid, an antituberculosis agent, and two antidepressants, phenelzine and iproniazid. These drugs were poorly efficient in preventing the oxidation of LDL mediated by smooth muscle cells (SMCs), but inhibited the toxicity of UV-oxidized LDL (oxLDL) and of 4-hydroxynonenal (4-HNE). Hydrazine derivatives prevented the formation of foam cells resulting from LDL oxidation in human macrophagic U937 cells, and blocked the carbonyl stress in SMCs, by inhibiting the decrease in free amino group content, the increase in carbonylated proteins, and the formation of 4-HNE adducts on PDGFR. Experimental studies carried out on apoE-/- mice supplemented with drugs (30 mg/L in drinking water) showed a significant carbonyl stress inhibition correlated with a net reduction of atherosclerotic lesion development. In conclusion, these data indicate that hydrazine derivatives exhibit carbonyl scavenger and antiatherogenic properties, which opens novel therapeutical approaches for atherosclerosis and its cardiovascular complications.     

Effect of hydrazine derivatives, plant growth regulators, on the cytochrome oxidase reaction

Gidrel, digidrel, and sodium salt of maleic hydrazide were shown to exert no influence on oxygen consumption by cytochrome oxidase in concentrations up to 10(-1) M. Similar concentrations of N,N-dimethylamino-succinic acid hydrazide inhibited cytochrome oxidase but did not influence the optical spectrum of cytochrome oxidase.     

Effect of hydrazine, isonicotinic acid hydrazide, hydrazine sulfate, and dimethylhydrazine on guanylate cyclase activity.

The chemical carcinogen hydrazine is a potent stimulator of guanylate cyclase. In the present investigation we found that three chemical carcinogens structurally related to hydrazine, isonicotinic acid hydrazide, hydrazine sulfate, and dimethylhydrazine, decreased guanylate cyclase activity. It is of interest that hydrazine has been shown to increase DNA synthesis whereas isonicotinic acid hydrazide, hydrazine sulfate, and dimethylhydrazine decrease DNA synthesis. The relationship, if any, linking the guanylate cyclase-cyclic GMP system to DNA synthesis and carcinogenesis remains to be explored.     

On the action of hydroxylamine,hydrazine and their derivatives on the water-oxidizing complex

Photosynthetic water oxidation proceeds by a four-step sequence of one-electron oxidations which is formally described by the transitions S₀ S₁, S₁ S₂, S₂ S₃, S₃ (S₄) S₀. State S₁ is most stable in the dark. Oxygen is released during S₃ (S₄) S₀. Hydroxylamine and hydrazine interact with S₁. They cause a two-digit shift in the oxidation sequence as observed from the dark equilibrium, i.e. from S₁ S₂ : S₂ S₃ : S₃ (S₄) S₀ : S₀ S₁ :... in the absence of the agents, to S₁ ^* S₀ : S₀ S₁ : S₁ S₂ : S₂ S₃ :... in the presence of hydroxylamine or hydrazine.We measured the concentration dependence of this two-digit shift via the pattern of proton release which is associated with water oxidation. At saturating concentrations hydroxylamine and hydrazine shift the proton-release pattern from OH⁺(S₁ S₂) : 1H⁺(S₂ S₃) : 2H(S₃ S₀) : 1H⁺(S₀ S₁) :... to 2H⁺(S₁ ^* S₀) : 1H⁺(S₀ S₁) : OH⁺(S₁ S₂) : 1H⁺(S₂ S₃) : 2H⁺(S₃ S₀) :... The 2H⁺ were released upon the first excitation with a half-rise time of 3.1 ms, both with hydroxylamine and withydrazine. The concentration dependence of the shift was rather steep with an apparent Hill coefficient at half saturation of 2.43 with hydroxylamien (Förster and Junge (1985) FEBS Lett. 186, 53–57) and 1.48 with hydrazine. The concentration dependence could be explained by cooperative binding of n3 molecules of hydroxylamine and of n2 molecules of hydrazine, respectively. Tentatively, we explain the interaction of hydroxylamine and hydrazine with the water-oxidizing complex (WOC) as follows: Two bridging ligands, possible Cl^- or OH^-, which normally connect two Mn nuclei, can be substituted by either 4 molecules of hydroxylamine or 2 molecules of hydrazine when the WOC resides in state S₁.Abbreviations DNP-INT dinitrophenylether of iodonitrothymol - FWHM full width at half maximum - NR neutral red (3-amino-7-dimethylamino-2-methylphenazine-HCI) - PS II photosystem II - WOC or (in formulas:) W water-oxidizing complex Dedicated to Prof. L.N.M. Duysens on the occasion of his retirement.     

Hydrazide derivatives produce active oxygen species as hydrazine

It is well documented that some hydrazines are quite sensitive to oxidation and may serve as the electron donor for the reduction of oxygen, whereas hydrazides are not believed to react directly with oxygen. Data presented in this paper show that both hydrazides and hydrazines share an N-N moiety, which is assumed to react with atmospheric oxygen and produce oxygen radicals, at various degrees of efficiency. Since spectrometric measurements of hydrazide just after solubilization showed that the molecular mass remains constant in the absence of oxygen, we can conclude that hydrazides do not react with the oxygen through a slow spontaneous hydrolytic release of hydrazine. However, hydrazine is more reactive than hydrazide, which requires hours rather than minutes to produce measurable quantities of radical species. Differences were also apparent for various substituted derivatives. The reaction was significantly enhanced by the presence of metal ions. Data reported here demonstrate that hydrazides cause irreversible damage to the prosthetic group of proteins as well as causing degradation of the polypeptide chain into small fragments.