The fate of phenylhydroxylamine in human red cells.

Phenylhydroxylamine added to human red cells under aerobic conditions and in the presence of glucose was partly reduced to aniline. About half the hydroxylamine was recovered as amine after a 2-hr incubation. The aniline, after acetylation, was identified as acetanilide by melting point, Rf-value in TCL as well as UV, IR, and NMR spectroscopy. The fate of the remaining phenylhydroxylamine was followed by use of 14C-labeled phenylhydroxylamine. About 30% of the total radioactivity was bound to hemoglobin or other proteins and about 20% was found in highly polar low-molecular substances which were insoluble in organic solvents. The elucidation of the sites at which phenylhydroxylamine was bound to hemoglobin was complicated by the lability of the bonds. When purified human hemoglobin had reacted with radioactive phenylhydroxylamine, large proportions of the radioactivity bound to hemoglobin were removed by treatment with acid or with PMB for separation of alpha- and beta-chains. The radioactive compound liberated from hemoglobin by acid was found to be aniline. After reaction with phenylhydroxylamine the number of SH groups titrable with PMB was found to be diminished. Pretreatment of hemoglobin with N-ethylmaleimide or PMB decreased the amount of phenylhydroxylamine bound to hemoglobin but did not fully prevent the reaction. Tryptic digestion of hemoglobin after reaction with radioactive phenylhydroxylamine yielded tryptic peptides with lower specific activity than that of hemoglobin. Chymotryptic digestion of the tryptic core yielded a core with specific activity much higher than that of hemoglobin. Fingerprinting of the tryptic or chymotryptic hydrolyzates showed the presence of peptides with high and other ones with low or no radioactivity and of radioactive compounds which did not react with ninhydrin. In the covalent binding of phenylhydroxylamine to globin the SH group beta93 plays an important role, but other yet unknown sites are also reactive.

Biotransformation and some effects of 2-dimethylamino-4-(N-methylanilino)-phenol in dogs.

2-Dimethylamino-4-(N-methylanilino)-phenol (MP), an active metabolite of N,N-dimethylaniline-N-oxide in the autocatalytic formation of ferrihemoglobin, reacted quickly in dogs after intravenous injection. A dose of 14C-labeled MP which oxidized 40% of the hemoglobin disappeared from the blood in 20 min. During this period of time MP transferred catalytically electrons from ferrohemoglobin to oxygen, reacted with sulfotransferases to form the sulfuric acid ester, and was covalently bound in blood and other tissues. In the urine, in addition to the sulfuric acid ester of MP (25%), methylamine, dimethylamine, and N-methylaniline were found. Their amount indicated that most of the MP not esterified with sulfuric acid had lost a nitrogen by hydrolysis of the quinonimine. The metabolites which were covalently bound in blood and other tissues disappeared slowly, traces of radioactivity being found in blood and urine 7 days after i.v. injection of MP, 15 mg/kg. The formation of methylamines as well as N-methylaniline from MP in vivo and in blood in vitro proves that the oxidation product of MP, a purple dye, is a resonance hybrid of the two structures 2-dimethylamino-N-methyl-N-phenyl-1,4-benzoquinone-4-imonium and 4-(N-methylanilino)-N,N-dimethyl-1,2-benzoquinone-2-imonium. In addition to ferrihemoglobin MP produced numerous Heinz bodies in red cells and caused hemolytic anemia. After lethal doses necroses in the kidney tubules were found.

The effect of tris(2-chloroethyl)amine on human hemoglobin.

The reaction of tris(2-chloroethyl)amine (TCEA) with purified hemoglobin and its effect on properties of hemoglobin was studied using 14C-labeled TCEA. Hemoglobin remained soluble after binding as much as 4 TCEA per heme. In concentrations which did not denature hemoglobin TCEA reacted only with a small proportion of the free SH groups; blockade of the SH groups with PMB did not noticeably affect the binding of TCEA to hemoglobin. Hydrolysis by trypsin or chymotrypsin of hemoglobin which had reacted with TCEA yielded radioactive peptides besides not radioactive peptides and radioactive compounds not reacting with ninhydrin. The reaction with TCEA caused a change in electrophoretic mobility of hemoglobin and prevented its complete disintegration by PMB into subunits. After reaction with TCEA the affinity of hemoglobin for oxygen was strongly increased and the heme-heme interaction strongly diminished. The Bohr effect and the effect of 2,3-diphosphoglycerate on oxygen affinity remained unchanged. The effect of TCEA on the properties of hemoglobin points to specificity in its reaction with functional groups of hemoglobin.

Mechanism of the autocatalytic formation of ferrihemoglobin by N,N-dimethylaniline-N-oxide. Structure and ferrihemoglobin forming activity of the purple dye.

The structure of the leuco compound of the purple dye which is formed in mixtrues of N,N-dimethylaniline-N-oxide (DANO) and ferrihemoglobin or ferricytochrome c was elucidated. IR, NMR, mass spectroscopy, and synthesis by oxidation of mixtures of N-methylaniline and 2-dimethylaminophenol showed that the leuco compound is produced by condensation of these two compounds. But only X-ray analysis proved the structure: 2-dimethylamino-4-(N-methylanilino)-phenol. The purple dye was produced from the leuco compound by withdrawal of two electrons and may be considered as resonance hybrid of the p-quinonimine and the o-quinonimine. When DANO was incubated with ferrihemoglobin or ferricytochrome c the oxygen of DANO was used for the production of the dye by oxidation of N-methylaniline and 2-dimethylaminophenol. The amount of N,N-dimethylaniline found in the incubation mixtures corresponded with the amount of purple dye produced. In the absence of molecular oxygen from incubation mixtures of DANO with cytochrome c the purple dye was formed at the same rate as under air. In blood in vitro the purple dye catalytically transferred electrons from ferrohemoglobin to molecuar oxygen. Its ferrihemoglobin-forming activity was lower than that of 4-dimethylaminophenol but higher than that of 2-dimethylaminophenol. The chemical mechanism of the autocatalytic formation of ferrihemoglobin by DANO is described.

Biotransformation of 4-dimethylaminophenol: reaction with glutathione, and some properties of the reaction products.

4-Dimethylaminophenol (DMAP) forms ferrihemoglobin by catalytic transfer of electrons from ferrohemoglobin to oxygen. In solutions of purified human hemoglobin, quick binding of oxidized DMAP to the globin moiety of hemoglobin terminates this reaction. Reduced glutathione in high concentrations, as in the red cell, substantially diminished binding of oxidized DMAP to hemoglobin by formation of S,S,S-(2-dimethylamino-5-hydroxy-1,3,4-phenylene)-tris-glutathione (tris-(GS)-DMAP), which does not form ferrihemoglobin. In the presence of reduced glutathione, DMAP disappeared more rapidly from hemoglobin solutions than in its absence. The formation of tris(GS)-DMAP in red cells was found to be of importance for the termination of catalytic ferrihemoglobin formation by DMAP in vivo. With low concentrations of GSH, DMAP in hemoglobin solutions formed another conjugate, (GS)-DMAP, S,S(2-dimethylamino-5-hydroxy-1,3-phenylene)-bis-glutathione. Similar to DMAP, bis(GS)-DMAP catalyzed the formation of ferrihemoglobin. As the oxidized bis(GS)-DMAP was bound to hemoglobin more slowly and to a lesser extent, it produced more ferrihemoglobin than DMAP. In contrast to the reactions of DMAP with hemoglobin, hydrogen peroxide and superoxide radicals are involved in the ferrihemoglobin formation by bis(GS)-DMAP. The radicals accelerate the oxidation of bis(GS)-DMAP and thereby the ferrihemoglobin formation.