Brian B. Hasinoff

Mechanism of ochratoxin a stimulated lipid peroxidation

Lipid peroxidation, measured as malondialdehyde formation or by oxygen uptake, was stimulated markedly by the mycotoxin ochratoxin A (OTA) in a reconstituted system consisting of phospholipid vesicles, the flavoprotein NADPH-cytochrome P450 reductase, Fe3+, EDTA and NADPH. Deletion of EDTA lowered the extent of lipid peroxidation but did not eliminate it. Fluorometric and spectrophotometric studies demonstrated the formation of a 1:1 Fe3(+)-OTA complex. The rate of reduction of Fe3+ to Fe2+ was enhanced markedly in the presence of OTA, and there was a further increase in the rate when EDTA was also included. The data indicate that OTA stimulates lipid peroxidation by complexing Fe3+ and facilitating its reduction. Subsequent to oxygen binding, an iron-oxygen complex of undetermined nature initiates lipid peroxidation. Free hydroxyl radicals appear not to participate in lipid peroxidation stimulated by Fe3(+)-OTA.

Kinetics of acetylthiocholine binding to electric eel acetylcholinesterase in glycerol/water solvents of increased viscosity Evidence for a diffusion-controlled reaction

Steady-state kinetic studies were made on the very efficient enzyme hydrolysis of acetylthiocholine by electric eel acetylcholinesterase (acetylcholine acetylhydrolase, EC 3.1.1.7) in glycerol/water solvents of increased viscosity. Determinations of the very fast minimum substrate association rate constants kmin, (2 . 10(8) M-1 . s-1 at I approximately 0.1 M and 25 degrees C) from the Michaelis parameters, V/(Km[E0]), were made at low substrate concentrations in order to obtain kmin directly. kmin was shown to be strongly dependent upon viscosity, which is characteristic of a diffusion-controlled reaction. kmin is as large or larger than plausible models for a simple diffusion-controlled reaction between a charged enzyme and substrate would suggest. Enhancement of the diffusion-controlled reaction through nonspecific binding of substrate to the highly negatively charged acetylcholinesterase followed by two-dimensional surface diffusion in a random walk to the active site may be a factor in this enzyme mechanism. Evidence for this comes from the viscosity dependence of kmin. Using the surface diffusion model it is estimated that the binding-site target area on acetylcholinesterase is effectively increased a minimum of 8-fold.

Adriamycin and its iron(III) and copper(II) complexes: Glutathione-induced dissociation; cytochrome c oxidase inactivation and protection; binding to cardiolipin

Some reactions of adriamycin (doxorubicin) and its Fe3+ and Cu2+ complexes were investigated with a view to understanding the mechanisms by which metal ion-adriamycin complexes damage cellular components. The ability of adriamycin in the presence of Cu2+ to inactivate the mitochondrial enzyme cytochrome c oxidase was effectively prevented by physiologic levels of glutathione. This result is explained by the observation that glutathione reacts with the Cu2+-adriamycin complex to produce free adriamycin. As sulfhydryl compounds are, in contrast, known to promote Fe3+-adriamycin-induced damage to cellular components, these results suggest that the response of a metal ion-adriamycin system to the presence of sulfhydryl compounds may be indicative of whether or not Cu2+-adriamycin is the damaging species. The partition of adriamycin into the octanol phase of an octanol-water two-phase system was greatly enhanced by the presence of cardiolipin. This result can be explained by the formation of a strong adriamycin-cardiolipin complex in the octanol phase which is one-half formed at an adriamycin concentration of 6 microM.

The iron(III) and copper(II) complexes of adriamycin promote the hydrolysis of the cardioprotective agent ICRF-187 ((+)-1,2-bis(3,5-dioxopiperazinyl-1-yl)propane)

ICRF-187 ((+)-1,2-bis(3,5-dioxopiperazinyl-1-yl)propane) has shown promise (Speyer et al., N. Engl. J. Med. 319, 745 (1988)) as a cardioprotective agent against what may be an iron-based adriamycin-induced cardiotoxicity. ICRF-187, which is membrane permeable, likely exerts its action through its ringsopened hydrolysis product which has a structure similar to EDTA and which, likewise, strongly binds metal ions. Both Fe3+-adriamycin and Cu2+-adriamycin reacted directly with ICRF-187, promoting a ring-opening hydrolysis of ICRF-187 that resulted in the displacement of the metal ion from its complex with adriamycin. Thus ICRF-187 can be considered to be acting as a “suicide protective agent” in its reaction with metal ion-adriamycin complexes. That this metal ion complex-promoted hydrolysis was preceeded by mixed ligand complex formation is evidenced by the fact that the first-order rate constant for loss of metal ion from the adriamycin complex exhibits saturation behaviour at high ICRF-187 concentrations. Also direct spectroscopic evidence was obtained both for a Cu2+-adriamycin-ICRF-187 mixed ligand complex and a Cu2+ (ICRF-187)2 complex. The Fe3+-adriamycin complex inactivates the cytochromec oxidase and NADH cytochromec reductase activity on submitochondrial particles. The protection that ICRF-187 affords against this loss of activity may be explained both on the basis of simple Fe3+ removal from Fe3+-adriamycin and also on formation of a less active Fe3+-adriamycin-ICRF-187 mixed ligand complex.

NADPH-cytochrome-P-450 reductase promoted hydroxyl radical production by the iron(III)-ochratoxin A complex.

The Fe3+ complex of ochratoxin A has been shown to produce hydroxyl radicals in the presence of NADPH and NADPH-cytochrome-P-450 reductase. ESR spin-trapping experiments carried out in the presence of the hydroxyl radical scavenger ethanol and the spin trap DMPO (5,5-dimethyl-1-pyrroline-1-oxide) produced ESR spectra characteristic of the hydroxyl radial-derived carbon-centered DMPO-alkoxyl radical adduct. Thus hydroxyl radicals produced by the Fe3(+)-ochratoxin A complex in the presence of an enzymatic reductase may be be partly responsible for ochratoxin A toxicity.

The diffusion-controlled reaction kinetics of the binding of CO and O2 to myoglobin in glycerol-water mixtures of high viscosity☆

Abstract The kinetics of the reaction of myoglobin (Mb) with CO and O 2 have been studied as a function of temperature by flash photolysis in mixtures of glycerol and water of high viscosities. This was done in order to examine the importance of diffusion-controlled kinetics on protein-ligand reactions. The apparent activation enthalpies of the binding reaction show changes with temperature consistent with a change from chemical activation control of the reaction at higher temperatures to diffusion control at the lower temperatures and higher viscosities. The activation enthalpies for ligand binding in the diffusion-controlled temperature region are similar in value to the viscosity activation energies of the particular solvent mixture as might be expected for a diffusion-controlled reaction. Curve fitting of the rate-temperature data yields factors by which the diffusion-controlled reaction departs from that predicted for reaction between spherically symmetric, uniformly reactive molecules of equal radii. This factor is between 0.1 and 6, depending both upon the solvent mixture and the ligand. Various models for diffusion-controlled reaction with steric requirements are examined in order to rationalize these results. The existence of a linear correlation between Δ H ‡ and Δ S ‡ for the chemica activation-controlled portions of reaction yield isokinetic temperatures of 305 and 288 °K for the CO and O 2 reactions, respectively.

The association reaction of yeast alcohol dehydrogenase with coenzyme is partly diffusion-controlled in solvents of increased viscosity

The steady-state kinetics of the yeast and liver alcohol dehydrogenase catalyzed reduction of aldehydes were examined in solvent mixtures of increased viscosity. This was done to investigate the effects of diffusion control on the fast association of NADH with the enzymes. Both glycerol and sucrose were unsatisfactory as viscosogens, as they inhibited the enzyme, but poly(ethylene glycol)/water mixtures were satisfactory. The 5-fold faster reaction of yeast alcohol dehydrogenase with NADH is partly diffusion controlled, whereas the slower liver alcohol dehydrogenase reaction showed no diffusion effects. These results are consistent with a yeast alcohol dehydrogenase active site that has relatively little steric hindrance to NADH binding. It is estimated that contributions to this association reaction from diffusion control and chemical activation control are equal at a solvent viscosity of 10 cP. Thus, under physiological conditions of increased viscosity the NADH association may be significantly affected by diffusion effects. In order to estimate accurately the maximum diffusion-controlled rate constant from diffusion theory, the diffusion coefficients of NADH were measured in poly(ethylene glycol)/water mixtures and were found to vary inversely as the solvent viscosity raised to the power of 0.5. The non-Stokesian behaviour of molecules as large as NADH in polymer/water mixtures may be a serious limitation to the routine use of poly(ethylene glycol) as a viscosogen for diffusion studies.

The Adriamycin (doxorubicin)-induced inactivation of cytochrome c oxidase depends on the presence of iron or copper

1. It was confirmed that Adriamycin (doxorubicin) inactivates cytochrome c oxidase upon incubation. However, further investigation shows that this inactivation is strongly dependent upon the presence of Fe3+ and Cu2+. Trace amounts of these transition metal ions, present in phosphate and Tris buffers, bind strongly to the Adriamycin and the complex formed is responsible for the inactivation of cytochrome c oxidase. No Adriamycin-induced inactivation of cytochrome c oxidase occurred in the presence of EDTA or in phosphate buffers purified on a cation exchange column to remove trace metals. 2. The metal ion-induced inactivation of cytochrome c oxidase by Adriamycin results in significant decreases in both the maximum velocity and the Michaelis constant. The degree of inactivation is strongly dependent on the Fe3+ concentration. 3. Cardiolipin partially protects against cytochrome c oxidase inactivation, presumably by binding to the cytochrome c oxidase, whereas catalase or superoxide dismutase partially protect by scavenging damaging reactive oxygen species generated within a Fe3+-Adriamycin-enzyme complex.

Quantitative structure-activity relationships for the reaction of hydrated electrons with heme proteins

Abstract Quantitative structure-activity relationships have been obtained for the reaction of a variety of heme proteins with the hydrated electron. The reaction path leading to heme reduction was found to be dependent primarily on protein molecular weight and charge. The reaction path leading to formation of radical sites not on the heme was weakly dependent upon the number of free cysteines. Mechanisms involving electron transfer between aromatic amino acids can be ruled out due to the lack of any dependence on the number or type of aromatic amino acids.

Kinetics of carbonic anhydrase catalysis in solvents of increased viscosity: A partially diffusion-controlled reaction☆

Steady-state kinetic studies of the bovine carbonic anhydrase B-catalyzed hydration of CO2, dehydration of HCO3-, and hydrolysis of p-nitrophenylacetate were made in glycerol/water solvents of increased viscosity in order that the effect of diffusion-control on the substrate association reactions could be determined. The minimum association rate constants (kmin = V/(Km[E0])) were obtained at low substrate concentrations. The esterase activity did not depend upon the solvent viscosity. However, both the CO2 hydration and HCO3- dehydration reactions depended upon the solvent viscosity consistent with partial diffusion control. Thus both chemical activation and diffusion control processes contribute to the observed kmin. In low-viscosity aqueous solutions both hydration and dehydration are largely controlled by chemical activation. However, at higher viscosities, equal to that found in the interior of the erythrocyte, both reactions are largely diffusion controlled. This result can be interpreted to mean that carbonic anhydrase is a highly evolved enzyme that has approached its maximum efficiency. The extent of diffusion control observed rules out H2CO3 as a significant reactant with the enzyme. Several models that yield minimum steric requirements for access of substrate to the active site are examined. Minimum steric constraints are less for the smaller CO2. The slower esterase reaction is not influenced by diffusion.