Ben-Zhan Zhu

New Modes of Action of Desferrioxamine: Scavenging of Semiquinone Radical and Stimulation of Hydrolysis of Tetrachlorohydroquinone

Desferrioxamine (DFO) is a common drug used in the treatment of iron overload. In addition to its iron-chelation, other properties have been identified. Alas, DFO has demonstrable effects which cannot be explained by its classically established properties; i.e., DFO protects against DNA single strand breaks induced by tetrachlorohydroquinone (TCHQ), while other iron chelators such as DTPA (diethylenetriaminepentaacetic acid) do not. The autooxidation process of TCHQ yielding the tetrachlorosemiquinone radical (TCSQ.) intermediate, was studied here in the presence of chelators. DFO led to a marked reduction in both concentration and life span of TCSQ. via formation of DFO-nitroxide radical (DFO.). In contrast, DTPA had no detectable effect on TCHQ autooxidation. Present studies indicate that the protective effects of DFO on TCHQ-induced DNA damage were not due to the binding of iron, but rather to scavenging of the reactive TCSQ. and the formation of the less reactive DFO.. An additional mode of action of DFO was identified, via stimulation of the hydrolysis (dechlorination) of tetrachloro-1,4-benzoquinone (chloranil), which is the oxidation product of TCHQ, to form 2,5-dichloro-3,6-dihydroxy-1,4-benzoquinone (chloranilic acid). The results of this study demonstrate two new modes of action for DFO: the scavenging of deleterious semiquinone radical, and the stimulation of the hydrolysis of halogenated substituents on the quinone structure. Both modes might prove highly relevant to the biological activities of DFO.

Protection by desferrioxamine and other hydroxamic acids against tetrachlorohydroquinone-induced cyto- and genotoxicity in human fibroblasts

Tetrachlorohydroquinone (TCHQ) has been identified as a major toxic metabolite of the widely used wood preservative pentachlorophenol and has also been implicated in its genotoxicity. We have recently demonstrated that protection by the trihydroxamate iron chelator desferrioxamine (DFO) on TCHQ-induced single-strand breaks in isolated DNA was not the result of its chelation of iron but rather of its efficient scavenging of the reactive tetrachlorosemiquinone (TCSQ) radical. In this study, we extended our research from isolated DNA to human fibroblasts. We found that DFO provided marked protection against both the cyto- and genotoxicity induced by TCHQ in human fibroblasts when it was incubated simultaneously with TCHQ. Pretreatment of the cells with DFO followed by washing also provided marked protection, although less efficiently compared with the simultaneous treatment. Similar patterns of protection were also observed for three other hydroxamic acids (HAs): aceto-, benzo-, and salicylhydroxamic acid. Dimethyl sulfoxide, an efficient hydroxyl radical scavenger, provided only partial protection even at high concentrations. In vitro studies showed that the HAs tested effectively scavenged the reactive TCSQ radical and enhanced the formation of the less reactive and less toxic 2,5-dichloro-3, 6-dihydroxy-1,4-benzoquinone (chloranilic acid). The results of this study demonstrated that the protection provided by DFO and other HAs against TCHQ-induced cyto- and genotoxicity in human fibroblasts is mainly through scavenging of the observed reactive TCSQ radical and not through prevention of the Fenton reaction by the binding of iron in a redox-inactive form.

Synergistic cytotoxicity between pentachlorophenol and copper in a bacterial model

Both pentachlorophenol (PCP) and copper compounds have been widely used as wood preservatives, and are commonly found not only in the area near wood-preserving facilities, but also in body fluids and tissues of people who are not occupationally exposed to them. In this study, we found that exposing bacteria to a combination of PCP and copper at non- or sub-toxic concentrations resulted in enhanced cytotoxic effect in a synergistic mode as indicated by both the inhibition of growth and the lowering of the colony-forming ability. The toxicity of the combination PCP/Cu(II) was relieved by hydrophilic chelating agents, thiol compounds and adventitious proteins, but was markedly potentiated by low levels of the lipophilic metal chelating agents.

Mechanism of the synergistic cytotoxicity between pentachlorophenol and copper-1,10-phenanthroline complex: the formation of a lipophilic ternary complex

When non- or sub-toxic levels of pentachlorophenol (PCP) and bis-(1, 10-phenanthroline)cupric complex, Cu(II)(OP)(2), were combined, a remarkable synergistic toxicity was observed as indicated by growth inhibition and bacterial inactivation. Similar synergistic cytotoxic effects were observed with other polychlorinated phenols and other positively charged cupric complexes. The synergism observed for these chemicals and similar reactive pairs of chemicals was found to be due to the formation of lipophilic ternary complexes which facilitated copper transport into the bacterial cells. The formation of ternary complexes of similar lipophilic character could be of relevance as a general mechanism of toxicity.

Synergism between the toxicity of chlorophenols and iron complexes.

Synergistic interactions could prove to be relevant when evaluating the toxicity of environmental pollutants in a complex mixture, especially when organic and inorganic substances co-occur at concentrations currently considered to be low-toxic or sublethal. Escherichia coli cells (SR-9 strain) were used as a model system for studying the cellular toxicity of environmental pollutants. Exposure of bacterial cells to a combination of pentachlorophenol (PCP) and a positively charged complex of iron or copper caused a dramatic inhibition of growth and an increase in cell death. Incubation of bacterial cells with PCP and either ferric-1,10-phenanthroline complex [Fe3+(OP)3]3+ (500 and 5 microM, respectively) or cupric-1,10-phenanthroline complex [Cu2+(OP)2]2+ (400 and 0.05 microM, respectively) showed two and four log units of cell death, respectively, in 30 min. In contrast, only minor amounts of cell death were observed with each component alone. Similar effects have been shown for other positively charged complexes of transition metals and for other biocides. The observed synergism was associated with the formation of novel noncharged and lipophilic ternary complexes, which contain PCP anions (or other polychlorinated anions) and the iron (or copper) complex. The ternary complexes demonstrated effective transport of their components into the cells.

Non-Chelation Dependent Redox Actions of Desferrioxamine

Desferrioxamine (DFO) has been widely used as a specific iron chelator. In this study, the non-chelation dependent redox actions of DFO were demonstrated. The protection by DFO against DNA scission caused by tetrachlorohydroquinone arises from a reaction between tetrachlorosemiquinone radical and DFO which yields a DFO nitroxide free radical. DFO was also found to enhance dechlorination of tetrachloro-1,4-benzoquinone. These results suggest two additional mechanisms through which DFO might have effects on biological oxidation reactions.

The “Push-Pull Mechanism”

Molecular oxygen (O2) probably appeared on the Earth’s surface about 2 × 109 years ago as a result of photosynthetic microorganisms acquiring the ability to split water. Oxygen is now the most abundant element in the biosphere. Its concentration in dry air has risen to 21%. Iron is the second most abundant metal in the Earth’s crust whereas copper is more scarce.