Abstract
Ribonucleotide reductase consists of two nonidentical subunits, proteins R1 and R2, the latter of which contains an iron-tyrosyl free radical center essential for activity. We have studied the in vivo effects on the R2 protein of the potent iron chelators parabactin and desferrioxamine using R2-overproducing mouse cells with a tyrosyl free radical signal easily quantifiable by EPR spectroscopy. Both chelators inhibited cell growth, and the inhibition was reversible by iron. Furthermore, both chelators, which penetrate cells and chelate the intracellular iron pool, caused a disappearance of the R2 tyrosyl free radical. In parallel, there was an accumulation of apo-R2 protein in the inhibited cells. In vitro studies using pure, 59Fe-labeled recombinant mouse R2 protein unexpectedly showed that its iron center is labile at physiological temperatures and that iron is spontaneously lost from the protein even in the absence of chelators in a temperature-dependent process. Our conclusion is that parabactin or desferrioxamine inhibits ribonucleotide reduction and cell growth not by directly attacking the iron-radical center of the R2 protein, but instead by chelating the intracellular iron pool. This prevents the regeneration of the iron-radical center both in newly synthesized apo-R2 protein and in apo-R2 protein continuously formed from active R2 protein by the loss of iron.
Highlights
(R2) subunit with a tyrosyl free radical signal quantifiabblye contains a binuclear ferric iron center anad stable tyrosyl free
Intracellular iron pool, caused a disappearanceR2of thTehe evidence for loss of ribonucleotide reductase activity as a tyrosyl free radicalI.n parallel, there was an accumula-cause of impaired DNA synthesis in iron-depleted or chelatortion of apo-R2 protein in the inhibited cells
In vitro treated mammalian cells is largely circumstantial.Few invesstudies using pure, 6eFe-labeled recombinant moRu2se protein unexpectedly showed thatits iron center is labile at physiological temperatures and thatisirsopnontaneously lost from the protein even in the absence of chelators in a temperature-dependent procOesusr. conclusion is that parabactin or desferrioxamine inhibits tigators have measured enzyme activity, but instead have relied on observations of deoxyribonucleotide pool changes or cell cycle blocks similar to those caused by the classic ribonucleotide reductase inhibitor hydroxyurea (6).a study of ribonucleotide reductaseactivityinmurineleukemia cells ribonucleotide reduction ancdell growth not by directlytreated with the potent iron chelator parabactinshowed comattacking the iron-radical centeorf the R2 protein, but plete loss of enzyme activity within 4 h (7)
Summary
Dept. of Medical Oncology, University of Sydney Westmead Center, Westmead,New South Wales 2145,Australia. Aliquots of incubation mixtures containing labeled R2 parabactinand desferrioxamine inhibimt ammalian ribonucleotide reductase by chelating all soluble iron and thereby preventing the regeneratiofnthe iron center nienwly synthesized apo-R2 protein as well as in apo-R2 protein conprotein ( < l opg) were diluted 1inml of 50 m~ Tris-Cl, pH 7.4,O.lM KCl, and the entire sample was immediately passed through a prewetted 13-mm GSWP 0.22-pm filter (Millipore) usinga Swinnex filter holder. The filter was dried, and the radioactivity was measureadBienckman Instruments scintillation counter after the additioonf Insta-Gel
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