Sensitivity of tyrosyl radical g-values to changes in protein structure: a high-field EPR study of mutants of ribonucleotide reductase.

The local electrostatic environment plays a critical role in determining the physicochemical properties of reactive radicals in proteins. High-field electron paramagnetic resonance (HF-EPR) spectroscopy has been used to determine the sensitivity of the tyrosyl radical g-values to local electrostatic environment. Site-specific mutants of ribonucleotide reductase from Escherichia coli were used to study the effect of introducing a charge group on the HF-EPR spectrum of the stable tyrosyl (Y122) radical. The changes affected by the mutations were small, but measurable. Mutation of isoleucine-74 to an arginine (I74R) or lysine (I74K) induced disorder in the hyperfine interactions. Similar effects were observed for the mutation of valine-136 to an arginine (V136R) or asparagine (V136N). For five or six mutants studied, the g(x)() component of the g-tensor was distributed. For the isoleucine-74 to lysine (I74K) and leucine-77 to phenylalanine (L77F) mutants, a shift of 1 x 10(-)(4) in g(x)() value was also detected. For the I74K mutant, it is shown that the shift is consistent with the introduction of a charged residue, but cannot be distinguished from changes in the electrostatic effect of the nearby diiron center. For the L77F mutant, the shift is induced by the diiron center. Using existing tyrosyl radical g-tensor measurements, we have developed a simple effective charge model that allows us to rationalize the effect of the local electrostatic environments in a number of proteins.

Resveratrol, a remarkable inhibitor of ribonucleotide reductase.

Resveratrol, a natural phytoalexin found in grapes, is well known for its presumed role in the prevention of heart disease, associated with red wine consumption. We show here that it is a remarkable inhibitor of ribonucleotide reductase and DNA synthesis in mammalian cells, which might have further applications as an antiproliferative or a cancer chemopreventive agent in humans.

Reactivity studies of the tyrosyl radical in ribonucleotide reductase from Mycobacterium tuberculosis and Arabidopsis thaliana--comparison with Escherichia coli and mouse.

Ribonucleotide reductase (RNR) is a key enzyme for DNA synthesis since it provides cells with deoxyribonucleotides, the DNA precursors. Class I alpha2beta2 RNRs contain a dinuclear iron center and an essential tyrosyl radical in the beta2 component (protein R2). This is also true for the purified protein R2 of Mycobacterium tuberculosis RNR, as shown by iron analysis, light absorption and EPR spectroscopy. EPR spectroscopy at 286 GHz revealed a high g(x) value, suggesting that the radical is not hydrogen bonded, as in other prokaryotic R2s and in contrast with eukaryotic R2s (from Arabidopsis thaliana and mouse). Furthermore, it proved to be very resistant to scavenging by a variety of phenols and thiols and by hydroxyurea, similar to the Escherichia coli radical. By comparison, the plant and mouse radicals are very sensitive to drugs such as resveratrol and 2-thiophenthiol. The radical from M. tuberculosis RNR does not seem to be an appropriate target for new antituberculous agents.

Reactivity of the tyrosyl radical of Escherichia coli ribonucleotide reductase -- control by the protein.

Ribonucleotide reductase is a key enzyme for DNA synthesis. Its small component, named protein R2, contains a tyrosyl radical essential for activity. Consequently, radical scavengers are potential antiproliferative agents. In this study, we show that the reactivity of the tyrosyl radical towards phenols, hydrazines, hydroxyurea, dithionite and ascorbate can be finely tuned by relatively small modifications of its hydrophobic close environment. For example, in this hydrophobic pocket, Leu77-->Phe mutation resulted in a protein with a much higher susceptibility to radical scavenging by hydrophobic agents. This might suggest that the protein is flexible enough to allow small molecules to penetrate in the radical site. When mutations keeping the hydrophobic character are brought further from the radical (for example Ile74-->Phe) the reactivity of the radical is instead very little affected. When a positive charge was introduced (for example Ile74-->Arg or Lys) the protein was more sensitive to negatively charged electron donors such as dithionite. These results allow us to understand how tyrosyl radical sites have been optimized to provide a good stability for the free radical.