Stephan Pötsch

Evidence by Mutagenesis that Tyr370 of the Mouse Ribonucleotide Reductase R2 Protein Is the Connecting Link in the Intersubunit Radical Transfer Pathway

Ribonucleotide reductase catalyzes all de novo synthesis of deoxyribonucleotides. The mammalian enzyme consists of two non-identical subunits, the R1 and R2 proteins, each inactive alone. The R1 subunit contains the active site, whereas the R2 protein harbors a binuclear iron center and a tyrosyl free radical essential for catalysis. It has been proposed that the radical properties of the R2 subunit are transferred ∼35 Å to the active site of the R1 protein, through a coupled electron/proton transfer along a conserved hydrogen-bonded chain, i.e. a radical transfer pathway (RTP). To gain a better insight into the properties and requirements of the proposed RTP, we have used site-directed mutagenesis to replace the conserved tyrosine 370 in the mouse R2 protein with tryptophan or phenylalanine. This residue is located close to the flexible C terminus, known to be essential for binding to the R1 protein. Our results strongly indicate that Tyr370 links the RTP between the R1 and R2 proteins. Interruption of the hydrogen-bonded chain in Y370F inactivates the enzyme complex. Alteration of the same chain in Y370W slows down the RTP, resulting in a 58 times lower specific activity compared with the native R2 protein and a loss of the free radical during catalysis.

Preserved Catalytic Activity in an Engineered Ribonucleotide Reductase R2 Protein with a Nonphysiological Radical Transfer Pathway THE IMPORTANCE OF HYDROGEN BOND CONNECTIONS BETWEEN THE PARTICIPATING RESIDUES

A hydrogen-bonded catalytic radical transfer pathway in Escherichia coli ribonucleotide reductase (RNR) is evident from the three-dimensional structures of the R1 and R2 proteins, phylogenetic studies, and site-directed mutagenesis experiments. Current knowledge of electron transfer processes is difficult to apply to the very long radical transfer pathway in RNR. To explore the importance of the hydrogen bonds between the participating residues, we converted the protein R2 residue Asp237, one of the conserved residues along the radical transfer route, to an asparagine and a glutamate residue in two separate mutant proteins. In this study, we show that the D237E mutant is catalytically active and has hydrogen bond connections similar to that of the wild type protein. This is the first reported mutant protein that affects the radical transfer pathway while catalytic activity is preserved. The D237N mutant is catalytically inactive, and its tyrosyl radical is unstable, although the mutant can form a diferric-oxo iron center and a R1-R2 complex. The data strongly support our hypothesis that an absolute requirement for radical transfer during catalysis in ribonucleotide reductase is an intact hydrogen-bonded pathway between the radical site in protein R2 and the substrate binding site in R1. Our data thus strongly favor the idea that the electron transfer mechanism in RNR is coupled with proton transfer, i.e. a radical transfer mechanism.

Peroxyl adduct radicals formed in the iron/oxygen reconstitution reaction of mutant ribonucleotide reductase R2 proteins from Escherichia coli

Abstract. Catalytically important free radicals in enzymes are generally formed at highly specific sites, but the specificity is often lost in point mutants where crucial residues have been changed. Among the transient free radicals earlier found in the Y122F mutant of protein R2 in Escherichiacoli ribonucleotide reductase after reconstitution with Fe2+ and O2, two were identified as tryptophan radicals. A third radical has an axially symmetric EPR spectrum, and is shown here using 17O exchange and simulations of EPR spectra to be a peroxyl adduct radical. Reconstitution of other mutants of protein R2 (i.e. Y122F/W48Y and Y122F/W107Y) implicates W48 as the origin of the peroxyl adduct. The results indicate that peroxyl radicals form on primary transient radicals on surface residues such as W48, which is accessible to oxygen. However, the specificity of the reaction is not absolute since the single mutant W48Y also gives rise to a peroxyl adduct radical. We used density functional calculations to investigate residue-specific effects on hyperfine coupling constants using models of tryptophan, tyrosine, glycine and cysteine. The results indicate that any peroxyl adduct radical attached to the first three amino acid α-carbons gives similar 17O hyperfine coupling constants. Structural arguments and experimental results favor W48 as the major site of peroxyl adducts in the mutant Y122F. Available molecular oxygen can be considered as a spin trap for surface-located protein free radicals.