Abstract
Reconstitution of the tyrosyl radical in ribonucleotide reductase protein R2 requires oxidation of a diferrous site by oxygen. The reaction involves one externally supplied electron in addition to the three electrons provided by oxidation of the Tyr-122 side chain and formation of the mu-oxo-bridged diferric site. Reconstitution of R2 protein Y122F, lacking the internal pathway involving Tyr-122, earlier identified two radical intermediates at Trp-107 and Trp-111 in the vicinity of the di-iron site, suggesting a novel internal transfer pathway (Sahlin, M., Lassmann, G., Pötsch, S., Sjöberg, B. -M., and Gräslund, A. (1995) J. Biol. Chem. 270, 12361-12372). Here, we report the construction of the double mutant W107Y/Y122F and its three-dimensional structure and demonstrate that the tyrosine Tyr-107 can harbor a transient, neutral radical (Tyr-107(.)). The Tyr-107(.) signal exhibits the hyperfine structure of a quintet with coupling constants of 1.3 mT for one beta-methylene proton and 0.75 mT for each of the 3 and 5 hydrogens of the phenyl ring. Rapid freeze quench kinetics of EPR-visible intermediates reveal a preferred radical transfer pathway via Trp-111, Glu-204, and Fe-2, followed by a proton coupled electron transfer through the pi-interaction of the aromatic rings of Trp-(Tyr-)107 and Trp-111. The kinetic pattern observed in W107Y/Y122F is considerably changed as compared with Y122F: the Trp-111(.) EPR signal has vanished, and the Tyr-107(.) has the same formation rate as does Trp-111(.) in Y122F. According to the proposed consecutive reaction, Trp-111(.) becomes very short lived and is no longer detectable because of the faster formation of Tyr-107(.). We conclude that the phenyl rings of Trp-111 and Tyr-107 form a better stacking complex so that the proton-coupled electron transfer is facilitated compared with the single mutant. Comparison with the formation kinetics of the stable tyrosyl radical in wild type R2 suggests that these protein-linked radicals are substitutes for the missing Tyr-122. However, in contrast to Tyr-122(.) these radicals lack a direct connection to the radical transfer pathway utilized during catalysis.
Highlights
Reconstitution of the tyrosyl radical in ribonucleotide reductase protein R2 requires oxidation of a diferrous site by oxygen
The kinetic pattern observed in W107Y/Y122F is considerably changed as compared with Y122F: the Trp-1111⁄7 EPR signal has vanished, and the Tyr-1071⁄7 has the same formation rate as does Trp-1111⁄7 in Y122F
The larger R1 protein contains the catalytic site with redox-active cysteines, whereas the function of the smaller R2 is to store a stable tyrosyl radical (Tyr-1221⁄7 in E. coli) that is essential for catalysis [3]
Summary
(Received for publication, January 6, 1997, and in revised form, February 12, 1997). Bettina Katterle‡, Margareta Sahlin‡, Peter P. Reconstitution of the tyrosyl radical in ribonucleotide reductase protein R2 requires oxidation of a diferrous site by oxygen. Reduction of substrate by ribonucleotide reductase is proposed to happen via a radical mechanism involving the formation of a thiyl radical at cysteine 439 (E. coli numbering) at the substrate binding site in R1. This raises the question how a radical is transferred from Tyr-122 in R2 to Cys-439 in R1 and vice versa. The reconstitution reaction provides a possibility to trap and characterize radical intermediates, and one FeIII-FeIV intermediate and several other intermediates have been observed prior to generation of the oxidized di-iron site in wild type and mutant protein (9, 14 –18). From the results we propose a pathway through which an electron/proton pair is delivered by the oxidizable amino acids surrounding the iron site
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