Abstract
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.
Highlights
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
The model suggests that the active site in R1 and the stable tyrosyl radical in R2 are connected via an array of conserved residues, which constitutes the radical transfer pathway
The existence of a dedicated radical transfer route in E. coli RNR has been established by a combination of three-dimensional structure determinations, phylogenetic sequence comparisons, and site-directed mutagenesis experiments
Summary
The model suggests that the active site in R1 and the stable tyrosyl radical in R2 are connected via an array of conserved residues, which constitutes the radical transfer pathway These residues are Tyr122, Asp, His118, Asp237, Trp, and Tyr356 in the R2 protein and Tyr730, Tyr731, and Cys439 in the R1 protein (see Fig. 1). Asp237 plays an essential role; it forms hydrogen bonds with His118, Trp, and Gln and thereby functions as a connecting point for three helices It participates both in the catalytic radical transfer [12] and in the generation of the tyrosyl radical [20, 51]. Our data emphasize the requirement for hydrogen bonds between the conserved residues in the radical transfer route and strongly suggest that the catalytic radical transfer process in RNR is a coupled electron/proton transfer
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