Ribonucleotide
reductases (RNRs) catalyze the conversion of ribonucleotides
to deoxyribonucleotides in all organisms. In all Class Ia RNRs, initiation
of nucleotide diphosphate (NDP) reduction requires a reversible oxidation
over 35 Å by a tyrosyl radical (Y122•, Escherichia coli) in subunit
β of a cysteine (C439) in the active site of subunit
α. This radical transfer (RT) occurs by a specific pathway involving
redox active tyrosines (Y122 ⇆ Y356 in
β to Y731 ⇆ Y730 ⇆ C439 in α); each oxidation necessitates loss of a proton
coupled to loss of an electron (PCET). To study these steps, 3-aminotyrosine
was site-specifically incorporated in place of Y356-β,
Y731- and Y730-α, and each protein was
incubated with the appropriate second subunit β(α), CDP
and effector ATP to trap an amino tyrosyl radical (NH2Y•)
in the active α2β2 complex. High-frequency (263 GHz) pulse
electron paramagnetic resonance (EPR) of the NH2Y•s
reported the gx values
with unprecedented resolution and revealed strong electrostatic effects
caused by the protein environment. 2H electron–nuclear
double resonance (ENDOR) spectroscopy accompanied by quantum chemical
calculations provided spectroscopic evidence for hydrogen bond interactions
at the radical sites, i.e., two exchangeable H bonds to NH2Y730•, one to NH2Y731•
and none to NH2Y356•. Similar experiments
with double mutants α-NH2Y730/C439A and α-NH2Y731/Y730F allowed
assignment of the H bonding partner(s) to a pathway residue(s) providing
direct evidence for colinear PCET within α. The implications
of these observations for the PCET process within α and at the
interface are discussed.
The reaction catalyzed by E. coli ribonucleotide reductase (RNR) composed of α and β subunits that form an active α2β2 complex is a paradigm for proton-coupled electron transfer (PCET) processes in biological transformations. β2 contains the diferric tyrosyl radical (Y·) cofactor that initiates radical transfer (RT) over 35 Å via a specific pathway of amino acids (Y· ⇆ [W] ⇆ Y in β2 to Y ⇆ Y ⇆ C in α2). Experimental evidence exists for colinear and orthogonal PCET in α2 and β2, respectively. No mechanistic model yet exists for the PCET across the subunit (α/β) interface. Here, we report unique EPR spectroscopic features of Y·-β, the pathway intermediate generated by the reaction of 2,3,5-FY·-β2/CDP/ATP with wt-α2, YF-α2, or YF-α2. High field EPR (94 and 263 GHz) reveals a dramatically perturbed g tensor. [H] and [H]-ENDOR reveal two exchangeable H bonds to Y·: a moderate one almost in-plane with the π-system and a weak one. DFT calculation on small models of Y· indicates that two in-plane, moderate H bonds (r ∼1.8-1.9 Å) are required to reproduce the g value of Y· (wt-α2). The results are consistent with a model, in which a cluster of two, almost symmetrically oriented, water molecules provide the two moderate H bonds to Y· that likely form a hydrogen bond network of water molecules involved in either the reversible PCET across the subunit interface or in H release to the solvent during Y oxidation.
The radical concentrations and g factors of stable organic radicals in different lignin preparations were determined by X-band EPR at 9 GHz. We observed that the g factors of these radicals are largely determined by the extraction process and not by the botanical origin of the lignin. The parameter mostly influencing the g factor is the pH value during lignin extraction. This effect was studied in depth using high-field EPR spectroscopy at 263 GHz. We were able to determine the gxx, gyy, and gzz components of the g tensor of the stable organic radicals in lignin. With the enhanced resolution of high-field EPR, distinct radical species could be found in this complex polymer. The radical species are assigned to substituted o-semiquinone radicals and can exist in different protonation states SH3+, SH2, SH1-, and S2-. The proposed model structures are supported by DFT calculations. The g principal values of the proposed structure were all in reasonable agreement with the experiments.
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