Project description:A class I ribonucleotide reductase (RNR) uses either a tyrosyl radical (Y(•)) or a Mn(IV)/Fe(III) cluster in its ? subunit to oxidize a cysteine residue ?35 Å away in its ? subunit, generating a thiyl radical that abstracts hydrogen (H(•)) from the substrate. With either oxidant, the inter-subunit "hole-transfer" or "radical-translocation" (RT) process is thought to occur by a "hopping" mechanism involving multiple tyrosyl (and perhaps one tryptophanyl) radical intermediates along a specific pathway. The hopping intermediates have never been directly detected in a Mn/Fe-dependent (class Ic) RNR nor in any wild-type (wt) RNR. The Mn(IV)/Fe(III) cofactor of Chlamydia trachomatis RNR assembles via a Mn(IV)/Fe(IV) intermediate. Here we show that this cofactor-assembly intermediate can propagate a hole into the RT pathway when ? is present, accumulating radicals with EPR spectra characteristic of Y(•)'s. The dependence of Y(•) accumulation on the presence of substrate suggests that RT within this "super-oxidized" enzyme form is gated by the protein, and the failure of a ? variant having the subunit-interfacial pathway Y substituted by phenylalanine to support radical accumulation implies that the Y(•)(s) in the wt enzyme reside(s) within the RT pathway. Remarkably, two variant ? proteins having pathway substitutions rendering them inactive in their Mn(IV)/Fe(III) states can generate the pathway Y(•)'s in their Mn(IV)/Fe(IV) states and also effect nucleotide reduction. Thus, the use of the more oxidized cofactor permits the accumulation of hopping intermediates and the "hurdling" of engineered defects in the RT pathway.

Project description:The class Ic ribonucleotide reductase (RNR) from Chlamydia trachomatis (Ct) employs a Mn(IV)/Fe(III) cofactor in each monomer of its β2 subunit to initiate nucleotide reduction. The cofactor forms by reaction of Mn(II)/Fe(II)-β2 with O2. Previously, in vitro cofactor assembly from apo β2 and divalent metal ions produced a mixture of two forms, with Mn at site 1 (Mn(IV)/Fe(III)) or site 2 (Fe(III)/Mn(IV)), of which the more active Mn(IV)/Fe(III) product predominates. Here we have addressed the basis for metal site selectivity by determining X-ray crystal structures of apo, Mn(II), and Mn(II)/Fe(II) complexes of Ct β2. A structure obtained anaerobically with equimolar Mn(II), Fe(II), and apoprotein reveals exclusive incorporation of Mn(II) at site 1 and Fe(II) at site 2, in contrast to the more modest site selectivity achieved previously. Site specificity is controlled thermodynamically by the apoprotein structure, as only minor adjustments of ligands occur upon metal binding. Additional structures imply that, by itself, Mn(II) binds in either site. Together, the structures are consistent with a model for in vitro cofactor assembly in which Fe(II) specificity for site 2 drives assembly of the appropriately configured heterobimetallic center, provided that Fe(II) is substoichiometric. This model suggests that use of a Mn(IV)/Fe(III) cofactor in vivo could be an adaptation to Fe(II) limitation. A 1.8 Å resolution model of the Mn(II)/Fe(II)-β2 complex reveals additional structural determinants for activation of the cofactor, including a proposed site for side-on (η(2)) addition of O2 to Fe(II) and a short (3.2 Å) Mn(II)-Fe(II) interionic distance, promoting formation of the Mn(IV)/Fe(IV) activation intermediate.

Project description:The beta(2) subunit of a class Ia or Ib ribonucleotide reductase (RNR) is activated when its carboxylate-bridged Fe(2)(II/II) cluster reacts with O(2) to oxidize a nearby tyrosine (Y) residue to a stable radical (Y(*)). During turnover, the Y(*) in beta(2) is thought to reversibly oxidize a cysteine (C) in the alpha(2) subunit to a thiyl radical (C(*)) by a long-distance ( approximately 35 A) proton-coupled electron-transfer (PCET) step. The C(*) in alpha(2) then initiates reduction of the 2' position of the ribonucleoside 5'-diphosphate substrate by abstracting the hydrogen atom from C3'. The class I RNR from Chlamydia trachomatis (Ct) is the prototype of a newly recognized subclass (Ic), which is characterized by the presence of a phenylalanine (F) residue at the site of beta(2) where the essential radical-harboring Y is normally found. We recently demonstrated that Ct RNR employs a heterobinuclear Mn(IV)/Fe(III) cluster for radical initiation. In essence, the Mn(IV) ion of the cluster functionally replaces the Y(*) of the conventional class I RNR. The Ct beta(2) protein also autoactivates by reaction of its reduced (Mn(II)/Fe(II)) metal cluster with O(2). In this reaction, an unprecedented Mn(IV)/Fe(IV) intermediate accumulates almost stoichiometrically and decays by one-electron reduction of the Fe(IV) site. This reduction is mediated by the near-surface residue, Y222, a residue with no functional counterpart in the well-studied conventional class I RNRs. In this review, we recount the discovery of the novel Mn/Fe redox cofactor in Ct RNR and summarize our current understanding of how it assembles and initiates nucleotide reduction.

Project description:Incorporation of 2,3,6-trifluorotyrosine (F(3)Y) and a rhenium bipyridine ([Re]) photooxidant into a peptide corresponding to the C-terminus of the ? protein (?C19) of Escherichia coli ribonucleotide reductase (RNR) allows for the temporal monitoring of radical transport into the ?2 subunit of RNR. Injection of the photogenerated F(3)Y radical from the [Re]-F(3)Y-?C19 peptide into the surface accessible Y731 of the ?2 subunit is only possible when the second Y730 is present. With the Y-Y established, radical transport occurs with a rate constant of 3 × 10(5) s(-1). Point mutations that disrupt the Y-Y dyad shut down radical transport. The ability to obviate radical transport by disrupting the hydrogen bonding network of the amino acids composing the colinear proton-coupled electron transfer pathway in ?2 suggests a finely tuned evolutionary adaptation of RNR to control the transport of radicals in this enzyme.

Project description:Ribonucleotide reductases (RNRs) catalyze the conversionof nucleotides to 2'-deoxynucleotides and are classified on the basis of the metallo-cofactor used to conduct this chemistry. The class Ia RNRs initiate nucleotide reduction when a stable diferric-tyrosyl radical (Y•, t1/2 of 4 days at 4 °C) cofactor in the ?2 subunit transiently oxidizes a cysteine to a thiyl radical (S•) in the active site of the ?2 subunit. In the active ?2?2 complex of the class Ia RNR from E. coli , researchers have proposed that radical hopping occurs reversibly over 35 Å along a specific pathway comprised of redox-active aromatic amino acids: Y122• ? [W48?] ? Y356 in ?2 to Y731 ? Y730 ? C439 in ?2. Each step necessitates a proton-coupled electron transfer (PCET). Protein conformational changes constitute the rate-limiting step in the overall catalytic scheme and kinetically mask the detailed chemistry of the PCET steps. Technology has evolved to allow the site-selective replacement of the four pathway tyrosines with unnatural tyrosine analogues. Rapid kinetic techniques combined with multifrequency electron paramagnetic resonance, pulsed electron-electron double resonance, and electron nuclear double resonance spectroscopies have facilitated the analysis of stable and transient radical intermediates in these mutants. These studies are beginning to reveal the mechanistic underpinnings of the radical transfer (RT) process. This Account summarizes recent mechanistic studies on mutant E. coli RNRs containing the following tyrosine analogues: 3,4-dihydroxyphenylalanine (DOPA) or 3-aminotyrosine (NH2Y), both thermodynamic radical traps; 3-nitrotyrosine (NO2Y), a thermodynamic barrier and probe of local environmental perturbations to the phenolic pKa; and fluorotyrosines (FnYs, n = 2 or 3), dual reporters on local pKas and reduction potentials. These studies have established the existence of a specific pathway spanning 35 Å within a globular ?2?2 complex that involves one stable (position 122) and three transient (positions 356, 730, and 731) Y•s. Our results also support that RT occurs by an orthogonal PCET mechanism within ?2, with Y122• reduction accompanied by proton transfer from an Fe1-bound water in the diferric cluster and Y356 oxidation coupled to an off-pathway proton transfer likely involving E350. In ?2, RT likely occurs by a co-linear PCET mechanism, based on studies of light-initiated radical propagation from photopeptides that mimic the ?2 subunit to the intact ?2 subunit and on [(2)H]-ENDOR spectroscopic analysis of the hydrogen-bonding environment surrounding a stabilized NH2Y• formed at position 730. Additionally, studies on the thermodynamics of the RT pathway reveal that the relative reduction potentials decrease according to Y122 < Y356 < Y731 ? Y730 ? C439, and that the pathway in the forward direction is thermodynamically unfavorable. C439 oxidation is likely driven by rapid, irreversible loss of water during the nucleotide reduction process. Kinetic studies of radical intermediates reveal that RT is gated by conformational changes that occur on the order of >100 s(-1) in addition to the changes that are rate-limiting in the wild-type enzyme (?10 s(-1)). The rate constant of one of the PCET steps is ?10(5) s(-1), as measured in photoinitiated experiments.

Project description:Bacillus subtilis class Ib ribonucleotide reductase (RNR) catalyzes the conversion of nucleotides to deoxynucleotides, providing the building blocks for DNA replication and repair. It is composed of two proteins: ? (NrdE) and ? (NrdF). ? contains the metallo-cofactor, essential for the initiation of the reduction process. The RNR genes are organized within the nrdI-nrdE-nrdF-ymaB operon. Each protein has been cloned, expressed, and purified from Escherichia coli. As isolated, recombinant NrdF (rNrdF) contained a diferric-tyrosyl radical [Fe(III)(2)-Y(•)] cofactor. Alternatively, this cluster could be self-assembled from apo-rNrdF, Fe(II), and O(2). Apo-rNrdF loaded using 4 Mn(II)/?(2), O(2), and reduced NrdI (a flavodoxin) can form a dimanganese(III)-Y(•) [Mn(III)(2)-Y(•)] cofactor. In the presence of rNrdE, ATP, and CDP, Mn(III)(2)-Y(•) and Fe(III)(2)-Y(•) rNrdF generate dCDP at rates of 132 and 10 nmol min(-1) mg(-1), respectively (both normalized for 1 Y(•)/?(2)). To determine the endogenous cofactor of NrdF in B. subtilis, the entire operon was placed behind a Pspank(hy) promoter and integrated into the B. subtilis genome at the amyE site. All four genes were induced in cells grown in Luria-Bertani medium, with levels of NrdE and NrdF elevated 35-fold relative to that of the wild-type strain. NrdE and NrdF were copurified in a 1:1 ratio from this engineered B. subtilis. The visible, EPR, and atomic absorption spectra of the purified NrdENrdF complex (eNrdF) exhibited characteristics of a Mn(III)(2)-Y(•) center with 2 Mn/?(2) and 0.5 Y(•)/?(2) and an activity of 318-363 nmol min(-1) mg(-1) (normalized for 1 Y(•)/?(2)). These data strongly suggest that the B. subtilis class Ib RNR is a Mn(III)(2)-Y(•) enzyme.

Project description:The class III ribonucleotide reductases (RNRs) are glycyl radical (G•) enzymes that provide the balanced pool of deoxynucleotides required for DNA synthesis and repair in many facultative and obligate anaerobic bacteria and archaea. Unlike the class I and II RNRs, where reducing equivalents for the reaction are delivered by a redoxin (thioredoxin, glutaredoxin, or NrdH) via a pair of conserved active site cysteines, the class III RNRs examined to date use formate as the reductant. Here, we report that reaction of the Escherichia coli class III RNR with CTP (substrate) and ATP (allosteric effector) in the absence of formate leads to loss of the G• concomitant with stoichiometric formation of a new radical species and a "trapped" cytidine derivative that can break down to cytosine. Addition of formate to the new species results in recovery of 80% of the G• and reduction of the cytidine derivative, proposed to be 3'-keto-deoxycytidine, to dCTP and a small amount of cytosine. The structure of the new radical has been identified by 9.5 and 140 GHz EPR spectroscopy on isotopically labeled varieties of the protein to be a thiosulfuranyl radical [RSSR2]•, composed of a cysteine thiyl radical stabilized by an interaction with a methionine residue. The presence of a stable radical species on the reaction pathway rationalizes the previously reported [(3)H]-(k(cat)/K(M)) isotope effect of 2.3 with [(3)H]-formate, requiring formate to exchange between the active site and solution during nucleotide reduction. Analogies with the disulfide anion radical proposed to provide the reducing equivalent to the 3'-keto-deoxycytidine intermediate by the class I and II RNRs provide further evidence for the involvement of thiyl radicals in the reductive half-reaction catalyzed by all RNRs.

Project description:Catalysis by a class I ribonucleotide reductase (RNR) begins when a cysteine (C) residue in the alpha(2) subunit is oxidized to a thiyl radical (C(*)) by a cofactor approximately 35 A away in the beta(2) subunit. In a class Ia or Ib RNR, a stable tyrosyl radical (Y(*)) is the C oxidant, whereas a Mn(IV)/Fe(III) cluster serves this function in the class Ic enzyme from Chlamydia trachomatis (Ct). It is thought that, in either case, a chain of Y residues spanning the two subunits mediates C oxidation by forming transient "pathway" Y(*)s in a multistep electron transfer (ET) process that is "gated" by the protein so that it occurs only in the ready holoenzyme complex. The drug hydroxyurea (HU) inactivates both Ia/b and Ic beta(2) subunits by reducing their C oxidants. Reduction of the stable cofactor Y(*) (Y122(*)) in Escherichia coli class Ia beta(2) is faster in the presence of alpha(2) and a substrate (CDP), leading to speculation that HU might intercept a transient ET pathway Y(*) under these turnover conditions. Here we show that this mechanism is one of two that are operant in HU inactivation of the Ct enzyme. HU reacts with the Mn(IV)/Fe(III) cofactor to give two distinct products: the previously described homogeneous Mn(III)/Fe(III)-beta(2) complex, which forms only under turnover conditions (in the presence of alpha(2) and the substrate), and a distinct, diamagnetic Mn/Fe cluster, which forms approximately 900-fold less rapidly as a second phase in the reaction under turnover conditions and as the sole outcome in the reaction of Mn(IV)/Fe(III)-beta(2) only. Formation of Mn(III)/Fe(III)-beta(2) also requires (i) either Y338, the subunit-interfacial ET pathway residue of beta(2), or Y222, the surface residue that relays the "extra electron" to the Mn(IV)/Fe(IV) intermediate during activation of beta(2) but is not part of the catalytic ET pathway, and (ii) W51, the cofactor-proximal residue required for efficient ET between either Y222 or Y338 and the cofactor. The combined requirements for the catalytic subunit, the substrate, and, most importantly, a functional surface-to-cofactor electron relay system imply that HU effects the Mn(IV)/Fe(III) --> Mn(III)/Fe(III) reduction by intercepting a Y(*) that forms when the ready holoenzyme complex is assembled, the ET gate is opened, and the Mn(IV) oxidizes either Y222 or Y338.

Project description:Ribonucleotide reductases (RNR) catalyze the reduction of nucleotides to deoxynucleotides through a mechanism involving an essential cysteine based thiyl radical. In the E. coli class 1a RNR the thiyl radical (C439•) is a transient species generated by radical transfer (RT) from a stable diferric-tyrosyl radical cofactor located >35 Å away across the ?2:?2 subunit interface. RT is facilitated by sequential proton-coupled electron transfer (PCET) steps along a pathway of redox active amino acids (Y122? ? [W48??] ? Y356? ? Y731? ? Y730? ? C439?). The mutant R411A(?) disrupts the H-bonding environment and conformation of Y731, ostensibly breaking the RT pathway in ?2. However, the R411A protein retains significant enzymatic activity, suggesting Y731 is conformationally dynamic on the time scale of turnover. Installation of the radical trap 3-amino tyrosine (NH2Y) by amber codon suppression at positions Y731 or Y730 and investigation of the NH2Y• trapped state in the active ?2:?2 complex by HYSCORE spectroscopy validate that the perturbed conformation of Y731 in R411A-?2 is dynamic, reforming the H-bond between Y731 and Y730 to allow RT to propagate to Y730. Kinetic studies facilitated by photochemical radical generation reveal that Y731 changes conformation on the ns-?s time scale, significantly faster than the enzymatic kcat. Furthermore, the kinetics of RT across the subunit interface were directly assessed for the first time, demonstrating conformationally dependent RT rates that increase from 0.6 to 1.6 × 104 s-1 when comparing wild type to R411A-?2, respectively. These results illustrate the role of conformational flexibility in modulating RT kinetics by targeting the PCET pathway of radical transport.

Project description:Escherichia coli class Ib ribonucleotide reductase (RNR) converts nucleoside 5'-diphosphates to deoxynucleoside 5'-diphosphates in iron-limited and oxidative stress conditions. We have recently demonstrated in vitro that this RNR is active with both diferric-tyrosyl radical (Fe(III)(2)-Y(•)) and dimanganese(III)-Y(•) (Mn(III)(2)-Y(•)) cofactors in the ?2 subunit, NrdF [Cotruvo, J. A., Jr., and Stubbe, J. (2010) Biochemistry 49, 1297-1309]. Here we demonstrate, by purification of this protein from its endogenous levels in an E. coli strain deficient in its five known iron uptake pathways and grown under iron-limited conditions, that the Mn(III)(2)-Y(•) cofactor is assembled in vivo. This is the first definitive determination of the active cofactor of a class Ib RNR purified from its native organism without overexpression. From 88 g of cell paste, 150 ?g of NrdF was isolated with ?95% purity, with 0.2 Y(•)/?2, 0.9 Mn/?2, and a specific activity of 720 nmol min(-1) mg(-1). Under these conditions, the class Ib RNR is the primary active RNR in the cell. Our results strongly suggest that E. coli NrdF is an obligate manganese protein in vivo and that the Mn(III)(2)-Y(•) cofactor assembly pathway we have identified in vitro involving the flavodoxin-like protein NrdI, present inside the cell at catalytic levels, is operative in vivo.