Ribonucleotide reductase mechanism

Fig. 9 Ribonucleotide reductase mechanism for conversion of ribonucleotides to 2 -deoxyribonucleotides (reproduced from reference 379 with the permission of the American Chemical Society).

Figure 25.11 Ribonucleotide reductase mechanism. (1) An electron is transferred from a cysteine residue on R1 to a tyrosine radical on R2. generating a highly reactive cysteine thiyl radical. (2) This radical abstracts a hydrogen atom from C-3 of the ribose unil. (3) The radica at C-3 releases OH from the C-2 carbon atom. Combined with a proton from a second cysteine residue, the OH is eliminated as water. (4) A hydride ion is transferred from a third cysteine residue with the concomitant formation of a disulfide bond. (5) The C-3 radical recaptures the originally abstracted hydrogen atom. (6) An electron is transferred from R2 to reduce the thiyl radical, which also accepts a proton. The deoxyribonucleotide is free to leave Rl. The disulfide formed in the active site must be reduced to begin another cycle.

The first two of these are mediated by 5 -deoxyadenosylcobalamin, whereas methyl transfers are effected by methylcobalamin. The mechanism of ribonucleotide reductase is discussed in Chapter 27. Methyl group transfers that employ tetrahydrofolate as a coenzyme are described later in this chapter. 

Sjbberg B-M (1997) Ribonucleotide Reductases - A Group of Enzymes with Different Metallosites and a Similar Reaction Mechanism. 88 139-174 Slebodnick C, Hamstra BJ, Pecoraro VL (1997) Modeling the Biological Chemistry of Vanadium Structural and Reactivity Studies Elucidating Biological Function. 89 51-108 Smit HHA, see Thiel RC (1993) 81 1-40... 

The iron(III) complexes of 21 and 22 were shown to be 3 to 6 times more active as inhibitors of partially purified ribonucleotide reductase than un-complexed thiosemicarbazones [128]. The mechanism of antitumor action by these complexes still remains largely speculative, although some excellent preliminary studies have appeared. It has been postulated [148] that tridentate... 

Metalloenzymes with non-heme di-iron centers in which the two irons are bridged by an oxide (or a hydroxide) and carboxylate ligands (glutamate or aspartate) constitute an important class of enzymes. Two of these enzymes, methane monooxygenase (MMO) and ribonucleotide reductase (RNR) have very similar di-iron active sites, located in the subunits MMOH and R2 respectively. Despite their structural similarity, these metal centers catalyze very different chemical reactions. We have studied the enzymatic mechanisms of these enzymes to understand what determines their catalytic activity [24, 25, 39-41]. 

Ribonucleotide reductase is responsible for the conversion of the four biological ribonucleotides (RNA) into their corresponding deoxy forms (DNA). Although RNR is not an oxygenase during its primary catalyzed reaction (the conversion of ribonucleotides), it activates oxygen to generate a stable tyrosyl radical that is essential to the overall mechanism [46 49]. The common link between the chemistry of MMO and RNR is the activation of O2 by the di-iron active site. 

The application of magnetic resonance techniques to biological systems is a relatively new approach for the study of macromolecules. In this review we have presented the different approaches which have been made to study Bi2-enzymes. Clearly some progress has been made particularly from the application of ESR to a study of the enzymes ethanolamine ammonia-lyase and ribonucleotide reductase. Although 13C NMR is well in its developmental stages it is obvious that this technique will prove to be very useful for the examination of coenzyme-enzyme interactions. Studies of how corrinoids bind in enzymes and how sulfhydryl containing proteins are involved in enzyme catalysis comprise two major problems which must be overcome before realistic mechanisms can be presented for this group of enzymes. 

Figure 13.4 A proposed mechanism for all three classes of ribonucleotide reductases. Classes I and II RNRs require an active site Glu residue and a pair of redox-active Cys. Class HI RNRs lack the Glu and one of the Cys, and use formate as the reductant. (From Stubbe etal., 2001. Copyright 2001, with permission from Elsevier.)...

Kolberg, M., Strand, K.R., Graff, P. and Andersson, K.K. (2004) Structure, function and mechanism of ribonucleotide reductases, Biochim. Biophys. Acta, 1699, 1-34. 

Liu, C., Powell, K. A., Mundt, K., Wu, L., Care, A. M., Caspaei, T. Cop9/signalosome subunits and Pcu4 regulate ribonucleotide reductase by both checkpoint-dependent and -independent mechanisms. Genes Dev. 2003, 17, 1130-1140. 

In addition to aconitases, nitric oxide is an inhibitor of many other enzymes such as ribonucleotide reductase [71], glutathione peroxidase [72,73], cytochrome c oxidase [74], NADPH oxidase [75], xanthine oxidase [76], and lipoxygenase [77] but not prostaglandin synthase [78]. (Mechanism of lipoxygenase inhibition by nitric oxide is considered in Chapter... 

Ribonucleotide reductase is notable in that its reaction mechanism provides the best-characterized example of the involvement of free radicals in biochemical transformations, once thought to be rare in biological systems. The enzyme in E. coli and most eukaryotes is a dimer, with subunits designated R1 and R2 (Fig. 22-40). The R1 subunit contains two lands of regulatory sites, as described below. The two active sites of the enzyme are formed at the interface between the R1 and R2 subunits. At each active site, R1 contributes two sulfhydryl groups required for activity and R2 contributes a stable tyrosyl radical. The R2 subunit also has a binuclear iron (Fe3+) cofactor that helps generate and stabilize the tyrosyl radicals (Fig. 22-40). The tyrosyl radical is too far from the active site to interact directly with the site, but it generates another radical at the active site that functions in catalysis. 

A likely mechanism for the ribonucleotide reductase reaction is illustrated in Figure 22-41. The 3 -ribonu-cleotide radical formed in step (T) helps stabilize the cation formed at the 2 carbon after the loss of H20 (steps and (3)). Two one-electron transfers accompanied by oxidation of the dithiol reduce the radical cation (step ). Step (5) is the reverse of step ( ) regenerating the active site radical (ultimately, the tyrosyl radical) and forming the deoxy product. The oxidized dithiol is reduced to complete the cycle (step ). Ini , coli, likely sources of the required reducing equivalents for this reaction are thioredoxin and glutaredoxin, as noted above. 

MECHANISM FIGURE 22-41 Proposed mechanism for ribonucleotide reductase. In the enzyme of . coli and most eukaryotes, the active thiol groups are on the R1 subunit the active-site radical (—X ) is on the R2 subunit and in . coli is probably a thiyl radical of Cys439 (see Fig. 22-40). Steps (T) through are described in the text. 

In green plants a soluble A9 stearoyl-acyl carrier protein desaturase uses 02 and NADH or NADPH to introduce a double bond into fatty acids. The structure of this protein (Fig. 16-20B,C) is related to those of methane oxygenase and ribonucleotide reductase.333347 Tire desaturase mechanism is discussed in Chapter 21. 

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