ABSTRACT: 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.