Allison D. Ortigosa scite author profile

The class I ribonucleotide reductases (RNRs) are composed of two homodimeric subunits: R1 and R2. R2 houses a diferric-tyrosyl radical (Y•) cofactor. Saccharomyces cerevisiae has two R2s: Y2 (β 2 ) and Y4 (β′ 2 ). Y4 is an unusual R2 because three residues required for iron binding have been mutated. While the heterodimer (ββ′) is thought to be the active form, several rnr4Δ strains are viable. To resolve this paradox, N-terminally epitope-tagged β and β′ were expressed in E. coli or integrated into the yeast genome. In vitro exchange studies reveal that when apo-(His 6 )-β 2 ( His β 2 ) is mixed with β′ 2 , apo-His ββ′ forms quantitatively within 2 min. In contrast, holo-ββ′ fails to exchange with apo-His β 2 to form holo-His ββ and β′ 2 . Isolation of genomically encoded tagged β or β′ from yeast extracts gave a 1:1 complex of β and β′, suggesting that ββ′ is the active form. The catalytic activity, protein concentrations, and Y• content of the rnr4Δ and wild type (wt) strains were compared to clarify the role of β′ in vivo. The Y• content of rnr4Δ is 15-fold less than that of wt, consistent with the observed low activity of rnr4Δ extracts (<0.01 nmol min −1 mg −1 ) versus wt (0.06 ± 0.01 nmol min −1 mg −1 ). FLAG β 2 isolated from the rnr4Δ strain has a specific activity of 2 nmol min −1 mg −1 , similar to that of reconstituted apo-His β 2 (10 nmol min −1 mg −1 ), but significantly less than holo-His ββ′ (~2000 nmol min −1 mg −1 ). These studies together demonstrate that β′ plays a crucial role in cluster assembly in vitro and in vivo and that the active form of the yeast R2 is ββ′.Ribonucleotide reductases (RNRs) 1 catalyze the conversion of ribonucleotides to deoxyribonucleotides, providing the monomeric precursors for DNA replication and repair (1). The class I RNRs are composed of a large subunit, R1, and a small subunit, R2. R1 contains the site of nucleotide reduction and the allosteric effector binding sites that control the rate and the specificity of nucleotide reduction. R2 houses the diferric-tyrosyl radical † D.L.P. and A.D.O. were supported in part by the NIH training grant 5T32 CA 09112-28. J.S. acknowledges support of the NIH (GM29595). M.H. acknowledges support of the NIH (CA095207) and the ACS (0305001GMC).

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Determination of the in Vivo Stoichiometry of Tyrosyl Radical per ββ‘ in Saccharomyces cerevisiae Ribonucleotide Reductase

Ortigosa

Hristova

Perlstein

et al. 2006

Biochemistry

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The class I ribonucleotide reductases catalyze the conversion of nucleotides to deoxynucleotides and are composed of two subunits: R1 and R2. R1 contains the site for nucleotide reduction and the sites that control substrate specificity and the rate of reduction. R2 houses the essential diferric-tyrosyl radical (Y • ) cofactor. In Saccharomyces cerevisiae, two R1s, α n and , have been identified, while R2 is a heterodimer (ββ′). β′ cannot bind iron and generate the Y • ; consequently, the maximum amount of Y • per ββ′ is 1. To determine the cofactor stoichiometry in vivo, a FLAGtagged β ( FLAG β) was constructed and integrated into the genome of Y300 (MHY343). This strain facilitated the rapid isolation of endogenous levels of FLAG ββ′ by immunoaffinity chromatography, which was found to have 0.45 ± 0.08 Y • / FLAG ββ′ and a specific activity of 2.3 ± 0.5 μmol min −1 mg −1 . FLAG ββ′ isolated from MMS-treated MHY343 cells or cells containing a deletion of the transcriptional repressor gene CRT1 also gave a Y • / FLAG ββ′ ratio of 0.5. To determine the Y • /ββ′ ratio without R2 isolation, whole cell EPR and quantitative Western blots of β were performed using different strains and growth conditions. The wild-type (wt) strains gave a Y • /ββ′ ratio of 0.83-0.89. The same strains either treated with MMS or containing a crt1Δ gave ratios between 0.49 and 0.72. Nucleotide reduction assays and quantitative Western blots from the same strains provided an independent measure and confirmation of the Y • /ββ′ ratios. Thus, under normal growth conditions, the cell assembles stoichiometric amounts of Y • and modulation of Y • concentration is not involved in the regulation of RNR activity.

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Disentangling the Web of Allosteric Communication in a Homotetramer: Heterotropic Inhibition of Phosphofructokinase from Bacillus stearothermophilus

2003

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A strategy for isolating each of the four potentially unique heterotropic pairwise allosteric interactions that exist in the homotetramer phosphofructokinase from Bacillus stearothermophilus is described. The strategy involves the construction of hybrid tetramers containing one wild-type subunit and three mutant subunits that have been modified to block binding of both the substrate, fructose 6-phosphate (Fru-6-P), and the allosteric inhibitor, phospho(enol)pyruvate (PEP). Each type of binding site occurs at a subunit interface, and mutations on either side of the interface have been identified that will greatly diminish binding at the respective site. Consequently, four different types of mutant subunits have been created, each containing a different active site and allosteric site modification. The corresponding 1:3 hybrids isolate a different pair of unmodified substrate and allosteric sites with a unique structural disposition located 22, 30, 32, and 45 A apart, respectively. The allosteric inhibition exhibited by the unmodified sites in each of these four hybrids has been quantitatively evaluated in terms of a coupling free energy. Each of the coupling free energies is unique in magnitude, and their relative magnitudes vary with pH. Importantly, the sum of these coupling free energies at each pH is equal to the total heterotropic coupling free energy associated with the tetrameric enzyme. The latter quantity was assessed from the overall inhibition of a control hybrid that removed the homotropic interactions in PEP binding. The results do not agree with either the concerted or sequential models that are often invoked to explain allosteric behavior in oligomeric enzymes.

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