The Active Form of the Saccharomyces cerevisiae Ribonucleotide Reductase Small Subunit Is a Heterodimer in Vitro and in Vivo

Perlstein, Deborah L.; Ge, Jie; Ortigosa, Allison D.; Robblee, John H.; Zhang, Zhen; Huang, Mingxia; Stubbe, JoAnne

doi:10.1021/bi051616+

Cited by 34 publications

(64 citation statements)

References 29 publications

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“…The calculations we have carried out can be extended to our recent studies with an rnr4Δ strain in the BY4741 background in which the specific activity of β was found to be 10 nmol min −1 mg −1 , and the cells were able to still double with a half-life of 180 min (14). Under these growth conditions, the amount of β has been elevated 14-fold.…”

Section: Specific Activity Measurements Suggest That Rnr Need Not Be mentioning

confidence: 75%

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

et al. 2006

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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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Section: Specific Activity Measurements Suggest That Rnr Need Not Be mentioning

confidence: 75%

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

et al. 2006

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“…The Kap proteins are known to interact with their cargo proteins either by direct binding or by indirect association via an adaptor protein (46,47). To determine whether Kap122 interacts with ␤␤Ј and to identify any adaptor protein(s) that may be involved in ␤␤Ј transport, we used an N-terminally tagged Flag ␤ expressed from the chromosomal RNR2 locus to facilitate rapid purification of ␤␤Ј from yeast cell extract (28). SDS͞PAGE analysis of the proteins purified by immunoaffinity chromatography subsequent to extensive washing revealed one major protein band and three or four minor bands ( Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Flag ␤ was purified by using an anti-Flag column as described in ref. 28. Samples of Flag ␤␤Ј (40 g) eluted from the column after extensive washing were analyzed on a 5-15% gradient gel and stained by Coomassie brilliant blue.…”

Section: Methodsmentioning

confidence: 99%

“…Protein extract was prepared as described in ref. 28. The extract was incubated with 750 l of anti-Myc agarose for 1 h at 4°C, and the mixture was poured into a column.…”

Section: Copurification Of Wtm1mentioning

confidence: 99%

“…Recent studies (26)(27)(28) have established the fact that the active form of R2 is the ␤␤Ј heterodimer (formerly designated Rnr2-Rnr4). Only ␤ is capable of forming the (Fe) 2 -Y⅐ cofactor (26,27), whereas ␤Ј facilitates cofactor assembly and stabilizes the resulting holoheterodimer (26)(27)(28)(29)(30).…”

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Nuclear localization of the Saccharomyces cerevisiae ribonucleotide reductase small subunit requires a karyopherin and a WD40 repeat protein

Zhang

Yang

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

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Ribonucleotide reductase (RNR) catalyzes the reduction of ribonucleotides to the corresponding deoxyribonucleotides and is an essential enzyme for DNA replication and repair. Cells have evolved intricate mechanisms to regulate RNR activity to ensure high fidelity of DNA replication during normal cell-cycle progression and of DNA repair upon genotoxic stress. The RNR holoenzyme is composed of a large subunit R1 (␣, oligomeric state unknown) and a small subunit R2 (␤ 2). R1 binds substrates and allosteric effectors; R2 contains a diferric-tyrosyl radical [(Fe) 2-Y⅐] cofactor that is required for catalysis. In Saccharomyces cerevisiae, R1 is predominantly localized in the cytoplasm, whereas R2, which is a heterodimer (␤␤ ), is predominantly in the nucleus. When cells encounter DNA damage or stress during replication, ␤␤ is redistributed from the nucleus to the cytoplasm in a checkpointdependent manner, resulting in the colocalization of R1 and R2. We have identified two proteins that have an important role in ␤␤ nuclear localization: the importin ␤ homolog Kap122 and the WD40 repeat protein Wtm1. Deletion of either WTM1 or KAP122 leads to loss of ␤␤ nuclear localization. Wtm1 and its paralog Wtm2 are both nuclear proteins that are in the same protein complex with ␤␤ . Wtm1 also interacts with Kap122 in vivo and requires Kap122 for its nuclear localization. Our results suggest that Wtm1 acts either as an adaptor to facilitate nuclear import of ␤␤ by Kap122 or as an anchor to retain ␤␤ in the nucleus. DNA-damage checkpoint ͉ subcellular redistributionT he levels and relative ratios of dNTP pools are important for high-fidelity DNA replication and repair (1). Failure to increase dNTP levels at the G 1 -to-S transition of the cell cycle is a lethal event at cellular level (2, 3). Conversely, elevated dNTP pools throughout the cell cycle lead to increased mutation rates (4-6). Imbalance in dNTP pools also contributes to mutagenesis by reducing the fidelity of DNA polymerases (7-9). Eukaryotic cells have evolved complex surveillance mechanisms (i.e., checkpoints) to ensure proper dNTP pool sizes during the normal cell-cycle progression and in response to genotoxic stress (3, 10-14). A major target of such checkpoint regulation is ribonucleotide reductase (RNR), which catalyzes the reduction of ribonucleoside diphosphate to deoxyribonucleoside diphosphate, an essential step in de novo biosynthesis of dNTPs (15).Class I RNRs were identified originally in Escherichia coli and are conserved from yeast to mammal (16). The mechanisms of enzymatic catalysis (17) and allosteric regulation (18, 19) have been studied extensively in E. coli and, more recently, in mice (20, 21). The archetype RNR holoenzyme consists of a large subunit R1 (␣, whose oligomeric state in eukaryotes is not completely understood) (22) and a homodimeric small subunit (␤ 2 ) (20). The eukaryotic R1 contains the catalytic site, an effector site that controls substrate specificity, an activity site that controls turnover, and a weak ATP-binding site that cont...

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Ribonucleotide Reductase: Recent Advances

Stubbe¹,

Cotruvo²

2004

Handbook of Metalloproteins

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Ribonucleotide reductases (RNRs) catalyze the conversion of nucleotides to deoxynucleotides and play an essential role in nucleic acid metabolism in all organisms. RNRs have been divided into three classes. They share a structurally homologous subunit where the reduction occurs, with the chemistry being initiated by thiyl radical‐mediated abstraction of the nucleotide's 3′‐hydrogen atom. The classification of RNRs is based on the different strategies used to generate the transient thiyl radical. The class Ia and Ib RNRs use a diferric‐tyrosyl radical cofactor, the class II RNRs use adenosylcobalamin, and the class III RNRs use a glycyl radical generated by a [4Fe4S] 1+ cluster and S ‐adenosylmethionine. This article focuses on the recent advances in our understanding of the in vitro and in vivo mechanisms of formation of the metallocofactors in the class I RNRs in E. coli and S. cerevisiae . The discovery of a new class of RNR, class Ic, whose active cofactor is proposed to be an Mn IV Fe III cluster, and a summary of recent insights into the chemistry of the novel cofactor are also described. Finally, the current understanding of the unprecedented role of the metallocofactor in radical propagation over 35 Å in the class Ia—and presumably class Ib and Ic—RNRs is presented.

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The Active Form of the Saccharomyces cerevisiae Ribonucleotide Reductase Small Subunit Is a Heterodimer in Vitro and in Vivo

Cited by 34 publications

References 29 publications

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

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

Nuclear localization of the Saccharomyces cerevisiae ribonucleotide reductase small subunit requires a karyopherin and a WD40 repeat protein

Ribonucleotide Reductase: Recent Advances

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