2011
DOI: 10.1074/jbc.m111.294074
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Investigation of in Vivo Diferric Tyrosyl Radical Formation in Saccharomyces cerevisiae Rnr2 Protein

Abstract: Background: Yeast RNR small subunit is an Rnr2-Rnr4 heterodimer; only Rnr2 contains a cluster. Results: rnr4 and dre2 mutants are defective in Rnr2 cluster formation and display synthetic growth defects with grx3/4. Conclusion: Rnr4 stabilizes Rnr2 for cluster assembly via a pathway dependent on monothiol glutaredoxins Grx3/Grx4 and Fe-S cluster protein Dre2. Significance: Understanding RNR cluster assembly may provide new cancer therapeutic strategy.

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Cited by 49 publications
(89 citation statements)
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“…An electron transfer process coupled with tightly regulated conformational rearrangements can therefore be proposed to occur in the anamorsin-Ndor1 complex ( Our study lays out the molecular basis for the comprehension of the two functional processes in which the anamorsin-Ndor1 complex is implicated, i.e., assembly of Fe/S proteins and regulation of cell survival/death mechanisms. From our data we can propose that the electron transfer process responsible for the assembly of ISC (13) and diferric (17) proteins occurs within a stable complex without the dissociation of the two protein partners but just through the modulation of the interactions of the domains involved in the electron transfer process. Although the molecular targets of the electron transfer flow generated by this protein-protein complex are not yet defined, suggestions for the targets of the electron flow include the conversion of the sulfur of cysteine (formally S 0 ) to the sulfide (S 2− ) present in Fe/S clusters and/or the reductive coupling of two [2Fe-2S] clusters to form a [4Fe-4S] cluster (13).…”
Section: Discussionmentioning
confidence: 79%
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“…An electron transfer process coupled with tightly regulated conformational rearrangements can therefore be proposed to occur in the anamorsin-Ndor1 complex ( Our study lays out the molecular basis for the comprehension of the two functional processes in which the anamorsin-Ndor1 complex is implicated, i.e., assembly of Fe/S proteins and regulation of cell survival/death mechanisms. From our data we can propose that the electron transfer process responsible for the assembly of ISC (13) and diferric (17) proteins occurs within a stable complex without the dissociation of the two protein partners but just through the modulation of the interactions of the domains involved in the electron transfer process. Although the molecular targets of the electron transfer flow generated by this protein-protein complex are not yet defined, suggestions for the targets of the electron flow include the conversion of the sulfur of cysteine (formally S 0 ) to the sulfide (S 2− ) present in Fe/S clusters and/or the reductive coupling of two [2Fe-2S] clusters to form a [4Fe-4S] cluster (13).…”
Section: Discussionmentioning
confidence: 79%
“…This is based on the structural characterization of the FMN-binding domain of Ndor1 and of the C-terminal region (linker and CIAPIN1 domain) of anamorsin containing the [2Fe-2S] cluster in the oxidized state ([2Fe-2S]-anamorsin, hereafter) and on the identification of the protein regions between [2Fe-2S]-anamorsin and the FMN-binding domain of Ndor1 responsible for the formation of their stable complex and of those regions interacting in the electron transfer process. The molecular model of the electron transfer process proposed here provides significant information on the functional processes in which the anamorsinNdor1 interaction has been implicated, i.e., the assembly of ISCs (13) and diferric (17) proteins and the regulation of cell survival/ death mechanisms (15,16). This article is a PNAS Direct Submission.…”
mentioning
confidence: 96%
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“…S288C) (29). These strains are also hypersensitive to the Y ⅐ quenching reagent hydroxyurea (28). We have been able to take advantage of this viability and our ability to permeabilize WT and ⌬rnr4 cells to take up proteins (e.g.…”
Section: Ribonucleotide Reductase (Rnr)mentioning
confidence: 97%
“…␤Ј is structurally homologous to ␤ but lacks three iron ligands, and as a consequence, contains no metallo-cofactor (18,22,(25)(26)(27). Although ␤Ј is catalytically inactive, it is required for converting ␤ into a conformation that is competent for iron loading and Y ⅐ formation in vitro and in vivo (23,24,28). Importantly, recombinant apo-␤ 2 and ␤Ј 2 rapidly form apo-␤␤Ј in vitro (24), and although cluster assembly from Fe II , O 2 , and reductant is inefficient (0.25 Y ⅐ /␤␤Ј), these properties allow us to study reconstitution in vitro with mutant small subunits.…”
Section: Ribonucleotide Reductase (Rnr)mentioning
confidence: 99%