High field EPR studies of mouse ribonucleotide reductase indicate hydrogen bonding of the tyrosyl radical

Ribonucleotide reductase catalyzes by free radical chemistry the reduction of ribonucleotides to deoxyribonucleotides. The R2 protein of a class 1 ribonucleotide reductase contains a stable tyrosyl radical of neutral phenoxy character, which is necessary for normal enzymatic activity. Here we present the EPR spectra from the tyrosyl free radical in the R2 protein from mouse at 9.62, 115, and 245 GHz. We show that the g-value anisotropy of the mouse R2 radical, when precisely determined from high field EPR spectra, is similar to that of the hydrogen bonded dark stable YD middle dot tyrosyl radical of photosystem II and different from that of the Escherichia coli R2 radical. Because the g-value anisotropy is an important indicator of the hydrogen bonding status of the tyrosyl radical, this result suggests that the mouse R2 radical has its tyrosylate oxygen hydrogen bonded with a D2O exchangeable proton, whereas this hydrogen bond is absent in the E. coli enzyme. It is suggested that the observed proton may be derived from the tyrosine that will become a tyrosyl radical.

Induction of the mouse ribonucleotide reductase R1 and R2 genes in response to DNA damage by UV light

Ribonucleotide reductase is responsible for the production of deoxyribonucleotides required for DNA synthesis and consists of two nonidentical subunits, proteins R1 and R2. Here we show that the R1 promoter can be induced up to 3-fold, and the R2 promoter is induced up to 10-fold by UV light in a dose-dependent manner. This was demonstrated using serum-starved, synchronized G0/G1 mouse fibroblast 3T3 cells stably transformed with different R1 and R2 promoter-luciferase reporter gene constructs. R2 promoter activation requires a minimal promoter, containing a TTTAAA element plus the transcription start, and either three upstream DNA-protein binding regions or one proximal, NF-Y binding region. This is different from proliferation-specific activation of the R2 promoter. Using Northern blotting we show a preferential accumulation of the minor, 1. 6-kilobase R2 transcript in irradiated cells, whereas the levels of the major 2.1-kilobase transcript are unchanged. No R2 promoter activation was observed after treatment of mouse cells with agents reported to induce the ribonucleotide reductase genes in Saccharomyces cerevisiae such as hydroxyurea or methylmethane sulfonate. This indicates that activation of ribonucleotide reductase gene expression is specific for nucleotide excision repair in mammalian cells and not part of a general response to DNA damage.

A kinetic study on the influence of nucleoside triphosphate effectors on subunit interaction in mouse ribonucleotide reductase

For enzymatic activity, mouse ribonucleotide reductase must form a heterodimeric complex composed of homodimeric R1 and R2 proteins. Both substrate specificity and overall activity are regulated by the allosteric effectors ATP, dATP, dTTP, and dGTP, which bind to two different sites found on R1, the activity site and the substrate specificity site. We have used biosensor technique to directly observe the effects of these nucleotides on R1/R2 interactions. In the absence of effectors, positive cooperativity was observed with a Hill coefficient of 1.8 and a KD of 0.5 microM. In the presence of dTTP or dGTP, there was no cooperativity and subunit interaction was observed at a much lower R1 concentration. The highest R1/R2 affinity was in the presence of dATP or ATP with KDs of 0.05-0.1 microM. In all experiments, the molar stoichiometry between the subunits was close to 1:1. Our data support a model whereby binding of any of the effectors to the substrate specificity site promotes formation of the R1 dimer, which we believe is prerequisite for binding to the R2 dimer. Additional binding of either ATP (a positive effector) or dATP (a negative effector) to the activity site further increases R1/R2 association. We propose that binding of ATP or dATP to the activity site controls enzyme activity, not by changing the aggregation state of the R1/R2 proteins as proposed earlier, but rather by locally influencing the long range electron transport between the catalytic site of R1 and the tyrosyl free radical of R2.

Formation of a free radical of the sulfenylimine type in the mouse ribonucleotide reductase reaction with 2'-azido-2'-deoxycytidine 5'-diphosphate

Mouse and Escherichia coli ribonucleotide reductases (RR) both belong to the same class of RR, where the enzyme consists of two non-identical subunits, proteins R1 and R2. A transient free radical was observed by EPR spectroscopy in the mouse RR reaction with the suicidal inhibitor 2'-azido-2'-deoxycytidine 5'-diphosphate. The detailed hyperfine structure of the EPR spectrum of the transient radical is somewhat different for the mouse and previously studied E. coli enzymes. When the positive allosteric effector ATP was replaced by the negative effector dATP, no transient radical was observed, showing that 'normal' binding of the inhibitor to the substrate binding site is required. Using the mouse protein R2 mutants W103Y and D266A, where the mutations have been shown to specifically block long range electron transfer between the active site of the R1 protein to the iron/radical site in protein R2, no evidence of transient radical was found. Taken together, the data suggest that the radical is located at the active site in protein R1, and is probably of the sulfenylimine type.

The TATA-less promoter of mouse ribonucleotide reductase R1 gene contains a TFII-I binding initiator element essential for cell cycle-regulated transcription

Mammalian ribonucleotide reductase shows S-phase specific expression and consists of two non-identical subunits, proteins R1 (large subunit) and R2 (small subunit). A comparison between the human and mouse TATA-less R1 gene promoters revealed four highly conserved DNA regions, while the remaining sequence showed a low degree of conservation. Two regions, alpha and beta, were earlier identified as protein binding regions in the mouse R1 promoter by using DNase footprinting technique. The two new regions are located to the transcription start and to a DNA sequence about 40 base pairs downstream from the start. Gel shift assays using TFII-I antibodies and competition with an oligonucleotide representing the terminal deoxynucleotidyl transferase inhibitor element identified the start region as a TFII-I binding initiator element. The conserved downstream region, called gamma, also formed specific DNA-protein complexes in gel shift assays. Functional studies, using synchronized cells stably transformed by R1 promoter-luciferase reporter gene constructs, indicated that the initiator and the gamma elements together were necessary for cell cycle-regulated R1 promoter activity. Earlier published data, indicating Sp1 binding to the R1 alpha/beta regions, could not be confirmed, suggesting that the R1 initiator element may function independent of Sp1.

Role of a proximal NF-Y binding promoter element in S phase-specific expression of mouse ribonucleotide reductase R2 gene

Cell cycle-regulated transcription of the R2 gene of mouse ribonucleotide reductase was earlier shown to be controlled at the level of elongation by an S phase-specific release from a transcriptional block. However, the R2 promoter is activated very early when quiescent cells start to proliferate, and this activation is dependent on three upstream sequences located nucleotide -672 to nucleotide -527 from the transcription start. In this study, we use R2-luciferase reporter gene constructs and gel shift assays to demonstrate that, in addition to the upstream sequences, a proximal CCAAT element specifically binding the transcription factor NF-Y is required for continuous activity of the R2 promoter through the S phase. When the CCAAT element is deleted or mutated, promoter activity induced by the upstream elements decays before cells enter S phase, and the transcriptional block is released. This is a clear example of how changing of a proximal sequence element can alter not only the quantitative but also the qualitative response to upstream transcription activation domains.

Crystallization and crystallographic investigations of the small subunit of mouse ribonucleotide reductase

The R2 protein component of mouse ribonucleotide reductase has been obtained from overproducing Escherichia coli bacteria. It has been crystallized using NaCl as precipitant. The crystals are orthorhombic, space group C222(1), with cell dimensions a = 76.9 A, b = 108.9 A, c = 92.7 A and diffract to at least 2.5 A. The asymmetric unit of the crystals contains one monomer. Rotation and translation function searches using a model based on the weakly homologous E. coli R2 gave one significant peak. Rotation about a crystallographic 2-fold axis parallel to the a-axis produces an R2 dimer with dimer interactions very similar to those found for E. coli R2.

Evidence by site-directed mutagenesis supports long-range electron transfer in mouse ribonucleotide reductase

Mammalian ribonucleotide reductase consists of two nonidentical subunits, proteins R1 and R2, each inactive alone. The R1 protein binds the ribonucleotide substrates while the R2 protein contains a binuclear iron center and a tyrosyl free radical, essential for activity. The crystal structures of the corresponding Escherichia coli proteins suggest that the distance from the active site in R1 to the tyrosyl radical buried in R2 is about 35 A. Therefore, an electron pathway was suggested between the active site and the tyrosyl radical. Such a pathway could include a conserved tryptophan on the suggested R1 interaction surface of R2 and a conserved aspartic acid hydrogen bonded both to the tryptophan and to a histidine iron ligand. To find experimental support for such an electron pathway, we have replaced the conserved tryptophan in mouse R2 with phenylalanine or tyrosine and the aspartic acid with alanine. All the mutated R2 proteins were shown to bind metal with the same affinity as native R2 and to form the binuclear iron center. In addition, the W103Y and D266A proteins formed a normal tyrosyl free radical while only low amounts of radical were observed in the W103F protein. Neither the kinetic rate constants nor the equilibrium dissociation constant of the R1/R2 complex was affected by the mutations as shown by BIAcore biosensor technique. However, all mutant R2 proteins were completely inactive in the enzymatic assay, supporting the hypothesis that the tryptophan and aspartic acid residues are important links in an amino acid residue specific long-range electron transfer.

The critical C-terminus of the small subunit of herpes simplex virus ribonucleotide reductase is mobile and conformationally similar to C-terminal peptides

The C-terminus of the small subunit of class I ribonucleotide reductases is essential for subunit association and enzymatic activity. 1H NMR analysis of the small subunit (2 x 38 kDa as a homodimer) of herpes simplex virus ribonucleotide reductase shows that this critical binding site is mobile and exposed in relation to the rest of the protein. Assignments of six C-terminal amino acids are made by comparing the TOCSY and NOESY spectra of the small subunit with the spectra of an identical protein truncated by seven amino acids at the C-terminus and the spectra of an analogous 15 amino acid peptide. The mobility of the C-terminus may be important for subunit recognition and could be general for other ribonucleotide reductases. The spectral comparisons also suggest that the six C-terminal amino acids of the small subunit and peptide are conformationally similar. This observation may be important for the design of inhibitors of ribonucleotide reductase subunit association.

Purification, characterization, and localization of subunit interaction area of recombinant mouse ribonucleotide reductase R1 subunit

Mammalian ribonucleotide reductase is a heterotetramer formed by the two non-identical homodimers proteins R1 and R2. We have succeeded in expressing the 90-kDa mouse R1 protein in Escherichia coli in an active, soluble form using the T7 RNA polymerase pET vector system. To avoid inclusion bodies, the bacteria were grown at 15 degrees C with minimal concentration of the inducer isopropyl-1-thio-beta-D-galactopyranoside. After a rapid purification procedure, approximately 20 mg of pure R1 protein were obtained per liter of bacterial culture. The concentrated R1 protein solution had a pinkish red color. Spectroscopy in combination with iron and labile sulfur analyses demonstrated that the color originated from an iron-sulfur complex. However, all attempts to demonstrate a function of this complex have been inconclusive. A comparison of the recombinant R1 protein with the corresponding protein purified from calf thymus showed no evidence for glycosylation. Circular dichroism spectroscopy indicated an alpha-helical content of 50%. A flexible COOH-terminal tail of 7 residues in the R2 protein was earlier shown to be essential for binding to the R1 protein. Using a peptide protection assay and photoaffinity labeling, we now show that the R2 protein tail interacts with a region close to the carboxyl terminus of the R1 protein.

1H NMR studies of mouse ribonucleotide reductase: the R2 protein carboxyl-terminal tail, essential for subunit interaction, is highly flexible but becomes rigid in the presence of protein R1

Mouse ribonucleotide reductase consists of two nonidentical subunits, proteins R1 and R2, each inactive alone. It has earlier been shown that the carboxyl-terminal part of the R2 protein is essential for subunit association to form the active enzyme complex. We now demonstrate that protein R2 gives rise to a number of sharp 1H NMR resonances, significantly narrower than the major part of the resonances. This line narrowing of certain resonances indicates segmental mobility in the molecule. In two-dimensional 1H TOCSY spectra of protein R2, cross-peak patterns from about 25 amino acid residues are visible. Most of these were assigned to the carboxyl-terminal part of the protein by comparisons with cross-peak patterns of oligopeptides corresponding to the carboxyl terminus of mouse R2 and to the patterns of a seven amino acid residue carboxyl-terminal truncated form of protein R2. These results and the magnitude of the chemical shifts of the assigned residues demonstrate that the carboxyl-terminal part of mouse R2 protein is highly mobile compared to the rest of the protein and essentially unstructured. When protein R1 is added to a solution of protein R2, the sharp resonances are broadened, suggesting that the mobility of the carboxyl-terminal tail of protein R2 is reduced. The possibility of making direct observations of subunit interaction in native and mutagenized R1/R2 proteins should allow discrimination between effects of amino acid replacements on the catalytic mechanism and effects on subunit interaction.

Role of ribonucleotide reductase in inhibition of mammalian cell growth by potent iron chelators

Ribonucleotide reductase consists of two nonidentical subunits, proteins R1 and R2, the latter of which contains an iron-tyrosyl free radical center essential for activity. We have studied the in vivo effects on the R2 protein of the potent iron chelators parabactin and desferrioxamine using R2-overproducing mouse cells with a tyrosyl free radical signal easily quantifiable by EPR spectroscopy. Both chelators inhibited cell growth, and the inhibition was reversible by iron. Furthermore, both chelators, which penetrate cells and chelate the intracellular iron pool, caused a disappearance of the R2 tyrosyl free radical. In parallel, there was an accumulation of apo-R2 protein in the inhibited cells. In vitro studies using pure, 59Fe-labeled recombinant mouse R2 protein unexpectedly showed that its iron center is labile at physiological temperatures and that iron is spontaneously lost from the protein even in the absence of chelators in a temperature-dependent process. Our conclusion is that parabactin or desferrioxamine inhibits ribonucleotide reduction and cell growth not by directly attacking the iron-radical center of the R2 protein, but instead by chelating the intracellular iron pool. This prevents the regeneration of the iron-radical center both in newly synthesized apo-R2 protein and in apo-R2 protein continuously formed from active R2 protein by the loss of iron.

Structure and promoter characterization of the gene encoding the large subunit (R1 protein) of mouse ribonucleotide reductase

Mammalian ribonucleotide reductase (EC 1.17.4.1) is composed of two nonidentical subunits, proteins R1 and R2, both required for enzyme activity. The structure of the genomic mouse ribonucleotide reductase R1 gene was compiled from a number of overlapping lambda clones isolated from a Charon 4A mouse sperm genomic library. The R1-encoding gene covers 26 kb and consists of 19 exons. All exon-intron boundaries were located by dideoxynucleotide sequencing, showing that intron 7 starts with the variant GC instead of GT. About 3.5 kb of DNA from the 5'-flanking region of the R1-encoding gene were cloned and sequenced, and the transcriptional start site was determined by nuclease S1 mapping of RNA. DNase I footprinting assays on the R1 promoter identified two nearly identical 23-bp-long protein-binding regions. Three protein complexes binding to one of the 23-mer regions were resolved and partially identified by using gel-retardation mobility-shift assays and UV crosslinking. One complex most likely contained Sp1, and another complex showed S-phase-specific binding, suggesting a direct role in the cell-cycle-dependent R1 gene expression.

Reduction and loss of the iron center in the reaction of the small subunit of mouse ribonucleotide reductase with hydroxyurea

Ribonucleotide reductase is a key enzyme for DNA synthesis in living cells, and the mechanisms for its reactions with inhibitors are of interest because the inhibitors are potential antiproliferative agents. Protein R2, the small subunit of mouse ribonucleotide reductase, contains a pair of mu-oxo-bridged ferric ions and a tyrosyl free radical in each of its two polypeptide chains. Light absorption spectroscopy was used to probe the reactions of these redox centers with hydroxyurea (HU), a potent inhibitor of iron containing ribonucleotide reductases. In Escherichia coli protein R2, HU reacts with the tyrosyl radical without affecting the iron center. In contrast to the case for the E. coli protein, HU destroys the specific absorbance bands of both the iron center and the radical on a similar time scale in mouse protein R2, and this is accompanied by release of iron from the protein. Anaerobic experiments with the iron chelator bathophenanthroline present during the HU reaction indicate that the iron is released from the mouse R2 protein in the ferrous form after treatment with HU. The reduced iron center, formed by reaction of Fe2+ with mouse apoprotein R2 under anaerobic conditions, was found to be much less stable than the native Fe3+ site in the presence of suitable iron chelators. The observations are of importance for understanding the mode of action of HU on mammalian cells and for the general question of the stability of the iron center of mouse protein R2 in different redox states.

An S-phase specific release from a transcriptional block regulates the expression of mouse ribonucleotide reductase R2 subunit

Ribonucleotide reductase (RR) activity in mammalian cells is closely linked to DNA synthesis. The RR enzyme is composed of two non-identical subunits, proteins R1 and R2. Both proteins are required for holoenzyme activity, which is regulated by S-phase specific de novo synthesis and breakdown of the R2 subunit. In quiescent cells stimulated to proliferate and in elutriated cell populations enriched in the various cell cycle phases the R2 protein levels are correlated to R2 mRNA levels that are low in G0/G1-phase cells but increase dramatically at the G1/S border. Using an R2 promoter-luciferase reporter gene construct we demonstrate an unexpected early activation of the R2 promoter as cells pass from quiescence to proliferation. However, due to a transcriptional block, this promoter activation only results in very short R2 transcripts until cells enter the S-phase, when full-length R2 transcripts start to appear. The position for the transcriptional block was localized to a nucleotide sequence approximately 87 bp downstream from the first exon/intron boundary by S1 nuclease mapping of R2 transcripts from modified in vitro nuclear run-on experiments. These results identify blocking of transcription as a mechanism to control cell cycle regulated gene expression.

EPR stopped-flow studies of the reaction of the tyrosyl radical of protein R2 from ribonucleotide reductase with hydroxyurea

The reaction of the functional tyrosyl radical in protein R2 of ribonucleotide reductase from E. coli and mouse with the enzyme inhibitor hydroxyurea has been studied by EPR stopped-flow techniques at room temperature. The rate of disappearance of the tyrosyl radical in E. coli protein R2 is k2 = 0.43 M-1 s-1 at 25 degrees C. The reaction follows pseudo-first-order kinetics up to 450 mM hydroxyurea indicating that no saturation by hydroxyurea takes place even at this high concentration. Transient nitroxide-like radicals from hydroxyurea have been detected for the first time in the reaction of hydroxyurea with protein R2 from E. coli and mouse, indicating that 1-electron transfer from hydroxyurea to the tyrosyl radical is the dominating mechanism in the inhibitor reaction. The hydroxyurea radicals appear in low steady-state concentrations during 2-3 half-decay times of the tyrosyl radical and disappear thereafter.

The role of herpes simplex virus ribonucleotide reductase small subunit carboxyl terminus in subunit interaction and formation of iron-tyrosyl center structure

Herpes simplex virus ribonucleotide reductase consists of two nonidentical subunits, proteins R1 and R2, which are required together for activity. Active R2 protein contains a tyrosyl free radical and a binuclear iron center. A truncated form of the R2 subunit, lacking 7 amino acid residues in the carboxyl terminus, was constructed, overexpressed in Escherichia coli and purified to homogeneity. In the presence of ferrous iron and oxygen, the truncated protein readily generated similar amounts of tyrosyl free radical as the intact protein. However, the radical showed differences in EPR characteristics in the truncated protein compared with the normal one, indicating an altered structural arrangement of the radical relative to the iron center. The truncated R2* protein was completely devoid of binding affinity to the R1 protein, demonstrating that the subunit interaction is totally dependent on the 7 outermost carboxyl-terminal amino acids of protein R2.

Rat apolipoprotein C-II lacks the conserved site for proteolytic cleavage of the pro-form

Apolipoprotein C-II (apoC-II) plays a critical role in the metabolism of plasma lipoproteins as an activator for lipoprotein lipase. Human apoC-II consists of 79 amino acid residues (pro-apoC-II). A minor fraction is converted to a mature form by cleavage at the site QQDE releasing the 6 amino-terminal residues. We have cloned and sequenced the cDNA for rat apoC-II from a liver cDNA library using human apoC-II cDNA as a probe. The cDNA encodes a protein of 97 amino acid residues including a signal peptide of 22 amino acid residues. There is approximately 60% similarity between the deduced amino acid sequence of rat apoC-II and other apoC-II sequences presently known (human, monkey, dog, cow, and guinea pig). Compared to these, rat apoC-II is one residue shorter at the carboxyl terminus. Furthermore, there is a deletion of 3 amino acid residues (PQQ) in the highly conserved cleavage site where processing from pro- to mature apoC-II occurs in other species. Accordingly, rat apoC-II isolated from plasma was mainly in the pro-form. Northern blot analyses indicated that rat apoC-II is expressed both in liver and in small intestine.