Regulation of ribonucleotide reductase during iron limitation

In this issue of Molecular Cell, Sanvisens et al. (2011) report a new mechanism for regulation of yeast ribonucleotide reductase activity that occurs during iron deprivation.     

Regulation of ribonucleotide reductase activity in mammalian cells

Mammalian ribonucleotide reductase catalyzes the rate-limiting for the de novo synthesis 2'-deoxyribonucleoside 5'-triphosphates. There is some suggestion that this step may also be the rate-limiting step of DNA synthesis. It is apparent that the level of the enzyme, ribonucleotide reductase, varies through the cell cycle and is highest in those tissues with the greatest proliferation rate. This increase in activity is associated with increased protein synthesis. The purified enzyme has been shown to be subject to strict allosteric regulation by the various nucleoside triphosphates and it has been proposed that allosteric regulation plays an important role in the level of ribonucleotide reductase activity which is expressed. All experimental data relating to this point, however, do not support the role of deoxyribonucleoside triphosphates as a major factor in determining cellular reductase activity during normal cell division. Several naturally occurring factors have been isolated from cells which lower ribonucleotide reductase activity in vitro. These factors have been found in tissues of low growth fraction and appear to be absent or low in tissues or high growth fraction such as tumor, regenerating liver and embryonic tissues. The expression of intracellular ribonucleotide reductase activity is therefore controlled at various levels and by various factors and the prevailing mode of regulation may vary throughout the cell cycle transverse and also in the various types of cells.     

Cross-talk between the allosteric effector-binding sites in mouse ribonucleotide reductase

We compared the allosteric regulation and effector binding properties of wild type R1 protein and R1 protein with a mutation in the "activity site" (D57N) of mouse ribonucleotide reductase. Wild type R1 had two effector-binding sites per polypeptide chain: one site (activity site) for dATP and ATP, with dATP-inhibiting and ATP-stimulating catalytic activity; and a second site (specificity site) for dATP, ATP, dTTP, and dGTP, directing substrate specificity. Binding of dATP to the specificity site had a 20-fold higher affinity than to the activity site. In all these respects, mouse R1 resembles Escherichia coli R1. Results with D57N were complicated by the instability of the protein, but two major changes were apparent. First, enzyme activity was stimulated by both dATP and ATP, suggesting that D57N no longer distinguished between the two nucleotides. Second, the two binding sites for dATP both had the same low affinity for the nucleotide, similar to that of the activity site of wild type R1. Thus the mutation in the activity site had decreased the affinity for dATP at the specificity site, demonstrating the interaction between the two sites.     

Regulation of ribonucleotide reductase activity in intact mammalian cells

An intact cell assay system based upon Tween-80 permeabilization was used to investigate the regulation of ribonucleotide reductase activity in Chinese hamster ovary cells. Models used to explain the regulation of the enzyme have been based upon work carried out with cell-free extracts, although there is concern that the properties of such a complex enzyme would be modified by extraction procedures. We have used the intact cell assay system to evaluate, within whole cells, the current model of ribonucleotide reductase regulation. While some of the results agree with the proposals of the model, others do not. Most significantly, it was found that ribonucleotide reductase within the intact cell could simultaneously bind the nucleoside triphosphate activators for both CDP and ADP reductions. According to the model based upon studies with cell-free preparations, the binding of one of these nucleotides should exclude the binding of others. Also, studies on intracellular enzyme activity in the presence of combinations of nucleotide effectors indicate that GTP and perhaps dCTP should be included in a model for ribonucleotide reductase regulation. For example, GTP has the unique ability to modify through activation both ADP and CDP reductions, and synergistic effects were obtained for the reduction of CDP by various combinations of ATP and dCTP. In general, studies with intact cells suggest that the in vivo regulation of ribonucleotide reductase is more complex than predicted from enzyme work with cell-free preparations. A possible mechanism for the in vivo regulation of ribonucleotide reductase, which combines observations of enzyme activity in intact cells and recent reports of independent substrate-binding subunits in mammalian cells is discussed.     

Regulation of ribonucleotide reductase in response to iron deficiency

Ribonucleotide reductase (RNR) is an essential enzyme required for DNA synthesis and repair. Although iron is necessary for class Ia RNR activity, little is known about the mechanisms that control RNR in response to iron deficiency. In this work, we demonstrate that yeast cells control RNR function during iron deficiency by redistributing the Rnr2-Rnr4 small subunit from the nucleus to the cytoplasm. Our data support a Mec1/Rad53-independent mechanism in which the iron-regulated Cth1/Cth2 mRNA-binding proteins specifically interact with the WTM1 mRNA in response to iron scarcity and promote its degradation. The resulting decrease in the nuclear-anchoring Wtm1 protein levels leads to the redistribution of the Rnr2-Rnr4 heterodimer to the cytoplasm, where it assembles as an active RNR complex and increases deoxyribonucleoside triphosphate levels. When iron is scarce, yeast selectively optimizes RNR function at the expense of other non-essential iron-dependent processes that are repressed, to allow DNA synthesis and repair.     

Autoregulation of the nar operon encoding nitrate reductase in Escherichia coli

Summary Nitrate reductase is demonstrated to exert an autogenous control on its own synthesis. This effect requires the participation of the molybdenum cofactor. Use of strains in which the control region of the nar operon is mutated reveals two loci in this region: one, affected in strain LCB94, is common to both autoregulation and induction by nitrate while the other, mutated in strain LCB188, is specific for the induction by nitrate. It is proposed that the autogenous control prevents the unnecessary accumulation of the nitrate reductase subunits in the cytoplasm.     

Dehydration of ribonucleotides catalyzed by ribonucleotide reductase: the role of the enzyme

This article focuses on the second step of the catalytic mechanism for the reduction of ribonucleotides catalyzed by the enzyme Ribonucleotide Reductase (RNR). This step corresponds to the protonation/elimination of the substrate's C-2' hydroxyl group. Protonation is accomplished by the neighbor Cys-225, leading to the formation of one water molecule. This is a very relevant step since most of the known inhibitors of this enzyme, which are already used in the fight against certain forms of cancer, are 2'-substituted substrate analogs. Even though some theoretical studies have been performed in the past, they have modeled the enzyme with minimal gas-phase models, basically represented by a part of the side chain of the relevant amino acids, disconnected from the protein backbone. This procedure resulted in a limited accuracy in the position and/or orientation of the participating residues, which can result in erroneous energetics and even mistakes in the choice of the correct mechanism for this step. To overcome these limitations we have used a very large model, including a whole R1 model with 733 residues plus the substrate and 10 A thick shell of water molecules, instead of the minimal gas-phase models used in previous works. The ONIOM method was employed to deal with such a large system. This model can efficiently account for the restrained mobility of the reactive residues, as well as the long-range enzyme-substrate interactions. The results gave additional information about this step, which previous small models could not provide, allowing a much clearer evaluation of the role of the enzyme. The interaction energy between the enzyme and the substrate along the reaction coordinate and the substrate steric strain energy have been obtained. The conclusion was that the barrier obtained with the present model was very similar to the one previously determined with minimal gas-phase models. Therefore, the role of the enzyme in this step was concluded to be mainly entropic, rather than energetic, by placing the substrate and the two reactive residues in a position that allows for the highly favorable concerted trimolecular reaction, and to protect the enzyme radical from the solvent.     

Regulation of ribonucleotide reductase M2 expression by the upstream AUGs

Ribonucleotide reductase catalyzes a rate-limiting reaction in DNA synthesis by converting ribonucleotides to deoxyribonucleotides. It consists of two subunits and the small one, M2 (or R2), plays an essential role in regulating the enzyme activity and its expression is finely controlled. Changes in the M2 level influence the dNTP pool and, thus, DNA synthesis and cell proliferation. M2 gene has two promoters which produce two major mRNAs with 5′-untranslated regions (5′-UTRs) of different lengths. In this study, we found that the M2 mRNAs with the short (63 nt) 5′-UTR can be translated with high efficiency whereas the mRNAs with the long (222 nt) one cannot. Examination of the long 5′-UTR revealed four upstream AUGs, which are in the same reading frame as the unique physiological translation initiation codon. Further analysis demonstrated that these upstream AUGs act as negative cis elements for initiation at the downstream translation initiation codon and their inhibitory effect on M2 translation is eIF4G dependent. Based on the findings of this study, we conclude that the expression of M2 is likely regulated by fine tuning the translation from the mRNA with a long 5′-UTR during viral infection and during the DNA replication phase of cell proliferation.     

The enantioselectivities of the active and allosteric sites of mammalian ribonucleotide reductase

Here we examine the enantioselectivity of the allosteric and substrate binding sites of murine ribonucleotide reductase (mRR). L-ADP binds to the active site and L-ATP binds to both the s- and a-allosteric sites of mR1 with affinities that are only three- to 10-fold weaker than the values for the corresponding D-enantiomers. These results demonstrate the potential of L-nucleotides for interacting with and modulating the activity of mRR, a cancer chemotherapeutic and antiviral target. On the other hand, we detect no substrate activity for L-ADP and no inhibitory activity for N3-L-dUDP, demonstrating the greater stereochemical stringency at the active site with respect to catalytic activity.     

Identification of phosphorylation sites on the yeast ribonucleotide reductase inhibitor Sml1

Sml1 is a small protein in Saccharomyces cerevisiae which inhibits the activity of ribonucleotide reductase (RNR). RNR catalyzes the rate-limiting step of de novo dNTP synthesis. Sml1 is a downstream effector of the Mec1/Rad53 cell cycle checkpoint pathway. The phosphorylation by Dun1 kinase during S phase or in response to DNA damage leads to diminished levels of Sml1. Removal of Sml1 increases the population of active RNR, which raises cellular dNTP levels. In this study using mass spectrometry and site-directed mutagenesis, we have identified the region of Sml1 phosphorylation to be between residues 52 and 64 containing the sequence GSSASASASSLEM. This is the first identification of a phosphorylation sequence of a Dun1 biological substrate. This sequence is quite different from the consensus Dun1 phosphorylation sequence reported previously from peptide library studies. The specific phosphoserines were identified to be Ser(56), Ser(58), and Ser(60) by chemical modification of these residues to S-ethylcysteines followed by collision activated dissociation. To investigate further Sml1 phosphorylation, we constructed the single mutants S56A, S58A, S60A, and the triple mutant S56A/S58A/S60A and compared their degrees of phosphorylation with that of wild type Sml1. We observed a 90% decrease in the relative phosphorylation of S60A compared with that of wild type, a 25% decrease in S58A, and little or no decrease in the S56A mutant. There was no observed phosphate incorporation in the triple mutant, suggesting that Ser(56), Ser(58), and Ser(60) in Sml1 are the sites of phosphorylation. Further mutagenesis studies reveal that Dun1 kinase requires an acidic residue at the +3 position, and there is cooperativity between the phosphorylation sites. These results show that Dun1 has a unique phosphorylation motif.     

Regulation of peptide transport in Escherichia coli: induction of the trp-linked operon encoding the oligopeptide permease.

Growth of Escherichia coli in medium containing leucine results in increased entry of exogenously supplied tripeptides into the bacterial cell. This leucine-mediated elevation of peptide transport required expression of the trp-linked opp operon and was accompanied by increased sensitivity to toxic tripeptides, by an enhanced capacity to utilize nutritional peptides, and by an increase in both the velocity and apparent steady-state level of L-[U-14C]alanyl-L-alanyl-L-alanine accumulation for E. coli grown in leucine-containing medium relative to these parameters of peptide transport measured with bacteria grown in media lacking leucine. Direct measurement of opp operon expression by pulse-labeling experiments demonstrated that growth of E. coli in the presence of leucine resulted in increased synthesis of the oppA-encoded periplasmic binding protein.     

Derepression and repression of the histidine operon: role of the feedback site of the first enzyme.

Thiazolealanine, a false feedback inhibitor, causes transient repression of the his operon previously derepressed by a severe histidine limitation in strains with a wild-type or feedback-hypersensitive first enzyme but not in feedback-resistant mutants. Since experiments reported here clearly demonstrate that thiazolealanine is not transferred to tRNAHis, it is proposed that this "transient repression" is effected through the interaction of thiazolealanine with the feedback site of the enzyme. Experiments in the presence of rifampin indicate that this thiazolealanine-mediated effect is exerted at the level of translation. We conclude that histidine (free), in addition to forming co-repressor, also represses the operon at the level of translation through feedback interaction with the first enzyme of the pathway (adenosine 5'-triphosphate phosphoribosyltransferase). Rates of derepression in feedback-resistant strains are roughly half of those observed in controls, suggesting a positive role played by a first enzyme with a normal but unoccupied feedback site. Some feedback-resistant mutants, in contrast to the wild type, were unable to exhibit derepression under histidine limitation caused by aminotriazole.     

Hydroxyurea-resistant vaccinia virus: overproduction of ribonucleotide reductase.

Repeated passages of vaccinia virus in increasing concentrations of hydroxyurea followed by plaque purification resulted in the isolation of variants capable of growth in 5 mM hydroxyurea, a drug concentration which inhibited the reproduction of wild-type vaccinia virus 1,000-fold. Analyses of viral protein synthesis by using [35S]methionine pulse-labeling at intervals throughout the infection cycle revealed that all isolates overproduced a 34,000-molecular-weight (MW) early polypeptide. Measurement of ribonucleoside-diphosphate reductase (EC 1.17.4.1) activity after infection indicated that 4- to 10-fold more activity was induced by hydroxyurea-resistant viruses than by the wild-type virus. A two-step partial purification which yielded greater than 90% of the induced ribonucleotide reductase activity in the fraction obtained by 35% saturation with ammonium sulfate resulted in a substantial enrichment for the 34,000-MW protein from extracts of wild-type and hydroxyurea-resistant-virus-infected, but not mock-infected, cells. In the presence of the drug, the isolates incorporated [3H]thymidine into DNA earlier and at a rate substantially greater than that of the wild type, although the onset of DNA synthesis was delayed in both cases. In the absence of the drug, the attainment of a maximum viral DNA synthesis rate was accelerated after infection by drug-resistant isolates. The drug resistance trait was markedly unstable in all isolates. In the absence of selective pressure, plaque-purified isolates readily segregated progeny that displayed a wide range of resistance phenotypes. The results of this study indicate that vaccinia virus encodes a subunit of ribonucleotide reductase which is a 34,000-MW early protein whose overproduction confers hydroxyurea resistance on reproducing viruses.