Use of EPR spectroscopy to check the changes in organism radioresistance. Experimental results

The responses of dNTP, DNA, and protein synthesis systems in blood-forming organs of animals (dogs, mice) as well as changes in blood Fe³⁺-transferrin (Fe-TF) and Cu²⁺-ceruloplasmin (Cu-CP) pools upon γ-irradiation and administration of radioprotectors have been studied. It is shown that changes in Fe-TF and Cu-CP pools are indices of change in body radioresistance and are reliably checked by the EPR technique. An increase in the Fe-TF pool promotes the activation of synthesis of dNTP, DNA, and Fe³⁺-containing proteins, which are essential for repair efficiency during early postirradiation time as well as for the development of compensatory-restorative reactions of cellular systems; i.e., they are responsible for body resistance to DNA-damaging factors. It is important that the intensity of responses depends on the initial state of the organism. Thus, dogs with initial individual characteristics of blood typical of “depressed” or “activated” states had abnormally high responses to irradiation at low doses of 0.25 and 0.5 Gy. This fact is important for estimating the consequences of prolonged low-dose irradiation for the human population. It has been shown that radioprotectors efficient in the survival test activate the synthesis of dNTP, DNA, and proteins in organs. The intensity of dNTP synthesis and the time when dNTP pools become maximal determine the efficiency of protectors and the time of irradiation after their administration.     

The activation of ribonucleotide reductase in animal organs as the cellular response against the treatment with DNA-damaging factors and the influence of radioprotectors on this effect

Cellular requirements for deoxyribonucleotide (dNTP) pools during DNA synthesis are related to ensuring of the accuracy of DNA copying during replication and repair. This paper covers some problems on the reactions of dNTP synthesis system in organs of animals against the treatment with DNA-damaging agents. Ribonucleoside diphosphate reductase (NDPR) is the key enzyme for the synthesis of dNTP, since it catalyses the reductive conversion of ribonucleotides to deoxyribonucleotides. The results obtained show that the rapid and transient increase in NDPR activity in animal organs occurs as cellular response against the treatment with DNA-damaging agents (SOS-type activation). We have also found the intensive radioprotector-stimulated activation of deoxyribonucleotide synthesis as well as DNA and protein synthesis in mice organs within 3 days after the administration of two radioprotectors, indralin and indometaphen, that provide the high animal survival. Our studies suggest that these effects are the most important steps in the protective mechanism of the radioprotectors and are responsible for the high animal survival.     

Activation of Deoxyribonucleotide Synthesis by Radioprotectants and Antioxidants as a Key Stage in Formation of Body Resistance to DNA-Damaging Factors

The responses of the systems of synthesis of deoxyribonucleotides (dNTPs), DNA, and proteins in hematopoietic organs and liver of animals to γ-radiation, administration of radioprotectants and antioxidants as well as the dependence of these responses on the doses of radiation and drugs were studied. Radioprotectants of acute (indralin) and durable effects (indomethaphen) as well as natural α₂-tocopherol) and synthetic antioxidants (ionol or 2,6-di-tert-butyl-4-methylphenol) efficient in survival test were used. Three stages could be recognized in the standard unspecific response of the studied systems to radiation: (1) immediate increase in ribonucleotide reductase activity in the tissues within the first 30 min as a part of the integrated SOS response to DNA damage, which activates dNTP synthesis; (2) inhibition of the synthesis of dNTPs, DNA, and proteins; and (3) restoring ribonucleotide reductase activity and integral increase in the production of dNTPs, DNA, and total protein, which is essential for the development of compensatory and restorative responses of the organism. The radioprotectants significantly increased ribonucleotide reductase activity, which increased intracellular concentrations of the four dNTP types in organs during radiation exposure and three following days. Within this period, ribonucleotide reductase activity was inhibited by 40–50% in animals not treated with radioprotectants as compared to control. Balanced high pools of dNTPs in the organs of radioprotectant-treated animals provided for high-performance repair of DNA damage. The radioprotectant-induced activation of dNTP synthesis during the development of compensatory and restorative responses provides for an earlier restoration of the cellular composition and functioning of the organs. Antioxidants stimulated the synthesis of dNTPs, DNA, and proteins in animal tissues in a strict dose interval. Their effect on the studied syntheses was dose-dependent: single or multiple long-term administration of high antioxidant doses inhibited synthesis of dNTPs, DNA, and proteins. Radioprotectants and antioxidants affected the pool of blood protein Fe³⁺-transferrin controlling the synthesis of iron-containing ribonucleotide reductase activity in hematopoietic organs, and hence, the iron-dependent stage in DNA synthesis—dNTP synthesis. Activation of protein synthesis in organs by the studied substances increased the pools of Fe³⁺-transferrin and Cu²⁺-ceruloplasmin in the blood, which activated dNTP and DNA synthesis. Activated synthesis of dNTP, DNA, and proteins in the organs and increased pools of studied plasma proteins underlay the formation of body resistance to DNA-damaging factors.__________Translated from Izvestiya Akademii Nauk, Seriya Biologicheskaya, No. 4, 2005, pp. 401–422.Original Russian Text Copyright © 2005 by Sharygin, Pulatova, Shlyakova, Mitrokhin, Todorov.     

Regulation of mammalian ribonucleotide reduction and dNTP pools after DNA damage and in resting cells

Ribonucleotide reductase (RNR) provides the cell with a balanced supply of deoxyribonucleoside triphosphates (dNTP) for DNA synthesis. In budding yeast DNA damage leads to an up-regulation of RNR activity and an increase in dNTP pools, which are essential for survival. Mammalian cells contain three non-identical subunits of RNR; that is, one homodimeric large subunit, R1, carrying the catalytic site and two variants of the homodimeric small subunit, R2 and the p53-inducible p53R2, each containing a tyrosyl free radical essential for catalysis. S-phase-specific DNA replication is supported by an RNR consisting of the R1 and R2 subunits. In contrast, DNA damage induces expression of the R1 and the p53R2 subunits. We now show that neither logarithmically growing nor G(o)/G1-synchronized mammalian cells show any major increase in their dNTP pools after DNA damage. However, non-dividing fibroblasts expressing the p53R2 protein, but not the R2 protein, have reduced dNTP levels if exposed to the RNR-specific inhibitor hydroxyurea, strongly indicating that there is ribonucleotide reduction in resting cells. The slow, 4-fold increase in p53R2 protein expression after DNA damage results in a less than 2-fold increase in the dNTP pools in G(o)/G1 cells, where the pools are about 5% that of the size of the pools in S-phase cells. Our results emphasize the importance of the low constitutive levels of p53R2 in mammalian cells, which together with low levels of R1 protein may be essential for the supply of dNTPs for basal levels of DNA repair and mitochondrial DNA synthesis in G(o)/G1 cells.     

Pool sizes of the deoxynucleoside triphosphates in the sea urchin egg and developing embryo.

The four deoxynucleoside triphosphate pools in unfertilized eggs of L. pictus and S. purpuratus were measured and found to be very large, ranging from 10^?3 to 10^?2 pmoles per egg. The high levels of the individual dNTP pools are sufficient for one to eight rounds of DNA synthesis. During the first division cycle these pools fluctuate with the highest levels being attained prior to DNA synthesis. The pools then decrease just preceding or during the S period. There is a large reduction in the total cellular dNTP in later stages of development when DNA synthesis is reduced relative to the cleavage stages.     

Synthesis of Mitochondrial DNA Precursors during Myogenesis,an Analysis in Purified C2C12 Myotubes

During myogenesis, myoblasts fuse into multinucleated myotubes that acquire the contractile fibrils and accessory structures typical of striated skeletal muscle fibers. To support the high energy requirements of muscle contraction, myogenesis entails an increase in mitochondrial (mt) mass with stimulation of mtDNA synthesis and consumption of DNA precursors (dNTPs). Myotubes are quiescent cells and as such down-regulate dNTP production despite a high demand for dNTPs. Although myogenesis has been studied extensively, changes in dNTP metabolism have not been examined specifically. In differentiating cultures of C2C12 myoblasts and purified myotubes, we analyzed expression and activities of enzymes of dNTP biosynthesis, dNTP pools, and the expansion of mtDNA. Myotubes exibited pronounced post-mitotic modifications of dNTP synthesis with a particularly marked down-regulation of de novo thymidylate synthesis. Expression profiling revealed the same pattern of enzyme down-regulation in adult murine muscles. The mtDNA increased steadily after myoblast fusion, turning over rapidly, as revealed after treatment with ethidium bromide. We individually down-regulated p53R2 ribonucleotide reductase, thymidine kinase 2, and deoxyguanosine kinase by siRNA transfection to examine how a further reduction of these synthetic enzymes impacted myotube development. Silencing of p53R2 had little effect, but silencing of either mt kinase caused 50% mtDNA depletion and an unexpected decrease of all four dNTP pools independently of the kinase specificity. We suggest that during development of myotubes the shortage of even a single dNTP may affect all four pools through dysregulation of ribonucleotide reduction and/or dissipation of the non-limiting dNTPs during unproductive elongation of new DNA chains.     

Deoxyribonucleoside triphosphate pools in regenerating rat liver: effect of hydroxyurea and exogenous deoxypyrimidines

Hydroxyurea (HU) causes inhibition of DNA synthesis in regenerating rat liver due to an inhibition of the ribonucleotide reductase. We studied the consequences of a continuous HU infusion for deoxyribonucleoside triphosphate (dNTP) pools in the liver after partial hepatectomy and tried to modify imbalances by application of deoxyribonucleosides in vivo. In normal liver, an intracellular concentration of 0.16, 0.84, 0.33 and 0.27 pmol/micrograms DNA was observed for dATP, dCTP, dGTP and dTTP, respectively. In regenerating liver the dNTP pools show minor changes until 18 h after partial hepatectomy. During and after a continuous HU infusion 14--24 h after partial hepatectomy, the intracellular dNTP pools change considerably. At 19.5 h after partial hepatectomy, 5.5 h after the start of HU infusion, and at 25 h after partial hepatectomy, 1 h after termination of HU infusion, the dTTP pool was more than 10-times, and the dGTP pool about 2-times higher than in controls, while the dATP and dCTP pools remain relatively unchanged. Simultaneous infusion of HU and deoxythymidine (dThd) 14--25 h after partial hepatectomy results in a further increase of the dTTP pool during and after HU infusion. Administration of deoxycytidine (dCyd) leads to a moderate increase of the dCTP pool and a weak decrease of the dTTP pool during HU infusion. The combined application of dCyd and dThd after HU infusion had similar effects on dNTP pools as observed with dThd alone. These results show that intracellular pools of dNTPs in hepatocytes can be altered by exogenous factors in a controlled pattern. This system can be used as a model for studying the implications of induced dNTP pool dysbalances for the initiation of liver carcinogenesis by mutagenic chemicals.     

dNTP pools determine fork progression and origin usage under replication stress

Intracellular deoxyribonucleoside triphosphate (dNTP) pools must be tightly regulated to preserve genome integrity. Indeed, alterations in dNTP pools are associated with increased mutagenesis, genomic instability and tumourigenesis. However, the mechanisms by which altered or imbalanced dNTP pools affect DNA synthesis remain poorly understood. Here, we show that changes in intracellular dNTP levels affect replication dynamics in budding yeast in different ways. Upregulation of the activity of ribonucleotide reductase (RNR) increases elongation, indicating that dNTP pools are limiting for normal DNA replication. In contrast, inhibition of RNR activity with hydroxyurea (HU) induces a sharp transition to a slow-replication mode within minutes after S-phase entry. Upregulation of RNR activity delays this transition and modulates both fork speed and origin usage under replication stress. Interestingly, we also observed that chromosomal instability (CIN) mutants have increased dNTP pools and show enhanced DNA synthesis in the presence of HU. Since upregulation of RNR promotes fork progression in the presence of DNA lesions, we propose that CIN mutants adapt to chronic replication stress by upregulating dNTP pools.     

Mitochondria as determinant of nucleotide pools and chromosomal stability

Mitochondrial function plays an important role in multiple human diseases and mutations in the mitochondrial genome have been detected in nearly every type of cancer investigated to date. However, the mechanism underlying the interrelation is unknown. We used human cell lines depleted of mitochondrial DNA as models and analyzed the outcome of mitochondrial dysfunction on major cellular repair activities. We show that the deoxyribonucleoside triphosphate (dNTP) pools are affected, most prominently we detect a 3-fold reduction of the dTTP pool when normalized to the number of cells in S-phase. It is known that imbalanced dNTP pools are mutagenic and in accordance, we show that mitochondrial dysfunction results in chromosomal instability, which can explain its role in tumor development. We did not find any straightforward correlation between ATP levels and dNTP pools in cells with defective mitochondrial activity. Our results suggest that mitochondria are central players in maintaining genomic stability and in controlling essential nuclear processes such as upholding a balanced supply of nucleotides.     

The role of mitochondrial dNTP levels in cells with reduced TK2 activity

Both the nuclear and mitochondrial DNA (mtDNA) depend on separate balanced pools of dNTPs for correct function of DNA replication and repair of DNA damage. Import of dNTPs from the cytosolic compartment to the mitochondria has been suggested to have the potential of rectifying a mitochondrial dNTP imbalance. Reduced TK2 activity has been demonstrated to result in mitochondrial dNTP imbalance and consequently mutations of mtDNA in non-dividing cells. In this study, the consequences of a reduced thymidine kinase 2 (TK2) activity were measured in proliferating HeLa cells, on both whole-cell as well as mitochondrial dNTP levels. With the exception of increased mitochondrial dCTP level no significant difference was found in cells with reduced TK2 activity. Our results suggest that import of cytosolic dNTPs in mitochondria of proliferating cells can compensate a TK2 induced imbalance of the mitochondrial dNTP pool.     

The Role of Mitochondrial dNTP Levels in Cells with Reduced TK2 Activity

Both the nuclear and mitochondrial DNA (mtDNA) depend on separate balanced pools of dNTPs for correct function of DNA replication and repair of DNA damage. Import of dNTPs from the cytosolic compartment to the mitochondria has been suggested to have the potential of rectifying a mitochondrial dNTP imbalance. Reduced TK2 activity has been demonstrated to result in mitochondrial dNTP imbalance and consequently mutations of mtDNA in non-dividing cells. In this study, the consequences of a reduced thymidine kinase 2 (TK2) activity were measured in proliferating HeLa cells, on both whole-cell as well as mitochondrial dNTP levels. With the exception of increased mitochondrial dCTP level no significant difference was found in cells with reduced TK2 activity. Our results suggest that import of cytosolic dNTPs in mitochondria of proliferating cells can compensate a TK2 induced imbalance of the mitochondrial dNTP pool.     

Consequences of the depletion of cellular deoxynucleoside triphosphate pools on the excision-repair process in cultured human fibroblasts

DNA excision repair requires the insertion of bases into gaps in the DNA which arise during the removal of damaged sites from the chromatin. The number of bases required is dependent on the amount of damage and the patch size of repair in response to the particular type of damage. In cells in which the ability to synthesize deoxynucleoside triphosphates (dNTPs) has been compromised, repair cannot proceed to completion following doses of DNA-damaging agents which induce repair that requires greater than the steady-state level of dNTPs. Repair is thus not equally sensitive to depletion of dNTPs when measured in rapidly cycling cells with relatively high dNTP pools or in non-cycling cells with significantly smaller pools. Critical depletion of dNTPs results in the production of long-lived DNA strand breaks at repairing sites and reduction in the number of sites initiating repair. On the other hand, elevation of dNTP pools to 10–50-fold normal levels did not inhibit repair. This indicates that dNTP pool depletion but not general pool-imbalance affects DNA excision repair.     

Time- and dose-dependent post-irradiation changes of Fe3+-transferrin and Cu2+-ceruloplasmin pools in blood, their influence on ribonucleotide reductase activity in animal tissues and the effects of radioprotectors

The time- and dose-dependent changes of Fe(3+)-transferrin (Fe(3+)-TF) and Cu(2+)-ceruloplasmin (Cu(2+)-CP) pools, of superoxide dismutase activity and the inhibitory activity of alpha 2-macroglobulin in blood as well as changes in synthesis rates of deoxyribonucleotides (dNTP), DNA and proteins in organs (spleen, liver, bone marrow, thymus) of mice and dogs given total body irradiation have been studied using of ESR spectroscopy, radioisotope techniques and biochemical determination of enzymatic activity. The experimental data have allowed us to reveal the sequence of organism's response reactions against irradiation and their modifications by radioprotectors. Changes in blood Fe(3+)-TF pool is one of the most informative, highly radiosensitive and rapidly reactive marker against irradiation and drug administrations. This irontransport protein controls a rate-limiting iron-dependent stage for DNA synthesis--the synthesis of dNTP, catalyzed by iron-containing ribonucleotide reductase (Fe(3+)-RR). It has been shown that time-dependent post-irradiation changes of Fe(3+)-TP pool in blood are characterized by three distinct stages: 1) the prompt increase of pool (SOS-type response) playing the important role in protecting of cell's genetic apparatus from damage; 2) the decrease of its pool within 3-18 h after irradiation resulting in the loss of Fe(3+)-RR activity in tissues of blood-forming organs that make more stronger radiation-induced damage; 3) the following phase-dependent increase in Fe(3+)-TF pool at the 2-nd, 6th, 10-17th days after irradiation due to an increase in transferrin synthesis. This increase may be considered as compensatory reaction of blood-forming organs directed at restoring blood and organ's cells. The time-dependent courses of the reactions are independent from radiation doses indicating to the universal and nonspecific response of organism against irradiation. But, the intensity of this compensatory-adaptive response at 2-nd and 6th days grows with increasing radiation dose up to lethal that, and organism's response becomes abnormal and physiologically hypertrophic. The prolonged "stressful syndrome of biochemical tense state" should be attributed to negative effects for organism, since it may result in the failure of compensatory adaptive organism's reactions and animal killing. The radioprotectors ward off the appearance of this dangerous state. Dogs with initial individual characteristics of blood which were typical for "suppressed" or "activated" states had abnormal response against irradiation by low doses 0.25 or 0.5 Gy. In these cases the intensity of response reactions of organism was essentially increased and markedly deviated from linear dose dependence. The phase-dependent increase of Fe(3+)-TF pool in blood in post-irradiation time resulted to the increase of Fe(3+)-RR activity in blood-forming organs. The key event ensuring the development of compensatory adaptive reactions is the increase of capacity of protein-synthesizing apparatus, the activation of biosynthesis of dNTP and DNA against the treatment with damaging factors.     

DNA repair after ultraviolet irradiation of ICR 2A frog cells. Pyrimidine dimers are long acting blocks to nascent DNA synthesis.

The ability of ICR 2A frog cells to repair DNA damage induced by ultraviolet irradiation was examined. These cells are capable of photoreactivation but are nearly totally deficient in excision repair. They have the ability to convert the small molecule weight DNA made after irradiation into large molecules but do not show an enhancement in this process when the UV dose is delivered in two separate exposures separated by a 3- or 24-h incubation. Total DNA synthesis is depressed and low molecular weight DNA continues to be synthesized during pulse-labeling as long as 48 h after irradiation. The effects of pyrimidine dimer removal through exposure of UV irradiated cells to photoreactivating light indicate that dimers act as the critical lesions blocking DNA synthesis.     

Mitochondrial purine and pyrimidine metabolism and beyond

ABSTRACT

Carefully balanced deoxynucleoside triphosphate (dNTP) pools are essential for both nuclear and mitochondrial genome replication and repair. Two synthetic pathways operate in cells to produce dNTPs, e.g., the de novo and the salvage pathways. The key regulatory enzymes for de novo synthesis are ribonucleotide reductase (RNR) and thymidylate synthase (TS), and this process is considered to be cytosolic. The salvage pathway operates both in the cytosol (TK1 and dCK) and the mitochondria (TK2 and dGK). Mitochondrial dNTP pools are separated from the cytosolic ones owing to the double membrane structure of the mitochondria, and are formed by the salvage enzymes TK2 and dGK together with NMPKs and NDPK in postmitotic tissues, while in proliferating cells the mitochondrial dNTPs are mainly imported from the cytosol produced by the cytosolic pathways. Imbalanced mitochondrial dNTP pools lead to mtDNA depletion and/or deletions resulting in serious mitochondrial diseases. The mtDNA depletion syndrome is caused by deficiencies not only in enzymes in dNTP synthesis (TK2, dGK, p53R2, and TP) and mtDNA replication (mtDNA polymerase and twinkle helicase), but also in enzymes in other metabolic pathways such as SUCLA2 and SUCLG1, ABAT and MPV17. Basic questions are why defects in these enzymes affect dNTP synthesis and how important is mitochondrial nucleotide synthesis in the whole cell/organism perspective? This review will focus on recent studies on purine and pyrimidine metabolism, which have revealed several important links that connect mitochondrial nucleotide metabolism with amino acids, glucose, and fatty acid metabolism.     

Mitochondrial deoxyribonucleoside triphosphate pools in thymidine kinase 2 deficiency

Deficiency of mitochondrial thymidine kinase (TK2) is associated with mitochondrial DNA (mtDNA) depletion and manifests by severe skeletal myopathy in infancy. In order to elucidate the pathophysiology of this condition, mitochondrial deoxyribonucleoside triphosphate (dNTP) pools were determined in patients' fibroblasts. Despite normal mtDNA content and cytochrome c oxidase (COX) activity, mitochondrial dNTP pools were imbalanced. Specifically, deoxythymidine triphosphate (dTTP) content was markedly decreased, resulting in reduced dTTP:deoxycytidine triphosphate ratio. These findings underline the importance of balanced mitochondrial dNTP pools for mtDNA synthesis and may serve as the basis for future therapeutic interventions.     

Kinetics of UV-induced changes in deoxynucleoside triphosphate pools in Chinese hamster ovary cells and their effect on measurements of DNA synthesis

Measurements of dNTP pools following exposure of Chinese hamster ovary cells to ultraviolet radiation reveals a rapid accumulation of cellular dTTP and a rapid loss of cellular dCTP. Exposure to 3-, 10- or 20 Jm-2 results in a 3-, 4- or 5.4-fold increase in cellular dTTP, respectively, within the first 10 min after exposure. dTTP levels then decrease noticeably, approaching the control value 3 to 5 hr later. In contrast, dCTP levels decrease rapidly within 10 min after exposure, ultimately to 1/10 that observed in the unirradiated control population. Recovery to normal dCTP levels is slow, taking in excess of 12 hr. No change in dATP is observed for 1-2 hr; subsequently, a moderate decrease in dATP levels occurs which is then followed by recovery, beginning 8 hr after irradiation. These results contrast with changes in dNTP pools observed in Chinese hamster V-79 cells exposed to mutagens. Measurements of rates of DNA synthesis by pulse-labeling cells with [3H]thymidine are also apparently affected by UV-induced transient deviations in the endogenous radiospecific activity of the labeled precursor.     

Deoxynucleotide pools and DNA synthesis in resting and PHA-stimulated human lymphocytes treated with mutagens.

In resting and PHA-stimulated PBL treated with uv light or MMS we measured the sizes of the dTTP and dATP pools and the variation of ATP content taken as an indicator of cytotoxicity. The effects on DNA synthesis were examined by measuring DNA repair (unscheduled DNA synthesis) in resting PBL and the inhibition of DNA replication in stimulated PBL. While both treatments affected DNA synthesis, only MMS perturbed dNTP pools and decreased the intracellular concentration of ATP. All the effects were more evident in cycling than in resting lymphocytes.     

Cyclin F-mediated degradation of ribonucleotide reductase M2 controls genome integrity and DNA repair

F-box proteins are the substrate binding subunits of SCF (Skp1-Cul1-F-box protein) ubiquitin ligase complexes. Using affinity purifications and mass spectrometry, we identified RRM2 (the ribonucleotide reductase family member 2) as an interactor of the F-box protein cyclin F. Ribonucleotide reductase (RNR) catalyzes the conversion of ribonucleotides to deoxyribonucleotides (dNTPs), which are necessary for both replicative and repair DNA synthesis. We?found that, during G2, following CDK-mediated phosphorylation of Thr33, RRM2 is degraded via SCF(cyclin F) to maintain balanced dNTP pools and genome stability. After DNA damage, cyclin F is downregulated in an ATR-dependent manner to allow accumulation of RRM2. Defective elimination of cyclin F delays DNA repair and sensitizes cells to DNA damage, a phenotype that is reverted by expressing a nondegradable RRM2 mutant. In summary, we have identified a biochemical pathway that controls the abundance of dNTPs and ensures efficient DNA repair in response to genotoxic stress.