Inhibitor Of DNA Polymerase Beta Research Articles

Phase 1/2 trial of FF-10502-01, a pyrimidine antimetabolite, in patients with advanced cholangiocarcinoma and solid tumors.

3008 Background: FF10502 is a synthetic pyrimidine nucleoside similar to gemcitabine (gem) with a sulfur in the pentose ring. FF10502 is a more potent inhibitor of DNA polymerase Beta than gem with activity in gem resistant patient (pt) derived xenograft models. FF10502 is avidly taken up into DNA and has greater activity against quiescent cells than gem. Methods: Pts > 18 years old with advanced disease who had progressed on standard of care were enrolled into 9 dose levels to determine maximum tolerated dose (MTD) and dose limiting toxicities (DLTs) and subsequently into two expansion cohorts: biliary or solid tumors (ST). FF10502 at doses of 8 to 135 mg/m2 was administered iv on days 1, 8, 15 of a 28-day cycle until progressive disease or toxicity. PK/PD evaluations were performed on all pts. Response was assessed by RECIST 1.1. Results: 76 pts were treated; 35 pts in dose escalation, including 7 cholangiocarcinoma pts. MTD was 90 mg/m2. DLTs included 2 pts with hypotension at 135mg/m2 (G3 and G4) and 1 pt each with G3 fatigue and G2 rash at 100mg/m2. In expansion, 19 cholangiocarcinoma, 3 gallbladder and 19 other pts (13 pancreatic, 2 urothelial, and 1 each ovarian, prostate, NSCLC, SCCHN each) were treated. 1 pt with prior rituximab for ITP developed PML. G3 treatment-related low platelets occurred in 3 pts at 90mg/m2 after cycle 1. There were 5 partial responses (PRs), including 4 pts who had progressed on prior gemcitabine: 3 of 26 pts with cholangiocarcinoma, 1 urothelial carcinoma and 1 chondroblastic osteosarcoma. 7 cholangiocarcinoma pts stayed on therapy for ≥6 months. FF10502 incorporation intoperipheral blood cellular DNA was seen, andbiomarkeranalysisdata to identify pts with higher potential for clinical response will be presented. Conclusions: FF10502 is well tolerated in pts with advanced cancers refractory to standard therapies. Early signals of efficacy warranting further exploration were seen in heavily pretreated cholangiocarcinoma pts (median: 4 prior therapies). Patient selection based on differential effects of FF10502 on DNA polymerases will be explored. Clinical trial information: NCT02661542.

Identification of 5-Methoxyflavone as a Novel DNA Polymerase-Beta Inhibitor and Neuroprotective Agent against Beta-Amyloid Toxicity.

Cell-cycle reactivation is a core feature of degenerating neurons in Alzheimer's disease (AD) and Parkinson's disease (PD). A variety of stressors, including β-amyloid (Aβ) in the case of AD, can force neurons to leave quiescence and to initiate an ectopic DNA replication process, leading to neuronal death rather than division. As the primary polymerase (pol) involved in neuronal DNA replication, DNA pol-β contributes to neuronal death, and DNA pol-β inhibitors may prove to be effective neuroprotective agents. Currently, specific and highly active DNA pol-β inhibitors are lacking. Nine putative DNA pol-β inhibitors were identified in silico by querying the ZINC database, containing more than 35 million purchasable compounds. Following pharmacological evaluation, only 5-methoxyflavone (1) was validated as an inhibitor of DNA pol-β activity. Cultured primary neurons are a useful model to investigate the neuroprotective effects of potential DNA pol-β inhibitors, since these neurons undergo DNA replication and death when treated with Aβ. Consistent with the inhibition of DNA pol-β, 5-methoxyflavone (1) reduced the number of S-phase neurons and the ensuing apoptotic death triggered by Aβ. 5-Methoxyflavone (1) is the first flavonoid compound able to halt neurodegeneration via a definite molecular mechanism rather than through general antioxidant and anti-inflammatory properties.

Evaluation of Novel DNA Polymerase Beta Inhibitors as Potential Radiosensitizers of Prostate Cancer Cells

DNA polymerase beta (Pol β) is an essential enzyme that plays a critical role in the repair of the DNA base damage and single stranded breaks (SSBs) commonly produced by ionizing radiation (IR). If left unrepaired clusters of such lesions can result in double strand breaks (DSBs), the major cause of cell death due to IR. Inhibitors of poly ADP ribose polymerases (PARP) another key family of proteins involved in the repair of SSBs have become important drugs in treatment of many cancers when combined with DNA damaging agents such as radiation or alkylating agents.

(+)-Myristinins A and D from Knema elegans, which Inhibit DNA Polymerase β and Cleave DNA

A survey of crude plant extracts for DNA polymerase beta inhibitors resulted in the identification of a methyl ethyl ketone extract prepared from Knema elegans that strongly inhibited the enzyme. Subsequent bioassay-guided fractionation of the extract, using an assay to monitor the activity of DNA polymerase beta, led to the isolation of two potent inhibitors, (+)-myristinins A (1) and D (2), which are known flavans having unusual structures. (+)-Myristinins A and D exhibited IC50 values of 12 and 4.3 microM, respectively, as inhibitors of DNA polymerase beta in the presence of bovine serum albumin (BSA), and 2.7 and 1.2 microM in the absence of BSA. As such, they are the most potent DNA polymerase beta inhibitors reported to date. Compounds 1 and 2 potentiated the cytotoxicity of bleomycin toward cultured P388D1 cells, reducing the number of viable cells by at least 30% when employed at 9 microM concentration for 6 h in the presence of an otherwise nontoxic concentration of bleomycin (75 nM). Principles 1 and 2 also induced strong Cu2+-dependent DNA strand scission in a DNA cleavage assay. Accordingly, 1 and 2 exhibit two activities, namely, DNA polymerase beta inhibition and DNA damage.

(+)-Myristinin A, a Naturally Occurring DNA Polymerase β Inhibitor and Potent DNA-Damaging Agent

The first stereoselective total synthesis of the naturally occurring flavan myristinin A has been accomplished, as well as its biochemical evaluation. This synthesis verified the structural assignment and allowed for the determination of the absolute stereochemistry. Myristinin A exhibits biochemical activity both as a potent DNA-damaging agent and DNA polymerase beta inhibitor. Relaxation of supercoiled plasmid DNA was observed at picomolar concentrations, in addition to inhibition of polymerase beta at low micromolar concentrations.

Triterpenoid total synthesis. Synthesis and absolute configuration of mispyric acid.

The first synthesis of mispyric acid (1), an inhibitor of DNA polymerase beta with a novel triterpene skeleton, was achieved by starting from isoprene (2), geraniol (6) and 1,5-dimethoxy-1,4-cyclohexadiene (14). The absolute configuration of the naturally occurring 1 was determined as 2S,4S.

Use of pi-allyltricarbonyliron lactone complexes in the synthesis of taurospongin A: a potent inhibitor of DNA polymerase beta and HIV revers transcriptase.

The total synthesis of taurospongin A by two new approaches has been achieved where pi-allyltricarbonyliron lactone complexes have been used to control highly stereoselective additions of the nucleophiles to a carbonyl unit located in the side chain of these complexes.

Endoreduplication is not inhibited but induced by aphidicolin in cultured cells of tobacco.

Endoreduplication is a common process in plants that allows cells to increase their DNA content. In the tobacco cell cultures studied in this work it can be induced by simple hormone deprivation. Mesophyll protoplast-derived cells cultured in the presence of NAA (auxin) and BAP (cytokinin) keep on dividing, while elongation and concomitant DNA endoreduplication are induced and maintained in a medium containing only NAA. If aphidicolin is given to the two types of culture, no effect is observed on elongating, endoreduplicating cells. However, the cells programmed for division switch to elongation and DNA endoreduplication. Thus aphidicolin, an inhibitor of the replicative DNA polymerases, alpha and delta, does not inhibit endoreduplication, and furthermore actually induces it when the mitotic cell cycle is blocked. DNA duplication and cell growth can only be completely blocked if ddTTP, an inhibitor of DNA polymerase-beta, is given together with aphidicolin. This result implies that an aphidicolin-resistant DNA polymerase, such as the repair-associated DNA polymerase-beta, can mediate DNA synthesis during endoreduplication and can substitute for polymerases-alpha and -delta when the latter are inhibited. Similar results are obtained in cultures of the BY-2 cell line by withdrawing auxins from the culture medium. In this cell line endoreduplication is induced only in a small proportion of the cells. A greater proportion of the cells are blocked in the G(2) phase of the cell cycle.

Three-dimensional structural model analysis of the binding site of lithocholic acid, an inhibitor of DNA polymerase beta and DNA topoisomerase II.

The molecular action of lithocholic acid (LCA), a selective inhibitor of mammalian DNA polymerase beta (pol beta), was investigated. We found that LCA could also strongly inhibit the activity of human DNA topoisomerase II (topo II). No other DNA metabolic enzymes tested were affected by LCA. Therefore, LCA should be classified as an inhibitor of both pol beta and topo II. Here, we report the molecular interaction of LCA with pol beta and topo II. By three-dimensional structural model analysis and by comparison with the spatial positioning of specific amino acids binding to LCA on pol beta (Lys60, Leu77, and Thr79), we obtained supplementary information that allowed us to build a structural model of topo II. Modeling analysis revealed that the LCA-interaction interface in both enzymes has a pocket comprised of three amino acids in common, which binds to the LCA molecule. In topo II, the three amino acid residues were Lys720, Leu760, and Thr791. These results suggested that the LCA binding domains of pol beta and topo II are three-dimensionally very similar.

Naturally Occurring Alkylresorcinols That Mediate DNA Damage and Inhibit Its Repair

A study of di- and trihydroxyalkylbenzenes and bis(dihydroxyalkylbenzenes) revealed that several compounds were capable of both mediating Cu(2+)-dependent DNA cleavage and strongly inhibiting DNA polymerase beta. The most potent DNA polymerase beta inhibitors were bis(dihydroxyalkylbenzenes) 5 and 6; compounds 3 and 4 were also reasonably potent. The length of the alkyl substituent was found to be a critical element for DNA polymerase beta inhibition, since compounds 1 and 2 had shorter substituents than 3 and were completely inactive. Lineweaver-Burk plots revealed that 3, 4, and 6 exhibited mixed inhibition of DNA polymerase beta with respect to both activated DNA and dTTP. Unsaturated bis(dihydroxyalkylbenzene) 5 was a pure noncompetitive inhibitor with respect to both substrates and associated avidly with the enzyme whether or not it was in complex with its substrate(s). Copper(II)-mediated DNA cleavage was the most pronounced for the trihydroxyalkylbenzene 3, consistent with an earlier report [Singh, U. S., Scannell, R. T., An, H., Carter, B. J., and Hecht, S. M. (1995) J. Am. Chem. Soc. 117, 12691-12699]. Unsaturated bis(dihydroxyalkylbenzene) 5 was the next most active DNA cleaving agent, followed by the dihydroxyalkylbenzene 4. The saturated bis(dihydroxyalkylbenzene) (6) did not cleave DNA well in a cell-free system under the conditions studied but nonetheless potentiated the effects of bleomycin to the greatest extent in cell culture studies. Interestingly, compound 5 produced a reduction in the numbers of viable cells when incubated in the presence of bleomycin and a further reduction in the numbers of viable cells in the presence of both bleomycin and Cu(2+). The same effect was noted to a lesser extent for compound 3 but not for 4 or 6.

DNA polymerase beta inhibitors from Baeckea gunniana.

Crude plant extracts were surveyed for their ability to inhibit DNA polymerase beta. A methyl ethyl ketone extract prepared from Baeckea gunniana was identified as a potent inhibitor of the enzyme. Bioassay-guided fractionation of the extract, using an assay to monitor the inhibitory potential of individual fractions toward DNA polymerase beta, led to the isolation of four active ursane and oleanane triterpenoids (1-4). Inhibitory principle 1 is a new natural product, and 2 is a novel compound. Their structures were established as 3 beta-hydroxyrus-12,19(29)-dien-28-oic acid (1) and 3 beta-hydroxyrus-18,20(30)-dien-28-oic acid (2) by spectroscopic analysis and by comparison with the data for the structurally related compound ursolic acid (4). Also isolated as a DNA polymerase beta inhibitor was oleanolic acid (3). Compounds 1-4 had IC50 values of 5.3-8.5 microM as inhibitors of polymerase beta in the presence of bovine serum albumin (BSA) and 2.5-4.8 microM in the absence of BSA.

DNA polymerase beta inhibitors from Sandoricum koetjape.

Bioassay-guided fractionation of Sandoricum koetjape using an assay sensitive to DNA polymerase beta inhibition led to the isolation of three active compounds (1-3) having IC(50) values from 20 to 36 microM. Derivatives 5-14 were prepared from compounds 1 and 2; derivatives 11, 12, and 13 showed activity against DNA polymerase beta with IC(50) values ranging from 16 to 36 microM.

KGF facilitates repair of radiation-induced DNA damage in alveolar epithelial cells.

Administration of exogenous keratinocyte growth factor (KGF) prevents or attenuates several forms of oxidant-mediated lung injury. Because DNA damage in epithelial cells is a component of radiation pneumotoxicity, we determined whether KGF ameliorated DNA strand breaks in irradiated A549 cells. Cells were exposed to 137Cs gamma rays, and DNA damage was measured by alkaline unwinding and ethidium bromide fluorescence after a 30-min recovery period. Radiation induced a dose-dependent increase in DNA strand breaks. The percentage of double-stranded DNA after exposure to 30 Gy increased from 44.6 +/- 3.5% in untreated control cells to 61.6 +/- 5.0% in cells cultured with 100 ng/ml KGF for 24 h (P < 0.05). No reduction in DNA damage occurred when the cells were cultured with KGF but maintained at 0 degree C during and after irradiation. The sparing effect of KGF on radiation-induced DNA damage was blocked by aphidicolin, an inhibitor of DNA polymerases-alpha, -delta, and -epsilon and by butylphenyl dGTP, which blocks DNA polymerase-alpha strongly and polymerases-delta and -epsilon less effectively. However, dideoxythymidine triphosphate, a specific inhibitor of DNA polymerase-beta, did not abrogate the KGF effect. Thus KGF increases DNA repair capacity in irradiated pulmonary epithelial cells, an effect mediated at least in part by DNA polymerases-alpha, -delta, and -epsilon. Enhancement of DNA repair capability after cell damage may be one mechanism by which KGF is able to ameliorate oxidant-mediated alveolar epithelial injury.

Increased DNA Repair Ability after Irradiation Following Treatment with the Immunomodulator AS101

Ammonium trichloro(dioxoethylene-o-o')tellurate (AS101) is a new synthetic compound previously described by us as being able to modulate the immune system and having minimal toxicity. Clinical trials are currently in progress with AS101 on cancer patients. AS101 has recently been found to have radioprotective effects on hemopoiesis and survival of irradiated mice when administered prior to irradiation. Radioprotection conferred by AS101 has recently been demonstrated by us to result partly from induction of progenitor cells to enter into S phase, which is assumed to be a more radioresistant phase of the cell cycle, and partly from the enhanced stimulation of CFU-S not only toward proliferation but also toward self-renewal. In the present study we demonstrate that the DNA repair processes expressing the cellular reponses associated with the restoration of the normal nucleotide sequence after damage caused to the DNA were also increased significantly after treatment with AS101. Unscheduled DNA repair synthesis was found to be significantly higher in both spleen and bone marrow cells from mice injected with AS101 compared to mice injected with PBS. DNA repair synthesis in spleen cells incubated with AS101 in vitro was also higher than that of PBS-treated cells. This was demonstrated by equilibrium alkaline cesium chloride density gradient of DNA from irradiated and nonirradiated spleen cells in the presence of hydroxyurea. In addition, using the neutral filter elution technique, we show that AS101 can both protect cells from DNA double-strand breaks (DSBs) induced by irradiation and enhance the ability of the affected cells to rejoin the DSBs. We show that extracts of splenocytes, either incubated with AS101 in vitro or obtained from mice injected with AS101, contain substantial DNA polymerase activity which is significantly higher compared to that of control treated cells. Aphidicolin, an inhibitor of DNA polymerases alpha and delta, and dideoxy-thymidine, an inhibitor of DNA polymerase beta, inhibited DNA repair synthesis of irradiated splenocytes stimulated with AS101. These results collectively indicate that AS101 confers its radioprotective effects partly by preventing the induction of DSBs induced by irradiation and partly by enhancing the ability of irradiated cells to repair their damaged DNA, probably by increasing mainly DNA polymerase activity. The understanding of the mechanism of radioprotection conferred by AS101 will enable us to use AS101 more effectively for the restoration of hemopoiesis in patients after radiation therapy or in patients suffering from overdose or accidental irradiation.

Inhibition of DNA repair with aphidicolin enhances sensitivity of targets to tumor necrosis factor.

To test whether DNA injury contributes to TNF-induced cytotoxicity, we attempted to enhance DNA injury by inhibiting its repair and then assessing effects on cytotoxicity. DNA repair, assayed as unscheduled DNA synthesis, was first detected in TNF-sensitive targets by 2-3 h of incubation with TNF. Targets resistant to TNF cytotoxicity did not demonstrate significant repair replication. Repair preceded the detection of TNF-induced DNA injury, which was subsequently demonstrated by a double-stranded DNA fragmentation assay, sedimentation of DNA in neutral and alkaline sucrose gradients, and gel electrophoresis of extracted DNA. This suggested that early during exposure to TNF, DNA repair proceeds more rapidly than strand breakage. To inhibit repair, nontoxic concentrations of aphidicolin (inhibitor of DNA polymerase-alpha) and dideoxythymidine (inhibitor of DNA polymerase-beta and gamma) were used. Aphidicolin inhibited repair and consistently sensitized to TNF cytotoxicity, decreasing the ID50 for TNF at least 10- to 50-fold. In contrast, dideoxythymidine had no effect on repair or cytotoxicity. Deoxycytidine, which competitively inhibits binding of aphidicolin to DNA polymerase, blocked the sensitization in a concentration-dependent fashion. In targets sensitized with aphidicolin, TNF-induced strand breakage was accelerated, being detected by 4 h of culture in the sucrose gradient assay. Sensitization to TNF was not due to a heightened activation of poly (ADP-ribose) polymerase. These results indicate that TNF-induced strand breakage participates in TNF-induced cytotoxicity and that the level of DNA repair plays a role in determining relative sensitivity of targets.

Plasmids bearing mammalian DNA-replication origin-enriched ( ors) fragments initiate semiconservative replication in a cell-free system

Four plasmids containing monkey (CV-1) origin-enriched sequences (ors), which we have previously shown to replicate autonomously in CV-1, COS-7 and HeLa cells (Frappier and Zannis-Hadjopoulos (1987) Proc. Natl. Acad. Sci. USA 84, 6668-6672), were found to replicate in an in vitro replication system using HeLa cell extracts. De novo site-specific initiation of replication on plasmids required the presence of an ors sequence, soluble low-salt cytosolic extract, poly(ethylene glycol), a solution containing the four standard deoxyribonucleoside triphosphates and an ATP regenerating system. The major reaction products migrated as relaxed circular and linear plasmid DNAs, both in the presence and absence of high-salt nuclear extracts. Inclusion of high-salt nuclear extract was required to obtain closed circular supercoiled molecules. Replicative intermediates migrating slower than form II and topoisomers migrating between forms II and I were also included among the replication products. Replication of the ors plasmids was not inhibited by ddTTP, an inhibitor of DNA polymerase beta and gamma, and was sensitive to aphidicolin indicating that DNA polymerase alpha and/or delta was responsible for DNA synthesis. Origin mapping experiments showed that early in the in vitro replication reaction, incorporation of nucleotides occurs preferentially at ors-containing fragments, indicating ors specific initiation of replication. In contrast, the limited incorporation of nucleotides into pBR322, was not site specific. The observed synthesis was semiconservative and appeared to be bidirectional.

Heteroduplex repair in extracts of human HeLa cells

A general repair process for DNA heteroduplexes has been detected in HeLa cell extracts. Using a variety of M13mp2 DNA substrates containing single-base mismatches and extra nucleotides, extensive repair is observed after incubation with HeLa cell cytoplasmic extracts and subsequent transfection of bacterial cells with the treated DNA. Most, but not all, mispairs as well as two frameshift heteroduplexes are repaired efficiently. Parallel measurements of repair in HeLa extracts and in Escherichia coli suggest that repair specificities are similar for the two systems. The presence of a nick in the molecule is required for efficient repair in HeLa cell extracts, and the strand containing the nick is the predominantly repaired strand. Mismatch-dependent DNA synthesis is observed when radiolabeled restriction fragments, produced by reaction of the extract with heteroduplex and homoduplex molecules, are compared. Specific labeling of fragments, representing a region of approximately 1,000 base pairs and containing the nick and the mismatch, is detected for the heteroduplex substrate but not the homoduplex. The repair reaction is complete after 20 min and requires added Mg2+, ATP, and an ATP-regenerating system, but not dNTPs, which are present at sufficient levels in the extract. An inhibitor of DNA polymerase beta, dideoxythimidine 5'-triphosphate, does not inhibit mismatch-specific DNA synthesis. Aphidicolin, an inhibitor of DNA polymerases alpha, delta, and epsilom, inhibits both semiconservative replication and repair synthesis in the extract. Butylphenyl-dGTP also inhibits both replicative and repair synthesis but at a concentration known to inhibit DNA polymerase alpha preferentially rather than delta or epsilon. This suggests that DNA polymerase alpha may function in mismatch repair.

DNA single stranded gaps formed during DNA repair synthesis induced by methyl methanesulfonate are filled by sequential action of aphidicolin- and dideoxythymidine sensitive DNA polymerases in HeLa cells

DNA repair synthesis induced by methyl methanesulfonate in preconditioned HeLa cells in which DNA replicative synthesis had been highly suppressed was inhibited by aphidicolin (an inhibitor of DNA polymerases alpha and delta) and dideoxythymidine (ddThR, an inhibitor of DNA polymerase beta). Incomplete repair patches sensitive to exonuclease III were accumulated in the presence of aphidicolin while not in the presence of ddThR. These patches were comopleted by the combined action of Klenow fragment and T4 DNA ligase, indicating that the single-stranded gaps were formed during the repair synthesis. Moreover, ddThR had little effect on the repair synthesis in the presence of aphidicolin. Thus, the results suggest that the single-stranded gaps may be sealed first by aphidicolin-sensitive polymerase followed by ddThR-sensitive DNA polymerase on the same site of the repair patch.

Differential inhibitory effects of various flavonoids on the activities of reverse transcriptase and cellular DNA and RNA polymerases

Four flavonoids, 5,6,7-trihydroxyflavone (baicalein), 3,3',4',5,7-pentahydroxyflavone (quercetin), 3,3',4',5,6,7-hexahydroxyflavone (quercetagetin) and 3,3',4',5,5',7-hexahydroxyflavone (myricetin), were found to be potent inhibitors of reverse transcriptases from Rauscher murine leukemia virus (RLV) and human immunodeficiency virus (HIV). Under the reaction conditions employed, any one of these flavonoids almost completely inhibited the activity of RLV reverse transcriptase at a concentration of 1 microgram/ml. HIV reverse transcriptase was inhibited by 100%, 100%, 90% and 70% in the presence of 2 micrograms/ml quercetin, myricetin, quercetagetin and baicalein, respectively. The mode of inhibition of these flavonoids was competitive (RLV reverse transcriptase) or partially competitive (HIV reverse transcriptase) with respect to the template.primer complex, (rA)n.(dT), and noncompetitive with respect to the triphosphate substrate, dTTP. The Ki values for RLV reverse transcriptase were found to be 0.37 microM and 0.08 microM for baicalein and quercetin, respectively and those for HIV reverse transcriptase were 2.52 microM, 0.52 microM, 0.46 microM and 0.08 microM for baicalein, quercetin, quercetagetin and myricetin, respectively. Comparative studies with other flavonoids (hydroxyflavones, dihydroxyflavones and polyhydroxyflavones and flavanones) carried out to clarify the structure/activity relationships, revealed that the presence of both the unsaturated double bond between positions 2 and 3 of the flavonoid pyrone ring, and the three hydroxyl groups introduced on positions 5, 6 and 7, (i.e. baicalein) were a prerequisite for the inhibition of reverse transcriptase activity. Removal of the 6-hydroxyl group of baicalein required the introduction of three additional hydroxyl groups at positions 3, 3' and 4' (quercetin), to afford a compound still capable of inhibiting the reverse transcriptase activity. Quercetagetin which contains the structures of both baicalein and quercetin, and myricetin which has the structure of quercetin with an additional hydroxyl group on the 5' position also proved strong inhibitors of reverse transcriptase activity. The inhibition by baicalein of reverse transcriptase is highly specific, whereas quercetin and quercetagetin were also strong inhibitors of DNA polymerase beta and DNA polymerase I, respectively. Myricetin was also a potent inhibitor of both DNA polymerase alpha and DNA polymerase I.

Stimulation of DNA repair synthesis of rat thymocytes by novobiocin and nalidixic acid in vitro without detectable DNA damage.

Scheduled (SDS) and unscheduled (UDS) DNA synthesis as well as nucleoid sedimentation was investigated in vitro under the influence of novobiocin (NB) and nalidixic acid (NA) using intact thymic (T-cells) and splenic (S-cells) rat cells and cells which were exposed to X-rays, UV irradiation, methyl methanesulfonate (MMS), and DNA polymerase inhibitors. At concentrations of greater than or equal to 56.25 (S-cells) and greater than or equal to 225 micrograms/ml (T-cells), respectively, NB inhibited SDS in a dose-dependent manner. Within a concentration range of greater than or equal to 225-900 micrograms NB/ml, UDS of S-cells decreased to values far below the tracer ([3H-methyl]-thymidine) incorporation of control cells, whereas UDS of T-cells increased by at least 200%. Within a concentration range of 450-1800 micrograms/ml, NA enhanced SDS and UDS by about 30% in S-cells and by 100% in T-cells. The stimulating activity of NB and/or NA could be eliminated specifically by the DNA polymerase beta inhibitor 2',3'-dideoxythymidine. Enhanced nucleoid sedimentation was observed at NB concentrations greater than or equal to 750 micrograms/ml; S-cells revealed a higher sedimentation rate than T-cells. It is suggested that NB (and NA) influence DNA topology in a rather cell specific manner, stimulating UDS of T-cells by a DNA polymerase beta - dependent repair-like mechanism.