Monoclonal antibody-mediated solid-phase assay for mammalian O6-alkylguanine DNA alkyltransferase activity.

We describe a sensitive, rapid, and simple assay for mammalian O6-alkylguanine DNA alkyltransferase (O6-AGT) utilizing solid-phase DNA as the substrate and a monoclonal antibody (Mab)-based immuno-slotblot (ISB) for quantitation of O6-ethylguanine (O6-EtG). lambda-phage DNA was treated with N-ethyl-N-nitrosourea and immobilized on newly developed hydrophilic latex beads. After incubation with cell extracts to be assayed for O6-AGT activity, the substrate DNA could be isolated easily by a brief centrifugation through 50% glycerol. The amount of O6-EtG retained in the substrate DNA was determined by ISB using the anti-(O6-ethyl-2'-deoxyguanosine) Mab ER-6. As little as 2 fmol of O6-AGT per reaction tube can be reproducibly measured by this procedure, which is suitable for handling large numbers of samples within a short time (e.g., 80 samples within 2 days). In normal and malignant cells, respectively, O6-AGT activity protects against O6-alkylguanine-mediated mutagenesis and oncogenesis following exposure to N-nitroso carcinogens or confers resistance against cytocidal anti-cancer drugs such as chloroethylnitrosoureas and related compounds. The analysis of cellular O6-AGT activity by a highly sensitive, routinely applicable method is, therefore, of particular interest in studies related to carcinogenesis, molecular epidemiology, and clinical oncology.     

Comparative effects of TGFβ on proliferation of 7- and 14-day-old chick embryo fibroblasts and lack of involvement of the ODC/PA system in the TGFβ signaling pathway

The growth regulatory activity of transforming growth factor β (TGFβ) on chick embryo skin fibroblasts was compared in two developmental ages, days 7 and 14. The time course of ³H-thymidine incorporation, an S-phase marker of replication, was determined during 36 hr of TGFβ treatment. Seven-day-old cells showed a prereplicative phase of 6 hr, and 14-day-old cells showed a prereplicative phase of 12 hr. DNA synthesis peaked at 24 hr in 7-day-old fibroblasts and was 10 times higher than that in 14-day-old fibroblasts. Ornithine decarboxylase (ODC) activity and content of the natural polyamines spermine (Spm), spermidine (Spd), and putrescine (Put) differed during cell cycle. ODC activity peaked at 12 hr in 7-day-old cells and at 6 hr in 14-day-old cells. Its level was two times higher at day 7 and was associated with a greater content of ODC mRNA. The maximum of polyamine (PA) concentration was determined after 12 hr of treatment in 7-day-old cells and after 36 hr in 14-day-old cells. These findings indicate that the TGFβ proliferative response of embryo fibroblasts changes during development and is associated with activation of the ODC/PA system. Cotreatment with α-difluoromethylornithine, an enzyme-activated irreversible inhibitor of ODC, did not reduced growth rate. Inhibition of ODC resulted in levels of Put and Spd comparable to that of quiescent fibroblasts, whereas Spm concentration remained higher. Because an altered ODC metabolism does not convey the effects of TGFβ on DNA synthesis, the ODC/PA system may not play a role in the pathway of TGFβ signaling. J. Cell. Physiol. 178:304–310, 1999. © 1999 Wiley-Liss, Inc.     

Cellular functions are required for the synthesis and integration of avian sarcoma virus-specific DNA.

We have used two experimental strategies to test the role of cellular functions in the synthesis and integration of virus-specific DNA in cells infected by avian sarcoma virus.First, quail embryo fibroblasts, placed in stationary phase (G₀) by prolonged serum starvation, did not support the efficient synthesis of viral DNA during the first 24–48 hr after infection. Synthesis of viral DNA was impaired according to at least two parameters: the amount of DNA was diminished, particularly the amount of the plus-strand DNA (identical in polarity to the viral genome); and the length of both minus and plus strands was reduced in the stationary cells. In parallel cultures fed with fresh serum, over two thirds of the cells were able to reenter the cell cycle within 24 hr, and viral DNA of normal size was synthesized.Second, density labeling of viral and cellular DNA with BUdR was used to determine whether cellular DNA synthesis was required for integration of viral DNA. In both quail embryo fibroblasts released from G₀ by serum replacement and randomly growing duck embryo fibroblasts, viral DNA was integrated only into cellular DNA replicated during the infection.Our results indicate that serum-starved cells lack a factor (or factors) required for the efficient and complete synthesis of ASV-specific DNA. We have not been able to establish whether such factor(s) are present in growing cells only during S phase. Integration of viral DNA appears to require cellular DNA synthesis; this may be due to a requirement for a factor (or factors) present in adequate concentration only during S phase or to a requirement for the structural changes in cellular DNA that accompany replication.     

Cycloheximide or puromycin can substitute for PDGF in inducing cellular DNA synthesis in quiescent 3T3 cells

A brief exposure of quiescent (Go) Swiss 3T3 mouse fibroblasts to inhibitors of protein synthesis can replace platelet-derived growth factor in the stimulation of cellular DNA synthesis. When 3T3 cells, after a 6 hr exposure to either cycloheximide or puromycin, are incubated with platelet-poor plasma, a significant percentage of cells enters DNA synthesis. Either inhibition of protein synthesis, or platelet poor plasma by themselves are totally ineffective. A possible mechanism by which inhibitors of protein synthesis may initiate cell cycle progression is through the activation of the c-myc gene.     

HYDROXYUREA EFFECTS IN THE C3H MOUSE: I. DUODENAL CRYPT CELL KINETICS

Duodenal crypt cell kinetics in C3H mice have been studied before and after the injection of a single dose (3 mg/g body weight) of hydroxyurea (HU). This was done by autoradiographic analysis of crypt cells which had been labeled with tritiated 5-iodo-2'-deoxyuridine. This dose of HU kills the cells which are synthesizing DNA at the time of injection, inhibits DNA synthesis completely for 4–5 hr, and causes a partial synchronization of the cells when they recover from the inhibitory effects of HU. Duodenal crypt recovery is manifested by a decrease in the mean cell cycle time, an increase in the proliferating fraction, and a lengthening of the crypts. The acute cellular responses are apparently complete within 24–48 hr, but the length of the crypt has not returned to normal by 48 hr after HU administration.     

Stable Cellular Senescence Is Associated with Persistent DDR Activation

The DNA damage response (DDR) is activated upon DNA damage generation to promote DNA repair and inhibit cell cycle progression in the presence of a lesion. Cellular senescence is a permanent cell cycle arrest characterized by persistent DDR activation. However, some reports suggest that DDR activation is a feature only of early cellular senescence that is then lost with time. This challenges the hypothesis that cellular senescence is caused by persistent DDR activation. To address this issue, we studied DDR activation dynamics in senescent cells. Here we show that normal human fibroblasts retain DDR markers months after replicative senescence establishment. Consistently, human fibroblasts from healthy aged donors display markers of DDR activation even three years in culture after entry into replicative cellular senescence. However, by extending our analyses to different human cell strains, we also observed an apparent DDR loss with time following entry into cellular senescence. This though correlates with the inability of these cell strains to survive in culture upon replicative or irradiation-induced cellular senescence. We propose a model to reconcile these results. Cell strains not suffering the prolonged in vitro culture stress retain robust DDR activation that persists for years, indicating that under physiological conditions persistent DDR is causally involved in senescence establishment and maintenance. However, cell strains unable to maintain cell viability in vitro, due to their inability to cope with prolonged cell culture-associated stress, show an only-apparent reduction in DDR foci which is in fact due to selective loss of the most damaged cells.     

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.     

Relevance of drug uptake,cellular distribution and cell membrane fluidity to the enhanced sensitivity of Down's syndrome fibroblasts to anticancer antibiotic-mitoxantrone

Sensitivity of human fibroblasts derived from Down's syndrome (DS) individuals (S-240, T-158, T-74, T-164) and normal donors (S-126, WA-1) to anticancer antibiotic-mitoxantrone (1,4-dihydroxy-5,8-bis((2-((2-hydroxy-ethyl)amino)ethyl)amino)-9,10-anthracenedione dihydrochloride; MIT) and its relationship to the transport rate, cellular distribution and interaction with cell membrane were studied. The survival assay showed that MIT was more toxic to trisomic fibroblast lines than to normal cells. Studies of transport kinetics indicated that the amount of drug taken up and extruded by DS cells was diminished, compared to control cells. In contrast, the cellular level of MIT associated with DNA was greater in trisomic than in normal cells. The fluorescence anisotropy measurements of TMA-DPH and 12-AS demonstrated that the fluidity of the polar region of the outer lipid monolayer of DS cell membrane was decreased in comparison with normal cells. MIT treatment decreased fluidity of the inner hydrophobic region of plasma membrane, but only slightly influenced the fluidity of the outer surface of the cell membrane. Finally, we concluded that lowered membrane fluidity, diminished amount of MIT extruded by cells and the enhanced level of the drug associated with DNA could be responsible for the enhanced sensitivity of DS fibroblasts to the MIT treatment.     

Stimulated rat T cell-derived inhibitory factor for cellular DNA synthesis (STIF). III. Effect on cell proliferation and immune responses

Stimulated T cell-derived inhibitory factor for cellular DNA synthesis (STIF), a lymphokine produced from concanavalin A (Con A)-stimulated rat suppressor T cells, was examined for its inhibitory effect on various cultured cells and on in vitro immune reactions. STIF could inhibit the DNA synthesis of a variety of normal and neoplastic cells from rats, mice, and humans in a dose-dependent fashion. Kinetics studies revealed that STIF selectively inhibited cellular DNA synthesis after incubation for 12 hr, but after 36 hr, it also inhibited RNA and protein syntheses. The inhibited cellular DNA synthesis by 12-hr incubation with STIF was recovered after culturing the cells in STIF-free medium. The inhibitory effect of STIF on the DNA synthesis was not blocked by addition of a sugar (alpha-methyl-D-mannoside, N-acetyl-D-glucosamine, N-acetyl-D-galactosamine, L-fucose, or L-rhamnose) in culture, as determined by using rat bone marrow cells. STIF inhibited proliferative responses of rat lymphocytes to T cell mitogens, Con A and phytohemagglutinin, and a B cell mitogen, lipopolysaccharide, as well as IL 2-dependent growth of cloned T572 cells. It could also inhibit both blastogenesis and cytotoxic T cell generation in allogeneic mixed lymphocyte reaction. The release of IL 2 from Con A-stimulated T cells was also inhibited by the added STIF in culture, as demonstrated from the finding that IL 2 activity was not detected in the supernatants even after an anion-exchange column chromatography. These results indicate that STIF could inhibit cellular DNA synthesis in a species-unrestricted manner and thus inhibits the proliferation of various normal and neoplastic cells, and that it could also inhibit lectin- or IL 2-dependent T cell proliferation as well as IL 2 production from T cells in in vitro immune reactions.     

Virus replication in infected epithelial cells is coupled to cell shape-responsive metabolic controls

The cell shape of monkey epithelial cells was varied from flat to spheroidal by gradually reducing the substrate adhesiveness with poly (HEMA) films of increasing thickness. The decrease in cell spreading is accompanied by a dramatic response in cellular macromolecular metabolism in the nucleus. Within 14 to 16 hr, DNA and RNA syntheses are inhibited by more than 95%, while the level of protein synthesis is reduced by only twofold after 24 hr in spheroidal-suspension culture. When epithelial cells, spread to various degrees, are infected with SV40 or herpes virus a parallel inhibition of virus replication and cellular macromolecular metabolism occurs. However, VSV can proliferate in the metabolically active cytoplasm of epithelial cells in which nuclear activity is inhibited owing to alterations in cell shape. The results suggest that the metabolic restrictions imposed on epithelial cells, owing to changes in cell spreading, are a dominant phenomenon that cannot be overcome by virus infection. Rather, virus replication, which is dependent on the cellular metabolic machinery, is inhibited in parallel with the inhibition of cellular macromolecular metabolism.     

The competitive miscoding of O6-methylguanine and O6-ethylguanine and the possible importance of cellular deoxynucleoside 5'-triphosphate pool sizes in mutagenesis and carcinogenesis

Using initiated poly(dG,O6-RdG) and poly(dA,O6-RdG) polynucleotides as templates for DNA polymerase I in vitro the promutagenic potential of O6-MeG and O6-EtG has been confirmed, together with the possibility of minor miscoding pathways for O6-RG. These lead to the incorporation of dAMP and dGMP, which could give rise to some of the limited number of transversions that have been observed arising from the action of alkylating agents. The results are compatible with the current knowledge of oncogenes, explaining the changes in base sequence that have been observed. The competition for the miscoding of O6-RG which leads to the incorporation of dCMP in addition to the expected dTMP is also shown. The relative amounts of these two nucleotides incorporated depend upon the concentrations of the dCTP and dTTP in the assay. The mutagenic efficiency of O6-MeG is constant at approx. 0.4 over a wide range of dTTP and dCTP concentrations and only increases when the dCTP in the assay ceases to saturate the polymerizing enzyme, indicating that the DNA polymerase I plays a role in determining the mutagenic efficiency of a modified base. Although the mutagenic efficiency of both O6-MeG and O6-EtG depends upon the relative concentrations. of dTTP and dCTP in the assay, a reduction in the concentration of dCTP can be more effective at increasing the mutagenic efficiency than a corresponding increase in the concentration of dTTP. These results indicate the importance of cellular dNTP pools in determining the cellular response to agents.     

Kinetics of Nucleic Acid Synthesis in Human Embryonic Kidney Cultures Infected with Adenovirus 2 or 12: Inhibition of Cellular Deoxyribonucleic Acid Synthesis

Infection of human embryonic kidney (HEK) cell cultures with adenovirus types 2 or 12 resulted in an initial drop in the rate of incorporation of (3)H-thymidine into deoxyribonucleic acid (DNA) during the early latent period of virus growth, followed by a marked rise in label uptake. It was shown by cesium chloride isopycnic centrifugation that, after adenovirus 2 infection, there was a decrease in the rate of incorporation of thymidine into cellular DNA. Moreover, DNA-DNA hybridization experiments revealed that, by 28 to 32 hr after infection with either adenovirus 2 or 12, the amount of isolated pulse-labeled DNA capable of hybridizing with HEK cell DNA was reduced by approximately 60 to 70%. Autoradiographic measurements showed that the inhibition of cellular DNA synthesis was due to a decrease in the ability of an infected cell to synthesize DNA. The adenovirus-induced inhibition of host cell DNA synthesis was not due to degradation of cellular DNA. (3)H-thymidine incorporated into cellular DNA at the time of infection remained acid-precipitable, and labeled material was not incorporated into viral DNA. Furthermore, when zone sedimentation through neutral or alkaline sucrose density gradients was employed, no detectable change was observed in the sedimentation rate of this cellular DNA at various times after infection with adenovirus 2 or 12. In addition, there was no increase in deoxyribonuclease activity in cells infected with either virus. Cultures infected for 38 hr with adenovirus 2 or 12 incorporated three to four times as much (3)H-uridine into ribonucleic acid (RNA) as did non-infected cultures. Furthermore, the net RNA synthesized by infected cultures substantially exceeded that of control cultures. The activity of thymidine kinase was induced, but there was no stimulation of uridine kinase.     

Elevated intracellular concentrations of cyclic AMP inhibited serum-stimulated, density-arrested BALB/c-3T3 cells in mid G1

The stimulation of DNA synthesis in quiescent, density-arrested BALB/c-3T3 cells by platelet-derived growth factor in plasma-supplemented medium was inhibited by the presence of isobutylmethylxanthine (IBMX) and cholera toxin, although neither IBMX or cholera toxin when used alone inhibited the stimulation of DNA synthesis. The cells were reversibly inhibited in mid G1 at a point 6 hr prior to the initiation of DNA synthesis. The inhibition of cell cycle traverse was associated with a 10-15 fold increase in cellular cyclic AMP concentration over basal levels. The reversal of this inhibition by removal of IBMX was correlated with a dramatic decrease in cyclic AMP levels. The traverse of G1 and the initiation of DNA synthesis after release from the cholera toxin and IBMX inhibition was dependent on the presence of plasma in the medium. Either somatomedin C (10-20 ng/ml) or insulin (10(-6)-10(-5) M) completely replaced the plasma requirement for late G1 progression and entry into S phase. Once the inhibited cells were released from the IBMX and cholera toxin block a subsequent increase in cyclic AMP did not prevent entry into S phase. The presence of cholera toxin alone inhibited the stimulation of human dermal fibroblasts. The elevation of intracellular cyclic AMP levels in the human dermal fibroblasts by cholera toxin was two to three fold greater than that found in the BALB/c-3T3 cells in the presence of cholera toxin and the IBMX.     

Purification of the E. coli ogt gene product to homogeneity and its rate of action on O6-methylguanine, O6-ethylguanine and O4-methylthymine in dodecadeoxyribonucleotides.

The E. coli gene ogt encodes the DNA repair protein O6-alkylguanine-DNA-alkyltransferase (O6-AlkG ATase). The protein coding region of the gene was cloned into a multicopy expression vector to obtain high yields of the enzyme (approximately 0.2% of total protein) which was purified to apparent homogeneity by affinity, molecular exclusion and reverse-phase chromatography. Good correlation was found between the determined and predicted amino acid compositions. The ability of the purified protein to act on O6-methylguanine (O6-MeG), O6-ethylguanine (O6-EtG) and O4-methylthymine (O4-MeT) in self-complementary dodecadeoxyribonucleotides was compared to that of 19 kDa fragment of the related ada-protein. With both proteins the rate order was O6-MeG greater than O6-EtG greater than O4-MeT, however, the ogt protein was found to repair O6-MeG, O6-EtG and O4-Met, 1.1, 173 and 84 times, respectively, faster than the ada protein.     

Inducible cell lysis system for the study of natural transformation and environmental fate of DNA released by cell death.

Two novel conditional broad-host-range cell lysis systems have been developed for the study of natural transformation in bacteria and the environmental fate of DNA released by cell death. Plasmid pDKL02 consists of lysis genes S, R, and Rz from bacteriophage lambda under the control of the Ptac promoter. The addition of inducer to Escherichia coli, Acinetobacter calcoaceticus, or Pseudomonas stutzeri containing plasmid pDKL02 resulted in cell lysis coincident with the release of high amounts of nucleic acids into the surrounding medium. The utility of this lysis system for the study of natural transformation with DNA released from lysed cells was assessed with differentially marked but otherwise isogenic donor-recipient pairs of P. stutzeri JM300 and A. calcoaceticus BD4. Transformation frequencies obtained with lysis-released DNA and DNA purified by conventional methods and assessed by the use of antibiotic resistance (P. stutzeri) or amino acid prototrophy (A. calcoaceticus) for markers were comparable. A second cell lysis plasmid, pDKL01, contains the lysis gene E from bacteriophage phi X174 and causes lysis of E. coli and P. stutzeri bacteria by activating cellular autolysins. Whereas DNA released from pDKL02-containing bacteria persists in the culture broth for days, that from induced pDKL01-containing bacteria is degraded immediately after release. The lysis system involving pDKL02 is thus useful for the study of both the fate of DNA released naturally into the environment by dead cells and gene transfer by natural transformation in the environment in that biochemically unmanipulated DNA containing defined sequences and coding for selective phenotypes can be released into a selected environment at a specific time point. This will allow kinetic measurements that will answer some of the current ecological questions about the fate and biological potential of environmental DNA to be made.     

Induction of Cellular Deoxyribonuleic Acid Synthesis by Simian Virus 40

The incorporation of (3)H-thymidine ((3)H-dT) into deoxyribonucleic acid (DNA) has been studied in uninfected confluent monolayer cultures of monkey kidney and mouse kidney cells, simian virus 40 (SV40)-infected cells, and in SV40-transformed mouse kidney cells. Radioautographic measurements revealed that during the period from 28 to 51 hr after productive SV40 infection of monkey kidney cultures about 80% of the cells synthesized DNA, compared to about 16% in uninfected cultures. At 28 to 43 hr after abortive SV40 infection of mouse kidney cultures, 24 to 37% of the cells synthesized DNA, compared to about 6 to 8% in uninfected cultures. The infected monkey kidney and mouse kidney cultures, respectively, incorporated about 5 to 10 times and 3 to 5 times as much (3)H-dT into DNA as did uninfected cultures. Moreover, the net DNA synthesized by SV40-infected monkey kidney cultures, estimated by colorimetric methods, substantially exceeded that of uninfected cultures.Nitrocellulose chromatography and band centrifugation experiments were performed to elucidate the kinds of DNA synthesized in the cultures. In uninfected monkey kidney cultures and at 2 to 12 hr after SV40 infection, almost all of the (3)H-dT labeled DNA sedimented more rapidly than SV40 DNA, and the radioactive DNA was denatured by heating for 12 min at 100 C (cellular DNA). Almost all of the labeled DNA obtained from abortively infected mouse kidney cultures and from SV40-transformed cells also had the properties of cellular DNA. However, approximately one-third to one-half of the labeled DNA obtained from monkey kidney cultures 28 to 51 hr after infection sedimented more slowly than cellular DNA and was not denatured by the heating (SV40 DNA). It is concluded that cellular DNA synthesis was induced during either the productive or abortive SV40 infections.     

Fate of adenovirus type 12 genomes in nonpermissive cells

The fate of ³H-thymidine-labeled adenovirus type 12 deoxyribonucleic acid (DNA) was studied in Nil-2 cells of Syrian hamster origin. It was found that a substantial fraction of ³H-adenovirus type 12 DNA became degraded within 24 hr after infection and was released into the culture fluid. After infection of 5-bromodeoxyuridine (BUdR)-prelabeled cells with ³H-adenovirus type 12, viral DNA became readily separable from cellular DNA by equilibrium centrifugation in CsCl. Part of the viral radioactivity was found to shift gradually to the position of cellular DNA as time progressed after infection. When exponentially growing cells were exposed simultaneously to BUdR, 5-fluorodeoxyuridine, and ³H-adenovirus type 12, up to 50% of the viral radioactivity shifted within 24 hr from the density of viral DNA to that of cellular DNA after equilibrium centrifugation in CsCl. Upon denaturation of the cellular DNA, the isotope was preferentially found to be associated with the “heavy” strand which was synthesized after infection. Upon hybridization of the “heavy” and the “light” strands with sonically treated, denatured ³H-adenovirus type 12 DNA, small and nearly equal amounts of counts hybridized with both strands. The number of counts annealed was in a range similar to that of those annealed with the same amount of DNA derived from adenovirus type 12-transformed hamster cells. These results demonstrate that (i) a substantial proportion of the adsorbed virus becomes degraded within 24 hr; (ii) part of the degradation products is reutilized for cellular DNA synthesis; (iii) only a small fraction, mainly fragments, of viral DNA becomes integrated into both the newly synthesized and the parental strands of cellular DNA.     

Histone gene expression remains coupled to DNA synthesis during in vitro cellular senescence

Despite a decrease in the extent to which confluent monolayers of late compared to early passage CF3 human diploid fibroblasts can be stimulated to proliferate, the time course of DNA synthesis onset is similar regardless of the in vitro age of the cells. A parallel and stoichiometric relationship is maintained between the rate of DNA synthesis and the cellular levels of histone mRNA independent of the age of the cell cultures. Furthermore, DNA synthesis and cellular histone mRNA levels decline in a coordinate manner after inhibition of DNA replication by hydroxyurea treatment. These results indicate that while the proliferative activity of human diploid fibroblasts decreases with passage in culture, those cells that retain the ability to proliferate continue to exhibit a tight coupling of DNA replication and histone gene expression.     

Growth hormone attenuation of epidermal growth factor-induced mitogenesis

Growth hormone (GH) has previously been reported to influence the adipose conversion of 3T3-F442A murine fibroblasts, partly by causing these cells to exit the cell cycle and to become unresponsive to serum-stimulated mitogenesis. To better understand this process, quiescent fibroblasts were treated with fully stimulatory doses (50 nM) of epidermal growth factor (EGF) in the presence or absence of pituitary human GH (hGH) or the phorbol ester phorbol 12-myristate 13-acetate (PMA), which is known to down-regulate EGF receptor activity. EGF-induced DNA synthesis was attenuated by hGH in a dose-dependent manner with an ED₅₀ of approximately 0.1 nM and a maximally effective dose of 10–30 nM. This effect appeared to be the result of inhibition of DNA synthesis and exclusive of a time shift in the initiation of the S phase of the cell cycle. Additionally, insulin-like growth factor-1 (IGF-1), which can act as an important in vivo mediator of GH, failed to mimic the anti-mitogenic effects of GH. The ability of hGH to antagonize EGF-stimulated mitogenesis did not appear to be due to the down-regulation of EGF receptor mass or to pronounced changes in EGF-induced tyrosine kinase activity. Furthermore, when GH was administered at various times after EGF addition, GH continued to be effective at inhibiting EGF-induced DNA synthesis for up to 9 hr after EGF treatment. Modulation of EGF-induced cell cycle progression was further evidenced by the ability of GH to promote a marked decrease in the EGF-induced expression of D cyclins. In comparison, PMA inhibited EGF-induced DNA synthesis for up to 18 hr after EGF addition and also down-regulated EGF receptor mass and activity; these observations suggest that the mechanism of GH action is largely distinct from that of PMA. We conclude that GH can selectively and dose-dependently modulate EGF receptor-mediated DNA synthesis exclusive of any rapid or extensive effects on EGF receptor mass or tyrosine kinase activity. Furthermore, the capacity of GH to attenuate EGF-induced mitogenesis, even when administered 9 hr after EGF addition, and the GH modulation of EGF-induced expression of D cyclins, suggest that there are GH-induced effects on systems involved in the transition of these fibroblasts through the G₁ phase of the cell cycle. In sum, these data support a specific interaction of this somatotropic hormone/cytokine with EGF in the control of cell cycle progression in 3T3-F442A fibroblasts. J. Cell. Physiol. 173:44–53, 1997. © 1997 Wiley-Liss, Inc.     

Physiological modification of alkylating agent induced mutagenesis. II. Influence of the numbers of chromosome replicating forks and gene copies on the frequency of mutations induced in Escherichia coli.

The frequency of reversions induced in Escherichia coli K-12 trpA58 by any of five different monofunctional alkylating agents increased as the growth rate of the organism was raised prior to mutagen treatment. The increase in mutation frequency did not correlate with growth rate-dependent changes in cell area or total cellular protein and DNA. After treatment of cells with N-methyl-N-nitrosourea (MNUA), no growth rate-dependent change was observed in the total DNA alkylation or percentage of O6-methylguanine present in the DNA extracted. The frequency of reversions induced by one mutagen, methyl methanesulphonate (MMS), increased in proportion to the average number of trpA gene copies per cell, whereas the frequency of reversions induced by the other compounds was dependent on the average number of chromosome replicating forks per cell. This difference was attributed to the different ratios of DNA base alkylation products observed, formed after treatment with MMS, an SN2-type reagent, or after treatment with the SN1-type reagents ethyl methanesulphonate (EMS), N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), MNUA and N-ethyl-N-nitrosourea (ENUA). Possible reasons for the dependence of mutation frequency on the number of replicating forks per cell are discussed.