Oxygen-dependent regulation of in vivo replication of simian virus 40 DNA is modulated by glucose.

Simian virus 40 (SV40)-infected CV1 cells exposed to hypoxia show an inhibition of viral replication. Reoxygenation after several hours of hypoxia results in new initiations followed by a nearly synchronous round of SV40 replication. In this communication, we examined the effect of glucose on inhibition of viral DNA replication under hypoxia. We found that glucose stimulated SV40 DNA replication under hypoxia in two different ways. First, the rate of DNA synthesis, i.e. the fork propagation rate, increased. This effect seemed to be mediated by inhibition of mitochondrial respiration by glucose (Crabtree effect). Inhibition of mitochondrial respiration probably resulted in a higher intracellular oxygen concentration and an activation of oxygen-dependent ribonucleotide reductase, which provides the precursors for DNA synthesis. This glucose effect was consequently strongly dependent on the strength of hypoxia and the extent of intracellular respiration; hypoxic gassing with 10 ppm instead of 200-400 ppm O(2) or treatment of hypoxic cells with a mitochondrial uncoupler (carbonyl cyanide m-chlorophenylhydrazone) reduced the glucose effect on replication, whereas antimycin A, an inhibitor of respiration, increased it. The second effect of glucose concerned initiation, i.e. stimulation of unwinding of the viral origin. This effect was not influenced by the strength of hypoxia or the extent of cellular respiration and seemed, therefore, not to be mediated through a Crabtree effect. No evidence for a direct correlation between the cellular ATP concentration and the extent of SV40 replication under hypoxia was found. The effect of glucose on replication under hypoxia was not restricted to SV40-infected CV1 cells but was also detectable in HeLa cells. This suggests it to be a mechanism of more general validity.

Hypoxia blocks in vivo initiation of simian virus 40 replication at a stage preceding origin unwinding.

Simian virus 40 (SV40)-infected CV1 cells transiently exposed to hypoxia show a burst of viral replication immediately after reoxygenation. DNA precursor incorporation and analysis of growing daughter strands by alkaline sedimentation demonstrated that SV40 DNA synthesis began with a lag of about 3 to 5 min after reoxygenation followed by a largely synchronous viral replication round. Viral RNA-DNA primers complementary to the SV40 origin region were not detectable before 3 min upon reoxygenation. A distinct form of circular closed, supercoiled SV40 DNA was detectable as soon as 3 min after reoxygenation but not under hypoxia. Sensitivity to the DNA nuclease Bal 31 and migration behavior in chloroquine-containing agarose gels suggested that this DNA species was highly underwound compared to other SV40 topoisomers and was probably related to the highly underwound form U DNA first described by Dean et al. (F. B. Dean, P. Bullock, Y. Murakami, C. R. Wobbe, L. Weissbach, and J. Hurwitz, Proc. Natl. Acad. Sci. USA 84:16-20, 1987), in vitro. 3'-OH ends of presumed RNA-DNA primers could be detected in form U by 3' end labeling with T7 polymerase. Addition of aphidicolin to the cells before reoxygenation led to a pronounced accumulation of form U DNA containing RNA-DNA primers. In vivo pulse-chase kinetic studies performed with aphidicolin-treated SV40-infected cells showed that form U is an initial intermediate of SV40 DNA replication which matures into higher-molecular-weight replication intermediates and into SV40 form I DNA after removal of the inhibitor. These results suggest that in vivo initiation of SV40 replication is arrested by hypoxia before origin unwinding and primer synthesis.

Fast control of DNA replication in response to hypoxia and to inhibited protein synthesis in CCRF-CEM and HeLa cells.

In order to elucidate whether data about the fast regulation of DNA replication in dependence on oxygen supply and on a functioning protein synthesis, previously elaborated with Ehrlich ascites cells, are valid for human cells too, we repeated key experiments with CCRF-CEM and HeLa cells. The most important techniques employed were DNA fibre autoradiography and alkaline sedimentation analyses of growing (pulse-labeled) daughter strand DNA. It was found that CCRF-CEM and HeLa cells responded to transient hypoxia and to transient inhibition of protein synthesis in an almost identical fashion. Scheduled replicon initiations were reversibly suppressed and the progress rates of replication forks, which were already active before the respective inhibitory conditions were established, were reversibly slowed down. The inclusion of the fork progress rate in the response differs from Ehrlich ascites cells, which respond only by suppressing initiation. Further circumstances of the fast oxygen dependent response, concerning the behaviour of ribonucleotide reductase and of the dNTP pools, revealed no significant differences among the three cell lines. The striking identity of the response of each of the cell lines to hypoxia and to inhibited protein synthesis prompts the suspicion that converging fast regulatory pathways act on the cellular replication machinery. The phenomena as such seem to be rather widespread among mammalian cells.

Role of ribonucleotide reductase and deoxynucleotide pools in the oxygen-dependent control of DNA replication in Ehrlich ascites cells.

Cultured Ehrlich ascites cells were exposed to different oxygen tensions (ranging from nearly complete anoxia to 95% O2 at 10(5) Pa) and to transient (5-10 h) hypoxia (0.02% O2 at 10(5) Pa). Treated cells were examined with respect to the intracellular concentration of the M2-specific tyrosyl free radical of ribonucleotide reductase by EPR spectroscopy, and with respect to the pool sizes of all four deoxynucleoside triphosphates by an enzymatic assay employing DNA polymerase I of Escherichia coli. From 2% to 0.02% O2, the free radical level decreased continually from a normal value to just above detectability by the EPR measurement employed, and quickly recovered when hypoxic cells were resupplied with atmospheric O2. Concurrently, analogous changes of the size of the dCTP pool occurred, whereas the pool sizes dATP and dGTP underwent no changes, and the size of the dTTP pool only moderate changes. The changes of the free radical concentration and of the dCTP pool correlated well with the suppression or reactivation of DNA replication under the respective O2 conditions. The results consistently support the hypothesis of a fast-acting regulatory pathway that controls the rate of DNA replication in proliferating cells according to sufficient availability of O2. Therefore, ribonucleotide reductase may serve, in addition to providing DNA building blocks, as a pO2 sensor, which transmits the signal in the form of an altered intracellular dCTP concentration, directly or indirectly, to the nuclear-replication machinery.

Reversible shutdown of replicon initiation by transient hypoxia in Ehrlich ascites cells. Dependence of initiation on short-lived protein.

The O2-dependent regulation of replication in Ehrlich ascites cells, characterized by a reversible shutdown of replicon initiation during hypoxia, was scrutinized with respect to the involvement of gene expression. Synchronous and asynchronous cells were subjected to transient hypoxia and examined for expression of selected 'late' growth-regulated mRNA and for the influence of inhibitors of transcription and translation on DNA replication. Irrespective of whether replicon initiation was suppressed by hypoxia or retriggered by reoxygenation, the levels of thymidine kinase mRNA and of proliferating cell-nuclear antigen/cyclin mRNA were as high as in untreated replicating cells. The level of histone H3.1 mRNA followed, with a distinct delay, the replicative activity of the cells governed by the imposed changes of pO2. The response of replication to inhibition of transcription and translation was virtually the same as to hypoxia, i.e. a selective suppression of replicon initiation. It was demonstrated that replicon initiation depends on one or several short-lived protein(s) (lifetime about 5 min) which is (are) formed under hypoxic conditions as well. The lifetime of the corresponding RNA message(s) is in the range of several hours. It is suggested that the expression of genes conditioning resting cells for DNA replication remains unaffected by hypoxia or by restoring the normal pO2. Hypoxic cell appear to rest in a state fully prepared for entering DNA replication, but a yet unknown event essential for replicon initiation is blocked. This event depends on a critical oxygen tension as well as on short-lived protein(s).

No significant overreplication occurs in Ehrlich ascites cells during and after reversal of hypoxia.

Labeling with bromodeoxyuridine and analysis by isopycnic banding for emergence of DNA-helices density-labeled in both strands (HH-DNA) were used to examine whether transient controlled hypoxia induces significant overreplication in the DNA of cultured Ehrlich ascites cells within a single cell cycle. Diverse situations of the hypoxic period (4-8 h) within the BrdUrd labeling time (8-16 h) were tested. If transversal of more than one complete cell cycle by very fast cycling individual cells was avoided by using short BrdUrd labeling periods or by addition of colcemid, HH-DNA was never detected. This indicates that hypoxia does not induce significant overreplication under the conditions chosen and, in particular, that the burst of replicon initiations occurring after reoxygenation of hypoxic cells principally is not due to overreplication.