Lysine tRNA and cell division: a G1 cell cycle mutant is temperature sensitive for the modification of tRNA5Lys to tRNA4Lys.

Ts-694 is a temperature sensitive mutant of hamster cells which is blocked in the G1 phase of the cell cycle at the restrictive temperature of 39 degrees. A comparison of the Lys-tRNA isoacceptors by RPC-5 chromatography showed a decrease in tRNA5Lys and an increase in tRNA4Lys at 39 degrees. This was identical to the changes seen in confluent cultures at the permissive temperature of 33 degrees. These Lys-tRNA changes were not seen in ts-694 cells blocked in G1 by isoleucine deficiency, nor in two other G1 ts mutants at the restrictive temperature. Cells trapped in S phase by a thymidine block also contained decreased levels of tRNA4Lys when raised to 39 degrees. Both tRNA4Lys levels and cell division increased when the cells were returned to the permissive temperature. An in vitro assay was established for the modification of tRNA5Lys to tRNA4Lys with tRNA6Lys and tRNA2Lys as intermediates. The first reaction is the synthesis of tRNA6Lys which involves the introduction of a modified uridine at the third position of the anticodon. Extracts of 694 cells grown at 33 degrees were able to modify rat liver [3H] tRNA5Lys to tRNA6Lys and tRNA4Lys in vitro when assayed at 25 degrees but not at 39 degrees. Extracts of Balb/c 3T3 cells, however, were more active at 39 degrees than at 25 degrees showing that the normal enzyme is not temperature sensitive. Ts-694 cell tRNA, isolated from cells grown at 33 degrees was aminoacylated at both 25 degrees and 39 degrees with rat liver synthetases. tRNA4Lys was present at both temperatures indicating that ts-694 cells do not contain a temperature sensitive tRNA4Lys.     

Cell division cycle in mammalian cells : VIII. Mapping of G1 into six segments using temperature-sensitive cell cycle mutants

The G1 blocks in three temperature-sensitive (ts) Syrian hamster cell-cycle mutants have been mapped in relation to other G1 landmarks. Two mutants reported here, ts-559 and ts-694, show defective progression only in G1. When shifted from the permissive temperature of 33 degrees C to the non-permissive temperature of 39 degrees C, G1 cells of these two mutants show no further cell cycle progression, while cells in S, G2 and mitosis progress through the cell cycle but become blocked after entering G1. The two mutants complement each other, and also complement the previously reported mutant ts-550C with blocks in both G1 and G2 of the cell cycle. The locations of the G1 blocks in both ts-559 and ts-694 are before the hydroxyurea arrest point. The G1 ts point in ts-694 is prior to the isoleucine deprivation and serum starvation points, while the G1 block in ts-559 is after the serum starvation point but before the isoleucine block. Other G1 block points which have been reported are in mutants of different species and isolated in different laboratories, causing difficulties for relative positioning of the blocks in G1. The mutants for mapping in this study have been isolated from the same cell line. The G1 ts arrest points of ts-559 and ts-694, and that found in ts-550C, together with nutritional deprivations and metabolic inhibitors, provide seven reference points which divide G1 into six segments, each of which is bracketed by two adjacent points: mitosis, ts-694 block, serum starvation arrest point, ts-559 block, isoleucine deprivation arrest point, ts-550C block, hydroxyurea or excess-thymidine arrest segment.     

Kinetics of G1 transit following brief starvation for serum factors

Growing fibroblasts such as 3T3 cells are well-known to enter a quiescent state (G0) after many hours of serum deprivation. They emerge from G0 upon readdition of serum and initiate DNA synthesis about 12 h later. In this paper, we analyzed the effects of brief periods of serum deprivation on the ability of cells in G1 to initiate DNA synthesis. Exponentially growing 3T3 fibroblasts were briefly deprived of serum and their progress into S phase was monitored by autoradiography of labeled nuclei. When 10% serum was added back to cultures deprived of serum for a few hours, the progress of G1 cells into S phase was delayed for intervals far in excess of the length of the serum deprivation. Longer serum starvations resulted in longer excess delays. Several transformed 3T3 derivatives were markedly less sensitive to this serum-induced G1 regression following deprivation. When 1 microgram/ml insulin (rather than 10% serum) was added back to the starved cultures, the G1 cells entered S phase immediately. Delay in S phase entry following serum readdition was completely prevented if insulin (and, to a lesser extent, EGF) was present during the starvation, was diminished if a lower serum concentration was used for readdition, and was partially abolished if 10% serum plus insulin was restored to the cultures. The above results, then, suggest that serum deprivation sensitizes the cells to an unidentified serum component which sets the cells back in G1, unless insulin is present to maintain the flow of cells into S.     

A temperature-sensitive cell cycle mutant of the BHK cell line

A temperature-sensitive growth mutant derived from the BHK 21 cell Line, ts AF8, was found to have greatly reduced DNA synthesis at the nonpermissive temperature. This reduction is mainly due to a decrease in the frequency of cells synthesizing DNA. Upon shift up, ts AF8 becomes blocked in the G1 phase of the cell cycle. The cells acquire elevated cAMP levels and a unimodal distribution of DNA content, equivalent to that of G1 cells at the permissive temperature, Ts AF8 cells blocked at the G1/S boundary with hydroxyurea will enter S when shifted to the nonpermissive temperature. On the other hand, ts AF8 cells arrested m G1 by serum deprivation and shifted to the nonpermissive temperature at the moment of serum addition do not enter S, while those synchronized by isoleucine deprivation and shifted at the time of isoleucine addition will enter S. These data suggest that the cycle arrest point of the ts AF8 mutation is located in G1 between the blocks induced by serum starvation and isoleucine deprivation. The reduction in DNA synthesis caused by the ts AF8 mutation is not reversed by infection or transformation with Polyoma virus. Mitochondrial DNA continues to be synthesized at wild-type levels at the nonpermissive temperature.     

Involvement of Fis protein in replication of the Escherichia coli chromosome.

We report evidence indicating that Fis protein plays a role in initiation of replication at oriC in vivo. At high temperatures, fis null mutants form filamentous cells, show aberrant nucleoid segregation, and are unable to form single colonies. DNA synthesis is inhibited in these fis mutant strains following upshift to 44 degrees C. The pattern of DNA synthesis inhibition upon temperature upshift and the requirement for RNA synthesis, but not protein synthesis, for resumed DNA synthesis upon downshift to 32 degrees C indicate that synthesis is affected in the initiation phase. fis mutations act synergistically with gyrB alleles known to affect initiation. oriC-dependent plasmids are poorly established and maintained in fis mutant strains. Finally, purified Fis protein interacts in vitro with sites in oriC. These interactions could be involved in mediating the effect of Fis on DNA synthesis in vivo.     

Cytoplasmic regulation of two G1-specific temperature-sensitive functions

tsAF8 and ts13 cells are temperature-sensitive (ts) mutants of BHK cells that specifically arrest, at nonpermissive temperature, in the G1 phase of the cell cycle. These two mutants can complement each other. Both cell lines can be made quiescent by serum deprivation (G0). When subsequently stimulated by serum, they can enter S phase at 34 degrees C but not at 39.5 degrees-40.6 degrees C. We have used these mutants to determine whether the nucleus is needed during the G0 leads to S transition for the expression of the G1 ts functions. For this purpose, we fused cytoplasts of G0-tsAF8 with whole ts13 cells in G0, and cytoplasts of G0-ts13 with whole tsAF8 cells in G0. Serum stimulation at the nonpermissive temperature induced DNA synthesis in both types of such fusion products. No DNA synthesis was induced by serum stimulation at the nonpermissive temperature in fusion products constructed between either G0-tsAF8 cytoplasts and whole G0-tsAF8 cells or G0-ts13 cytoplasts and whole G0-ts13 cells. These results demonstrate that the information for these two ts functions, which are required for entry of serum-stimulated cells into the S phase, are already present in the cytoplasm of G0 cells--that is, before serum stimulation commits them to the transition from the nonproliferating to the proliferating state.     

GC-7 cells are growth arrested by cytochalasin D at two different points in the cell cycle

GC-7 cells, a cell line from African green monkey kidney, which had been growth arrested in G0 phase by serum deprivation, entered S phase 15 h after serum stimulation. They were blocked from entering S phase in the presence of 0.6 micrograms/ml of cytochalasin D. The cells growth arrested between G0 and S phase by cytochalasin D entered S phase 6 h following the removal of the drug. The progression of S, G2, and M phases was not affected by cytochalasin D. On the other hand, when G0-arrested GC-7 cells were stimulated with serum for 23 h up to a late S/G2 phase and then cultured in the presence of cytochalasin D, or when an exponentially growing culture was treated with the drug, the cells were growth arrested at a point 15 h, not 6 h, before the next S phase. This point of growth arrest is kinetically similar to G0 phase, both occur 15 h before S phase, but is different from G0 in terms of c-fos expression after release from the block.     

Serum-mediated regulation of amino acid transport in cultured chick embryo fibroblasts

Three different temperature sensitive mutants derived from the Syrian hamster cell line BHK 21 were found to have greatly reduced DNA synthesis at the non-permissive temperature. These mutants are distinct by complementation analysis and behave at the non-permissive temperature as cell cycle traverse defective mutants. Microfluorometric analysis of mutant populations arrested at the non-permissive temperature shows an accumulation of cells with G1 DNA content. Mutants ts 13 and ts HJ4 synchronized in G1 by serum or isoleucine deprivation and shifted to the non-permissive temperature at the time of release do not enter the S phase, while in the case of mutant ts 11 preincubation at the non-permissive temperature before release is required to completely prevent its entry into S. Ts 13 and ts 11 are able to traverse the S phase at the non-permissive temperature when synchronized at the boundary G1/S; in this case, preincubation of ts 11 at the non-permissive temperature before release does not affect the ability of these cells to perform DNA synthesis. On the other hand, ts HJ4 appears to traverse S only partially when tested under similar conditions. Temperature shift experiments of mutant populations at different times after isoleucine synchronization suggest that ts 13 and ts 11 are blocked at the non-permissive temperature in early G1, whereas ts HJ4 is probably affected near the initiation of DNA synthesis, or in some early S function.     

Cl- channel blockers inhibit transition of quiescent (G0) fibroblasts into the cell cycle

Modulation of ion permeability during the cell cycle is one of the key events in cell cycle progression. We have compared the effects of K+ and Cl- channel blockers on the cell cycle in synchronous and asynchronous NIH3T3 cells. The Cl- channel blocker 5-N-2-(3-phenylpropylamino) benzoic acid (NPPB; 0.2 mM) inhibited entry into S phase in synchronous cells but not in asynchronous cells, while the K+ channel blocker 4-aminopyridine (4-AP) showed similar inhibitory effects in both conditions. In NIH3T3 cells synchronized by serum deprivation/replenishment, G0-to-G1 transition occurred within 8 h after serum addition, and the G1/S checkpoint at 10-14 h. NPPB applied only at 0-8 or 8-14 h after serum addition inhibited entry into S phase. Cl- permeability measured as 125I efflux increased at 4 and 10 h after serum addition. Ki-67-negative cells, which represent quiescent G0 phase cells, progressively decreased in number until 8 h after serum addition. The Cl- channel blockers (NPPB and 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid [DIDS]) but not the K+ channel blocker (4-AP) significantly decreased the rate of reduction in number of Ki-67-negative cells. These data indicate that an increase in Cl- permeability plays an important role in reentry of quiescent cells into the proliferating phase, in addition to the known effects on passage through the G1/S checkpoint.     

Elevation of intracellular glutathione content associated with mitogenic stimulation of quiescent fibroblasts

The relationship between total glutathione (GSH) content and cell growth was examined in 3T3 fibroblasts. The intracellular GSH level of actively growing cultures gradually decreases as these cells become quiescent by either serum deprivation or high cell density. Upon mitogenic stimulation of sparse, quiescent (G0/G1) cultures with serum, there is a rapid 2.3-fold elevation in intracellular GSH levels which is maximal by 1 h and returns to baseline by 2 h. This is followed by a more gradual increase in GSH content as cells enter the S phase. In addition, the elevation in GSH content is required for maximum induction of DNA synthesis. Treatments that prevent the early increase in intracellular GSH levels do not affect protein synthesis but result in a reversible dose-dependent decrease in the percent of cells capable of entering S phase. These results indicate that GSH may be important in the regulation of cellular proliferation.     

Identification of adenovirus 2 early genes required for induction of cellular DNA synthesis in resting hamster cells.

tsAF8 cells are temperature-sensitive (ts) mutants of BHK-21 cells that arrest at the nonpermissive temperature in the G1 phase of the cell cycle. When made quiescent by serum restriction, they can be stimulated to enter the S phase by 10% serum at 34 degrees C, but not at 40.6 degrees C. Infection by adenovirus type 2 or type 5 stimulates cellular DNA synthesis in tsAF8 cells at both 34 and 40.6 degrees C. Infection of these cells with deletion Ad5dl312, Ad5dl313, Ad2 delta p305, and Ad2+D1) and temperature-sensitive (H5ts125, H5ts36) mutants of adenovirus indicates that the expression of both early regions 1A and 2 is needed to induce quiescent tsAF8 cells to enter the S phase at the permissive temperature. This finding has been confirmed by microinjection of selected adenovirus DNA fragments into the nucleus of tsAF8 cells. In addition, we have shown that additional viral functions encoded by early regions 1B and 5 are required for the induction of cellular DNA synthesis at the nonpermissive temperature.     

Cell cycle parameters of adult rat hepatocytes in a defined medium. A note on the timing of nucleolar DNA replication

Hepatocytes, isolated from adult (250-350 g) rats, attached and survived well in primary culture on highly diluted (less than 1 microgram/cm2) collagen gel in a synthetic medium without serum or hormones. About 20% of the cells "spontaneously" entered S phase during the first 4 days of culturing, and mitoses were easily demonstrated at the near physiological concentration (1.25 mM) of Ca++ prevailing in the medium. Cultures given 9 nM epidermal growth factor (EGF) and 20 nM insulin 20 h after inoculation showed vigorous DNA synthesis and mitotic activity. Autoradiography of such cells exposed to [3H]thymidine allowed the determination of the following cell cycle parameters: Lag period from EGF/insulin stimulation till onset of increased DNA synthesis, 17 h; rate of entry into S phase (kG1/S), 0.028/h; duration of S phase, 8.4 h; duration of G2 phase, 2.7 h. The peak DNA synthesis (pulse labelling index, 24%) and peak mitotic activity (mitotic index, 1.7%) occurred 35 and 43 h, respectively, after the stimulation with EGF/insulin. These values are comparable to those reported during the in vivo compensatory hyperplasia following partial hepatectomy of adult rats. A marked variation of the intranuclear [3H]thymidine pulse labelling pattern was noted: During the first 1.5 h of the S phase, the labelling was extranucleolar and during the last 1.5 h chiefly nucleolar. The cells survived well in the absence of glucocorticoid, whose effect on cell cycle parameters therefore could be studied. Dexamethasone (25-250 nM) did not appreciably affect the durations of S phase and G2 phase or the pattern of preferential extranucleolar and nucleolar DNA synthesis within the S phase.     

Exogenous GM1 ganglioside caused G1-arrest of human diploid fibroblasts. Flow cytometric studies

Exogenous GM1 ganglioside (II3 NeuAc-Gg0se4-Cer) inhibited growth and DNA synthesis of human diploid fibroblasts, TIG-1 cells. We examined the effect of exogenous GM1 on their cell cycle traverse by flow cytometry. When the cells were partially synchronized by serum deprivation, addition of GM1 at the time of refeeding caused about 70% reduction of their reentry into S phase from the level observed in the control culture untreated with the ganglioside. However, the addition of GM1 6 h later caused only about 30% reduction of the reentry from the control level. These results suggest that the exogenous ganglioside blocks the cell cycle traverse in an early G1 period. This is consistent with the fact that GM1-treated cells showed a high level of histone H1(0) similar to that observed in G1-arrested cells in confluent culture.     

Expression of histone genes in a G1-specific temperature-sensitive mutant of the cell cycle

The expression of genes coding for the four core histones (H2A, H2B, H3, and H4) was studied in tsAF8 cells. These baby hamster kidney-derived cells are a temperature-sensitive (ts) mutant of the cell cycle that arrest in G1 at the restrictive temperature. When serum-deprived tsAF8 cells are stimulated with serum, they enter the S phase at the permissive temperature of 34 degrees C, but are blocked in G1 at the nonpermissive temperature of 39.6 degrees C. Northern blot analysis using cloned human histone DNA probes detected only very low levels of histone RNA either in quiescent tsAF8 cells or in cells serum stimulated at the nonpermissive temperature for 24 h. Cellular levels of histone RNA were markedly increased in cells serum stimulated at 34 degrees C for 24 h. Temperature shift-up experiments after serum stimulation of quiescent populations showed that the amount of histone RNA was related to the number of cells that entered the S phase. Those cells that synthesized histone RNA and entered the S phase were capable of dividing. This is the first demonstration in a mammalian G1-specific ts mutant that the expression of H2A, H2B, H3, and H4 histone genes depends on the entry of cells into the S phase of the cell cycle.     

NADH-dependent O-deethylation of p-nitrophenetole with rabbit liver microsomes.

A previous paper in this series (C. K. Mathews, (1972) J. Biol. Chem.247, 7430) showed that deoxynucleoside triphosphate pools expand manyfold when DNA synthesis is blocked genetically in infection by bacteriophage T4. This paper describes a more detailed analysis of this phenomenon. The key approach involves labeling with thymine or thymidine under conditions of infection where both phage and host bear mutations that inactivate thymidylate synthetase. Principal findings include the following: (1) Nucleotides in the expanded pools are derived in roughly equal measure from breakdown of host cell DNA and from nucleotide synthesis de novo after infection. (2) Thymidine diphosphate pool expansion is comparable, in rate and extent, to thymidine triphosphate pool expansion, but thymidine monophosphate pools accumulate much less. (3) The rate of expansion of the total thymine nucleotide pool following temperature upshift in infection by a temperature-sensitive gene 45 mutant is approximately equal to the rate of thymine incorporation into DNA immediately preceding the upshift. (4) Similarly, when DNA synthesis is restored by a downshift, the total thymine nucleotide pool drains at a rate commensurate with that of thymine incorporation into DNA. (5) Under these latter conditions the dTTP pool begins to drain earlier than the dTDP pool, suggesting that dTTP is the more proximal DNA precursor in this system.     

Plasma and platelet associated factors act in G1 to maintain proliferation and to stabilize arrested cells in a viable quiescent state : A temporal map of control points in the G1 phase

In medium supplemented with defibrinogenated, platelet-poor human plasma and a low molecular weight growth factor derived from human platelets (PDGF), Swiss 3T3 cells proliferate exponentially with the same cell cycle kinetics as cells cultured in medium supplemented with commercial calf serum. Removal of PDGF from the culture medium arrests proliferating cells in a stable, reversible G0/G1 quiescent state. This arrested state is similar to the known quiescent state induced by deprivation of calf serum in cell exit kinetics and cytoplasmic proteins synthesized. Cells are sensitive to PDGF deprivation only at the beginning of G1. Reduction of the plasma concentration in the culture medium also arrests cells in G1. The resulting arrested population is unstable and exhibits progressive cell death. Reduced levels of plasma block cellular transit through the cell cycle at a median time of approx. 2.1 h following mitosis, approx. 3.3 h prior to S phase initiation. In addition to being required by cycling cells, plasma associated factors are required to maintain G1 cells blocked by PDGF deprivation in a stable quiescent state. Establishment of a stable, viable G0/G1 growth-arrested state, therefore, apparently involves two distinct processes: arrest of cellular proliferation in G1 and stabilization of the arrested cells in a viable quiescent state. Together with previously reported findings on serum and isoleucine starvation, these results provide a temporal map of growth control points in the G1 phase.