Preliminary characterization of the temperature-sensitive defect in DNA replication in a mutant mouse L cell

Temperature-sensitive Chinese hamster fibroblast mutant with a defect in RNA metabolism

We describe a new temperature-sensitive mutant of Chinese hamster cell fibroblasts. After a shift to the nonpermissive temperature of 40.5 degrees C, the rates of DNA, RNA, and protein synthesis declined rapidly (to < or = 50% within 12 h) and the progression of unsynchronized cells through the cell cycle was affected. We believe that DNA synthesis came to a halt after a short time, because cells no longer entered the S phase. The decrease in protein synthesis at 40.5 degrees C was shown to be a consequence of a decrease in the number of polysomes, whereas free 80S ribosomes accumulated. We concluded that the components of the protein biosynthetic machinery were intact (ribosomes and soluble factors), but synthesis was limited by a shortage of mRNA. The decline in mRNA production had a significant effect on the synthesis of proteins (e.g., heat shock proteins) translated from short-lived messages. We observed that both polyadenylated and nonpolyadenylated RNA syntheses declined at 40.5 degrees C, whereas the synthesis of small RNAs (4 to 5S) was less reduced. The argument is made that the temperature-sensitive phenotype is the result of a defect affecting mRNA synthesis.

Nuclear localization of the ubiquitin-activating enzyme, E1, is cell-cycle-dependent

The mechanisms that regulate ubiquitin-mediated degradation of proteins such as the mitotic cyclins at defined stages of the cell cycle are poorly understood. The initial step in the conjugation of ubiquitin to substrate proteins involves the activation of ubiquitin by the ubiquitin-activating enzyme, E1. Previously we have described the subcellular localization of this enzyme to both nuclear and cytoplasmic compartments. In the present study, we have used the 1C5 anti-E1 monoclonal antibody in immunofluorescent-microscopy and subcellular-fractionation techniques to examine the distribution of E1 during the HeLa cell cycle. E1 is both cytoskeletal and nuclear during the G1-phase. As the cells progress into S-phase, E1 is exclusively cytoskeletal and has a perinuclear distribution. During G2-phase, E1 reappears in the nucleus before breakdown of the nuclear envelope. In mitotic cells, E1 localizes to both the mitotic spindle and the cytosol, but is absent from the chromosomes. Immunoblot analysis reveals multiple forms of E1 in HeLa whole cell extract. This heterogeneity is not a result of polyubiquitination and may represent inactive pools of E1. Only the characteristic E1 doublet is able to activate ubiquitin. Cell-fractionation studies reveal a differential distribution of specific E1 isoforms throughout the cell cycle. Therefore we propose that the subcellular localization of E1 may play a role in regulating cell-cycle-dependent conjugation of ubiquitin to target proteins.

tsBN75 and tsBN423, temperature-sensitive x-linked mutants of the BHK21 cell line, can be complemented by the ubiquitin-activating enzyme E1 cDNA

tsBN75 and tsBN423 are independently isolated temperature-sensitive (ts) mutants of the BHK21 cell line for cell growth. Both tsBN75 and tsBN423 belong to the same complementation group and show G2 block at the nonpermissive temperature. Both were efficiently transformed to ts+ cells with the mouse and human cDNA encoding the ubiquitin-activating enzyme, E1. While no transformants of tsBN423 cells had a DNA content greater than the parental 2C, several ts+ transformants of tsBN75 cells acquired a multiploid DNA content. These data thus demonstrate the function of the human and mouse E1 cDNAs and further suggest that E1 functions in more than one step in cell cycle progression.

Inhibitors of DNA topoisomerase II prevent chromatid separation in mammalian cells but do not prevent exit from mitosis

DNA topoisomerase II (EC 5.99.1.3) is necessary for chromosome condensation and disjunction in yeast but not for other functions. In mammalian cells, it has been reported to be necessary for progression toward mitosis but not for transit through mitosis. We have found, on the contrary, that specific inhibition of topoisomerase II (but not of topoisomerase I) interferes with mammalian mitotic progression. Metaphase is prolonged, and anaphase separation of chromatids is completely inhibited, in cells given high concentrations of topoisomerase II inhibitors; nevertheless these cells attempt cleavage, sometimes generating nucleate and anucleate daughters. Lower concentrations of inhibitors interfere with anaphase and produce abnormalities of segregation. DNA topoisomerase II activity is therefore necessary for mammalian chromatid separation, but it is not tightly coupled to the control of other mitotic events.

DNA polymerase-primase complex in wild-type and ts A1S9 mouse L-cells, temperature-sensitive for DNA replication during cell cycle progression

ts A1S9 mutant cells, derived from wild type WT-4 mouse L-cells, are temperature-sensitive (ts) for DNA synthesis and cell division. We try to determine the cause of the arrest of DNA replication in ts A1S9 cells at the nonpermissive temperature by comparing the modifications induced by the shift of temperature on the activity and the synthesis of DNA polymerase-alpha and DNA primase as a function of time. Forty-seven hours after temperature upshift DNA polymerase-alpha activity of ts A1S9 cells was inhibited by 90% while primase activity was barely detectable. By contrast, the activities of both enzymes increased to a plateau level in WT-4 cultured at either temperature and in ts A1S9 cells grown at the low permissive temperature. Study of the synthesis of DNA polymerase-alpha primase and of the structure of the enzyme complex during cell cycle progression was approached by immunoprecipitation of [35S]-labelled cells, with a specific monoclonal antibody directed against DNA polymerase-alpha. We have found that, irrespective of temperature of cultivation of WT-4 or ts A1S9 cells, this antibody precipitated polypeptides of 220, 186, 150, 110, 68-70, 60, and 48 kDa from cell extracts. With ts A1S9 cells cultivated at 38.5 degrees C for 48 hr the polypeptides of 220 and 186 kDa, associated with alpha-polymerase activity, were considerably more abundant than in the control cells, with a concomitant decline in the polypeptides of 60 and 48 kDa, implicated in primase activity. Thus the inhibition of DNA polymerase-alpha cannot be due to a decreased synthesis of the 186 kDa subunit but to its temperature inactivation. Consistent with a recent asymmetric dimeric model where polymerase-alpha complex and polymerase delta complex synthesize co-ordinately at the replication fork lagging and leading DNA strands, the observed alterations of polymerase-alpha and primase content explain the inhibition of DNA synthesis and the cell cycle arrest of the ts A1S9 cells at the nonpermissive temperature.

Molecular cloning of human A1S9 locus: an X-linked gene essential for progression through S phase of the cell cycle

The temperature-sensitive (ts) A1S9 mouse L-cell mutant is defective in an X-linked gene essential for the progression of cells through the S phase of the cell duplication cycle. We recently reported the complementation of the ts A1S9 cell defect with total human DNA and the isolation of independent temperature-resistant transformants that retained a common set of human specific Alu-containing fragments. Here we describe the molecular cloning of these human DNA sequences from one of the secondary transformants. ST-1-0. A genomic library prepared from ST-1-0 was screened with a total human DNA probe, and two recombinant bacteriophages carrying overlapping segments were isolated. The cloned region was extended in both directions using a human X-chromosome specific library. In total, a human region spanning 42 kb in length, and containing all the Alu-specific DNA sequences found in ST-1-0, was isolated in five overlapping recombinant phages. The A1S9 gene appeared to be larger than the DNA recovered in individual phage isolates, as was assessed by transfection experiments. A single-copy probe derived from the phage DNA was shown to be conserved in independent primary, secondary, and tertiary transformants of ts A1S9 cells and mapped to the X chromosome by molecular hybridization. Northern blot hybridization of this probe with poly(A)+ mRNA derived from ST-1-0 cells identified a transcript of about 3.6 kb.

Gene on short arm of human X chromosome complements murine tsA1S9 DNA synthesis mutation

We have created somatic cell hybrids between the temperature-sensitive mouse cell line tsA1S9 and human cell lines in order to localize the human gene (A1S9T) complementing the cell cycle defect of the murine line. Segregation of the human X chromosome is completely concordant with growth at the nonpermissive temperature. Hybrids retaining the X chromosome are temperature-resistant, whereas those without a human X are temperature-sensitive. Further hybrids made using human cell lines with X-autosome translocations indicate that the A1S9T gene is located on the short arm of the human X chromosome.

Identification of human gene complementing ts AlS9 mouse L-cell defect in DNA replication following DNA-mediated gene transfer

The temperature-sensitive (ts) mouse L-cell, ts AlS9, is defective in a gene required for nuclear DNA replication early in the S phase of the cell cycle. Human DNA sequences were introduced into ts AlS9 cells together with the plasmid pSV2neo, which can confer resistance to the drug geneticin. Cotransformants, expressing both the plasmid-derived neomycin gene and the transferred human AlS9 gene, were selected for growth in the presence of the drug at the nonpermissive temperature (npt). The resulting transformants retained a common set of human-specific Alu repetitive DNA sequences. These are likely to be accommodated within, or in proximity to, the transferred human AlS9 gene. The results obtained provide the basis for cloning human genes required for DNA replication.

DNA flow cytometry of control Euglena and cell cycle blockade of vitamin B12-starved cells

Vitamin B12 starvation in Euglena induces a cell cycle arrest that leads to unbalanced growth. Microfluorometry and flow cytometry analyses of cellular DNA fluorescence after Hoechst 33258 staining were performed on control and vitamin B12-deficient cells. Convergent results are obtained with both methods. Histograms that represent arrested cells are unimodal, with a mode channel value nearly twice that of the G1 control cell peak. Dispersion of fluorescence values is great, and values from 2C and over 4C are observed and discussed. It appears that vitamin B12 starvation in Euglena leads to defective DNA synthesis. Blocked cells have different DNA content, corresponding to blockade of DNA replication during the S phase. A second block prevents the onset of mitosis even for 4C cells.

Species-specific in vitro synthesis of DNA containing the polyoma virus origin of replication

In vitro replication of DNA containing the polyoma (Py) virus origin of replication has been carried out with cell-free extracts prepared from mouse FM3A cells. The in vitro system required the Py virus-encoded large tumor (T) antigen, DNA containing the Py virus origin of replication, ATP, and an ATP-regenerating system. The replication reaction was inhibited by aphidicolin, suggesting the involvement of DNA polymerase alpha in this system. Simian virus 40 (SV40) T antigen could not substitute for the Py T antigen. Cell extracts prepared from HeLa cells, a source that replicates SV40 DNA in the presence of SV40 T antigen, replicated Py DNA poorly. The addition of purified DNA polymerase alpha-primase complex isolated from FM3A cells enabled HeLa cell extracts to replicate Py DNA with the same efficiency as FM3A cell extracts. Complementary experiments have shown that FM3A cell extracts do not support SV40 DNA replication unless supplemented with DNA polymerase alpha-primase complex from HeLa cells [Murakami, Y., Wobbe, C.R., Weissbach, L., Dean, F.B. & Hurwitz, J. (1986) Proc. Natl. Acad. Sci. USA 83, 2869-2873]. These results indicate that the host-cell source of the DNA polymerase alpha-primase complex plays an important role in discriminating between SV40 T antigen- and Py T antigen-dependent replication of their homologous DNA in vitro. This may explain the host-range specificity of these viruses in vivo.

Conversion of replicative intermediates in human DNA-repair defective cells

We have examined the conversion of intermediates of DNA replication in normal human skin fibroblasts and fibroblasts isolated from patients with genetic diseases caused by putative DNA repair defects. Experiments were performed in non-transformed, unchallenged cells using alkaline sucrose sedimentation analysis to demonstrate precursor low molecular weight (LMW) DNA molecules which converted into high molecular weight (HMW) DNA with time. Analyses of conversion of replicative intermediates were conducted in cells from patients with ataxia telangiectasia (AT), Fanconi anemia (FA), Bloom syndrome (BS), Cockayne syndrome (CS) and xeroderma pigmentosum (XP). Our studies show that conversion of replicative intermediates occurs in all cell strains examined. However, XP cells (complementation groups A and E) show evidence of abnormalities in the conversion of LMW replicative intermediates, with the most dramatic alterations shown by cells from complementation group A.

Characterization of a temperature-sensitive mutant of mouse FM3A cells defective in DNA replication

The characterization of a temperature-sensitive mutant (tsFT20 strain, dnats) of mouse FM3A cells is reported. After incubation of tsFT20 cells at the nonpermissive temperature (39 degrees C), DNA synthesis ceased with little change in either RNA or protein synthesis. Flow-microfluorometric analysis revealed that the cell cycle of tsFT20 cells grown at 39 degrees C for 16 hr was similar to that of wild-type cells that were synchronized at the G1/S boundary and at S phase by treatment with aphidicolin, a specific inhibitor of DNA polymerase alpha. The DNA polymerase alpha activity of tsFT20 cells measured in crude cell extracts or in purified preparations was inactivated more rapidly at 39 degrees C than the activity of wild-type cells. In the growth revertants of the tsFT20 cell strain, the heat lability of DNA polymerase alpha decreased. These data suggest that tsFT20 is a temperature-sensitive mutant of DNA polymerase alpha or of a factor associated with DNA polymerase alpha that is essential for its activity.

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.

Isolation and characterization of mutator mutants from cultured mouse FM3A cells

A method to select mutator mutants was developed and 3 mutants were isolated from cultured mouse FM3A cells. Fluctuation analyses revealed that these mutator mutants have increased rates of spontaneous mutation at 3 genetic loci tested (resistance to ouabain, blasticidin S and tunicamycin). None of the 3 mutator mutants showed altered sensitivity to aphidicolin or arabinofuranosylcytosine, and so they differed from the mammalian mutator mutants reported previously. Also, all the mutator mutants had the same sensitivity as wild-type to UV or other DNA-damaging agents. Thus, these mutator mutants do not seem to have any deficiency in the DNA-repair process. To determine whether the mutator activity was due to the intracellular dNTP pool imbalance, 4 dNTPs in these mutator mutants were determined by high-pressure liquid chromatography and compared to that of the wild-type cells. The results show that there is no large dNTP pool imbalance in these mutator mutants. Since the mutator activity is not associated with the dNTP pool imbalance, these mutants may have altered protein(s) directly involved in DNA replication.

Analysis of a Chinese hamster temperature-sensitive cell cycle mutant arrested in early S phase

E36 ts24 is a temperature-sensitive cell cycle mutant which has been derived from the Chinese hamster lung cell line E36. This mutant is arrested in phase S when incubated at the restrictive temperature (40.3 degrees C) for growth. At this temperature, proliferation of the mutant cells ceases after 10 h. About 2 h earlier, DNA synthesis is arrested. These kinetic studies indicate that the execution point of the mutant cells is in early S phase well beyond the G1/S boundary. The pattern of replication bands in E36 ts24 cell grown for 9 h at 40.3 degrees C strengthen the kinetic studies and map the execution point to early S phase. The exact point of arrest of the mutant cells in phase S was mapped in early S phase near the execution point. At the point of arrest the cells continue to synthesize DNA at at a high rate but practically all of the newly synthesized DNA is degraded. This high rate of DNA degradation is limited to nascent DNA at the point of arrest. In the presence of 5-bromodeoxyuridine (5-BudR), the last E36 ts24 cells which reach mitosis at the restrictive temperature for growth show asymmetric replication bands which illustrate DNA degradation and resynthesis occurring in these cells at 40.3 degrees C.

ts A1S9 locus in mouse L cells may encode a novobiocin binding protein that is required for DNA topoisomerase II activity

Nuclear novobiocin binding proteins (NBPs) from a set of mouse L cells have been extensively purified by affinity chromatography on novobiocin-Sepharose columns. The NBPs, specifically eluted with 100 micrograms of novobiocin per ml, exhibited equivalent DNA topoisomerase activities (measured as ATP-dependent relaxation or catenation of phi X174 replicative-form I DNA substrate) when extracted from equal numbers of wild-type (WT-4) mouse L cells growing logarithmically at 34 degrees C or at 38.5 degrees C, from ts A1S9 cells similarly cultivated at the low, permissive temperature or from revertant ts+ AR cells in exponential growth at either temperature. The NBPs isolated from similar numbers of ts A1S9 cells grown to midlogarithmic phase and then incubated for 24 hr at 38.5 degrees C (the nonpermissive temperature) showed no topoisomerase II activity. Preliminary NaDodSO4/polyacrylamide gel electrophoretic analysis of enzymatically active material revealed that the NBPs of WT-4 and ts+ AR cells grown at 34 degrees C comprised three major polypeptides of 76,000, 74,000, and 30,000 daltons and a number of larger molecular mass components present in trace amounts. The NBP of ts A1S9 cells grown at the permissive temperature was similar, except that the 30,000-kilodalton polypeptide was not detected. Such enzymatically active NBPs from WT-4 and ts+ AR cells were unaffected by 100 micrograms of novobiocin per ml, whereas the analogous preparation from ts A1S9 cells was totally inhibited. On the basis of these and other considerations, it is postulated that the ts A1S9 locus of mouse L cells encodes a temperature-sensitive polypeptide that is required for normal DNA topoisomerase II activity.

Synthesis of multimeric polyoma virus DNA in mouse L-cells: role of the tsA1S9 gene product

Several different forms of progeny viral DNA can be identified in polyoma virus (Py)-infected mouse L-cells. The majority comprise mature form I superhelical DNA and the circular, double-stranded "theta" replicating intermediates in which the progeny DNA strands never exceed the unit genome length of the template. There is formed, in addition, a minority fraction of multimeric, linear, double-stranded Py DNA molecules that sediment heterogeneously at 28 to 35S and greater than 35S. Restriction enzyme analysis of these large Py DNA molecules reveals them to be tandem arrays of multiple unit genome lengths, covalently linked head to tail. It is estimated that the 28 to 35S multimeric DNA has an average size of about 20 megadaltons, made up of 6 to 20 Py genome units. The greater than 35S Py DNA is, of course, larger. Kinetic analysis indicates that formation of the monomeric progeny viral DNA and the 28 to 35S multimeric Py DNA reaches a peak at about 35 to 36 h postinfection. Synthesis of the very large linear molecules of greater than 35S is first detected after this interval and continues thereafter. The de novo synthesis of all of these progeny Py DNA molecules proceeds apparently normally in Py-infected tsA1S9 mouse L-cells incubated at 38.5 degrees C under conditions which restrict normal cellular DNA replication. These findings suggest that the cellular DNA topoisomerase II activity, encoded in the tsA1S9 locus (R. W. Colwill and R. Sheinin, submitted for publication), is not required for de novo formation of any form of Py DNA. However, the total amount made and the rate of synthesis of the large molecular weight Py DNA are affected very late in temperature-inactivated tsA1S9 cells.

Temperature-Sensitive Chinese Hamster Fibroblast Mutant with a Defect in RNA Metabolism

We describe a new temperature-sensitive mutant of Chinese hamster cell fibroblasts. After a shift to the nonpermissive temperature of 40.5°C, the rates of DNA, RNA, and protein synthesis declined rapidly (to ≤50% within 12 h) and the progression of unsynchronized cells through the cell cycle was affected. We believe that DNA synthesis came to a halt after a short time, because cells no longer entered the S phase. The decrease in protein synthesis at 40.5°C was shown to be a consequence of a decrease in the number of polysomes, whereas free 80S ribosomes accumulated. We concluded that the components of the protein biosynthetic machinery were intact (ribosomes and soluble factors), but synthesis was limited by a shortage of mRNA. The decline in mRNA production had a significant effect on the synthesis of proteins (e.g., heat shock proteins) translated from short-lived messages. We observed that both polyadenylated and nonpolyadenylated RNA syntheses declined at 40.5°C, whereas the synthesis of small RNAs (4 to 5S) was less reduced. The argument is made that the temperature-sensitive phenotype is the result of a defect affecting mRNA synthesis.

Large-scale selection and analysis of temperature-sensitive mutants for cell reproduction from BHK cells

Temperature-sensitive (ts) mutant cells for cell reproduction were isolated from the Syrian hamster cell line BHK21/13 by multiple culturing in the presence of 5-fluoro-2'-deoxyuridine (FdU) at 37.5 degrees after N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. A simple method for cell fusion was devised, which enabled us to perform complementation studies with a large number of ts mutants. By using the method we have analyzed 219 ts mutants and classified them into 18 complementation groups. Mutants that belonged to the same complementation groups tended to exhibit similar patterns of inhibition of DNA synthesis at 39.5 degrees; however, some mutants belonging to the same group showed somewhat different patterns, probably due to occurrence of different mutations in the same gene. Distribution of the ts mutants among the 18 complementation groups was uneven; more than 50% of the mutants examined were assigned to complementation group B and G. The mutations belonging to complementation group B and G were found to be linked to the X chromosome.

Studies on cell division in mammalian cells: VI. A temperature-sensitive mutant blocked in both G1 and G2 phases of the cell cycle

A temperature-sensitive mammalian cell cycle mutant with blocks in G1 and G2 phases of the cell cycle has been isolated in culture. When shifted from the permissive temperature of 33 degrees C to the nonpermissive temperature of 39 degrees C, the fraction of cells initiating DNA synthesis as well as the fraction of cells entering mitosis decreased rapidly. Combined cytophotometric and autoradiographic analysis on the cells at 39 degrees C showed that G1 cells, with the exception of those in late G1, were arrested in that phase. Cells is S phase at the time of temperature shift, together with the late g1 cells which subsequently entered S, continued through S into G2, but were blocked in that phase of the cell cycle and unable to initiate mitosis. Those cells already in mitosis completed cell division at 39 degrees C. The G1 block point of ts-550C was found to be located after the serum starvation and isoleucine deprivation arrest points, approximately 3 h before initiation of DNA synthesis.

A temperature-sensitive DNA synthesis mutant isolated from the Chinese hamster ovary cell line

A temperature-sensitive DNA synthesis mutant, tsC8, was isolated from mutagenized Chinese hamster ovary cells by the fluorodeoxyuridine suicide technique. The tsC8 cells showed inhibition of DNA synthesis at the nonpermissive temperature (NPT) with little effect on initial levels of RNA and protein synthesis. Temperature-arrested tsC8 cells had G1 or S DNA content and the temperature-sensitive (ts) period of the tsC8 cell cycle was the interval between the G1/S border and the middle of the S period. The tsC8 cells were unable to enter the S phase when exposed to the NPT during the G1 period of the cell cycle. When S phase tsC8 cells were shifted to the NPT, they incorporated [3H]thymidine at rates similar to the parental cell type for only 2 h, indicating a ts defect in DNA synthesis. The tsC8 mutation is expressed in a recessive manner and is in a gene distinct from those affected in other DNA synthesis mammalian cell mutants.

Rapid decrease in thymidine kinase activity of mouse cell temperature-sensitive mutants at a non-permissive temperature

A rapid decrease in the incorporation of [3H]thymidine into DNA at a non-permissive temperature was observed in two temperature-sensitive mutants that were isolated from mouse FM3A cells. This change was not due to a decrease in the rate of DNA replication, but was closely associated with a decrease in thymidine kinase activity of these cells. Experiments to test thermolability of thymidine kinase in extracts showed that there are two components of the thymidine kinase, but there was no alteration in the sensitivity of the enzyme to high temperature. Also, the decrease in enzyme activity in the temperature-sensitive mutants at the non-permissive temperature occurred much faster than expected from the half-life of the enzyme in wild-type cells, which was measured in the presence of cycloheximide. These results suggested that the enzyme was somehow rapidly inactivated, or degraded, in the cells at the non-permissive temperature.

Poly(ADP-ribose) polymerase activity in mouse cells which exhibit temperature-sensitive DNA synthesis

The poly(ADP-ribose) polymerase activity of wild-type mouse L cells and of Balb/C-3T3 mouse fibroblasts remained relatively unchanged (at approx. 400 nmol substrate utilized/mg DNA per h) in actively-growing cells incubated at 34 degrees C or at 38.5 degrees C for at least 72 h. A similar result was obtained with the following temperature-sensitive cells grown at the permissive temperature (34 degrees C): ts A1S9 mouse L cells, ts C1 mouse L cells and Balb/C-3T3 ts mouse fibroblasts. The poly(ADP-ribose) polymerase activity of the temperature-sensitive cells was little affected during incubation for 20-24 h at the non-permissive temperature of 38.5 degrees C under which conditions temperature-inactivation of DNA replication was complete. Thereafter, this enzyme activity was found to increase some 2-fold, at a time when normal semi-conservative DNA synthesis was totally suppressed and replaced by repair replication (Sheinin, R. and Guttman, S. (1977) Biochim. Biophys. Acta 479, 105-118; Sheinin, R., Dardick, I. and Doane, F.W. (1980) Exp. Cell. Res., in the press).

Decreased initiation of DNA synthesis in a temperature-sensitive mutant of hamster cells

We have analyzed ongoing DNA replication in ts BN-2, a dna- mutant of BHK-21 cells (Nishimoto et al. '78). At the non-permissive temperature of 39.5 degrees C, inhibition of 3H-thymidine into acid-precipitable material begins 1 to 2 h after the cells are released from a block at the start of the S-phase. The fraction of nuclei incorporating 3H-thymidine is similar to that of wild-type cells through the synchronized S-phase of 8 h. Alkaline sucrose gradient analysis shows that pulse-labeled DNA from mutant cells is incorporated into high molecular weight material after 3 h at either the permissive or non-permissive temperature. DNA fiber autoradiograms reveal that, at 39.5 degrees C, the rate of replication fork movement is about 30% increased in the mutant as compared to wild-type cells. In the mutant cells, however, the interval between adjacent initiation sites is increased and the relative frequency of initiation events is decreased at the restrictive temperature. The results indicate that there is a block to ongoing replication in ts BN-2 at the level of initiation of synthesis on individual replication units; elongation of nascent chains is not inhibited.

Protein synthesis and degradation during expression of the temperature-sensitive defect in ts A1S9 mouse L-cells

The involvement of altered protein metabolism in the expression of the temperature-sensitive (ts) pleiotropic phenotype of ts A1S9 cells was investigated. Cells are ts in growth and DNA replication. They undergo decondensation of their heterochromatin, interruptions of chromatin synthesis, and changes in cell size and morphology at the non-permissive temperature (npt) of 38.5 degrees C. Whereas the rates of incorporation of 3H-leucine, 35S-methionine, and 3H-fucose into proteins were unaffected at 38.5 degrees C, net protein accumulation was greatly reduced. This imbalance resulted from a rapid increase in the rate of protein degradation at the npt. Enhancement of protein degradation was detected within 2-4 hours after temperature upshift and constitutes the earliest metabolic alteration thus far observed during expression of the temperature-sensitive phenotype. The average half-life of proteins performed in ts A1S9 cells at 34 degrees C was decreased four-fold at the npt, and all major cytoplasmic proteins were affected equally. Enhanced protein degradation at the npt was shown to be sensitive to cycloheximide, ammonia, chloroquine, and vinblastine at concentrations that did not affect the basal protein degradation of normally cycling cells. Increased protein degradation at 38.5 degrees C did not involve an equivalent increase in total cellular protease activity. The data obtained are compatible with a model that suggests that temperature inactivation of the ts A1S9 gene product results in activation of a lysosome-mediated mechanism for the rapid degradation of cytoplasmic proteins.

Studies on temperature-sensitive mutants of Chinese hamster ovary cells affected in DNA synthesis

DNA synthesis in two mutants of Chinese hamster overy cells, ts 13A and ts 15C, which were temperature sensitive for growth, was found to be shut off rapidly at the nonpermissive temperature. The mutants did not complement each other and the ts lesion was not located on the X chromosome. Both isolates were found to be considerably more sensitive to the alkylating agents, ethylmethanesulfonate (EMS) and methylmethanesulfonate (MMS), as compared to the parental cells, but showed normal sensitivity to UV irradiation. The mutants also showed interesting differences in their response to EMS-induced mutation frequencies at the ouabain-resistant and thioguanine-resistant loci. At high survival (50%) the frequencies of mutations at these genetic loci were markedly low in the ts mutants as compared to the parental cells. In ts+ revertants isolated from the mutants, the ts phenotype and the increased sensitivity to EMS and MMS were affected simultaneously, indicating that both these characteristics resulted from a single genetic lesion.

Temperature-sensitive mutants of BALB/3T3 cells. III. Hybrids between ts2 and other mouse mutant cells affected in DNA synthesis and correction of ts2 defect by human X chromosome

Complementation studies were performed with ts2, a mouse 3T3 cell mutant temperature sensitive (ts) for cell and viral DNA synthesis. The ts phenotype is corrected by non-ts mouse or human cells and a non-DNA ts mutant. This gene had been localized to a region on the human X chromosome near the HPRT locus based on isozyme and karyotype analysis of hybrids. Unusually rapid loss and fragmentation of human chromosomes occurs in hybrids with ts2. Hybrids between ts2 and other DNA- ts mutants of mouse cells did not show complementation of the growth phenotype.

DNA and histone synthesis in mouse cells which exhibit temperature-sensitive DNA synthesis

It is demonstrated that temperature inactivation of histone synthesis is coupled to inhibition of DNA replication in ts AlS9 and ts Cl mouse L-cells, which are temperature-sensitive (ts) in an S-phase function. In contrast, uncoupling of histone and DNA synthesis occurs in BalB/C-3T3 ts 2 cells which are ts in a function of the pre-DNA-synthetic phase. Termination of histone synthesis in ts AlS9 and ts Cl cells is 16--18 h after onset of temperature inactivation of DNA replication and appears to be associated with general cessation of chromatin replication triggered by the earlier event. Synthesis of histone and other chromosomal proteins proceeds in ts 2 cells under conditions in which DNA synthesis undergoes temperature inactivation. It is suggested that the terminal phenotype of coupled temperature inactivation of DNA and histone synthesis may be diagnostic of cells ts in an S-phase function and may therefore be a useful secondary screen in designation of cell cycle mutants.

A ts mutant isolated from CHL cells: inhibition of DNA replication at nonpermissive temperature

A mutant Chinese hamster cell clone has been isolated from an S phase culture. This clone, ts154, could not replicate DNA at nonpermissive temperature (39 degrees C), although it synthesized DNA normally at permissive temperature (33 degrees C). After transfer to 39 degrees, ts154 cells replicated DNA semiconservatively through precisely two complete rounds and divided twice before they ceased DNA synthesis and further growth. The mutation in ts154 affects DNA replication specifically, as its rates of cellular transcription, its ability to support growth of vesicular stomatitis virus, and its ribo- and deoxyribonucleoside triphosphate pools were normal at 39 degrees. Cultures of ts154 resumed DNA replication within 6h when shifted from 39 degrees to 33 degrees, even after 78 h at the nonpermissive temperature. Upon return to 33 degrees, mutant cells achieved a normal steady-state rate of DNA synthesis by 10 h, suggesting that they had come to rest within G1 phase at 39 degrees. Resumption of DNA synthesis and growth after a shift-down to 33 degrees were sensitive to cycloheximide in ts154, and thus likely required synthesis of new protein.

Premature of chromosome condensation in a ts DNA- mutant of BHK cells

A temperature-sensitive mutant of BHK, designated ts BN-2, shows a rapid drop in 3H-thymidine incorporation along with accumulation of the cells in the G1 phase of the cycle when asynchronous cultures are shifted from 33.5 degrees C to the nonpermissive temperature of 39.5 degrees C. Synchronized cultures of ts BN-2 cells did not enter DNA synthesis when shifted up in G1. Shift-up of cultures at the beginning of the S phase resulted in an approximately normal rate of DNA synthesis for about 2 hr. The rate of DNA synthesis then quickly declined, and the cells became arrested in mid-S after completion of approximately 0.5 rounds of DNA replication. At the same time, the majority of the cells were observed to lose the nuclear membrane and displayed premature chromosome condensation. These events were followed by the appearance of cells containing several micronuclei and eventual cell disruption and death. The nonpermissive temperature appeared to have no effect on either the elongation of short fragments of DNA or the execution of mitosis after the completion of the S phase under permissive conditions. The ts defect in this mutant may directly limit the initiation of DNA synthesis or alter the regulation of chromatin condensation.

Mutant mouse L-cells: a model for megaloblastic anaemia

When temperature-sensitive (ts) mutant lines of mouse L-cells, ts AIS9 and ts CI, are shifted from 34C to 38.5C, a rapid inhibition of DNA synthesis and mitosis occurs. During this phase, cell and nuclear growth continues and results in a substantial increase in cell and nuclear volume. Such cellular modifications are also associated with a marked dispersal of the condensed chromatin masses of interphase nuclei, so that after 48-72 h of incubation at 38.5C, nuclear profiles of both ts cell lines bear a striking resemblance to the nuclear features characteristic of megaloblastic anaemia. Despite these marked alterations in nuclear chromatin organization, morphometric analysis indicates that the volume of condensed chromatin does not decrease. Current biochemical, cytological and morphometric data on the two ts lines of mutant mouse L-cells during expression of the mutation, suggest that they might provide a useful model to further elucidate cytological features of megaloblastic anaemia.

Structure of interphase nuclei in relation to the cell cycle. Chromatin organization in mouse L cells temperature-sensitive for DNA replication

Mutant lines of mouse L cells, TS A1S9, and TS C1, show temperature-sensitive (TS) DNA synthesis and cell division when shifted from 34 degrees to 38.5 degrees C. With TS A1S9 the decline in DNA synthesis begins after 6-8 h at 38.5 degrees C and is most marked at about 24 h. Most cells in S, G2, or M at temperature upshift complete one mitosis and accumulate in the subsequent interphase at G1 or early S as a result of expression of a primary defect, failure of elongation of newly made small DNA fragments. Heat inactivation of TS C1 cells is more rapid; they fail to complete the interphase in progress at temperature upshift and accumulate at late S or G2. Inhibition of both cell types is reversible on return to 34 degrees C. Cell and nuclear growth continues during inhibition of replication. Expression of both TS mutations leads to a marked change in gross organization of chromatin as revealed by electron microscopy. Nuclei of wild-type cells at 34 degrees and 38.5 degrees C and mutant cells at 34 degrees C show a range of aggregation of condensed chromatin from small dispersed bodies to large discrete clumps, with the majority in an intermediate state. In TS cells at 38.5 degrees C, condensed chromatin bodies in the central nuclear region become disaggregated into small clumps dispersed through the nucleus. Morphometric estimation of volume of condensed chromatin indicates that this process is not due to complete decondensation of chromatin fibrils, but rather involves dispersal of large condensed chromatin bodies into finer aggregates and loosening of fibrils within the aggregates. The dispersed condition is reversed in nuclei which resume DNA synthesis when TS cells are downshifted from 38.5 degrees to 34 degrees C. The morphological observations are consistent with the hypothesis that condensed chromatin normally undergoes an ordered cycle of transient, localized disaggregation and reaggregation associated with replication. In temperature-inactivated mutants, normal progressive disaggregation presumably occurs, but subsequent lack of chromatin replication prevents reaggregation.

Semi-conservative and non-conservative replication of DNA in temperature-sensitive mouse L-cells

The mode of DNA replication has been studied in wild-type mouse L-cells (WT-4) and in two subclones (TS A1S9 and ts C1 cells) which are temperature-sensitive in DNA synthesis. It has been demonstrated that DNA is replicated by the semi-conservative mechanism in WT-4 cells grown at 34 degrees C or at 38.5 degrees C throughout the logarithmic phase and into the stationary phase. Similar results were obtained with ts A1S9 and ts C1 cells grown at the permissive temperature (34 degrees C). When the latter cells were incubated at the non-permissive temperature (38.5 degrees C) inactivation of DNA synthesis appeared to proceed through three general stages. During the first 24 h after temperature upshift suppression of semi-conservative DNA replication occurred. During the second stage a very low level of semi-conservative synthesis was maintained. During the third stage, incorporation of dThd into DNA began to increase, often reaching 10-20% of control levels after 3-5 days. During this third stage DNA synthesis was effected by a non-conservative mechanism. Temperature-inactivated ts A1S9 cells and ts C1 cells were able to perform semi-conservative synthesis upon back-shift to 34 degrees C, using as template that DNA synthesized prior to temperature upshift.

Cell-cycle, cell-shape mutant with features of the Go state

A cold-sensitive mutant of CHO cells has features of "reverse transformation" at the non-premissive temperature of 33 degrees C. Cells accumulate at G1 with altered morphology and remain viable and quiescent for more than 40 d. Such cultures are synchronised by a temperature shift back to the permissive 39 degrees C.