Mitochondrial DNA synthesis in mouse L cells temperature sensitive in nuclear DNA replication

Temperature-sensitive (ts) A 1S9 mouse L cells continue to synthesize double-stranded covalently closed mitochondrial (mt) DNA at a temperature (38.5 degrees C) which is nonpermissive for chromosomal DNA replication. The amount of mt DNA made appears to be quantitatively linked to nuclear DNA synthesis. Nuclear DNA replication proceeds normally for 6-8 h after the cells are shifted to 38.5 degrees C, and then declines to reach a minimum at 20-24 h. The level of mt DNA synthesis remains high during this period and decreases once the ts lesion has been established.     

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.     

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.     

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).     

Polyoma and cell DNA synthesis in mouse L cells temperature sensitive for the replication of cell DNA.

Polyoma (Py) virus multiplies, at 34 and 38.5 C, in wild-type (WT-4) and in ts A1S9 mouse L cells, which are temperature sensitive for growth and for DNA replication (R. Sheinin, 1976; L. H. Thompson et al., 1970). De novo synthesis of double-stranded, fully covalently closed Py DNA has been shown to proceed by semiconservative replication in WT-4 and ts A1S9 cells at the permissive and nonpermissive temperatures. Cell DNA is made late during infection, by both cell types and at both temperatures. Semiconservative replication of cell DNA proceeds in Py-infected WT-4 cells incubated at 34 or at 38.5 C and in Py-infected ts A1S9 cells incubated at 34 C. In virus-infected ts A1S9 cells incubated at 38.5 C, cell DNA synthesis appears to proceed almost entirely by a process analogous to repair replication. The inability of ts A1S9 cells to produce large-molecular-weight chromosomal DNA strands, at 38.5 C, by the normal mechanism is not overcome by Py infection.     

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.     

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.     

Differential stimulation of histone and high mobility group chromatin protein synthesis in the rat uterus by estrogen

Uterine tissue isolated from immature rats at different times after estradiol injection was incubated with medium containing [3H]lysine. The acid-extractable protein from the uterine tissue was subjected to electrophoresis on sodium dodecyl sulfate and acid-urea-Triton X-100 polyacrylamide gels, and the rate of chromatin protein synthesis determined by densitometric analysis of the fluorographs of the gels. Synthesis of chromatin proteins (histones and high mobility group chromatin proteins) was stimulated by 3 h after estrogen treatment and reached a peak at 9 h, several hours before DNA synthesis was stimulated. Synthesis of chromatin proteins occurred at the same time as total cellular protein synthesis. Estrogen stimulated the synthesis of histone variants at different rates, but the accumulation of histone proteins remained coordinated such that equivalent amounts of histone proteins were being produced at any one time.     

A temperature-sensitive mutant of the mammalian RNA helicase,DEAD-BOX X isoform,DBX, defective in the transition from G1 to S phase

ts ET24 cells are a novel temperature-sensitive (ts) mutant for cell proliferation of hamster BHK21 cells. The human genomic DNA which rescued the temperature-sensitive lethality of ts ET24 cells was isolated and screened for an open reading frame in the deposited human genomic library. X chromosomal DBX gene encoding the RNA helicase, DEAD-BOX X isoform, which is homologous to yeast Ded1p, was found to be defective in this mutant. The single point mutation (P267S) was localized between the Motifs I and Ia of the hamster DBX of ts ET24 cells. At the nonpermissive temperature of 39.5 degrees C, ts ET24 cells were arrested in the G1-phase and survived for more than 3 days. In ts ET24 cells, total protein synthesis was not reduced at 39.5 degrees C for 24 h, while mRNA accumulated in the nucleus after incubation at 39.5 degrees C for 17 h. The amount of cyclin A mRNA decreased in ts ET24 cells within 4 h after the temperature shift to 39.5 degrees C, consistent with the fact that the entry into the S-phase was delayed by the temperature shift.     

Properties of ts Cl mouse L cells which exhibit temperature-sensitive DNA synthesis.

ts Cl mouse L cells are temperature-sensitive (ts) in DNA synthesis. The protein involved undergoes inactivation at 38.5 °C, with an apparent half-life of 3–4 h. A variety of experimental approaches yield data indicating that the ts Cl gene product acts directly during the DNA-synthesis period, probably late during the duplication of chromosomal DNA. The specificity of the ts lesion is reflected in the fact that replication of mitochondrial DNA is unaffected for many hours after nuclear DNA synthesis is almost totally inhibited. Temperature inactivation is not due to degradation or to loss of template capacity of preformed DNA. ts Cl cells are able to enter a DNA-synthesis phase at the higher temperature, as indicated by radioautographic experiments and by studies in which cells, blocked at the permissive temperature (34 °C) in a pre-DNA synthesis phase by isoleucine deprivation, are subsequently incubated at 38.5 °C. Cells arrested early in DNA synthesis by hydroxyurea treatment at 34 °C continue such synthesis for a short interval after up-shift to 38.5 °C. However, they are then unable to complete the S phase in progress nor can they proceed into cell division. The kinetics of DNA synthesis in cells incubated at 38.5 °C and back-shifted to 34 °C are compatible with the model that the ts Cl locus encodes an S phase function.     

A temperature-sensitive mutant of cultured mouse cells defective in chromosome condensation

A temperature-sensitive mutant, designated ts85, was isolated from a mouse mammary carcinoma cell line, FM3A. The ts85 cells grew at 33 °C (permissive temperature) with a doubling time of 18 h, which was almost the same as with wild-type cells, whereas the cell number scarcely increased at all at 39 °C (non-permissive temperature). When the ts85 cells were shifted from 33 to 39 °C, their DNA synthesis fell to below 1% of the initial value in 14 h. RNA or protein synthesis, however, was maintained at the initial levels for at least 14 h at 39 °C. Cytofluorometric analysis of asynchronous cultures and studies with synchronous cultures suggested that the bulk of the cells cultured at 39 °C for 12–18 h were arrested in late S and G2 phases. Electron microscopic observations revealed that chromatin was abnormally condensed into fragmented and compact forms, particularly around nucleoli, in about 80% of cells of an asynchronous culture incubated at 39 °C for 16 h. Cells in mitosis were not detected in such cultures and nuclear membrane and nucleoli were still intact. Such abnormal chromosome condensation was not observed in the ts85 cells at 33 °C or in wild-type cells at either temperature. Since these findings suggest that a ts gene product of ts85 cells is necessary for chromosome condensation, ts85 cells may represent a useful tool for establishing the mechanisms of chromosome condensation. The interrelationship between abnormal chromosome condensation and reduction in DNA synthesis of the ts85 cells is discussed.     

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.     

Isolation of temperature-sensitive cell cycle mutants from mouse FM3A cells. Characterization of mutants with special reference to DNA replication

A large number of mutants that are temperature sensitive (ts) for growth have been isolated from mouse mammary carcinoma FM3A cells by an improved selection method consisting of cell synchronization and short exposures to restrictive temperature. The improved method increased the efficiency of isolating DNA ts mutants, which showed a rapid decrease in DNA-synthesizing ability after temperature shift-up. Sixteen mutants isolated by this and other methods were selected for this study. Flow microfluorometric analysis of these mutants cultured at a nonpermissive temperature (39 degrees C) for 16 h indicated that five clones were arrested in the G1 to S phase of the cell cycle, six clones were in the S to G2 phase, and two clones were arrested in the G2 phase. The remaining three clones exhibited 8C DNA content after incubation at 39 degrees C for 28 h, indicating defects in mitosis or cytokinesis. These mutants were classified into 11 complementation groups. All the mutants except for those arrested in the G2 phase and those exhibiting defects in mitosis or cytokinesis showed a rapid decrease in DNA synthesis after temperature shift-up without a decrease in RNA and protein synthesis. The polyomavirus DNA cell-free replication system, which consists of polyomavirus large tumor antigen and mouse cell extracts, was used for further characterization of these DNA ts mutants. Among these ts mutants, only the tsFT20 strain, which contains heat-labile DNA polymerase alpha, was unable to support the polyomavirus DNA replication. Analysis by DNA fiber autoradiography revealed that DNA chain elongation rates of these DNA ts mutants were not changed and that the initiation of DNA replication at the origin of replicons was impaired in the mutant cells.     

A temperature-sensitive mutation affecting S-phase progression can lead to accumulation of cells with a G2 DNA content

Cultures of ts BN75, a temperature-sensitive mutant of BHK 21 cells, show a gradual biphasic drop in [3H]thymidine incorporation together with an accumulation of cells having a G2 DNA content when incubated at 39.5 degrees. However, when higher (41 degrees - 42 degrees) nonpermissive temperatures were used, the major block was in S-phase DNA synthesis. The cultures of ts BN75 shifted to 42 degrees at the start of the S phase, cell-cycle progress was arrested in the middle of S, while under these conditions wild-type BHK cells underwent at least one cycle of DNA synthesis. When ts BN75 cells growth-arrested at high temperature with a G2 DNA content were shifted to the permissive temperature (33.5 degrees C), the restart of DNA synthesis preceded the appearance of mitotic cells. These data suggest that the ts defect of ts BN75 cells might affect primarily the S phase of the cycle rather than the G2 phase.     

Histone synthesis in isolated neuronal perikaryon relative to the postnatal appearance of a short DNA repeat length

Neuronal perikaryon were purified from rabbit cerebral hemispheres at early postnatal stages of brain development. When incubated in vitro these neuronal cells demonstrated the ability to incorporate labeled amino acids into total protein at a linear rate, however, incorporation of labeled thymidine was not apparent. Isolated neuronal perikaryon showed a transient ability to incorporate labeled lysine and arginine into both core (H3, H2B, H2A, H4) and linker (H1) histones between 30 and 90 hr following birth, with a maximum incorporation at 42 hr. This period of histone synthesis may correlate with the conversion of neuronal chromatin to a short DNA repeat length which occurs between 60 and 84 hr following birth.     

DNA replication, chromatin structure, and histone phosphorylation altered by theophylline in synchronized HeLa S3 cells

The onset of DNA replication normally is coincident with an increase in histone 1 phosphorylation and a relaxation in chromatin structure. In this paper we show that 5 mM theophylline, added 2 h after selective detachment to synchronized HeLa-S-3 cells, delays the onset and reduces the rate of DNA synthesis while theophylline treatment beginning at 8 h has no effect on subsequent DNA synthesis. These actions of theophylline are accompanied by an inhibition of histone 1 phosphorylation and a prevention of the normal relaxation in chromatin structure between G1 and S phases as revealed by image analysis of Feulgen-stained nuclei. The time courses of intracellular cyclic AMP levels, nonhistone protein phosphorylation, and [3H]lysine incorporation are also compared in the same treated and untreated synchronized HeLa cells. Comparison with experiments using 1-beta-D- arabinofuranosylcytosine (Ara-C) shows that the above phenomena are not a direct result of inhibition of DNA synthesis. We interpret our results as evidence that the associations between histone 1 phosphorylation, chromatin relaxation, and the onset of DNA synthesis are temporally and causally related.     

Characterization of a ts mutant of BALB/3T3 cells and correction of the defect by in vitro addition of extracts from wild-type cells.

ts20 is a temperature-sensitive mutant cell line derived from BALB/3T3 cells. DNA synthesis in the mutant decreased progressively after an initial increase during the first 3 h at the restrictive temperature. RNA and protein synthesis increased for 20 h and remained at a high level for 40 h. Cells were arrested in S phase as determined by flow microfluorimetry, and DNA chain elongation was retarded as measured by fiber autoradiography. Infection with polyomavirus did not bypass the defect in cell DNA synthesis, and the mutant did not support virus DNA replication at the restrictive temperature. After shift down to the permissive temperature, cell DNA synthesis was restored whereas virus DNA synthesis was not. Analysis of virus DNA synthesized at the restrictive temperature showed that the synthesis of form I and replicative intermediate DNA decreased concurrently and that the rate of completion of virus DNA molecules remained constant with increasing time at the restrictive temperature. These studies indicated that the mutation inhibited ongoing DNA synthesis at a step early in elongation of nascent chains. The defect in virus and cell DNA synthesis was expressed in vitro. [3H]dTTP incorporation was reduced, consistent with the in vivo data. The addition of a high-salt extract prepared from wild-type 3T3 cells preferentially stimulated the incorporation of [3H]dTTP into the DNA of mutant cells at the restrictive temperature. A similar extract prepared from mutant cells was less effective and was more heat labile as incubation of it at the restrictive temperature for 1 h destroyed its ability to stimulate DNA synthesis in vitro, whereas wild-type extract was not inactivated until incubated at that temperature for 3 h.     

Specific Sindbis virus-coded function for minus-strand RNA synthesis.

The synthesis of minus-strand RNA was studied in cell cultures infected with the heat-resistant strain of Sindbis virus and with temperature-sensitive (ts) belonging to complementation groups A, B, F, and G, all of which exhibited an RNA-negative (RNA-) phenotype when infection was initiated and maintained at 39 degrees C, the nonpermissive temperature. When infected cultures were shifted from 28 degrees C (the permissive temperature) to 39 degrees C at 3 h postinfection, the synthesis of viral minus-strand RNA ceased in cultures infected with ts mutants of complementation groups B and F, but continued in cultures infected with the parental virus and mutans of complementation groups A and G. In cultures infected with ts11 of complementation group B, the synthesis of viral minus-strand RNA ceased, whereas the synthesis of 42S and 26S plus-strand RNAs continued for at least 5 h after the shift to 39 degrees C. However, when ts11-infected cultures were returned to 28 degrees C 1 h after the shift to 39 degrees C, the synthesis of viral minus-strand RNA resumed, and the rate of viral RNA synthesis increased. The recovery of minus-strand synthesis translation of new proteins. We conclude that at least one viral function is required for alphavirus minus-strand synthesis that is not required for plus-strand synthesis. In cultures infected with ts6 of complementation group F, the syntheses of both viral plus-strand and minus-strand RNAs were drastically reduced after the shift to 39 degrees C. Since ts6 failed to synthesize both plus-strand and minus-strand RNAs after the shift to 39 degrees C, at least one common viral component appears to be required for the synthesis of both minus-strand and plus-strand RNAs.     

Early changes in the synthesis of proteins with affinity for single-stranded DNA during the onset of transformation in NRK cells.

Early alterations in the synthesis of proteins which bind to single-stranded DNA have been examined following the onset of transformation in NRK cells transformed by a heat-sensitive mutant (ts339) of Rous sarcoma virus. Transformation was initiated by shifting quiescent cultures from nonpermissive to permissive temperatures. Cultures were prelabelled with [3H]leucine for several generations at the non-permissive temperature, and with [35S]methionine at times after shift to the permissive temperature. Cytosol extracts were passed through sequential columns of double-stranded and single-stranded DNA bound to cellulose. Within the first hour of transformation there was an increase in the synthetic rate of proteins binding tightly to single-stranded DNA, but not to double-stranded DNA. More loosely bound protein fractions showed no such early synthetic increase. Electrophoresis of the fraction eluted from single stranded DNA-cellulose with 2 M NaCl demonstrated the presence of a major protein of 93 000 daltons, which comprised more than 0.1% of the cytosol protein. The synthesis of the 93 000 dalton protein increased continuously over the first 4 h interval after the onset of transformation. The synthetic rate of a 35 000 dalton protein, a major DNA-binding polypeptide found in mammalian cells, began to increase after a 1-h lag, following the onset of transformation. The protein fraction containing the 93 000 dalton protein had considerable unwinding activity, depressing the melting temperature of poly(dA-dT) by 39 degrees C. The protein fraction containing the bulk of the 35 000 dalton protein did not have unwinding activity. Transformation-induced DNA synthesis was measured in cells made permeable to deoxyribonucleoside triphosphates at times after shift to the permissive temperature. It was determined that synthesis of DNA began within the first 1--2 h after the onset of transformation. We conclude that the early transformation-associated synthesis of SS93 and perhaps other proteins binding to single-stranded DNA may be related to early transformation-associated changes preparatory to DNA replication and subsequent growth.     

Reactivation of chick erythrocyte nuclei in heterokaryons with temperature-sensitive Chinese hamster cells.

Chinese hamster cell line K12 is temperature-sensitive for the initiation of DNA synthesis. K12 cells synchronized by serum deprivation were collected in early G1(G0). Heterokaryons were formed by fusing chick erythrocytes with serum-starved K12 cells through the use of UV-irradiated Sendai virus. At the permissive temperature (36.5 degrees C), erythrocyte nuclei in heterokaryons enlarged, the chromatin dispersed, and erythrocyte nuclei synthesized DNA at about the same time as the K12 nuclei. At the restrictive temperature (41 degrees C), erythrocyte nuclei enlarged, but neither erythrocyte nor K12 nuclei initiated DNA synthesis. When erythrocyte nuclei were fused with Wg-1A cells, the wild-type parent for ts K12 cells, both kinds of nuclei synthesized DNA at 36.5 degrees C and 41 degrees C. Activation of erythrocyte nuclei was inefficient in heterokaryons incubated in low-serum medium. The results indicate that serum factors and a cellular function defined by the K12 mutation are required for activation of chick erythrocyte nuclear DNA synthesis.