Transplantation of germ nucleus in Paramecium caudatum I : Nuclei in the pre-meiotic S phase can enter into mitotic cycle

Cells of Paramecium caudatum have two functionally different nuclei, somatic macronucleus and germinal micronucleus. We succeeded in transplanting the micronucleus of the pre-meiotic S phase into vegetative cells in the stationary phase by microinjection. Transplanted micronucleus in pre-meiotic S phase stopped proceeding into meiosis but entered the mitotic cycle when the recipient cells were grown. The result shows that commitment to meiosis in the micronucleus occurs some time after pre-meiotic DNA synthesis.     

An Absence of Nuclear Lamins in Keratinocytes Leads to Ichthyosis,Defective Epidermal Barrier Function,and Intrusion of Nuclear Membranes and Endoplasmic Reticulum into the Nuclear Chromatin

B-type lamins (lamins B1 and B2) have been considered to be essential for many crucial functions in the cell nucleus (e.g., DNA replication and mitotic spindle formation). However, this view has been challenged by the observation that an absence of both B-type lamins in keratinocytes had no effect on cell proliferation or the development of skin and hair. The latter findings raised the possibility that the functions of B-type lamins are subserved by lamins A and C. To explore that idea, we created mice lacking all nuclear lamins in keratinocytes. Those mice developed ichthyosis and a skin barrier defect, which led to death from dehydration within a few days after birth. Microscopy of nuclear-lamin-deficient skin revealed hyperkeratosis and a disordered stratum corneum with an accumulation of neutral lipid droplets; however, BrdU incorporation into keratinocytes was normal. Skin grafting experiments confirmed the stratum corneum abnormalities and normal BrdU uptake. Interestingly, the absence of nuclear lamins in keratinocytes resulted in an interspersion of nuclear/endoplasmic reticulum membranes with the chromatin. Thus, a key function of the nuclear lamina is to serve as a “fence” and prevent the incursion of cytoplasmic organelles into the nuclear chromatin.     

Host DNA replication is induced by geminivirus infection of differentiated plant cells

The geminivirus Tomato golden mosaic virus (TGMV) replicates in differentiated plant cells using host DNA synthesis machinery. We used 5-bromo-2-deoxyuridine (BrdU) incorporation to examine DNA synthesis directly in infected Nicotiana benthamiana plants to determine if viral reprogramming of host replication controls had an impact on host DNA replication. Immunoblot analysis revealed that up to 17-fold more BrdU was incorporated into chromosomal DNA of TGMV-infected versus mock-infected, similarly treated healthy leaves. Colocalization studies of viral DNA and BrdU demonstrated that BrdU incorporation was specific to infected cells and was associated with both host and viral DNA. TGMV and host DNA synthesis were inhibited differentially by aphidicolin but were equally sensitive to hydroxyurea. Short BrdU labeling times resulted in some infected cells showing punctate foci associated with host DNA. Longer periods showed BrdU label uniformly throughout host DNA, some of which showed condensed chromatin, only in infected nuclei. By contrast, BrdU associated with viral DNA was centralized and showed uniform, compartmentalized labeling. Our results demonstrate that chromosomal DNA is replicated in TGMV-infected cells.     

Nuclear metabolic changes induced by tumor necrosis factor in Daudi lymphoma cells; a multiparametric analysis.

The effects of r-TNF alpha on cell cycle progression and DNA polymerase activity in Daudi lymphoma cells have been analyzed. Cytofluorimetric analysis of the cell cycle after 6 to 24 hr of treatment revealed both a decrease of BrdU incorporation per cell and a light inhibition of S phase as assessed by the analysis of the percentual distribution of cell cycle compartments. The reduction of BrdU incorporation can be related to the early decrease in the rate of DNA synthesis that follows r-TNF alpha treatment. These results suggest that one of the early events induced by r-TNF alpha at nuclear level is the slowering of DNA synthesis leading to a reduced cell cycle progression.     

In vitro bromodeoxyuridine labeling of nuclei: application to myotube hybridization

Rat myoblast nuclei were labeled with various concentrations of bromodeoxyuridine (BrdU), an analogue of thymidine, for 24 or 48 hr. Almost every myoblast was labeled with BrdU at concentrations between 10(-7) M and 10(-5) M. When the cells were labeled with 0.5 microM or more, the percentage of labeled cells remained over 90% and 80% at 2 and 5 days, respectively. However, when the cells were labeled with BrdU concentration lower than 10(-7) M the percentage of labeled nuclei decreased more rapidly with time. The BrdU-labeled cells were mixed with an unlabeled population to determine whether their capacity to fuse was reduced. At a BrdU concentration of 0.5 x 10(-6) M, labeled myoblasts fused to a similar extent as unlabeled myoblasts, and a high percentage of marked cells were still perceptively labeled after 5 days. In contrast, the fusion capacity of myoblasts incubated with more than 10(-6) M BrdU was inhibited after only few rounds of DNA synthesis. These myoblasts were eventually able to fuse, however, when the BrdU diminished in the DNA due to cell division. These results indicate that labeling with BrdU at a concentration of 0.5 x 10(-6) M and an incorporation time of 48 hr is optimal to obtain perceptible immunocytochemical staining without affecting myoblast fusion. Such BrdU immunolabeling could be used as a nuclear marker for hybridization studies.     

Interruption of Somatic Embryogenesis in Daucus carota L. by 5-Bromodeoxyuridine

Embryogenic Daucus carota L. cells grown in 9 micromolar 2.4-dichlorophenoxyacetic acid are resistant to greater than 5 micromolar 5-bromodeoxyuridine (BrdU). In contrast, 5 micromolar BrdU strongly inhibits somatic embryogenesis within 24 hours after transfer of cells to an auxin-free medium. DNA synthesis rates in control and BrdU-treated cultures are rapid and similar; however, the DNA content does not reach levels as great in the presence of BrdU as in control cultures. BrdU substitutes for thymidine in the DNA in 28% of the available sites 48 hours after auxin removal. Following DNA repair, somatic embryogenesis resumes. BrdU DNA incorporation leads to somatic embryogenesis inhibition and provides an alternative to auxin treatment for the interruption of carrot cell culture differentiation.     

Dose response of hepatic and renal DNA synthetic rates to continuous exposure of bromodeoxyuridine (BrdU) via slow-release pellets or osmotic minipumps in male B6C3F1 mice

We studied the use of acute and chronic 5-bromo-2'-deoxyuridine (BrdU) administration for detection of DNA-synthesizing cells in the liver and kidney of B6C3F1 male mice. Six-week-old mice were exposed to BrdU either acutely with a single-pulse (IP) injection 1 hr before sacrifice or chronically with the use of slow-release pellets or osmotic minipumps at one of four BrdU dose rates. Pellets (2.5, 10, 25, and 50 mg) and minipumps (2.5 and 10 mg equivalents) were implanted subcutaneously on the backs of the animals 4 or 7 days before sacrifice). BrdU incorporation into DNA was determined by immunohistochemistry using an anti-BrdU antibody. Mice chronically exposed to BrdU demonstrated increased levels of nuclear labeling compared with those receiving a single-pulse injection. No time-related increases in nuclear labeling were detected in hepatocytes or renal tubule cells of mice exposed to BrdU pellets and in the kidneys of mice receiving BrdU minipumps at the 7-day compared with the 4-day time point. In some cases, the labeling indices at 7 days were significantly decreased compared with those at 4 days. In contrast, a time-related increase in nuclear labeling was seen in hepatocytes and Kupffer cells of mice exposed to BrdU minipumps. Therefore, the method used to administer BrdU chronically to the animal appears to play an important role in presenting the true proliferative scenario in cell kinetic studies. Our findings also provide evidence for an effect of BrdU on normal proliferation rates in these tissues.     

Detection of in situ mitotic activity of dendritic epidermal T-cells by BrdU labeling.

We analyzed mitotic dendritic epidermal T-cells (DETC) in the epidermis of C3H/He (Thy-1.2+) mice, using double immunoenzymatic labeling. Ear skin was incubated with 100 microM bromodeoxyuridine (BrdU) for 5 hr and then either directly studied or cultured for an additional 12 hr in BrdU-free medium. After BrdU labeling, with or without additional culture, epidermal sheets were obtained by ethylenediaminetetraacetic acid separation. The epidermal specimens were immunostained by the peroxidase method to visualize nuclear BrdU and then by the biotin-streptavidin-alkaline phosphatase method for surface Thy-1.2 antigen. In specimens processed immediately after BrdU labeling, a mean 3.0% of all basal cells were labeled with BrdU and a mean 1.1% of the BrdU-labeled cells were also positive for Thy-1.2. Moreover, a mean 2.1% of the DETC had incorporated BrdU. BrdU-labeled DETC had a variety of appearances; they were dendritic and round in the BrdU-treated specimens, while oval and paired cells were also found in the specimens after additional culture. These morphological changes of BrdU-labeled DETC demonstrate that resident DETC can become mother cells undergoing mitosis through the retraction of their dendrites, and it appears that DETC divide at a relatively high rate, i.e., up to 10% of the DETC may enter the S-phase of the cell cycle every 24 hr.     

The temporal structure of S phase.

DNA synthesis in the S phase of V79 and CHO Chinese hamster cells was examined in detail using an automated system for selection and subculturing of mitotic cells and four different assays for DNA synthesis. Flow microfluorometric (FMF) analysis showed that the selected populations were highly synchronous with few noncycling cells. In CHO cells changes in mean and modal fluorescence in the FMF suggested that DNA content increased in a saltatory fashion with 10-20% of the DNA replicated in early S, 40% in mid S, and 40-50% in late S. Pulse labeling and acid precipitation revealed a repeatable pattern of fluctuations in the rate of isotope incorporation with the maximum rate occurring late in S both V79 and CHO. Autoradiography proved to be the best means of accurately determining the beginning of S phase. Cumulative labeling from mitosis to points in S exaggerated the differences in rate between early and late S, so that significant DNA synthesis in early S might easily be overlooked using this method. In CHO cells DNA-specific fluorescence by the Kissane and Robins assay supported the isotopic incorporation data and the FMF analyses by exhibiting a stepwise increase. In V79 cells, S phase lasts only 5 or 5.5 hr, and consequently the mid S and late S steps in fluorescence are compressed. In V79, greater than 80% of the increase in DNA-specific fluorescence occurred between 4.5 and 7 hr after mitotic selection. In both cell lines, fluorescence in early S phase frequently increased transiently to maximum and then decreased.     

Sensitive period for the induction of endoreduplication by rotenone in cultured Chinese hamster cells

Rotenone-induced endoreduplication was investigated in Chinese hamster CHL cells. Cell cycle analyses, using 5-bromo-2-deoxyuridine (BrdU) labeling, revealed that endoreduplicaiton was induced between the G₂-phase and mitotic metaphase. Morphological studies indicated that the chromosomes of cells in metaphase at the time of rotenone exposure immediately aggregated. Within 1 h, however, the aggregated chromosomes began to decondense forming telophase nuclei. Cells with aggregated chromosomes were collected by mitotic selection using the mitotic arrestant TN-16 and then cultured for 30 h following rotenone administration. This population of cells demonstrated an extremely high frequency of endoreduplicated metaphases. Further analysis by BrdU labeling indicated that the aggregated metaphases underwent only one round of DNA replication before endoreduplicated metaphases were formed. The most sensitive period for the induction of endoreduplication by rotenone occurs during mitotic metaphase.by M.F. Trendelenburg     

Some Characteristics of DNA Synthesis and the Mitotic Cycle in Ehrlich Ascites Tumor Cells

In vivo studies of Ehrlich ascites tumor cells during the first 5 days of growth in peritoneal cavities of mice consisted of the following: 1. Determination of growth curves by direct enumeration of cells. 2. Estimation of the duration of each phase of the mitotic cycle based on incidence of cells in different phases. 3. Radioautographic studies to determine the proportion of cells in different phases of the mitotic cycle that incorporate tritiated thymidine during a single brief exposure to this precursor of DNA. 4. Estimation of the rate of incorporation of tritiated thymidine at different times during the period of DNA synthesis by comparison of mean grain counts over nuclei in radioautographs at different times following exposure to tritiated thymidine. The assumptions underlying these experiments and our observations concerning the duration of the period of DNA synthesis and its relation to the mitotic cycle are discussed. It is concluded that DNA synthesis is continuous, occupying a period of 8.5 hours during the interphase and that the average rate of synthesis is approximately constant.     

The synthesis of acidic chromosomal proteins during the cell cycle of HeLa S-3 cells. II. The kinetics of residual protein synthesis and transport

The kinetics of acidic residual chromosomal protein synthesis and transport were studied throughout the cell cycle in HeLa S-3 cells synchronized by 2 mM thymidine block and selective detachment of mitotic cells. Pulse labeling the cells with leucine-³H for 2 min and then "chasing" the radioactive proteins for up to 3 hr showed that the amount of protein synthesized, transported, and retained in the acidic residual chromosomal protein fraction is greater immediately after mitosis and later in G₁ than in the S or G₂ phases of the cell cycle. During S, only 20–25% of the proteins synthesized and transported to the acidic residual chromosomal protein fraction are chased during the first 2 hr after pulse labeling, whereas up to 40% of the material entering the residual nuclear fraction in mitosis, G₁, and G₂ leaves during a 2 hr chase. Polyacrylamide gel electrophoretic profiles of these proteins, at various times after pulse labeling, reveal that the turnover of individual polypeptides within this fraction has kinetics of synthesis and turnover which are markedly different from one another and undergo stage-specific changes.     

Analysis of Cell Cycle Position in Mammalian Cells

The regulation of cell proliferation is central to tissue morphogenesis during the development of multicellular organisms. Furthermore, loss of control of cell proliferation underlies the pathology of diseases like cancer. As such there is great need to be able to investigate cell proliferation and quantitate the proportion of cells in each phase of the cell cycle. It is also of vital importance to indistinguishably identify cells that are replicating their DNA within a larger population. Since a cell′s decision to proliferate is made in the G1 phase immediately before initiating DNA synthesis and progressing through the rest of the cell cycle, detection of DNA synthesis at this stage allows for an unambiguous determination of the status of growth regulation in cell culture experiments.DNA content in cells can be readily quantitated by flow cytometry of cells stained with propidium iodide, a fluorescent DNA intercalating dye. Similarly, active DNA synthesis can be quantitated by culturing cells in the presence of radioactive thymidine, harvesting the cells, and measuring the incorporation of radioactivity into an acid insoluble fraction. We have considerable expertise with cell cycle analysis and recommend a different approach. We Investigate cell proliferation using bromodeoxyuridine/fluorodeoxyuridine (abbreviated simply as BrdU) staining that detects the incorporation of these thymine analogs into recently synthesized DNA. Labeling and staining cells with BrdU, combined with total DNA staining by propidium iodide and analysis by flow cytometry¹ offers the most accurate measure of cells in the various stages of the cell cycle. It is our preferred method because it combines the detection of active DNA synthesis, through antibody based staining of BrdU, with total DNA content from propidium iodide. This allows for the clear separation of cells in G1 from early S phase, or late S phase from G2/M. Furthermore, this approach can be utilized to investigate the effects of many different cell stimuli and pharmacologic agents on the regulation of progression through these different cell cycle phases.In this report we describe methods for labeling and staining cultured cells, as well as their analysis by flow cytometry. We also include experimental examples of how this method can be used to measure the effects of growth inhibiting signals from cytokines such as TGF-β1, and proliferative inhibitors such as the cyclin dependent kinase inhibitor, p27KIP1. We also include an alternate protocol that allows for the analysis of cell cycle position in a sub-population of cells within a larger culture⁵. In this case, we demonstrate how to detect a cell cycle arrest in cells transfected with the retinoblastoma gene even when greatly outnumbered by untransfected cells in the same culture. These examples illustrate the many ways that DNA staining and flow cytometry can be utilized and adapted to investigate fundamental questions of mammalian cell cycle control.     

Fate of adenovirus type 12 genomes in nonpermissive cells

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

Human Parvovirus B19 Infection Causes Cell Cycle Arrest of Human Erythroid Progenitors at Late S Phase That Favors Viral DNA Replication

Human parvovirus B19 (B19V) infection has a unique tropism to human erythroid progenitor cells (EPCs) in human bone marrow and the fetal liver. It has been reported that both B19V infection and expression of the large nonstructural protein NS1 arrested EPCs at a cell cycle status with a 4 N DNA content, which was previously claimed to be “G₂/M arrest.” However, a B19V mutant infectious DNA (M20^mTAD2) replicated well in B19V-semipermissive UT7/Epo-S1 cells but did not induce G₂/M arrest (S. Lou, Y. Luo, F. Cheng, Q. Huang, W. Shen, S. Kleiboeker, J. F. Tisdale, Z. Liu, and J. Qiu, J. Virol. 86:10748–10758, 2012). To further characterize cell cycle arrest during B19V infection of EPCs, we analyzed the cell cycle change using 5-bromo-2′-deoxyuridine (BrdU) pulse-labeling and DAPI (4′,6-diamidino-2-phenylindole) staining, which precisely establishes the cell cycle pattern based on both cellular DNA replication and nuclear DNA content. We found that although both B19V NS1 transduction and infection immediately arrested cells at a status of 4 N DNA content, B19V-infected 4 N cells still incorporated BrdU, indicating active DNA synthesis. Notably, the BrdU incorporation was caused neither by viral DNA replication nor by cellular DNA repair that could be initiated by B19V infection-induced cellular DNA damage. Moreover, several S phase regulators were abundantly expressed and colocalized within the B19V replication centers. More importantly, replication of the B19V wild-type infectious DNA, as well as the M20^mTAD2 mutant, arrested cells at S phase. Taken together, our results confirmed that B19V infection triggers late S phase arrest, which presumably provides cellular S phase factors for viral DNA replication.     

Epigenesis in developing avian scales. III. Stage-specific alterations of the developmental program caused by 5-bromodeoxyuridine

As an approach to the study of a developmental program, 5-bromodeoxyuridine (BrdU) was administered to chick embryos in ovo at various stages of avian scale formation. This brought about stage-specific alterations in morphogenesis in the anterior tarsometatarsus such as feathered scales, from Day 6 through Day 6 1/2; feathers only, from Day 6 3/4 through Day 7 1/4; scalelessness and rudimentary scales, from Day 7 7/8 through Day 8 1/8; and partial ridge scales, from Day 8 1/8 through Day 10. The effects of BrdU were completely nullified by an excess dose of thymidine which instantly suppressed BrdU incorporation into nuclear DNA. Effects of BrdU causing scalelessness were further examined. The percentage of BrdU labeled cells was immunohistochemically detected. It increased linearly in both the epidermis and dermis, reaching nearly 100% 24 hr following its injection on Day 8. However, scale forming potency, as assayed by the area of scale epidermis on Day 11, decreased with the duration of BrdU incorporation into the cells and disproportionately dropped at 15 hr when about 50% of the cells had incorporated BrdU. Scalelessness was also produced when the period of the incorporation of BrdU exceeded 15 hr. Time sequence observations demonstrated epidermal cell shape, polarity, alignment, and packing density to be remarkably disordered so that the placode and interplacode failed to develop on Day 9 1/4. Epidermal-dermal recombinations were carried out by exchanging normal tissues with those treated with BrdU in the anterior tarsometatarsus. The results clearly showed defects in the dermis at the time of reassociation, giving rise to scalelessness.     

Effect of 5-bromodeoxyuridine substitution on sister chromatid exchange induction by chemicals

The fluorescence-plus-Giemsa (FPG) technique for analysis of sister chromatid exchange (SCE) is widely used as an assay for mutagenic carcinogens. There is very little information, however, on whether incorporation of the bromodeoxyuridine (BrdU) necessary for visualization of SCEs affects the sensitivity of the SCE test system to different chemical agents. We have investigated the effect of BrdU incorporation on SCE induction by labeling cells with BrdU for either the first cell cycle or the first and second cell cycles. The cells were then treated with bleomycin, which produces DNA strand breakage; proflavine, which intercalates into DNA; mitomycin C, which produces monoadducts and DNA crosslinks; or aphidicolin, which inhibits DNA polymerase . Chemicals were added before BrdU exposure or during the first, second, or both cell cycles. Only mitomycin C, which induces long-lived lesions, elevated the SCE frequency when cells were treated before BrdU labeling. When bleomycin, proflavine, or mitomycin C was present concurrently with BrdU, the frequency of SCEs was increased independently of the BrdU labeling protocol. Aphidicolin, on the other hand, induced more SCEs when present for the second cell cycle, when DNA replicates on a template DNA strand containing BrdU. We also examined the induction of SCEs in the first cell cycle (twins) and in the second cell cycle (singles) after continuous treatment of cells with BrdU and the test chemicals. Only aphidicolin increased SCE frequency in the second cell cycle. These results indicate that aphidicolin, but not bleomycin, proflavine, or mitomycin C, affects BrdU-substituted DNA and unsubstituted DNA differently. This type of interaction should be taken into consideration when the SCE test is used as an assay system.     

DIURNAL VARIATION IN THE LABELING INDEX OF MOUSE EPIDERMIS: A DOUBLE ISOTOPE AUTORADIOGRAPHIC DEMONSTRATION OF CHANGING FLOW RATES

A diurnal rhythmicity in the labeling index was observed in the epidermis of hairless mice, injected with either ¹⁴C- or ³H-thymidine, at different times during a 24 hr period. A modified autoradiographic technique, using ¹⁴C- and ³H-thymidine and two overlying emulsion layers, makes it possible to clearly differentiate synthesizing cells which are singly labeled with either carbon-14 or tritium, and cells labeled with both isotopes. At various times during a 24 hr period, hairless mice were injected with thymidine-2-¹⁴C and colcemid, followed at 2 or 3 hr by a second injection of ³H-thymidine. The labeling indices were calculated for the ¹⁴C- and ³H-thymidine injection times. These labeling indices were consistent with the control, single isotope, labeling indices and exhibited the same diurnal rhythm. Cells singly labeled with ³H- or ¹⁴C-thymidine have either started or completed DNA synthesis during the interval between the two injections. Flow rates into and out of DNA synthesis, throughout the 24 hr period, can be calculated from these singly labeled cells. The flow rates varied rhythmically throughout the day and paralleled changes in the labeling indices. The influx and efflux flow rates, at all times measured, were not equal. The influx flow rate was reflected in the efflux rate at a time later equal to the duration of S. By means of these flow rates, the per cent of cells in DNA synthesis was calculated for each hour during a 24 hr period. The resulting labeling index curve matches the observed 24 hr diurnal rhythm in labeling indices. By extension of these flow rates through mitosis, the resulting mitotic index curve is comparable to the reported 24 hr diurnal rhythm in mitotic indices.     

Determination of the fraction of S-phase cells in root meristems using bromodeoxyuridine labeling

The use of bromodeoxyuridine (BrdU) and subsequent immunocytochemical visualization for studying cell proliferation in plant meristems was investigated in Allium cepa L. root-tips. We describe the optimization of an indirect immunoperoxidase method for detecting incorporation of this DNA precursor in pulse-labeled cells. The basic object of this study is to quantify the extent to which the fraction of S-phase cells can reliably be estimated in asynchronous populations. A matrix of parallel labeling schedules with tritiated-thymidine or BrdU was developed, and the labeling indices provided by autoradiography or immunocytochemistry were compared. Thus, 0.5 mM BrdU assured saturation S-phase labeling after an exposure time of 30 min, and the mean length of the S-phase determined under such conditions was similar to that previously reported for this plant system. Interestingly, Feulgen staining did not interfere with subsequent detection of the BrdU probe. This allowed comparative evaluations of the nuclear DNA content by Feulgenmicrodensitometry and the position of a given cell in G1, S or G2 compartments. We also explored the possibility of quantifying BrdU-incorporation in single nuclei by densitometry measurement of the peroxidase label.     

Initiation of DNA synthesis in the prematurely condensed chromosomes of G1 cells

The objective of this study was to investigate whether G1 cells could enter S phase after premature chromosome condensation resulting from fusion with mitotic cells. HeLa cell synchronized in early G1, mid-G1, late G1, and G2 and human diploid fibroblasts synchronized in G0 and G1 phases were separately fused by use of UV-inactivated Sendai virus with mitotic HeLa cells. After cell fusion and premature chromosome condensation, the fused cells were incubated in culture medium containing Colcemid (0.05 micrograms/ml) and [3H]thymidine ([3H]ThdR) (0.5 microCi/ml; sp act, 6.7 Ci/mM). At 0, 2, 4, and 6 h after fusion, cell samples were taken to determine the initation of DNA synthesis in the prematurely condensed chromosomes (PCC) on the basis of their morphology and labeling index. The results of this study indicate that PCC from G0, G1, and G2 cells reach the maximum degree of compaction or condensation at 2 h after PCC induction. In addition, the G1-PCC from normal and transformed cells initiated DNA synthesis, as indicated by their "pulverized" appearance and incorporation of [3H]ThdR. Further, the initiation of DNA synthesis in G1-PCC occurred significantly earlier than in the mononucleate G1 cells. Neither pulverization nor incorporation of label was observed in the PCC of G0 and G2 cells. These findings suggest that chromosome decondensation, although not controlling the timing of a cell's entry into S phase, is an important step for the initiation of DNA synthesis. These data also suggest that the entry of a S phase may be regulated by cell cycle phase-specific changes in the permeability of the nuclear envelope to the inducers of DNA synthesis present in the cytoplasm.