Gene expression and cell cycle regulation

Identification of proteins whose synthesis is modulated during the cell cycle of Saccharomyces cerevisiae

We examined the synthesis and turnover of individual proteins in the Saccharomyces cerevisiae cell cycle. Proteins were pulse-labeled with radioactive isotope (35S or 14C) in cells at discrete cycle stages and then resolved on two-dimensional gels and analyzed by a semiautomatic procedure for quantitating gel electropherogram-autoradiographs. The cells were obtained by one of three methods: (i) isolation of synchronous subpopulations of growing cells by zonal centrifugation.; (ii) fractionation of pulse-labeled steady-state cultures according to cell age; and (iii) synchronization of cells with the mating pheromone, alpha-factor. In confirmation of previous studies, we found that the histones H4, H2A, and H2B were synthesized almost exclusively in the late G1 and early S phases. In addition, we identified eight proteins whose rates of synthesis were modulated in the cell cycle, and nine proteins (of which five, which may well be related, were unstable, with half-lives of 10 to 15 min) that might be regulated in the cell cycle by periodic synthesis, modification, or degradation. Based on the time of maximal labeling in the cell cycle and on experiments with alpha-factor and hydroxyurea, we assigned the cell cycle proteins to two classes: proteins in class I were labeled principally in early G1 phase and at a late stage of the cycle, whereas those in class II were primarily synthesized at times ranging from late G1 to mid S phase. At least one major control point for the cell cycle proteins occurred between "start" and early S phase. A set of stress-responsive proteins was also identified and analyzed. The rates of synthesis of these proteins were affected by certain perturbations that resulted during selection of synchronous cell populations and by heat shock.

Identification of proteins whose synthesis is modulated during the cell cycle of Saccharomyces cerevisiae

We examined the synthesis and turnover of individual proteins in the Saccharomyces cerevisiae cell cycle. Proteins were pulse-labeled with radioactive isotope (35S or 14C) in cells at discrete cycle stages and then resolved on two-dimensional gels and analyzed by a semiautomatic procedure for quantitating gel electropherogram-autoradiographs. The cells were obtained by one of three methods: (i) isolation of synchronous subpopulations of growing cells by zonal centrifugation.; (ii) fractionation of pulse-labeled steady-state cultures according to cell age; and (iii) synchronization of cells with the mating pheromone, alpha-factor. In confirmation of previous studies, we found that the histones H4, H2A, and H2B were synthesized almost exclusively in the late G1 and early S phases. In addition, we identified eight proteins whose rates of synthesis were modulated in the cell cycle, and nine proteins (of which five, which may well be related, were unstable, with half-lives of 10 to 15 min) that might be regulated in the cell cycle by periodic synthesis, modification, or degradation. Based on the time of maximal labeling in the cell cycle and on experiments with alpha-factor and hydroxyurea, we assigned the cell cycle proteins to two classes: proteins in class I were labeled principally in early G1 phase and at a late stage of the cycle, whereas those in class II were primarily synthesized at times ranging from late G1 to mid S phase. At least one major control point for the cell cycle proteins occurred between "start" and early S phase. A set of stress-responsive proteins was also identified and analyzed. The rates of synthesis of these proteins were affected by certain perturbations that resulted during selection of synchronous cell populations and by heat shock.

Coiled body numbers in the Arabidopsis root epidermis are regulated by cell type, developmental stage and cell cycle parameters

We have used whole mount immunofluorescence labelling with the antibody 4G3, raised against the human snRNP-specific protein U2B″, and whole mount in situ hybridization with an anti-sense probe to a conserved region of U2 snRNA, in combination with confocal microscopy, to examine the organization of spliceosomal components throughout the development of the Arabidopsis thaliana root epidermis. We show that the number of coiled bodies, nuclear organelles in which splicing snRNPs and snRNAs concentrate, is developmentally regulated in the Arabidopsis root epidermis. Firstly, there is a progression from a small number of coiled bodies in the quiescent centre and initial cells, to a larger number in the cell division zone, returning to a lower number in the cell elongation and differentiation zone. Secondly, trichoblasts (root-hair forming epidermal cells) have on average 1.5 times more and often smaller coiled bodies than atrichoblasts (hairless epidermal cells). Moreover, we have shown that these differences in coiled body numbers are related to differences in cell cycle stage, cell type and developmental stage, but are not due to differences in nucleolar or general metabolic activity per se. We discuss possible explanations, including a model in which coiled bodies coalesce during interphase, for the developmental dynamics of coiled bodies.

Comparison of bax, waf1, and IMP dehydrogenase regulation in response to wild-type p53 expression under normal growth conditions

Recently, we demonstrated that downregulation of inosine-5'-monophosphate dehydrogenase (IMPD; IMP:NAD oxidoreductase, EC 1.2.1.14), the rate-limiting enzyme for guanine nucleotide biosynthesis, is required for p53-dependent growth suppression. These studies were performed with cell lines derived from immortal, nontumorigenic fibroblasts that express wild-type p53 conditionally by virtue of a metal-responsive promoter. Here, the p53-dependent properties of the original "p53-inducible" fibroblasts are presented in detail and compared to related properties of epithelial cells that also express wild-type p53 conditionally, but by virtue of a temperature-responsive promoter. Both types of p53-inducible cells were designed to approximate normal physiologic relationships between the host cell and the regulated p53 protein. Together, they were used to investigate expression relationships between IMPD and other p53-responsive genes proposed as mediators of p53-dependent growth suppression. In both types of cells, IMPD activity, protein, and mRNA were consistently coordinately reduced in response to p53 expression. In contrast, mRNAs for waf1, bax, and mdm2 showed disparate patterns of expression, being induced in one conditional cell type, but not the other. This distinction in regulation pattern suggests that under normal growth conditions, unlike IMPD downregulation, bax and waf1 induction is not a rate-determining event for p53-dependent growth suppression.

Inosine-5'-monophosphate dehydrogenase is a rate-determining factor for p53-dependent growth regulation

We have proposed that reduced activity of inosine-5'-monophosphate dehydrogenase (IMPD; IMP:NAD oxidoreductase, EC 1.2.1.14), the rate-limiting enzyme for guanine nucleotide biosynthesis, in response to wild-type p53 expression, is essential for p53-dependent growth suppression. A gene transfer strategy was used to demonstrate that under physiological conditions constitutive IMPD expression prevents p53-dependent growth suppression. In these studies, expression of bax and waf1, genes implicated in p53-dependent growth suppression in response to DNA damage, remains elevated in response to p53. These findings indicate that under physiological conditions IMPD is a rate-determining factor for p53-dependent growth regulation. In addition, they suggest that the impd gene may be epistatic to bax and waf1 in growth suppression. Because of the role of IMPD in the production and balance of GTP and ATP, essential nucleotides for signal transduction, these results suggest that p53 controls cell division signals by regulating purine ribonucleotide metabolism.

Subnucleolar location of fibrillarin and variation in its levels during the cell cycle and during differentiation of plant cells

The nucleolar protein fibrillarin has been studied in onion cells; it is detected as an M(r) 37,000 protein by immunoblotting using a human autoimmune serum. Quantitative immunoelectron microscopy showed that most fibrillarin is localized in the transition zone between the fibrillar center (FC) and the dense fibrillar component (DFC) as well as in the proximal zone of the DFC, where the labeling shows a gradual decrease outward until it reaches insignificant levels in the distal zone of the DFC. Thus, fibrillarin is not uniformly distributed throughout the DFC of plant cells. This result supports the hypothesis that the morphologically homogeneous DFC may not be uniform in function; it is also in agreement with the hypothesized vectorial flow of ribosome biogenesis through the same compartments. Data are also presented showing that the amount of fibrillarin increases when nucleolar activity increases in G2, and probably decreases when nucleolar activity decreases during differentiation.

Inosine-5'-monophosphate dehydrogenase activity is maintained in immortalized murine cells growth-arrested by serum deprivation

We have examined properties of IMPD activity in soluble extracts from immortalized murine epithelial and fibroblastic cells. The absence of significant xanthine oxidase activity in these extracts allowed the use of a spectrophotometric assay to study the enzyme activity. The observed enzymatic activity had subcellular localization and kinetic properties similar to those of previously described mammalian IMPD from other sources. Analysis of IMPD activity in extracts from cells in different states of growth related to serum concentration gave a surprising result. Extracts from exponentially growing cells exhibited a level of IMPD activity similar to that of extracts from quiescent cells arrested by serum-deprivation. In previous studies, the cellular variable designated to account for changes in IMPD activity was proliferative rate. Our findings suggest that either proliferative rate is not the functionally significant variable related to IMPD regulation or that there are other factors that can supersede it in certain contexts. Given the role of the enzyme in regulating the synthesis of guanine nucleotides, which are key regulatory molecules for many cellular processes, this may indeed be the case. Using immortalized cell lines growth-arrested by serum deprivation, we have experimentally isolated the enzyme activity from the previously assigned variable of growth rate. Based on our findings we propose that regulation of IMPD activity is more appropriately related to proliferative capacity as opposed to proliferative rate.

Increased yield in GST-P-positive liver pre-neoplastic foci induced by DENA or ENU in rats pre-treated with estradiol or tamoxifen

We investigated the mechanisms by which partial hepatectomy (PH) increases the ability of chemical hepatocarcinogens to induce pre-neoplastic liver foci. Comparison of the effects of pre-treatment with PH, estradiol (E2) or tamoxifen (TAM) on the yield in glutathione-S-transferase(GST-P)-positive preneoplastic foci in rat liver induced by subsequent treatment with ethylnitrosourea (ENU) or diethylnitrosamine (DENA) showed that pre-treatment with E2 increased the yield in foci induced by subsequent treatment with ENU or DENA, as compared with that in animals not pre-treated, the increase being of similar magnitude with either carcinogen. Compared with that of PH, the effect of the hormone was much more pronounced than would be expected from the relative mitogenic effect of the hormonal and surgical pre-treatments if the mitotic rate were the cause. On the other hand, the average volume of pre-neoplastic liver lesions in rats treated with ENU or DENA was 2.5 to 5.0 times higher than in rats not pretreated whenever PH was included in the pre-treatment, whereas it was not affected by any other pre-treatment.

Reduction of proliferative heterogeneity of CHEF18 Chinese hamster cell line during the progression toward tumorigenicity

Doubling time and generation time represent two parameters by which the proliferation of cultured mammalian cells can be monitored. In this study we report the characterization of CHEF18 Chinese hamster cell line during the progression toward tumorigenicity by analysis of doubling time and generation time. The two parameters reveal that the proliferation was initially different, indicating the presence of a proliferative heterogeneity among the cycling cells. The progressive reduction up to the disappearance of this discrepancy suggests that a modification of the length of some phases of the cell cycle may have occurred during the progression toward tumorigenicity. However, the hypothesis that the shortening of doubling time might be due to a continuous coming out of cells from the cell cycle rather than to a shortening of the cell cycle is presented.

Decreases in the relative concentrations of specific hepatocyte plasma membrane proteins during liver regeneration: down-regulation or dilution?

Antibodies were used to quantify seven domain-specific integral proteins of the rat hepatocyte plasma membrane during rat liver regeneration in response to two-thirds hepatectomy. Quantitative immunoblotting revealed that a subset of the plasma membrane proteins exhibited transient 30-70% decreases in relative concentration during the period of hepatocyte proliferation. The list of affected proteins included at least one representative from each of the plasma membrane domains: the apical protein HA 4, the lateral protein HA 321, and the basolateral receptors for epidermal growth factor and asialoglycoproteins. In contrast, the relative concentrations of three other plasma membrane proteins, the basolateral protein CE 9 and the two apical proteins dipeptidylpeptidase IV and aminopeptidase N, remained unchanged throughout liver regeneration. The decreases in the relative concentrations of the plasma membrane proteins were observed even when the synthesis of hepatocyte DNA was blocked by hydroxyurea, suggesting that the signalling for these two delayed consequences of two-thirds hepatectomy occurred along parallel, dependent pathways. Pulse and pulse-chase metabolic radiolabeling studies revealed that the decreases in the concentrations of the PM proteins were accomplished through protein-selective decreases in the rates of synthesis of the high-mannose precursors of the affected proteins, but not through the accelerated degradation of the mature plasma membrane proteins.

Mechanisms and kinetics of monoclonal antibody synthesis and secretion in synchronous and asynchronous hybridoma cell cultures

The kinetics of monoclonal antibody synthesis and secretion have been studied in synchronous and asynchronous mouse hybridoma cell cultures. Pulse-labelling of IgG followed by immunoprecipitation and quantitation of synthesized and secreted IgG in synchronous cultures show maximum production during G1/S phases. Secretion takes place through exocytotic release of vesicle contents. Pulse-chase experiments show that 71% of the synthesized IgG is secreted within 8 h of the pulsing period and only a further 4% is secreted by 22 h. Higher specific antibody production (QA) is obtained if (a) cells are arrested and then maintained in G1/S phases, (b) viability is decreased during the death phase of batch culture, (c) the dilution rate is decreased in continuous culture or (d) cells are subjected to hydrodynamically induced stress. The increase in QA in all these cases is mainly due to the passive release of the accumulated intracellular antibody. DNA and protein synthetic activity peak during the early exponential phase and decline rapidly during mid and late exponential and death phases. Metabolic activity however peaks up to 20 h after the peak in DNA synthesis, and declines similarly during the death phase. The data are consistent with the idea that slow growth and higher death rates increase QA and that Ig secretion is probably subject to complex intracellular control.

Cell cycle-dependent DHFR and t-PA production in cotransfected, MTX-amplified CHO cells revealed by dual-laser flow cytometry

The cell cycle-dependent regulation of the cellular dihydrofolate reductase content (DHFR) and tissue plasminogen activator (t-PA) production and secretion in plasmid-amplified cells was investigated in the DHFR-negative CHO cells transfected with the plasmid pSV-tPA.dhfr. This plasmid, carrying the dhfr and t-PA gene under control of different promotors, was amplified by serial passages in 5 microM methotrexate (MTX) for dhfr gene amplification. The intracellular amount of DHFR was quantitated in viable cells by MTX-FITC labeling and flow cytometric analysis of the FITC fluorescence. In comparison with the original CHO cells, the pSVtPA.dhfr-amplified cells showed a greater than 230-fold increase in MTX-FITC fluorescence. Using dual laser flow cytometry (uv: vital cell cycle with Hoechst 33342; 488 nm: DHFR with MTX-FITC), we show a maximum increase in the intracellular DHFR content during G1 and/or at G1/S transition (100 to 157%), followed by a continuous increase to 200% during S and G2/M. To determine t-PA production CHO cells were sorted from G1-, early/late S-, and G2/M-phase. After 1-, 2-, and 4-h incubation periods, t-PA production was quantitated using a sensitive t-PA ELISA technique. We found that t-PA production and secretion (2-h assay), unlike the expression of DHFR, increased continuously from relatively 100% in G1 to 127% in early S and reached its maximum of 159% in late S, whereas in G2/M-phase it decreased to 118%. Our results show that in pSVtPA.dhfr-coamplified CHO cells gene products DHFR and t-PA both exhibit different cell cycle-correlated accumulation and secretion, respectively, indicating that the brightest MTX-FITC-positive cells (G2/M) do not display the highest t-PA secretion rate.

The continuum model and c-myc synthesis during the division cycle

Discordant results on the synthesis of c-myc gene products during the division cycle are reanalyzed and shown to be understood in light of the continuum model. It is proposed that there is no G1-phase dependence of c-myc synthesis. The large amount of data supporting G1-specific syntheses and a G(0) state must be re-examined.

Synchronization of replicons in Ehrlich ascites cells

Ehrlich ascites cells, in which replication units at the beginning of the S phase started and grew synchronously, were obtained by the following protocol: (1) selection of G1 cells by zonal centrifugation, (2) hypoxia for 12 h, (3) reaeration, (4) addition of cycloheximide (30 microM) within the first minute after reoxygenation. Studies on the effectiveness of the different steps revealed: (i) G1 cells reoxygenated after 12 h of hypoxia traverse two succeeding cell cycles highly synchronously. This was shown by monitoring the thymidine incorporation rate, the thymidine pulse-labeling index, and the mitotic index. (ii) Cycloheximide, like hypoxia, suppresses replicon initiation in Ehrlich ascites cells without interfering with DNA chain growth and DNA maturation. The reversibility of the suppression is less complete than in the case of hypoxia. This was shown by DNA fiber autoradiography and by analyzing the length distribution of pulse- or pulse/pulse-chase-labeled daughter DNA in alkaline sucrose gradients. The alkaline sedimentation patterns of daughter-strand DNA, pulse labeled immediately after the cycloheximide addition at the end of the elaborated protocol and 1 and 2 h later, indicated synchronous initiation and growth of a homogeneous population of DNA molecules to replicon-sized lengths.

An antigen expressed in proliferating cells at late G1-S phase

A monoclonal antibody Pr-28 was prepared, which recognized an antigen present only in proliferating cells. Immunofluorescence analysis of Pr-28 antigen showed that the antigen was localized mainly in perinuclear cytoplasm. Although Pr-28 antibody was produced against a chicken cell antigen, it reacts not only with chicken cells but also other cells of murine origin, such as L-cells and NIH 3T3 cells. The molecular weight (Mr) of the antigen recognized by Pr-28 antibody was 45,000 D as determined by SDS-PAGE run under reducing conditions. The antigen disappeared in NIH 3T3 quiescent cells, reappearing in quiescent cells stimulated by fetal calf serum (FCS). The synthesis of Mr 45,000 protein occurred at late G1 phase, just before DNA synthesis in serum-stimulated quiescent NIH 3T3 cells and ceased in S phase.

Cloning of a human S-phase cell cycle gene: use of transient expression for screening

We report here the cloning of a human cell cycle gene capable of complementing a temperature-sensitive (ts) S-phase cell cycle mutation in a Chinese hamster cell line. Cloning was performed as follows. A human genomic library in phage lambda containing 600,000 phages was screened with labeled cDNA synthesized from an mRNA fraction enriched for the specific cell cycle gene message. Plaques containing DNA inserts which hybridized to the cDNA were picked, and their DNAs were assayed for transient complementation in DNA transformation experiments. The transient complementation assay we developed is suitable for most cell cycle genes and indeed for many genes whose products are required for cell proliferation. Of 845 phages screened, 1 contained an insert active in transient complementation of the ts cell cycle mutation. Introduction of this phage into the ts cell cycle mutant also gave rise to stable transformants which grew normally at the restrictive temperature for the ts mutant cells.

The pharmacological mediation of epithelial cell proliferation

In the past, it has been necessary for pharmacological intervention of epithelial proliferation to mostly be limited to non-specifically arresting or killing actively proliferating cells. As our understanding of the mechanisms involved in mediating the processes of growth and differentiation increases, we can hope to see the development of a new pharmacology, in which proliferation of individual systems may be regulated in a less drastic manner.

Kinetics of DNA replication in C3H 10T1/2 cells synchronized by aphidicolin

Aphidicolin is an inhibitor of DNA polymerase alpha and blocks nuclear DNA replication without interfering with mitochondrial DNA synthesis. The efficacy of this mycotoxin as a tool in cell synchronization was evaluated in C3H 10T1/2 clone 8 cells. At concentrations of 1-2 micrograms/mL, aphidicolin quickly reduced the [3H]thymidine uptake to less than 5% of control levels in the first 5 min of incubation. This inhibition was easily reversed by washing and refeeding cells with fresh medium. The synchronization protocol consisted of first blocking cells by confluence arrest, replating them at lower density, and then treating the cells with aphidicolin for 24 h. Once the inhibitor was removed, DNA replication started without any delay. The cell population traversed the S phase in about 8 h and synchronously doubled in cell number. Autoradiography studies revealed a labeling index of 89-93% during the S phase. However, it was also observed that 10T1/2 cells were able to enter S phase in the presence of aphidicolin. The extent of the ensuing replication in the nucleus was dependent on the time that cells remained arrested in early S phase. Analyses of the newly replicated DNA in alkaline sucrose gradients revealed a fairly homogeneous distribution of sizes of nascent DNA in synchronized cells pulse-labeled at the beginning of the S phase. Upon chase in nonradioactive medium, the average molecular weight of the nascent DNA increased linearly with time of DNA synthesis for 2 h. The apparent rate of DNA chain growth determined from pulse and chase experiments was 1.2 micron/min. This rate was strongly inhibited (93%) by aphidicolin at a concentration of 2 micrograms/mL.

Stimulation by somatostatin of dephosphorylation of membrane proteins in pancreatic cancer MIA PaCa-2 cell line

A membrane receptor and a cytosolic receptor for somatostatin were found in a human undifferentiated pancreatic cancer cell line (MIA PaCa-2). Binding of somatostatin to this membrane receptor activates dephosphorylation of a phosphotyrosyl-membrane protein whose phosphorylation was promoted by epidermal growth factor (EGF). Vanadate, a purported inhibitor of dephosphorylation, interferes with the action of somatostatin. These findings suggest a possible biochemical mechanism by which somatostatin may inhibit the growth of human pancreatic cancers.

Co-ordinate control of centrosomal separation and DNA synthesis by growth regulators

We have tested the effects of various mitogens and growth inhibitors on centrosomal separation (CS) in serum-deprived HeLa, gerbil fibroma (GF) and A431 cells. All of the agents which were mitogenic in a given cell type also stimulated CS. No agent was found which stimulated CS but failed to stimulate DNA synthesis. Inhibitors of DNA synthesis, including somatostatin, hydrocortisone, 8-bromo-cAMP, and epidermal growth factor (EGF) in A431 cells, also inhibited CS in response to mitogens. In GF cells (blocked at the G1/S interface with hydroxyurea) centrosomal re-association and the decay in commitment to DNA synthesis upon serum withdrawal occurred with a similar t1/2 (8.8 h). These results demonstrate that CS and DNA synthesis are co-ordinately regulated by a variety of stimulators and inhibitors of cell proliferation. Separation of the centrosomes, or an underlying event with which it is tightly coupled, may represent the point of cellular commitment to enter S phase.

Cell cycle regulation of human histone H1 mRNA

A cloned genomic DNA fragment containing a human histone H1 gene has been used to analyze histone H1 gene expression in two human cell lines (HeLa S3 and WI-38). The cellular abundance of histone H1 mRNA was compared with that of core (H2A, H2B, H3, and H4) histone mRNAs as a function of the cell cycle: core and H1 histone mRNA levels are related both to each other and to the apparent rate of DNA synthesis and are rapidly destabilized after DNA synthesis inhibition. The use of three synchronization protocols, and of transformed and normal diploid cells in culture, suggests that the detected core and H1 histone mRNA levels are regulated by similar mechanisms in continuously dividing human cell lines and nondividing cells stimulated to proliferate.

Phosphorylation of nuclear proteins

Many nuclear proteins are phosphorylated: they range from enzymes to several structural proteins such as histones, non-histone chromosomal proteins and the nuclear lamins. The pattern of phosphorylation varies through the cell cycle. Although histone H1 is phosphorylated during interphase its phosphorylation increases sharply during mitosis. Histone H3, chromosomal protein HMG 14 and lamins A, B and C all show reversible phosphorylation during mitosis. Several nuclear kinases have been characterized, including one that increases during mitosis and phosphorylates H1 in vitro. Factors have been demonstrated in maturing amphibian oocytes and mitotic mammalian cells that induce chromosome condensation and breakdown of the nuclear membrane. The possibility that they are autocatalytic protein kinases is considered. The location of histone phosphorylation sites within the nucleosome is consistent with a role for phosphorylation in modulating chromatin folding.

Growth of the mitochondrial inner membrane in synchronous cultures of Tetrahymena pyriformis: an examination of phospholipid accumulation

Based on morphological evidence, mitochondrial inner membrane growth has been reported to be discontinuous in heat shock-synchronized Tetrahymena pyriformis. As a biochemical measure of membrane growth under these conditions, we have examined phospholipid accumulation in the cell. No marked modulation of the accumulation of any of the major phospholipids could be detected through the cell cycle. At least 89% of the cardiolipin in the cells is restricted to the mitochondria, and we have used it as a marker for the growth of the mitochondrial inner membrane. During the heat shock synchrony, cardiolipin accumulates uniformly in parallel with the exponential rate of increase of total cellular phospholipids. These results suggest that at least the phospholipid component of all membrane systems in the cell grow continuously and uniformly. Additionally, we have shown that the total phospholipid content of Tetrahymena increases by a factor of 2.4 per generation following a series of heat shocks. No such net overaccumulation is observed for protein content.

The G1 period. Two cycles of chromatin conformational changes monitored by single cell dye intercalation

In previous papers the existence of two cycles of chromosome condensation-decondensation per cell cycle was suggested based on experiments involving nuclear morphometry measurements of Feulgen-stained nuclei. This conclusion can be criticized since its assumption of a relationship between nuclear morphology and chromatin structure is derived from indirect evidence. In this paper, we report simultaneous measurements of nuclear area and nuclear fluorescence intensity on individual cells stained with the intercalating dye, acridine orange (AO). Using cells in various stages of G1 and synchronized by two different methods, our results demonstrate a linear correlation between nuclear area and fluorescence intensity. They also indicate two cycles of chromatin condensation-decondensation during the G1 period, as assayed by the number of chromatin primary, intercalating AO binding sites. Finally, they show that the first of these cycles involves a transition in early G1 from a very small condensed nucleus (immediately after telephase) to a relatively large, dispersed nucleus that occurs abruptly.

Comparison of kinetics of X-ray-induced cell killing in normal, ataxia telangiectasia and hereditary retinoblastoma fibroblasts

Survival, cumulative labeling indices and chromosomal aberrations were studied in normal, ataxia telangiectasia (AT) and hereditary retinoblastoma fibroblasts after X-irradiation during density-inhibition of growth and immediate release by subculture to low density. The D0 of the survival curves were: normal strains, 150-160 rad; Retinoblastoma strains AG 1880, 95 rad; AG 1978, 40-50 rad (sensitive fraction); AT5BI, 45 rad. Mainly chromosome-type Aberrations were induced in normal and retinoblastoma cells. The frequency of X-ray-induced chromosomal aberrations was much higher in AT5BI cells, and 33-45% were of the chromatid type. Normal and retinoblastoma cells showed a measureable X-ray induced G1 delay before entering S. In addition, a fraction of the cells showed an apparently irreversible G1 block; these cells did not initiate DNA synthesis up to 120 h post-irradiation and subculture. The G1 block was much more marked in retinoblastoma cells; after 400 rad about 70% of retinoblastoma cells did not enter S as compared with only 20% of normal cells. Neither a G1 delay nor a G1 block was observed in AT cells irradiated with up to 400 rad despite their hypersensitivity to cell killing by X-rays and evidence of severe chromosome damage. These results suggest different mechanisms for the X-ray hypersensitivity of AT and retinoblastoma cells.

Differences in growth regulation of normal and tumor cells

Normal cells cannot initiate DNA synthesis under inadequate external conditions, yet after growth has started they complete their division cycle under these conditions. The sensitive biochemical event for a growing cell is proposed to be accumulation of a labile protein which in adequate amounts permits entry into S phase, after about 2 hr, and completion of the cycle. Instability of this protein (half-life about 2.5 hr) creates a dynamic state so that its accumulation depends on rates of both synthesis and degradation. Neoplastic cells may show poorly regulated growth either by synthesizing this protein more rapidly or degrading it less rapidly, under conditions that limit normal cells' growth. Known mechanisms of overproduction include: more copies of the protein's structural gene per cell, an adjacent high-activity promoter, or autoproduction of growth factors. Less rapid degradation could result from less protease activity or from stabilizing modifications of the protein. Thus, derangement in the control of a labile growth-regulatory protein acting by any one of these diverse mechanisms could lead to neoplasia.