REGULATION OF INITIATION OF DNA SYNTHESIS IN CHINESE HAMSTER CELLS : II. Induction of DNA Synthesis and Cell Division by Isoleucine and Glutamine in G(1)-Arrested Cells in Suspension Culture

Explaining Redundancy in CDK-Mediated Control of the Cell Cycle: Unifying the Continuum and Quantitative Models

In eukaryotes, cyclin-dependent kinases (CDKs) are required for the onset of DNA replication and mitosis, and distinct CDK–cyclin complexes are activated sequentially throughout the cell cycle. It is widely thought that specific complexes are required to traverse a point of commitment to the cell cycle in G1, and to promote S-phase and mitosis, respectively. Thus, according to a popular model that has dominated the field for decades, the inherent specificity of distinct CDK–cyclin complexes for different substrates at each phase of the cell cycle generates the correct order and timing of events. However, the results from the knockouts of genes encoding cyclins and CDKs do not support this model. An alternative “quantitative” model, validated by much recent work, suggests that it is the overall level of CDK activity (with the opposing input of phosphatases) that determines the timing and order of S-phase and mitosis. We take this model further by suggesting that the subdivision of the cell cycle into discrete phases (G0, G1, S, G2, and M) is outdated and problematic. Instead, we revive the “continuum” model of the cell cycle and propose that a combination with the quantitative model better defines a conceptual framework for understanding cell cycle control.

The Amino Acid Sensor Eif2ak4/GCN2 Is Required for Proliferation of Osteoblast Progenitors in Mice

Skeletal stem/progenitor cells (SSPC) are critical regulators of bone homeostasis by providing a continuous supply of osteoblasts throughout life. In response to inductive signals, SSPC proliferate before osteoblast differentiation. Proliferation requires the duplication of all cellular components before cell division. This imposes a unique biosynthetic requirement for amino acids that can be used for biomass production. Thus, the ability to sense and respond to amino acid availability is likely a major determinant for proliferation. Using a cellular and genetic approach, we demonstrate the amino acid sensor GCN2 is required to support the robust proliferative capacity of SSPC during bone homeostasis. GCN2 ablation results in decreased postnatal bone mass due primarily to reduced osteoblast numbers. Decreased osteoblast numbers is likely attributed to reduced SSPC proliferation as loss of GCN2 specifically affected proliferation in cultured bone marrow stromal cells (BMSCs) without impacting osteoblast differentiation in vitro. Mechanistically, GCN2 regulates proliferation by increasing amino acid uptake downstream of the transcriptional effector ATF4. Collectively, these data suggest amino acid sensing through the GCN2/ATF4 pathway is indispensable for robust SSPC proliferation necessary for bone homeostasis. © 2020 American Society for Bone and Mineral Research.

Cell suicide in starving hybridoma culture: survival-signal effect of some amino acids

Two mouse hybridoma cell lines cultured in different basal media withthe iron-rich protein-free supplement were subjected to deliberatestarvation by inoculation into media diluted with saline to 50% or less.In the diluted media the growth was markedly suppressed and a largefraction of cells died by apoptosis. The cells could be rescued fromapoptotic death by individual additions of amino acids, such as glycine,L-alanine, L-serine, L-threonine, L-proline, L-asparagine, L-glutamine,L-histidine, D-serine, β-alanine or taurine. Amino acids withhydrophobic or charged side chains were without effect. The apoptosispreventing activity manifested itself even in extremely diluted media,down to 10% of the standard medium. The activity of L-alanine in theprotection of cells starving in 20% medium was shown also in semicontinuousculture. In the presence of 2 mM L-alanine the steady-state viable cell density more than doubled, with respect to control, andthe apoptotic index dropped from 37% in the control to 16%. It wasconcluded that the apoptosis-preventing amino acids acted as signalmolecules, rather than nutrients, and that the signal had a character ofa survival factor. The specificity of present results, obtained with twodifferent hybridomas, supports our view (Franěk and Chládková-Šrámková, 1995) that the membranetransport macromolecules themselves may play the role of therecognition elements in a signal transduction pathway controlling thesurvival of hybridoma cells.

Cell suicide in starving hybridoma culture: survival-signal effect of some amino acids

Two mouse hybridoma cell lines cultured in different basal media with the iron-rich protein-free supplement were subjected to deliberate starvation by inoculation into media diluted with saline to 50% or less. In the diluted media the growth was markedly suppressed and a large fraction of cells died by apoptosis. The cells could be rescued from apoptotic death by individual additions of amino acids, such as glycine, L-alanine, L-serine, L-threonine, L-proline, L-asparagine, L-glutamine, L-histidine, D-serine, β-alanine or taurine. Amino acids with hydrophobic or charged side chains were without effect. The apoptosis preventing activity manifested itself even in extremely diluted media, down to 10% of the standard medium. The activity of L-alanine in the protection of cells starving in 20% medium was shown also in semicontinuous culture. In the presence of 2 mM L-alanine the steady-state viable cell density more than doubled, with respect to control, and the apoptotic index dropped from 37% in the control to 16%. It was concluded that the apoptosis-preventing amino acids acted as signal molecules, rather than nutrients, and that the signal had a character of a survival factor. The specificity of present results, obtained with two different hybridomas, supports our view (Franěk and Chládková-Šrámková, 1995) that the membrane transport macromolecules themselves may play the role of the recognition elements in a signal transduction pathway controlling the survival of hybridoma cells.

Protein profiles of the Chinese hamster ovary cells in the resting and proliferating stages

Identification and characterization of the proteins that regulate the transition from the resting stage (G0) through G1 to S phase of the cell cycle are of central importance to understand the control of cell proliferation and chromosome replication. Unlike in lower organisms, where relatively small numbers of key factors are involved in this process, the factors involved in the same control mechanisms in mammalian systems are much more complex. Furthermore, accumulating lines of evidence now suggest that the nuclear matrix and chromatin organization also play an essential role for the cell cycle control in mammalian cells. To gain a better understanding of the overall dynamics and changes of the protein factors in the context of matrix/chromatin organization, we examined the protein profiles of the Chinese hamster ovary (CHO) cells in different cell cycle compartments. The methods used in this study included subcellular fractionations (cytosol, nuclear extraction, chromatin, and nuclear matrix), two-dimensional polyacrylamide gel electrophoresis (2-D PAGE), silver staining, and immunoblotting. As expected, significant changes of protein profiles were observed when cells entered into proliferating stages from G0. Among approximately 1200 protein spots analyzed by 2-D PAGE, at least 12 showed marked increase or decrease at this transitional period. Further cell-cycle progression from G1 to S phase showed less dramatic changes of overall protein protile. However, the profile of certain proteins showed rather dramatic changes of their subcellular localization during this transitional period. In particular, the levels of proliferating cell nuclear antigen (PCNA) in the nuclear matrix and chromatin dramatically increased in mid-G1 and in the beginning of S phase, respectively, while the overall PCNA level was relatively constant throughout the cell cycle.

Protective function of p27(KIP1) against apoptosis in small cell lung cancer cells in unfavorable microenvironments

A previous study of ours unexpectedly found that in contrast to frequent reductions in non-small cell lung cancer, high expression of the p27(KIP1) cyclin-dependent kinase (CDK) inhibitor was retained in virtually all small cell lung cancers (SCLCs), suggesting the possibility of high expression of nonfunctional p27(KIP1) in this virulent tumor. The study presented here, however, shows that p27(KIP1) in SCLC biochemically functions as a CDK inhibitor, clearly showing induction apparently associated with G(1)/G(0) arrest and efficient binding to and inhibition of the cyclin E-CDK2 complex. Interestingly, induction of p27(KIP1) seems to confer on SCLC cells the ability to survive under culture conditions unfavorable for cell growth such as a lack of nutrients and hypoxia. Subsequent experiments manipulating p27(KIP1) levels by using a sense p27(KIP1) expression construct or an antisense oligonucleotide supported this notion. These observations suggest that high expression of p27(KIP1) in vivo may favor the survival of SCLC by preventing apoptosis in a microenvironment unfavorable for cell proliferation.

Amino acid deprivation induces translation of branched-chain alpha-ketoacid dehydrogenase kinase

Leucine, isoleucine, and valine are used by cells for protein synthesis or are catabolized into sources for glucose and lipid production. These branched-chain amino acids influence proteolysis, hormone release, and cell cycle progression along with their other metabolic roles. The branched-chain amino acids play a central role in regulating cellular protein turnover by reducing autophagy. These essential amino acids are committed to their catabolic fate by the activity of the branched-chain alpha-ketoacid dehydrogenase complex. Activity of the branched-chain alpha-ketoacid dehydrogenase complex is regulated by phosphorylation/inactivation of the alpha-subunit performed by a complex specific kinase. Here we show that elimination of the branched-chain amino acids from the medium of cultured cells results in a two- to threefold increased production of the branched-chain alpha-ketoacid dehydrogenase kinase with a decrease in the activity state of the branched-chain alpha-ketoacid dehydrogenase complex. The mechanism cells use to increase kinase production under these conditions involves recruitment of the kinase mRNA into polyribosomes. Promoter activity and the steady-state concentration of the mRNA are unchanged by these conditions.

Mechanisms of progesterone receptor export from nuclei: role of nuclear localization signal, nuclear export signal, and ran guanosine triphosphate

Steroid hormone receptors are, in most cases, mainly nuclear proteins that undergo a continuous nucleocytoplasmic shuttling. The mechanism of the nuclear export of these proteins remains largely unknown. To approach this problem experimentally in vivo, we have prepared cell lines permanently coexpressing the wild-type nuclear progesterone receptor (PR) and a cytoplasmic receptor mutant deleted of its nuclear localization signal (NLS) [(deltaNLS)PR]. Each receptor species was deleted from the epitope recognized by a specific monoclonal antibody, thus allowing separated observation of the two receptor forms in the same cells. Administration of hormone provoked formation of heterodimers during nucleocytoplasmic shuttling and import of (deltaNLS)PR into the nucleus. Washing out of the hormone allowed us to follow the export of (deltaNLS)PR into the cytoplasm. Microinjection of BSA coupled to a NLS inhibited the export of (deltaNLS)PR. On the contrary, microinjection of BSA coupled to a nuclear export signal (NES) was without effect. Moreover, leptomycin B, which inhibits NES-mediated export, was also without effect. tsBN2 cells contain a thermosensitive RCC1 protein (Ran GTP exchange protein). At the nonpermissive temperature, the nuclear export of (deltaNLS)PR could be observed, whereas the export of NES-BSA was suppressed. Microinjection of GTPgammaS confirmed that the export of (deltaNLS)PR was not dependent on GTP hydrolysis. These experiments show that the nuclear export of PR is not NES mediated but probably involves the NLS. It does not involve Ran GTP, and it is not dependent on the hydrolysis of GTP. The nucleocytoplasmic shuttling of steroid hormone receptors thus appears to utilize mechanisms different from those previously described for some viral, regulatory, and heterogeneous ribonuclear proteins.

Occurrence and role of an early antigen and evidence for transforming ability of porcine circovirus

By means of indirect immunofluorescence assay (IFA) using natural swine immune serum and hyperimmune serum from rabbits infected with porcine circovirus (PCV), a PCV antigen was detected present prior to the onset of viral and cellular DNA synthesis in nucleoli of cells of synchronized and growth stimulated infected PS cell cultures grown for more than 12 h in the presence of hydroxyurea. The number of cells containing specifically fluorescing nucleoli increased with increasing time of growth in the presence of hydroxyurea. The concomitant increase in the number of cells containing virus structural (VS) antigen in the nuclei and the increase in the amount of replicative (RF) DNA and accompanying 5 S DNA after release from the hydroxyurea block suggest that EA is involved in induction of PCV DNA replication. Primary pig kidney cell cultures persistently infected with PCV survived mock-infected control cultures for 16 passages. They had lost contact inhibition and formed cell colonies in soft agar at a ratio of 0.1 to 0.4%. Cell lines derived from agar colonies showed properties of transformed cells e.g. low requirement for serum growth factors, ability to overgrow a continuous cell layer, anchorage independence of growth. In transformed cells stimulated to growth and grown in the presence of hydroxyurea, non-structural viral antigen visible by IFA in nucleoli and VS antigen located in the cytoplasm were expressed. Contrary to virus bound nuclear VS antigen in productive infection, accumulation of cytoplasmatic VS antigen was independent of DNA synthesis and caused cell destruction, thus limiting growth of cell layers and colonies in soft agar.

Arrest of cell cycle progression of HeLa cells in the early G1 phase in K(+)-depleted conditions and its recovery upon addition of insulin and LDL

Cell cycle progression of synchronized HeLa cells was studied by measuring labeling of the nuclei with [3H]thymidine. The progression was arrested in a chemically defined medium in which K+ was replaced by Rb+ (Rb-CDM) but was restored upon addition of insulin and/or low density lipoprotein (LDL). Cells started DNA synthesis 12 hr after addition of insulin and/or LDL, regardless of the time of arrest, suggesting their arrest early in the G1 phase. After incubation of cells in Rb-CDM containing insulin or LDL singly for 3, 6, or 9 hr, replacement of the medium by that without an addition resulted in marked delay in entry of cells into the S phase, but in its replacement by medium containing both agents, the delay was insignificant. Synthesis of bulk protein, estimated as increase in the cell volume, was not strongly inhibited. From these results we conclude that cell cycle progression of HeLa cells in K(+)-depleted CDM is arrested early in the G1 phase and that the arrest is due to lack of some protein(s) required for entry into the S phase that is synthesized in the early G1 phase.

NS2 is required for efficient translation of viral mRNA in minute virus of mice-infected murine cells

Detailed analysis of five NS2 mutants of the autonomous parvovirus minute virus of mice (MVMp) has revealed the following. At low multiplicities of infection, NS2 mutants killed NB324K cells as well as wild-type (wt) MVM did and grew to high titers, while in contrast they grew poorly and did not readily kill murine A9 cells. Following CaPO4 transfection of murine fibroblasts, NS2 mutant infectious clones generated approximately 10-fold less monomer replicative-form DNA than wt and no detectable progeny single-stranded DNA. On nonmurine semipermissive NB324K cells, however, these mutant plasmid clones generated near wt levels of all replicative DNA forms. After infection of highly synchronized murine fibroblasts by NS2 mutant virus at inputs equivalent to those of the wt, mutant monomer replicative-form DNA was decreased 5- to 10-fold compared with that of the wt, and progeny single-stranded DNA accumulation was decreased to an even greater extent. Both total and cytoplasmic NS2 mutant RNA was decreased, but the amount of total viral mRNA generated, relative to accumulated viral DNA in the same experiments, was similar to that seen in wt infection. The accumulation of virus-generated proteins was also decreased in NS2 mutant infection; however, the magnitude of this decrease, compared with that of wt infections, was significantly greater than the concomitant decrease in mutant-generated levels of accumulated cytoplasmic RNA, and this effect was most dramatic for VP2. There was no such disparity between the relative accumulation of mutant-generated RNA and protein in cells permissive for the growth of these mutants. These results suggest that translation of MVM viral RNA is specifically reduced in NS2 mutant infection of restrictive cells. Because the affected viral proteins are required for the efficient production of viral replicative DNA forms, these results reveal a fundamental, although perhaps not the only, role for NS2 in parvovirus infection.

Transcription initiation and temporal expression of thymidine kinase mRNA in Chinese hamster cells

The induction of thymidine kinase mRNA has proved to be a valuable model for understanding regulatory events at the G1/S boundary of the cell cycle (1, 2, 3). As an initial step toward characterizing the regulation of this gene in Chinese hamster cells, I have mapped the transcription start sites for TK mRNA in CHEF/18 cells. Two closely spaced sites of transcription initiation were detected downstream of a nonconsensus TATAA element in the promoter region. Using primer extension analyses, I demonstrated that the transcription initiation sites remained constant while the absolute levels of TK mRNA varied during the cell cycle in synchronized populations of Chinese hamster cells.

Chinese hamster ovary cell growth and interferon production kinetics in stirred batch culture

Recombinant human interferon-gamma production by Chinese hamster ovary cells was restricted to the growth phase of batch cultures in serum-free medium. The specific interferon production rate was highest during the initial period of exponential growth but declined subsequently in parallel with specific growth rate. This decline in specific growth rate and interferon productivity was associated with a decline in specific metabolic activity as determined by the rate of glucose uptake and the rates of lactate and ammonia production. The ammonia and lactate concentrations that had accumulated by the end of the batch culture were not inhibitory to growth. Glucose was exhausted by the end of the growth phase but increased glucose concentrations did not improve the cell yield or interferon production kinetics. Analysis of amino acid metabolism showed that glutamine and asparagine were exhausted by the end of the growth phase, but supplementation of these amino acids did not improve either cell or product yields. When glutamine was omitted from the growth medium there was no cell proliferation but interferon production occurred, suggesting that recombinant protein production can be uncoupled from cell proliferation.

Accumulation of MVM gene products is differentially regulated by transcription initiation, RNA processing and protein stability

The accumulation and stability of minute virus of mice (MVMp) RNA and protein as well as comparative strengths of the two viral promoters have been analyzed in highly synchronous infections of murine A9 fibroblasts. Results indicate that there is a temporal phasing of the accumulation of MVM RNA and protein: the RNA products of the P4 promoter appear prior to the products of the P38 promoter and NS1 and NS2 appear prior to the capsid proteins. Total and cytoplasmic spliced RNA accumulate similarly, although there is a lag in cytoplasmic accumulation of about 2 hr. Total RNA contains abundant unspliced R1 and R3 which are confined to the nucleus. There is no detectable difference in the ratio of the various spliced versions of each RNA species throughout infection. R2 accumulates faster and in a greater amount than R1 in both total and cytoplasmic RNA even though they are generated from the same promoter. During this same period, however, NS1 and NS2 accumulate to similar levels during 1-hr pulses. The stabilities of all MVM RNA species produced at both 9 and 12 hr postrelease are equivalent. Late in infection R3 accumulates faster and in greater amounts than the combined products of the P4 promoter, by approximately two- to threefold. This increase can be accounted for by an increase in the frequency of initiation from the P38 promoter, relative to P4, as assayed by nuclear run-on experiments. Therefore, the steady-state levels of the individual viral proteins during infection is controlled by specific regulation at the level of the initiation of transcription, RNA processing, and protein stability.

Enhancement of anticancer agent activity by selective inhibition of rapidly proliferating tissues of the host

Most cytotoxic drugs used in cancer therapy do not discriminate between neoplastic and normal proliferating cells. To avoid irreversible damage to vital host tissues, such as bone marrow and intestine, drugs must be administered at dosages which usually prove insufficient to eradicate all of the neoplastic cells present. This review focuses on an approach to improve cancer chemotherapy by selectively protecting normal, proliferating cells during treatment, thereby permitting the administration of otherwise lethal doses of drug. Preclinical in vivo studies of cytokinetic modulation with interferon, or L-histidinol, as well as recent clinical studies of interferon modulation of the activity of 5-fluorouracil are reviewed.

S-phase-specific expression of mammalian ribonucleotide reductase R1 and R2 subunit mRNAs

Ribonucleotide reductase in mammalian cells is composed of two nonidentical subunits, proteins R1 and R2, each inactive alone. The R1 protein is present in excess in proliferating cells, and its levels are constant during the cell cycle. Expression of the R2 protein, which is limiting for enzyme activity, is strictly S-phase-correlated. In this paper, we have used antisense RNA probes in a solution hybridization assay to measure the levels of R1 and R2 mRNA during the cell cycle in centrifugally elutriated cells and in cells synchronized by isoleucine or serum starvation. The levels of both transcripts were very low or undetectable in G0/G1-phase cells, showed a pronounced increase as cells progressed into S phase, and then declined when cells progressed into G2 + M phase. The R1 and R2 transcripts increased in parallel, starting slightly before the rise in S-phase cells, and reached the same levels. The relative lack of cell cycle dependent variation in R1 protein levels, obtained previously, may therefore simply be a consequence of the long half-life of the R1 protein. Hydroxyurea-resistant, R2-overproducing mouse TA3 cells showed the same regulation of the R1 and R2 transcripts as the parental cells, but with R2 mRNA at a 40-fold higher level.

Limited cell attachment time as a method to synchronize cells grown in monolayer culture

A novel method of synchronizing monolayer tissue culture cells is described. By limiting the period of attachment of trypsinized cells and the subsequent removal of unattached cells a G1 population of cells is isolated. Evaluation of the degree of synchrony has been carried out by measuring the labeling index and incorporation of [3H]thymidine into DNA. Further conformation of synchrony, as well as a comparison with synchrony by isoleucine deprivation, was obtained by flow cytometry. The expected peak in DNA synthesis rate following limited attachment was observed. This peak becomes more prominent and shifts to earlier times with shorter attachment intervals. The synchronization method described is simple, rapid, yields a substantial number of cells, and is applicable to many cell lines.

Availability of glutamine from peptides and acetylglutamine for human tumor-cell cultures

In a recent study we showed that the growth behavior of a hematopoietic cell line (K 562) in culture was the same when using glutamine-containing dipeptides or glutamine as substrate. In this article we study the growth behavior of different tumor cells, originating from the hematopoietic system (K 562), stomach (Kato III), pancreas (Panc 1), and breast (T 47 D), to test the biological activity as preclinical in vitro screening system. We compared L-glutamine (GLN), N-acetyl-L-glutamine (ACE-GLN), L-alanyl-L-glutamine (ALA-GLN), and glycyl-L-glutamine (GLY-GLN). Cell proliferation was measured with the incorporation of [3H] thymidine or the MTT assay (cleavage of 3-(4,5-dimethyldiazol-2-yl)-2-5-diphenyl tetrazolium bromide by mitochondria). In all investigated cell types cell growth was stimulated when using glutamine-containing dipeptides or ACE-GLN instead of a glutamine-free media (not significant for T 47 D). However, GLN or ALA-GLN was advantageous to GLY-GLN or ACE-GLN when measuring cell proliferation with the MTT-assay up to 72 hours. However, alanylglutamine does not enhance proliferation, compared with free glutamine.

Interferons and indoleamine 2,3-dioxygenase: role in antimicrobial and antitumor effects

Indoleamine 2,3-dioxygenase (IDO) is an interferon (IFN)-induced protein that initiates the metabolism of tryptophan along the kynurenine pathway. Although IDO can be induced by IFN-gamma in many cell types, only mononuclear phagocytes have been shown to be induced to decyclize tryptophan by all three IFN classes. Since tryptophan is an essential amino acid necessary for a variety of metabolic processes, depletion of available tryptophan may be an important mechanism for control of rapidly-dividing microbial pathogens and tumors. The purpose of this review is to present evidence that documents the effects of IFN-induced IDO on prokaryotic and eukaryotic pathogens, as well as on a variety of tumor cell lines.

Centriole ciliation and cell cycle variability during G1 phase of BALB/c 3T3 cells

Although variability in the duration of the cell cycle is thought to reflect growth-regulatory processes that control cell cycle progression, the precise timing of the variable period within the G1 phase of the cell cycle has not been defined. In particular, the timing of cell cycle variability in relation to the cell's commitment (R point) to the initiation of DNA synthesis remains controversial. In order to investigate cell cycle variability, indirect immunofluorescence was used to measure the formation of the primary cilium as a possible marker of G1 events in both stimulated quiescent and exponentially growing cells. The primary cilium, an internal "9 + 0" nonmotile structure formed by one of the interphase centrioles, was first detected in postmitotic BALB/c 3T3 cells 5 hr before the initiation of DNA synthesis, an interval similar to that for the reassembly of the primary cilium in serum-stimulated quiescent fibroblasts. This similarity in the timing of ciliation suggests that serum-stimulated quiescent cells reenter the cell cycle in early G1 and recapitulate much of G1. Moreover, the rate of cilia formation in both postmitotic and serum-stimulated quiescent cells was identical to the rate of DNA synthesis initiation. Thus, cell cycle variability occurs before ciliation in both stimulated quiescent and exponentially growing cells. Furthermore, since ciliation also precedes the R point, variability in the centriole cycle occurs before the R point and thus may reflect processes controlling the cell's commitment to the initiation of DNA synthesis.

Influence of the deprivation of a single amino acid on cellular proliferation and survival in rat 3Y1 fibroblasts and their derivatives transformed by a wide variety of agents

We compared proliferation and survival of various syngeneic transformed cell lines under conditions of depletion of 15 amino acids in Dulbecco-Eagle's medium. We used a normal fibroblast line 3Y1 and 22 transformed sublines of 3Y1 which had been induced by one of seven transforming agents--simian virus 40, mouse polyomavirus, adenovirus type 12, E1A gene of adenovirus type 12, cDNA of Harvey murine sarcoma virus, Rous sarcoma virus, or N-methyl-N'-nitro-N-nitrosoguanidine. Unlike other untransformed cells examined (mouse BALB/c-3T3 line, mouse NIH-3T3 line, and primary Fischer rat embryo fibroblasts), 3Y1 ceased to proliferate and accumulated in a viable state with a G1-phase DNA content under 14 singular deprivations of amino acid. None of the transformed 3Y1 lines completely arrested in the G1 phase of the cell cycle and each showed different levels of survival, depending on each transforming agent. As for transformed 3Y1 cells induced by a given virus or a given transforming gene, any one of the three sublines shared the same trend with respect to proliferation and survival. Transformed derivatives induced by N-methyl-N'-nitro-N-nitrosoguanidine showed almost the same trend in proliferation, but the patterns of survival were not uniform. Our observations suggest that the unique responses of 3Y1 to amino acid depletion are differently modified by different transforming agents.

Generation and characterization of a temperature-sensitive mutation in the NS-1 gene of the autonomous parvovirus minute virus of mice

In-phase single-codon insertion mutations were constructed in the open reading frames of the NS-1 and NS-2 genes of the autonomous parvovirus minute virus of mice. A viral mutant containing an isoleucine insertion exclusively within NS-1 between residues 229 and 230 was isolated that produced approximately 3 orders of magnitude fewer plaques at 39 degrees C than at 32 degrees C. Preliminary characterization of the mutant demonstrated that the NS-1 gene product is independently required for both genome amplification and the regulation of the temporal expression between the two viral transcription units during lytic infection.

Introduction and metabolism of pentose and hexose phosphates in permeabilized Morris hepatoma 5123TC cells

Metabolism of arabinose 5-P, ribose 5-P and glucose 6-P in permeabilized and resealed Morris hepatoma 5123TC cells was investigated by measuring the contribution of these compounds to nucleic acid biosynthesis. The level of [14C]-arabinose (non-phosphorylated) incorporation into nucleic acids was slight, presumably due to the low activity of the transport system or the absence or low activity of a specific 'kinase' enzyme. The permeabilizing procedure involved the brief treatment of Morris hepatoma 5123TC cells with lysolecithin and resulted in a cell population which was permeable to charged compounds i.e. sugar phosphates and nucleotides, that otherwise could not cross the plasma membrane. The permeabilized (and resealed cells) retained normal cellular morphology and intactness of specific organelles as judged by the maintenance of functional properties. Following permeabilization, these cells resealed when transferred back to normal growth medium, and continued to divide and increase at the same rates as control non-permeabilized cell cultures. The permeabilized cells incorporated deoxyribonucleotides ([methyl -3H]-TTP) into DNA at a linear rate of 0.047 nmol per 10(7) cells min-1, representing 90-100 per cent of the DNA synthesis rate in vivo. The permeabilization technique, when coupled with procedures to establish cell synchrony, permitted the comparative estimate of the contributions of [14C]-labelled arabinose 5-P, ribose 5-P and glucose 6-P to RNA, DNA, amino acids, CO2, lactate and sugar mono- and bisphosphates. The percentage of [14C]-isotope incorporated into total nucleic acids by these three labelled sugar phosphates were 2.3, 4.9 and 6.3 respectively. Possible reasons for the lower incorporation of 14C from arabinose 5-P are given. The results are consistent with the proposal that arabinose 5-P, an intermediate of the L-type pentose pathway activity of 5123TC cells, was incorporated into nucleic acids by its interconversion with ribulose 5-P and ribose 5-P and thus into PRPP. This study represents the first report of sugar phosphate as opposed to free sugar metabolism by tumour cells in culture.

The transcription of B2 repeated sequences is regulated during the transition from quiescent to proliferative state in cultured rodent cells

The RNA polymerase III-dependent transcription of B2 repeated sequences has been monitored during the transition from the quiescent to proliferative state in cultured rodent cells and after polyomavirus-induced transformation. The level of RNAs containing B2 sequences was found to be higher in both the proliferative state of normal cells and in polyomavirus-transformed cells. In both systems, nuclear run-off transcription assays indicated that high levels of B2 RNAs are due to an enhanced transcription rate. These results suggest the presence of a B2-specific RNA pol III transcription factor(s) whose activity is sensitive to cell cycle progression and oncogenic transformation.

Replication of porcine circovirus: induction by glucosamine and cell cycle dependence

Multiplication of porcine circovirus (PCV) was found to be inducible by treatment of infected cell cultures with 300 mM glucosamine. One day after glucosamine treatment and after growth in fresh medium, an increase in the number of cells containing virus antigen of up to 50 times as compared to mock-treated cultures was observed. Analysis of this phenomenon revealed that replication of PCV DNA was induced. Only aminohexoses but not hexoses and acetylated aminohexoses were efficacious. The course of PCV replication in synchronized cell cultures infected at different periods of the cell cycle showed that PCV DNA synthesis depends on cellular enzymes expressed during S phase growth of cells. However, whereas in cell cultures treated with glucosamine after infection in G0 or during G1, the start of PCV replication was observed during the first S phase after growth stimulation, the latent period in mock-treated cultures lasted until the second S phase. Also in cell cultures transfected with PCV DNA in G0 or during G1 using DEAE-dextran as mediator, PCV replication started during the first S phase after growth release of the cells. From these findings the conclusion is drawn that glucosamine and DEAE-dextran initiate PCV replication by enabling the PCV genome to get entry to the cell nucleus that normally can be achieved only by inclusion in the daughter nuclei at the end of mitosis.

Factors controlling the size of DNA loops in frog embryos and Friend erythroleukemia cells

Measurements were made of the average size of fluorescent halos of nucleoids of developing frog embryos, mouse fibroblasts (A9 cells) and Friend erythroleukemia cells cultured with various compounds. These halos are thought to represent relaxed lengths of loops of DNA attached to the nuclear matrix. Measurement of transcription of RNA from nuclei in vitro suggested that cells with more loops (smaller halos) had more initiation sites for transcription. DNA loop number decreases during development of the frog embryos, and red blood cells of adults have even fewer and larger loops. One or two days of culture of Friend cells in various compounds that induce differentiation resulted in more DNA loops than for control cells, but after 5 days of culture the differentiated erythrocytes had fewer DNA loops than control cells at stationary phase. Stationary phase cells have almost twice as many DNA loops as log phase cells. Various compounds that stall cells at the G1/S border induced more DNA loops, but subsequently the number of DNA loops decreased as the cells entered S phase. A number of compounds which slow the rate of cell division cause the formation of more DNA loops, perhaps due to longer G1 periods.

Cell cycle-dependent modulation of biosynthesis and stimulus-evoked release of catecholamines in PC12 pheochromocytoma cells

Catecholamine biosynthesis and its stimulus-evoked release in PC12 pheochromocytoma cells were studied as a function of cell cycle by means of HPLC with electrochemical detection. We found that 3,4-dihydroxyphenylethylamine (dopamine) levels in PC12 cells remained constant throughout the period of cell cycle. In contrast, the noradrenaline content was dependent on the cell cycle: it increased during the S + G2 phase followed by a decrease in the M phase. These results were confirmed further by measuring the activities catalyzing the catecholamine biosynthesis. Thus, activities of tyrosine 3-monooxygenase and 3,4-dihydroxyphenylalanine decarboxylase were independent of the cell cycle, whereas both soluble and membrane-bound dopamine beta-monooxygenase activities were modulated during the cell cycle. On the other hand, release of the catecholamines stimulated with 50 mM KCl increased in the G1 phase, reached a maximum in the late G1, and then gradually decreased in later periods. We also found that carbamylcholine-induced release of the catecholamines occurred maximally in the early S + G2 phase followed by a decrease during the M phase. Cell cycle dependence of the catecholamine release was in good agreement with that of 45Ca2+ uptake. Thus, this study provides evidence that the catecholamine biosynthesis and its release in PC12 cells are modulated during the period of cell cycle.

Translation kinetics in cultured mouse hepatoma cells. Regulation of albumin synthesis by amino acids

The synthesis of albumin in the liver has been shown to correlate with the availability of essential amino acids in the diet. We have investigated this phenomenon in the highly differentiated mouse hepatoma cell line, Hepa. Cells were grown for three days in complete medium with daily changes. The cells were then incubated for 22 h in media containing varying concentrations of individual essential amino acids. The deficient media were then changed; 1.5 h later the cells were labeled for 0.5 h with [3H]leucine. Albumin was immunoprecipitated and total protein was acid-precipitated from postribosomal supernatants of detergents-solubilized cells. With the exception of isoleucine, the relative rates of albumin synthesis decreased as a function of amino acid concentration from 4.3% in complete medium to 2.5% in totally deficient media. This specific reduction in albumin synthesis was confirmed by analysis of labeled Hepa proteins displayed on sodium dodecyl sulfate/polyacrylamide gels. Essential amino acid limitation reduced total protein synthesis by 50%. This is the result of a decrease in the translation efficiency of total mRNA from 5 to 3 polypeptides/message min-1 and is consistent with a reduction in the initiation rate. In contrast, the 70% decrease in albumin synthesis was a result of a reduced number of functional albumin messages/cell. The translation efficiency of these albumin messages remained unchanged at 1.

Homogeneously staining regions (HSRs) of a rat hepatoma cell line are not early replicating

The rat hepatoma cell line H4-IIE-C3 (H4) has homogeneously staining regions (HSRs) which contain multiple, tandemly repeated copies of ribosomal RNA (rRNA) genes. We determined the time of replication of the DNA within these HSRs autoradiographically after incorporation of [3H]thymidine and by Hoechst 33258 and Giemsa staining after 5-bromodeoxyuridine (5-BrdU) incorporation. The DNA within the H4 HSRs is not early replicating, unlike that in other HSRs. It begins replicating later than much of the other nuclear DNA, continues replicating throughout most of the S phase, and is completed 1-2 h before mitosis.

Late G1 amino acid restriction point in human dermal fibroblasts

Human dermal fibroblasts arrested in G0 by maintenance in medium supplemented with 0.1% serum were not restimulated to divide when fresh medium containing 10% dialyzed serum but lacking group B amino acids (cystine, isoleucine, lysine, phenylalanine and tyrosine) was added. Unlike rodent cells, the addition of fresh serum-supplemented medium lacking only isoleucine did not cause a growth arrest. The amino acid sensitive growth arrest in human fibroblasts was dependent both on presynchronization in G0 as well as a prestarvation for amino acids prior to stimulation with high serum. When cells were restimulated in the absence of amino acids, they arrested predominantly in G1, although a small percentage of cells entered early S phase. When medium containing a complete complement of amino acids was then added, cells initiated DNA synthesis following a minimum lag of 2-3 hr. Growth arrested cells initiated DNA synthesis even when complete unsupplemented medium was added, although the addition of high concentrations of insulin or 10% serum increased the rate of entry.

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

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

Threonine starvation of concanavalin A treated lymphocytes impairs DNA polymerase alpha activity

When cultured in a threonine-deficient medium, concanavalin A treated guinea-pig lymphocytes do not incorporate tritiated thymidine. DNA polymerase activity is strongly affected. The addition of the missing amino acid is followed by an early increase in protein and RNA synthesis and a delayed rise in DNA polymerase alpha activity associated with the onset of DNA synthesis.

Coexpression of two thermosensitive defects in a Chinese hamster cell line. Manifestation of a G1 block associated with a mitosis defect

Asynchronous cultures of ts12, an anchorage-dependent derivative of the thermosensitive Chinese hamster cell line ts111, show a rapid drop in [3H]thymidine incorporation with accumulation of the cells in the G1 and in the G2 phases of the cycle, when shifted from 34.5 to 39.4 degrees C. Shift-up experiments carried out after either isoleucine deprivation or synchronization at 39.4 degrees C, locate the execution point of a ts function in late G1 (2.5-3 h before S). However, stimulation of proliferation of a high density-arrested population allows a fraction of the cells to enter S. In addition to the G1 ts defect, ts12 expresses a slight cytokinesis defect at 39.4 degrees C (8-15% binucleate cells). The results suggest that altered processes are taking place at a post-metaphasic stage during the first hours after the shift-up. When populations are synchronized by a thymidine block and released at 39.4 degrees C, multinucleate cells in addition to binucleate cells are observed. Part of these multinucleate cells result from abnormal karyokinesis without inhibition of cytokinesis. Evidence is presented suggesting that excess thymidine allows the re-expression of the multinucleation phenotype of ts111.

The relationship between purines, pyrimidines, nucleosides, and glutamine for fibroblast cell proliferation

Previous studies indicate that glutamine is a critical requirement for cell proliferation in vitro. We recently showed that depletion of glutamine from the culture medium supporting growing cells significantly reduced the proportion of cells undergoing DNA synthesis. Similarly glutamine depletion significantly reduced the stimulatory response of quiescent cells to 10% serum. This study shows that the inhibitory effects of depletion of glutamine--in either of these two situations--can be overcome by the addition of adenine or adenosine. Adenine was the only nitrogen base and adenosine was the only nucleoside for which this effect was observed. Such effects could, however, also be achieved by addition of the purine metabolites hypoxantine and inosine. Furthermore, it was found that glutamine (or adenine/adenosine) is only required during a limited interval coinciding with the late part of the G1-phase and the beginning of S-phase. These data suggest the possibility that glutamine exerts its main regulatory effects on cell proliferation by acting as a precursor for adenine and adenosine.

Cell-cycle dependence of a ganglioside glycosyltransferase activity and its inhibition by enkephalin in a neurotumor cell line

Rat glioma X mouse neuroblastoma hybrid neurotumor cells (NG108-15), synchronized by amino acid deprivation, showed a cell-cycle-dependent peak of activity of a ganglioside N-acetylgalactosaminyl transferase 14-24 h following release from the cell cycle block (S/G2 phase). Maximal expression of two typical lysosomal hydrolases, N-acetyl-beta-hexosaminidase and beta-galactosidase, occurred between 18 and 21 h following release (S phase), declining to G1 phase levels during the peak of N-acetylgalactosamine (GalNAc) transferase activity. In addition, glycosyltransferase activity in G2 phase cells showed an increase in apparent Vmax (suggesting the presence of more enzyme/mg of cell protein) and apparent binding affinity for uridine diphosphate N-acetylgalactosamine (UDP-GalNAc) (32 versus 14 microM) when compared to transferase activity in the G1 phase. However, the opioid peptide enkephalin [D-Ala2, D-Leu5], which inhibits ganglioside GalNAc transferase activity in unsynchronized NG108-15 cultures, was much more inhibitory in whole cells 8 h after release from the cell cycle block (G1 phase) than in cells 20 h after release (G2 phase), with 50% inhibition occurring at 2 X 10(-9) M and 2 X 10(-7) M, respectively. These results suggest that the GalNAc transferase activity is regulated in more than one way during the cell cycle, since both Vmax and Km changes are observed, and that the cyclic AMP-dependent mechanism by which opiates reduce transferase activity is receptor mediated and cell cycle dependent.

Genetic analysis of control of proliferation in fibroblastic cells in culture. II. Alteration in proliferative and survival phenotypes in a set of temperature-sensitive mutants of rat 3Y1 cells after infection or transformation with simian virus 40

Mutants of rat 3Y1 fibroblasts, temperature sensitive for proliferation or survival and which represent each of eight complementation groups, were examined to determine whether cells made quiescent at confluence at 33.8 degrees C (permissive temperature) can be stimulated to enter S phase at 39.8 degrees C (nonpermissive temperature) by 20% serum or by infection with simian virus 40 (SV40). Three mutants with a short survival at 39.8 degrees C did not enter S phase at 39.8 degrees C under either condition. The remaining five entered S at 39.8 degrees C by infection with SV40. However, only one of these five entered S in response to high serum. After transformation with SV40, three mutants accumulating at 39.8 degrees C with a predominantly 2n (G1) DNA content did not proliferate, there was a rapid and extensive cell death, and the cells had a DNA content similar to that seen in randomly proliferating populations. The other two mutants, accumulating at 39.8 degrees C with a predominantly 2n or 2n X 4n DNA content, proliferated at this temperature after transformation with SV40. These results clearly indicate that SV40 interacts closely with cellular ts lesions related to control of proliferation and cell survival.

Identification of mammalian DNA repair factors using a reconstituted subcellular system. Partial characterization and subcellular location of a DNA repair-stimulating protein in hamster cells

By reconstituting lysolecithin-permeabilized hamster cells with endogenous proteins, a protein(s) which stimulated bleomycin-induced DNA repair synthesis was identified. The repair protein was inactivated by proteinase K and had an apparent molecular weight of 12 000-15 000 D. The following enzymatic activities were not detected in the partially purified DNA repair protein: general endonuclease, apurinic endonuclease, exonuclease, DNA polymerase or DNA polymerase beta-stimulating activity. The subcellular location of the DNA repair-stimulating activity was investigated by cytochalasin B enucleation; approx. 80% of the activity was associated with karyoplasts, suggesting a nuclear location. Neither the activity nor subcellular location of the repair protein fluctuated appreciably during the cell cycle, consistent with a physiological role in DNA repair. Although the function of the DNA repair protein is not yet known, this approach should be useful in identifying and characterizing mammalian DNA repair proteins.

Cell cycle regulation of ribonucleoside diphosphate reductase activity in permeable mouse L cells and in extracts

Ribonucleoside diphosphate reductase (EC1.17.4.1) was previously characterized in exponentially growing mouse L cells selectively permeabilized to small molecules by treatment with dextran sulfate (Kucera and Paulus, 1982b). This characterization has now been extended to cells in specific phases of the cell cycle and in transition between cell cycle phases, with activity studied both in situ (permeabilized cells) and in cell extracts. Cells at various stages in the cell cycle were obtained by unit-gravity sedimentation employing a commercially available reorienting chamber device, by G1 arrest induced by isoleucine limitation, and by metaphase arrest induced by Colcemid. G1 cells from both cycling and noncycling populations had negligible levels of ribonucleotide reductase activity as measured by CDP reduction both in situ and in extracts. When G1 arrested cells were allowed to progress to S phase, ribonucleotide reductase activity increased in parallel with [3H]thymidine incorporation into DNA. Ribonucleotide reductase activity in extracts increased at a somewhat greater rate than in situ activity. S phase ribonucleotide reductase activity measured in situ resembled the previously characterized activity in exponentially growing cells with respect to an absolute dependence on ATP or its analogs as positive allosteric effector, sensitivity to the negative allosteric effector dATP, and low susceptibility to stimulation by NADPH, dithiothreitol, and FeCl3. Disruption of permeabilized cells caused reductase activity to become highly dependent on the presence of both dithiothreitol and FeCl3. As synchronized cultures progressed from S into G2/M phase, no significant change in ribonucleotide reductase activity was seen. On the other hand, when cells that had been arrested in metaphase by Colcemid were allowed to resume cell cycle traversal by removing the drug, in situ ribonucleotide reductase activity decreased by 75% within 2.5 h. This decrease seemed to be a late mitotic event, since it was not correlated with the percentage of cells entering G1 phase. The cause of a subsequent slight increase of in situ ribonucleotide reductase activity is not clear. Parallel measurements of ribonucleotide reductase activity in cell extracts indicated also an initial decline accompanied by increasing dependence on added dithiols and FeCl3, followed by complete activity loss. Our results suggest a cell cycle pattern of ribonucleotide reductase activity that involves negligible levels in G1 phase, a progressive increase of activity upon entry into S phase paralleling overall DNA synthesis, continued retention of significant ribonucleotide reductase activity well into the metaphase period of mitosis, and a very rapid decline in activity during the later phases of mitosis. The periods of increase and decrease of ribonucleotide reductase activity were accompanied by modulation of the properties of the enzyme as indicated by differential changes in enzyme activity measured in situ and in extracts.

Cell cycle-dependent expression of specific opiate binding with variable coupling to adenylate cyclase in a neurotumor hybrid cell line NG108-15

Monolayer cultures of neuroblastoma X glioma hybrid (clonal) cell line NG108-15, synchronized by the isoleucine/glutamine deprivation method, showed maximal expression of opiate binding sites at the same point in the cell cycle at which prostaglandin E1 (PGE1) had a maximum stimulatory effect on cyclic AMP synthesis. However, the capacity of enkephalin [D-Ala2D-Leu5] to block the stimulation of cyclic AMP synthesis by PGE1 was not related to the number of opiate receptors expressed. The Ki for the inhibition of cyclic AMP synthesis by opioid peptides increased substantially during the period of the cell cycle at which maximal expression of opiate binding sites occurred, making the effective level of inhibition of adenylate cyclase activity by 0.1 microM enkephalin [D-Ala2D-Leu5] the same through the cell cycle. Data are presented to suggest that enkephalin receptor coupling to adenylate cyclase, via a GTP-binding protein, is maximal during G1 phase (which may approximate the state of the differentiated neuron) and minimal during S + G2 phase, just prior to cell division, when many receptors are uncoupled.

Influence of amino acid deficiency and tRNA aminoacylation on DNA synthesis and DNA polymerase activity during the secondary immune response in vitro

DNA synthesis and DNA polymerase activity are increased when KLH-primed guinea-pig lymphocytes are restimulated in vitro with the homologous antigen. This response can be modulated by glutamine deficiency and by an inhibitor of the histidyl-tRNA synthetase.

Changes in the glycoprotein composition of plasma membrane during the differentiation of friend erythroleukemia cells

Friend erythroleukemia cells display transient and permanent changes in the composition of their plasma membrane-bound glycoproteins during dimethyl sulfoxide-induced differentiation. The transient changes, as revealed by metabolic labeling with [14C]glucosamine, are most conspicuous around the time during which most cells become committed to terminal differentiation. Permanent changes are revealed by reductive tritiation after oxidation with NaIO4 or galactose oxidase. In differentiated cells one glycoprotein fraction (Mr 150 000) could not be labeled by any of these methods, although it does contain neuraminic acid. We found no evidence in support of the hypothesis that the anomalous behavior of this fraction is caused by an increased degree of O-acetylated neuraminic acid in the plasma membrane of differentiated cells.

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

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