The effect of folic acid and/or methionine deficiency on deoxyribonucleotide pools and cell cycle distribution in mitogen-stimulated rat lymphocytes

Abstract. Folate deficiency will induce abnormal deoxynucleoside triphosphate (dNTP) metabolism because folate-derived one-carbon groups are essential for de novo synthesis of purines and the pyrimidine, thymidylate. Under conditions of methionine deprivation, a functional folate deficiency for deoxynucleoside triphosphate synthesis is induced as a result of the irreversible diversion of available folates toward endogenous methionine resynthesis from homocysteine. The purpose of the present study was to examine the effect of nutritional folate and/or methionine deprivation in vitro on intracellular dNTP pools as related to DNA synthesis activity and cell cycle progression. Primary cultures of mitogen-stimulated rat splenic T-cells were incubated in complete RPMI 1640 medium or in custom-prepared RPMI 1640 medium lacking in folic acid and/or methionine. Parallel cultures, initiated from the same cell suspension, were analysed for deoxyribonucleotide pool levels and for cell proliferation. The distribution of cells within the cell cycle was quantified by dual parameter flow cytometric bromodeoxyuridine/propidium iodide DNA analysis which allows more accurate definition of DNA synthesizing S-phase cells than the traditional DNA-specific staining with propidium iodide alone. Relative to cells cultured in complete RPMI 1640 media, the cells cultured in media deficient in folate, methionine or in both nutrients manifested increases in the deoxythymidylate pool and an apparent depletion of the deoxyguanosine triphosphate pool. Both adenosine triphosphate and nicotinamide adenine diphosphate levels were significantly reduced with single or combined deficiencies of folate and methionine. These nucleotide pool alterations were associated with a decrease in the proportion of cells actively synthesizing DNA and an increase in cells in G₂+ M phase of the cell cycle. Folate deprivation in the presence of adequate methionine produced a moderate decrease in DNA synthesizing cells over the 68 h incubation. However, methionine deprivation, in the presence or absence of folate, severely compromised DNA synthesis activity. These results are consistent with the established ‘methyl trap’ diversion of available folates towards the resynthesis of methionine from homocysteine and away from nucleotide synthesis. The data confirm the metabolic interdependence of folic acid and methionine and emphasize the pivotal role of methionine on the availability of folate one-carbon groups for deoxynucleotide synthesis. The decrease in DNA synthesis activity under nutrient conditions that negatively affect nucleotide biosynthesis suggest a possible role for abnormal dNTP metabolism in the regulation of cell cycle progression and DNA synthesis.     

Cyclic nucleotides and cell growth

Growth induction in resting fibroblast cultures by serum or growth factors induces a fast, transient cGMP peak which may constitute the intracellular signal for growth. A similar cGMP peak occurs when 3T3 cells arrested at the restriction point or in G₀ by starvation for certain amino acids are induced for growth by readdition of the lacking nutrients. Both 3T3 and SV3T3 cells which are arrested randomly all around the cell cycle do not exhibit major changes in cyclic nucleotides after growth induction. Determination of intracellular cAMP and cGMP levels in normal and transformed fibroblasts under different growth conditions shows that the transition between growing and resting state (G₀ arrest) is accompanied and probably induced by characteristic changes in cAMP to cGMP ratios. cGMP is decreased 2-5-fold in resting as compared to growing cultures, and increased 10-20-fold in activated cultures 20 min after serum induction. No major cGMP change was observed in growing, confluent, or serum-activated cultures of transformed cells. Measurement of guanylcyclase under unphysiological conditions (2 mM Mn⁺⁺) in crude and purified membranes from 3T3 and SV3T3 cultures did not show increased enzyme activity in the transformed cells. Significant differences may only show up when synchronized cells pass through the restriction point in G₁ phase. As a hypothesis it is proposed that transformed cells have an activated guanylcyclase system or a relaxed cGMP-pleiotypic response mechanism at the restriction point of their cell cycle.     

Effect of serum on the growth of Balb oT3 A31 mouse fibroblasts and an SV40-transformed derivative.

The effect of serum on the growth properties of non-transformed Balb 3T3 A31 and SV40-transformed Balb 3T3 A31 was studied. The concentration of serum in the growth medium of non-transformed cells had little effect on the initial population doubling time, but did regulate the cell density at which the population became quiescent in G1. The doubling time of transformed cells, however, was increased significantly as the concentration of serum was decreased below 4%. This effect on the growth of transformed cells was seen at serum concentrations so low that non-transformed cells did not complete one population doubling. Flow microfluorometric analysis of these populations indicated that the primary effect of different serum concentrations on the non-transformed cells was to modulate the average residence time in G1, whereas, all the cell cycle phases of the transformed cells were affected by serum. At saturation densities, the non-transformed cells became quiescent in G1, but the transformed cells still traversed the cell cycle and their saturation density appeared to be a balance between cell production and cell death occurring primarily in the G1 phase of the cell cycle.     

Arrest of C1300 neuroblastoma cells by limiting serum or isoleucine: implications for growth control in malignant cells.

The arrest of C1300 neuroblastoma cells by limiting serum or isoleucine in the growth medium is described. The resumption of DNA synthesis after the return of the cells to complete medium indicates that they stop in the early G₁ (or G₀) phase of the cell cycle with both arrest procedures. However, the isoleucine limitation procedure also arrests about half of the cells in the G₂ phase of the cell cycle. This result is used to modify a recent model for growth control of transformed cells.     

Growth control of normal and transformed cells

Both serum factors and protein synthesis are required for normal cell growth. Swiss 3T3 cells require the serum growth factors insulin and EGF (epidermal growth factor) during the initial part of the G₁ period, until they pass a restriction point about 2 h before the initiation of DNA synthesis. Concentration of cycloheximide that inhibit protein synthesis by as much as 70% dramatically lengthen the cell cycle before the restriction point, while the cell cycle after the restriction point remains nearly constant. These results are consistent with a model in which labile proteins are required for transit of cells past the serum-sensitive restriction point. The relation of these findings to the growth control of transformed cells is discussed.     

DNA replication in isolated HeLa cell nuclei

DNA replication was investigated in HeLa cell nuclei isolated from different phases of the cell cycle. DNA synthesis occurred only in S-phase nuclei and was dependent on the presence of the four deoxynucleoside triphosphates, Mg⁺⁺, ATP and S-phase cytoplasm. G₁-phase cytoplasm was unable to support such DNA synthesis. A purified preparation of calf thymus DNA polymerase, however, was able to replace S-phase cytoplasm in supporting ATP dependent DNA synthesis, which suggests that the S-phase cytoplasmic factor is a DNA polymerase. G₁-phase nuclei could under no conditions be stimulated to initiate DNA replication prematurely.     

Observations consistent with autocrine stimulation of hybridoma cell growth and implications for large-scale antibody production

Existence of autocrine growth factors (aGFs) may influence the serum requirement for growth of hybridoma cells and thus significantly influence process economics. For the murine hybridoma cell line S3H5/2bA2, critical inoculum density (cID) and serum requirement for growth were inversely related for cultivation in both T flasks and spinner flasks. In spinner flasks, an inoculum density of 10⁶ cells/ml was necessary for the cells to grow in RPMI 1640 medium without serum supplement, and an inoculum density of 10³ cell/ml was necessary in RPMI 1640 medium with 10% serum. In T flasks, where the local cell density is higher than in spinner flasks, an inoculum density of 10⁶ cells/ml was necessary for the cells to grow in RPMI 1640 medium without serum supplement, and an inoculum density of 1 cell/ml was also necessary in RPMI 1640 medium with 10% serum. Further, immobilized cells at high local cell density could grow under conditions where cells in T flasks at corresponding overall cell density could not grow. The cells at high inoculum density were less sensitive to shear induced by mechanical agitation than the cells at low inoculum density. Taken together these observations support the existence of secreted aGF(s) by the hybridoma cell line used. Since the specific MAb production rate was independent of cultivation method and inoculum density, the existence of autocrine growth factors would suggest that the use of immobilized cells should improve the economics of MAb production.     

The culture of rat myeloma and rat hybridoma cells in a protein-free medium

Y0 is a rat x rat hybridoma cell line, which does not secrete immunoglobulin, produced using a fusion partner derived from the Y3 (Y3,Ag.1.2.3) rat myoloma cell line. Y0 and Y3 have both been widely used as fusion partners in the production of rat x rat hybridomas. Y0 has also been used in recombinant gene technology. Y0 cells grown in shake flask culture, using RPMI 1640 medium with 4mM l-glutamine and 5% foetal bovine serum, reached a maximal cell density of 1.5×10⁶ cells ml^–1 with 86% viability. Y0 cells which has been adapted to grow in ABC protein-free medium reached a maximal density, in shake flask culture, of 8.75×10⁵ cells ml^–1 with 79% viability. An improved protein-free medium, designated W38 medium, was developed. In shake flask culture, W38 medium supported Y0 cell growth to a density of 2.02×10⁶ cells ml^–1 with 96% viability. Two Y3 hybridomas, YID 13.9.4 cells and SAM 618 cells were adapted to growth in W38 medium. For both hybridomas, cell growth and product yield in shake flask culture using W38 medium was superior to that obtained with serum-containing RPMI 1640 medium.Abbreviations F12 Hams F12 medium - DMEM Dulbeccos medium - RPMI RPMI 1640 medium - FBS foetal bovine serum     

Dissociation of cellular transformation from platelet-derived growth factor independence

ST2-3T3, a spontaneously transformed BALB/c-3T3 cell line which does not require platelet-derived growth factor (PDGF) for growth, was fused to THO2, a PDGF-responsive non-transformed BALB/c-3T3 cell line, in order to learn whether transformation is expressed coordinately with PDGF independence. Hybrid cells were selected and grown in medium containing both HAT (hypoxanthine-aminopterin-thymidine) and ouabain; unfused cells of each parental type were killed in HAT-ouabain medium. Five independently isolated ST2-3T3xTHO2 hybrid cell lines were established and characterized for both transformation and PDGF responsiveness. All five were transformed, having a disorganized growth pattern and achieving a final cell density similar to that of ST2-3T3 cells. Two of these lines did not respond to a brief treatment with PDGF: the mitogen neither induced the synthesis of a PDGF-modulated lysosomal protein (termed MEP), nor stimulated the cells to enter the S phase; one line responded to PDGF by synthesizing both MEP and DNA, whereas two others synthesized MEP but not DNA. In contrast, four independently isolated cell lines obtained by fusing PDGF-responsive non-transformed BALB/c-3TC cells to the THO2 line were all PDGF-responsive for both MEP and DNA synthesis and were not transformed. It appears that PDGF independence is not required for the transformation of BALB/c-3T3 cells.     

Intracellular plasminogen activator activity in growing and quiescent cells

Intracellular plasminogen activator (PA) was examined in 3T3 and transformed 3T3 cells under various growth conditions to determine whether expression of this activity changes with the growth state. During exponential growth, SV40 and benzpyrene (BP) transformed 3T3 cells exhibited 3- to 5-fold more intracellular PA activity than untransformed 3T3 cells. This relationship changed as the cells exhausted serum factors and arrested in G₁. The specific activity of intracellular PA in cells that have retained a serum-sensitive restriction point in G₁ (G₀) (3T3 and BP 3T3) increased 200- and 20-fold, respectively, at this time, while the level in cells that have lost most growth control mechanisms (SV3T3) remained constant. At confluency, 3T3 cells had considerably more PA than either of their transformed counterparts. Sparse cultures of 3T3 and BP3T3 cells arrest at G₁ following serum depravation, and also accumulate high intracellular PA activity. The addition of serum or purified epidermal growth factor to these cultures initiated cell proliferation and resulted in a rapid, actinomycin D-sensitive loss of this activity. Less than 50% of the original activity remained 30 minutes after growth stimulation. This loss of intracellular PA activity did not appear to result from the presence of serum or cellular inhibitors. Intracellular PA activity remained low following growth stimulation. It increased again as the cells traversed through G₁. These findings indicate that intracellular PA activity fluctuates with the growth state of cells, and may be related to the cell cycle. Culture conditions which place cells, whether normal or transformed, in G₁ arrest lead to increased intracellular PA, while factors that initiate growth again result in a rapid loss of this activity. This behavior is lacking in cells not subject to density-dependent inhibition of growth. Like many other correlates of transformation, comparison of intracellular PA in normal and transformed cells must be defined in terms of the growth state of the cells in question.     

DNAase I and cellular factors that affect chromatin structure

The use of DNAase I as a probe of chromatin structure is frequently fraught with problems of irreproducibility. We have recently evaluated this procedure, documented the sources of the problems, and standardized the method for reproducible results (Prentice and Gurley (1983) Biochim. Biophys. Acta 740, 134–144). We have now used this probe to detect differences in chromatin structure between cells blocked (1) in G₁ phase by isoleucine deprivation, or (2) in early S phase by sequential use of isoleucine deprivation followed by release into the presence of hydroxyurea. The cells blocked in G₁ phase have easily-digestible chromatin, while cells blocked in early S phase have chromatin which is much more resistant to DNAase I. These differences were found to be the result of diffusible factors found in the cytoplasm and nuclei of G₁- and S-phase cells, respectively. The G₁ cells contained a cytoplasmic factor which modulates the chromatin structure of S-phase nuclei to a more easily digestible state, while cells blocked in S phase contain a nuclear factor which modulates the chromatin structure of G₁ nuclei to a state more resistant to digestion. DNAase I is much more sensitive to these cell cycle-specific chromatin changes than is micrococcal nuclease. The results indicate that, under controlled conditions, DNAase I should be a valuable probe for detecting chromatin structural changes associated with cell cycle traverse, differentiation, development, hormone action and chemical toxicity.     

Nutritional Requirements of Plasmodium falciparum in Culture. I. Exogenously Supplied Dialyzable Components Necessary for Continuous Growth

Continuous cultivation of Plasmodium falciparum presently requires the nutritionally complex medium, RPMI 1640. A basal medium of KCl, NaCl, Na₂HPO₄, Ca(NO₃)₂, MgSO₄, glucose, reduced glutathione, HEPES buffer, hypoxanthine, phenol red (in RPMI 1640 concentrations), and 10% (v/v) exhaustively dialyzed pooled human serum was used to determine which vitamins and amino acids had to be exogenously supplied for continuous cultivation. Supplementation of basal medium with calcium pantothenate, cystine, glutamate, glutamine, isoleucine, methionine, proline, and tyrosine was necessary for continuous growth. This semi-defined minimal medium supported continuous growth of four isolates of P. falciparum at rates slightly less than those obtained with RPMI 1640. Adding any other vitamin or amino acid did not improve growth. Incorporation of several non-essential amino acids, particularly phenylalanine and leucine, into proteins was markedly enhanced in the minimal medium compared to RPMI 1640.     

Cell cycle specificity and reversibility of the inhibitory effect of epidermal G1-chalone on DNA synthesis in partially synchronized RTE-2 keratinocytes in vitro

The specific action of a pig skin fraction enriched in epidermal G₁-chalone, a tissuespecific inhibitor of epidermal DNA synthesis, was investigated by means of flow cytofluorometry. The results indicate that G₁-chalone inhibits progression of partially synchronized rat tongue epithelial cells (line RTE-2) through the cell cycle at a point 2 h prior to the beginning of the S-phase. Approximately 8 h after chalone addition, the cells can overcome the inhibition and begin to enter the S-phase. The duration of this delay is concentrationindependent, but the fraction of cells affected is proportional to the chalone concentration. The progression of cells which already have entered S-phase is not affected. In contrast to the G₁-chalone preparation, aphidicolin, a potent inhibitor of DNA polymerase α, clearly shows S-phase-specific inhibition. These results indicate that the epidermal G₁-chalone inhibits epidermal cell proliferation in a fully reversible manner by a highly specific effect on cell cycle traverse.     

ANALYSIS OF GROWTH OF TETRAPLOID NUCLEI IN ROOTS OF VICIA FABA

Growth of nuclei of a marked population of cells was determined from G₁ to prophase in roots of Vicia faba. the cells were marked by inducing them to become tetraploid by treatment with 0.002% colchicine for 1 hr. Variation in nuclear volume is large; it is established in early G₁ and maintained through interphase and into prophase. One consequence of this variation is that there is considerable overlap between volumes of nuclei of different ages in the cell cycle; nuclear volume, we suggest, cannot be used as an accurate indicator of the age of the cell in its growth cycle. Nuclei exhibit considerable variation in their growth rate through the cell cycle. of the marked population of cells, about 65% had completed a cell cycle 14–15 hr after they were formed. These tetraploid nuclei have a cell cycle duration similar to that of fast cycling diploid cells of the same roots. Since they do complete a cell cycle, at least 65% of the nuclei studied must come from rapidly proliferating cells, showing that variability in nuclear volumes must be present in growing cells and cannot be attributed solely to the presence, in our samples, of non-cycling cells.     

The restriction point and control of cell proliferation

Research over the past two decades has defined a window of time in the early/mid G₁ phase of the cell cycle during which mammalian cells are responsive to extracellular signals. Recent evidence indicates that this period ends with the phosphorylation of the retinoblastoma protein, enabling the cells to pass through the restriction point at the end of mid G₁ phase and to commit to completing the remaining phases of the growth cycle.     

Characterization of human cells transformed by chemical and physical carcinogens in vitro

Summary Several different classes of chemical carcinogens induced the transformation of human fibroblasts grown in vitro. Characteristics of the events that occur from time of treatment through the expression of neoplastic transformation are presented. The S-phase appeared to be the portion of the cell cycle most vulnerable to insult. Staging of the cells by blocking them in G₁ before releasing them to proceed through scheduled DNA synthesis (S) was required to induce reproducible transformation. Compounds such as insulin were added to the cells upon release from the block to sensitize the cells to the carcinogen that was added during S. Growth of the transformed cells as distinct from nontransformed cells was promoted by growth in medium supplemented with 8X nonessential amino acids. Carcinogen-treated cells in the early stage of transformation exhibited abnormal colony morphology and were able to grow at 41°C, in air atmosphere, and in medium supplemented with only 1% serum. In addition, the transformed cells were insensitive to KB cell lysate and exhibited density independent, as well as anchorage independent, growth (i.e., growth in 0.33% agar). Cells that grew in soft agar also produced undifferentiated mesenchymal tumors in preirradiated nude mice. This work was supported in part by National Cancer Institute Grant ROI-CA-25907 and Air Force Office of Scientific Research Grant F49620-77-C0110 and EPA-R806638. The hydrazine compounds were furnished by Ms. Marilyn George and Dr. Kenneth Back, AFSOR Toxicology Division, Wright Patterson Air Force Base, Dayton, OH. The hydroxylate and phenyl napthylamines were furnished by Dr. Fred Kadlubar, Division of Chemical Carcinogenesis at the National Center for Toxicological Research, Jefferson, AR.     

Cell cycle regulated expression of nucleolar antigen P120 in normal and transformed human fibroblasts

Normal and SV40 virus-transformed WI-38 human lung fibroblasts were serum starved and refed, or synchronized by double thymidine block and released from the block. At different time points in the cell cycle, steady state levels of P120 mRNA and P120 protein content of the cells were determined by densitometric scans of Northern and Western blots. At the same time points, [³H]thymidine uptake was measured and flow cytometric analysis performed for DNA content and P120 antigen staining. Levels of P120 protein and P120 mRNA were approximately 4 times greater in non-synchronous, exponentially growing transformed cells than in similarly growing normal cells. Early G₁-cells, synchronized either with serum deprivation or with metabolic block, contained only a trace amount of P120 protein and mRNA. The P120 gene was transcribed early in G₁ and P120 protein synthesis initiated in middle G₁. A dramatic increase of P120 protein level occurred in S-phase with a corresponding mRNA peak preceding the P120 protein peak. These results indicate that P120 is overexpressed in transformed WI-38 cells and that P120 is temporally regulated during the cell cycle of both transformed and normal fibroblasts. The dramatic increase in P120 protein expression at the G₁ to S boundary suggests that P120 may play a role in the regulation of cell cycle and increased nucleolar activity that is associated with cell proliferation. © 1993 Wiley-Liss, Inc.     

Cytokinetic analysis of lung cancer by bromodeoxyuridine labeling of cytology specimens

Recent flow cytometric (FCM) studies have indicated the prognostic value of S-phase cells (SPF) in lung cancer. More refined cytokinetic analysis can be obtained by dual-parameter FCM, labeling S-phase cells with 5-bromodeoxyuridine (BrdUrd), which can be detected using a monoclonal antibody (MoAb) to BrdUrd. Tumor cells obtained through bronchoscopic brush were incubated for 1 hr in RPMI 1640 medium with 10% fetal calf serum and 10 microM BrdUrd. After fixation in ethanol, pepsin treatment, and DNA denaturation, the nuclei were stained with anti-BrdUrd MoAb and propidium iodide. From 14 of 20 patients, sufficient material was obtained (three adenocarcinoma and seven squamous cell, one giant cell, and three small cell carcinoma). The measured SPF ranged from 5.2% to 26%. The labeling index (LI), calculated as the ratio of the number of BrdUrd-labeled cells to the total number of aneuploid cells, or diploid cells in the case of a diploid tumor, ranged from 1.2% to 16.7%; LI and SPF correlated significantly (r = 0.69). In this study, we have demonstrated the feasibility of determining the actively DNA-synthesizing cells on brush material from lung cancer cells. In addition, some extra information can be obtained about the SPF population, including the fraction of unlabeled SPF, which could be of prognostic significance.     

The effect of cell-to-cell contact on the surface morphology of Chinese hamster ovary cells

In the previous report (Porter et al., in this issue) morphological changes in Chinese hamster ovary (CHO) cells during the cell cycle were described. In this report we describe the role of intercellular contact on these changes. We find that intercellular contact is required for cells to exhibit the morphologies Porter et al. described for S and G₂. When cells are synchronized by mitotic selection and plated onto cover slips at very low density such that no intercellular contact occurs, the cells remain in a G₁ configuration (rounded and highly blebbed through G₁, S, and G₂). This G₁ morphology is also observed in nonsynchronized log phase cells plated at low densities and allowed to grow for several generations. The addition of conditioned medium from confluent cultures does not induce low density cells to change morphology during the cell cycle. These results indicate that extensive intercellular contact is required for the complete expression of the morphological changes associated with the cell cycle (as described by Porter et al.). It is concluded that although classic contact inhibition of movement and of growth may be absent in this transformed cell line, some contact-dependent response persists.