Effect of cell physiological state on infection by rat virus

Infection by rat virus has been studied in cultures of rat embryo cells to evaluate the Margolis-Kilham hypothesis that the virus preferentially infects tissues with actively dividing cells. An enhancement of infection was seen in cultures infected 10 hr after fresh medium was added as compared to infection of stationary cultures (infected before addition of fresh medium). Since addition of fresh medium stimulates deoxyribonucleic acid (DNA) synthesis, the number of cells per culture synthesizing DNA at the time of infection was compared with the proportion of cells which synthesized viral protein. Cells were infected before the medium change and 10 or 24 hr after the medium change and were pulse-labeled with ³H-thymidine at the time virus was added. The cells were allowed to initiate viral protein synthesis before they were fixed and stained with fluorescein-conjugated anti-rat virus serum. Fluorescence microscopy permitted both labels to be counted simultaneouly and showed that the greatest proportion of cells synthesizing viral protein were those which had incorporated ³H-thymidine at the time of infection.     

Regulation of the in vitro anamnestic antibody response by cyclic AMP: I. Antigen-induced uptake of nucleotides and nucleosides by lymphocytes

Addition of N⁶, O²′-dibutyryl cAMP (DbcAMP) to keyhole limpet hemocyanin (KLH)-primed rabbit lymph node cells for 1 hr, followed by its removal and the addition of KLH, had no effect on the subsequent antibody response, whereas addition of KLH for 1 hr followed by DbcAMP resulted in a 100% enhancement of antibody synthesis. Addition of cholera enterotoxin (CT), which rapidly and irreversibly binds to lymphocytes and activates adenylate cyclase, either before or after the addition of antigen, elevated the antibody response by 100%. These results suggested that some antigen-induced event(s) may be required for DbcAMP to exert its enhancing effects on the antibody response. The effect of KLH on the uptake of DbcAMP by KLH-primed lymph node cells was investigated. One and one hundred micrograms of KLH, which induce optimal and supraoptimal antibody synthesis, respectively, promoted maximal uptake of DbcAMP. This induced uptake was first detectable about 12 hr after addition of KLH, and it peaked during 24–48 hr of culture. DbcAMP uptake induced by a brief exposure of KLH (0–1 hr) was equivalent to that observed with long-term KLH addition (0–24 hr). KLH-induced DbcAMP uptake required KLH-reactive lymphocytes and represented active transport. Antibody to rabbit T lymphocytes inhibited this antigen-induced uptake. The mitogens concanavalin A (Con A) (T cells) and goat anti-rabbit Fab' (anti-Fab') (B cells) also stimulated DbcAMP uptake, as did human serum albumin (HSA) and myoglobulin (Mb) when added to homologously primed cells, indicating the generality of the phenomenon. [³H]DbcAMP entered the cells as di- or monobutyryl cAMP with about 40% metabolized to 5′AMP. This uptake could be competitively inhibited by other adenine or guanine nucleotides and nucleosides.     

Pyruvate-Induced changes in hepatoma cell morphology and macromolecular synthesis

Cells maintained in basal growth medium with 0.2–1.0% serum often require citric acid cycle intermediates for optimal viability. We have found that pyruvate added to minimal growth medium causes cellular flattening and formation of external processes accompanied by increaded DNA synthesis in cultured hepatoma cells (HTC cells). Cells were cultured in plalstic T-flasks (0.5, 1.0, or 2.0 × 10⁶ cells/flask) containing 5 ml medium (90% Eagle's Basal Medium (BME) and 10% Swim's S-77) with various concentrations of fetal calf serum (0.2,0.25, 0.5, 1.0, 2.0, 10%) and either pyruvate (50, 100, 250,500, 1,000μg/ml), or one of: dibutyryl cAMP (DBcAMP) or dibutyryl cGMP (DBcGMP) at 10^?3, 10^?4, or 10^?5 M. At 44–48 hr cultures were pulsed with tritiated thymidine, uridine, or lecucine. Cells became attached to the plastic surface within 24hr. Cells in medium with 0.25 to 2.0% serum had a rounded appearance. With added pyruvate, cellular flattening, process formation, and an increased adherence to the substratum was absorbed. By 48 hr, culture without pyruvate grew in rounded clusters; with pyruvate, cells formed extensive interconnecting processes that appeared loosely attached to the monolayer surface. At the cell densities tested, process formation was maximal with 250 to 500 μg/ml pyruvate. Cytochalasin B blocked flattening and process formation; EDTA (1 mg/ml) caused retraction of processes within 3 min, and a slow dissolution of these structures within cells was observed. DBcAMP or DBcGMP did not induce process formation. Flattening and process foormation in pyruvate-enriched cultures were accompanied by marked stimulation of DNA synthesis and smaller increases in RNA and protein synthesis. Cell number was not affected. These pyruvate-induced changes suggest that alterations in energy metabolism, or precursors that enhance viability and macromolecular synthesis in mammalian cell cultures, may exert marked effects on cellular morphology without corresponding changes in growth of neoplastic liver cells.     

Stimulative effect of serum on the growth of HeLa cells suppressed in a K+-deficient chemically defined medium

Growth of HeLa cells cultured with a chemically defined medium was slightly stimulated in the presence of 5% dialyzed calf serum. The growth-promoting action of serum was more conspicuous when cell growth was suppressed in the same medium, in which K⁺ was replaced by Rb⁺ to various ratios. The growth-promoting factors(s) of serum was heat-labile. Upon addition of dialyzed serum, passive K⁺ or Rb⁺ influx was increased, whereas the active cation uptake was unaffected and cell K⁺ was rather decreased. The serum did not alter uptake of [³H] amino acids. Also, protein synthesis inhibited in the Rb⁺-substituted medium was not stimulated significantly, except that observed only when the external K⁺/Rb⁺ ratio was $\text{1}\text{5}$. From the distinct effects of serum on cell growth and protein synthesis, we conclude that (i) the serum-induced stimulation of cell growth, which is suppressed in the Rb⁺-substituted medium, is not a result of the direct effect of serum on synthesis of bulk protein, but a reflection of the effect on another mechanism(s) required for cell growth; and that (ii) this action is basically identical with the growth-promoting action on cells cultured in the normal medium.     

Analysis of lymphocytes reactive to histocompatibility antigens. II. Exponential alloantigen-dependent lymphocyte growth in vitro

Rat thoracic duct lymphocytes were maintained in continual blast transformation and cell division by repeated in vitro stimulation with allogeneic cells. This resulted in increases in responder cell numbers of up to 10,000-fold in 10-day periods. Growth of responder lymphocyte populations was dependent upon cell density, culture medium nutrients, and the presence of antigen in the form of allogeneic cells. A titration assay for mixed lymphocyte interactions (MLI) was used to relate absolute growth of cells in preparative cultures to [³H]thymidine incorporation in analytical MLI. Growth of lymphocyte populations derived by repeated stimulation with cells bearing a single foreign MHC haplotype was supported to lesser, variable degrees by stimulation with unrelated “third party” stimulator cells. The extent of this operational cross-reactivity was assessed by parallel line analysis of MLI titrations of responder lymphocytes enriched for specific alloreactivity.     

Regulation of retinol-binding protein metabolism in cultured rat liver cell lines

Retinol-binding protein (RBP), the plasma transport protein for vitamin A, is synthesized and secreted by the liver. In vitamin A deficiency, RBP secretion is blocked, leading to low serum and high liver levels of RBP. Administration of retinol to the intact rat stimulates a rapid secretion of RBP from liver into serum. We explored the use of a liver cell culture system to study the regulation of the synthesis and secretion of RBP. We found two lines of differentiated rat hepatoma cells, MH₁C₁ and H₄ II EC₃ (H₄), that synthesized RBP during culture in vitro. The net synthesis of RBP was a function of the number of cells per dish and the duration of incubation. Both cell lines synthesized RBP when incubated in Neuman and Tytell's Serumless Medium (NTS medium), while the MH₁C₁ cells also synthesized RBP in Ham's F-12 medium with added serum. A relatively large proportion (14–56%) of the RBP was retained within the cells when they were incubated in the vitamin A-free NTS medium alone. Addition of serum to NTS medium stimulated the release of RBP from the cells into the medium and also increased the net synthesis of RBP. These effects were not due to the increased adhesion of the cells to the petri dish. Addition of retinol (at levels of 0.35 or 3.5 nmole/ml) to the NTS medium resulted in the stimulation of RBP secretion from the cells into the medium and an increase in the net synthesis of RBP. By contrast, retinol had no effect on either the net synthesis or the cell-to-medium distribution of rat serum albumin. The data from these cell lines in culture suggest that retinol has a specific regulatory effect on RBP metabolism. These cells thus resemble the normal rat liver cell in vivo in regard to the known regulation of RBP metabolism.     

Maintenance of the primary symbiote of the pea aphid Acyrthosiphon pisum in liquid media

The primary symbiote of the pea aphid was maintained in liquid culture media for 12 hr for the purpose of optimizing certain culture parameters. The optimum temperature for protein and nucleic acid synthesis was found to be 28–30°C. There was no dependence of this microorganism on fetal calf serum added to the growth medium. Grace's insect tissue culture medium and Grace's insect tissue culture medium (modified by Tokumitsu and Maramorosch) were found to be best suited for the maintenance of this organism.The suitability of the growth medium for the microorganism was directly related to the age of the culture medium.     

Collagen synthesis by monkey arterial smooth muscle cells during proliferation and quiescence in culture

Monkey arterial smooth muscle cells (SMC) which are stimulated to proliferate in the presence of 5% monkey blood serum (MBS) and which remain quiescent in 5% monkey platelet-poor plasma serum (MPPPS) were examined for their ability to synthesize collagen in each of these conditions in culture. Collagen synthesis was measured by determining amounts of newly formed labeled hydroxyproline, following labelling in the presence of [³H]proline and ascorbic acid. Ascorbate requirements of SMC were examined to assure maximal hydroxylation. SMC synthesize the same amount of collagen/cell in 5% whole blood serum (MBS) during the early phase of rapid proliferation as during slow growth in later phases in culture. SMC grown in the presence of serum-lacking platelet factors synthesize 60–90% less collagen and 60–90% less non-collagen protein (per cell or per mg protein) than cells grown in MBS. Non-collagen protein synthesis was measured as incorporation of both [³H]proline and of [³H]leucine, determined as trichloroacetic acid (TCA)-precipitable material. Previous studies indicate that a factor derived from platelets is the principal mitogen present in whole blood serum for diploid cells such as SMC and fibroblasts in culture. Similarly derived factors are potent stimulators of both collagen and non-collagen protein synthesis by SMC. SMC, quiescent in medium lacking platelet derived material (MPPPS), is being used to investigate factors important in SMC proliferation since this is a significant event in atherogenesis in vivo. An increased deposition of collagen also occurs during atherogenesis. Consequently it will be useful to employ similar cultures of quiescent SMC to examine agents which affect production of this connective tissue matrix protein.     

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.     

Serum and insulin inhibit cell death induced by cycloheximide in the human breast cancer cell line MCF-7

Summary Continuous exposure of cells to cycloheximide (CHM) terminates in cell death. This may result from CHM’s inhibition of protein synthesis. In the present study we investigated the effect of serum and insulin on cell death induced by CHM in the human breast cancer cell line MCF-7, and correlated this effect to the inhibition of protein synthesis. Cell death was evaluated by measuring either dead cells by the trypan blue dye exclusion test or by the release of lactic dehydrogenase into the culture medium. CHM (0.1 to 50 μg/ml) was shown to induce cell death in a time- and concentration-dependent manner. Including either fetal bovine serum or insulin in the culture medium inhibited this cell death in a concentration-dependent manner. Protein synthesis as measured by [³H]leucine incorporation was inhibited by the increasing concentration of CHM, However, fetal bovine serum and insulin did not alter the protein synthesis inhibition rate induced by CHM. These results indicate that inhibition of protein synthesis is not enough for cell death to proceed. Insulin or factors present in serum may stabilize some crucial cell proteins (key enzymes, cytoskeletal or membrane components) which are vital for cell life.     

The program of protein synthesis during heterocyst differentiation in nitrogen-fixing blue-green algae

The program of protein synthesis that accompanies cellular differentiation following transfer of the blue-green alga Nostoc muscorum from nitrogen-containing to nitrogen-free medium has been determined by polyacrylamide gel electrophoresis of whole cell proteins labeled with ³⁵SO₄⁼ during successive intervals of the differentiation. Differentiating cells (proheterocysts, which become heterocysts) are distinguished from vegetative cells on the basis of the latter's susceptibility to lysis with lysozyme.At least ten sets of proteins can be distinguished on the basis of the time at which they are synthesized or the type of cell in which they are located. Regulation of most of these sets can be accounted for by classical induction or repression involving NH₄⁺ or a simple derivative of NH₄⁺. An additional mechanism is required to explain how the synthesis of several sets of proteins is initiated in all cells following transfer to nitrogen-free medium, but is permitted to continue only in developing proheterocysts. The structural polypeptides of the nitrogenase enzyme complex are members of the latter set.In differentiated filaments, very few proteins are synthesized in both vegetative cells and heterocysts. The qualitatively different pattern of protein synthesis is established very early, within the first 9 hr after transfer. Moreover, the proteins present in proheterocysts at that time are already qualitatively different from those of vegetative cells. Rapid turnover of vegetative cell proteins appears to be a characteristic of the early development of proheterocysts.     

Biosynthesis of catecholamines in organotypic cultures of the peripheral autonomic nervous system: Modifications by biopterin and other agents

Organotypic cultures of chick-embryo sympathetic ganglion chains maintained in vitro for 3–4 weeks rapidly synthesized catecholamines, as demonstrated by the conversion of L-[U-¹⁴C]tyrosine to catechol derivatives and by histofluorescence assay. The biosynthesis of catechols from radioactive L-tyrosine leveled off at 6 hr of incubation and dropped slightly at 10 hr. The addition of DL-α-methyl-p-tyrosine to the culture medium did not affect protein synthesis, but produced a complete block in the synthesis of catecholamines from L-tyrosine, with consequent loss of fluorescence in the bodies and proximal processes of adrenergic neurons in 2 hr, and essentially complete loss in 6 hr. Our observations suggest that a major portion of the catecholamines were synthesized in the perikarya and transported via neuronal processes to their terminals. The addition of monoamine oxidase inhibitors to the incubation medium produced a moderate to pronounced increase in fluorescence; reserpine caused a rapid and profound loss of catecholamines. When added to the culture medium, crude biopterin produced an increase in the synthesis of catechol derivatives from radioactive L-tyrosine and a marked increase in fluorescence, beginning in the neuronal perikarya. This effect was completely blocked by DL-α-methyl-p-tyrosine. The mechanism of biopterin's action in the synthesis of catecholamines in cultures of sympathetic ganglia is not completely elucidated from these studies, but may be related to the role it plays as cofactor for tyrosine hydroxylase.     

A specific radioimmunoassay for vitellogenesis in mosquitoes

Hagedorn's assay for vitellogenesis, in which a crude antigen-antibody complex is collected directly on a Millipore membrane, without prior separation of soluble from insoluble proteins, is unspecific. This was proven as follows.Fat bodies of blood-fed mosquitoes (Aedes aegypti) were incubated in a medium containing ³H valine. The medium was analyzed for synthesis of vitellogenin by incubation with serum of normal rabbits (control) or of rabbits which were immunized against mosquito egg protein (antibody).When these mixtures were filtered directly through Millipore membranes (Hagedorn's method), the radioactivity in the control was about two-thirds of that in the antibody membrane. However, when the antigen-serum and antigen-antibody complex were centrifuged, the antigen-serum precipitate (control) contained only a very small percentage of the radioactivity present in the antigen-antibody precipitate. Apparently, the medium contained a large amount of soluble, nonvitellogenic protein that binds to the membrane.Analysis of the fat body homogenate showed that a large amount of the newly synthesized vitellogenin was stored intracellularly.Since all published data on vitellogenesis in mosquitoes depend on Hagedorn's assay, the validity of current concepts of the control of vitellogenesis in mosquitoes is open to question.     

Hormonal requirements for the larval-pupal transformation of the epidermis of Manduca sexta in vitro

In the tobacco hornworm, Manduca sexta, metamorphosis occurs in response to two releases of ecdysone that occur 2 days apart. Epidermis was explanted from feeding final-instar larvae before the first release of ecdysone and was cultured in Grace's medium. When exposed to 1 μg/ml of β-ecdysone for 24 hr and then to hormone-free medium for 24 hr, followed by 5 μg/ml of β-ecdysone for 4 days, the epidermis produced tanned pupal cuticle in vitro. During the first 24 hr of exposure to β-ecdysone, the epidermis first changed its cellular commitment to that for pupal cuticle formation (ET₅₀ = 14 hr), then later (by 22 hr) it became committed to tan that cuticle. Then, for most of the pupal cuticle to be tanned, at least a 12-hr period of culture in hormone-free medium was required before the cuticle synthesis was initiated. Consequently, some events prerequisite to sclerotization of pupal cuticle not only occur during the ecdysone-induced change in commitment but also during the ecdysone-free period. When the tissue was preincubated in 3 μg/ml of juvenile hormone (JH I or a mimic epoxygeranylsesamole) for 3 hr and then exposed to both ecdysone and juvenile hormone for 24 hr, it subsequently formed larval cuticle. The optimal conditions for this larval cuticle formation were exposure to 5 μg/ml of β-ecdysone in the presence of 3 μg/ml of epoxygeranylsesamole for 48 hr. When the epidermis was cultured in Grace's medium for 3 days and then exposed to 5 μg/ml of β-ecdysone for 4 days, 70% of the pieces formed pupal cuticle. By contrast, if both ecdysone and JH were added, 77% formed larval cuticle. Therefore, the change from larval to pupal commitment of the epidermal cells requires not only the absence of JH, but also exposure to ecdysone.     

Control of mitogen-induced transformation: characterization of a splenic suppressor cell and its mode of action.

The present study demonstrates that mouse spleen cells contain a population of glass wool adherent T lymphocytes which exhibit the capacity to suppress non-glass adherent lymphocyte responses to mitogens. These suppressor cells are stimulated by both low and high doses of PHA¹ and high doses of con A. The suppressor cell effect is observed when UNA, but not RNA or protein synthesis, is studied. This glass-adherent suppressor cell population is characterized as being the primary DNA synthesizing cells during the early (0–8 hr) stages of culture. Suppression still occurs when the suppressor cells are treated with mitomycin C, actinomycin D or cycloheximide. This implies that new macromolecular synthesis may not be required for suppression to occur. Suppression is blocked by inhibiting synthesis of prostaglandin and is mimicked by Bu₂cAMP. This suggests that mitogen activated suppressor cells regulate T cell responses via production of prostaglandin which modulates the concentration of intracellular cyclic nucleotide levels.     

In vitro synthesis of peritrophic membranes of the blowfly, Calliphora erythrocephala.

Tyrode solution containing added glutamine and Leloup's medium 1 has been used as a basic medium for the in vitro culture of the so-called proventriculus of adult Calliphora erythrocephala to elucidate some of the factors controlling the synthesis of peritrophic membranes (PM) in vitro. The formation rate was chosen as a quantitative criterion for the evaluation of the modifications of the incubation media.After systematic variation of osmolarity, pH, and temperature optimal formation rates were obtained in media with an osmolarity of 320 to 360 mOsmol, a pH of 6·8, and an incubation temperature of 27°C. Under these conditions the average rate of formation was in the modified Tyrode solution 3·0±1·1 mm PM/hr, and in Leloup's medium 3·6±0·8 mm PM/hr. In the modified Tyrode solution the formation of PM was complete after 5 to 7 hr, whereas in Leloup's medium it continued up to 24 hr. The addition of β-ecdysone caused an increase of the formation rate of PM to 4·5 to 5·5 mm PM/hr.The results obtained led to the hypothesis that an osmotically regulated enzyme system could be the limiting factor of the formation rate of peritrophic membranes, i.e. a system which could regulate the internal osmolarity of the formative cells by the interconversion of a bulk polymer and its monomer which are needed for the synthesis of PM.     

In vitro sensitization of human lymphoid cells to antigens on cultured melanoma cells. I. Culture conditions resulting in augmented cell-mediated cytotoxicity

Culture conditions have been established that result in the sensitization of normal human peripheral blood lymphoid cells on allogeneic melanoma monolayers. Optimal culture conditions require 2 to 8 × 10⁶ mitomycin C treated stimulator melanoma cells to sensitize 5 to 10 × 10⁶ responder lymphoid cells. Neither rocking nor refeeding of the culture is necessary for the sensitization procedure. Stimulator cells grown in either fetal calf serum or human serum will serve as effective stimulator or target cells. Peak cytotoxic activity was detected at 44 hr in a microcytotoxicity assay, although some cytotoxic activity was detectable at 24 hr.     

Insulin regulates protein metabolism in mouse blastocysts

Mouse blastocysts, in vitro, endocytosed 100 μg/ml ¹²⁵I-labelled bovine serum albumin (BSA) at a rate equivalent to 192 ± 27 μl/hr/mg embryonic protein over the first 20 min. Insulin stimulated this initial uptake by 30% (P < 0.05). After this time, accumulation of ¹²⁵I-labelled BSA began to plateau as the endocytosed ¹²⁵I-labelled BSA was catabolized and ¹²⁵I was released from the cells. Insulin caused an ≈?72% (P < 0.05) increase in the amount of uncatabolized ¹²⁵I-labelled BSA remaining in insulin-treated blastocysts after 2 hr as compared to control blastocysts. Insulin partially inhibited catabolism of endocytosed ¹²⁵I-labelled BSA during the first 2 hr following transfer to nonradioactive medium. After this time, degradation ceased in both control and insulin-treated blastocysts, leaving a small, uncatabolized protein pool remaining in the embryos; however, as a result of insulin's inhibitory effects on the initial catabolic rate, the uncatabolized protein pool was 30% (P < 0.05) larger in insulin-treated blastocysts after the 4 hr chase. Insulin inhibited endogenous protein degradation in blastocysts by 37% (P < 0.05). Combined with previous studies showing a 90% increase in endogenous protein synthesis in blastocysts following short-term stimulation with insulin (Harvey and Kaye, 1988), these results suggest that insulin acts to increase the endogenous protein-reserves in the embryo. Dose-response studies indicated an EC₅₀ of 0.5 pM for insulin's stimulation of ¹²⁵I-labelled BSA accumulation, consistent with action via its own receptor. Insulin-like growth factor-1 (IGF-1) also stimulated protein accumulation at concentrations similar to those observed with insulin, suggesting that IGF-1 may act via its own receptor rather than the insulin receptor to exert its effects on endocytosis. © 1993 Wiley-Liss, Inc.     

Induction by ouabain of hemoglobin synthesis in cultured friend erythroleukemic cells

Induction of erythroid differentiation in ouabain-resistant murine erythroleukemia cells by ouabain is reported. Ouabain induction results in the appearance of hemoglobin-containing cells 12–24 hr earlier than induction of the same clone by dimethyl sulfoxide. The levels of globin mRNA after ouabain induction are similar in amount to the globin mRNA levels observed after induction by dimethyl sulfoxide. The concentration of ouabain required to induce hemoglobin synthesis depends upon the K⁺ ion levels in the culture medium. Lowering the extracellular K⁺ ion concentration 2–4 fold reduced by 10–40 fold the ouabain concentration necessary for the induction of hemoglobin synthesis. In low K⁺ medium (1.8 mM), ouabain is an effective inducer of hemoglobin synthesis at a concentration of 0.02 mM. This K⁺ effect is specific for ouabain induction, since induction by other inducers, such as dimethyl sulfoxide and dimethyl acetamide, does not exhibit this marked sensitivity to the levels of K⁺ ions in the culture medium. These results suggest that the binding of ouabain to the plasma membrane enzyme, $\text{Na}\text{K}$ ATPase, is required for the induction of erythroid differentiation by ouabain. A small but significant proportion of wild-type, ouabain-sensitive cells also can be induced by ouabain, below ouabain concentrations that are toxic to these cells. The observation that the binding of ouabain to the $\text{Na}\text{K}$ ATPase induces hemoglobin synthesis suggests that changes in the intracellular concentration of K⁺ ions may be involved in the control of erythroid differentiation in Friend erythroleukemic cells.     

EXPERIMENTAL CONTROL OF DNA SYNTHESIZING AND DIVIDING CELLS IN EXCISED ROOT TIPS OF PISUM

The number of dividing and DNA-synthesizing cells in excised pea roots can be regulated by eliminating the carbohydrate normally supplied in the culture medium. When the excised roots were allowed to remain for 24 hr in a medium lacking carbohydrate, the number of mitotic figures and tritiated thymidine (H³-T) labeled cells was reduced almost to zero. After an additional 24 hr in the incomplete culture medium, 15% of the interphase cells were H³-T labeled, the percentage of the cells that were dividing never exceeded 1.4, and 30% of these were H³-T labeled. When the roots remained in the deficient medium for 72 hr, neither cell division nor cells synthesizing DNA were observed. Upon addition of 2% sucrose, cell division and DNA synthesis were resumed in the roots that were maintained for 24 or 72 hr without an exogenous carbohydrate supply. It has been hypothesized that some proliferative systems consist of two cellular subpopulations which selectively stop or remain in either the pre-DNA synthetic (G₁) or post-DNA synthetic (G₂) periods of the mitotic cycle. The addition of sucrose, H³-T, and 5-aminouracil to the medium, after the roots had been maintained for 24 hr without a carbohydrate, indicated that most of the proliferative cells in the roots had accumulated in either G₁, a quasi-G₁ condition, i.e., DNA synthesis stopped sometime before completion, or G₂ periods of interphase; the majority, however, were in G₁ or quasi-G₁ conditions. The results suggested that DNA synthesis (S period) and mitosis or the onset of these processes have the highest metabolic requirements in the mitotic cycle and that G₁ and G₂ were the most probable states for proliferative cells in a meristem with a low metabolic level.