Cation transport and content in serum-stimulated CHO-773 cells. I. Rapid changes in rubidium and lithium influxes and intracellular sodium content

The cultures of Chinese hamster ovary cells (CHO-K1 clone 773) can be brought to the stationary state with most of cellular populations in G1 phase by growing continuously for 4 days up to the cultural density (10-12) X 10(4) cells/cm2. Upon introduction of fresh Eagle medium with 10% calf serum the cells progress from G1 to S phase for 7-9 hours. It is shown that within the first minutes of serum addition ouabain-sensitive rubidium influx increases, however, lithium influx, which serves a test for passive sodium pathways in the membrane, increases or does not change. No correlation was found between the rubidium influx and intracellular sodium changes, induced by serum. From comparative studies of ouabain-sensitive rubidium influx, lithium influx and intracellular sodium content it is concluded that the increase in intracellular sodium is not responsible for serum-induced Na,K-ATPase activation.     

Cation transport and content in serum-stimulated CHO-773 cells. II. Late changes in rubidium influx and intracellular potassium content

Serum stimulation of stationary cultures of Chinese hamster ovary cells CHO-K1 (clone 773) is accompanied by sustained increase in ouabain-sensitive rubidium (potassium) influx which results in the elevation of intracellular potassium content from 0.5-0.6 to 0.7-0.8 mmole per gram of protein. Cytofluorometric studies of serum-stimulated CHO-773 cultures have shown that the intracellular potassium increase is necessary for successful G1----S progression. The elevation of intracellular potassium was found to occur simultaneously with the cellular protein growth. Cycloheximide (10 micrograms/ml) does not influence the early Na,K-ATPase activation induced by serum; however, it abolishes the sustained increase of both rubidium influx and intracellular potassium content. In serum stimulated cells ouabain increases the potassium efflux; this ouabain effect is not observed after S phase, when rubidium (potassium) influx decreases and intracellular potassium content stops growing.     

Early and late changes in potassium transport during the start of proliferation in CHO cell cultures. The action of serum, isoproterenol, propranolol and theophylline

The stimulation of DNA synthesis by serum is accompanied by early (30 minutes) and late (2-8 hours) increase in ouabain-sensitive rubidium (potassium) influx and the elevation of intracellular potassium content from 0.5-0.6 to 0.7-0.8 mmole per gram protein in CHO-K1 cells. Isoproterenol alone induces the transient increase both in potassium influx via Na,K-ATPase and in potassium efflux without any effect on intracellular potassium content and cell proliferation. Isoproterenol acts synergistically with serum in eliciting the early and late changes in potassium transport and in stimulating G1----S transition. The combination of serum and theophylline produces a rapid increase in potassium influx, however, it does not stimulate DNA synthesis and does not induce any later increase in intracellular potassium content. It is concluded that early and late activation of Na,K-ATPase by mitogens can be dissociated; the Na,K-ATPase activation is involved in mitogenic response when producing the sustained potassium influx and the elevation of intracellular potassium content during G1----S transition.     

Changes in the content of potassium, sodium and potassium influx in human peripheral blood lymphocytes during long-term cultivation with phytohemagglutinin

Intracellular potassium, sodium and potassium influx were examined in PHA-activated human lymphocytes within 6 days of cultivation. DNA flow cytometry was used to estimate the percentage of cells in G1, S and G2 + M phases. Potassium influx and content per g protein were found to be increased, whereas sodium content decreased with the progression of cells from G1 to S phases, being maximum on the 3rd day. Later on the percentage of cells in S phase was seen diminished, and the potassium content decreased just as sodium content increased. It is concluded that ionic changes may correlate with the entering of cells into S phase.     

Ion transport and cell proliferation]

Recent studies of potassium fluxes and intracellular potassium content is mitogen-activated cells have shown that the stimulation of G0----G1----S transition in arrested cell cultures in associated with both immediate (early) and prolonged (delayed) increase in potassium influx due to elevation of ouabain-inhibitable transport by Na,K-ATPase. The early and the delayed changes in ion transporters of plasma membrane can be disrupted, mechanisms of these changes being presumably different. The dissociation between the early and delayed ionic events were demonstrated in cell cultures activated to proliferate by growth factors, hormones, cAMP-elevating agents, as well as in the presence of cycloheximide. The early ionic events are related to the primary transduction of membrane signal, whereas the delayed modulation of ion transport via Na,K-ATPase has another function and is associated with cell growth. The increase in cell potassium content per gram of protein is typical of the successful G1----S transition in mitogen-activated cell cultures.     

Dependence of ion transport across the plasma membrane on cell culture density. II. Active and passive cation transport during the growth of L cell cultures

Rubidium and lithium influxes as well as intracellular potassium and sodium contents were investigated in L cells during the culture growth. In sparse culture over the cell densities 0.5-3 X 10(4) cells/cm2 ouabain-sensitive rubidium influx is small and ouabain-resistant lithium influx in high. With the increase in culture density up to 4-5 X 10(4) cells/cm2 the active rubidium influx, mediated by ouabain-sensitive component, is enhanced, and ion "leakage" tested by lithium influx is diminished. Simultaneously with the exponential growth of culture the intracellular potassium content is increased and the intracellular sodium content is decreased resulting in the higher K/Na ratio in cell. During the further transition to dense culture and in stationary state (10-17 X 10(4) cells/cm2) the sodium content and lithium influx do not change significantly, but the potassium content is decreased. The decrease in intracellular potassium is correlated with that in the portion of cells in S-phase from 27-30 to 12%. Thus, in transformed cells the density-dependent alterations in membrane cation transport are observed.     

Changes in sodium pump transport activity and Na+, K+-ATPase expression level following lymphocytes activation in humans

Ouabain-inhibitable rubidium influxes, intracellular sodium content (Nai), and alpha 1-subunit abundance have been studied in human blood lymphocytes, stimulated by phytohemagglutinin (PHA) or by the phorbol 12,13-dibutyrate (PDBu), and calcium ionophore--ionomycin. It is shown that at early stages of PHA-induced activation, the Na/K pump expression (as determined by Wesrn blots of alpha 1 protein in membrane fractions of total cell lysates) does not change, and the increase in Rb influx is due to the increase in Nai and results from the enhanced transport activity of Na/K pumps present in plasma membrane. During the late stages of G0-->G1-->S transit (16-48 h), the increase in Rb influx occurs without changes in Nai, and monensin increases both Nai, and the Rb influx via the Na/K pump. To the end of the first day of mitogen activation, the alpha 1 protein content was found to increase by 5-7 times. A correlation was revealed between changes in ouabain-inhibitable Rb influxes, alpha 1 protein abundance, and the proliferation rate. It is concluded that blasttransformathion of normal human lymphocytes is accompanied by the increase in membrane-associated pool of alpha 1-subunit of Na+,K(+)-ATPase, and the enhanced activity of sodium pump during the G0-->G1-->S progression is provided by increased number of Na+,K(+)-ATPase pumps in plasma membrane.     

Proliferation patterns of peripheral blood lymphocytes in CLL patients: cytophotometric and microfluorimetric study

Peripheral blood lymphocytes of 19 patients with CLL, 9 patient with LS and 10 healthy donors were studied by Feulgen cytophotometry, 3HTdR autoradiography, A0 microfluorimetry and PHA stimulated cultures. In CLL the bulk of cells are in G0 (80.6 +/- 3.7%) the rest are in G1 (16.3 +/- 3.6%) and S + G2 (3.0 +/- 1.0%). Thymidine LI values were two orders lower (0.098 +/- 0.04). In five cases combined autoradiographic and cytophotometric study on the same cells revealed 6-14% of cells arrested in S. In peripheral blood of LS patients G0 cells also predominate, and only in 3 cases cytophotometry revealed hyperdiploid (S + G2) cells. In normal lymphocytes 1.5 hrs after PHA stimulation A0 binding increases on the average by 80% compared to unstimulated cultures and remains at this level during 12 hrs. CLL and LS cells behave nearly the same with the only difference: the 80% increase is observed only after 3-4.5 hrs in culture. G0----G1 flow rate in case of normal lymphocytes is higher than for neoplastic cells but both are recruited into cell cycle during all the period in culture. G1----S transition is delayed in case of LS lymphocytes and strongly inhibited in CLL lymphocyte cultures compared to normal cells. The possible mechanisms of these features are discussed.     

The transport and distribution of monovalent cations during the blast transformation of human peripheral blood lymphocytes activated by phytohemagglutinin]

Potassium (rubidium) influx, sodium and potassium contents, as well as size distribution, DNA and protein contents and synthesis have been examined in PHA-activated human lymphocytes within 0.5-72 h. A complex set of ionic events was found to include at least two stages of the increase in potassium and sodium contents per g cell protein and in ouabain-sensitive potassium influx which are preceded by a decrease in potassium content by almost 17% within the first 2-5 h. The kinetics of potassium and sodium changes has own pattern for each of cations, thus indicating definite changes in the ouabain-resistant transport of potassium and sodium during the G0----G1----S progression. The late increase in potassium content per g cell protein was found to correlate with the growth in cell size. This finding confirms the rule which was stated earlier for other animal cells, i. e. cells that prepare to proliferate are to raise their potassium per g cell protein up to the level of 0.8-1.0 mmole (Vereninov. Marakhova, 1986).     

45Ca2+ uptake and peptide hormones secretion in the presence of excess Mg2+ content

Studies have been performed on the relationship between PRL and GH production and the 45Ca2+ influx in high magnesium content in vitro. The obtained data show that an elevated magnesium concentration in Krebs-Ringer solution is capable of inhibiting some hormonal function of the pituitary gland. It has been found, that PRL and GH released into the media in normal KRB solution revealed nearly two times higher concentration than in the presence of high Mg2+. Instead the cellular iPRL and iGH did not show any significant differences in control and in treated cultures. The incorporation of 4.5-3H-leucine into the prolactin and growth hormone demonstrate a significant decrease in the presence of high Mg2+ indicating that the ion is able to inhibit the secretion of newly synthesized PRL an GH. High concentration of Mg2+ abolished either the stimulation effect of releasing hormones on calcium uptake.     

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

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

Na+/Ca2+ exchange in cardiac myocytes. Effect of ouabain on voltage dependence.

Sarcolemmal sodium/calcium exchange activity was examined in individual chick embryonic myocardial cell aggregates that were loaded with quin 2. The baseline [Ca2+]i was 68 +/- 4 nM (n = 29). Abrupt superfusion with sodium-free lithium solution produced a fourfold increase in steady-state [Ca2+]i to 290 +/- 19 nM, which was reversible upon sodium restitution. Other methods of increasing [Ca2+]i such as KCl-depolarization or caffeine produced a dose-dependent increase in quin 2 fluorescence, accompanied by sustained contracture. The [Ca2+]i increase in zero sodium was linear, and its half-time (t1/2) of 15.1 +/- 0.1 s was similar to that of the sodium-free contracture (t1/2 = 14.4 +/- 0.5 s) under the same conditions. The sodium-dependent [Ca2+]i increase was not significantly greater when potassium served as the sodium substitute instead of lithium. This suggests that sodium/calcium exchange has little voltage dependence in this situation. However, in aggregates pretreated with ouabain (2.5 microM), the [Ca2+]i increase was almost threefold greater with potassium than with lithium (P less than 0.007). Ouabain therefore potentiated the effect of membrane potential on calcium influx. We propose that elevation of [Na2+]i is a prerequisite for voltage dependence of the sodium/calcium exchange under the conditions studied. Sodium loading will then drastically increase calcium influx during the action potential while inducing an outward membrane current that could accelerate repolarization.     

MiR-7 Triggers Cell Cycle Arrest at the G1/S Transition by Targeting Multiple Genes Including Skp2 and Psme3

MiR-7 acts as a tumour suppressor in many cancers and abrogates proliferation of CHO cells in culture. In this study we demonstrate that miR-7 targets key regulators of the G1 to S phase transition, including Skp2 and Psme3, to promote increased levels of p27^KIP and temporary growth arrest of CHO cells in the G1 phase. Simultaneously, the down-regulation of DNA repair-specific proteins via miR-7 including Rad54L, and pro-apoptotic regulators such as p53, combined with the up-regulation of anti-apoptotic factors like p-Akt, promoted cell survival while arrested in G1. Thus miR-7 can co-ordinate the levels of multiple genes and proteins to influence G1 to S phase transition and the apoptotic response in order to maintain cellular homeostasis. This work provides further mechanistic insight into the role of miR-7 as a regulator of cell growth in times of cellular stress.     

Magnesium and phosphate enrichment of culture medium stimulates the proliferation of epidermal cells from newborn and adult mice

The proliferation and differentiation of mouse epidermal cells can be sequentially analyzed by modification of extracellular calcium. Newborn cells cultured in low calcium medium (less than 0.1 mM) proliferate as a monolayer and maintain a typical basal cell phenotype in culture but have a limited proliferative capacity and short lifespan. Elevation of the magnesium content of the culture medium from 1 to 5 mM stimulated the proliferation of newborn mouse (1-3 days old) keratinocytes. Maximal DNA synthesis rates, as determined on day 5 of culture, were up to 2-3-fold higher in the magnesium-enriched cultures. Exposure to high magnesium caused 3-4-fold increases in the DNA content of newborn keratinocyte cultures, and extended the confluent phase of epidermal cell growth to over 10 days. Other divalent cations (strontium, copper, zinc, nickel, beryllium, and barium) did not improve keratinocyte growth in culture. Keratinocytes from the tail skin of adult (3 months old) mice displayed an absolute requirement for high phosphate in the culture medium. The medium containing an optimal (10 mM) phosphate concentration prevented the cell detachment caused by the standard low (1 mM) phosphate medium, and in combination with an elevated magnesium content (10-15 mM) it markedly increased both DNA synthesis rates and DNA content of the adult cell cultures. Optimally growing, newborn or adult cultures contained less cells in the G1 phase of the cell cycle and more cells in S and G2 +M. The addition of phosphate and magnesium per se did not induce keratinocyte differentiation and did not interfere with the high calcium (1 mM)-induced differentiation.     

Cell cycle dependence of calmodulin levels during HL-60 proliferation and myeloid differentiation: No changes during pre-commitment

The putative role of Ca²⁺ and calmodulin in regulating cell proliferation and differentiation was tested in HL-60 human promyelocytic leukemia cells. The dependence of retinoic acid (RA)-induced terminal myeloid differentiation of HL-60 promyelocytic leukemia cells on calmodulin levels and calcium ion flux was ascertained. RA-treated and untreated control cells were stained for cellular DNA with a Hoechst dye. Populations of G1/0, S and G2+M phase cells were isolated by fluorescence activated cell sorting (FACS). Cytosolic calmodulin levels were then measured as a function of cell cycle phase for RA-treated and untreated cells using a radioimmunoassay. RA-treated cells were measured at early times, corresponding to the precommitment state, and late times, when significant cell differentiation had occurred. Cellular calmodulin levels increased with progression through the cell cycle. In contrast, no difference in calmodulin levels was observed between RA-untreated or -treated cells in the same cell cycle phases at early or late times. RA-induced HL-60 terminal myeloid differentiation was thus apparently not regulated by cellular cytosolic calmodulin levels. These conclusions were supported by the effects of calmodulin antagonists and calcium flux inhibitors. The calmodulin antagonists trifluoperazine and compound 48/80 both retarded cell growth in a concentration-dependent manner. But at concentrations where cellular effect was evidenced by slight growth inhibition, neither antagonist inhibited RA-induced cell differentiation or G1/0 growth arrest. The same was true of the gated calcium channel inhibitors, verapamil and nitrendipene, and the passive calcium flux inhibitor, CoC1₂. RA-induced HL-60 cell differentiation and arrest in G0 was thus apparently not strongly dependent on cellular calmodulin levels or calcium flux. This is in strong contrast to murine erythroleukemia cells. The results argue against a central regulatory role for calmodulin or calcium flux in control of HL-60 growth arrest or differentiation.     

Molecular signals in B cell activation. II. IL-2-mediated signals are required in late G1 for transition to S phase after ionomycin and PMA treatment

We report that sustained increase of intracellular calcium ion concentration and protein kinase C (PKC) activation maintained throughout the G1 phase of cell cycle do not provide sufficient signals to cause S-phase entry in rabbit B cells, and that additional signals transduced by IL-2 and IL-2 receptor interaction are essential for G1 to S transition. We have shown earlier that rabbit B cells can be activated to produce IL-2 and express functional IL-2 receptors after treatment with ionomycin and PMA. Herein we have compared the response of rabbit PBLs, which contain about 50% T cells, with those of purified B cells. After activation with ionomycin or PMA, comparable numbers of PBLs and B cells entered the cell cycle; but DNA synthesis by the PBL cultures was three to four times higher than that of cultures of purified B cells. Interestingly, IL-2 production by the PBL cultures was also three to four times higher than in B cell cultures, suggesting an involvement of IL-2 in inducing DNA synthesis in these cells. The hypothesis that IL-2, which is produced in early G1, acts in late G1 and is required for G1 to S transition in B cells was supported by the following observations: (i) IL-2 production by B cells was detected as early as 6 hr after activation and preceded DNA synthesis by at least 24 hr. (ii) B cell blasts in G1 (produced by treatment of resting B cells with ionomycin and PMA) showed DNA synthesis in response to IL-2, but showed very little DNA synthesis in response to restimulation with ionomycin and PMA. (iii) A polyclonal rabbit anti-human IL-2 antibody caused nearly complete inhibition of DNA synthesis by B cells activated by ionomycin and PMA. (iv) A PKC inhibitor, K252b, inhibited DNA synthesis in ionomycin and PMA-stimulated cells if added at the beginning of culture but was not inhibitory if added 16 hr later. We conclude that increased [Ca2+]i and PKC activation are not sufficient signals for G1 to S transition in B cells; entry into S is signaled by IL-2, and IL-2-mediated signal transduction probably does not involve increased [Ca2+]i or PKC activation.     

CALCULATIONS OF BIOELECTRIC POTENTIALS : VI. SOME EFFECTS OF GUAIACOL ON NITELLA

Values have been calculated for apparent mobilities and partition coefficients in the outer non-aqueous layer of the protoplasm of Nitella. Among the alkali metals (with the exception of cesium) the order of mobilities resembles that in water and the partition coefficients (except for cesium) follow the rule of Shedlovsky and Uhlig, according to which the partition coefficient increases with the ionic radius. Taking the mobility of the chloride ion as unity, we obtain the following: lithium 2.04, sodium 2.33, potassium 8.76, rubidium 8.76, cesium 1.72, ammonium 4.05, ½ magnesium 20.7, and ½ calcium 7.52. After exposure to guaiacol these values become: lithium 5.83, sodium 7.30, potassium 8.76, rubidium 8,76, cesium 3.38, ammonium 4.91, ½ magnesium 20.7, and ½ calcium 14.46. The partition coefficients of the chlorides are as follows, when that of potassium chloride is taken as unity: lithium 0.0133, sodium 0.0263, rubidium 1.0, cesium 0.0152, ammonium 0.0182, magnesium 0.0017, and calcium 0.02. These are raised by guaiacol to the following: lithium 0.149, sodium 0.426, rubidium 1.0, cesium 0.82, ammonium 0.935, magnesium 0.0263, and calcium 0.323 (that of potassium is not changed). The effect of guaiacol on the mobilities of the sodium and potassium ions resembles that seen in Halicystis but differs from that found in Valonia where guaiacol increases the mobility of the sodium ion but decreases that of the potassium ion.     

Membrane transport in synchronized Ehrlich ascites tumor cells: uptake of amino acids by the A and L system during the cell cycle.

Using the double thymidine block technique. Ehrlich ascites tumor cells (ELD) carried in continuous spinner culture have been synchronized. Simultaneous monitoring of 3H-thymidine incorporation, cell number and mitotic index yielded a cell cycle time of approximately 13.5 hours. This is composed of an S period of 3-4 hours. G2 of 6-8 hours and M of 1-2 hours. No appreciable G1 is present. Ehrlich cells synchronized in this manner were used to investigate the characteristics of two neutral amino acid transport systems during progression through the cell cycle. Unidirectional influx via the Na-dependent system A was studied using C14-alpha-aminoisobutyrate (AIB) as substrate. The Na-independent system L was monitored using 3H-leucine and 14C-cycloleucine as substrates. Transport by the A system was minimal in M and early S. It underwent a three-fold increase during late S and early G2. In mid G2 the transport via this system rapidly dropped and remained low again through M and early S. The intracellular/extracellular ratios of AIB indicate that the system is actively transporting AIB thoughout the cell cycle. The minimum ratios of approximately 3 were achieved during early M and the maximum ratios of approximately 9 were achieved in late S, early G2. The uptake of leucine and cycloleucine by the L system was quite different during the cell cycle. Maximal unidirectional influx by this system occurred during early and mid S period. Upon progression into G2 the transport rate dropped and remained reduced throughout M. Intracellular/extracellular ratios of leucine or cycloleucine were near unity at the peak of the transport activity (early S) and dropped to values of 0.5 to 0.6 throughout the remainder of the cycle. This result indicates that inward transport by the L system is, for the most part, non-active in growing cells.     

Accumulation of cAMP and calcium in S49 mouse lymphoma cells following hyposmotic swelling

Swelling of S49 "wild type" mouse lymphoma cells in hyposmolar medium was used to examine the effects of cellular deformation on cAMP metabolism. In S49 wild type mouse lymphoma cells incubated in a defined medium, progressive reductions in medium osmolarity of 5-50% resulted in proportionate expansion of cell volume. Increases in cell volume were accompanied by incremental increases in intracellular cAMP and calcium. These responses in S49 cells occurred rapidly, with increases in calcium concentration and cAMP content occurring within 1-2 min. Swelling of S49 cells in the absence of ions (hyposmolar versus normosmolar sorbitol) resulted in a significant accumulation of cAMP. Inclusion of papaverine or isobutyl methylxanthine amplified cAMP accumulation, and omission of calcium, sodium, or magnesium from the medium attenuated, but did not prevent accumulation of cAMP in S49 cells in response to swelling. Exposure to propranolol or nadolol attenuated the ability of swelling to increase cAMP concentration, while treatment with 2',5'-dideoxyadenosine or phentolamine had no effect on swelling-induced cAMP accumulation. It is concluded that cellular deformation of S49 wild type mouse lymphoma cells stimulates rapid accumulation of intracellular calcium and cAMP.     

Non-histone protein synthesis during G1 phase and its relation to DNA replication.

The kinetics of non-histone chromosomal protein (NHCP) synthesis were studied in Chinese hamster ovary (CHO) plateau phase cells stimulated to proliferate and were compared to NHCP synthesis kinetics in two populations of synchronous G1 traversing cells. In all cases, NHCP synthesis rates increase 3- to 5-fold as cells traversed G1 and attained maximum values one hour before semi-conservative DNA replication began. Similar to results in synchronous G1 cells, the molecular weight distributions of the NHCP fraction from stimulated plateau phase cells underwent only minor changes, measured by sodium dodecylsulfate (SDS) polyacrylamide gel electrophoresis, as these cells moved toward S phase. Yet, during this progression after plateau phase and in the transition from early G1 to late G1 in synchronous cells, the total NHCP fraction increased significantly (1.5-2-fold) in amount per cell. These data indicate that plateau phase cells are similar to early G1 cells both in terms of their amounts of non-histone per cell and in their subsequent NHCP synthesis kinetics as they move toward S phase. These results extend previous findings which suggested that NHCP synthesis was coupled to DNA replication and demonstrate that the increased NHCP synthesis and accumulation in chromatin may be a biochemical marker for G1 progression.