Role of cytoplasmic ATP in the restoration and maintenance of a membrane permeability barrier in transformed mammalian cells

Addition of ATP to medium surrounding intact, transformed 3T3 cells activates the formation of aqueous channels in the plasma membrane. This results in efflux of nucleotide pools and ions and entry into the cytosol of charged, phosphorylated species. In such permeabilized cells, glycolysis is totally dependent on the external addition of glucose, inorganic phosphate, ADP, K+, Mg2+ and NAD+ which restore lactic acid formation to levels found in untreated cells. As expected, such reconstitution of glycolytic activity is found to restore intracellular ATP levels. This is accompanied by sealing of the membrane channels so that efflux of nucleotide pools ceases. Pyruvate, a substrate for mitochondrial ATP synthesis, when provided along with ADP and inorganic phosphate also produces sealing of the membrane channels. On the other hand, reactivation of pentose phosphate shunt activity, which does not lead to ATP synthesis, does not induce restoration of the membrane permeability barrier. Furthermore, compounds which lower the internal ATP pool prevent sealing, and also render the plasma membrane more sensitive to external ATP (Rozengurt and Heppel, '79). Sealing of aqueous channels following restoration of the internal ATP pool is associated with phosphorylation of the inner membrane surface, and is unaffected by inhibitors of protein synthesis, microfilament or microtubular assembly. These results indicate the probable role of intracellular ATP in the restoration and/or maintenance of an active membrane barrier against efflux of small molecules and ions in transformed 3T3 cells.     

Protein synthesis in transformed 3T3 cells permeabilized by exogenous ATP

Exogenous ATP has been shown to cause a rapid and reversible increase in permeability in transformed 3T3 cells (3T6 and SV3T3) but not in untransformed 3T3 cells. The cells remain viable, but lose intracellular acid-soluble pools. Treatment of transformed cells with ATP greatly reduces incorporation of ¹⁴C-leucine into protein, which is restored by the incubation of the cells with Dulbecco's modified Eagle's medium or by the external additions of certain ions and energy sources. tRNA is not required for the restoration of protein synthesis. In the permeabilized cells the energy for protein synthesis can be provided by glycolysis, oxidative phosphorylation, or direct addition of ATP. These studies demonstrate the usefulness of this method for studying the control of metabolism and macromolecular synthesis in monolayer cultures of transformed mammalian cells.     

A specific effect of external ATP on the permeability of transformed 3T3 cells

Addition of ATP causes a dramatic increase in the rate of p-nitrophenyl phosphate hydrolysis by intact 3T6 and 3T3 cells transformed by polyoma virus and simian virus 40 (SV40). In sharp contrast, untransformed 3T3 cells or secondary mouse embryo fibroblasts, either growing or resting, do not respond to ATP. The activation displays specificity, reversibility and dependence on pH, temperature and ATP concentration. The data suggest that exposure to ATP changes the permeability of transformed cells to p-nitrophenyl phosphate thus revealing an internal, ouabain-insensitive, phosphatase activity.     

Early effect of growth factors (EGF+insulin) upon ATP turnover in 3T3 cells

Various early biochemical events have been observed after the addition of growth factors to quiescent cultures of 3T3 cells; however, the cascade of events which take place in the cells after growth-factor addition is not yet entirely known. Our results show that the addition of a mixture of two growth factors, i.e., Epidermal Growth Factor (EGF) and insulin, to quiescent cultures of 3T3 cells rapidly stimulated phosphate uptake and ATP turnover. Our present and previous results suggest that the increase in phosphate uptake is the consequence of the stimulation of ATP synthesis. This stimulation was not simply a consequence of an increase in oxidative phosphorylation or in glucose transport and metabolism. The change in ATP turnover was an early event observed as soon as 5 min after growth-factor addition; furthermore, it was not dependent on protein synthesis. This change may therefore be the result of post-synthetic modification of enzymes by phosphorylation. We do not know what cellular process is responsible for the increase in ATP turnover. Since growth-factor addition rapidly enhanced ATP degradation in quiescent 3T3 cell cultures, we assumed that this increase is the result of an increase in ATP degradation. We know that it was not due to a stimulation of an oligomycin-sensitive ATPase. We verified that it was not the consequence of early biochemical events like an increase in Na+/K+ ATPase or a stimulation of RNA or protein synthesis. However, it is of interest to note that the stimulation of ATP turnover due to the growth-factor addition was inhibited by quercetin.     

Interferon-associated, dsRNA-dependent enzyme activities in a mutant 3T6 cell engaged in the semiconstitutive synthesis of interferon

Cytoplasmic extracts of untreated cultures of a virus-resistant mutant of mouse 3T6 cells, designated 3T6-VrB2, contain two double-stranded, RNA-activated enzyme activities associated with interferon action. These are the synthesis of a low molecular weight oligonucleotide inhibitor of cell-free protein synthesis from ATP, and the phosphorylation of a 67,000 dalton polypeptide by transfer of the gamma phosphate of ATP. Basal levels of both enzyme activities are detectable in extracts of untreated parental 3T6 cells, and are greatly enhanced upon interferon pretreatment. A procedure was developed, using a nonionic detergent to effect cell lysis, which allowed the analysis of the protein kinase activity from as few as 2 x 10(7) cells. Using this procedure, direct proportionalities were demonstrated between the concentration of interferon to which 3T6 cells were exposed, and both the level of protein kinase activity and the magnitude of the antiviral state were established in these cells. Furthermore, untreated cultures of 3T6-VrB2 exhibited both an antiviral state and an intracellular protein kinase activity equal to that of cultures of the parental 3T6 cells pretreated with a single concentration of mouse interferon.     

Transformation by different oncogenes relies on specific metabolic adaptations

Metabolic adaptations are emerging as common traits of cancer cells and tumor progression. In vitro transformation of NIH 3T3 cells allows the analysis of the metabolic changes triggered by a single oncogene. In this work, we have compared the metabolic changes induced by H-RAS and by the nuclear resident mutant of histone deacetylase 4 (HDAC4). RAS-transformed cells exhibit a dominant aerobic glycolytic phenotype characterized by up-regulation of glycolytic enzymes, reduced oxygen consumption and a defect in complex I activity. In this model of transformation, glycolysis is strictly required for sustaining the ATP levels and the robust cellular proliferation. By contrast, in HDAC4/TM transformed cells, glycolysis is only modestly up-regulated, lactate secretion is not augmented and, instead, mitochondrial oxygen consumption is increased. Our results demonstrate that cellular transformation can be accomplished through different metabolic adaptations and HDAC4/TM cells can represent a useful model to investigate oncogene-driven metabolic changes besides the Warburg effect.     

Diffusible factor(s) controlling density inhibition of 3T3 cell growth: a new approach

In 3T3 Swiss mouse fibroblasts, incorporation of phosphate into cells and phosphorylation of small organic compounds were increased by shaking dense cultures. This response was not obtained with SV40 transformed Swiss 3T3 cells (SV-3T3). It appeared likely that these results could be accounted for by an inhibitor released from 3T3 cells but not from SV-3T3 cells. Our new method of co-incubation of sparse and dense cultures allowed us to demonstrate inhibition of growth and phosphate metabolism in sparse 3T3 cultures which were shaken in the presence of dense cultures. The inhibition was much less when the cultures were co-cultivated but not shaken. The inhibition of phosphate incorporation in acid-soluble and acid-insoluble fractions of sparse cultures was observed as early as 20 minutes of co-incubation in the presence of dense cultures, so this inhibition is not the result of depletion of growth factors in the medium. Our experiments suggest that an inhibitor(s) was released from dense cultures of 3T3 cells.     

The high rate of aerobic glycolysis of transformed 3T3 cells persists after cell homogenization.

The high rate of lactic acid production by 3T3 cells which have been transformed by simian virus 40 or by polyoma virus as compared to confluent untransformed 3T3 cells persists after cell homogenization. This difference is also reflected by increased phosphofructokinase activity in the viral transformed cells. The findings imply that the increased aerobic glycolysis in the transformed cells results from changes in the glycolytic pathway rather than changes in sugar transport.     

Retinoic acid-promoted expansion of total cellular ATP pools in 3T3 cells can mediate its stimulatory and growth inhibitory effects

Exposure of Swiss 3T3 cells to micromolar quantities of β-all-trans-retinoic acid (RA) results in either inhibition of growth or stimulation of cellular responsiveness to mitogens, depending on the length of treatment. Inhibition of growth is produced by treatment of the cells with RA for at least 48 hours. The total cellular pools of adenosine 5′-triphosphate (ATP) are markedly increased after 48-hour RA treatment and dose dependence studies show a correlation between the expanded ATP pools and the inhibitory effects. The expansion of total cellular ATP pools by retinoic acid occurs throughout the cell cycle and parallels the cell cycle-dependent fluctuations in total cellular ATP pools of untreated cells. Studies of [³H]thymidine incorporation and labeling indices in intact cells and [³H]dTTP incorporation and labeling indices in isolated nuclei of RA-treated and control cultures suggest that cellular acid-soluble nucleotide pools mediate the inhibition of DNA replication in the 48-hour-RA-treated cells. The stimulatory activity of RA for mitogenic responsiveness is demonstrated by treatment of G₀/G₁-arrested 3T3 cells with micromolar levels of RA for a maximum of 18 hours resulting in the potentiation of phorbol myristate acetate (PMA)-stimulated transition into S phase of the cell cycle. Marked increases in total cellular ATP and UTP pools are produced by 18-hour treatment of G₀/G₁-arrested cells with RA, before their exposure to PMA.     

The role of calcium ions in the permeability changes produced by external ATP in transformed 3T3 cells

External ATP causes a rapid increase in passive permeability to nucleotides and phosphate esters in transformed cell lines, such as 3T6 mouse fibroblasts. However, untransformed lines, such as 3T3, do not show a similar sensitivity to external ATP. Ca²⁺ inhibits permeabilization, but only at concentrations approaching those of external ATP. In contrast, La³⁺ and Tb³⁺ inhibit ATP-dependent permeabilization at one-fifth the concentration of external ATP. Considering reports that lanthanides can substitute for calcium ion in many enzymatic reactions, often with a higher affinity, it would appear that Ca²⁺ plays a specific role in the maintenance of a passive membrane permeability barrier and in opposing the effects of external ATP.Other data suggest a regulatory role for the Ca²⁺-calmodulin complex in the permeabilization process. Trifluoperazine, chlorpromazine and W-7, compounds which inhibit cellular functions dependent on the Ca²⁺-calmodulin complex, are able to enhance the effect of external ATP. Thus, a dramatic stimulation of nucleotide permeability occurs with concentrations of external ATP and inhibitor that are ineffective when added alone. Calmodulin antagonists and low concentrations of external ATP increased membrane permeability to Na⁺ and K⁺ as was previously shown for permeabilization with ATP alone. Earlier studies have shown that energy inhibitors which reduce intracellular ATP levels greatly increase the sensitivity of transformed cells to external ATP. However, the Ca²⁺-calmodulin antagonists used in the present study exert their effects at concentrations which do not alter intracellular ATP levels.     

ATP-resistant variants of transformed mouse fibroblasts

Addition of ATP to cultures of transformed mouse fibroblasts, 3T6 cells, resulted in cell growth inhibition, whereas the growth of the non-transformed counterparts, 3T3 cells, was only slightly affected. The inhibition was found to be specific for adenine nucleotides, and concentration dependent. At relatively low concentrations (e.g., 1.0 mM) the effect of ATP was cytostatic, whereas at higher concentrations (e.g., 1.0 mM) a cytotoxic effect was exerted. ATP-resistant variants of 3T6 cells were selected by exposure of cultures to gradually elevated concentrations of ATP. The variants were found to resemble the non-transformed counterparts, 3T3 cells, more than the 3T6 parent cells, by the following criteria: ATP-induced alterations in the membrane potential, changes in membrane permeability, cell growth inhibition, and colony formation on soft agar. The data indicate that long exposure of the transformed cells to external ATP results in redifferentiation and reduction in their tumorigenicity.     

Glycolysis in quiescent cultures of 3T3 cells. Stimulation by serum, epidermal growth factor, and insulin in intact cells and persistence of the stimulation after cell homogenization.

Addition of serum to quiescent cultures of 3T3 cells rapidly increases lactic acid formation and subsequently stimulates cell division. The stimulation of lactic acid production is seen at high, saturating concentrations of extra-cellular glucose. It is dependent on the time of exposure and on the dose of serum and is not blocked by the addition of cycloheximide, puromycin, or actinomycin D. In contrast, serum only marginally affects glycolysis by rapidly growing 3T6 or SV40-3T3 cells. In addition to serum, epidermal growth factor (0.1 to 10 ng/ml) and insulin (10 to 500 ng/ml) cause a striking stimulation of glycolysis in quiescent 3T3 cells. Neither exogenous cyclic nucleotides nor ouabain effect the glycolytic response, but the presence of Ca2+ markedly influences the activation of glycolysis by epidermal growth factor and by insulin. A novel finding in this study is that homogenates prepared from quiescent cells treated with serum, epidermal growth factor, or insulin show increased glycolysis as compared with homogenates from nonstimulated cultures. This finding will allow further experimental analysis of the cause of increased glycolysis in rapidly proliferating cells.     

Ascorbate-independent proline hydroxylation resulting from viral transformation of Balb 3T3 cells and unaffected by dibutyryl cAMP treatment.

Collagen synthesis, hydroxylation of proline in collagen, and collagen secretion were studied in the contact-inhibited mouse fibroblast line, Balb 3T3; the Kirsten virus transformed line, Ki-3T3; and dibutyryl cAMP (dbcAMP)-treated Ki-3T3 cells, during the various phases of the growth cycle. Transformed cells in both logarithmic and stationary phase produced lower levels of collagen than the parent line but 85-90% of the theoretically possible hydroxyproline residues of the collagen were formed even when ascorbic acid was not added to the culture medium. Moreover, the transformed cells showed only about a 20% increase of collagen secretion upon addition of ascorbate. This was in contrast to the ascorbate requirement for maximal proline hydroxylation and the 2-3 fold stimulation of collagen secretion by ascorbate in the parent Balb 3T3 cells. Although dbcAMP treatment caused Ki-3T3 cells to assume a more normal morphology and increased the relative rate of collagen synthesis to levels similar to that of 3T3, such treatment did not restore an ascorbate requirement for proline hydroxylation or collagen secretion. The specific activity of the enzyme prolyl hydroxylase also was not affected by dbcAMP treatment although collagen synthesis was increased by such treatment. In addition, it was found that ascorbic acid was not effective in activating prolyl hydroxylase derived from Ki-3T3 or dbcAMP-treated Ki-3T3 cell cultures either in logarithmic phase or stationary phase. Ki-3T3 cultures did not accumulate ascorbic acid in cells or medium nor was ascorbic acid synthesized from the precursor 14C-glucuronate in cell homogenates. The results suggest that virally transformed Balb 3T3 cells acquire the capacity to synthesize a reducing cofactor for prolyl hydroxylase and that this function may be related to the increased glycolytic metabolism of these cells since neither cellular metabolism nor ascrobate-independent hydroxylation was altered by treatment with dbcAMP.     

Bongkrekic acid facilitates glycolysis in cultured cells and induces cell death under low glucose conditions

Bongkrekic acid (BKA) inhibits adenine nucleotide translocator (ANT) and suppresses ADP/ATP exchange in the mitochondrial inner membrane. Previously, we demonstrated that BKA exhibited cytotoxic effects on 4T1 tumor cells, depending on the cell number in the culture, but not on NIH3T3 cells. However, the cause of this differential sensitivity was unelucidated. Here we demonstrate that BKA reduced the O₂ consumption in both cell lines and increased the mitochondrial membrane potential, thereby facilitating glucose consumption. BKA reduced cellular ATP in 4T1 cells in a dose-dependent manner but not in NIH3T3 cells. The cellular ATP of 4T1 cells was decreased with a reduced glucose concentration in the media, but that of NIH3T3 cells remained constant. We also demonstrated that BKA-induced cell death in both cell lines in low glucose media; however, the susceptibility to the reduced glucose concentration was slightly higher in 4T1 cells, which may be attributed to the difference in the dependency on glycolysis as their energy source. These results indicate that 4T1 tumor cells rely heavily on glucose for energy production. Our data demonstrate that BKA disturbs ATP production in mitochondria and increases the susceptibility to a low glucose condition.     

Modulation of mammalian sperm motility by quercetin

The flavonoid quercetin inhibits collective motility of ejaculated ram spermatozoa in the first 2 hr of incubation; during the next 3-4 hr motility is stimulated. To explain this interesting effect, we followed the influence of quercetin on sperm glycolysis, extracellular pH, ATP content, mitochondrial respiration, and lipid peroxidation. The collective motility of untreated cells is decreased to about 40% of the original motility during two hours of incubation. During this time, the rate of glycolysis is constant, respiration rate is increasing, there is no change in ATP content, the rate of lipid peroxidation is very slow, and the extracellular pH became very acidic (pH 5.5). It is concluded that motility is decreased due to this acidification. This acidification is prevented to some extent by quercetin, which indirectly inhibits glycolysis. Quercetin inhibits motility due to the inhibition of the plasma membrane calcium pump, as we showed previously (Breitbart et al., J Biol Chem 260:11548-11553, 1985). The motility of untreated cells is arrested after 3.5 hr of incubation, whereas quercetin-treated cells show high motility, which continues for additional 2-3 hr. After 3.5 hr, the control cells show no glycolytic activity, ATP content and respiration rates are decreased, and rate of lipid peroxidation is highly increased. At this time, quercetin-treated cells show no glycolytic activity, only a small decrease in ATP content and respiratory rate, and a very low rate of lipid peroxidation. Based on these data it is concluded that sperm motility after 3.5 hr of incubation is dependent mainly on mitochondrial respiration.(ABSTRACT TRUNCATED AT 250 WORDS)     

The growth requirements of SV40 virus transformed Balb/c-3T3 cells in serum-free monolayer culture

The growth requirements of SV40 transformed Balb/c-3T3 cells have been studied in the absence of serum. For growth in serum-free medium, the cells require (i) insulin, (ii) transferrin, and (iii) cis-unsaturated fatty acids added in combination with fatty acid free bovine serum albumin. The growth rate, saturation density, and morphology of cells grown in this serum-free medium are the same as those of cells grown in serum supplemented medium. This mixture also supports the growth of SV40 transformed Swiss-3T3 cells and SV40 transformed primary mouse embryo cells, but does not support the growth of untransformed Balb/c-3T3 cells. The addition of fibronectin to this mixture allows routine subculture, repeated passage, and indefinite propagation of SV40 transformed Balb/c-3T3 cells. Cells grown in this medium for a period of two months retain their ability to induce tumors when injected into athymic nude mice.     

Endgoenous protein kinase in outer plasma membrane of cultured 3T3 cells. Nature of the membrane-bound substrate and effect of cell density, serum addition, and oncogenic transformation.

Endogenous protein kinase activity was detected in the outer plasma membrane of 373 and SV40 transformed 3T3 cells. When intact cells were incubated with [gamma-32P]ATP, there was a transfer of [32P]phosphate into an acid-insoluble product. The reaction was: (a) linear as a function of time (up to 30 min), (b) proportional to the number of cells present and (c) dependent on temperature and Mg2+ concentration. The acid-insoluble product was susceptible to pronase but not RNase or DNase. More specifically, phosphomonoester bonds to serine and threonine were identified. There was less than 3% hydrolysis of the [gamma-32P]ATP during the reaction; moreover, free [32P]phosphate failed to substitute for the ATP. The reaction product was located on the cell surface, as evidenced by the fact that it could be removed by mild trypsin treatment of intact 3T3 cells. Further evidence for the surface location of the kinase was shown by its activity in phosphorlating exogenous substrate, histone, and phosvitin. The level of phosphorylation increased by 2- to 4-fold prior to the start of S phase when quiescent 3T3 cells were stimulated to reinitiate growth by the addition of serum. The SV40 3T3 cells had from 5- to 10-fold more activity per cell than the quiescent 3T3 cells. Sodium dodecyl sulfate polyacrylamide gel electrophoresis and radioautography show at least 25 phosphorylated proteins; the surface label pattern of 3T3 cells differs from that of SV40-transformed 3T3 cells.     

Comparison of oxygen consumption rates in minimally transformed BALB/3T3 and virus-transformed 3T3B-SV40 cells

In the recent years, bioenergetics of tumor cells and particularly cell respiration have been attracting great attention because of the involvement of mitochondria in apoptosis and growing evidence of the possibility to diagnose and treat cancer by affecting the system of oxidative phosphorylation in mitochondria. In the present work, a comparative study of oxygen consumption in 3T3B-SV40 cells transformed with oncovirus SV40 and parental BALB/3T3 cells was conducted. Such fractions of oxygen consumption as “phosphorylating” respiration coupled to ATP synthesis, “free” respiration not coupled to ATP synthesis, and “reserve” or hidden respiration observed in the presence of protonophore were determined. Maximal respiration was shown to be only slightly decreased in 3T3B-SV40 cells as compared to BALB/3T3. However, in the case of certain fractions of cellular respiration, the changes were significant. “Phosphorylating” respiration was found to be reduced to 54% and “reserve” respiration, on the contrary, increased up to 160% in virus-transformed 3T3B-SV40 cells. The low rate of “phosphorylating” respiration and high “reserve” respiration indicate that under normal incubation conditions the larger part of mitochondrial respiratory chains of the virus-transformed cells is in the resting state (i.e. there is no electron transfer to oxygen). The high “reserve” respiration is suggested to play an important role in preventing apoptosis of 3T3B-SV40 cells.     

Phosphate and the regulation of DNA replication in normal and virus-transformed 3T3 cells.

3T3 cells were cultured in media with different phosphate concentrations and the effects on DNA synthesis were examined. Even a modest phosphate depletion markedly inhibited DNA synthesis and cell multiplication in proliferating cultures. Furthermore, the decrease in the proportion of DNA-synthesizing cells observed after phosphate starvation followed the same time-course as the decrease seen after serum starvation. Cells starved to quiescence in a medium with a 100-fold decrease in phosphate concentration remained viable but non-proliferating for up to 3 weeks, i.e. they had entered a state of quiescence comparable with that seen after serum starvation. Addition of phosphate to phosphate-depleted cultures restored DNA synthesis within 24h. Furthermore, the kinetics of [3H]thymidine labelling after phosphate addition were nearly identical with the labelling kinetics following addition of serum to serum-depleted cultures. In contrast, phosphate deprivation had no inhibitory effects on DNA synthesis in simian-virus-40-transformed 3T3 cells. Furthermore, the inhibitory effects on DNA synthesis in such cells caused by a complete removal of serum could not be further enhanced by decreasing the phosphate concentration in the culture medium.