Mutual potentiation by magnesium and calcium of growth in animal cells

Is Liver Enzyme Release Really Associated with Cell Necrosis Induced by Oxidant Stress?

Hepatic diseases are a major concern worldwide. Increased specific plasma enzyme activities are considered diagnostic features for liver diseases, since enzymes are released into the blood compartment following the deterioration of the organ. Release of liver mitochondrial enzymes is considered strong evidence for hepatic necrosis, which is associated with an increased production of ROS, often leading to greater hepatic lipid peroxidation. Lipotoxic mediators and intracellular signals activated Kupffer cells, which provides evidence strongly suggesting the participation of oxidant stress in acute liver damage, inducing the progression of liver injury to chronic liver damage. Elevated transaminase activities are considered as an index marker of hepatotoxicity, linked to oxidant stress. However, a drastic increase of serum activities of liver enzyme markers ought not necessarily to reflect liver cell death. In fact, increased serum levels of cytoplasmic enzymes have readily been observed after partial hepatectomy (PH) in the regenerating liver of rats. In this regard, we are now showing that in vitro modifications of the oxidant status affect differentially the release of liver enzymes, indicating that this release is a strictly controlled event and not directly related to the onset of oxidant stress of the liver.

The role of calcium and nitric oxide during liver enzyme release induced by increased physical forces as evidenced in partially hepatectomized rats

Although increased plasma enzyme activities could be diagnostic for tissue damage, the mechanisms controlling cellular enzyme release remain poorly understood. We found a selective and drastic elevation of serum enzyme activities accompanying rat liver regeneration after partial hepatectomy (PH), apparently controlled by a mechanism dependent on flow-bearing physical forces. In fact, this study assesses a putative role of calcium mobilization and nitric oxide (NO) production underlying rat liver enzyme release. The role of increased shear stress (by enhancing viscosity during perfusion) and the participation of cell calcium and NO were tested in isolated livers subjected to increasing flow rate. After PH, there was a drastic elevation of serum activities for liver enzyme markers, clearly predominating those of mitochondrial localization. Liver enzyme release largely depended on extracellular calcium entry, probably mediated by stretch-sensitive calcium channels, as well as by increasing NO production. However, these effects were differentially observed when comparing liver enzymes from cytoplasmic or mitochondrial compartments. Moreover, a possible role for cell-mediated mechanotransduction in liver enzyme release was suggested by increasing shear stress (high viscosity), which also selectively affected the release of the enzymes tested. Therefore, we show, for the first time, that flow-induced shear stress can control the amount of hepatic enzymes released into the bloodstream, which is largely regulated through modifications in cell calcium mobilization and production of liver NO, events markedly elevated in the proliferating rat liver.

The possible relationship between keratoconus and magnesium deficiency

The cause of keratoconus is unknown. However, an earlier report demonstrated magnesium deficiency in keratoconus patients, and suggested that magnesium deficiency could pathologically affect the mechanisms of the cornea. Experimental and clinical papers concerning a possible relationship between keratoconus and magnesium deficiency were reviewed. These studies have demonstrated molecular and cellular alterations specific to the keratoconic cornea, including: thinning and fragmentation of membranes, degenerated cells and collagen fibres, swelling of the mitochondria, and biochemical abnormalities in protein synthesis. Similar alterations have reportedly been induced by magnesium deficiency. This review suggests a possible relationship between the specific keratoconic disorders and the alteration induced by magnesium deficiency at the intracellular and extracellular levels. Although the etiology of keratoconus is still unknown, this paper may give some new ideas for further experimental and clinical studies on the etiology of keratoconus.

The roles of magnesium in biotechnology

This review highlights the important roles played by magnesium in the growth and metabolic functions of microbial and animal cells, and therefore assigns a key role for magnesium ions in biotechnology. The fundamental biochemical and physiological actions of magnesium as a regulatory cation are outlined. Such actions are deemed to be relevant in an applied sense, because Mg2+ availability in cell culture and fermentation media can dramatically influence growth and metabolism of cells. Manipulation of extracellular and intracellular magnesium ions can thus be envisaged as a relatively simplistic, but nevertheless versatile, means of physiological cell engineering. In addition, biological antagonism between calcium and magnesium at the molecular level may have profound consequences for the optimization of biotechnological processes that exploit cells. In fermentation, for example, it is argued that the efficiency of microbial conversion of substrate to product may be improved by altering Mg:Ca concentration ratios in industrial feedstocks in a way that makes more magnesium available to the cells. With particular respect to yeast-based biotechnologies, magnesium availability is seen as being crucially important in governing central pathways of carbohydrate catabolism, especially ethanolic fermentation. It is proposed that such influences of magnesium ions are expressed at the combined levels of key enzyme activation and cell membrane stabilization. The former ensures optimum flow of substrate to ethanol and the latter acts to protect yeasts from physical and chemical stress.

Optimization of murine keratinocyte culture for the production of graftable epidermal sheets

The aim of the present study was to optimize murine epidermal cell cultures in order to obtain graftable sheets. Newborn (1-3 days old) Balb/c mice skin were used to optimize culture media and plating cell concentration, then epidermal sheet production, and grafting. Epidermal cells were plated at various concentrations in different culture media containing low (0.1 mM) or high (greater than 1 mM) Ca2+ levels. After a 3 day culture at the 10(4) cells/cm2 plating cell concentration, the percentage of differentiated cells was more than 80% in the high Ca2+ culture medium and less than 50% with bulky cells in the low Ca2+ culture medium. Under these conditions confluence was not obtained. At the 10(5) cells/cm2 seeding inoculum, the percentage of confluence increased to 95-100% during the first 72 h of culture in both high and low Ca2+ culture media. Three-day-old culture showed stratified multilayer epidermal sheets in the high calcium medium, and monolayer epidermal sheets were present in the low calcium medium after seeding keratinocytes in fibronectin precoated flasks. Seven days after plating, post confluent cultures were composed of a high percentage of differentiated cells (90%) with an increase in shedding cells in the medium. Considering the above morphological observations, sheets obtained with 10(5) cells/cm2 in MCDB-153 (A), DME-HAM (B) or GMEM (C) media after 3 days in culture were grafted. Twenty days after grafting, histological analysis of biopsies showed an epidermal structure and organization comparable to normal murine epidermis without hair follicles. Epidermal transplants showed a complete basement membrane, hemidesmosomes, and tonofilament bundles. Sheets obtained after seven day culture in all media showed lower coverage of the wound bed. These studies point out the importance of the plating cell and Ca2+ concentrations, and the culture time for murine keratinocyte confluence and differentiation to obtain graftable epidermal sheets.

Effect of magnesium on the growth and cell cycle of transformed and non-transformed epithelial rat liver cells in vitro

The effects of magnesium (Mg) restriction on cell growth and the cell cycle were determined in transformed (TRL-8) and non-transformed (TRL-12-15) epithelial-like rat liver cells. Cells were cultured in RPMI 1640 medium in which the Mg concentration was reduced to 0.5, 0.1, and 0 x the concentration in the regular RPMI 1640 media (100mg/l). Cell growth in the transformed cells was not influenced by the Mg restriction as greatly as in the non-transformed cell line. Transit through the cell cycle also exhibited an independence of the Mg in the medium in the transformed cells. When transformed cells were grown for two generations in Mg-limited medium, the growth rate slowed to a rate similar to that demonstrated by the non-transformed cells. Analysis by flow cytometry showed that transit through the cell cycle was minimally slowed in Mg deficient transformed cells; however, transit through the G1 and S phases in the non-transformed cells was slowed. The TRL-8 cells in Mg-limited medium resulted in fewer nuclei in G1 with subsequent increases in the percentages of S-phase nuclei. The TRL 12-15 cells reacted oppositely with the number of G1 nuclei increased and the number of S-phase nuclei decreased. In respect to growth, these results show that epithelial cells respond in a similar manner to Mg-limitation as do fibroblast cells. The transformed cells exhibited a level of independence from Mg in respect to growth, reproduction, and cell-cycle kinetics.

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.

Superoxide-induced deimination of arginine in hematopoietic cells

Murine bone marrow cells can produce citrulline directly from L-arginine without intermediate ornithine. An L-arginine-dependent biochemical pathway synthesizing L-citrulline and nitrate, coupled to an effector mechanism has also been recently demonstrated in murine cytotoxic activated macrophages. We show herein that L-citrulline synthesis in murine bone marrow cells can be induced by the generation of superoxide. It can take place in an arginine-free medium, suggesting the implication of a superoxide-dependent peptidyl arginine deiminase.

Optimized medium for clonal growth of human microvascular endothelial cells with minimal serum

An optimized basal nutrient medium, MCDB 131, has been developed that supports clonal growth of human microvascular endothelial cells (HMVEC) with as little as 0.7% dialyzed fetal bovine serum (dFBS) when also supplemented with 10 ng/ml epidermal growth factor (EGF) and 1 microgram/ml hydrocortisone. An extensive initial survey of available media showed that MCDB 402, a medium optimized for low-serum growth of Swiss 3T3 cells, supported the best clonal growth of HMVEC with 10% dFBS. Quantitative adjustment of the composition of MCDB 402 for improved clonal growth of HMVEC with reduced amounts of dFBS resulted in development of MCDB 131. Although many different adjustments contributed to the optimal properties of MCDB 131 for growth of HMVEC, the most unusual feature of this medium is its high magnesium concentration. A major benefit was achieved by increasing Mg2+ from 0.8 mM in MCDB 402 to 10.0 mM in MCDB 131. In the absence of defined supplements, MCDB 131 supports good clonal growth of HMVEC with 2% dFBS. This can be reduced to 0.7% by adding EGF and hydrocortisone, which act synergistically to improve growth with low levels of dFBS.

Coding sequence and growth regulation of the human vimentin gene

We have established the complete coding sequence of the human vimentin gene. It had 91% homology to the coding sequence of the Syrian hamster vimentin gene (Quax et al., Cell 35:215-223, 1983) and partial homology to several other sequences coding for intermediate filament proteins. The most striking difference between the Syrian hamster and human vimentin genes was in the 3' untranslated region, which was considerably longer in the Syrian hamster. Using RNA blots and a human vimentin cDNA clone from an Okayama-Berg library, we have established that expression of the vimentin gene was growth regulated. The steady-state levels of cytoplasmic vimentin mRNA in 3T3 cells were increased by serum and platelet-derived growth factor, but not by epidermal growth factor, insulin, or platelet-poor plasma. The increase in expression of the vimentin gene that occurred when G0-phase cells were stimulated to proliferate was detected in six different cell types from four different species. The expression of the vimentin gene was also increased when HL60 cells were induced to differentiate by phorbol esters; it decreased when differentiation was induced by retinoic acid.

Coding sequence and growth regulation of the human vimentin gene

We have established the complete coding sequence of the human vimentin gene. It had 91% homology to the coding sequence of the Syrian hamster vimentin gene (Quax et al., Cell 35:215-223, 1983) and partial homology to several other sequences coding for intermediate filament proteins. The most striking difference between the Syrian hamster and human vimentin genes was in the 3' untranslated region, which was considerably longer in the Syrian hamster. Using RNA blots and a human vimentin cDNA clone from an Okayama-Berg library, we have established that expression of the vimentin gene was growth regulated. The steady-state levels of cytoplasmic vimentin mRNA in 3T3 cells were increased by serum and platelet-derived growth factor, but not by epidermal growth factor, insulin, or platelet-poor plasma. The increase in expression of the vimentin gene that occurred when G0-phase cells were stimulated to proliferate was detected in six different cell types from four different species. The expression of the vimentin gene was also increased when HL60 cells were induced to differentiate by phorbol esters; it decreased when differentiation was induced by retinoic acid.

Anchorage dependence and Ca2+ requirement are independently modulated by hydrocortisone hormone in rat C6 glioma cells

We had previously shown that hydrocortisone (Hy), a glucocorticoid hormone, regulates the expression of the transformed phenotype of rat C6 glioma cells. The hormone reversibly renders C6 cells dependent on anchorage and high Ca2+ concentration for growth. We had also isolated Hy-resistant C6 variants in agarose suspension cultures. Here we report that Hy-resistant variants selected in high (1.8mM) Ca2+ medium become growth-arrested in low (30 microM) Ca2+ medium upon hormone treatment. We conclude that Hy-induced anchorage dependence and Hy-induced high Ca2+ requirement for growth of C6 glioma cells, are two independent phenotypes.

Treatment of patients with advanced malignant lymphoma using gallium nitrate administered as a seven-day continuous infusion

Previous trials of gallium nitrate (NSC-15200) showed that bolus administration produced dose-limiting nephrotoxicity without substantial antitumor activity. As an effort to increase the therapeutic index of this compound and to establish a satisfactory out-patient schedule, the authors evaluated the effects of gallium nitrate administered as a continuous infusion in patients with advanced malignant lymphoma. In an initial Phase I trial, four dose levels which ranged from 200 to 400 mg/m2/day in 27 patients were studied. Nausea which impaired oral hydration was found to be dose-limiting. A dose of 300 mg/m2/day was chosen for extended Phase II evaluation and 37 additional patients were entered into the study at that dose level. Overall, 16 of 47 patients (34%) who had bi-dimensionally measurable parameters of disease achieved major antitumor responses (six of 15 with diffuse "histiocytic" lymphoma, five of ten with diffuse poorly-differentiated lymphocytic lymphoma, two of five with nodular poorly-differentiated lymphocytic lymphoma, and three of 17 with Hodgkin's disease). The median duration of response was 2.5 months. Only 8% of patients who received 300 mg/m2/day developed an increase in serum creatinine concentration greater than 1.1 mg/dl over baseline values. Hypocalcemia occurred in two-thirds of patients. Other toxic effects, including paresthesiae, diarrhea, and hearing loss, were noted in less than 5% of patients. There was minimal myelosuppression. The authors conclude that gallium nitrate administered as a continuous infusion for seven days at 300 mg/m2/day is well-tolerated and effective treatment for patients with advanced malignant lymphoma. Outpatient administration using portable infusion pumps is safe and practical. Further evaluation of the drug administered as a constant infusion is indicated in patients with other neoplastic diseases.

Glucocorticoid hormone renders rat glioma cells dependent on high concentrations of external Ca2+ for growth

C6 rat glioma cells, like other tumor cells, grow optimally in Ca2+-or Mg2+-depleted 5% serum medium. However, the glucocorticoid hormone hydrocortisone renders these cells dependent on high concentrations of external Ca2+ for growth. Upon Ca2+ deprivation (30-80 microM Ca2+ medium) hydrocortisone-treated C6 cells undergo reversible cell-cycle arrest at G0/G1 phase. This effect is specific for glucocorticoid hormones and occurs at physiological concentrations. Growth restimulation of Ca2+-deprived, hydrocortisone-treated C6 cells by bovine pituitary growth factors or serum growth factors only takes place if the external Ca2+ concentration is increased. On the other hand, C6 cell growth requirement for external Mg2+ was not increased by the glucocorticoid hormone treatment. A minimum of 80 microM of external Mg2+ is required to keep cells adhered and spread in Ca2+-depleted (30 microM) 5% serum medium; in high Ca2+ concentration (1.8 mM), Mg2+ is not required for adhesion or spreading. Thus, the hormone hydrocortisone renders the cell cycle of C6 glioma cells controllable by the levels of external Ca2+, a minimal external Mg2+ being necessary to warrant normal adhesion.

Calcium, magnesium, and serum factors in multiplication of normal and transformed human lung fibroblasts

Serum factors determine the extracellular requirement for both Ca2+ and Mg2+ for multiplication of normal human lung fibroblasts in vitro. Serum factors also affect the extracellular Ca2+ requirement for transformed fibroblasts but to a different extent than for normal cells. Transformed cells exhibit a reduced requirement for both Ca2+ and Mg2+ for multiplication. The apparent reduction in Ca2+ requirement of transformed cells is dependent on the level of serum factors in the medium. The reduced Mg2+ requirement for transformed cells is more striking than the loss of Ca2+ and independent of the level of serum factors in the medium. A sequential effector relationship among serum factors, Ca2+ and Mg2+, in a proliferative control system for normal cells is proposed. Alteration or bypass of an intracellular Mg2+-requiring process is proposed as a major lesion in the transformed cells. This alteration causes an observed loss of requirements for both Ca2+ and serum factors for the multiplication of transformed cells.

Calcium, magnesium, and growth control in the WI-38 human fibroblast cell

WI-38 and SV40WI-38 cells have been synchronized using centrifugal elutriation. This technique allows for the rapid harvesting of early G1 phase cells from exponentially growing populations of both the normal and transformed cell. Using these cells, as well as WI-38 cells synchronized by serum deprivation, we have examined the effects of extracellular Ca and Mg levels on the progression of cells through G1 phase. A differential sensitivity to both Ca and Mg deprivation is observed between normal and transformed cells. The WI-38 cell requires higher levels of both ions for traversal of G1 phase and for continued proliferation as compared to the transformed cell. The temporal nature of the Ca and Mg requirements for the WI-38 cell has been examined during G1 phase. Ca is strictly required during early and late G1 phase, but not necessarily throughout mid-G1. An early as well as a late G1 Ca requirement is also found in serum-stimulated WI-38 cells. In contrast, the Mg requirement of WI-38 cells does not appear to be temporally well-defined. Mg appears to be a permissive factor, required throughout G1 phase rather than at certain prescribed intervals. On the basis of these data, it seems unlikely that these two cations exert their effects on cell growth entirely through a common competitive mechanism. Ca would appear to be involved in early serum or growth factor-mediated G1 events and later pre-S-phase events, as suggested in previous studies on other cell lines.

Effects of depletion of K+, Na+, or Ca2+ on DNA synthesis and cell cation content in chick embryo fibroblasts

Decreasing the K+ concentration of the medium from 5 mM to 0.59 mM decreased the K+ content of chick embryo fibroblasts to 22% of control values and increased the Na+ content to 820% of control values. The alteration of monovalent cation content occurred within two hours but had no effect on the rate of DNA synthesis, as measured by 3H-thymidine incorporation, for at least 16 hours. By decreasing the Na+ concentration in the medium, a 50% reduction in cellular Na+ could be obtained with no effect on thymidine incorporation. Since these changes in cellular Na+ or K+ are much larger than any known to occur under physiological conditions but have no effect on thymidine incorporation, we conclude that Na+ and K+ do not play a critical role in determining multiplication rate. Addition of 1.8 mEGTA to cells in media containing 1.7 mM Ca2+ and 0.8 mM Mg2+ inhibited thymidine incorporation and sharply decreased cellular K+ and increased cellular Na+ content. However, there was no reduction in total cellular Ca2+ levels. Likewise, decreasing the Ca2+ concentration of the medium below 0.01 mM inhibited thymidine incorporation, decreased cellular K+ and Mg2+, and increased cellular Na+ but did not affect total cellular Ca2+ levels. Inhibition of DNA synthesis, therefore, could not be correlated with changes in cellular Ca2+ levels.

A calcium requirement for movement of cultured cells

When calcium is removed from culture medium, motility of cultured cells is decreased. The effect is rapid, reversible and pronounced. Decreased motility is observed with normal mouse Balb/c 3T3 cells, mouse L929 cells, rat kidney fibroblasts and chick embryo fibroblasts. The calcium dependence of movement can be observed both with individual cells and with the movement of the margin of a monolayer into a wound. Magnesium will not substitute for calcium to maintain motility. Strontium will substitute, but is not as effective as calcium for maintaining cell movement. Low concentrations of the divalent cation ionophore A23187 (0.5-1 micron) partially reverse the reduced migration observed at low calcium concentrations. These results are consistent with the hypothesis that movement of non-muscle cells occurs through mechanisms similar to those important in the contraction of muscle.

Major intracellular cations and growth control: correspondence among magnesium content, protein synthesis, and the onset of DNA synthesis in BALB/c3T3 cells

Omission of Ca(2+) from the medium of confluent BALB/c3T3 cells for a period of 17 hr causes a large decrease in the number of cells synthesizing DNA. This effect is reversed by raising the Mg(2+) concentration of the medium to 20 mM. However, if the [Mg(2+)] is greater than 20 mM ("ultra-high" Mg(2+)), there is again a decrease in the number of cells synthesizing DNA. The synthesis of protein has a similar dependence on Mg(2+) concentration in Ca(2+)-deficient medium, but it responds within 45 min of the shift in cation concentrations rather than the 10 hr that is required for the change in DNA synthesis to become apparent. Cells in the ultrahigh Mg(2+) concentrations that are at first inhibitory to protein synthesis later return to maximal protein synthesis. This delayed increase in protein synthesis is reflected in a delayed increase in DNA synthesis. Intracellular concentrations of Mg(2+) in Ca(2+)-deficient media increase in proportion to extracellular Mg(2+) concentrations. Cells in medium with 30 mM Mg(2+) have a high intracellular content of Mg(2+) at 3 hr but have decreased their intracellular content by 17 hr, a time at which protein synthesis has been restored to normal. Intracellular Na(+) and K(+) concentrations also change in Ca(2+)-deficient medium, but independent variation of these ions shows that protein synthesis is relatively insensitive to their concentration. Intracellular Ca(2+) remains fairly constant under all these conditions. The rate of protein synthesis of intact cells changes as a function of intracellular Mg(2+) content in a manner very similar to that which has been reported for cell-free systems. We conclude that protein synthesis is very sensitive to small changes in intracellular [Mg(2+)] within physiological range and that the onset of DNA synthesis is dependent on the rate of protein synthesis. Regulation of the availability of Mg(2+) within the cell therefore presents a plausible mechanism for growth control.

Transient growth inhibition of Escherichia coli K-12 by ion chelators: "in vivo" inhibition of ribonucleic acid synthesis

The ion chelators picolinic acid, quinaldic acid, 1,10-phenanthroline, and 8-hydroxyquinoline, but not ethylenediaminetetraacetate, ethyleneglycol-bis-(beta-aminoethyl ether)-N,N-tetraacetate, or dipicolinic acid, rapidly but transiently arrest growth of Escherichia coli K-12. Cells adapt and become resistant to growth inhibition by these agents, a process which requires protein synthesis. Mn2+, at low concentrations, decreases the time required for resumption of growth. Proteins synthesized during the lag are quantitatively and qualitatively different from those synthesized during normal growth. Inhibition of growth can explained by an effect on RNA polymerase, a known metalloenzyme.

Calcium transport and exchange in mouse 3T3 and SV40-3T3 cells

The kinetics of Ca++ uptake have been evaluated in 3T3 and SV40-3T3 mouse cells. The data reveal at least two exchangeable cellular compartments in the 3T3 and SV40-3T3 cell over a 50-min exposure to 45Ca++. A rapidly exchanging compartment may represent surface-membrane-localized Ca++ whereas a more slowly exchanging compartment is presumably intracellular. The transition of the 3T3 cell from exponential growth (at 3 day's incubation) to quiescence (at 7 days) is characterized by a 7.5-fold increase in the size of the fast component. Quiescence of the 3T3 cell is also characterized by a 3.2-fold increase in the unidirectional Ca++ influx into the slowly exchanging compartment and a 3.6-fold increase in its size. The increase in size of the slow compartment at quiescence may result from a redistribution of intracellular Ca++ to a more readily exchangeable compartment, possibly reflecting a release of previously bound Ca++. In contrast, no significant change in any of these parameters is observed in the proliferatively active SV40-3T3 cells after corresponding period of incubation, even though these cells attained higher growth densities and underwent postconfluence.

Separate roles for calcium and magnesium in their synergistic effect on uridine uptake by cultured cells: significance for growth control

The uptake of uridine by BALB/c3T3 cells is markedly inhibited by reducing the concentration of Mg(2+) in medium containing only traces of Ca(2+). When physiological [Ca(2+)] is present in the medium, omission of Mg(2+) has no effect on uridine uptake, and when Mg(2+) is present, omission of Ca(2+) has only a slight inhibitory effect. When both Ca(2+) and Mg(2+) are omitted, the concentration of Ca(2+) in the cells is not reduced, but that of Mg(2+) is reduced to about one-half in 3 hr. The concentration of K(+) is also reduced, and that of Na(+) is increased, suggesting increased membrane permeability to cations. The rate of diffusion of the nontransported hexose, L-glucose, into the cells is greatly increased. Changes in intracellular Na(+) and K(+) concentrations do not in themselves affect uridine uptake. When Ca(2+) alone is restored to the medium of cells that had been deprived of both Ca(2+) and Mg(2+), there is no increase in the greatly depressed rate of uridine uptake, but when Mg(2+) alone is restored, the rate of uridine uptake returns to control values. We conclude that the omission of Ca(2+) from the medium has no direct effect on uridine uptake, but acts by increasing the exchange of Mg(2+) between cells and medium and by otherwise altering the availability of Mg(2+) for this reaction. A similar conclusion is reached in considering the role of these ions in the regulation of other reactions of the coordinate response, including the initiation of DNA synthesis and the control growth.

Membrane bound and cellular cationic changes associated with insulin stimulation of cultured cells

Insulin was employed as a stimulant in our continuing investigations of the molecular mechanisms involved in the coordinate control of cellular metabolism and growth. Incubation of chicken embryo fibroblasts for 16 hours in media containing 0-0.1 U insulin/ml resulted in a 17-fold increase in the rate of 3H-thymidine incorporation into DNA. Concomitantly, there were graded increases in intracellular K+ (14%) AND Mg2+ (22%) and no significant change in Ca2+. These changes in cation content occurred within 10 to 30 minutes and preceded the changes in 3H-thymidine incorporation. Insulin produced a consistent graded decrease in externally bound Mg2+ and Ca2+ and a concomitant increase in bound Na+ and K+ with no significant change in the rates of K+ and Mg2+ efflux. The results are consistent with the concept of Mg2+ as a second messenger for insulin action, as well as with the more general hypothesis that Mg2+ is the centtral agent in the coordinate control of metabolism and growth in animal cells.

Magnesium reverses inhibitory effects of calcium deprivation on coordinate response of 3T3 cells to serum

Deprivation of Ca(2+) in crowded cultures of 3T3 cells inhibits the onset of DNA synthesis. By raising [Mg(2+)] to 15 mM the inhibition produced by Ca(2+) deprivation can be fully overcome. Sparse cultures are not inhibited by a similar deprivation of Ca(2+), and therefore are not stimulated by supranormal [Mg(2+)]. The time course of stimulation of the onset of DNA synthesis by supranormal [Mg(2+)] in low [Ca(2+)] is the same as that produced by serum in physiological concentrations of Ca(2+) and Mg(2+). Concentrations of Mg(2+) > 20 mM in low [Ca(2+)] reverse the stimulation, and [Mg(2+)] >/= 30 mM kills many cells. In contrast to the stimulation by 15 mM Mg(2+), supranormal [Ca(2+)] has no effect on the onset of DNA synthesis in cultures inhibited by Mg(2+) deprivation, if the formation of insoluble Ca-P(i) complexes is prevented. Neither Na(+) nor K(+) reproduces the effects of Mg(2+). The uptake of uridine is another parameter of the coordinate response of 3T3 cells to serum stimulation that is inhibited by Ca(2+) deprivation, and supranormal [Mg(2+)] also reverses this inhibition. The results support the thesis that the coordinate response of growth and metabolism to external effectors is regulated by the availability of Mg(2+) within the cell and that the inhibitory effects of Ca(2+) deprivation are indirect and caused by a reduction in the availability of Mg(2+).

Serum-stimulated changes in calcium transport and distribution in mouse 3T3 cells and their modification by dibutyryl cyclic AMP

Serum stimulation of quiescent 3T3 cells returns the cells to a proliferative state. Changes in Ca content, transport and distribution during the transition through G1 and S phase have been investigated following serum stimulation of these cells. 45 Ca exchange data indicate at least two kinetically defined cellular compartments for Ca; a rapidly exchanging component presumably representing surface Ca which is removable by EGTA and a slowly exchanging component presumably representing cytoplasmically located Ca. Previous studies (Tupper and Zorgniotti, '77) indicate that the approach to quiescence in the 3T3 cells is characterized by a large increase in the surface Ca component. The present data demonstrate that this component is rapidly lost following serum stimulation. Furthermore, the serum induces an 8-fold increase in Ca influx into the cytoplasmic compartment and a reduction in the unidirectional efflux rate coefficient for Ca. The increased Ca uptake peaks at approximately six hours (mid G1) and is accompanied by a parallel increase in cellular Ca. Prior to entrance of the cells into S phase (10-12 hours), Ca uptake declines. This is followed by a slower decline in cytoplasmic Ca levels. Simultaneous addition to fresh serum plus 0.5 mM dibutryl cAMP inhibits the entrance of the cells into S phase. Under these conditions the loss of surface Ca is not blocked. However, the presence of 0.5 mM dibutyryl cAMP inhibits the increase in Ca uptake and, in turn, diminishes the increase in cellular Ca following serum stimulation. In contrast, a low level of dibutyryl cAMP (0.1 mM) enhances progression through G1 phase but also reduces both Ca uptake and Ca content of the cells. The data suggest that the serum induced changes in Ca content and transport are linked to intracellular cyclic nucleotide levels and progression through G1 phase and that extracellular cAMP elevating agents may enhance of inhibit these interactions in a concentration dependent manner.

Calcium content and distribution as a function of growth and transformation in the mouse 3T3 cell

Total Ca content and that fraction of Ca sensitive to removal by the chelator ethylene glycol-bis(beta-aminoethyl ether)N,N,N',N'-tetraacetate (EGTA) have been investigated in the mouse 3T3 cell as a function of growth stage, transformation with SV40 virus, and serum levels of the media. Cells were allowed to grow through several doublings in media containing (45)Ca. The cellular content of (45)Ca was used to access total cell Ca. That fraction of (45)Ca removed by EGTA was presumed to represent primarily surface-localized Ca. The data are expressed on a per cell volume basis to compensate for size differences as a function of growth stage and transformation. During exponential growth phase, the 3T3 cell contains 525pmol Ca/mul cell volume. Of this, approx. 457 pmol/mul is not removable by EGTA and, presumably, is cytoplasmically located. This value is in close agreement with previous studies on the HeLa cell (470 pmol Ca/mul cell water after the removal of the surface Ca). The low level of EGTA- removable Ca present in the 3T3 cell during early exponential growth (68 pmol Ca/mul cell volume) increases progressively with increasing cell density, and upon quiescence it is sevenfold greater. In contrast, SV40- transformed 3T3 cells growing exponentially possess total levels of Ca which are approximately two-thirds the levels of the normal 3T3 cell. However, their EGTA-sensitive Ca is not significantly different from that of exponentially growing, normal 3T3 cells. As the transformed cells continue to grow at high density, their total ca and their sensitivity to EGTA do not change, in contrast to the normal 3T3 cell. Thus, an increase in Ca associated with the cell surface appears to be correlated with growth inhibition. This has been investigated further by regulating growth of the normal and transformed cell with alterations in the serum level of the media. In 4 percent calf serum the normal cell is stopped from continued proliferation. Growth stoppage under these conditions is characterized by a nearly fourfold increase in EGTA-removable Ca, similar to the increase observed upon quiescence in depleted 10 percent serum. Similar treatment of the transformed cell does not reduce its growth rate, nor does it significantly alter Ca distribution. However, at 0.5 percent medium serum levels, the SV40 3T3 growth rate is substantially reduced and, under these conditions, EGTA-removable Ca increases twofold.

Effect of medium composition on protein degradation and DNA synthesis in rat embryo fibroblasts

Fibroblasts in medium deficient in serum, amino acids, phosphate, or glucose stop synthesizing DNA and increase the rate of degradation of their long-lived cellular proteins approximately 2-fold. There is no difference in the rate of degradation of short-lived proteins under these conditions. Insulin, dexamethasone, and fibroblast growth factor act synergistically to inhibit protein degradation and to stimulate thymidine incorporation to about the same extent as serum. When the medium content in serum or fibroblast growth factor is varied over a wide range, there is a close, inverse correlation between the rate of protein degradation and the extent of thymidine incorporation. When serum is added to cells that have been deprived of serum, the inhibition of protein degradation is immediate whereas the enhanced rate of protein degradation in serum-free medium is attained within 1 hr after serum removal. A 30-min exposure to serum followed by incubation in serum-free medium was as effective as continuous exposure to serum in stimulating thymidine incorporation after 8-24 hr.

Magnesium and calcium effects on uptake of hexoses and uridine by chick embryo fibroblasts

Cultures of chick embryo fibroblasts were incubated for varying periods in media containing different concentrations of Ca2+ and Mg2+-Mg2+ deprivation produced a gradual decrease in the Vmax of the glucose transport system for the D-glucose analogues 3-O-[3H]methyl-D-glucose and 2-deoxy-D-[3H]glucose and a parallel decrease in the rate of production of lactate from glucose in the medium. It greatly reduced the rates of [3H]uridine uptake and incorporation by decreasing the Vmax of the uridine transport system. Addition of Mg2+ to Mg2+-deprived cultures rapidly increased the rate of [3H]uridine uptake without requiring protein synthesis and increased the rate of 2-deoxy-D-[3H]glucose uptake without requiring RNA synthesis. These effects of changes in Mg2+ concentration qualitatively reproduce the effects of such variables as cell density and serum and insulin concentrations. Ca2+ deprivation resulted in similar, though much smaller, changes in the activities of the two transport systems, but also greatly increased the "leakiness" of the cells to the nontransported hexose L-[3H]glucose.

Magnesium deprivation reproduces the coordinate effects of serum removal or cortisol addition on transport and metabolism in chick embryo fibroblasts

A variety of unrelated effectors stimulate or inhibit coordinately the same array of metabolic reactions in chick embryo fibroblasts, including the uptake of 2-deoxy-D-glucose and uridine, and the incorporation of uridine and thymidine into acid insoluble material. The coordinate inhibition of these reactions by omission of serum or addition of cortisol is reproduced quantitatively by lowering the concentration of magnesium (Mg2+) in medium containing 0.2 mM Ca2+. The response times for the utilization of uridine and thymidine following the removal of addition of Mg2+ are similar to those which follow removal or addition of serum. The effect of serum on the incorporation of choline, which is not part of the coordinate response to unrelated effectors, is not reproduced by varying Mg2+ concentrations. The results support the hypothesis that the availability of Mg2+ within the cell plays a central role in the coordinate control of transport, metabolism and growth by external physiological effectors.