Ionically mediated induction of mitogenesis in CNS neurons

Bioelectrical approaches to cancer as a problem of the scaling of the cellular self

One lens with which to understand the complex phenomenon of cancer is that of developmental biology. Cancer is the inevitable consequence of a breakdown of the communication that enables individual cells to join into computational networks that work towards large-scale, morphogenetic goals instead of more primitive, unicellular objectives. This perspective suggests that cancer may be a physiological disorder, not necessarily due to problems with the genetically-specified protein hardware. One aspect of morphogenetic coordination is bioelectric signaling, and indeed an abnormal bioelectric signature non-invasively reveals the site of incipient tumors in amphibian models. Functionally, a disruption of resting potential states triggers metastatic melanoma phenotypes in embryos with no genetic defects or carcinogen exposure. Conversely, optogenetic or molecular-biological modulation of bioelectric states can override powerful oncogenic mutations and prevent or normalize tumors. The bioelectrically-mediated information flows that harness cells toward body-level anatomical outcomes represent a very attractive and tractable endogenous control system, which is being targeted by emerging approaches to cancer.

Role of calcium and kinases on the neurotrophic effect induced by gamma-aminobutyric acid

An increasing body of evidence supports a trophic action of gamma-aminobutyric acid (GABA) during nervous system development. The purported mediator of these trophic effects is a depolarizing response triggered by GABA, which elicits a calcium influx in immature CNS cells. This Mini-Review focuses on the neurotrophic role of neural activity and GABA and some of the most common intracellular cascades activated by depolarization and trophic factors. Several biological effects induced by GABA in the developing nervous system are reviewed, with particular emphasis on what is known about calcium-dependent neurotrophic effects induced by GABA and its intracellular mechanisms.

Effect of dietary selenite on N-nitrosodiethylamine-induced and phenobarbital promoted multistage hepatocarcinogenesis in rat: reflection in some minerals

Selenium (Se), a dietary micronutrient, plays a vital role in cancer chemotherapy in many organs including the liver. We have studied the relationship between some minerals, which are essential in normal functioning of cells and anticancer effect of Se in N-nitrosodiethylamine (DEN) induced and phenobarbital (PB) promoted multistage hepatocarcinogenesis. Se (4 ppm through drinking water; as sodium selenite) was given to animals throughout the study, before initiation and during promotion phase of hepatocarcinogenesis, in a defined experimental protocol. Se, sodium, potassium, calcium and iron were measured either in hepatoma, or surrounding liver tissue or whole liver tissue and serum of experimental animals. DEN and PB treatment significantly (P < 0.001) increased potassium, calcium and iron levels in serum, while it decreased (P < 0.001) the Se and sodium levels when compared with control rats. We have also observed significantly increased (P < 0.001) sodium, calcium and iron levels in hepatoma and surrounding liver tissue, whereas, Se, and potassium level was found to be decreased (P < 0.001) when compared with control rats. Supplementation of selenite throughout the study, before initiation and during promotion stage significantly alters the above mineral content. Results showed that the most significant beneficial effect of selenium during hepatocarcinogenesis was exerted potentially in long-term continuous and/or before the initiation phase of carcinogenicity, rather than in the promotion phase. The present and previous results from our laboratory suggest that sub-optimal intake of a single trace mineral can have broad effects on chemotherapy, providing a framework for understanding the multiple beneficial effects of selenium in cancer chemoprevention.

Bioelectromagnetics in morphogenesis

Understanding the factors that allow biological systems to reliably self-assemble consistent, highly complex, four dimensional patterns on many scales is crucial for the biomedicine of cancer, regeneration, and birth defects. The role of chemical signaling factors in controlling embryonic morphogenesis has been a central focus in modern developmental biology. While the role of tensile forces is also beginning to be appreciated, another major aspect of physics remains largely neglected by molecular embryology: electromagnetic fields and radiations. The continued progress of molecular approaches to understanding biological form and function in the post genome era now requires the merging of genetics with functional understanding of biophysics and physiology in vivo. The literature contains much data hinting at an important role for bioelectromagnetic phenomena as a mediator of morphogenetic information in many contexts relevant to embryonic development. This review attempts to highlight briefly some of the most promising (and often underappreciated) findings that are of high relevance for understanding the biophysical factors mediating morphogenetic signals in biological systems. These data originate from contexts including embryonic development, neoplasm, and regeneration.

Contribution of Ca2+ calmodulin-dependent protein kinase II and mitogen-activated protein kinase kinase to neural activity-induced neurite outgrowth and survival of cerebellar granule cells

In this report we describe our studies on intracellular signals that mediate neurite outgrowth and long-term survival of cerebellar granule cells. The effect of voltage-gated calcium channel activation on neurite complexity was evaluated in cultured cerebellar granule cells grown for 48 h at low density; the parameter measured was the fractal dimension of the cell. We explored the contribution of two intracellular pathways, Ca2+ calmodulin-dependent protein kinase II and mitogen-activated protein kinase kinase (MEK1), to the effects of high [K+ ]e under serum-free conditions. We found that 25 mm KCl (25K) induced an increase in calcium influx through L subtype channels. In neurones grown for 24-48 h under low-density conditions, the activation of these channels induced neurite outgrowth through the activation of Ca2+ calmodulin-dependent protein kinase II. This also produced an increase in long-term neuronal survival with a partial contribution from the MEK1 pathway. We also found that the addition of 25K increased the levels of the phosphorylated forms of Ca2+ calmodulin-dependent protein kinase II and of the extracellular signal-regulated kinases 1 and 2. Neuronal survival under resting conditions is supported by the MEK1 pathway. We conclude that intracellular calcium oscillations can triggered different biological effects depending on the stage of maturation of the neuronal phenotype. Ca2+ calmodulin-dependent protein kinase II activation determines the growth of neurites and the development of neuronal complexity.

Regulation of Na+,K+-ATPase by persistent sodium accumulation in adult rat thalamic neurones

The present study investigated the regulatory mechanism of the Na+, K+-ATPase and the level of internal Na+ and Ca2+ in response to persistent Na+ influx in acutely dissociated rat thalamic neurones. Whole-cell patch-clamp recordings and Na+ imaging revealed a stable [Na+]i and low background pump activity. Exposure to veratridine (50 microM) for 1 h resulted in a progressive rise in [Na+]i (DeltaFNa = 64 +/-22%) and [Ca2+]i (DeltaFCa = 44 +/- 14%) over 3 h. Increases in [Na+]i and [Ca2+]i were also observed during neuronal exposure to the Na+ ionophore monensin (50 microM). Subcellular confocal immunofluorescence quantification of alpha3 catalytic Na+-K+ pump subunits showed that a veratridine-induced rise in [Na+]i was accompanied by a significant increase in pump density in both membrane and cytoplasmic compartments, by 39 and 54%, respectively. Similar results were also obtained in experiments when neurones were treated with monensin. A fluorescent 9-anthroylouabain binding assay detected a 60 and 110% increase in phosphorylated (active) pumps after veratridine and monensin exposure, respectively. During the entire experiment, application of ouabain or veratridine alone induced little cell swelling and death, but pump inhibition in cells pre-loaded with Na+ led to rapid cell swelling and necrosis. The above results indicate that a persistent influx of Na+ may trigger rapid enhancement of pump synthesis, membrane redistribution and functional activity. However, these compensatory mechanisms failed to prevent persistent Na+ accumulation.

Voltage-activated K+ channels and membrane depolarization regulate accumulation of the cyclin-dependent kinase inhibitors p27(Kip1) and p21(CIP1) in glial progenitor cells

Neural cell development is regulated by membrane ion channel activity. We have previously demonstrated that cell membrane depolarization with veratridine or blockage of K+ channels with tetraethylammonium (TEA) inhibit oligodendrocyte progenitor (OP) proliferation and differentiation (); however the molecular events involved are largely unknown. Here we show that forskolin (FSK) and its derivative dideoxyforskolin (DFSK) block K+ channels in OPs and inhibit cell proliferation. The antiproliferative effects of TEA, FSK, DFSK, and veratridine were attributable to OP cell cycle arrest in G1 phase. In fact, (1) cyclin D accumulation in synchronized OP cells was not affected by K+ channel blockers or veratridine; (2) these agents prevented OP cell proliferation only if present during G1 phase; and (3) G1 blockers, such as rapamycin and deferoxamine, mimicked the anti-proliferative effects of K+ channel blockers. DFSK also prevented OP differentiation, whereas FSK had no effect. Blockage of K+ channels and membrane depolarization also caused accumulation of the cyclin-dependent kinase inhibitors p27(Kip1) and p21(CIP1) in OP cells. The antiproliferative effects of K+ channel blockers and veratridine were still present in OP cells isolated from INK4a-/- mice, lacking the cyclin-dependent kinase inhibitors p16(INK4a) and p19(ARF). Our results demonstrate that blockage of K+ channels and cell depolarization induce G1 arrest in the OP cell cycle through a mechanism that may involve p27(Kip1) and p21(CIP1) and further support the conclusion that OP cell cycle arrest and differentiation are two uncoupled events.

Extracellular potassium concentration regulates proliferation of immature cerebellar granule cells

The present study examines the effect of depolarizing potassium concentrations on the proliferation of immature rat cerebellar neurons. Cells inoculated in serum free medium and 5 mM KCl (5 K) showed a high degree of 3H-thymidine incorporation that decreased 24-48 h after plating as differentiation began. During the first 24 h after inoculation, cells grown in high potassium (25 K), showed a 34 +/- 3% increase (mean +/- S.E.M., n = 12) in 3H-thymidine incorporation as compared with the values observed in 5 K. After 24 h in vitro, cells grown in 25 K showed 23 +/- 3% (mean +/- S.E.M., n = 3) less DNA synthesis than those inoculated in 5 K. The increase in DNA synthesis due to 25 K was blocked by MgCl2 and nifedipine, but not by omega-conotoxin GVIA, suggesting that it is mediated by a Ca2+ influx via voltage-gated calcium channels (VGCC) of the L-subtype. High potassium-induced cell proliferation was blocked by the mitogen-activated protein kinase kinase (MEK1) inhibitor (PD98059, 75 microM). The number of neurons counted after 48 h in vitro in 25 K was 35-100% above of the number obtained with 5 K and this increase also was blocked by MgCl2 and nifedipine. These data support the hypothesis that depolarizing activity during neurogenesis plays a role in the modulation of cerebellar granule cells proliferation.

K+ channel expression and cell proliferation are regulated by intracellular sodium and membrane depolarization in oligodendrocyte progenitor cells

The effects of a variety of antiproliferative agents on voltage-dependent K+ channel function in cortical oligodendrocyte progenitor (O-2A) cells were studied. Previously, we had shown that glutamate receptor activation reversibly inhibited O-2A cell proliferation stimulated by mitogenic factors and prevented lineage progression by attenuating outward K+ currents in O-2A cells. We now show that the antiproliferative actions of glutamate receptor activation are Ca2+-independent and arise from an increase in intracellular Na+ and subsequent block of outward K+ currents. In support of this mechanism, agents that acted to depolarize O-2A cells or increase intracellular sodium similarly had an antiproliferative effect, attributable at least in part to a reduction in voltage-gated K+ currents. Also, these effects were reversible and Ca2+-independent. Chronic treatment with glutamate agonists was without any long-term effect on K+ current function. Cells cultured in elevated K+, however, demonstrated an upregulation of inward rectifier K+ currents, concomitant with an hyperpolarization of the resting membrane potential. This culture condition therefore promoted a current phenotype typical of pro-oligodendroblasts. Finally, cells chronically treated with the mitotic inhibitor retinoic acid displayed a selective downregulation of outward K+ currents. In conclusion, signals that affect O-2A cell proliferation do so by regulating K+ channel function. These data indicate that the regulation of K+ currents in cells of the oligodendrocyte lineage plays an important role in determining their proliferative potential and demonstrate that O-2A cell K+ current phenotype can be modified by long-term depolarization of the cell membrane.

A quantitative analysis of the role of K+ channels in mitogenesis of neuroblastoma cells

The role of K+ channels in mitogenesis was studied on mouse neuroblastoma cells by analysing the effects of various chemical agents on the whole-cell K+ current and the cell proliferation. The outward current recorded during depolarizations on undifferentiated cells was made up of a small and slow inactivating K+ current. Foetal calf serum, which is mitogen for neuroblastoma cells, shifted in opposite directions by 7-10 mV peak activation and steady-state inactivation-voltage curves of the K+ current. The resulting effect was an increase in K+ conductance. The effect on the resting K+ flux of the classical K+ channel blockers tetraethylammonium, 4-aminopyridine and capsaicin, the anticancer agent tamoxifen, the heat inactivated serum and the increase in external K+ concentration were estimated from their effects on the K+ current. The cell proliferation was determined under the same conditions. The results indicate that cell proliferation is correlated to the resulting K+ flux. It is supposed that mitogenesis is controlled by the intracellular Na+ concentration which, via a cell volume regulation, is a function of the K+ flux. A quantitative model is developed on the basis of these hypotheses.

Modulation of nuclear rotation in neuronal interphase nuclei by nerve growth factor, by gamma-aminobutyric acid, and by changes in intracellular calcium

Nuclear rotation (NR) is typically measured as motion of nucleoli within nuclei of cells in vitro. This occurs in cycling cells. However, its observation in neurons arrested in interphase indicates that mechanisms related to mitosis are not a prerequisite. We have recently shown that NR occurs in three dimensions within the nuclear space, that it occurs within the space delineated by the outer nuclear membrane and that it includes chromatin domains in addition to nucleoli and have postulated that this motion of chromatin domains is related to changes in gene expression. We now show that exposure of dorsal root, sensory neurons in vitro to nerve growth factor (NGF) or to gamma-aminobutyric acid (GABA), agents which alter gene expression, and to agents causing redistribution of calcium, such as EGTA and the calcium ionophore A23187, significantly alters NR. The NGF increased the mean rate of NR and did so at a time after exposure when activity of RNA polymerases have been shown to rise. Exposure to GABA resulted, within minutes, in shifts of the nucleolus within the three-dimensional space of the nucleus, associated in some neurons with significant, sigmoidal increases in the rate of NR. The calcium ionophore A23187 as well as chelation of extracellular calcium with EGTA similarly increased rates. Importantly, excess calcium, with EGTA remaining present, returned NR of all nucleoli to rates not different from controls. This indicates that the increase in NR seen with EGTA is specific to the chelation of calcium and not an nonspecific response to EGTA. It is difficult to link the action of agents which alter gene expression or transmembrane ion balance with changes in NR. Nevertheless, in support of our hypothesis, the results presented here show that agents known to alter gene expression, alter NR in a temporally coincident manner and that they do so, possibly, by calcium-dependent mechanisms.

Membrane potentials and sodium channels: hypotheses for growth regulation and cancer formation based on changes in sodium channels and gap junctions

Based on several convergent lines of investigation, we make two hypotheses which are sufficient to explain many phenomena of growth regulation in both normal and cancer cells. 1. The first hypothesis is that there is a boundary or threshold of resting cell membrane potential that separates normal resting cells from normal proliferating cells and cancer cells. The basis for this in existing literature values of membrane potentials in resting and proliferating cells is established. A discussion of how these differences in potential can be explained focuses on changes in sodium permeability and internal sodium concentration. Of many sodium transfer mechanisms, the sodium channel is emphasized and how increased intracellular transfer may stimulate DNA synthesis. The effects of changing cell junctions, in particular gap junctions, on membrane potentials is also discussed, as well as the indications of altered junctions in tumor cells. The linking factor of the effects of growth factors on both cell junctions and sodium permeability leads to the second hypothesis. 2. Since growth initiation and inhibition involve sodium channels and gap junctions, several phenomena can be explained by postulating that they are one and the same entity. The basis for this hypothesis in existing descriptions of functional and structural similarities is outlined. The possible interchange of these elements in the cell cycle lead to several corollaries consequent to the conservation of their total number. The formation of gap junctions would consume sodium channels, decrease sodium permeability and stop DNA synthesis. Conversely, growth factors may competitively bind to channel-connexon elements, cleave gap junctions, liberate sodium channels to increase sodium permeability, and trigger DNA synthesis. Alterations in the structure of gap junction-channel elements in tumor cells would be sufficient to explain some carcinogenesis.

Effects of dimethylsulfoxide on membrane currents of neuroblastoma x glioma hybrid cell

Giga-ohm seal whole cell recording technique was used to examine ionic currents changes induced by dimethylsulfoxide (DMSO) in neuroblastoma X glioma hybrid NG 108-15 cells. DMSO (0.5-1%) reversible blocks sodium, potassium and calcium currents and shifts by about 6 mV the sodium inactivation curve towards more negative voltages.

Serum factors affect Na+ pump activity and DNA synthesis in cultured cerebellar neural cells

In neurone-enriched cultures derived from early postnatal rat cerebellum and maintained in serum-free medium, addition of serum (10% FCS) evoked a rapid increase in Na+ pump activity (as measured by ouabain-sensitive 86Rb accumulation) by activation of a Na+/H+ exchanger. This effect did not occur with cultured cerebellar astrocytes. In contrast, exposure to serum increased DNA synthesis ([3H]thymidine incorporation) in both cultured cerebellar astrocytes and in the neurone-enriched cultures. However, in the latter cultures this effect was shown by autoradiography to be due to contaminating astrocytes. Thus, in cultured cerebellar neural cells an enhancement of intracellular Na+ accumulation by serum factors may not be linked to initiation of DNA synthesis. Furthermore, raising intracellular Na+ by ouabain exposure actually decreased neural cellular DNA synthesis.

Intracellular sodium activity in the sea urchin egg during fertilization

Fertilization of the sea urchin egg triggers a sequence of events that are necessary for metabolic derepression and stimulation of proliferation. Changes in intracellular Ca2+ and H+ activities regulate the sequence of events. Intracellular sodium activity is important in the regulation of the intracellular activities of these ions and may directly regulate metabolic events. Using Na+-sensitive microelectrodes we continuously measured the intracellular Na+ activity during fertilization. The results show an increase in intracellular sodium activity medicated by two pathways of Na+ entry: Na+ permeability increase during the fertilization potential and initiation of Na+-H+ exchange activity. Intracellular Na+ activity returned to unfertilized levels by 20 min after fertilization. This decrease was inhibited by ouabain, which suggests the activation of Na+, K+ ATPase during fertilization.

Role of Ca2+ in serum-stimulated Na+ influx in normal and transformed cells

Previous studies in human foreskin fibroblasts suggested that the mechanism by which serum stimulates Na+ influx is via a Ca2+-calmodulin-mediated event. In the present experiments in normal WI-38 cells (human lung fibroblasts), both the intracellular Ca2+ antagonist 8-(N,N-diethylamino)-octyl-3,4,5-trimethoxybenzoate (TMB-8) and the potent calmodulin antagonist trifluoperazine (TFP) blocked serum-stimulated Na+ influx [TMB-8 concentration causing half-maximal inhibition (Ki) = 15 microM and TFP Ki = 10 microM]. Similar results were obtained in Swiss 3T3 cells. In contrast, in transformed WI-38 or Swiss 3T3 cells neither TMB-8 nor TFP had any effect on serum-stimulated Na+ influx (TMB-8 Ki greater than 100 microM and TFP Ki greater than 100 microM). In addition, when 45Ca2+ efflux measurements were made on normal and transformed cells, serum stimulated significant 45Ca2+ efflux (P less than 0.05) from WI-38 and Swiss 3T3 cells, while having no effect on 45Ca2+ efflux from simian virus 40 (SV40)-WI-38 or SV40-Swiss 3T3 cells. However, an elevation of intracellular Ca2+ can stimulate Na+ influx, since it was found that A23187 mimicked the effects of serum in both normal and transformed cells. These results suggest that the Ca2+-calmodulin-mediated event, which is thought to be involved in serum-stimulated Na+ influx in normal cells, may be bypassed or overridden in transformed cells.

Desensitization of the serum effect on Na+ influx in cultured human fibroblasts

Stimulation of an amiloride-sensitive Na+ influx pathway, which mediates Na+/H+ exchange, has been postulated to be an important step in the initiation of DNA synthesis in quiescent human fibroblasts. If the elevation of intracellular Na+ or the alkalinization of intracellular pH resulting from the activation of this system is a trigger for subsequent mitogenic events, then its inactivation may also be important to cellular functions. We investigated the duration of the activation of Na+ influx by serum in human foreskin fibroblasts (HSWP). It was found that activation of Na+ influx by 10% serum was transient, declining with a t 1/2 = 15 min. Similarly, the Na+ content of the cells rose rapidly following serum addition and decreased with a t 1/2 = 15 min. In addition, both the lys-bradykinin- and the vasopressin-stimulated Na+ influx and Na+ content declined with a t 1/2 of approximately 15 min. Similar results were obtained using both Tris-buffered and Hepes-buffered, amino-acid-free EMEM. Finally, the above experiments were repeated under conditions normally used to assess the mitogenic response of cells. It was found that in cells arrested in G0 by serum deprivation in CO2-buffered EMEM, the serum activated Na+ flux was also transient with a t 1/2 of approximately 20 min. The desensitization of cells to serum could be readily (t 1/2 = 20') reversed by a subsequent incubation of cells in serum-free medium. Stimulation of Na+ influx by both the divalent cation ionophore A23187 and the phospholipase activator melittin in also desensitized rapidly, suggesting the process is independent of receptor downregulation. The desensitization during serum preincubation occurred in both low Na+ and low pH medium suggesting that the process is not due to negative feedback on the transport system via a rise in cellular Na+ concentration or a rise in intracellular pH. Although the mechanism of desensitization is at present not known, it is likely to be a physiologically important event.

High-resolution 23Na-NMR studies of human erythrocytes: use of aqueous shift reagents

Aqueous shift reagents were used to clearly distinguish intra-and extracellular 23Na-nuclear magnetic resonance (NMR) signals in samples consisting of whole blood or suspensions of washed human erythrocytes (both fresh and outdated). The lanthanide chelates Dy(PPP)2(7-) and Tm( TTHA )3- were used to shift the extracellular signals upfield, and Dy( TTHA )3- and Tm(PPP)2(7-) were similarly used to shift extracellular resonances downfield. The absolute intensities of the signals were used along with the measured hematocrit to simultaneously determine the intra- and extracellular Na+ concentrations. The results were generally within 5% of the values determined by more time-consuming centrifugation-flame emission photometry measurements on the same samples. Thus the 23Na-NMR signals from both intra- and extracellular cations suffer no NMR invisibility within experimental error. The lower level of intracellular Na+ in fresh erythrocytes (less than 12 mM) is easily distinguished from the higher level (approximately 30 mM) in erythrocytes that have been stored (in the cold) outside the body for some weeks.

Vanadium ions stimulate DNA synthesis in Swiss mouse 3T3 and 3T6 cells

Vanadyl sulfate and sodium orthovanadate in the concentration range between 5 and 50 microM are shown to be mitogenic for quiescent cultures of Swiss mouse 3T3 and 3T6 cells. The compounds caused a striking shift in the dose-response for the effect of serum on [3H]thymidine incorporation and DNA synthesis. In the absence of serum the effect of vanadium was greatly potentiated by insulin. Vanadium ions produced no more than additive increases in [3H]thymidine incorporation when combined with epidermal growth factor, cholera toxin, or phorbol 12-myristate 13-acetate. Both vanadium compounds stimulated ouabain-inhibitable 86Rb+ uptake, indicating that the vanadium ions increase, rather than inhibit, Na+/K+ pump activity in the intact cell. Neither vanadium compound had any effect on cellular cAMP under a variety of different conditions. The mitogenic effect of the vanadium compounds was similar to that of colchicine. Taxol, which stabilizes cytoplasmic microtubules, prevented the stimulation of DNA synthesis by vanadium.

Efflux of 45Ca2+ from human fibroblasts in response to serum or growth factors

Previous studies have indicated that intracellular Ca2+ is involved in fetal bovine serum (FBS)- or growth factor (GF)-stimulated Na+ influx in human foreskin fibroblasts (HSWP). In the present study, 45Ca2+ efflux from serum-deprived HSWP cells was measured in response to 10% FBS or GF [lys-bradykinin, vasopressin, epidermal growth factor, and insulin]. Efflux data were analyzed using a computer program and the best fit indicated the presence of three Ca2+ compartments: a compartment (C1) with a very fast turnover rate, one (C2) with a fast turnover rate, and one (C3) with a slow turnover rate. When serum-deprived cells were treated with 10% FBS, efflux from C2 and C3 increased significantly (p less than 0.05). Similar effects on efflux were observed when serum-deprived cells were treated with individual GFs. Combination of the four GFs produced a higher stimulation than any single factor and a response that was equal to that of FBS. On the other hand, when cells were serum-treated in the presence of the intracellular Ca2+ antagonist, B-(N-N,diethylamino)-octyl-3,4,5-trimethoxybenzoate (TMB-8), 45Ca2+ efflux from C2 was substantially reduced. Finally, when cells were treated with the Na+ transport inhibitor amiloride, there was no significant effect on serum-stimulated Ca2+ efflux. These results are consistent with a FBS- or GF-induced mobilization of Ca2+ that can be blocked by intracellular Ca2+ antagonists, and support the hypothesis that the action of these agents on Na+ influx may be via their effects on intracellular Ca2+.

Factors influencing calcium-induced terminal differentiation in cultured mouse epidermal cells

Mouse epidermal cells can be grown as a proliferating monolayer in medium containing 0.02-0.1 mM calcium. Terminal differentiation of these cells with formation of cornified cells and cell death is induced by elevating calcium in the medium to greater than 0.1 mM. A variety of agents were studied as potential modifiers of this calcium-induced terminal differentiation. Other than calcium, no cation tested was active in inducing or preventing epidermal maturation. Modifiers of calcium or sodium fluxes, local anesthetics and protease inhibitors were also without effect. Modulators or analogues of cyclic nucleotides did not influence epidermal differentiation, and cyclic nucleotide levels did not change significantly in the first 10 min after increasing calcium. Effective inhibition of calcium-induced differentiation, as estimated by morphology, ultrastructure and cornified envelope formation, was seen with the divalent cation ionophore A23187 and the Na+K+ATPase inhibitor ouabain. The well-known effects of ouabain on intracellular sodium and potassium suggested the possible involvement of these ions in the program of calcium-induced epidermal maturation. The increase in medium calcium produced an elevation of both intracellular sodium and potassium within 12-24 hours. The calcium-induced increase in intracellular potassium appears to be the more relevant of these changes since the increase was blocked by both ouabain and A23187. Other inhibitors of calcium-induced differentiation, including harmaline, 8(diethylamino)octyl 3,4,5-trimethoxybenzoate hydrochloride (TMB-8) and low potassium medium, also blocked the rise of intracellular potassium. The five inhibitors had no consistent effect on intracellular sodium. Thus, elevated intracellular potassium may be necessary for the later stages of epidermal differentiation. However, neither ouabain nor A23187 affected the assembly of desmosomes, the earliest ultrastructural change noted after increasing medium calcium. This rapid change in cell-cell contact, beginning within minutes after calcium elevation, appears to be independent of changes in sodium and potassium, but may instead be modulated by increased calcium at the cell surface.

Lys-bradykinin stimulates Na+ influx and DNA synthesis in cultured human fibroblasts

The effect of Lys-bradykinin on net Na+ influx in serum-deprived cultured human fibroblasts (HSWP cells) was measured. It was found that Lys-bradykinin stimulates net Na+ influx with a K1/2 of 1 nM. When Lys-bradykinin was combined with epidermal growth factor, vasopressin and insulin, the net Na+ influx stimulated was comparable with that measured in response to 10% serum. The above combination of growth factors also was found to stimulate DNA synthesis to 92% of the serum-stimulated levels in HSWP cells and to support cell growth over a period of 6 days. In addition, it was observed that the Na+ influx stimulated by Lys-bradykinin or by the combination of four growth factors was completely inhibited by the amiloride analog benzamil. Thus Lys-bradykinin presumably stimulates the same Na+ transport system as is stimulated by serum. Finally, the present results suggest that an increase in Na+ influx always accompanies DNA synthesis in HSWP cells. On the basis of these observations, it can be hypothesized that Na+ influx is a necessary event to stimulate DNA synthesis.

A survey of intracellular Na+ and K+ of various normal, transformed, and tumor cells

Intracellular concentrations of Na+ and K+ of various normal, transformed, and tumor cell cultures were analyzed by atomic absorption spectrophotometry. In all of the cultures analyzed there were markedly different concentrations in the transformed and tumor cells when compared to their normal counterparts. Although increased Na+ was often observed, there were no definitive correlations between absolute ion concentrations, or Na+:K+ ratios, and cell transformation.

The effects of nitrogen mustard (HN2) on activities of the plasma membrane of PC6A mouse plasmacytoma cells

Nitrogen mustard, HN2 (10(-5) M), inhibited the transport of the potassium congener 86rubidium into PC6A mouse plasmacytoma cells by 45% after a 4 hr incubation at 37 degree in vitro. HN2 (10(-3) M) had a rapid effect on the profile of 86rubidium transport into PC6A cells when added simultaneously with the 86rubidium whereas a monofunctional analogue of HN2((2-chloroethyl)dimethylamine) had no effect at 10(-3) M. The transport of the amino acid analogues alpha-aminoisobutyric acid and cycloleucine into PC6A cells was inhibited by 19% and 5% respectively after a 4 hr incubation with 10(-5) M HN2. The results suggest that the activity of plasma membrane Na+K+-ATPase may be affected by HN2. This enzyme may play a pivotal role in controlling cell growth and division. Crude cell membrane preparations from PC6A cells had variable Na+K+-ATPase activity which was possibly due to contamination with mitochondrial Mg2+-ATPase. Incubation of a crude cell membrane preparation in the presence of 40 nM dicyclohexylcarbodiimide gave constant Na+K+-ATPase activity which was inhibited by 44% on incubation with HN2 (10(-3) M) for 0.5 hr. The monofunctional analogue of HN2 inhibited this preparation by only 7% under the same conditions. It is suggested that inhibition of Na+K+-ATPase by HN2 may be an important facet of its cytotoxic activity.