Signalling events employed in the hypertonic activation of cation channels in HeLa cells.

In the present study, the signalling network behind the hypertonic activation of cation channels in HeLa cells was analysed by use of various inhibitors. Channel activation was monitored in whole-cell patch-clamp recordings, whereas the role of the channel in cell volume regulation was determined by electronic cell sizing. It is found that channel activation and volume control probably employs tyrosine kinases, G-proteins, PLC, PKC and p38MAP kinase, and that the process appears to depend on an intact actin skeleton. In contrast, RhoA, PI 3-kinase, ERK 1/2, JNK 1/2 as well as the exocytotic insertion of channels into the plasma membrane are likely not part of the signalling machinery.     

Monovalent cation metabolism and cytopathic effects of poliovirus-infected HeLa cells.

To better understand the significance of 22Na+ accumulation by poliovirus-infected HeLa cells (C. N. Nair, J. W. Stowers, and B. Singfield, J. Virol. 31:184, 1979), measurements of cellular Na+, K+, and Cl- contents, volume, and density were carried out at intervals after infection. In addition, the rates of 22Na+ washout from infected and control cells were determined. Starting at around 3 h postinfection, the Na+ content of infected cells increased, whereas the K+ content decreased progressively, resulting in a net loss in the monovalent cation content decreased progressively, resulting in a net loss in the monovalent cation content per cell. The loss in cellular chloride content exceeded that in monovalent cation content. The kinetics of 22Na+ washout from infected and control cells revealed the presence of an extra Na+ compartment in infected cells. A net loss in the monovalent cation activity of infected cells was indicated by the loss of cell water as reflected in a decrease in cell volume and an increase in cell density. In spite of a net loss in monovalent cation content per cell, Na+ accumulation coupled with cell shrinkage resulted in substantial increases in the concentrations of not only Na+ but also K+. The results suggested a possible role for tonicity change in the morphological lesions of poliovirus cytotoxicity.     

Guanidine-sensitive Na+ accumulation by poliovirus-infected HeLa cells.

The Na+ content of poliovirus-infected HeLa S3 cells increased during the late phase of virus replication, after virus inhibition of host cell protein synthesis and in coincidence with late viral functions. Guanidine hydrochloride blocked the rise in Na+ content, whereas the antiguanidine agent choline fully reversed the guanidine block. Expression of one or more late viral functions was essential for Na+ accumulation to occur because accumulation was inhibited by cycloheximide or guanidine added to the infected culture during the late phase. Increased adenosine triphosphatase activity appears to be primarily responsible for Na+ accumulation by virus-infected cells.     

Factors influencing ADP-ribosylation differences between chromosomal proteins of interphase and metaphase HeLa cells

Fundamental differences were previously discovered in the ADP-ribosylation of proteins from metaphase chromosomes and interphase nuclei of HeLa cells. The number of modified nonhistone species was found to be dramatically reduced for metaphase chromosomes. An investigation has therefore been made of factors which could influence, and therefore be responsible for, this change in ADP-ribosylation during the cell cycle. Modified proteins were detected by autoradiography of sodium dodecyl sulfate-polyacrylamide gels containing mitotic and interphase samples from permeabilized cells that had been incubated with [32P]NAD. Whole cells showed a difference between interphase and metaphase similar to that for isolated nuclei and chromosomes. Chromosome expansion, disruption of chromosomes or nuclei, DNA nicking, and cellular growth activity significantly changed the incorporation of 32P label. Inhibitors of protein, RNA, and DNA synthesis did not, however, greatly affect ADP-ribosylation. The pattern of labeled species was not altered by the presence of nonradioactive NAD, though the extent of labeling declined. The results were not artifactually due to the procedure used to arrest cells in mitosis. Similar results were found with Novikoff rat hepatoma cells, demonstrating that the difference between metaphase and interphase is not confined to HeLa cells.     

Inhibition of hypertonicity-induced cation channels sensitizes HeLa cells to shrinkage-induced apoptosis.

Hypertonicity-induced cation channels (HICCs) are an effective mechanism of regulatory volume increase (RVI), which is a restoration process of cell volume after osmotic cell shrinkage, in HeLa cells. Since a reduction of cell size is a hallmark of programmed cell death, we tested whether a blockage of HICCs sensitizes HeLa cells to shrinkage-induced apoptosis by using proliferation assays, apoptosis assays, and patch-clamp recordings. Under control conditions, increasing osmolality up to 600 mosmol/kg-H2O had no detectable effect on either cell proliferation or apoptosis. With HICCs blocked by flufenamate and Gd3+, however, a significant reduction of proliferation and a stimulation of apoptosis were observed. Both effects exhibited virtually identical sensitivity profiles to osmotic stress as well as to flufenamate and Gd3+. Moreover, the observed concentration dependency of flufenamate and Gd3+ on proliferation and apoptosis was in excellent accordance with that on HICC inhibition. These results suggest that persistent cell shrinkage may function as a specific signal in the induction of apoptosis. In addition, they provide further evidence for the interplay of proliferation vs. apoptosis and the actual role that mechanisms of cell volume regulation do play in these processes.     

Measurement of plasma membrane potential in isolated rat hepatocytes using the lipophilic cation, tetraphenylphosphonium: correction of probe intracellular binding and mitochondrial accumulation.

The lipophilic cation tetraphenylphosphonium (TPP+) has been extensively utilized as the probe for the membrane potential (Vm) in various cells. For application to mammalian cells, however, two serious problems require resolution: (1), correction of TPP+ binding to intracellular constituents and (2), estimation of the considerable TPP+ accumulation in mitochondria. We propose here a simple corrective method for the TPP+ binding and its accumulation. TPP+ distribution is assumed as: (1), two compartments (a cytosolic and a mitochondrial space); (2), a proportional relationship between TPP+ bound amount and its unbound concentration in each compartment. We theoretically derived the simple equation: Vm = - RT/F ln(C/Mphys ratio/C/Mabol ratio) where R, T and F have their usual thermodynamic significance. Here, the C/M ratio is defined as the ratio of TPP+ concentration of apparent intracellular to extracellular space. The suffixes phys and abol, respectively, mean the physiological and solely Vm-abolished conditions. This equation was checked with hepatocytes, because estimating hepatocytes Vm with TPP+ distribution is not considered possible because of the relatively high mitochondrial content. The selective Vm abolition was achieved by permeabilization with 20 microM of amphotericin B. The Vm value was, thus, estimated to be -38.6 +/- 0.3 mV, compatible with those obtained with microelectrodes in other laboratories. Vm in hepatocytes is composed of transmembrane K+ diffusion potential (-20.6 +/- 0.3 mV) and electrogenic Na+/K(+)-ATPase (-19.6 +/- 0.4 mV). Addition of rheogenic L-alanine caused a transient but significant depolarization (from control to -34 +/- 0.3 mV). These results taken together indicate that hepatocyte Vm can be accurately determined with the present simple method, so that it may possibly be applicable to the evaluation of Vm in other mammalian cells.     

The mechanism by which cyclopiazonic acid potentiates accumulation of tetraphenylphosphonium in cultured renal epithelial cells

Cyclopiazonic acid (CPA), a fungal metabolite produced by Aspergillus and Penicillium, potentiated the accumulation of the quaternary cation tetraphenylphosphonium (TPP+) in cultured pig renal epithelial cells. This is the first report of a natural product mediating the tight and apparently nonsaturable binding of a membrane potential probe to subcellular compartments. The potentiated TPP+ accumulation was dose dependent, nonsaturable, and not a result of hyperpolarization across the plasma membrane. Cyclopiazonic acid-potentiated accumulation was completely inhibited by the protonophore carbonylcyanide-m-chlorophenylhydrazone (CCCP). Dinitrophenol (DNP), tetrahexylammonium (THA), and n-ethylmaleimide (NEM) were also effective inhibitors of CPA-potentiated TPP+ accumulation. Although CPA-potentiated TPP+ uptake appeared to be energy dependent, TPP+ efflux (in the presence of CCCP) from CPA-treated cells was incomplete and most of the TPP+ accumulated in the presence of CPA was tightly bound. Dicyclohexylcarbodiimide (DCC), verapamil, and monensin also stimulated TPP+ accumulation, but the TPP+ which accumulated in the presence of these compounds was not tightly bound. As with controls, fractionation of cells which had accumulated TPP+ in the presence of DCC, verapamil, or monensin always resulted in near complete recovery (greater than 93%) of the TPP+ in the cytosolic fraction, whereas with CPA, greater than 88% of the TPP+ was recovered noncovalently bound in the plasma membrane and mitochondrial fractions. These results are consistent with the hypothesis that CPA-potentiated TPP+ accumulation is a result of potentiated partitioning of TPP+ into the plasma membranes and mitochondria of LLC-PK1 cells.     

Stimulation of protein accumulation in HeLa cells by inhibitors of DNA replication. Ferritin

Incubation of HeLa cells for 24 h with either hydroxyurea (HU), aphidicolin (APHI), thymidine (T) or butyrate (BU), substances used to inhibit replication and accumulate cells at the G1/S interphase, followed by the elimination of the inhibitor and the addition of iron to the growth medium, results in an immediate (HU, APHI, T) or slightly delayed (BU) increased accumulation (18-24-fold higher than the basal level) of ferritin. Under the same experimental circumstances, 5-azacytidine is without effect. As a result of the action of these inhibitors on the structure of DNA, it is proposed that ferritin genes remain accessible to RNA polymerase allowing the accumulation in the cytoplasm of mature ferritin mRNA ready to be mobilized by iron for the production of ferritin molecules.     

Monovalent cation dependence of tissue plasminogen activator synthesis by HeLa cells

HeLa cells synthesize and secrete increased levels of tissue plasminogen activator (tPA) when incubated for 18 h with 10-20 nM phorbol myristate acetate. This response was inhibited by a number of conditions which affect intracellular Na+ and K+ concentrations. Removing extracellular Na+, while maintaining isotonicity with choline+, reduced the secretion of both functional and antigenic tPA in a linear fashion. A series of cardiac glycosides and related compounds strongly inhibited tPA secretion with the following rank order of potency: digitoxin = ouabain greater than digoxin greater than digitoxigenin greater than digoxigenin greater than digitoxose greater than digitonin. These compounds also inhibited cellular Na+/K+-ATPase activity over an identical concentration range. Two compounds which selectively increase cellular permeability to K+, valinomycin, and nigericin, strongly inhibited tPA secretion, with IC50 values of approximately 50 nM. In contrast, monensin, which selectively increases cellular permeability to Na+, was much less active. Valinomycin, but not nigericin, also inhibited cellular Na+/K+-ATPase activity. Phorbol myristate acetate, 5-20 nM, increased Na+/K+-ATPase activity up to 2-fold and tPA secretion up to 15-fold. We conclude that the secretion of tPA by HeLa cells treated with phorbol myristate acetate proceeds via a mechanism which requires extracellular Na+ and a functional Na+/K+-ATPase ("sodium pump") enzyme.     

Factors influencing recombinant human lysozyme extraction and cation exchange adsorption

Human lysozyme has numerous potential therapeutic applications to a broad spectrum of human diseases. This glycosidic enzyme is present in tears, saliva, nasal secretions, and milk--sources not amendable for commercial development. Recently, a high expression level of recombinant human lysozyme (0.5% dry weight) was achieved in transgenic rice seed. This paper evaluates the effects of pH and ionic strength on rice protein and lysozyme extractability, as well as their interactions with the strong cation-exchange resin, SP-Sepharose FF. The extraction conditions that maximized lysozyme yield and the ratio of extracted human lysozyme to native rice protein were not optimal for lysozyme adsorption. The conditions that gave the highest extracted lysozyme to native protein ratio were pH 4.5 and 100 mM NaCl in 50 mM sodium acetate buffer. At pH 4.5, salt concentrations above 100 mM NaCl reduced the lysozyme-to-protein ratio. The best conditions for lysozyme adsorption were pH 4.5 and 50 mM sodium acetate buffer. Lysozyme extraction and subsequent adsorption at pH 4.5 and 50 mM NaCl was an acceptable compromise between lysozyme extractability, adsorption, and purity. The primary recovery of human lysozyme from pH 6 extracts, irrespective of ionic strength, was inferior to that using pH 4.5 with unacceptably low saturation capacities and lysozyme purity. High purity was achieved with a single chromatography step by adjusting the pH 4.5 extract to pH 6 before adsorption. The disadvantage of this approach was the drastically lower saturation capacity compared to adsorption at pH 4.5.     

Lactoferrin induces growth arrest and nuclear accumulation of Smad-2 in HeLa cells

Lactoferrin (Lf) is a multifunctional glycoprotein. Due to its anti-inflammatory and anti-cancer properties and the resulting therapeutical potential, lactoferrin is at present focus of a variety of research areas. The regulation of cell growth represents one of the prominent performances of lactoferrin. In this study we found lactoferrin to inhibit proliferation of the human epithelial cancer cell line HeLa. The extent of this growth inhibition was comparable to the one induced by the transforming-growth-factor-beta-1 (TGFβ1). In contrast to other cell lines where lactoferrin stimulates growth, lactoferrin failed to activate the MAP kinases ERK1/2 or p38 in HeLa cells. However, by immunocytochemistry and cell fractionation experiments, we found that lactoferrin is capable of activating the TGFβ/Smad-2 pathway. The nuclear accumulation of Smad-2 induced by Lf was comparable in magnitude to the one induced by TGFβ1.     

Cyclic AMP accumulation in HeLa cells induced by cholera toxin. Involvement of the ceramide moiety of GM1 ganglioside.

The influence of ceramide composition on the rate of GM1 association to HeLa cells has been investigated by incubating the cells in the presence of either native ganglioside or molecular species carrying highly homogeneous long chain base moieties, fractionated from native GM1. The GM1 ganglioside species carrying the unsaturated C18 long chain base moiety proved to have the fastest rate of association, whereas the saturated species carrying 20 carbon atoms had the slowest rate. After having increased the GM1 cell content (65-fold) by incubation with the various ganglioside species, the cells were incubated with cholera toxin and the time course of cyclic AMP accumulation was monitored. Remarkable differences among cells enriched with the various molecular species were found in the duration of the lag time preceding the accumulation of cyclic AMP, the shortest being displayed by the unsaturated C18 species. Moreover, the amount of cyclic AMP accumulated after a given time of incubation with cholera toxin was significantly higher when the C18:1-GM1 species was present than with native GM1. Fluorescence anisotropy experiments, carried out using the probe 1,3-diphenylhexatriene, show that the GM1 ganglioside ceramide moiety was also modifying the cell membrane fluidity of the host.     

Pitfalls in the measurement of membrane potential in yeast cells using tetraphenylphosphonium

The uptake of the lipophilic cation tetraphenylphosphonium (Ph₄P⁺) by Saccharomyces cerevisiae was measured using yeast grown on glucose and harvested either at the logarithmic or at the stationary phase of growth. When yeast was collected at the stationary phase, Ph₄P⁺ uptake proceeded steadily during several hours until an equilibrium was reached. When yeast was collected in the logarithmic phase of growth, a biphasic uptake was observed. The second phase of uptake began when the glucose of the incubation medium had been exhausted. From experiments in the presence of cycloheximide or chloramphenicol it is concluded that the second phase of Ph₄P⁺ uptake is dependent on the synthesis of some protein(s) repressed by glucose but unrelated with the existence of functional mitochondria. The addition of compounds which collapse the membrane potential provokes an efflux from the yeast cells of the Ph₄P⁺ accumulated both during the first phase and the second phase of uptake. It is concluded that accumulation of Ph₄P⁺ in yeast cells is a complex process and that Ph₄P⁺ cannot be used to give a quantitative measure of the yeast plasma membrane potential.