Perturbation of Na+ and K+ gradients in human fibroblasts incubated in unsupplemented saline solutions

Induction of BGT-1 and amino acid system A transport activities in endothelial cells exposed to hyperosmolarity

We studied the responses to hypertonicity of cultured endothelial cells from swine pulmonary arteries. In 0.5 osmol/kgH(2)O medium, initial cell shrinkage was followed by a regulatory volume increase (RVI), complete after 1 h, concomitant with an increase in cellular K(+) content. Then the activity of amino acid transport System A increased, accompanied by an accumulation of ninhydrin-positive solutes (NPS), reaching a peak at approximately 6 h. The subsequent decline in System A activity was paralleled by an induction of the betaine-GABA transporter (BGT-1), detected as increases of BGT-1 mRNA and of transport activity, which peaked at approximately 24 h. Inhibitors of transcription or translation prevented induction of both transport activities. The increased expression of BGT-1, which involved activation of "tonicity-responsive enhancer," was inhibited by 5 mM extracellular betaine. Cellular K(+) concentration gradually declined after the accumulation of NPS and during the induction of BGT-1. This very effective adaptation to hypertonicity suggests it has a physiological role.

Functional characterization of the carnitine transporter defective in primary carnitine deficiency

Primary carnitine deficiency is an autosomal recessive disorder caused by defective carnitine transport which impairs fatty acid oxidation and manifests as nonketotic hypoglycemia or skeletal or heart myopathy. Here we report the functional characterization of this transporter in human fibroblasts. Carnitine enters normal cells by saturable and unsaturable routes, the latter corresponding to Na+-independent uptake. Saturable carnitine transport was absent in cells from patients with primary carnitine deficiency. In control cells, saturable carnitine transport was energized by the electrochemical gradient of Na+. Carnitine uptake was not inhibited by amino acid substrates of transport systems A, ASC, and X-AG, but was inhibited competitively (in potency order) by butyrobetaine > carnitine > palmitoylcarnitine = acetylcarnitine > betaine. Carnitine uptake was also noncompetitively inhibited by verapamil and quinidine, inhibitors of the multidrug resistance family of membrane transporters, suggesting that the carnitine transporter may share a functional motif with this class of transporters. A high-affinity carnitine transporter was present in kidney 293 cells, but not in HepG2 liver cells, whose carnitine transporter had a Km in the millimolar range. These result indicate the presence of multiple types of carnitine transporters in human cells.

Insulin stimulates the Na+,K(+)-ATPase and the Na+/K+/Cl- cotransporter of human fibroblasts

Insulin regulation of K+ (Rb+) transport was investigated in cultured human fibroblasts using a non-radioactive method which allows the simultaneous determination of the intracellular concentration of other monovalent cations. Insulin stimulated Rb+ influx through the Na+,K(+)-ATPase and the Na+/K(+)/Cl- cotransporter in human fibroblasts. Insulin stimulation was very rapid and maximal effect was observed within 10 min. Insulin stimulation of Rb+ uptake via the Na+,K(+)-ATPase and the Na+/K(+)/Cl- cotransporter was dose-dependent, with half-maximal stimulation at 2-3 nM of hormone. Insulin increased the V(max) of both transporters involved, affecting only minimally their Km. In other cells, insulin stimulates the Na+,K(+)-pump by increasing Na+ availability through the Na+/H+ exchanger. In human fibroblasts, insulin stimulation of Na+,K(+)-ATPase occurred in the presence of ethyl-isopropyl amiloride, an inhibitor of the Na+/H+ exchanger, and without sustained changes in intracellular[Na+]. By contrast, insulin action on Na+,K(+)-ATPase was impaired by the protein kinase inhibitors staurosporine and genistein. These results indicate that, in human fibroblasts, insulin stimulates both the Na+,K(+)-ATPase and the Na+/K+/Cl- cotransporter, that stimulation of the Na+,K(+)-ATPase occurs in the absence of changes in intracellular [Na+], and that protein kinase activity is essential for this insulin action.

Quinine sensitive changes in cellular Na+ and K+ homeostasis of COS-7 cells caused by a lipophilic phenol red impurity

An impurity of phenol red (PRI) has been shown to markedly alter the intracellular Na+ and K+ homeostasis of several cell types. The effect of PRI seems to involve intracellular Ca(++)-dependent mechanisms. Using COS-7 cells as a model, we further characterized the mechanism of action of PRI by measuring cellular Na+/K+ contents and 86Rb+ efflux. Similar to human skin fibroblasts, in COS-7 cells calmodulin inhibition moderated the cationic transport effects of PRI. A TMB-8 dependent intracellular Ca++ pool does not seem to be involved in these transport events. We found no evidence for participation of the transcriptional-translational machinery in the effect of PRI. Both quinine and quinidine are able to prevent nearly all changes caused by PRI in the cellular Na+/K+ contents and 86Rb+ efflux. Although phenol red contained multiple impurities by high performance liquid chromatography (HPLC), phenolphthalein, a structurally close relative of phenol red, was free of any detectable contamination. Phenolphthalein elicited qualitatively similar transport changes to those observed during exposure to PRI. Regardless of the exact mechanism of action, we propose that the as yet unidentified substance is not a cellular toxin, rather it is a cationic transport modulator. Directly or indirectly, it may interact with the cellular Ca++/calmodulin system and activate some quinine/quinidine sensitive transport processes. This transport process is likely to be a Ca(++)-sensitive K+ channel but, due to the lack of specificity of quinine and quinidine, other transport mechanisms must be also considered. The chemical nature of PRI may be similar to phenolphthalein.

Lipophilic impurity of phenol red is a potent cation transport modulator

Previously, we described substantial alterations in the Na+ and K+ homeostasis of human skin fibroblasts following removal of fetal bovine serum (FBS). Herein, we report that FBS removal per se does not cause any cellular ionic changes unless a lipophilic impurity of commercial phenol red preparations is present. This substance accelerates 86Rb+ efflux four to seven times, causes a four to eight time increase in cellular Na+, and a 40-70% reduction in cellular K+ contents. FBS (10%) or albumin (0.8%) appears to bind the impurity thus inhibiting its action. The increased cellular Na+ and decreased K+ contents do not return to baseline within 4 hours following the removal of the phenol red extract. However, albumin completely reverses the cellular cationic changes that develop during a 2 hour exposure of the cells to the free substance. The reversibility of its action by albumin suggests that the substance exerts its effect on or within the cell membrane and not intracellularly. Among seven different cell lines tested the 86Rb+ efflux from, and the Na(+)-K+ contents of, COS-7 and Hs68 cells also responded to unpurified phenol red in a way similar to human fibroblasts. The amount of the phenol red contaminant is manufacturer dependent. As little as 0.5 microM phenol red, from one vendor, was sufficient to elicit response in the 86Rb+ efflux. Given that the impurity is unlikely to be more than a small fraction of phenol red, it seems to be a potent ionic transport modulator. Based on these results, the presence of commercial phenol red in serum-free growth or test media, including the increasing variety of chemically defined culture media, should be considered as a potential confounding factor in measurements that depend on intracellular Na(+)-K+ homeostasis. The findings of such earlier studies may need to be reconsidered if the cells were exposed to unbound phenol red. We recommend that, until the manufacturers further refine their product, phenol red be purified by ether extraction before its use. The evaluation of the potential physiologic or pharmacologic relevance of this potent cation transport modulator awaits its isolation.

An impurity in phenol red opens an ion channel in cultured human cells

Human fibroblast, bladder carcinoma, and breast carcinoma cells in commercial serum-free media or balanced salt solutions rapidly lose K+ and gain Na+. This rapid K+ loss is caused by one or more impurities in phenol red. Adding serum or albumin to media or to balanced salts prevents K+ loss. Quinine also prevents part of this loss in fibroblasts and breast carcinoma cells, suggesting that the impurity acts on an ion channel.

Characterization of Na(+)-K+ homeostasis of cultured human skin fibroblasts in the presence and absence of fetal bovine serum

Previously, we demonstrated that removal of fetal bovine serum (FBS) from the medium of human skin fibroblasts resulted in an accelerated 86Rb+ washout, decreased cellular K+, and increased Na+ contents. In the present study we examined the mechanism underlying these changes. The efflux rate constant for 86Rb+, and the cellular contents of Na+ and K+ were measured. Verapamil (K1/2 = 15 microM) and chlorpromazine (K1/2 = 1 microM) reduced by approximately 70% the increased 86Rb+ washout evoked by FBS removal. The effect of the two drugs was additive at low, but not high, concentrations. Verapamil and chlorpromazine also attenuated the decrease in cellular K+ content and prevented the increase in cellular Na+ content associated with FBS depletion. Bumetanide (50 microM) was only partially effective in offsetting the enhanced 86Rb+ efflux and was completely without any effect on the cellular Na+ and K+ changes induced by FBS removal. In the presence of FBS, A-23187 produced a slight and transient increase of the 86Rb+ washout. The protein kinase C activator phorbol 12-myristate 13-acetate enhanced the 86Rb+ efflux in FBS-containing medium for a prolonged period but this increase was only a fraction of that caused by serum removal. Cellular Na+ and K+ contents were not changed by the phorbol ester. We conclude that FBS removal raises the cellular Na+ content, and enhances 86Rb+ efflux, through a calmodulin-dependent pathway activated by calcium influx.

A simple method for evaluation of Rb+ transport and Na(+)-K+ pump stoichiometry in adherent cells

This report describes a method based on flame photometry for the evaluation of transmembrane Rb+ transport and Na(+)-K+ pump stoichiometry in adherent cells. In monolayers of cultured fibroblasts, the rates of 86Rb+, an isotope widely used as a K+ congener in transport studies, and nonradioactive Rb+ influx were equivalent when measured in the absence and presence of the transport inhibitors ouabain and bumetanide. Ouabain- and bumetanide-sensitive Rb+ fluxes were also equal with the two methods. Flame photometry allowed the simultaneous determination of intracellular [Na+] in the same sample in which Rb was measured. The incubation of human fibroblasts with ouabain for 5 min promoted a significant increase in intracellular [Na+]. Under appropriate experimental conditions, the ratio between the rate of ouabain-promoted increase in intracellular [Na+] and ouabain-sensitive Rb+ influx was 1.4, close to the theoretical value of 1.5 corresponding to a Na(+)-K+ pump stoichiometry of 3 Na+ extruded from the cell in exchange for 2 K+.

The transport of L-glutamine into cultured human fibroblasts

The transport of L-glutamine has been studied in diploid human fibroblasts in culture. Mathematical discrimination by nonlinear regression, competition analysis, and conditions varying the relative contribution of the various mediations have been used to characterize the systems engaged in the inward transport of this amino acid. The adopted criteria showed that L-glutamine enters the fibroblast by the Na(+)-dependent systems ASC and A and by a Na(+)-independent route identified as system L. The relative contribution of these agencies to the total saturable uptake of glutamine varied with the concentration of the amino acid and with the nutritional state of the cell. At amino acid concentrations approaching those encountered in human plasma: (1) system ASC represented the primary mediation for entry of L-glutamine in human fibroblasts; (2) the contribution of system A was lower, though significant, in unstarved repressed cells and became predominant in starved derepressed cells; (3) the Na(+)-dependent system L accounted for less than one-fifth of glutamine uptake in either nutritional condition. The changes in the relative contribution of the various systems to the uptake of glutamine as a function of its concentration may have implications in pathophysiology under conditions associated with enhanced glutamine concentrations in the extracellular fluids.

Correlation between the lipophilicity of substituted phenols and their inhibition of the Na+/K+-ATPase of Chinese hamster ovary cells

The Na+/K+-ATPase of Chinese Hamster Ovary (CHO) cells, a plasma membrane bound protein was used as a test system to evaluate the toxicity of several phenol derivatives on membranes. Taking only 2 physico-chemical parameters into consideration, viz., the logarithm of the octanol/water partition coefficient as an indicator for the lipophilicity and the sigma-Hammett constant as a measure for the polarity of the phenol substitutes, it was possible to predict the toxicity with high significance. A multivariate regression analysis calculated a correlation coefficient of 0.99. The results confirm studies performed in our laboratory on cytotoxicity and on functional membrane proteins of fungal and mammalian cells [1,2], suggesting a common mechanism of toxicity by the action of hydrophobic xenobiotics on biomembranes. Taking into account the different sensitivities of the test systems, Quantitative Structure-Activity Relationship (QSAR) analyses could help to explain the basic toxicity of several classes of environmental chemicals.

Quiescent fibroblasts in a cellular model system

Quiescent fibroblasts are non-dividing cells in a reversible postmitotic state induced by lowering the serum concentration of the medium (e.g. from 10% to 0.3%). Three to seven days after lowering the serum concentration only minor metabolic changes will take place in the cells. During this period the quiescent fibroblasts can be used experimentally in a model system for various periods of time.