Further studies on the effect of chloroquine on the uptake, metabolism and intracellular translocation of [35S]cystine in cystinotic fibroblasts

The present study uses the lysosomotropic drug chloroquine to investigate the mechanisms by which exogenous [35S]cystine is able to label the intracellular (intralysosomal) cystine pool(s) in cystinotic fibroblasts. When cystinotic fibroblasts were labelled for short periods of time (8 h or less), chloroquine (20 microM) inhibited the labelling of the intracellular cystine pool(s). However, when the cells were labelled for longer periods of time (24 h or more) chloroquine stimulated the labelling of the intracellular cystine pool(s). The short-term effect was selectively abolished when the cells were washed free of chloroquine, while the long-term effect was selectively abolished when the medium was depleted of cystine. Two routes of translocation of exogenous cystine to the lysosomes could be defined. One route was fast, had a low capacity, was inhibited by chloroquine and increased with increasing medium pH, while the other route was slow, had a high capacity, was stimulated by chloroquine and was more active at low pH. The former pathway probably consisted of plasma membrane transport of cystine into the cytosol followed by direct or indirect transport into the lysosomes. The latter route possibly consisted of pinocytosis with fusion of the cystine-containing pinosomes with lysosomes.     

Uptake of cystine by cystine-depleted fibroblasts from patients with cystinosis

[³⁵S]L-cystine uptake was measured in cultured skin fibroblasts from patients with nephropathic cystinosis, pretreated with cysteamine to deplete their cystine pools. The uptake was greater in the cystinotic cells than in normal cells. The data suggest that the enhanced [³⁵S]-cystine uptake observed in cystinotic cells is not a consequence of disulfide exchange with stored cystine and may be related to the underlying abnormality in this enigmatic disorder.     

Cysteamine depletes cystinotic leucocyte granular fractions of cystine by the mechanism of disulphide interchange.

Cystinotic lysosome-rich leucocyte granular fractions, loaded with [35S]cystine, were exposed to different cystine-depleting agents. During a 30 min incubation at 37 degrees C, untreated cystinotic granular fractions lost negligible [35S]cystine when corrected for lysosome rupture. Granular fractions exposed to 0.1 mM-cysteamine lost 64% of their initial cystine, and hexosaminidase activity was decreased by 10%. This was accompanied by the formation of high concentrations of [35S]cysteine-cysteamine mixed disulphide within the granular-fraction pellet, and, in the presence of N-ethylmaleimide, increasing amounts of [35S]cysteine-N-ethylmaleimide adduct outside the granular fraction. In separate experiments, [35S]cystine exited cystinotic leucocyte lysosomes at a negligible rate (half-times 199 and 293 min), but [35S]cysteine-cysteamine mixed disulphide exhibited substantial egress (half-times 66 and 88 min) and was recovered intact outside the granular-fraction pellet. We conclude that cysteamine depletes lysosomes of cystine by participating in a thiol-disulphide interchange reaction to produce cysteine and cysteine-cysteamine mixed disulphide, both of which traverse the cystinotic leucocyte lysosomal membrane.     

Cystinotic and normal fibroblasts: Differential susceptibility to cysteine toxicity in vitro

Summary Extracellular cysteine concentrations between 0.5 and 2.5 mM resulted in death of normal but not cystinotic cells grown in Eagle's minimal essential medium containing supplemental fetal bovine serum and antibiotics. Differential cell survival was determined by viable cell counting using Trypan Blue dye exclusion. In cocultivation experiments of [³H]thymidine-labelled cystinotic fibroblasts with nonradioactive normal fibroblasts, autoradiography confirmed the selective survival of cystinotic cells in medium containing 1 mM cysteine. At this concentration of 1 mM cysteine, intracellular cystine content increased slightly in surviving normal cells but not in cystinotic cells, which normally contain a high level of intracellular cystine. This comparative resistance of cystinotic fibroblasts to elevated extracellular cysteine concentrations forms the basis for an in vitro selective system for these mutant human cells. Further exploration of this resistance phenomenon may well expand the understanding of the molecular defect in cystinotic cells.     

Effect of selenium compounds on selenium content, growth and 35S-cystine metabolism of skin fibroblasts from normal and cystinotic individuals.

Kidney samples from children with the inborn metabolic disease cystinosis contain 4 times more selenium (Se) than do kidney samples from normal individuals (p = 0.1). However, when cultured skin fibroblasts from cystinotic patients and normal control individuals are incubated in Se-D,L-methionine, Se-D,L-cystine, Se-cystamine X HCl, Se-urea, selenite or in medium without added selenium, only the cystinotic fibroblasts grown in Se-urea or selenite (SeO3=) contain more selenium than do the corresponding normal cells (p less than 0.05). In both types of cultured fibroblasts, the order of descending toxicity per ppm selenium is: Se-urea greater than Se-cystamine greater than Se-cystine greater than or equal to SeO3= much greater than Se-methionine. High (apparently toxic) concentrations of Se-urea and Se-cystamine lower the elevated intracellular free (nonprotein) cystine content of cystinotic fibroblasts to less than 60% of control values; at lower concentrations, these compounds raise the cystine content of these cells to over 140% of control values. Appropriate concentrations of SeO3=, Se-cystine and Se-methionine also elevate the free cystine content of the cystinotic cells. During a 75 minute incubation in 35S-cystine, the incorporation of 35S into the acid precipitable (protein) fraction of both cell types is significantly inhibited by Se-cystamine (approximately 55% control; p less than 0.05). The incorporation of 35S-cystine into glutathione is inhibited by Se-cystine (approximately 40% control) in both fibroblast types (p less than 0.05). In cystinotic cells, Se-cystamine significantly reduces incorporation of 35S-cystine into the cystine pool (40% control) as does SeO3= (67% control; p less than 0.05). Protein and glutathione synthesis in cystinotic fibroblasts are more strongly inhibited by Se-cystine and SeO3=, respectively, than in normal fibroblasts (p less than 0.05). These studies demonstrate that selenium compounds exhibit a different sequence of toxicity in fibroblasts than in the intact animal and that some previously unreported metabolic effects (i.e. inhibition of glutathione synthesis) may contribute to their toxicity.     

Impaired clearance of free cystine from lysosome-enriched granular fractions of I-cell-disease fibroblasts.

Cultured fibroblasts from patients with I-cell disease (mucolipidosis II) accumulate excessive amounts of free cystine, similarly to cells from patients with nephropathic cystinosis, a disorder of lysosomal cystine transport. To clarify whether the intralysosomal accumulation of cystine in I-cell-disease fibroblasts was due to a defective disposal mechanism, we measured the rates of clearance of free [35S]cystine from intact normal, cystinotic and I-cell-disease fibroblasts. Loss of radioactivity from the two mutant cell types occurred slowly (t 1/2 = 500 min) compared with the rapid loss from normal cells (t 1/2 = 40 min). Lysosome-rich granular fractions isolated from three different cystine-loaded normal, cystinotic and I-cell-disease fibroblast strains were similarly examined for non-radioactive cystine egress. Normal granular fractions lost cystine rapidly (mean t 1/2 = 43 min), whereas cystinotic granular fractions did not lose any cystine (mean t 1/2 = infinity). I-cell-disease granular fractions displayed prolonged half-times for cystine disposal (mean = 108 min), suggesting that I-cell-disease fibroblasts, like cystinotic cells, possess a defective carrier mechanism for cystine transport.     

Unique characteristics of rat spleen lymphocyte, L1210 lymphoma and HeLa cells in glutathione biosynthesis from sulfur-containing amino acids

Suspensions of rat spleen lymphocyte, murine L1210 lymphoma and HeLa cells were partially depleted of glutathione (GSH) with diethyl maleate and allowed to utilize either [35S]methionine, [35S]cystine or [35S]-cysteine for GSH synthesis. Lymphocytes preferentially utilized cysteine, compared to cystine, at a ratio of about 30 to 1, which was not related to differences in the extent of amino acid uptake. Only HeLa cells displayed a slight utilization of methionine via the cystathionine pathway for cysteine and GSH biosynthesis. HeLa and L1210 cells readily utilized either cystine or cysteine for GSH synthesis. The three cell types accumulated detectable levels of intracellular cysteine glutathione mixed disulfide when incubated in a medium containing a high concentration of cystine. Various enzyme activities were measured including gamma-glutamyl transpeptidase, GSH S-transferase and gamma-cystathionase. These results support the concept of a dynamic interorgan relationship of GSH to plasma cyst(e)ine that may have importance for growth of various cell types in vivo.     

Effect of 2-mercaptoethanol on glutathione levels, cystine uptake and insulin secretion in insulin-secreting cells.

The role of glutathione (GSH) in the differentiated state of insulin-secreting cells was studied using 2-mercaptoethanol as a means of varying intracellular GSH levels. 2-Mercaptoethanol (50 microM) caused a marked increase of GSH in two rat insulinoma cell lines, RINm5F and INS-1, the latter being dependent on the presence of 2-mercaptoethanol for survival in tissue culture. The effect of 2-mercaptoethanol on GSH was shared by other thiol compounds. Since in other cell types 2-mercaptoethanol is thought to act on cystine transport, thereby increasing the supply of cysteine for GSH synthesis, we have studied [35S]cystine-uptake in INS-1 cells. At equimolar concentrations to cystine, 2-mercaptoethanol caused stimulation of [35S]cystine-uptake. The effect persisted in the absence of extracellular Na+, probably suggesting the involvement of the Xc- carrier system. INS-1 cells with a high GSH level, cultured 48 h with 2-mercaptoethanol, displayed a lower cystine uptake than control cells with a low GSH content. The effect of variations of the GSH levels on short-term insulin release was studied. No alteration of glyceraldehyde-induced or KCl-induced insulin release in RINm5F cells was detected. In contrast, both in islets and in INS-1 cells, a high GSH level was associated with a slightly lower insulin release. In INS-1 cells the effect was more marked at low glucose concentrations, resulting in an improved stimulation of insulin secretion. On the other hand, in islets, a decrease in the incremental insulin release evoked by glucose was seen. As in other cell types, oxidized glutathione (GSSG) was less than 5% of total GSH, and in INS-1 cells no change in the GSH/GSSG ratio was detected during glucose-induced or 3-isobutyl-1-methylxanthine-induced insulin release. In conclusion, 2-mercaptoethanol-dependent INS-1 cells, as well as RINm5F cells and islets of Langerhans, display a low capacity in maintaining intracellular levels of GSH in tissue culture without extracellular thiol supplementation; 2-mercaptoethanol possibly acts by promoting cyst(e)ine transport; changes in GSH levels caused a moderate effect on the differentiated function of insulin-secreting cells.     

Characteristics of cystine counter-transport in normal and cystinotic lysosome-rich leucocyte granular fractions.

Normal leucocyte lysosome-rich granular fractions exhibited counter-transport of cystine, confirming that cystine transport across the lysosomal membrane is carrier-mediated. The trans-activation of cystine transport was temperature-dependent but relatively independent of the external Na+ or K+ concentration in phosphate buffer. Counter-transport, measured as uptake of exogenous [3H]cystine, increased with increasing intralysosomal cystine content up to approx. 3 nmol of half-cystine/unit of hexosaminidase activity. The amount of [3H]cystine entering lysosomes loaded with unlabelled cystine decreased when unlabelled cystine was added to the extralysosomal medium. Lysosomal cystine counter-transport was stereospecific for the L-isomer. Cystathionine, cystamine and cysteamine-cysteine mixed disulphide gave evidence of sharing the lysosomal cystine-transport system, although at lower activity than cystine. Other tested amino acids, including arginine, glutamate and homocystine, were inactive in this system. Nine leucocyte lysosome-rich preparations from eight different cystinotic patients displayed virtually no counter-transport of cystine, conclusively establishing that a carrier-mediated system for cystine transport is dysfunctional in cystinotic lysosomes.     

pH-profile of cystine and glutamate transport in normal and cystinotic human fibroblasts

In the human recessive condition cystinosis, cystine transport has been reported to be normal in the plasma membrane but defective in the lysosome membrane. A possible explanation is that the transport systems at the two cellular sites are identical and that the defect in cystinosis affects the porter's ability to operate at the low pH of the lysosome. To test this hypothesis the uptake of 3H-labelled cystine and glutamate by normal and cystinotic human skin fibroblasts has been measured in vitro at pH 5.8, 6.5, 7.0, 7.4 and 8.0. Uptake of glutamate was more rapid than that of cystine. Uptake of cystine increased with increasing pH, but uptake of glutamate showed no marked pH-dependence. Transport in cystinotic cells was similar to that in normal cells, and similarly affected by pH. This finding is incompatible with the hypothesis proposed above. It is concluded that the cystine porters of the plasma membrane and the lysosome membrane are probably genetically distinct.     

Cysteamine restores glutathione redox status in cultured cystinotic proximal tubular epithelial cells

Recent evidence implies that impaired metabolism of glutathione has a role in the pathogenesis of nephropathic cystinosis. This recessive inherited disorder is characterized by lysosomal cystine accumulation and results in renal Fanconi syndrome progressing to end stage renal disease in the majority of patients. The most common treatment involves intracellular cystine depletion by cysteamine, delaying the development of end stage renal disease by a yet elusive mechanism. However, cystine depletion does not arrest the disease nor cures Fanconi syndrome in patients, indicating involvement of other yet unknown pathologic pathways. Using a newly developed proximal tubular epithelial cell model from cystinotic patients, we investigate the effect of cystine accumulation and cysteamine on both glutathione and ATP metabolism. In addition to the expected increase in cystine and defective sodium-dependent phosphate reabsorption, we observed less negative glutathione redox status and decreased intracellular ATP levels. No differences between control and cystinosis cell lines were observed with respect to protein turnover, albumin uptake, cytosolic and mitochondrial ATP production, total glutathione levels, protein oxidation and lipid peroxidation. Cysteamine treatment increased total glutathione in both control and cystinotic cells and normalized cystine levels and glutathione redox status in cystinotic cells. However, cysteamine did not improve decreased sodium-dependent phosphate uptake. Our data implicate that cysteamine increases total glutathione and restores glutathione redox status in cystinosis, which is a positive side-effect of this agent next to cystine depletion. This beneficial effect points to a potential role of cysteamine as anti-oxidant for other renal disorders associated with enhanced oxidative stress.     

Kinetic and pharmacological analysis of L-[35S]cystine transport into rat brain synaptosomes

The synaptosomal transport of L-[35S]cystine occurs by three mechanisms that are distinguishable on the basis of their ionic dependence, kinetics of transport and the specificity of inhibitors. They are (a) low affinity sodium-dependent transport (Km 463 +/- 86 microM, Vmax 185 +/- 20 nmol mg protein-1 min-1), (b) high affinity sodium-independent transport (Km 6.90 +/- 2.1 microM, Vmax 0.485 +/- 0.060 nmol mg protein(-1) min(-1)) and (c) low affinity sodium-independent transport (Km 327 +/- 29 microM, Vmax 4.18 +/- 0.25 nmol mg protein(-1) min(-1)). The sodium-dependent transport of L-cystine was mediated by the X(AG)- family of glutamate transporters, and accounted for almost 90% of the total quantity of L-[35S]cystine accumulated into synaptosomes. L-glutamate (Ki 11.2 +/- 1.3 microM) was a non-competitive inhibitor of this transporter, and at 100 microM L-glutamate, the Vmax for L-[35S]cystine transport was reduced to 10% of control. L-cystine did not inhibit the high-affinity sodium-dependent transport of D-[3H]aspartate into synaptosomes. L-histidine and glutathione were the most potent inhibitors of the low affinity sodium-independent transport of L-[35S]cystine. L-homocysteate, L-cysteine sulphinate and L-homocysteine sulphinate were also effective inhibitors. 1 mM L-glutamate reduced the sodium-independent transport of L-cystine to 63% of control. These results suggest that the vast majority of the L-cystine transported into synaptosomes occurs by the high-affinity glutamate transporters, but that L-cystine may bind to a site that is distinct from that to which L-glutamate binds. The uptake of L-cystine by this mechanism is sensitive to inhibition by increased extracellular concentrations of L-glutamate. The importance of these results for understanding the mechanism of glutamate-mediated neurotoxicity is discussed.     

Chloroquine,a novel inhibitor of amino acid transport by rat renal brush border membrane vesicles

Summary Chloroquine is an antimalarial and antirheumatic lysosomotropic drug which inhibits taurine uptake into and increases efflux from cultured human lymphoblastoid cells. It inhibits taurine uptake by rat lung slices and affects the uptake and release of cystine from cystinotic fibroblasts. Speculations on its mode of action include a proton gradient effect, a non-specific alteration in membrane integrity, and membrane stabilization. In this study, the effect of chloroquine on the uptake of several amino acids by rat renal brush border membrane vesicles (BBMV) was examined. Chloroquine significantly inhibited the secondary active, NaCl-dependent component of 10µM taurine uptake at all concentrations tested, but did not change equilibrium values. Analysis of these data indicated that the inhibition was non-competitive. Taurine uptake was reduced at all osmolarities tested, but inhibition was greatest at the lowest osmolarity. Taurine efflux was not affected by chloroquine, nor was the NaCl-independent diffusional component of taurine transport. Chloroquine (1 mM) inhibited uptake of the imino acids L-proline and glycine, and the dibasic amino acid L-lysine. It inhibited the uptake of D-glucose, but not the neutral-amino acids L-alanine or L-methionine. Uptake of the dicarboxylic amino acids, L-glutamic acid and L-aspartic acid, was slightly enhanced. With regard to amino acid uptake by BBMV, these findings may support some of the currently proposed mechanisms of the action of chloroquine but further studies are indicated to determine why it affects the initial rate of active amino acid transport.     

Chloroquine inhibits cyclization of squalene oxide to lanosterol in mammalian cells

Chloroquine inhibits the incorporation of [14C]acetate into sterols at a concentration of 10 microM or more in mouse L cells but has no effect on fatty acid synthesis and CO2 production from the same substrate even at a 10-fold higher concentration of the drug. The site of inhibition is distal to the formation of mevalonate since chloroquine also inhibits [14C]mevalonate metabolism to sterols and does not decrease the activity of 3-hydroxy-3-methylglutaryl coenzyme A reductase (EC 1.1.1.34) or the incorporation of [14C]acetate into the total nonsaponifiable lipids. Analyses by thin layer and high pressure liquid chromatography of the nonsaponifiable lipid fraction from cultures incubated with chloroquine show an accumulation of radioactivity in the region of squalene oxide. Identification of the radiolabeled lipid as squalene oxide has been established by: (a) its co-migration with the authentic squalene oxide standard; (b) its conversion into squalene glycol by acid hydrolysis; and (c) its further metabolism to desmosterol when chloroquine is removed from the medium. Addition of chloroquine (12.5-50 microM) to 20,000 X g supernatant fractions of mouse liver homogenates inhibits the incorporation of [14C]mevalonolactone into cholesterol and lanosterol, with corresponding increases of [14C]squalene oxides, in a concentration-dependent manner. It appears, therefore, that chloroquine inhibits the enzymatic step catalyzed by 2,3-oxidosqualene-lanosterol cyclase (EC 5.4.99.7). Incubation of cell cultures with chloroquine (50 microM) arrests cell growth and causes cell death after 1-3 days. However, simultaneous incubation of chloroquine with either cholesterol or lanosterol prevents cell death and permits cell growth. Uptake of chloroquine is not affected by exogenous sterols since intracellular chloroquine concentrations are the same in cells grown with or without added sterols. The cytotoxicity of chloroquine, under our experimental conditions, must, therefore, be due primarily to its inhibition of sterol synthesis. In addition to its well known effect on protein catabolism, chloroquine has been found to inhibit protein synthesis. The significance of these findings concerning the use of chloroquine in studying the regulation of 3-hydroxy-3-methylglutaryl coenzyme A reductase activity is discussed.     

Biosynthesis of intestinal microvillar proteins. Surface expression of aminopeptidase N is not affected by chloroquine

The effect of chloroquine on the biosynthesis of pig intestinal aminopeptidase N (EC 3.4.11.2) was studied by labelling with [35S]methionine in organ cultured mucosal explants. The lysosomotropic agent did not alter the molecular size of either the transient or the mature form of the enzyme and did not markedly influence the relative intracellular distribution of the two forms. The microvillar expression of aminopeptidase N during labelling periods of 80-120 min was found to be unaffected by chloroquine. Together these data indicate that pH neutralization of the acidic compartments of the cell bears no consequence on the intracellular transport of the newly synthesized microvillar enzyme. This suggests that the acidic compartments are not involved in the post-Golgi transport and that this, in turn, probably occurs via a constitutive rather than a regulated pathway.     

Glutathione metabolism in normal and cystinotic fibroblasts

Intracellular concentrations of glutathione and activities of the enzymes gamma-glutamylcysteine synthetase, glutathione synthetase, and gamma-glutamyl transpeptidase were measured in confluent cultured human fibroblasts cell lines from 14 normal cell lines and four cystinotic cell lines. gamma-Glutamyl transpeptidase had a wide range of variability while the glutathione synthetic enzymes, gamma-glutamylcysteine synthetase and glutathione synthetase, had narrower variations and also exhibited no apparent relationship to glutathione content. No differences in the activities of these enzymes were found between normal and cystinotic cells in confluent cell cultures. The activities of the above enzymes and the cell number and content of glutathione, cystine, DNA, and total protein in two normal and two cystinotic fibroblast cell lines were measured during growth. The following growth-dependency patterns were observed: (1) gamma-glutamylcysteine synthetase activity increased markedly in lag and early log phases in both normal and cystinotic cells and decreased rapidly to low confluent levels thereafter. (2) gamma-Glutamyl transpeptidase showed the same wide range of activity noted at confluency but activities decreased in the log phase of growth, a pattern also seen in cystinotic cells. (3) Glutathione synthetase activity remained relatively constant during growth of normal cells but exhibited a peak of activity during lag and early growth of cystinotic cells. (4) Comparative glutathione levels of normal and cystinotic cells were not significantly different and exhibited similar fluctuations with time. (5) The cystine content of normal and cystinotic cells unexpectedly rose to high levels in the lag phase, then decreased to 0.1 nmol 1/2 cystine/mg protein in normal cells and to 0.3 to 1.2 nmol 1/2 cystine/mg protein in cystinotic cells during the log phase. As confluency was approached, normal cell cystine remained at low levels while cystinotic cell cystine rose to characteristically high levels of 50- to 100-fold greater than normal cells at late confluency. These studies extend our understanding of the regulation of glutathione and cystine content in cultured fibroblasts and suggest that glutathione content is closely controlled throughout the cell cycle in the face of varying activities of its anabolic and catabolic enzymes.     

A cysteine-specific lysosomal transport system provides a major route for the delivery of thiol to human fibroblast lysosomes: possible role in supporting lysosomal proteolysis

Lysosomes constitute only 4% of the intracellular volume of a normal human fibroblast. When human fibroblasts are incubated for 2-5 min with 20 microM [35S]cystine in Krebs-Ringer phosphate solution at pH 7.4, a minimum of 50-60% of the total radioactivity taken up by the cells is found sequestered into the lysosomal compartment in the form of cysteine. A lysosomal transport system, highly specific for cysteine, appears to facilitate this rapid lysosomal cysteine sequestration. Time courses of [35S]cysteine uptake into isolated, Percoll-purified fibroblast lysosomes at pH 7.0 and 37 degrees C are linear for the first 4-5 min and attain a steady state by 10 min. Lysosomal cysteine uptake displays a Km of 0.05 mM at pH 7.0 and an activation energy of 21 kcal/mol, corresponding to a Q10 of 3.2. The role of this transport system in delivering cysteine into lysosomes is supported by its pH curve showing a slow rate of cysteine transport at the acidic pHs between 5 and 6, but then increasing sevenfold between pH 6 and 7.5 to be maximally active near the cytosolic pH of 7. Carrier mediation by this lysosomal transport route demonstrates a high specificity for cysteine as indicated by the inability of the following amino acids to significantly inhibit at 5 mM the lysosomal uptake of 0.035 mM [35S]L-cysteine: ala, ser, pro, val, gly, homocysteine, D- or L-penicillamine, arg, asp, or leu. Similarly, D-cysteine and beta-mercaptopropionate were poor inhibitors, suggesting that both the L-isomer and alpha-amino group of cysteine appear to be required for recognition by the cysteine-specific transport system. In contrast, cysteamine, which lacks an alpha-carboxyl group, was able to strongly inhibit lysosomal cysteine uptake. The physiological importance of this cysteine-specific lysosomal transport system may be to aid lysosomal proteolysis by delivering cysteine into the lysosomal compartment to (a) maintain the catalytic activity of the thiol-dependent lysosomal enzymes and (b) break protein disulfide bridges at susceptible linkages, thereby allowing proteins to unfold, facilitating their degradation.     

Interaction of a permeant maleimide derivative of cysteine with the erythrocyte glucose carrier. Differential labelling of an exofacial carrier thiol group and its role in the transport mechanism.

S-(Bismaleimidomethyl ether)cysteine (Cys-Mal) was synthesized as a probe for reactive thiol groups on the erythrocyte glucose carrier. Although Cys-Mal entered cells, its reaction with intracellular GSH prevented alkylation of endofacial membrane proteins, limiting its effect to the cell surface at concentrations below 5 mM. Cys-Mal irreversibly inhibited hexose transport half-maximally at 1.5 mM by decreasing the maximal rate of transport, with no effect on the affinity of substrate for the carrier. Reaction occurred with the outward-facing form of the carrier, but did not affect the ability of the carrier to change orientation. In intact cells, several exofacial proteins were labelled by [35S]Cys-Mal, including the band-4.5 glucose carrier, the labelling of which occurred on a single site sensitive to transport inhibitors. The reactive exofacial group was a thiol group, since both transport inhibition and band-4.5 labelling by Cys-Mal were abolished by the thiol-specific and impermeant compound 5,5'-dithiobis(2-nitrobenzoic acid). Selectivity for carrier labelling in cells was increased by a double differential procedure, which in turn allowed localization of the exofacial thiol group to the Mr 18,000-20,000 membrane-bound tryptic carrier fragment. In protein-depleted ghosts the exofacial thiol group was preferentially labelled at low concentrations of [35S]Cys-Mal, whereas with the reagent at 10 mM the Mr 26,000-45,000 tryptic carrier fragment was also labelled. Cys-Mal should be useful in the study of carrier thiol-group location and function.     

Enhanced channelling of sulphate through a rapidly exchangeable sulphate pool in response to stimulated glycosaminoglycan synthesis in pancreatic epithelial cells.

The ability of cells to decorate glycosaminoglycans (GAGs) with sulphate in highly specific patterns is important to extracellular matrix biogenesis and placing appropriate glycosulphated ligands on the cell surface. We have examined sulphate metabolism in two pancreatic duct epithelial cell lines - PANC-1 and CFPAC-1 (derived from a cystic fibrosis patient) with a view to understanding how pancreatic cells utilise intracellular sulphate. [35S]Sulphate uptake was rapid and reached near steady state levels within 10 min. However, the intracellular specific activity of [35S]sulphate for PANC-1 and CFPAC-1 reached only 35 and 10%, respectively, of the medium specific activity at 10 min. Therefore, sulphate appears to reside within two compartments; a rapidly exchangeable sulphate pool (RESP) and a slowly exchangeable sulphate pool (SESP). Reducing chloride in the medium, increased the specific activity of [35S]sulphate within cells and increased the size of the inorganic sulphate pool, suggesting that the RESP was enlarged. Sulphate pools were not different in size between the two cell lines in physiological NaCl. Increasing the size of the sulphate pool had no effect on [35S]sulphate:[3H]glucosamine ratios incorporated into glycosaminoglycans (GAGs); however, stimulating the synthesis of GAGs with 4-methylumbelliferyl-beta-d-xyloside, stably elevated [35S]:[3H] ratios. This was due to higher [35S]sulphate incorporation. [35S]Cysteine contributed less than 0.1% of the cells' sulphate requirements. We conclude that in the face of elevated demand for sulphate, pancreatic cells appear to channel a greater proportion through the RESP.     

Polyamines stimulate lysosomal cystine transport

Lysosomal cystine transport is a carrier-dependent process that, in isolated lysosomes, is stimulated by proton gradients, membrane potential, and millimolar concentrations of divalent cations. The importance of these regulatory factors in vivo is not well established. Polyamines were found to stimulate cystine transport in Percoll gradient purified rat liver lysosomes with spermidine greater than putrescine = cadaverine greater than spermine in order of effectiveness. Maximal stimulation was achieved with 500 microM spermidine. The effects of optimal concentrations of polyamines and divalent cations on cystine transport were not additive. Spermidine stimulated cystine efflux from lysosomes of cultured human diploid fibroblasts, but had no effect on lysosomes of cystinotic fibroblasts which have defective cystine transport. Spermidine did not accumulate within lysosomes in exchange for cystine, had no effect on lysosomal pH, had only slight effects on the lysosomal membrane potential, and had little effect on either methionine or tyrosine efflux. Polyamines are cellular cytoplasmic components that, in physiologic concentrations, stimulate lysosomal cystine transport.