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.     

Lysosomal cystine transport. Effect of intralysosomal pH and membrane potential

The regulation of lysosomal cystine transport was studied using cystine dimethyl ester-loaded lysosomes isolated from human diploid fibroblasts. Net efflux from normal fibroblast lysosomes was compared to that from lysosomes of cystinotic fibroblasts, which contain an inherited mutation decreasing lysosomal cystine transport. This exodus of cystine from normal fibroblast lysosomes was greater than from cystinotic fibroblast lysosomes. When lysosomes were incubated with both 5 mM MgCl2 and 2 mM ATP (Mg/ATP), the amount of lysosomal cystine lost from normal lysosomes doubled, but the amount of cystine lost from cystinotic lysosomes remained small. This effect of Mg/ATP on cystine loss from lysosomes isolated from normal fibroblasts was abolished when either carbonyl cyanide m-chlorophenylhydrazone or N-ethylmaleimide was present, suggesting that the effect of Mg/ATP was mediated by the action of a lysosomal proton-translocating ATPase. Addition of KCl, RbCl, or NaCl to normal lysosomes caused smaller increases in cystine exodus. A variety of experimental conditions altered lysosomal pH, membrane potential, and the cystine lost from normal fibroblast lysosomes. These same experimental conditions produced similar alterations in the lysosomal pH and membrane potential of cystinotic fibroblast lysosomes without a comparable alteration in cystine loss. These results have led us to propose a model in which the transport of cystine out of the normal lysosome is regulated by both the lysosomal membrane potential gradient and the transmembrane pH gradient.     

The effects of decreased growth temperature on the cystine content of cystinotic fibroblasts

Cystinotic fibroblasts transferred from 37 degrees C to 28 degrees C accumulated additional cystine over the period from 4 to 7 days of incubation at 28 degrees C, after which the additional cystine was lost; warming (to 37 degrees C) of cells with elevated cystine stores led to rapid cystine loss. These results, taken together with previously published data showing cystine release from cystinotic fibroblasts incubated at above-normal temperature, are interpreted as indicating the presence in the cystinotic fibroblast lysosome membrane of a cystine-porter whose efficacy is increased by an increase in membrane fluidity. This porter may be the residual activity of the cystine porter that is known to be deficient in cystinosis, or it may be a second as yet unrecognized porter. It is further proposed that this porter is responsible for the presumed efflux of cystine from cystinotic lysosomes.     

The effect of lysosomotropic detergents on the permeability properties of the lysosome membrane

Compounds such as N-dodecylimidazole and N-dodecylmorpholine kill cells in culture. Their cytotoxicity has been attributed to accumulation in lysosomes where protonation confers detergent properties resulting in membrane destabilization. This hypothesis has been tested by examining the ability of N-dodecylimidazole and N-dodecylmorpholine to decrease the latency of alpha-glucosidase in isolated rat liver lysosomes. No effect was observed. Nor was N-dodecylimidazole apparently able to increase the permeability of isolated rat liver lysosomes to L-alanine, as no diminution of the disruptive effect of L-alanine methyl ester was seen. N-Dodecylimidazole (10-20 micrograms per ml) caused lactate dehydrogenase release from cystinotic fibroblasts, but marginally toxic concentrations failed to induce cystine release, as might have been expected if lysosome membrane damage had occurred. It is concluded that the cytotoxic effects of lysosomotropic detergents may be mediated by a non-lysosomal mechanism.     

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.     

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.     

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.     

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.     

Stem cell microvesicles transfer cystinosin to human cystinotic cells and reduce cystine accumulation in vitro

Cystinosis is a rare disease caused by homozygous mutations of the CTNS gene, encoding a cystine efflux channel in the lysosomal membrane. In Ctns knockout mice, the pathologic intralysosomal accumulation of cystine that drives progressive organ damage can be reversed by infusion of wildtype bone marrow-derived stem cells, but the mechanism involved is unclear since the exogeneous stem cells are rarely integrated into renal tubules. Here we show that human mesenchymal stem cells, from amniotic fluid or bone marrow, reduce pathologic cystine accumulation in co-cultured CTNS mutant fibroblasts or proximal tubular cells from cystinosis patients. This paracrine effect is associated with release into the culture medium of stem cell microvesicles (100-400 nm diameter) containing wildtype cystinosin protein and CTNS mRNA. Isolated stem cell microvesicles reduce target cell cystine accumulation in a dose-dependent, Annexin V-sensitive manner. Microvesicles from stem cells expressing CTNS(Red) transfer tagged CTNS protein to the lysosome/endosome compartment of cystinotic fibroblasts. Our observations suggest that exogenous stem cells may reprogram the biology of mutant tissues by direct microvesicle transfer of membrane-associated wildtype molecules.     

Proton-translocating ATPase and lysosomal cystine transport

A proton-translocating ATPase was identified in highly purified lysosomes from Epstein-Barr virus-transformed human lymphoblasts. Activity of this ATPase caused acidification of highly purified, fluorescein isothiocyanate dextran-loaded lysosomes and correlated with the ATP-dependent efflux of lysosomal cystine. The lysosomal ATPase was distinct from mitochondrial F1-ATPase in its responses to a variety of inhibitors. Although ATP-dependent lysosomal cystine efflux is not demonstrable in cultured lymphoblasts from individuals with nephropathic cystinosis, ATPase activity and acidification in lysosomes from these cells is comparable to that in noncystinotic lysosomes. ATPase activity in lymphoblasts from normal individuals was 543 +/- 79 nmol/mg/min while in lymphoblasts from cystinotic individuals this activity was 541 +/- 25 nmol/mg/min. ATP-dependent acidification of lysosomes from normals was -0.5 +/- 0.1 pH units compared to -0.5 +/- 0.1 pH units in cystinotic lysosomes. Activity of the lysosomal proton-translocating ATPase is a necessary, but not sufficient, condition for lysosomal cystine efflux.     

Cystine accumulation in cystinotic fibroblasts from free and protein-linked cystine but not cysteine

The accumulation of cystine in cystinotic fibroblasts from free and protein-linked cystine has been investigated. Cystine is not accumulated from cysteine but is readily accumulated from cystine. The accumulation from free cystine does not occur as a result of pinocytosis or from the degradation of a rapidly metabolized protein pool. Further studies of the degradation of disulphide-containing proteins by these cells may aid understanding of the mechanisms of proteolysis.     

Abnormal mitochondrial autophagy in nephropathic cystinosis

Cystinosis, which is characterized by lysosomal accumulation of cystine in many tissues, was the first known storage disorder caused by defective metabolite export from the lysosome. The molecular and cellular mechanisms underlying nephropathic cystinosis, the most severe form, which exhibits generalized proximal tubular dysfunction and progressive renal failure, remain largely unknown. We used renal proximal tubular epithelial (RPTE) cells and fibroblasts from patients with three clinical variants of cystinosis: nephropathic, intermediate and ocular to explore the specific injury mechanism in nephropathic cystinosis. We demonstrate enhanced autophagy of mitochondria, increase in apoptosis and mitochondrial dysfunction in the nephropathic cystinosis phenotype. Furthermore, specific inhibition of autophagy results in significant attenuation of cell death in nephropathic cystinosis. This study provides ultrastructural and functional evidence of abnormal mitochondrial autophagy in nephropathic cystinosis, which may contribute to renal Fanconi syndrome and progressive renal injury.Key words: cystinosis, autophagy, mitochondria, kidney, lysosome, apoptosis, cell death, mitophagyCystinosis is an autosomal recessive metabolic disorder caused by mutations in the CTNS gene, which encodes a 7-transmembrane domain protein, cystinosin, a lysosomal cystine transporter. Cystinosis belongs to the family of lysosomal storage disorders (LSDs) characterized by the tissue accumulation of cystine crystals leading to multiple organ dysfunction. The three types of cystinosis, i.e., nephropathic (classic renal and systemic disease), intermediate (a late-onset variant of nephropathic cystinosis) and non-nephropathic (clinically affecting only the cornea) are allelic disorders caused by CTNS mutations. Children affected with nephropathic cystinosis present with the Fanconi syndrome and usually develop progressive renal failure within the first decade of life. The mechanism linking lysosomal cystine storage to pathological manifestations, in particular to the prominent proximal tubular defect and renal injury, remains unclear. Renal injury in nephropathic cystinosis may not simply be caused just by cystine accumulation, as disruption of the ctns gene in mice induces cystine storage in many tissues but does not result in signs of tubulopathy or renal failure; renal injury is not seen in other human forms of cystinosis and progressive renal injury occurs despite cystine depletion therapy.The purpose of our study was to investigate the specific mechanism leading to tubulopathy and end stage renal injury in nephropathic cystinosis. We used primary fibroblast and renal proximal tubular epithelial (RPTE) cells derived from patients with three clinical phenotypes of cystinosis. Our data show an abnormal increase in macroautophagy (hereafter referred to as autophagy), specific to the nephropathic variant of cystinosis. We also demonstrate that specific inhibition of autophagy rescues cell death in nephropathic cystinotic RPTE cells. Our results indicate that mitochondrial autophagy may be a critical mechanism contributing to renal Fanconi syndrome and progressive renal injury in nephropathic cystinosis.Abnormal autophagy was also recently observed in other types of lysosomal storage diseases (LSD). However, our study provides the first evidence supporting the extensive involvement of autophagy in nephropathic cystinosis pathogenesis. Abundant vacuolization and abnormal mitochondria are detected by electron microscopy (EM) in nephropathic cystinotic cells. Additionally, elevated levels of LC3-II and Beclin 1 are also observed in nephropathic cystinotic RPTE cells, indicating a role of Beclin 1-mediated autophagy in cystinosis. These results altogether establish an abnormal increase in autophagy in nephropathic cystinotic cells.Renal biopsies from patients with nephropathic cystinosis can reveal abnormally large mitochondria, but the relevance of this finding and other ultrastructural abnormalities is unclear. Our study further demonstrates a significant decrease in mitochondrial ATP generation with an increase in reactive oxygen species (ROS) in cystinotic cells. To further dissect the association of abnormal mitochondria with increased autophagy in cystinosis, we carefully examined the electron micrographs at higher magnifications. We discovered various stages of degradation of mitochondria by autophagy (hereafter referred to as mitophagy). To further validate mitophagy in cystinosis, we used an immunofluorescence (IF) approach to capture colocalization images of LC3, LAMP-2 (lysosomal marker) and ATP5H (mitochondrial marker). Intriguingly, an increase in LAMP-2 perinuclear staining is detected by IF assay in cystinotic cells. This observation may also denote enhanced active autophagy as LAMP-2 is involved in lysosomal biogenesis and/or the fusion between autophagosomes and lysosomes. Alternatively, LAMP-2 accumulation could be a manifestation of retarded autophagic flux in cystinotic cells. A decreased ability of lysosomes to fuse with autophagosomes has been reported in various LSDs. However, the colocalization of LC3 and LAMP-2 in nephropathic cystinotic RPTE cells argues against this possibility. Nevertheless, the possibility of autophagic flux blockade after autophagosome-lysosome fusion leading to detrimental effects is yet to be investigated. Interestingly, previously published EM reports of the renal biopsies of patients with nephropathic cystinosis show only the nucleus and a thin rim of cytoplasm as remnants in a proximal tubular cell, while mitochondria and lysosomes completely disappear.Conventionally, autophagy has been suggested as a cytoprotective mechanism to ensure cell survival during starvation. In contrast, several forms of cell death have been associated with the appearance of autophagic vesicles. To gain insight into the role of autophagy as regards to cell death or cell survival in nephropathic cystinosis, we used 3-methyladenine (3MA), a specific inhibitor of autophagy and assayed cell viability and apoptosis in cystinotic cells. Increased apoptosis has been previously reported in cultured cystinotic fibroblasts and RPTE cells. Treatment with 3MA in cystinotic cells significantly rescues cell death, thus suggesting a synergistic role of apoptosis and autophagy in cystinosis.In conclusion, as illustrated in Figure 1, we speculate that there is a multifaceted impact of autophagy in nephropathic cystinosis as follows: (1) the mechanism linking autophagy to lysosomal cystine or apoptosis in cystinotic cells could potentially be related to lysosomal membrane permeabilization (LMP), proposed as an early step in apoptosis in cystinosis. We hypothesize that abnormal induction of autophagy besides providing more cargo to be digested in the lysosomes, leads to increased fusion of autophagosomes with cystine-laden lysosomes, rendering them more sensitive to membrane destabilization, and thus making them readily enter the apoptotic pathway; (2) the second most important question is the link between abnormal mitochondria and mitophagy in cystinosis. A decreased level of cytosolic glutathione in cystinotic cells is one of the known factors responsible for generating damaged mitochondria. Our data also indicate an impairment of complex I activity, an increase in ROS and a decrease in mitochondrial ATP generation in cystinotic cells. We hypothesize that the abnormal induction of autophagy leads to depletion of mitochondria, forcing cells to enter the ‘starvation mode,’ thereby leading to an uncontrolled autophagy and cell death; (3) the third key question yet to be answered is the link between autophagy and renal injury in nephropathic cystinosis. Skeletal muscles and neuronal tissues are the primary organs where autophagy is physiologically enhanced. Recently, it has been shown that mouse kidneys exert a high level of autophagy under basal conditions, influencing the susceptibility to glomerular disease and renal failure. Thus, we postulate an organ- and tissue-specific effect of abnormally induced autophagy in nephropathic cystinosis, causing severe injury to kidneys leading to loss of renal function, ultimately culminating in end-stage renal disease.Open in a separate windowFigure 1A schematic view of the interplay between autophagy, abnormal mitochondria and cell death in cystinosis. Abnormal induction of autophagy, typically mitophagy, forces cells into a starvation mode leading to cell death; and renders cystine-laden lysosomes sensitive to lysosomal membrane permeabilization (LMP) making it readily enter the apoptosis pathway. A potential block in autophagic flux, after autophagosome-lysosome fusion, remains to be elucidated. Preferential severe kidney damage in nephropathic cystinosis may be due to the tissue- and organ-specific injury effect of autophagy.The recent progress in autophagy research has increased the need for additional studies so that we can fully understand the underlying pathological mechanisms and the significance of the lysosomal cell death axis in lysosomal storage disorders.     

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.     

Transformation of skin fibroblast cells of a cystinotic patient by simian virus 40: evidence for an establishment of a permanent cell clone which retains the original metabolism defect.

Human skin fibroblast cells derived from a juvenile patient with nephropathic cystinosis were transformed by simian virus 40. Transformed cell clones were isolated and established in tissue culture. In comparison to the parental cystinotic cells, the newly isolated, transformed cell clones had a higher plating efficiency, a modal chromosome number of 68, grew in soft agar, and showed a nuclear immunofluorescence typical for SV 40-specific tumor (T) antigen. The content of intracellular, unbound cystine in the transformed cell clone was of the same level (6.1 nmol 1/2 cystine/mg protein) as in the parental cystinotic cells (7.4 nmol). Control cells (SV 80 and WI-38) contained normal levels of cystine (0.31 and 0.47 nmol 1/2 cystine/mg protein). The growth characteristics make the transformed cystinotic cell clone suitable for large scale preparation of cellular constituents, i.e. lysosomes which seem to be affected in cystinotic patients.     

Glutathione precursors replenish decreased glutathione pool in cystinotic cell lines

Cystinosis is an inherited disorder due to mutations in the CTNS gene which encodes cystinosin, a lysosomal transmembrane protein involved in cystine export to the cytosol. Both accumulation of cystine in the lysosome and decreased cystine in the cytosol may participate in the pathogenic mechanism underlying the disease. We observed that cystinotic cell lines have moderate decrease of glutathione content during exponential growth phase. This resulted in increased solicitation of oxidative defences of the cell denoted by concurrent superoxide dismutase induction, although without major oxidative insult under our experimental conditions. Finally, decreased glutathione content in cystinotic cell lines could be counterbalanced by a series of exogenous precursors of cysteine, denoting that lysosomal cystine export is a natural source of cellular cysteine in the studied cell lines.     

Renal cell culture using autopsy material from children with cystinosis

Renal cell cultures were initiated using fresh autopsy material from two individuals with cystinosis, ages 5 and 8 yr. Cells obtained from collagenase treated autopsy material were grown in a selective kidney medium containing Coon's modified F12, 2.5% fetal bovine serum, transferrin, insulin, selenium, hydrocortisone, PGE1, and fibronectin. These cells had an epithelial appearance, formed domes, and were periodic acid-Schiff positive. Both tight junctions and microvilli were seen by electron microscopy. Fibroblasts had a cloning efficiency of zero in the selective medium and grew poorly compared to their growth in Coon's F12 with 10% fetal bovine serum. The lysosomal cystine content of the renal cells was greatly elevated and comparable to that of fibroblasts from cystinotic patients. Renal cell lysosomal cystine levels were only partially reduced by exposure to either pantethine or the aminothiol, cysteamine. However, exposure to either compound effectively depleted cystinotic cultured fibroblasts of their lysosomal cystine. Study of cultured renal material may have practical significance in pharmacologic considerations.     

Renal cell culture using autopsy material from children with cystinosis

Summary Renal cell cultures were initiated using fresh autopsy material from two individuals with cystinosis, ages 5 and 8 yr. Cells obtained from collagenase treated autopsy material were grown in a selective kidney medium containing Coon's modified F12, 2.5% fetal bovine serum, transferrin, insulin, selenium, hydrocortisone, PGE₁, and fibronectin. These cells had an epithelial appearance, formed domes, and were periodic acid-Schiff positive. Both tight junctions and microvilli were seen by electron microscopy. Fibroblasts had a cloning efficiency of zero in the selective medium and grew poorly compared to their growth in Coon's F12 with 10% fetal bovine serum. The lysosomal cystine content of the renal cells was greatly elevated and comparable to that of fibroblasts from cystinotic patients. Renal cell lysosomal cystine levels were only partially reduced by exposure to either pantethine or the aminothiol, cysteamine. However, exposure to either compound effectively depleted cystinotic cultured fibroblasts of their lysosomal cystine. Study of cultured renal material may have practical significance in pharmacologic considerations. This work was supported by Grants AM 01074-01, AM 18434, and GM 17702 from the National Institutes of Health, Bethesda, MD.     

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.     

Detection and characterization of carrier-mediated cationic amino acid transport in lysosomes of normal and cystinotic human fibroblasts. Role in therapeutic cystine removal?

The discovery of a trans-stimulation property associated with lysine exodus from lysosomes of human fibroblasts has enabled us to characterize a system mediating the transport of cationic amino acids across the lysosomal membrane of human fibroblasts. The cationic amino acids arginine, lysine, ornithine, diaminobutyrate, histidine, 2-aminoethylcysteine, and the mixed disulfide of cysteine and cysteamine all caused trans-stimulation of the exodus of radiolabeled lysine from the lysosomal fraction of human fibroblasts at pH 6.5. In contrast, neutral and acidic amino acids did not affect the rate of lysine exodus. trans-Stimulation of lysine exodus was observed over the pH range from 5.5 to 7.6, was specific for the L-isomer of the cationic amino acid, and was intolerant to methylation of the alpha-amino group of the amino acid. The lysosomotropic amine, chloroquine, greatly retarded lysine exodus, whereas the presence of sodium ion was without effect. The specificity and lack of Na+ dependence of this lysosomal transport system is similar to that of System y+ present on the plasma membrane of human fibroblasts. In addition, we find cystine exodus from the lysosomal fraction of cystinotic human fibroblasts to be greatly retarded as compared to that of normal human fibroblasts with half-times of exodus similar to those reported for the lysosomes of cystinotic and normal human leukocytes (Gahl, W. A., Tietze, F., Bashan, N., Steinherz, R., and Schulman, J. D. (1982) J. Biol. Chem. 257, 9570-9575). In contrast, normal and cystinotic human fibroblasts did not show any differences with regard to lysine efflux or its trans-stimulation by cationic amino acids. An important mechanism by which cysteamine treatment of cystinosis allows cystine escape from lysosomes may be the ability of the mixed disulfide of cysteine and cysteamine formed by sulfhydryl-disulfide exchange to migrate by this newly discovered system mediating cationic amino acid transport.     

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.