Characteristics of cystine uptake by cultured LLC-PK1 cells

The characteristics of the uptake of L-cystine by LLC-PK1 cells were examined. The uptake diminished with time in culture after passage of cells while the uptake of sugar increased. In 48-h-cultured cells at a range of cystine concentrations including physiological levels uptake occurred via a saturable process which was independent of medium sodium concentration and pH. No inhibition of cystine uptake occurred in the presence of lysine which is known to share the cystine transport system in uncultured renal proximal tubule cells and brush-border membrane vesicles. Glutamate was a potent inhibitor of cystine uptake and participated in heteroexchange diffusion with cystine. The cystine-glutamate transport process resembles that of cultured human fibroblasts. The inability of these cells to reflect the genetically determined cystine-lysine system which is altered in the kidney in human cystinuria makes them an inappropriate model of the renal tubule cell cystine transport system. On the other hand, they may provide a model system for examining the factors which determine the presence of the various cystine transport process.     

The influence of pH on cystine and dibasic amino acid transport by rat renal brushborder membrane vesicles

The uptake of cystine and lysine by rat renal brushborder membrane vesicles was examined at various intravesicular and extravesicular hydrogen ion concentrations to discern whether ionic species are determinants of specificity for the shared transport system and whether hydrogen ion gradients play a role in determining uptake values. When intravesicular and extravesicular pH are identical, the highest uptake of cystine occurred at pH 7.4, with lesser uptake at pH 6.0 and 8.3. Since cystine is electroneutral at pH 6.0 and 90% anionic at pH 8.3, it appears that neither form of the amino acid is a preferred species for transport. A similar relationship between pH and uptake occurs for lysine, which is cationic at pH below 8.5. This suggests that pH affects the functioning of the membrane carrier system independent of ionic species of the substrate. There is no apparent relationship of cystine uptake to hydrogen ion gradients across the membrane. Over the range of extravesicular pH studied, optimal cystine uptake occurred whenever the intravesicular pH was 7.4. Competitive interactions between unlabeled amino acids and labeled cystine were not affected by the extravesicular pH and, therefore, did not seem determined by the ionic species of cystine.     

Cystine-glutamate transport interactions in rat renal cortical tubules,brushborder vesicles,and cultured renal tubule cells

Glutamate had no significant effect on the uptake of 0.025 mM cystine by isolated rat renal cortical tubules and brushborder membrane vesicles in contrast to lysine which significantly inhibits cystine transport. Glutamate, however, markedly inhibited cystine uptake by rat renal tubule cells grown in a serum-free, hormonally defined media for 5 days. Lysine also inhibited cystine transport in these cultured renal tubule cells.     

Ion dependence of cystine and lysine uptake by rat renal brush-border membrane vesicles.

The shared transport system for uptake of L-cystine and L-lysine was examined in isolated rat renal brush-border membrane vesicles for the ionic requirements for activation of the system. No requirement for sodium was seen for either cystine or lysine influx. However, the efflux of lysine from the vesicle was stimulated by Na+. Therefore, the transport system appears to be asymmetric in its requirement for sodium. Two different divalent cations were used in the membrane isolations which resulted in different responses of cystine uptake to the electrogenic movement of K+ out of the vesicle. Membranes prepared by Mg-aggregation showed no stimulation of cystine influx by the imposition of a transient interior negative potential while vesicles prepared by Ca-aggregation did respond to electrogenic stimulation by an outwardly directed K-diffusion potential in the presence of valinomycin. Lysine influx was stimulated by electrogenic potassium efflux in both Mg-prepared and Ca-prepared membranes. No difference in sodium requirement for cystine influx was seen between the vesicles isolated by different cation-aggregation methods.     

Studies on the unique presence of an N-acetylgalactosamine residue in the carbohydrate moieties of human follicle-stimulating hormone

The effect of cystine starvation on the transport system of cystine and glutamate was examined in cultures of human diploid fibroblasts. The 2-min uptake of cystine and glutamate increased progressively after a lag of 6 h of cystine starvation. There was approx. 2-3-fold increase, and the increased rate of uptake was accompanied by an increase in the Vmax and unchanged Km. The cystine starvation-induced enhancement appeared specific for the uptake of cystine and glutamate. Actinomycin D or cycloheximide completely blocked the time-related increase in th uptake. Depletion of glutamate did not lead to the enhanced uptake, whereas depletion of glycine and serine caused as much increase in the uptake as depletion of cystine did. The intracellular pool of glutathione was extremely reduced by depletion of cystine, or of glycine and serine, but to a far less extent by depletion of glutamate. The results indicate that te transport system for cystine and glutamate appears to undergo adaptive regulation. It is suggested that glutathione may function as a regulatory signal to this transport system.     

Adaptive enhancement of cystine and glutamate uptake in human diploid fibroblasts in culture

The effect of cystine starvation on the transport system of cystine and glutamate was examined in cultures of human diploid fibroblasts. The 2-min uptake of cystine and glutamate increased progressively after a lag of 6 h of cystine starvation. There was approx. 2–3-fold increase, and the increased rate of uptake was accompanied by an increase in the V_max and unchanged K_m. The cystine starvation-induced enhancement appeared specific for the uptake of cystine and glutamate. Actinomycin D or cycloheximide completely blocked the time-related increase in the uptake. Depletion of glutamate did not lead to the enhanced uptake, whereas depletion of glycine and serine caused as much increase in the uptake as depletion of cystine did. The intracellular pool of glutathione was extremely reduced by depletion of cystine, or of glycine and serine, but to a far less extent by depletion of glutamate. The results indicate that the transport system for cystine and glutamate appears to undergo adaptive regulation. It is suggested that glutathione may function as a regulatory signal to this transport system.     

Mouse lymphoma L1210 cells acquire a new cystine transport activity upon adaptation in vitro

Summary Mouse lymphoma L1210 cells maintained in vitro at a high cell density for a certain time period adapted themselves to the in vitro environment and were able to grow indefinitely. From these adapted cells, more than 30 clones were isolated. They all had much higher activity to take up cystine than the original L1210 cells, supporting a previous view that the deficiency of the cystine uptake limits the survival and growth of L1210 cells in vitro. The cystine uptake of one cloned cell line was characterized. The enhanced uptake of cystine in these cells was mainly mediated by a Na⁺-independent, saturable system and was potently inhibited by glutamate and some other anionic amino acids, but less by aspartate. Such activity of cystine uptake was not observed in the original L1210 cells. The results suggest that, upon adaptation in vitro, L1210 cells acquire a new cystine transport activity necessary for survival and growth in vitro.     

Role of proton dissociation in the transport of cystine and glutamate in human diploid fibroblasts in culture

The effect of extracellular pH on the transport interaction of cystine and glutamate in cultured human diploid cells was examined over the pH range of 5.8-8.0. The initial rates of uptake of cystine increased with an increase in pH and glutamate potently inhibited the cystine uptake independently of pH. The uptake of glutamate was almost invariable within the pH range, but it was inhibited by cystine in a pH-dependent manner; the inhibition increased with an increase in pH. Regardless of pH, the uptake of cystine and glutamate was strongly inhibited by alpha-aminoadipate, alpha-aminopimelate, and homocysteate. From the pK values of cystine and other amino acids, it is suggested that cystine is transported in the same ionic form as is glutamate.     

Characterization of cystine uptake in cultured astrocytes

Glutathione is involved in the maintenance of the structural and functional integrity of membrane proteins, in protection against free radicals and oxidative stress, and in the detoxification of xenobiotics. The cellular uptake of cystine is the rate limiting step in the biosynthesis of glutathione. The precise mechanism for such uptake is not clear as some reports indicate that the uptake occurs through a glutamate-cystine antiporter (system X(c)(-)), whereas, others suggest that it is taken up by the glutamate transporter (system X(AG)). Our studies in cultured astrocytes derived from neonatal rats showed that glutamate, D- and L-aspartate inhibited cystine uptake; that factors that increased intracellular glutamate levels, which would have enhanced the activity of the antiporter, did not stimulate cystine uptake; that the uptake was sodium dependent and partially chloride dependent; that the b(o,+) and ASC systems, which have been shown to carry cystine in some cells, did not mediate cystine uptake in astrocytes; that glutamate uptake blockers such as L-aspartate-beta-hydroxamate (AbetaH) and L-trans-pyrrolidine-2,4-dicarboxylate (PDC), as well as cystine uptake inhibitor L-alpha-aminoadipate (AAA) potently reduced cystine uptake. Additionally, deferoxamine (100 microM) as well as ammonium chloride (5 mM), both of which inhibit glutamate uptake, also inhibited cystine uptake. Taken together, our findings indicate that astrocytes take up cystine through a similar, if not identical, system used to take up glutamate. Interference of cystine uptake by astrocytes through the glutamate transport system may have profound effects on the redox state and the structural and functional integrity of the CNS.     

Uptake of l-[35S]Cystine by Isolated Rat Brain Capillaries

Adult rat brain capillaries were isolated by a simplified procedure and showed an enrichment of the marker enzyme, γ-glutamyltranspeptidase. The uptake of [³⁵S]cystine at 37°C by this preparation can be divided into two components, a sodium- and energy-dependent transport process for the free amino acid pool, with an apparent K_m of 36 μm , and a binding process, with an apparent K_m of 1.13 mm . Chemical analysis of the amino acid pool indicates that cystine is the major form of intracapillary ³⁵S. Cystine transport was not inhibited by lysine, but glycine, α-methylaminoisobutyric acid and β-2-aminobicyclo-[2,2,1]-heptane-2-carboxylic acid were inhibitory to a small extent.     

Transport of cystine in isolated rat hepatocytes in primary culture

Uptake of cystine and factors affecting the transport were investigated in adult rat hepatocytes in primary monolayer culture. The cystine uptake was initially mediated by Na+-dependent route(s). However, the activity of Na+-dependent uptake decreased markedly during the culture, and Na+-independent uptake emerged with a lag period of 12 h in response to insulin and dexamethasone in the culture medium. After 48 h in culture, cystine was mainly transported into the cells through this Na+-independent route. The action of insulin and dexamethasone on the enhancement of the Na+-independent uptake was apparently additive, and the enhancement was completely blocked by cycloheximide or actinomycin D. Emergence of the Na+-independent uptake of cystine was also regulated by cell density; at lower density, the uptake tended to be elevated. The transport of cystine through the Na+-independent system was pH sensitive and was inhibited by some anionic amino acids, such as glutamate and homocysteate, but not by aspartate. These results suggest that the emerging system is similar to the ones reported in fibroblasts and in some hepatoma cell lines; the anionic form of cystine is transported through the system.     

l-Cystine transport by papain-treated rat renal brush-border membrane vesicles

In papain-treated rat renal brush-border membrane vesicles, cystine uptake was enhanced under sodium gradient conditions. This effect was not observed when sodium was equilibrated across the vesicle membrane or when sodium was completely absent from the incubation medium. The increased rate of cystine uptake occurred within the first two minutes of incubation and coincided with the period of increased flux of sodium known to occur after papain treatment. Under sodium gradient conditions, the V_max of cystine uptake by treated vesicles was 65% greater while the K_m was 25% lower than the value observed in untreated membranes. The increased cystine uptake after papain treatment occurred when medium cystine was in the electroneutral form. In the absence of a sodium gradient, cystine uptake by control membranes was insensitive to changes in membrane potential and this was unaltered after papain treatment. Exposure of the membranes to papain also resulted in a profound decrease in cystine binding which occurs in native membranes incubated with cystine. The fact that cystine uptake is unchanged under sodium equilibration and even enhanced under sodium gradient conditions suggests that the component of cystine binding is not essential for cystine transport and may represent non-specific binding to membrane proteins.     

l-[35S]CYSTINE UPTAKE BY RAT BRAIN SYNAPTOSOMES

Abstract— The uptake of [³⁵S]cystine at 37°C by synaptosomal fractions isolated from adult rat cerebrum can be divided into two components. About 60% of the uptake is due to binding to synaptosomal proteins while the remainder exists as a free amino acid pool. Chemical analysis of this soluble component indicates that considerable reduction of cystine to cysteine occurs with 75% or more of the labeled molecular species being cysteine. The process involved in the uptake into the soluble pool was composed of two saturable systems with apparent K _m values of 0.14 and 1.4 m m . The low K _m system was sodium and oxygen independent but inhibited by dinitrophenol. Dibasic amino acids, lysine, arginine and ornithine, did not inhibit cystine uptake. The characteristics of cystine uptake by synaptosomes from newborn brain are very similar to those of adult brain.     

Expression of rat jejunal cystine carrier in Xenopus oocytes

Functional interactive cystine-lysine carriers have been expressed in Xenopus oocytes following the injection of RNA extracted from rat intestinal mucosa. Lysine-inhibitable cystine uptake was able to be measured 16 h after oocyte injection with RNA. The longer the oocytes were maintained after injection, the more cystine transport capability was induced. Uninjected or water-injected oocytes showed virtually no lysine-inhibitable cystine uptake, and no system developed after the oocytes had been isolated and maintained in vitro. The cystine uptake expressed after RNA injection was selectively inhibited by dibasic amino acids and phenylalanine but not by other amino acids or alpha-methyl-D-glucoside. Expression of the interactive cystine-lysine system was induced only by RNA isolated from intestinal tissue and not by RNA from rat liver. The Km for cystine uptake in RNA-injected oocytes was 0.01 mM and appears identical to the single system found in the RNA source tissue.     

Cysteine and Cystine Transport at the Blood-Brain Barrier

Abstract: The nature of cysteine and cystine uptake from the cerebral capillary lumen was studied in the rat using the carotid injection technique. [³⁵S]-Cysteine uptake was readily inhibited by the synthetic amino acid 2-amino-bicyclo(2,2,1)heptane-2-carboxylic acid (BCH), the defining substrate for the leucine-preferring (L) system in the Ehrlich ascites cell. The addition of non-radioactive alanine or serine, representatives of the alanine, serine, and cysteine-preferring (ASC) system, produced no significant decrease in the uptake of cysteine after cysteine transport by the L system was blocked with BCH. This indicated that the major component of cysteine's transport from the brain capillary lumen was by the L system with no detectable uptake of cysteine by the ASC system. No carrier-mediated transport of cystine, the disulfide form of the amino acid, was detected, nor was there any inhibition by cystine of the transport of the neutral amino acid methionine or the basic amino acid arginine. These results suggest that the ASC system, if present, is not quantitatively important for the transport of neutral amino acids from the brain capillary lumen.     

Na+-independent Lysine Transport in Human Intestinal Caco-2 Cells

The nature of transepithelial and cellular transport of the dibasic amino acid lysine in human intestinal epithelial Caco-2 cells has been characterized. Intracellular accumulation of lysine across both the apical and basolateral membranes consists of a Na⁺-independent, membrane potential-sensitive uptake. Na⁺-independent lysine uptake at the basolateral membrane exceeds that at the apical membrane. Lysine uptake consists of both saturable and nonsaturable components. Na⁺-independent lysine uptake at both membranes is inhibited by lysine, arginine, alanine, histidine, methionine, leucine, cystine, cysteine and homoserine. In contrast, proline and taurine are without inhibitory effects at both membranes. Fractional Na⁺-independent lysine efflux from preloaded epithelial layers is greater at the basolateral membrane and shows trans-stimulation across both epithelial borders by lysine, arginine, alanine, histidine, methionine, and leucine but not proline and taurine. Na⁺-independent lysine influx (10 μm) in the presence of 10 mm homoserine shows further concentration dependent inhibition by lysine. Taken together, these data are consistent with lysine transport being mediated by systems b^o,+, y⁺ and a component of very low affinity (nonsaturable) at both membranes. The relative contribution to lysine uptake at each membrane surface (at 10 μm lysine), normalized to total apical uptake (100%), is apical b^o,+ (47%), y⁺ (27%) and the nonsaturable component (26%), and basal b^o,+ (446%), y⁺ (276%) and the nonsaturable component (20%). Northern analysis shows hybridization of Caco-2 poly(A)⁺RNA with a human rBAT cDNA probe. Received: 3 July 1995/Revised: 6 February 1996     

Developmental pattern of cystine transport in isolated rat renal tubules

Isolated renal cortical tubule fragments from rats ranging in age from less than 48 h to 15 weeks were used to examine the pattern of cystine uptake with development. Immature tubules took up cystine with a faster initial rate than mature tubules and did not reach a steady state by 60 min. By eight weeks of age, the timed uptake of cystine began to approach a steady state and between 8 and 11 weeks the uptake pattern achieved its adult form of reaching a steady state by 30 min of incubation. Analysis of the intracellular metabolism of the cystine taken up by the newborn tubules revealed that the majority had been reduced to cysteine with the formation of small amounts of reduced glutathione. Cystine entered the renal cortical tubule cell from the newborn via two saturable transport systems similar to the mature animal. The kinetic parameters of initial uptake of these two transport systems were similar in the mature and newborn animal except for a higher maximum transport velocity for the low K_m, low capacity system in the newborn. Lysine inhibited cystine uptake by newborn tubules and this inhibition appeared to occur on the low K_m, low capacity transport system similar to the adult. Cystine uptake was sodium dependent with an apparent affinity for sodium of 36 mequiv./l. From this data, the physiologic cystinuria of the immature animal does not appear to be referrable to a lower rate of influx as previously observed with the cortical slice. Other mechanisms should be sought to explain this phenomenon of immaturity.     

Absence of a role of gamma-glutamyl transpeptidase in the transport of amino acids by rat renal brushborder membrane vesicles

Summary The role of the enzyme, gamma-glutamyl transpeptidase on the uptake of amino acids by the brushborder membrane of the rat proximal tubule was examined by inhibiting it with AT-125 (l-[S, 5S]--amino-3-chloro-4,5-dihydro-5-isoxazoleacetic acid). AT-125 inhibited 98% of the activity of gamma-glutamyl transpeptidase when incubated for 20 min at 37°C with rat brushborder membrane vesicles. AT-125 given to ratsin vivo inhibited 90% of the activity of gamma-glutamyl transpeptidase in subsequently isolated brushborder membrane vesicles from these animals. AT-125 inhibition of gamma-glutamyl transpeptidase bothin vivo andin vitro had no effect on the brushborder membrane uptake of cystine. Similarly, there was no effect of gamma-glutamyl transpeptidase inhibition by AT-125 on glutamine, proline, glycine, methionine, leucine or lysine uptake by brushborder membrane vesicles. Furthermore, the uptake of cystine by isolated rat renal cortical tubule fragments, in which the complete gamma-glutamyl cycle is present, was unaffected by AT-125 inhibition of gamma-glutamyl transpeptidase. Therefore, in the two model systems studied, gamma-glutamyl transpeptidase did not appear to play a role in the transport of amino acids by the renal brushborder membrane.     

Cystine and dibasic amino acid uptake by opossum kidney cells

The characteristics of the uptake of L-cystine by the continuous opossum kidney cell line, OK, were examined. Uptake of cystine is rapid and, in contrast to other continuous cultured cell lines, these cells retain the cystine/dibasic amino acid transport system which is found in vivo and in freshly isolated kidney tissue. Confluent monolayers of cells also fail to show the presence of the cystine/glutamate transport system present in LLC-PK1 cells, fibroblasts, and cultured hepatocytes. Uptake of cystine occurs via a high-affinity saturable process which is independent of medium sodium concentration. The predominant site of cystine transport is across the apical cell membrane. The intracellular concentration of GSH far exceeds that of cystine with a ratio greater than 100:1 for GSH:cysteine. Incubation of cells for 5 minutes with a physiological level of labelled cystine resulted in the labelling of 66% and 5% of the total intracellular cysteine and glutathione, respectively. The ability of these cells to reflect the shared cystine/dibasic amino acid transport system makes them a suitable model for investigation of the cystine carrier which is altered in human cystinuria.     

Regulation of sulfate assimilation in Cytophaga johnsonae

We have studied the regulation of sulfate assimilation by the gliding bacterium Cytophaga johnsonae in which 20% of the total sulfur is in the sulfornate moiety of sulfonolipid. Added cystine inhibited sulfate uptake and growth with cystine as sulfur source resulted in a repression of sulfate uptake. However, low concentrations of cystine preferentially repressed the terminal reactions of sulfate assimilation responsible for cysteine synthesis while allowing the transport and activation of sulfate for sulfonolipid synthesis. The significance of this novel pattern of regulation in bacteria is discussed.