A cystine-cysteine shuttle mediated by xCT facilitates cellular responses to S-nitrosoalbumin

We have shown previously that extracellular cysteine is necessary for cellular responses to S-nitrosoalbumin. In this study we have investigated mechanisms involved in accumulation of extracellular cysteine outside vascular smooth muscle cells and characterized the role of cystine-cysteine release in transfer of nitric oxide (NO)-bioactivity. Incubation of cells with cystine led to cystine uptake, reduction, and cysteine release. The process was inhibitable by extracellular glutamate, suggesting a role for system x(c)(-) amino acid transporters. Smooth muscle cells express this transporter constitutively and induction of the light chain component (xCT) by either diethyl maleate or 3-morpholino-sydnonimine (SIN-1) led to glutamate-inhibitable cystine uptake and an increased rate of cysteine release from cells. Likewise, overexpression of xCT in smooth muscle cells or endothelial cells led to glutamate-inhibitable cysteine release. The resulting extracellular cysteine was found to be required for transfer of NO from extracellular S-nitrosothiols into cells via system L transporters leading to formation of cellular S-nitrosothiols. Cysteine release coupled to cystine uptake was also found to be required for cellular responses to S-nitrosoalbumin and facilitated S-nitrosoalbumin-mediated inhibition of epidermal growth factor signaling. These data show that xCT expression can constitute a cystine-cysteine shuttle whereby cystine uptake drives cysteine release. Furthermore, we show that extracellular cysteine provided by this shuttle mechanism is necessary for transfer of NO equivalents and cellular responses to S-nitrosoablumin.     

Redox imbalance in cystine/glutamate transporter-deficient mice

Cystine/glutamate transporter, designated as system x(-)(c), mediates cystine entry in exchange for intracellular glutamate in mammalian cells. This transporter consists of two protein components, xCT and 4F2 heavy chain, and the former is predicted to mediate the transport activity. This transporter plays a pivotal role for maintaining the intracellular GSH levels and extracellular cystine/cysteine redox balance in cultured cells. To clarify the physiological roles of this transporter in vivo, we generated and characterized mice lacking xCT. The xCT(-/-) mice were healthy in appearance and fertile. However, cystine concentration in plasma was significantly higher in these mice, compared with that in the littermate xCT(-/-) mice, while there was no significant difference in plasma cysteine concentration. Plasma GSH level in xCT(-/-) mice was lower than that in the xCT(-/-) mice. The embryonic fibroblasts derived from xCT(-/-) mice failed to survive in routine culture medium, and 2-mercaptoethanol was required for survival and growth. When 2-mercaptoethanol was removed from the culture medium, cysteine and GSH in these cells dramatically decreased, and cells started to die within 24 h. N-Acetyl cysteine also rescued xCT(-/-)-derived cells and permitted growth. These results demonstrate that system x(-)(c) contributes to maintaining the plasma redox balance in vivo but is dispensable in mammalian development, although it is vitally important to cells in vitro.     

A novel approach to enhancing cellular glutathione levels

GSH and GSH-associated metabolism provide the major line of defense for the protection of cells from oxidative and other forms of toxic stress. Of the three amino acids that comprise GSH, cysteine is limiting for GSH synthesis. As extracellularly cysteine is readily oxidized to form cystine, cystine transport mechanisms are essential to provide cells with cysteine. Cystine uptake is mediated by system x(c)(-), a Na(+)-independent cystine/glutamate antiporter. Inhibition of system x(c)(-) by millimolar concentrations of glutamate, a pathway termed oxidative glutamate toxicity, results in GSH depletion and nerve cell death. Recently, we described a series of compounds derived from the conjugation of epicatechin (EC) with cysteine and cysteine derivatives that protected nerve cells in culture from oxidative glutamate toxicity by maintaining GSH levels. In this study, we characterize an additional EC conjugate, cysteamine-EC, that is 5- to 10-fold more potent than the earlier conjugates. In addition, we show that these EC conjugates maintain GSH levels by enhancing the uptake of cystine into cells through induction of a disulfide exchange reaction, thereby uncoupling the uptake from system x(c)(-). Thus, these novel EC conjugates have the potential to enhance GSH synthesis under a wide variety of forms of toxic stress.     

Transport of cystine and cysteine and cell growth in cultured human diploid fibroblasts: effect of glutamate and homocysteate

Human diploid fibroblasts take up cystine in the culture medium and the cystine is immediately reduced to cysteine in the cells. It is found that cysteine thus formed is rapidly released from the cells into the medium and accumulates there. The system transporting cysteine is convincingly similar to the ASC system described by Christensen et al. (1967). Since cysteine in the medium is sensitive to autoxidation and readily changes back to cystine, the uptake of cystine seems crucial to the cells. Inhibitors of cystine uptake, such as glutamate and homocysteate, potently reduce the intracellular and extracellular levels of cysteine. These inhibitors modify the cell growth depending upon the cystine concentration is physiological. An excessive concentration of cystine is in itself inhibitory action is antagonized by glutamate or homocysteate.     

Transport of L-[14C]cystine and L-[14C]cysteine by subtypes of high affinity glutamate transporters over-expressed in HEK cells

Transport of L-cystine across the cell membrane is essential for synthesis of the major cellular antioxidant, glutathione (gamma-glutamylcysteinylglycine). In this study, uptake of L-[14C]cystine by three of the high affinity sodium-dependent mammalian glutamate transporters (GLT1, GLAST and EAAC1) individually expressed in HEK cells has been determined. All three transporters display saturable uptake of L-[14C]cystine with Michaelis affinity (K(m)) constants in the range of 20-110 microM. L-glutamate and L-homocysteate are potent inhibitors of sodium-dependent L-[14C]cystine uptake in HEK(GLAST), HEK(GLT1) and HEK(EAAC1) cells. Reduction of L-[14C]cystine to L-[14C]cysteine in the presence of 1mM cysteinylglycine increases the uptake rate in HEK(GLT1), HEK(GLAST) and HEK(EAAC1) cells, but only a small proportion (<10%) of L-[14C]cysteine uptake in HEK(GLT1) and HEK(GLAST) cells occurs by the high affinity glutamate transporters. The majority (>90%) of L-[14C]cysteine transport in these cells is mediated by the ASC transport system. In HEK(EAAC1) cells, on the other hand, L-[14C]cysteine is transported equally by the ASC and EAAC1 transporters. L-homocysteine inhibits L-[14C]cysteine transport in both HEK(GLAST) and HEK(GLT1) cells, but not in HEK(EAAC1) cells. It is concluded that the quantity of L-[14C]cyst(e)ine taken up by individual high affinity sodium-dependent glutamate transporters is determined both by the extracellular concentration of amino acids, such as glutamate and homocysteine, and by the extracellular redox potential, which will control the oxidation state of L-cystine.     

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.     

System xc? and Thioredoxin Reductase 1 Cooperatively Rescue Glutathione Deficiency

GSH is the major antioxidant and detoxifier of xenobiotics in mammalian cells. A strong decrease of intracellular GSH has been frequently linked to pathological conditions like ischemia/reperfusion injury and degenerative diseases including diabetes, atherosclerosis, and neurodegeneration. Although GSH is essential for survival, the deleterious effects of GSH deficiency can often be compensated by thiol-containing antioxidants. Using three genetically defined cellular systems, we show here that forced expression of xCT, the substrate-specific subunit of the cystine/glutamate antiporter, in γ-glutamylcysteine synthetase knock-out cells rescues GSH deficiency by increasing cellular cystine uptake, leading to augmented intracellular and surprisingly high extracellular cysteine levels. Moreover, we provide evidence that under GSH deprivation, the cytosolic thioredoxin/thioredoxin reductase system plays an essential role for the cells to deal with the excess amount of intracellular cystine. Our studies provide first evidence that GSH deficiency can be rescued by an intrinsic genetic mechanism to be considered when designing therapeutic rationales targeting specific redox enzymes to combat diseases linked to GSH deprivation.     

Expression of the activity of cystine/glutamate exchange transporter,system x(c)(-), by xCT and rBAT

The expression of the activity of cystine/glutamate exchange transporter, designated system x(c)(-), requires two components, xCT and 4F2 heavy chain (4F2hc) in Xenopus oocytes. rBAT (related to b(0,+) amino acid transporter) has a significant homology to 4F2hc and is known to be located in the apical membrane of epithelial cells. To determine whether xCT can associate with rBAT and express the activity of system x(c)(-), xCT, and rBAT were co-expressed in Xenopus oocytes and in mammalian cultured cells. In the oocytes injected with rBAT cRNA alone, the activities of cystine and arginine transport were induced, indicating that the system b(0,+)-like transporter was expressed by associating the exogenous rBAT with an endogenous b(0,+)AT-like factor as reported previously. In the oocytes injected with xCT and rBAT cRNAs, the activity of cystine transport was further induced. This induced activity of cystine transport was partially inhibited by glutamate or arginine and completely inhibited by adding both amino acids. In these oocytes, the activity of glutamate transport was also induced and it was strongly inhibited by cystine. In NIH3T3 cells transfected with xCT cDNA alone, the activity of cystine transport was significantly increased, and in the cells transfected with both xCT and rBAT cDNAs, the activity of cystine transport was further enhanced. The enhanced activity was Na(+)-independent and was inhibited by glutamate and homocysteate. These results indicate that rBAT can replace 4F2hc in the expression of the activity of system x(c)(-) and suggest that system x(c)(-) activity could be expressed in the apical membrane of epithelial cells.     

Determinants of glutamine dependence and utilization by normal and tumor-derived breast cell lines

A continual supply of the amino acid glutamine (GLN) may be necessary for cancerous cell growth. GLN plays a central role in multiple metabolic pathways and has long been considered an essential component of tissue culture media. However, the GLN requirements of tumor cell lines and the factors that determine a cell's need for GLN have not been comprehensively studied. Also, it remains unclear how various metabolic pathways contribute to GLN consumption. In the present study, possible determinants of GLN metabolism were examined in seven breast cell lines, two derived from immortalized normal tissue and five of tumor origin. These cells exhibited different dependencies on media GLN concentration for growth and a wide range of GLN utilization rates. GLN uptake was facilitated by a single, common transporter functionally defined as System ASC. However, the affinities for GLN exhibited by this transporter differed appreciably between cell lines. Furthermore, the concentration at which media GLN became a limiting factor for cellular proliferation correlated with transporter affinity. The origin of the cell lines was not a determinant of GLN metabolism because immortalized cells of nontumor origin exhibited GLN dependence and utilization rates comparable to those of tumor-derived cells. The rates of CO₂ production from GLN were similar for each cell lines. Rates of GLN disappearance and glutamate appearance in media were strongly correlated, with 32–80% of media GLN converted to glutamate. Both rates were directly affected by media cystine concentration, suggesting that a large portion of glutamate efflux was coupled with cystine import through the amino acid transport system X These results demonstrated that cell growth is a function of GLN influx and suggest that GLN is used to supply glutamate and cystine, perhaps for glutathione synthesis. J. Cell. Physiol. 176:166–178, 1998. © 1998 Wiley-Liss, Inc.     

High-Throughput Assay Development for Cystine-Glutamate Antiporter (xc -) Highlights Faster Cystine Uptake than Glutamate Release in Glioma Cells

The cystine-glutamate antiporter (system x_c ^-) is a Na⁺-independent amino acid transporter that exchanges extracellular cystine for intracellular glutamate. It is thought to play a critical role in cellular redox processes through regulation of intracellular glutathione synthesis via cystine uptake. In gliomas, system x_c ^- expression is universally up-regulated while that of glutamate transporters down-regulated, leading to a progressive accumulation of extracellular glutamate and excitotoxic cell death of the surrounding non-tumorous tissue. Additionally, up-regulation of system x_c ^- in activated microglia has been implicated in the pathogenesis of several neurodegenerative disorders mediated by excess glutamate. Consequently, system x_c ^- is a new drug target for brain cancer and neuroinflammatory diseases associated with excess extracellular glutamate. Unfortunately no potent and selective small molecule system x_c ^- inhibitors exist and to our knowledge, no high throughput screening (HTS) assay has been developed to identify new scaffolds for inhibitor design. To develop such an assay, various neuronal and non-neuronal human cells were evaluated as sources of system x_c ^-. Human glioma cells were chosen based on their high system x_c ^- activity. Using these cells, [¹⁴C]-cystine uptake and cystine-induced glutamate release assays were characterized and optimized with respect to cystine and protein concentrations and time of incubation. A pilot screen of the LOPAC/NINDS libraries using glutamate release demonstrated that the logistics of the assay were in place but unfortunately, did not yield meaningful pharmacophores. A larger, HTS campaign using the 384-well cystine-induced glutamate release as primary assay and the 96-well ¹⁴C-cystine uptake as confirmatory assay is currently underway. Unexpectedly, we observed that the rate of cystine uptake was significantly faster than the rate of glutamate release in human glioma cells. This was in contrast to the same rates of cystine uptake and glutamate release previously reported in normal human fibroblast cells.     

System X c − Antiporter Inhibitors: Azo-Linked Amino-Naphthyl-Sulfonate Analogues of Sulfasalazine

Neurochemical Research - The cystine/glutamate antiporter system x c ? (Sx c ? ) mediates the exchange of intracellular l-glutamate (l-Glu) with extracellular l-cystine (l-Cys2). Both...     

Immature cortical neurons are uniquely sensitive to glutamate toxicity by inhibition of cystine uptake

Using the N18-RE-105 neuroblastoma X retina cell line, we previously described Ca2(+)-dependent quisqualate-type glutamate toxicity caused by the inhibition of high-affinity cystine uptake, leading to glutathione depletion and accumulation of cellular oxidants. We now demonstrate that primary cultures of rat cortical neurons (E17; 24-72 h in culture), but not glia, also degenerate when exposed to culture medium with reduced cystine or containing competitive inhibitors of cystine uptake, including glutamate. At this developmental stage, neurotoxicity did not occur as a consequence of continuous exposure to glutamate receptor subtype agonists, N-methyl-D-aspartate, kainate, or 2(RS)-amino-3-hydroxy-5-methyl-4-isoxazolepropionate. However, those that inhibited neuronal cystine uptake--quisqualate, glutamate, homocysteate, beta-N-oxalyl-L-alpha,beta-diaminopropionic acid, and ibotenate--were neurotoxic. Toxicity related to quisqualate did not correlate with the development of quisqualate-stimulated phosphatidylinositol turnover. The toxic potencies of glutamate, quisqualate, and homocysteate were inversely proportional to the concentration of cystine in the medium, suggesting that they competitively inhibit cystine uptake. Autoradiographic analysis of the cellular localization of L-[35S]cystine uptake indicated that embryonic neurons have a high-affinity transport system that is sensitive to quisqualate, whereas non-neuronal cells in the same cultures have a low-affinity system that is insensitive to quisqualate but potently blocked by D-aspartate and glutamate. Exposure to glutamate or homocysteate resulted in a time-dependent depletion of the cellular antioxidant glutathione. The centrally acting antioxidant idebenone and alpha-tocopherol completely blocked the neurotoxicity resulting from glutamate exposure. We propose that competitive inhibition of cystine transport and reduction of extracellular cystine levels result in neuronal cell death due to accumulation of cellular oxidants.     

Thrombin-stimulated glutamate uptake in human platelets is predominantly mediated by the glial glutamate transporter EAAT2

Glutamate toxicity has been implicated in the pathogenesis of various neurological diseases. Glial glutamate transporters play a key role in the regulation of extracellular glutamate levels in the brain by removing glutamate from the extracellular fluid. Since human blood platelets possess an active glutamate uptake system, they have been used as a peripheral model of glutamate transport in the central nervous system (CNS). The present study is aimed at identifying the glutamate transporter on blood platelets, and to asses the influence of platelet activation on glutamate uptake. Platelets from healthy donors showed Na+-dependent glutamate uptake (Km, 3.5+/-0.9 microM; Vmax, 2.8+/-0.2 pmol glutamate/75 x 10(6)platelets/30 min), which could be blocked dose-dependently by the EAAT specific inhibitors DL-threo-E-benzyloxyaspartate (TBOA), L-trans-pyrrolidine-2,4-dicarboxylic acid (tPDC) and high concentrations of the EAAT2 inhibitor dihydrokainate (DHK). Analysis of platelet homogenates on Western blots showed EAAT2 as the predominant glutamate transporter. Platelet activation by thrombin caused an increase in glutamate uptake, which could be inhibited by TBOA and the EAAT2 inhibitor DHK. Kinetic analysis showed recruitment of new transporters to the membrane. Indeed, Western blot analysis of subcellular fractions revealed that alpha-granules, which fuse with the membrane upon thrombin stimulation, contained significant EAAT2 immunoreactivity. Inhibition of the second messengers involved in alpha-granule secretion (protein kinase C, phosphatidylinositol-3-kinase) inhibited thrombin-stimulated uptake, but not basal uptake. These data show that the glial EAAT2 is the predominant glutamate transporter on blood platelets and suggest, that thrombin increases glutamate uptake capacity by recruiting new transporters (EAAT2) from alpha-granules.     

Stimulation of cystine uptake by nitric oxide: regulation of endothelial cell glutathione levels

Nitric oxide (NO)is known to produce some of its biological activity throughmodification of cellular thiols. Return of cellular thiols to theirbasal state requires the activity of the GSH redox cycle, suggestingimportant interactions between NO signaling and regulation of cellularredox status. Because continuous exposure to NO may lead to adaptiveresponses in cellular redox systems, we investigated the effects of NOon cellular GSH levels in vascular endothelial cells. Acute exposure (1 h) of cells to >1 mMS-nitroso-N-acetyl-penicillamine (SNAP) led to depletion of GSH. On the other hand, chronic exposure tolower concentrations of SNAP (1 mM) led to a progressive increase incytosolic GSH, reaching fourfold above basal by 16 h. The mechanism mayinvolve an increase in GSH biosynthesis through effects on biosyntheticenzymes or through increased supply of cysteine, the limitingsubstrate. In this regard, we report that chronic exposure to SNAP ledto a concentration-dependent increase in cystine uptake over a timecourse similar to that seen for elevation of GSH. The effect of SNAP oncystine uptake was inhibitable by either cycloheximide or actinomycinD, suggesting a requirement for both RNA and protein synthesis.Furthermore, uptake was Na⁺independent and was blocked by extracellular glutamate. Extracellular glutamate also blocked SNAP-mediated elevation of cytosolic GSH. Finally, in a coculture model, NO produced by cytokine-pretreated RAW264.7 cells increased both GSH levels and cystine uptake in naiveendothelial cells. These findings strongly suggest that NO leads toadaptive induction of thex_c amino acidtransport system, increased cystine uptake, and elevation ofintracellular GSH levels.     

EAAC1 gene deletion alters zinc homeostasis and enhances cortical neuronal injury after transient cerebral ischemia in mice

The excitatory amino acids glutamate and cysteine are actively transported into neurons from the extracellular space by the high affinity glutamate transporter EAAC1. The astrocyte glutamate transporters, GLT1 and GLAST, are the primary mediators of glutamate clearance. EAAC1 has a limited role in this function. However, uptake of cysteine into neurons via EAAC1 contributes to neuronal antioxidant function by providing cysteine substrate for glutathione synthesis. Mice in which the EAAC1 gene has been deleted were seen to have enhanced susceptibility to neuronal oxidative stress and developed brain atrophy and cognitive function decline with aging. The aim of the current study was to evaluate if EAAC1 confers protection against ischemic events. Young adult CD-1 wild-type or EAAC1(-/-) mice were subjected to 30 min of bilateral common carotid artery occlusion and evaluated for neuronal death and zinc translocation. The intensity of TSQ fluorescence in the cytoplasm of cortical neurons in the EAAC1(-/-) mice was significantly higher than wild-type mice, indicating that the cortical neurons of EAAC1(-/-) mice contain higher cytoplasmic concentrations of labile (or free) zinc. Zinc translocation into cortical neurons was also enhanced in EAAC1(-/-) mice. Three days after ischemia, Fluoro-Jade B staining revealed that EAAC1(-/-) mice had more than twice as many degenerating neurons as wild-type mice. N-acetylcysteine, a membrane-permeant cysteine pro-drug, normalized basal zinc levels, reduced TSQ (+) neurons and reduced ischemic neuronal death in the EAAC1(-/-) mice when delivered in a pre-treatment fashion. Taken together, this study implicates EAAC1-dependent cysteine uptake as an endogenous source of enhancing antioxidant function and zinc homeostasis in neurons in the ischemic brain.     

Role of glutamate transporters in the regulation of glutathione levels in human macrophages

Cysteine is the limiting precursor forglutathione synthesis. Because of its low bioavailability, cysteine isgenerally produced from cystine, which may be taken up through twodifferent transporters. The cystine/glutamate antiporter(x system) transports extracellular cystine inexchange for intracellular glutamate. The X_AG transportsystem takes up extracellular cystine, glutamate, and aspartate. Bothare sensitive to competition between cystine and glutamate, and excessextracellular glutamate thus inhibits glutathione synthesis, anonexcitotoxic mechanism for glutamate toxicity. We demonstratedpreviously that human macrophages express the glutamate transportersexcitatory amino acid transporter (EAAT)1 and EAAT2 (which do nottransport cystine, X system) and overcomecompetition for the use of cystine transporters. We now showthat macrophages take up cystine through the x andnot the X_AG system. We also found that glutamate, although competing with cystine uptake, dose-dependently increases glutathione synthesis. We used inhibitors to demonstrate that this increase ismediated by EAATs. EAAT expression in macrophages thus leads toglutamate-dependent enhancement of glutathione synthesis by providingintracellular glutamate for direct insertion in glutathione and alsofor fueling the intracellular pool of glutamate andtrans-stimulating the cystine/glutamate antiporter.

     

The oxidative stress-inducible cystine/glutamate antiporter, system x c ? : cystine supplier and beyond

The oxidative stress-inducible cystine/glutamate exchange system, system x_c⁻, transports one molecule of cystine, the oxidized form of cysteine, into cells and thereby releases one molecule of glutamate into the extracellular space. It consists of two protein components, the 4F2 heavy chain, necessary for membrane location of the heterodimer, and the xCT protein, responsible for transport activity. Previously, system x_c⁻ has been regarded to be a mere supplier of cysteine to cells for the synthesis of proteins and the antioxidant glutathione (GSH). In that sense, oxygen, electrophilic agents, and bacterial lipopolysaccharide trigger xCT expression to accommodate with increased oxidative stress by stimulating GSH biosynthesis. However, emerging evidence established that system x_c⁻ may act on its own as a GSH-independent redox system by sustaining a redox cycle over the plasma membrane. Hallmarks of this cycle are cystine uptake, intracellular reduction to cysteine and secretion of the surplus of cysteine into the extracellular space. Consequently, increased levels of extracellular cysteine provide a reducing microenvironment required for proper cell signaling and communication, e.g. as already shown for the mechanism of T cell activation. By contrast, the enhanced release of glutamate in exchange with cystine may trigger neurodegeneration due to glutamate-induced cytotoxic processes. This review aims to provide a comprehensive picture from the early days of system x_c⁻ research up to now.     

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.     

Cystine/cysteine metabolism in cultured Sf9 cells: influence of cell physiology on biosynthesis, amino acid uptake and growth

Spodoptera frugiperda (Sf9) insect cells proliferate in a cystine-free medium, with the same growth rate, reaching the same final cell density, as in a cystine-containing medium, provided that the inoculum is taken from a pre-culture sufficiently early, at 47–53 h. With an inoculum from a 103 h culture an extended lag phase accompanied by cell death was observed during the first 50 h of cystine-free culture, even though the culture had been adapted to cystine-free conditions for 10 passages. Cystine-free cultures seeded with a 103 h inoculum had lower growth rates and reached lower final cell densities than corresponding cystine-supplied cultures. Cysteine biosynthesis occurs from methionine via the β-cystathionine pathway. More methionine was consumed by the cells in cystine-free media, and cystathionine was secreted when methionine and cystine were supplied in excess. The data suggest that cysteine biosynthesis is up-regulated in proliferating cells but down-regulated when the cells enter the stationary phase. In cultures supplied with cystine (10–100 mg 1^-1), the specific uptake rate and total consumption of cystine, as well as the uptake of glutamate, glutamine and glucose increased with increasing cystine concentrations. These results are interpreted in view of system x _c ^– , a concentration dependent amino acid transporter. Similarly, the consumption of amino acids transported by system L (ile, leu, val, tyr) was enhanced in cystine-containing cultures, as compared to cystine-free cultures. Uptake of cystine, methionine and system L amino acids ceases abruptly in all cultures, even before growth ceased. The specific growth rate starts to decline early during the growth phase, but this growth behaviour could not be correlated to the depletion of nutrients. We therefore propose that the observed growth pattern is a result of (auto)regulatory events that control both proliferation and metabolism. This revised version was published online in August 2006 with corrections to the Cover Date.