The occurrence of cystinylglycine in blood plasma.

Cystinylglycine has been identified as a minor ninhydrin-positive component of deproteinized blood plasma from human, bovine, rat and rabbit blood. The amount present in human blood plasma is approximately one-fifth of that of cystine and is not significantly correlated with age or with the cystine level.     

Low membrane transport activity for cystine in resting and mitogenically stimulated human lymphocyte preparations and human T cell clones.

In order to determine whether the cysteine requirement of human T lineage cells is met primarily by extracellular cysteine or by cystine, amino-acid-transport activities were measured in resting and mitogenically stimulated human peripheral blood lymphocytes (PBL) and several human T cell clones and T cell tumors. The transport activity of the small neutral amino acids cysteine and alanine (ASC system) and the transport of the cationic amino acid arginine (y+ system) were found to be markedly increased after stimulation of PBL by the T cell mitogen phytohemagglutinin from Phaseolus vulgaris. The anionic transport activity for cystine and glutamate (Xc- system), in contrast, was extremely weak in both resting and activated human PBL and also in all human T cell lines under test. The weak system Xc- activity of human T lineage cells was further confirmed by an independent line of experiments showing that an increase of the extracellular concentration of glutamate, i.e. a competitive inhibitor of cystine transport, causes a decrease in the intracellular cystine levels in cells of the promonocytic line U937, but not in T lineage cells (Molt-4). A third set of experiments showed that the rate of DNA synthesis in mitogenically stimulated human PBL is strongly influenced by variations of the extracellular cysteine level, even in cultures with relatively high and approximately physiological concentrations of cystine. Cysteine cannot be replaced in this case by the addition of corresponding amounts of cystine or methionine. This demonstrates an important functional consequence of the weak cystine transport activity of human lymphocytes. The results may be relevant for the pathogenetic mechanism of the acquired immunodeficiency syndrome, since the mean plasma cysteine concentration of human-immunodeficiency-virus-1-seropositive persons was found to be strongly decreased in comparison with that of healthy blood donors, and since the cysteine level even of healthy persons is extremely low in comparison with all other protein-forming amino acids.     

Role of N-acetylcysteine and cystine in glutathione synthesis in human erythrocytes

Abstract

Glutathione is an intracellular antioxidant that often becomes depleted in pathologies with high oxidative loads. We investigated the provision of cysteine for glutathione synthesis to the human erythrocyte (red blood cell; RBC). Almost all plasma cysteine exists as cystine, its oxidized form. In vitro, extracellular cystine at 1.0 mM sustained glutathione synthesis in glutathione-depleted RBCs, at a rate of 0.206 ± 0.036 μmol (L RBC)^?1min^?1 only 20% of the maximum rate obtained with cysteine or N-acetylcysteine. In plasma-free solutions, N-acetylcysteine provides cysteine by intracellular deacetylation but to achieve maximum rates of glutathione synthesis by this process in vivo, plasma N-acetylcysteine concentrations would have to exceed 1.0 mM, which is therapeutically unattainable. ¹H-NMR experiments demonstrated that redox exchange reactions between NAC and cystine produce NAC-cysteine, NAC-NAC and cysteine. Calculations using a mathematical model based on these results showed that plasma concentrations of N-acetylcysteine as low as 100 μM, that are attainable therapeutically, could potentially react with plasma cystine to produce ～50 μM cysteine, that is sufficient to produce maximal rates of glutathione synthesis. We conclude that the mechanism of action of therapeutically administered N-acetylcysteine is to reduce plasma cystine to cysteine that then enters the RBC and sustains glutathione synthesis.     

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.     

Exchange of cystine and glutamate across plasma membrane of human fibroblasts

It is found that both the inward and outward transport of cystine and glutamate through the plasma membrane of cultured human fibroblasts is mediated mostly by a single transport system. Cystine and glutamate at one side of the membrane stimulate the passage of these amino acids present at the other side of the membrane. When the concentration of intracellular glutamate is reduced to near zero, cystine hardly enters the cell, and likewise the release of glutamate from the cell ceases when cystine is absent in the medium. Homocysteate and alpha-aminoadipate share this transport system and, when added, similarly participate in the transport process. Since the intracellular pool of cystine is negligibly small whereas that of glutamate is very large, the physiologic flows via this system are the entry of cystine and the exodus of glutamate coupled together. Measurements of the rate of uptake of cystine into the cells and the rate of release of glutamate from the cells indicate that the entry of cystine and the exodus of glutamate occur at a ratio close to 1:1. Since cystine is known to behave as an anionic form in this transport, it is concluded that the transport system for cystine and glutamate in plasma membrane of human fibroblasts is a kind of an anion-exchanging agency.     

Mechanism of cystine reaccumulation by cystinotic fibroblastsin vitro

It is well established that when cystine-depleted cystinotic cells are cultured in cystine-containing medium, they reaccumulate cystine within their lysosomes more rapidly than when cultured in cystine-free medium. This has been a puzzling result, since the lysosome membrane of cystinotic cells is impermeable to cystine. To probe the mechanism of cystine reaccumulation, we have measured reaccumulation in the presence of colchicine, an inhibitor of pinocytosis, or of glutamate, a competitive inhibitor of cystine transport into human fibroblasts. Colchicine had no effect, thus eliminating pinocytosis as a putative mechanism for cystine translocation from the culture medium to the lysosomes. Glutamate, however, strongly inhibited cystine reaccumulation. It is concluded that the true mechanism is as follows. 1. Exogenous cystine crosses the plasma membrane on the cystine-glutamate porter. 2. Cystine is reduced in the cytoplasm by GSH. 3. The cysteine that is generated enters the lysosome, where it becomes cystine by participating in the reduction of cystine residues during intralysosomal proteolysis, or by autoxidation.     

A novel function of glutamine in cell culture: utilization of glutamine for the uptake of cystine in human fibroblasts

Transport and metabolism of glutamine has been investigated in human diploid fibroblasts, IMR-90. Glutamine was taken up via System ASC (Na+-dependent amino acid transport system especially reactive with short or polar side chain amino acids). In the routine culture medium the cells contained a large quantity of glutamate; its major source was shown to be glutamine in the medium. Previously we described a transport system that mediates the entrance of cystine in exchange for the exit of glutamate (Bannai, 1986). Since the cystine taken up is reduced to cysteine and the cysteine readily exits to the medium where it is oxidized to cystine, a cystine-cysteine cycle across the plasma membrane has been postulated. When the cells were cultured in glutamate/glutamine-free medium, intracellular glutamate decreased, depending on the amount of cystine in the medium; in the absence of cystine, glutamate decreased very slowly. When the cells were cultured in ordinary medium, glutamine in the medium decreased, and glutamate in the medium increased. Both changes were well correlated with cystine concentration in the medium. These results are consistent with the view that the intracellular glutamate, of which the source is glutamine in the medium, is released from the cells into the medium in order to take up cystine and thereby to rotate the cystine-cysteine cycle. In the routine culture one-third to one-half of the total consumption of glutamine seems to be used for the uptake of cystine.     

Induction of cystine transport activity in human fibroblasts by oxygen

The transport activity for cystine in cultured human fibroblasts decreased after incubation of the cells under a low oxygen concentration. After the incubation for 48 h under 3% oxygen, the Vmax of the transport was decreased to less than one-third of that of the control cells, with little change in Km. The similar transport activity was observed in the cells cultured under 3% oxygen for 10-40 days with several times of passages. When these low oxygen-cultured cells were incubated under room air, the activity was enhanced with a lag of about 4 h and was almost completely restored within 24 h. This restoration required protein synthesis. The cystine transport activity increased by 50% after exposure of the cells to hyperoxia (40% oxygen). From these results it is concluded that the transport activity for cystine is induced by oxygen. In contrast, little change in the transport activities for alanine and leucine occurred in the cells exposed to the corresponding hypoxia or hyperoxia. Since the cystine transported into the cells is reduced to cysteine and the cysteine readily exits to the culture medium where it autoxidizes to cystine, a cystine-cysteine cycle across the plasma membrane has been postulated. Since the autoxidation of cysteine in the culture medium was markedly slowed down under the low oxygen concentration, the change in the cystine transport activity in response to the oxygen concentration was regarded as pertinent. Induction of the cystine transport activity may constitute a protective mechanism against the oxidative stress, to which the culture cells are exposed, by providing the cells with cysteine which is mainly incorporated into glutathione.     

CgCYN1, a plasma membrane cystine-specific transporter of Candida glabrata with orthologues prevalent among pathogenic yeast and fungi

We describe a novel plasma membrane cystine transporter, CgCYN1, from Candida glabrata, the first such transporter to be described from yeast and fungi. C. glabrata met15Δ strains, organic sulfur auxotrophs, were observed to utilize cystine as a sulfur source, and this phenotype was exploited in the discovery of CgCYN1. Heterologous expression of CgCYN1 in Saccharomyces cerevisiae met15Δ strains conferred the ability of S. cerevisiae strains to grow on cystine. Deletion of the CgCYN1 ORF (CAGL0M00154g) in C. glabrata met15Δ strains caused abrogation of growth on cystine with growth being restored when CgCYN1 was reintroduced. The CgCYN1 protein belongs to the amino acid permease family of transporters, with no similarity to known plasma membrane cystine transporters of bacteria and humans, or lysosomal cystine transporters of humans/yeast. Kinetic studies revealed a K(m) of 18 ± 5 μM for cystine. Cystine uptake was inhibited by cystine, but not by other amino acids, including cysteine. The structurally similar cystathionine, lanthionine, and selenocystine alone inhibited transport, confirming that the transporter was specific for cystine. CgCYN1 localized to the plasma membrane and transport was energy-dependent. Functional orthologues could be demonstrated from other pathogenic yeast like Candida albicans and Histoplasma capsulatum, but were absent in Schizosaccharomyces pombe and S. cerevisiae.     

Alterations in the immune system in cats fed diets with excess cystine

As part of an ongoing biochemical study in nutrition we examined blood profiles, serum chemistry, lymphocyte transformation and lymphoid pathology in cats fed a diet containing 5% cystine with and without taurine. Automated blood counts of whole blood samples showed a decrease in red blood cell counts accompanied by a significant decrease in hemoglobin and hematocrit in cats fed 5% cystine in the absence of taurine compared to cats fed 0.05% taurine (control). A significant increase was noted in serum cholesterol in cats fed cystine and cystine/taurine compared to cats fed control diets. There were no significant differences in lymphocyte transformation using leukocytes isolated from the spleen and blood with the mitogens, phytohemagglutinin and pokeweed. However, lymphocyte transformation of both spleen and blood without mitogen from the excess cystine group were significantly higher than leukocytes from the 0.05% taurine group (control). Pathological examination of regional lymph nodes, livers, and spleens showed histological abnormalities in cats fed the excess cystine diet. These results indicate that there are alterations in the immune system of cats fed a diet containing 5% cystine with and without dietary taurine.     

Comparative genomic analysis of the eight-membered ring cystine knot-containing bone morphogenetic protein antagonists

TGF-beta family proteins with a cystine knot motif serve as ligands for diverse families of plasma membrane receptors. Bone morphogenetic protein (BMP) antagonists represent a subgroup of these proteins, some of which bind BMPs and antagonize their actions during development and morphogenesis. Availability of completed genome sequences from diverse organisms allows bioinformatic analysis of the evolution of BMP antagonists and facilitates their classification. Using a regular expression algorithm (http://BioRegEx.stanford.edu), an exhaustive search of the human genome identified all cystine knot-containing BMP antagonists. Based on the size of the cystine ring, these proteins were divided into three subfamilies: CAN (eight-membered ring), twisted gastrulation (nine-membered ring), as well as chordin and noggin (10-membered ring). The CAN family can be divided further into four subgroups based on a conserved arrangement of additional cysteine residues-gremlin and PRDC, cerberus and coco, and DAN, together with USAG-1 and sclerostin. We searched for orthologs of human BMP antagonists in the genomes of model organisms and analyzed their phylogenetic relationship. New human paralogs were identified together with the verification of orthologous relationships of known genes. We also discuss the physiological roles of the CAN subfamily of BMP antagonists and the associated genetic defects. Based on the known three-dimensional structure of key cystine knot proteins, we postulated disulfide bondings for eight-membered ring BMP antagonists to predict their potential folding and dimerization.     

Oxidative stresses induced the cystine transport activity in human erythrocytes

Cystine was transported into human erythrocytes in the presence of tertiary-butyl hydroperoxide (t-BH) or 1-chloro-2,4-dinitrobenzene (CDNB). The transport rate of cystine was dependent on the extracellular concentration of t-BH or CDNB, and on the incubation time. According to Dowex-1 column chromatography, the transported cystine was incorporated into fractions of glutathione disulfide (GSSG) and glutathione-S (GSH-S) conjugate. The transport of cystine was competitively inhibited by DL-homocystine and alanine. The inhibition rates by DL-homocystine and alanine were 75% and 68%, with similar Ki values of 0.7 mM and 0.6 mM, respectively. It is suggested that cystine transport is induced for glutathione synthesis when human erythrocytes are exposed to oxidative stresses. This transport system of cystine may serve as an emergency function in human erythrocytes.     

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.     

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.     

Low concentrations of acid-soluble thiol (cysteine) in the blood plasma of HIV-1-infected patients

Blood plasma samples from HIV-1-infected persons contain elevated glutamate concentrations up to 6-fold the normal level and relatively low concentrations of acid-soluble thiol (i.e. decreased cysteine concentrations). The intracellular glutathione concentration in peripheral blood-mononuclear cells (PBMC) and monocytes from HIV antibody-positive persons are also significantly decreased. Therapy with azidothymidine (AZT) causes a substantial recovery of the plasma thiol levels; but glutamate levels remain significantly elevated and intracellular glutathione levels remain low. Cell culture experiments with approximately physiological amino-acid concentrations revealed that variations of the extracellular cysteine concentration have a strong influence on the intracellular glutathione level and the rate of DNA synthesis [( 3H]thymidine incorporation) in T cell clones and human and murine lymphocyte preparations even in the presence of several-fold higher cystine and methionine concentrations. Cysteine cannot be replaced by a corresponding increase of the extracellular cystine or methionine concentration. These experiments suggest strongly that the low cysteine concentration in the plasma of HIV-infected persons may play a role in the pathogenetic mechanism of the acquired immunodeficiency syndrome.     

Nonxenobiotic manipulation and sulfur precursor specificity of human endothelial cell glutathione

Confluent human umbilical vein endothelial (HUVE) cells were readily (within 1 h) depleted of their glutathione (GSH) by diethylmaleate (0.1-1.0 mM), but dose-dependent cell detachment was noted. Buthionine sulfoximine (BSO, 25 microM) depleted cell GSH with sigmoidal kinetics, showing an initial half-life of depletion of 4-6 h and greater than 95% depletion by 48 h without morphological changes to the cells. However, BSO-dependent depletion of cell GSH was only partially reversible by cell washing and reincubation with complete medium. Likewise, incubation of the cells in sulfur-free medium depleted cell GSH again without morphological changes to the cells. However, unlike with BSO, these cells readily resynthesized GSH when resupplied with complete medium, fresh plasma, or whole blood, with a characteristic overloading of cell GSH (up to 200%) by 12 h. By use of the sulfur-free medium, it was shown that both cystine and cysteine are effective precursors to GSH synthesis in HUVE cells in culture and that cystine is the most likely precursor in vivo. During cystine-supported resynthesis of GSH, high levels of cysteine accumulated in the cells (up to 10% of total soluble free thiol). Physiologically relevant concentrations of extracellular GSH were not as effective as cystine or cysteine in stimulating GSH biosynthesis, whereas nonphysiologically high (mM) concentrations resulted in substantial elevation of GSH levels above those of control cells in a BSO-insensitive manner. These findings provide a simple methodology for the manipulation of HUVE cell GSH in studies of endothelial-specific oxidant toxicity and the sulfur dependence of the biochemistry and turnover of GSH in these human cells.     

The targeting of cystinosin to the lysosomal membrane requires a tyrosine-based signal and a novel sorting motif

Cystinosis is a lysosomal transport disorder characterized by an accumulation of intra-lysosomal cystine. Biochemical studies showed that the lysosomal cystine transporter was distinct from the plasma membrane cystine transporters and that it exclusively transported cystine. The gene underlying cystinosis, CTNS, encodes a predicted seven-transmembrane domain protein called cystinosin, which is highly glycosylated at the N-terminal end and carries a GY-XX-Phi (where Phi is a hydrophobic residue) lysosomal-targeting motif in its carboxyl tail. We constructed cystinosin-green fluorescent protein fusion proteins to determine the subcellular localization of cystinosin in transfected cell lines and showed that cystinosin-green fluorescent protein colocalizes with lysosomal-associated membrane protein 2 (LAMP-2) to lysosomes. Deletion of the GY-XX-Phi motif resulted in a partial redirection to the plasma membrane as well as sorting to lysosomes, demonstrating that this motif is only partially responsible for the lysosomal targeting of cystinosin and suggesting the existence of a second sorting signal. A complete relocalization of cystinosin to the plasma membrane was obtained after deletion of half of the third cytoplasmic loop (amino acids 280-288) coupled with the deletion of the GY-DQ-L motif, demonstrating the presence of the second signal within this loop. Using site-directed mutagenesis studies we identified a novel conformational lysosomal-sorting motif, the core of which was delineated to YFPQA (amino acids 281-285).     

Homocysteine and cysteine - albumin binding in homocystinuria: assessment of cysteine status and implications for glutathione synthesis?

Summary. Measurement of plasma total cysteine rather than free dimeric cystine gives a better indication of cysteine status in homocystinuric patients. This is the result of displacement of cysteine from albumin by homocysteine and is related to the plasma homocysteine concentration. In control subjects the free/bound cyst(e)ine ratio was independent of albumin and total cysteine concentrations. In homocystinuric (HCU) patients both free and total cyst(e)ine values differed significantly from control values (P < 0.001) but whilst free cystine considerably overlapped control values the total cysteine concentrations were almost invariably lower. The possible consequences of this on glutathione synthesis was explored by assay of plasma total glutathione but no evidence for glutathione deficiency was found. Measurement of total cysteine, rather than free cystine, provides a better indication of cysteine status in HCU. Received February 1, 2001 Accepted November 13, 2001     

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.     

Abnormal amino-acid concentrations in the blood of patients with acquired immunodeficiency syndrome (AIDS) may contribute to the immunological defect

The acquired immunodeficiency syndrome (AIDS) is accompanied by a metabolic disturbance. Serum samples from persons with antibodies against the AIDS associated human immunodeficiency virus (HIV/LAV/HTLV III) including persons without overt symptoms, patients with lymphadenopathy syndrome (LAS) and patients with AIDS or AIDS-related complex (ARC) contain on the average significantly elevated concentrations of arginine and glutamate. The serum from patients with overt AIDS contains also, on the average, significantly reduced concentrations of methionine and cystine. In vitro experiments revealed that the [3H]thymidine incorporation by mitogenically stimulated murine lymphocytes and cloned T cells is inhibited by an elevation of the extracellular glutamate concentration and augmented by the addition of cysteine. This suggests the possibility that the abnormal concentrations of glutamate and cystine in the blood of HIV-infected persons may contribute to the defect in the lymphoid system.