Cysteine Sulphinic Acid Research Articles

Hepatic cysteine sulphinic acid decarboxylase depletion and defective taurine metabolism in a rat partial nephrectomy model of chronic kidney disease

BackgroundTaurine depletion occurs in patients with end-stage chronic kidney disease (CKD). In contrast, in the absence of CKD, plasma taurine is reported to increase following dietary L-glutamine supplementation. This study tested the hypothesis that taurine biosynthesis decreases in a rat CKD model, but is rectified by L-glutamine supplementation.MethodsCKD was induced by partial nephrectomy in male Sprague-Dawley rats, followed 2 weeks later by 2 weeks of 12% w/w L-glutamine supplemented diet (designated NxT) or control diet (NxC). Sham-operated control rats (S) received control diet.ResultsTaurine concentration in plasma, liver and skeletal muscle was not depleted, but steady-state urinary taurine excretion (a measure of whole-body taurine biosynthesis) was strongly suppressed (28.3 ± 8.7 in NxC rats versus 78.5 ± 7.6 μmol/24 h in S, P < 0.05), accompanied by reduced taurine clearance (NxC 0.14 ± 0.05 versus 0.70 ± 0.11 ml/min/Kg body weight in S, P < 0.05). Hepatic expression of mRNAs encoding key enzymes of taurine biosynthesis (cysteine sulphinic acid decarboxylase (CSAD) and cysteine dioxygenase (CDO)) showed no statistically significant response to CKD (mean relative expression of CSAD and CDO in NxC versus S was 0.91 ± 0.18 and 0.87 ± 0.14 respectively). Expression of CDO protein was also unaffected. However, CSAD protein decreased strongly in NxC livers (45.0 ± 16.8% of that in S livers, P < 0.005). L-glutamine supplementation failed to rectify taurine biosynthesis or CSAD protein expression, but worsened CKD (proteinuria in NxT 12.5 ± 1.2 versus 6.7 ± 1.5 mg/24 h in NxC, P < 0.05).ConclusionIn CKD, hepatic CSAD is depleted and taurine biosynthesis impaired. This is important in view of taurine’s reported protective effect against cardio-vascular disease - the leading cause of death in human CKD.

Structure and substrate specificity determinants of the taurine biosynthetic enzyme cysteine sulphinic acid decarboxylase

Pyridoxal 5́-phosphate (PLP) is an important cofactor for amino acid decarboxylases with many biological functions, including the synthesis of signalling molecules, such as serotonin, dopamine, histamine, γ-aminobutyric acid, and taurine. Taurine is an abundant amino acid with multiple physiological functions, including osmoregulation, pH regulation, antioxidative protection, and neuromodulation. In mammalian tissues, taurine is mainly produced by decarboxylation of cysteine sulphinic acid to hypotaurine, catalysed by the PLP-dependent cysteine sulphinic acid decarboxylase (CSAD), followed by oxidation of the product to taurine. We determined the crystal structure of mouse CSAD and compared it to other PLP-dependent decarboxylases in order to identify determinants of substrate specificity and catalytic activity. Recognition of the substrate involves distinct side chains forming the substrate-binding cavity. In addition, the backbone conformation of a buried active-site loop appears to be a critical determinant for substrate side chain binding in PLP-dependent decarboxylases. Phe94 was predicted to affect substrate specificity, and its mutation to serine altered both the catalytic properties of CSAD and its stability. Using small-angle X-ray scattering, we further showed that CSAD presents open/close motions in solution. The structure of apo-CSAD indicates that the active site gets more ordered upon internal aldimine formation. Taken together, the results highlight details of substrate recognition in PLP-dependent decarboxylases and provide starting points for structure-based inhibitor design with the aim of affecting the biosynthesis of taurine and other abundant amino acid metabolites.

The possible role of dermatophyte cysteine dioxygenase in keratin degradation

Cysteine dioxygenase (CDO, EC 1.13.11.20) is a key enzyme involved in the homeostatic regulation of cysteine level and in production of important oxidized metabolites of cysteine such as pyruvate, sulphite, sulphate, hypotaurine, and taurine in all eukaryotic cells. The intracellular CDO concentration is regulated at both transcriptional and posttranslational levels. In several fungi, CDO plays an important role as a virulence factor involved in morphological transition from yeast to mycelial forms. CDO is crucial for oxidation of cysteine to cysteine sulphinic acid and therefore for sulphite production and secretion. Because sulphite cleaves disulphide bridges as a first unavoidable step in keratinolysis, it is hypothesized that in dermatophytes, CDO is a virulence factor crucial for keratin degradation.

Novel Oxidative Modifications in Redox-Active Cysteine Residues

Redox-active cysteine, a highly reactive sulfhydryl, is one of the major targets of ROS. Formation of disulfide bonds and other oxidative derivatives of cysteine including sulfenic, sulfinic, and sulfonic acids, regulates the biological function of various proteins. We identified novel low-abundant cysteine modifications in cellular GAPDH purified on 2-dimensional gel electrophoresis (2D-PAGE) by employing selectively excluded mass screening analysis for nano ultraperformance liquid chromatography-electrospray-quadrupole-time of flight tandem mass spectrometry, in conjunction with MODi and MODmap algorithm. We observed unexpected mass shifts (Δm=-16, -34, +64, +87, and +103 Da) at redox-active cysteine residue in cellular GAPDH purified on 2D-PAGE, in oxidized NDP kinase A, peroxiredoxin 6, and in various mitochondrial proteins. Mass differences of -16, -34, and +64 Da are presumed to reflect the conversion of cysteine to serine, dehydroalanine (DHA), and Cys-SO2-SH respectively. To determine the plausible pathways to the formation of these products, we prepared model compounds and examined the hydrolysis and hydration of thiosulfonate (Cys-S-SO2-Cys) either to DHA (Δm=-34 Da) or serine along with Cys-SO2-SH (Δm=+64 Da). We also detected acrylamide adducts of sulfenic and sulfinic acids (+87 and +103 Da). These findings suggest that oxidations take place at redox-active cysteine residues in cellular proteins, with the formation of thiosulfonate, Cys-SO2-SH, and DHA, and conversion of cysteine to serine, in addition to sulfenic, sulfinic and sulfonic acids of reactive cysteine.

Isolation of recombinant cysteine dioxygenase protein from Trichophyton mentagrophytes

Cysteine dioxygenase (CDO, EC 1.13.11.20) catalyses the oxygenation of cysteine to cysteine sulphinic acid leading to the production of sulphite, sulphate and taurine as the final metabolites of cysteine catabolism. Keratinolytic fungi secrete sulphite and sulphate to reduce disulphide bridges in host tissue keratin proteins as the first step of keratinolysis. In the present study, we describe the identification of cDNA, as well as expression and characterisation of recombinant CDO protein from Trichophyton mentagrophytes. The cDNA was amplified using primers designed on the basis of high conservancy CDO regions identified in other fungi. PCR product was cloned and sequenced. Recombinant CDO was expressed in Escherichia coli, and affinity purified and identified by matrix-assisted laser desorption/ionization - time-of-flight mass spectrometry (MALDI-TOF MS). Enzyme activity was assayed by monitoring the production of cysteine sulphinate using mass spectrometry. The Cdo cDNA encodes for a protein consisting of 219 amino acids. Recombinant CDO protein C-terminally fused with a His tag was purified by affinity chromatography. The CDO purified under native condition was proved to be enzymatically active. Protein identity was confirmed by MALDI-TOF MS. Comparison of cDNA sequence with those identified in other fungi revealed significant homology. Identification of T. mentagrophytes CDO provides indispensable tools for future studies of dermatophyte pathogenicity and development of new approaches for prevention and therapy.

Taurine

Taurine, a sulfur-containing amino acid (Figure), has been termed a functional nutrient that could be used to protect against, among others, diabetes mellitus and atherosclerosis.1 Indeed, an increasing body of literature supports the use of taurine supplements. Because taurine has very diverse functions, notably, intracellular osmoregulation and bile acid formation, and is abundantly present in several organs, multiple pathways could be involved. Some of these are discussed in this editorial. Figure. A simplified biosynthesis pathway from methionine to taurine. Methionine is converted to homocysteine in 3 steps. Homocysteine is used as a substrate to form cysteine in 2 steps but can also be converted back to methionine by 2 different mechanisms. Cysteine, precursor for the important antioxidant glutathione and the gaseous transmitter/signaling molecule H2S, can be further converted to cysteine sulfinate. Cysteine sulfinate is converted to taurine in 2 steps via 2 different pathways. Taurine can decrease methionine by decreasing uptake. Whether taurine decreases homocysteine directly or via a reduction of methionine is unclear. Of the 20 canonical amino acids, 18 are composed of carbon, hydrogen, nitrogen, and oxygen only. The remaining 2, methionine and cysteine, also contain 1 atom of sulfur. Because sulfur is not as electronegative as oxygen, the sulfur-containing amino acids play a key role in protein structure and synthesis.2 Methionine and cysteine also play important roles in cell metabolism. For instance, methionine serves as a substrate for S-adenosylmethionine, which is vital for methylation of nucleic acids, proteins, lipids, etc. In proteins, cysteine easily forms double bonds with other cysteine residues, thus determining tertiary structure and binding sites. Moreover, cysteine is substrate for glutathione, an important intracellular antioxidant, and H2S, a gas that can induce endothelial-dependent relaxation.3 Cysteine is considered a nonessential amino acid because it is synthesized …

Oxidant‐dependent switching between reversible and sacrificial oxidation pathways for Bacillus subtilis OhrR

The Bacillus subtilis OhrR protein functions as a transcriptional repressor of the inducible peroxidase, OhrA. Derepression is mediated by the organic-peroxide selective oxidation of an active site cysteine (C15). In the presence of cumene hydroperoxide (CHP), oxidation of OhrR leads to a sulphenic acid intermediate which reacts to form either a mixed-disulphide or a protein sulphenamide. These inactive forms of OhrR can be reactivated by thiol-disulphide exchange reactions allowing restoration of repression. Here, we demonstrate that linoleic acid hydroperoxide (LHP) is a potent oxidant for OhrR and even low levels lead to overoxidation of OhrR to cysteine sulphinic (and sulphonic) acid derivatives. Kinetic competition experiments indicate that further oxidation of the initial OhrR sulphenate product occurs at least 100-fold more rapidly with LHP than with CHP. Thus, depending on the oxidant, OhrR can be either reversibly oxidized or can instead function as a sacrificial regulator.

The protective effect of hypotaurine and cysteine sulphinic acid on peroxynitrite-mediated oxidative reactions

The protective activity of hypotaurine (HTAU) and cysteine sulphinic acid (CSA) on peroxynitrite-mediated oxidative damage has been assessed by monitoring different target molecules, i.e. tyrosine, dihydrorhodamine-123 (DHR) and glutathione (GSH). The inhibition of tyrosine oxidation exerted by HTAU and CSA both in the presence and the absence of bicarbonate can be ascribed to their ability to scavenge hydroxyl (•OH) and carbonate (CO3•−) radicals. HTAU and CSA also reduce tyrosyl radicals, suggesting that this repair function of sulphinates might operate as an additional inhibiting mechanism of tyrosine oxidation. In the peroxynitrite-dependent oxidation of DHR, the inhibitory effect of HTAU was lower than that of CSA. Moreover, while HTAU and CSA competitively inhibited the direct oxidation of GSH by peroxynitrite, HTAU was again poorly effective against the oxidation of GSH mediated by peroxynitrite-derived radicals. The possible involvement of secondary reactions, which could explain the difference in antioxidant activity of HTAU and CSA, is discussed.

Taurine Intestinal Absorption and Renal Excretion Test in Diabetic Patients

There is evidence that diabetes is characterized by taurine deficiency (1–4), which has been linked to diabetic retinopathy, neuropathy, and nephropathy (5–7). Taurine is involved in neuronal modulation, osmoregulation (8), and protection against oxidative stress (9). Its plasma levels are maintained within a normal range through protein intake, and de novo synthesis is limited by the activity of hepatic cysteinesulphinic acid decarboxylase, which is low in humans. Taurine depletion can occur rapidly (10), possibly leading to retinal, cardiac, neural, immune, and hemostatic dysfunction (4,11–14). The reasons for taurine deficiency in diabetes remain unclear. A decrease in the overall body pool (1,2) and/or internal redistribution between the intra- and extracellular compartments are possibilities. The former can be secondary to decreased oral intake, poor intestinal absorption, renal wasting, or a combination of factors. In diabetic rats, intestinal absorption of taurine is reduced (K.B., Camille Nassar, unpublished data), while urinary taurine excretion is enhanced (15). Kidney loss in uncontrolled diabetes is aggravated by severe hyperglycemia and ketoacidosis (4). Data are lacking, however, on urinary excretion and pharmacokinetics of taurine absorption in human diabetes with mild-to-moderate hyperglycemia. This pilot study was therefore conducted in patients with moderately impaired glucose control and in matched nondiabetic subjects to evaluate the pharmacokinetics of taurine absorption following an oral load and to elucidate the mechanism of taurine deficiency in diabetes. A total of 16 subjects were enrolled in the study: 6 patients with type 2 diabetes, 2 with type 1 diabetes, and 8 healthy subjects; subjects were pair-matched for age, sex, and BMI. …

Homocysteine and other structurally-diverse amino thiols can alter pancreatic beta cell function without evoking cellular damage

Homocysteine and related amino thiols, homocysteic acid, cysteic acid, homocysteine sulphinic acid and cysteine sulphinic acid have been labelled as neurotoxins. Homocysteine thiolactone, a metabolic derivative of homocysteine, is cytotoxic to endothelial cells and other cell lineages. Since pancreatic beta cells share many phenotypic similarities with neuronal cells, the present study uses clonal pancreatic BRIN-BD11 cells to investigate possible detrimental effects of these amino thiols on insulin secretion and pancreatic beta cell function. Insulin secretion was concentration-dependently inhibited at both basal (1.1 mM) and stimulatory (16.7 mM) glucose by homocysteine, homocysteine thiolactone and homocysteine sulphinic acid. Cysteic acid concentration-dependently inhibited insulin secretion at 16.7 mM glucose. Cell viability was not compromised by any of the amino thiols. Insulin secretory responses to alanine were inhibited by homocysteine, homocysteine thiolactone, homocysteic acid and cysteic acid. Insulin secretion in the presence of elevated Ca 2+ and forskolin were lowered by all amino thiols, except homocysteic acid. The secretory responsiveness to PMA, GLP-1 and KCl were only impaired in the presence of homocysteine and homocysteine thiolactone. These findings indicate that homocysteine, homocysteine thiolactone and, to a lesser extent, other amino thiols cause dysfunctional insulin secretion from pancreatic beta cells.

Multistep enzyme catalysed deracemisation of 2-naphthyl alanine

Kinetic parameters of d-amino acid oxidase from R. gracilis (DAAO) towards d-2-naphthyl alanine (d-2-NAla) and of l-aspartate amino transferase (l-AAT) from Escherichia coli towards 2-naphthyl pyruvate (2-NPA) were measured. The two enzymes were then combined in a one-pot reaction in which DAAO was used to generate 2-NPA which was the substrate of l-AAT in the presence of cysteine sulphinic acid (CSA) as an amino donor. The combined reactions afforded enantiomerically pure l-2-NAla in almost quantitative yield. The extremely low water solubility of 2-NAla can be partially overcome by running the biotransformation in suspension with higher formal concentration. In these conditions multiple enzyme additions are required.

Induction of Cysteine Dioxygenase Activity by Oral Administration of Cysteine Analogues to the Rat: Implications for Drug Efficacy and Safety

One of the major steps in the oxidation of the sulphur-containing amino acid, L-cysteine, is the production of cysteine sulphinic acid, catalysed by the enzyme cysteine dioxygenase. This enzyme plays a key role in the intermediary metabolism of sulphur-containing compounds. The activity of this crucial enzyme is known to be influenced by sulphur-compound intake, being increased in animals fed an excess of L-cysteine or methionine. However, the affects on this enzyme of the chronic administration of drugs similar in structure to cysteine are unknown. This has now been investigated using the anti-rheumatic agent, D-penicillamine, and the mucoactive compound, S-carboxymethyl-L-cysteine. Repeated oral administration of these sulphur-containing drugs to male Wistar rats for five consecutive days led to a significant increase in hepatic cysteine dioxygenase activity. This increase in the production rate of cysteine sulphinic acid remained evident until returning to control levels four days after cessation of drug administration. These observations provide evidence that these two drugs interact with the intermediary biochemistry of sulphur compounds and may provide hitherto unappreciated insights into mechanisms by which therapeutic effects and adverse reactions may occur.

Oxidation of hypotaurine and cysteine sulphinic acid by peroxynitrite

Peroxynitrite mediates the oxidation of the sulphinic group of both HTAU (hypotaurine) and CSA (cysteine sulphinic acid), producing the respective sulphonates, TAU (taurine) and CA (cysteic acid). The reaction is associated with extensive oxygen uptake, suggesting that HTAU and CSA are oxidized by the one-electron transfer mechanism to sulphonyl radicals, which may initiate an oxygen-dependent radical chain reaction with the sulphonates as final products. Besides the one-electron mechanism, HTAU and CSA can be oxidized by the two-electron pathway, leading directly to sulphonate formation without oxygen consumption. The apparent second-order rate constants for the direct reaction of peroxynitrite with HTAU and CSA at pH 7.4 and 25 degrees C are 77.4+/-5 and 76.4+/-9 M(-1).s(-1) respectively. For both sulphinates, the apparent second-order rate constants increase sharply with decrease in pH, and the sigmoidal curves obtained are consistent with peroxynitrous acid as the species responsible for sulphinate oxidation. The kinetic data, together with changes in oxygen uptake, sulphinate depletion, sulphonate production, and product distribution of nitrite and nitrate, suggest that oxidation of sulphinates by peroxynitrite may take place by the two reaction pathways whose relative importance depends on reagent concentrations and pH value. In the presence of bicarbonate, the direct reaction of sulphinates with peroxynitrite is inhibited and the oxidative reaction probably involves only the radicals *NO2 and CO3*-, generated by decomposition of the peroxynitrite-CO2 adduct.

ATP-dependent reduction of cysteine-sulphinic acid by S. cerevisiae sulphiredoxin.

Proteins contain thiol-bearing cysteine residues that are sensitive to oxidation, and this may interfere with biological function either as 'damage' or in the context of oxidant-dependent signal transduction. Cysteine thiols oxidized to sulphenic acid are generally unstable, either forming a disulphide with a nearby thiol or being further oxidized to a stable sulphinic acid. Cysteine-sulphenic acids and disulphides are known to be reduced by glutathione or thioredoxin in biological systems, but cysteine-sulphinic acid derivatives have been viewed as irreversible protein modifications. Here we identify a yeast protein of relative molecular mass M(r) = 13,000, which we have named sulphiredoxin (identified by the US spelling 'sulfiredoxin', in the Saccharomyces Genome Database), that is conserved in higher eukaryotes and reduces cysteine-sulphinic acid in the yeast peroxiredoxin Tsa1. Peroxiredoxins are ubiquitous thiol-containing antioxidants that reduce hydroperoxides and control hydroperoxide-mediated signalling in mammals. The reduction reaction catalysed by sulphiredoxin requires ATP hydrolysis and magnesium, involving a conserved active-site cysteine residue which forms a transient disulphide linkage with Tsa1. We propose that reduction of cysteine-sulphinic acids by sulphiredoxin involves activation by phosphorylation followed by a thiol-mediated reduction step. Sulphiredoxin is important for the antioxidant function of peroxiredoxins, and is likely to be involved in the repair of proteins containing cysteine-sulphinic acid modifications, and in signalling pathways involving protein oxidation.

Cysteine dioxygenase: regional localisation of protein and mRNA in rat brain.

Cysteine dioxygenase (CDO) converts cysteine to cysteinesulphinic acid and is the rate-limiting step in sulphate production. Most studies have centred upon the hepatic form of the enzyme, but several studies have investigated brain CDO using activity assays and western blotting. The aim of this study was to investigate the expression of CDO in the rat brain using a combination of immunohistochemistry and in situ hybridisation. Affinity-purified anti-R and anti-H CDO antibodies were immunoprecipitated using rat brain homogenate to determine whether the antibodies could remove enzyme activity. Immunohistochemistry and in situ hybridisation were then used to determine the cellular and regional expression of both CDO protein and mRNA. Immunoprecipitation of rat brain homogenate removed up to 98% and 70% (anti-R and anti-H, respectively) of enzyme activity. Nonimmune sheep serum had no effect upon enzyme activity. CDO protein and mRNA was localised solely to the neurones of the brain, including the pyramidal cells of the hippocampus and the Purkinje cells of the cerebellum. Regional localisation varied, with high levels of expression in the hippocampus, the dentate gyrus, the outer cortices of the brain, and the substantia nigra. The relative expression of CDO activity and protein in these regions is most probably a result of the relative abundance of neurones in these regions. CDO expression in the brain may have several possibilities functions, the most likely being the prevention of free radical production by the autoxidation of cysteine and dopamine.

Effects of methionine loading on plasma and erythrocyte sulphur amino acids and sulph-hydryls before and after co-factor supplementation in haemodialysis patients.

Hyperhomocysteinaemia, which is potentially atherogenic, is common in chronic haemodialysis (HD) patients but the reason for this is not yet known. The methionine (Met) loading test (MLT) is used to test the capacity of homocysteine (Hcy) disposal by the trans-sulphuration pathway and thus may provide information on the metabolism of sulphur amino acids. The availability of vitamin B(6) and folic acid, as co-factors for Hcy metabolism may affect the response to MLT. In the present study, we compared the effect of Met loading on plasma and erythrocyte (RBC) sulphur amino acids and sulph-hydryls before and after co-factor supplementation in healthy subjects and HD patients. In 10 HD patients and 10 healthy subjects the effect of Met loading, 0.1 g/kg BW, on plasma and RBC methionine metabolites was studied over 7 h, before and after 4 weeks supplementation with high daily doses of vitamin B(6) (200 mg) and folic acid (15 mg). MLT before vitamin supplementation in HD patients, compared to the healthy subjects, caused significantly greater increases in plasma Hcy levels (43+/-12 vs 15+/-5 micromol/l), cysteinesulphinic acid (CSA) (1.34 vs 0.36 micromol/l) and gamma-glutamylcysteine (0.98+/-0.83 vs -01+/-0.42 micromol/l) and no decline in plasma cysteine (Cys) (0.5+/-33.9 vs -31+/-26 micromol/l), but no significant differences in plasma taurine, cysteinylglycine, and glutathione concentrations. In RBCs there was a small increase in Hcy levels and a more marked increase in Tau levels, with no difference between the healthy subjects and HD patients. Vitamin supplementation in pharmacological doses failed to correct the abnormal responses to MLT in the HD patients. Oral methionine loading in HD patients leads to higher accumulation of Hcy and other Met metabolites in plasma and RBCs than in healthy subjects, indicating impaired metabolism of sulphur amino acids via the trans-sulphuration pathway. Supplementation with high doses of vitamin B(6) and folic acid does not correct this impairment, suggesting that it most probably is not due to lack of these co-factors.

Crystal structure of decameric 2-Cys peroxiredoxin from human erythrocytes at 1.7Å resolution

Background: The peroxiredoxins (Prxs) are an emerging family of multifunctional enzymes that exhibit peroxidase activity in vitro, and in vivo participate in a range of cellular processes known to be sensitive to reactive oxygen species. Thioredoxin peroxidase B (TPx-B), a 2-Cys type II Prx from erythrocytes, promotes potassium efflux and down-regulates apoptosis and the recruitment of monocytes by endothelial tissue. Results: The crystal structure of human decameric TPx-B purified from erythrocytes has been determined to 1.7Å resolution. The structure is a toroid comprising five dimers linked end-on through predominantly hydrophobic interactions, and is proposed to represent an intermediate in the in vivo reaction cycle. In the crystal structure, Cys51, the site of peroxide reduction, is oxidised to cysteine sulphinic acid. Cys172, the second catalytic cysteine residue, lies ∼10Å away from Cys51 and in this conformation of TPx-B is too distant to recycle the activity of Cys51. Conclusions: The oxidation of Cys51 appears to have trapped the structure into a stable decamer, as confirmed by sedimentation analysis. A comparison with two previously reported dimeric Prx structures reveals that the catalytic cycle of 2-Cys Prx requires significant conformational changes that include the unwinding of the active-site helix and the movement of four loops. It is proposed that the stable decamer forms in vivo under conditions of oxidative stress. Similar decameric structures of TPx-B have been observed by electron microscopy, which show the protein associated with the erythrocyte membrane.

Hepatic localisation of rat cysteine dioxygenase

Background/Aim: Cystein dioxygenase (CDO, E.C. 1.13.11.20) is the main catabolic enzyme of cysteine, metabolising cystein to cysteinesulphinic acid. CDO abnormality has been implicated in a number of neurologic and non-neurological diseases, with CDO deficiency possibly leading to excitotoxic damage to the brain and impaired Phase II metabolism in the liver. Methods: Two novel anti-CDO antibodies raised against linear synthetic peptides corresponding to two distinct epitopes on the 22 kDa gene product of the CDO-I gene were used for immunohistochemistry and Western blotting. These antibodies were characterised by their ability to both block and precipitate CDO enzyme activity as well as the ability of the respective antigenic peptides to absorb the antibodies and prevent the immunodetection of CDO. Results: The antibodies were found to detect the presence of a 68 kDa protein, which was subsequently shown to be CDO. Distribution was found to be centrilobular and did not alter when CDO was induced with cysteine or methionine; however, the intensity of staining increased, indicating an increase in the levels of CDO in that region. Conclusion: These results suggest that the 68 kDa Type II is the predominant isoform in vitro and in vivo and that is centrilobular localisation may allow CDO to initate the production of sulphate and taurine for Phase II conjugation in the liver.

Sulphur-containing amino acids are agonists for group 1 metabotropic receptors expressed in clonal RGT cell lines

Comparison of the pharmacological effects of a range of sulphur-containing amino acids on human mGluR1 α and mGluR5a has been undertaken. cDNAs of each mGluR were transfected into a Syrian hamster tumour cell line AV12-664 that was previously transfected with the rat glutamate–aspartate transporter protein (GLAST). The l-isomers of cysteine sulphinic acid (CSA), homocysteine sulphinic acid (HCSA), cysteic acid (CA) and serine- O-sulphate (SOS) stimulated PI hydrolysis in human mGluR1 α and mGluR5a cells with full agonist effects. d-CSA, the only active d-isomer, was a partial agonist for mGluR5a whereas l-sulphocysteine ( S-CYS) showed weak agonist-like effects at high concentrations on both mGluR1 α and mGluR5a. l-Homocysteic acid was inactive on both mGluR1 α and mGluR5a cells. Treatment of mGluR cultures with glutamate pyruvate transaminase did not alter the potencies of the S-amino acids on PI hydrolysis responses. Inhibitor constants ( K i) obtained for l-HCSA, l-CSA, l-CA and l-SOS in [ 3H]glutamate receptor binding studies with mGluR1 α cells indicated that l-HCSA, l-CSA, l-CA and l-SOS can bind specifically to mGluR1 with l-HCSA showing the highest affinity. These results confirm that certain endogenously produced S-amino acids may interact directly with group 1 mGluRs.

Total, free, and protein-bound sulphur amino acids in uraemic patients.

Fasting plasma concentrations of sulphur amino acids (sAA) were measured in nine non-dialysed (ND) chronic uraemic patients on conservative treatment, 10 patients on continuous ambulatory peritoneal dialysis (CAPD), nine patients on haemodialysis (HD) treatment, and 10 healthy subjects (HS). Methionine and taurine concentrations were significantly decreased in the CAPD and HD patients and tended to be low in the ND patients. Cysteine sulphinic acid (CSA) levels were significantly higher in all patient groups. Total (t), free (f), and protein-bound (pb) homocysteine (Hcy) and cysteine (Cys) were significantly increased in all patient groups. Serine, a substrate for cystathionine synthesis from Hcy, showed significantly lower concentrations in all patient groups. The percentages of pbHcy were significantly higher in the CAPD and HD patients than in the ND patients (P < 0.0001, P = 0.002 respectively) or in the HS (P < 0.0001, P = 0.008 respectively), whereas the percentages of pbCys in CAPD and HD patients were significantly higher than in ND patients (P = 0.0006, P = 0.009 respectively) and tended to be high without reaching statistical significance compared to the HS. A single HD treatment decreased tHcy by 26%, fHcy by 39%, and pbHcy by 22%, as well as tCys by 40%, fCys by 54%, and pbCys by 27%. The tHcy concentration, although decreased by HD treatment, remained higher than in HS, whereas tCys was normalized by the dialysis session. In addition, HD treatment significantly decreased the plasma concentrations of methionine, CSA, taurine, and serine. We conclude that, except for methionine and taurine, the plasma sAA in their different forms are markedly increased in dialysed and non-dialysed uraemic patients. The percentages of pbHcy and pbCys were significantly higher in dialysed than in ND uraemic patients. HD treatment can normalize the tCys concentration, and decrease the tHcy concentration but not normalize it. The observed hyperhomocysteineaemia and low taurine levels may contribute to the high incidence of cardiovascular disease in uraemic patients.