Roles of 1-Cys peroxiredoxin in haem detoxification in the human malaria parasite Plasmodium falciparum

In the present study, we investigated whether Plasmodium falciparum 1-Cys peroxiredoxin (Prx) (Pf1-Cys-Prx), a cytosolic protein expressed at high levels during the haem-digesting stage, can act as an antioxidant to cope with the oxidative burden of haem (ferriprotoporphyrin IX; FP). Recombinant Pf1-Cys-Prx protein (rPf1-Cys-Prx) competed with glutathione (GSH) for FP and inhibited FP degradation by GSH. When rPf1-Cys-Prx was added to GSH-mediated FP degradation, the amount of iron released was reduced to 23% of the reaction without the protein (P < 0.01). The rPf1-Cys-Prx bound to FP-agarose at pH 7.4, which is the pH of the parasite cytosol. The rPf1-Cys-Prx could completely protect glutamine synthetase from inactivation by the dithiothreitol-Fe(3+)-dependent mixed-function oxidation system, and it also protected enolase from inactivation by coincubation with FP/GSH. Incubation of white ghosts of human red blood cells and FP with rPf1-Cys-Prx reduced formation of membrane associations with FP to 75% of the incubation without the protein (P < 0.01). The findings of the present study suggest that Pf1-Cys-Prx protects the parasite against oxidative stresses by binding to FP, slowing the rate of GSH-mediated FP degradation and consequent iron generation, protecting proteins from iron-derived reactive oxygen species, and interfering with formation of membrane-associated FP.     

Interaction of antimony tartrate with the tripeptide glutathione implication for its mode of action.

The tripeptide glutathione (gamma-L-Glu-L-Cys-Gly, GSH) is thought to play an important role in the biological processing of antimony drugs. We have studied the complexation of the antileishmanial drug potassium antimony(III) tartrate to GSH in both aqueous solution and intact red blood cells by NMR spectroscopy and electrospray ionization mass spectrometry. The deprotonated thiol group of the cysteine residue is shown to be the only binding site for Sb(III), and a complex with the stoichiometry [Sb(GS)3] is formed. The stability constant for [Sb(GS)3] was determined to be log K 25 (I = 0.1 M, 298 K) based on a competition reaction between tartrate and GSH at different pH* values. In spite of being highly thermodynamically stable, the complex is kinetically labile. The rate of exchange of GSH between its free and Sb-bound form is pH-dependent, ranging from slow exchange on the 1H-NMR timescale at low pH (2 s-1 at pH 3.2) to relatively rapid exchange at biological pH (> 440 s-1). Such facile exchange may be important in the transport of Sb(III) in various biofluids and tissues in vivo. Our spin-echo 1H-NMR data show that Sb(III) rapidly entered red blood cell walls and was complexed by intracellular glutathione.     

Involvement of glutathione in the inhibition of sea urchin egg mitosis by phenyl glyoxal

Cell division in fertilized sea urchin eggs was reversibly inhibited when the ketoaldehyde phenyl glyoxal (PG) at a concentration of 0.1 mM was added to eggs for ten minutes prior to the formation of the mitotic spindle. We investigated whether inhibition of mitosis was due to PG binding to the cell surface (as previously suggested by Stein and Berestecky, '74) or to some intracellular effect. When 14C-PG was added to eggs, label was readily taken up into the egg cytoplasm; very little label was associated with the egg surface. In the cytoplasm PG combined with equimolar amounts of reduced glutathione (GSH), decreasing the levels of cellular GSH to less than 15% of normal and accounting for at least 50% of the PG taken up by eggs. The concentrations of oxidized and protein-bound glutathione were unaffected by PG treatment. We showed that glyoxalase enzymes were present in sea urchin eggs and were capable of metabolizing the PG-GSH complex, thereby restoring GSH to normal levels after PG was removed from the sea water. Though some other effect of PG cannot be ruled out, the major fate of PG in eggs was to combine with GSH, and the transient decrease in GSH which resulted could lead to inhibition of mitosis. While other reports (Nath and Rebhun, '76; Oliver et al., '76) have shown that reagents which oxidize GSH disrupt microtubule-related events, our results showed that such inhibition could be caused by decreased GSH levels alone.     

Effect of CdTe Quantum Dots Size on the Conformational Changes of Human Serum Albumin: Results of Spectroscopy and Isothermal Titration Calorimetry

Quantum dots (QDs) are recognized as some of the most promising candidates for future applications in biomedicine. However, concerns about their safety have delayed their widespread application. Human serum albumin (HSA) is the main protein component of the circulatory system. It is important to explore the interaction of QDs with HSA for the potential in vivo application of QDs. Herein, using spectroscopy and isothermal titration calorimetry (ITC), the effect of glutathione-capped CdTe quantum dots of different sizes on the HSA was investigated. After correction for the inner filter effect, the fluorescence emission spectra and synchronous fluorescence spectra showed that the microenvironment of aromatic acid residues in the protein was slightly changed when the glutathione (GSH)–cadmium telluride (CdTe) QDs was added, and GSH–CdTe QDs with larger particle size exhibited a much higher effect on HSA than the small particles. Although a ground-state complex between HSA and GSH–CdTe QDs was formed, the UV–vis absorption and circular dichroism spectroscopic results did not find appreciable conformational changes of HSA. ITC has been used for the first time to characterize the binding of QDs with HSA. The ITC results revealed that the binding was a thermodynamically spontaneous process mainly driven by hydrophobic interactions, and the binding constant tended to increase as the GSH–CdTe QDs size increased. These findings are helpful in understanding the bioactivities of QDs in vivo and can be used to assist in the design of biocompatible and stable QDs.     

Role of GSH in estrone sulfate binding and translocation by the multidrug resistance protein 1 (MRP1/ABCC1)

Multidrug resistance protein 1 (MRP1/ABCC1) is an ATP-dependent efflux pump that can confer resistance to multiple anticancer drugs and transport conjugated organic anions. Unusually, transport of several MRP1 substrates requires glutathione (GSH). For example, estrone sulfate transport by MRP1 is stimulated by GSH, vincristine is co-transported with GSH, or GSH can be transported alone. In the present study, radioligand binding assays were developed to investigate the mechanistic details of GSH-stimulated transport of estrone sulfate by MRP1. We have established that estrone sulfate binding to MRP1 requires GSH, or its non-reducing analogue S-methyl GSH (S-mGSH), and further that the affinity (Kd) of MRP1 for estrone sulfate is 2.5-fold higher in the presence of S-mGSH than GSH itself. Association kinetics show that GSH binds to MRP1 first, and we propose that GSH binding induces a conformational change, which makes the estrone sulfate binding site accessible. Binding of non-hydrolyzable ATP analogues to MRP1 decreases the affinity for estrone sulfate. However, GSH (or S-mGSH) is still required for estrone sulfate binding, and the affinity for GSH is unchanged. Estrone sulfate affinity remains low following hydrolysis of ATP. The affinity for GSH also appears to decrease in the post-hydrolytic state. Our results indicate ATP binding is sufficient for reconfiguration of the estrone sulfate binding site to lower affinity and argue for the presence of a modulatory GSH binding site not associated with transport of this tripeptide. A model for the mechanism of GSH-stimulated estrone sulfate transport is proposed.     

The role of SH-groups in the development sensitivity of ATPase in plasma membranes of plant cells to ions

The effects of the SH-groups binding agent p-chloromercurybenzoate (rho CMB) and the SH-containing compounds dithiothreitol (DTT), beta-mercaptoethanol (ME) and reduced glutathione (GSH) on activation by Mg2+ and K+ of ATPase in plasma membrane preparations from corn sprout root cells were studied. Rho CMB inhibited the ATPase activity, the degree of inhibition being directly dependent on the increase of the inhibitor concentration (from 10(-6) up to 10(-4) M); the inhibition was eliminated by the SH-containing agents (25 mM). DTT and ME added to the homogenization medium and ME added to the reaction mixture produced different effects on the ATPase activity of the membranes depending on the nature of the cations added. In the absence of the additives the ATPase activity was somewhat decreased, showing a sharp rise in the presence of Mg2+; an addition of K+ to a Mg2+-containing medium further increased the enzyme activity. GSH had no effect on the ATPase activation by the cations.     

Kinetics of Congo-red binding by haemin-limited and haemin-excess cells of Porphyromonas gingivalis W50

The binding of Congo red to P. gingivalis W50 grown in a chemostat under haemin-limitation and haemin-excess was quantified. Congo red bound to both haemin-excess and haemin-limited cells with similar capacity and affinity. Binding of Congo red was greater than for ferri- (haemin) or ferroprotoporphyrin IX (haem), and was not influenced by redox potential at low added ligand concentrations. Both haemin-limited and haemin-excess cells showed positive co-operativity towards Congo red binding. Pre-exposure of haemin-limited and haemin-excess cells to sub-saturating concentrations of ferriprotoporphyrin IX did not affect Congo red binding, whereas pre-exposure of haemin-excess cells to ferroprotoporphyrin IX increased binding. Iron protoporphyrin IX binding was enhanced after exposure of both haemin-excess and haemin-limited cells to Congo red, especially under reducing conditions. These results confirm that Congo red binding cannot be used as an indirect measure of haemin binding, nor can Congo red be used to inhibit haemin binding to P. gingivalis.     

A proton nuclear magnetic resonance study of the interaction of mercury with intact human erythrocytes

The binding of mercuric ion (Hg(II)) by small molecules in the intracellular region of intact human erythrocytes has been studied by ¹H-NMR spectroscopy. HgCl₂ added to intact erythrocytes in saline-glucose suspension is found to cross the membrane and reach an equilibrium distribution among the molecules of the erythrocyte within 4 min. In the intracellular region Hg(II) reacts with GSH and hemoglobin to form the ternary mixed-ligand complex GSH-Hg(II)-hemoglobin. The analogous complex with ergothioneine is formed after all the GSH is complexed. ¹H-NMR spectra show that the GSH-Hg(II)-hemoglobin complex also forms in simpler solutions containing HgCl₂, GSH and hemoglobin, whereas the complex Hg(GSH)₂ predominates in solutions of GSH and HgCl₂. The lifetime of the GSH in the GSH-Hg(II)-hemoglobin complex is shown to be less than 30 s, which provides direct evidence for the first time that Hg(II) complexes in biological systems are quite labile, even though their thermodynamic stability is large. The effectiveness of eight sulfhydryl-containing ligands, some of which have been used as antidotes for Hg(II) poisoning, for releasing GSH from its Hg(II) complex in hemolyzed erythrocytes was also studied. Dithiol ligands were found to be more effective than monothiols, with dithioerythritol the most effective of the dithiols.     

Quantitation of reduced and total glutathione at the femtomole level by high-performance liquid chromatography with fluorescence detection: application to red blood cells and cultured fibroblasts

A new rapid and highly sensitive HPLC method with ortho-phthalaldehyde (OPA) pre-column derivatization has been developed for determination of reduced glutathione (GSH) and total glutathione (GSHt) in human red blood cells and cultured fibroblasts. OPA derivatives are separated on a reversed-phase HPLC column with an acetonitrile–sodium acetate gradient system and detected fluorimetrically. An internal standard (glutathione ethyl ester) is added to facilitate quantitation. Total glutathione is determined after reduction of disulfide groups with dithiothreitol; the oxidized glutathione (GSSG) concentration is calculated by subtraction of the GSH level from the GSHt level. The assay shows high sensitivity (50 fmol per injection, the lowest reported), good precision (C.V. <5.0%), an analytical recovery of GSH and GSSG close to 100%, and linearity (r>0.999). This HPLC technique is very simple and rapid. Its wide applicability and high sensitivity make it a convenient and reliable method for glutathione determination in various biological samples.     

Partial characterization and detergent solubilization of the putative glutathione chemoreceptor from hydra.

Feeding behavior in hydra is initiated by the association of glutathione (GSH) with a putative external chemoreceptor. In the present study, the binding of [35S]GSH to hydra membranes has been characterized. Nondisplaceable [35S]GSH binding which compromised previous analyses [Grosvenor, W., Bellis, S., Kass-Simon, G., & Rhoads, D. (1992) Biochim. Biophys. Acta (in press)] was eliminated by treating membranes with an inhibitor of GSH metabolism, borate in combination with L-serine. The specific binding which was not inhibited by borate/serine demonstrated many of the characteristics expected of a ligand/receptor interaction. The binding was rapid, reversible, and saturable. A Scatchard analysis of saturation isotherms indicated a dissociation constant (KD) of 3.4 microM, a value which is in good agreement with concentrations of glutathione which are known to induce feeding behavior. Hydra membranes were detergent-solubilized with 10 mM 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS), 100 mM KCl, and 10% glycerol. The soluble fraction contained 40% of the original saturable, reversible GSH binding activity. The KD for GSH binding to the solubilized preparation was estimated as 2.7 microM, a valuable which is not appreciably different from the KD for binding to intact membranes. The fidelity of GSH binding in the solubilized preparation suggests that this preparation will be useful in further characterization of the putative glutathione chemoreceptor.     

Stability of etiochloroplasts isolated from pine cotyledons as studied by means of low temperature absorption and fluorescence spectroscopy

77 K absorption and fluorescence spectra are measured during incubation of etiochloroplast isolated from pine cotyledons and suspended in buffers with or without various co-factors (GSH, ATP, CoA) and NADPH. It is shown that, in the absence of co-factors, rapid spectral changes due to denaturation of the protein-pigment complexes occur. The spectral changes differ according to whether denaturation occurs in the light or in the dark. The rate of denaturation of the Ch1-protein complexes is significantly lowered when co-factors are added and a protective effect of NADPH on the PChlide-protein complexes was observed.

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Chemoreception in hydra: specific binding of glutathione to a membrane fraction.

Specific binding of reduced [35S]glutathione (GSH) was measured using a crude membrane fraction of Hydra vulgaris (attenuata). The specific binding shows both rapid displaceable and nondisplaceable components. Rapid displaceable binding accounted for 20% of the total specific binding. Data from saturation binding experiments indicates half maximal total specific binding occurs at 2 microM GSH which is similar to reported EC50 values from behavioral experiments. Calcium is required for displaceable binding of GSH to the putative receptor. Oxidized glutathione (GSSG), an antagonist of the GSH-activated feeding response, and S-methylglutathione (GSM), an agonist of the feeding response, inhibit the binding of radiolabeled GSH to the putative receptor. Glutamate, a putative competitive antagonist of the GSH-activated feeding response in hydra, does not inhibit the specific binding of radiolabeled GSH to the receptor and must therefore block the feeding response by a mechanism other than competitive inhibition.     

The use of ELISA to monitor amplified hemolysis by the combined action of osmotic stress and radiation: potential applications

A new assay has been developed to study the osmotic fragility of red blood cells (RBCs) and the involvement of oxygen-derived free radicals and other oxidant species in causing human red blood cell hemolysis. The amount of hemoglobin released into the supernatant, which is a measure of human red blood cell hemolysis, is monitored using an ELISA reader. This ELISA-based osmotic fragility test compared well with the established osmotic fragility test, with the added advantage of significantly reduced time and the requirement of only 60 mul of blood. This small amount of blood was collected fresh by finger puncture and was immediately diluted 50 times with PBS, thus eliminating the use of anticoagulants and the subsequent washings. Since exposure of RBCs to 400 Gy gamma radiation caused less than 5% hemolysis 24 h after irradiation, the RBC hemolysis induced by gamma radiation was amplified by irradiating the cell in hypotonic saline. The method was validated by examining the protective effect of Trolox, an analog of vitamin E and reduced glutathione (GSH), a well-known radioprotector, against human RBC hemolysis caused by the combined action of radiation and osmotic stress. Trolox, a known membrane stabilizer and an antioxidant, and GSH offered significant protection. This new method, which is simple and requires significantly less time and fewer RBCs, may offer the ability to study the effects of antioxidants and membrane stabilizers on human red blood cell hemolysis induced by radiation and oxidative stress and assess the osmotic fragility of erythrocytes.     

Actin—membrane interactions: Association of G-actin with the red cell membrane

Chemically tritiated actin from rabbit skeletal muscle was used to investigate the association of G-actin with the red cell membrane. The tritiated actin was shown to be identical to unmodified actin in its ability to polymerize and to activate heavy meromyosin ATPase. Using sealed and unsealed red cell ghosts we have shown that G-actin binds to the cytoplasmic but not the extracellular membrane surface of ghosts. Inside-out vesicles which have been stripped of endogenous actin and spectrin by low-ionic-strength incubation bind little G-actin. However, when a crude spectrin extract containing primarily spectrin, actin, and band 4.1 is added back to stripped vesicles, subsequent binding of G-actin can be increased up to 40-fold. Further, this crude spectrin extract can compete for and abolish G-actin binding to unsealed ghosts. Actin binding to ghosts increases linearly with added G-actin and requires the presence of magnesium. In addition, actin binding is inhibited by cytochalasin B and DNAase I. Negative staining reveals an abundance of actin filaments formed when G-actin is added to reconstituted inside-out vesicles but none when it is added to unreconstituted vesicles. These observations indicate that added G-actin binds to the red cell membrane via filament formation nucleated by some membrane component at the cytoplasmic surface.     

GSTB1-1 from Proteus mirabilis: a snapshot of an enzyme in the evolutionary pathway from a redox enzyme to a conjugating enzyme

The native form of the bacterial glutathione transferase B1-1 (EC ) is characterized by one glutathione (GSH) molecule covalently linked to Cys-10. This peculiar disulfide, only found in the Beta and Omega class glutathione S-transferases (GSTs) but absent in all other GSTs, prompts questions about its role and how GSH can be activated and utilized in the reaction normally performed by GSTs. Stopped-flow and spectroscopic experiments suggest that, in the native enzyme (GSTB1-1ox), a second GSH molecule is present, albeit transiently, in the active site. This second GSH binds to the enzyme through a bimolecular interaction followed by a fast thiol-disulfide exchange with the covalently bound GSH. The apparent pK(a) of the non-covalently bound GSH is lowered from 9.0 to 6.4 +/- 0.2 in similar fashion to other GSTs. The reduced form of GSTB1-1 (GSTB1-1red) binds GSH 100-fold faster and also induces a more active deprotonation of the substrate with an apparent pK(a) of 5.2 +/- 0.1. Apparently, the absence of the mixed disulfide does not affect k(cat) and K(m) values in the GST conjugation activity, which is rate-limited by the chemical step both in GSTB1-1red and in GSTB1-1ox. However, GSTB1-1ox follows a steady-state random sequential mechanism whereas a rapid-equilibrium random sequential mechanism is adopted by GSTB1-1red. Remarkably, GSTB1-1ox and GSTB1-1red are equally able to catalyze a glutaredoxin-like catalysis using cysteine S-sulfate and hydroxyethyl disulfide as substrates. Cys-10 is an essential residue in this redox activity, and its replacement by alanine abolishes this enzymatic activity completely. It appears that GSTB1-1 behaves like an "intermediate enzyme" between the thiol-disulfide oxidoreductase and the GST superfamilies.     

Reduction of nitroxide free radical by normal and G6PD deficient red blood cells

The electron spin resonance signal of Tempol decays in the presence of red cells. The decay is due to reduction of oxidant, paramagnetic nitroxide group by the metabolic activity of the red cell. In normal red cells, GSH level was stable and Tempol reduction rate followed a first-order kinetics. In G6PD-deficient red cells, GSH dropped and Tempol reduction rate was slower and followed a second-order kinetics. In normal red cells, diamide reversibly oxidized GSH. First-order kinetics of Tempol reduction rate was attained after a delay time proportional to the diamide concentration and corresponding to the full regeneration of GSH. In diamide-treated G6PD deficient, and in NEM-treated, normal red cells, irreversible disappearance of GSH was followed by irreversible dose-dependent decrease in Tempol reduction rate. A correlation between GSH levels and Tempol reduction rate was observed. A correlation was also established between Tempol reduction rate and stimulation of pentosephosphate shunt activity.     

Intrinsic fluorescence quenching of glutathione transferase pi by glutathione binding.

The binding of the GSH to the GSH transferase pi quenches the protein intrinsic fluorescence more than the binding of GS-Me. The calculated dissociation constants are 38.6 microM and 90.9 microM for GSH and GS-Me, respectively. From the reported data it is evident that the binding of GSH to GSH transferase pi quenches the intrinsic fluorescence with two different mechanisms. The first one is a conformational change induced by the binding of the GSH and it is present also with the GS-Me binding. A second proposed mechanism is a contact quenching between the sulphydryl GSH group and a tryptophan residue. This suggests that at least one of the tryptophan residues is located near the GSH binding site.     

Prolonged inorganic arsenite exposure suppresses insulin-stimulated AKT S473 phosphorylation and glucose uptake in 3T3-L1 adipocytes: involvement of the adaptive antioxidant response

Intracellular B(12) metabolism involves a B(12) trafficking chaperone CblC that is well conserved in mammals including human. The protein CblC is known to bind cyanocobalamin (CNCbl, vitamin B(12)) inducing the base-off transition and convert it into an intermediate that can be used in enzyme cofactor synthesis. The binding affinity of human CblC for CNCbl was determined to be K(d)=≈6-16 μM, which is relatively low considering sub-micromolar B(12) concentrations (0.03-0.7 μM) in normal cells. In the current study, we discovered that the base-off transition of CNCbl upon binding to bCblC, a bovine homolog of human CblC, is facilitated in the presence of reduced form of glutathione (GSH). In addition, GSH dramatically increases the binding affinity for CNCbl lowering the K(d) from 27.1 ± 0.2-0.24 ± 0.09 μM. The effect of GSH is due to conformational change of bCblC upon binding with GSH, which was indicated by limited proteolysis and urea-induced equilibrium denaturation of the protein. The results of this study suggest that GSH positively modulates bCblC by increasing the binding affinity for CNCbl, which would enhance functional efficiency of the protein.     

Biochemical characterization of human S-nitrosohemoglobin. Effects on oxygen binding and transnitrosation.

S-Nitrosation of cysteine beta93 in hemoglobin (S-nitrosohemoglobin (SNO-Hb)) occurs in vivo, and transnitrosation reactions of deoxygenated SNO-Hb are proposed as a mechanism leading to release of NO and control of blood flow. However, little is known of the oxygen binding properties of SNO-Hb or the effects of oxygen on transnitrosation between SNO-Hb and the dominant low molecular weight thiol in the red blood cell, GSH. These data are important as they would provide a biochemical framework to assess the physiological function of SNO-Hb. Our results demonstrate that SNO-Hb has a higher affinity for oxygen than native Hb. This implies that NO transfer from SNO-Hb in vivo would be limited to regions of extremely low oxygen tension if this were to occur from deoxygenated SNO-Hb. Furthermore, the kinetics of the transnitrosation reactions between GSH and SNO-Hb are relatively slow, making transfer of NO+ from SNO-Hb to GSH less likely as a mechanism to elicit vessel relaxation under conditions of low oxygen tension and over the circulatory lifetime of a given red blood cell. These data suggest that the reported oxygen-dependent promotion of S-nitrosation from SNO-Hb involves biochemical mechanisms that are not intrinsic to the Hb molecule.     

Reaction of cis- and trans-[PtCl2(NH3)2] with reduced glutathione inside human red blood cells, studied by 1H and 15N-[1H] DEPT NMR

Reactions of cis- and trans-[PtCl2(NH3)2] with glutathione (GSH) inside intact red blood cells have been studied by 1H spin-echo nuclear magnetic resonance (NMR). Upon addition of trans-[PtCl2(NH3)2] to a suspension of red cells, there was a gradual decrease in the intensity of the resonances for free GSH, and new peaks were observed that were assignable to coordinated GSH protons in trans-[Pt(SG)Cl(NH3)2], trans-[Pt(SG)2(NH3)2], and possibly the S-bridged complex trans-[[NH3)2PtCl)2SG]+. Formation of trans-[Pt(SG)2(NH3)2] inside the cell was confirmed from the 1H NMR spectrum of hemolyzed cells, which were ultrafiltered to remove large protein molecules; the ABM multiplet of the coordinated GSH cys-beta CH2 protons was resolved using selective-decoupling experiments. Seventy percent of the total intracellular GSH was retained by the ultrafiltration membrane, suggesting that the mixed complex trans-[Pt(SG)(S-hemoglobin)(NH3)2] also is a major metabolite of trans-[PtCl2(NH3)2] inside red cells. The reaction of cis-[PtCl2(NH3)2] with intracellular GSH was slower; only 35% of the GSH had been complexed after a 4-hr incubation compared to 70% for the trans isomer. There was a gradual decrease in the intensity of the GSH 1H spin-echo NMR resonances, but no new peaks were resolved. This was interpreted as formation of high-molecular weight Pt:GSH and mixed GS-Pt-S(hemoglobin) polymers. By using a 15N-[1H] DEPT pulse sequence, we were able to study the reaction of cis-[PtCl2(15NH3)2] with red cells at concentrations as low as 1 mM. 15NH3 ligands were released, and no resonances assignable to Pt-15NH3 species were observed after a 12-hr incubation.