Ginseng polysaccharide attenuates red blood cells oxidative stress injury by regulating red blood cells glycolysis and liver gluconeogenesis.

ETHNOPHARMACOLOGICAL RELEVANCE: Panax ginseng C.A. Mey (PG) is famous for "Qi-tonifying" effect, which has a medicinal history of more than 2 millennia. Modern pharmacology has confirmed that the "Qi-tonifying" effect of PG may be closely related to its pharmacological properties such as anti-oxidation, antineoplastic and treatment of cardiovascular disease. As one of the earliest cells affected by oxidative stress, RBCs are widely used in the diagnosis of diseases. Ginseng polysaccharide (GPS), is one of the major active components of PG, which plays an important role in resisting oxidative stress, affecting energy metabolism and other effects. However, the molecular mechanism explaining the "Qi-tonifying" effect of GPS from the perspective of RBCs oxidative damage has not been reported. AIM OF THE STUDY: This study aimed to investigate the protective effect of GPS on oxidatively damaged RBCs using in vitro and in vivo models and explore the molecular mechanisms from the perspective of glycolysis and gluconeogenesis pathways. To provides a theoretical basis for the future research of antioxidant drugs. MATERIALS AND METHODS: Established three different in vitro and in vivo research models: an in vitro model of RBCs exposed to hydrogen peroxide (H2O2) (40 mM), an in vivo model of RBCs from rats subjected to exhaustive swimming, and an in vitro model of BRL-3A cells exposed to H2O2 (25 µM). All three models were also tested in the presence of different concentrations of GPS. RESULTS: The findings showed that GPS was the most potent antagonist of H2O2-induced hemolysis and redox inbalance in RBCs. In exhaustive exercise rats, GPS ameliorated RBVs hemolysis, including reducing whole-blood viscosity (WBV), improving deformability, oxygen-carrying and -releasing capacities, which was related to the enhancing of antioxidant capacity. Moreover, GPS promoted RBCs glycolysis in rats with exhaustive exercise by recovering the activities of glycolysis-related enzymes and increasing band 3 protein expression, thereby regulating the imbalance of energy metabolism caused by oxidative stress. Furthermore, we demonstrated that GPS improved antioxidant defense system, enhanced energy metabolism, and regulated gluconeogenesis via activating PPAR gamma co-activator 1 alpha (PGC-1α) pathway in H2O2-exposed BRL-3A cells. Mechanistically, GPS promoted glycolysis and protected RBCs from oxidative injury was partly dependent on the regulation of gluconeogenesis, as inhibition of gluconeogenesis by metformin (Met) attenuates the regulation of antioxidant enzymes and key enzymes of glycolytic by GPS in exhaustive exercise rats. CONCLUSION: This study demonstrates that GPS protects RBCs from oxidative stress damage by promoting RBCs glycolysis and liver gluconeogenesis pathways. These results may contribute to the study of new RBCs treatments to boost antioxidant capacity and protect RBCs against oxidative stress.

Antioxidant Activity of Quercetin in a H2O2-Induced Oxidative Stress Model in Red Blood Cells: Functional Role of Band 3 Protein.

During their lifespan, red blood cells (RBCs) are exposed to a large number of stressors and are therefore considered as a suitable model to investigate cell response to oxidative stress (OS). This study was conducted to evaluate the potential beneficial effects of the natural antioxidant quercetin (Q) on an OS model represented by human RBCs treated with H2O2. Markers of OS, including % hemolysis, reactive oxygen species (ROS) production, thiobarbituric acid reactive substances (TBARS) levels, oxidation of protein sulfhydryl groups, CD47 and B3p expression, methemoglobin formation (% MetHb), as well as the anion exchange capability through Band 3 protein (B3p) have been analyzed in RBCs treated for 1 h with 20 mM H2O2 with or without pre-treatment for 1 h with 10 µM Q, or in RBCs pre-treated with 20 mM H2O2 and then exposed to 10 µM Q. The results show that pre-treatment with Q is more effective than post-treatment to counteract OS in RBCs. In particular, pre-exposure to Q avoided morphological alterations (formation of acanthocytes), prevented H2O2-induced OS damage, and restored the abnormal distribution of B3p and CD47 expression. Moreover, H2O2 exposure was associated with a decreased rate constant of SO42- uptake via B3p, as well as an increased MetHb formation. Both alterations have been attenuated by pre-treatment with 10 µM Q. These results contribute (1) to elucidate OS-related events in human RBCs, (2) propose Q as natural antioxidant to counteract OS-related alterations, and (3) identify B3p as a possible target for the treatment and prevention of OS-related disease conditions or aging-related complications impacting on RBCs physiology.

Lacking deoxygenation-linked interaction between cytoplasmic domain of band 3 and HbF from fetal red blood cells.

AIM: Several of the red blood cell's metabolic and membrane functions display dependence on haemoglobin oxygenation. In adult human red cells, the increased glycolytic rate at low O2 tension results from binding of deoxygenated HbA at negatively charged, N-terminal, cytoplasmic domain of the membrane protein band 3, which liberates glycolytic enzymes from this site. This study aims to investigate the role of fetal HbF (that has lower anion-binding capacity than HbA) in fetal red cells (that are subjected to low O2 tensions), and to elucidate possible linkage (e.g. via the major red cell membrane organising centre, band 3) between the individual oxygenation-linked reactions encountered in red cells. METHODS: The interaction between band 3 and Hb is analysed in terms of the effects, measured under different conditions, of a 10-mer peptide that corresponds to the N-terminus of human band 3 protein, on the oxygenation reaction of HbF and HbA, isolated from umbilical chord red cells. RESULTS: Contrasting with the unequivocal interaction of the peptide with HbA that with fetal HbF is weak, and annihilated in the presence of autochthonous red cell O2 affinity modulators (chloride and organic phosphates). CONCLUSION: The data indicate that HbF does not function as a transducer mediating O2 dependence of glycolysis in fetal red cells, in accordance with the different O2 and metabolic profiles compared to those in HbA-bearing adult red cells. In conjunction with the previously discovered O2 dependence of K+ transport in HbF-rich fetal cells, they moreover argue against linkage between different, physiologically relevant, O2-dependent red cell functions.

Adhesion of human red blood cells and surface charge of the membrane.

To elucidate the mechanism by which red blood cells (RBC) participate in thrombus formation, we investigated the mechanism of adhesion between human RBC. Our study showed that the morphology of RBC was changed by various cationic reagents, inducing adhesion between RBC. When RBC suspended in PBS buffer containing sodium phosphate (PBS(Na)) or potassium phosphate (PBS(K)) were treated with cationic reagents, stronger adhesion occurred between RBC treated with the latter. When concentrations of the reagents were low, adhesion was released and the RBC resumed its original morphology after washing. However, when the concentrations of reagents were high, the morphology did not normalize, although the adhesion was released. When fresh RBC were treated with cationized ferritin (CF), CF bound to the periphery of RBC membranes and induced adhesion. However, when RBC were induced to adhere strongly by a cationic reagent, no binding of CF to the membrane was not observed. When RBC were treated with CF, bindings between substances outside the membranes and bindings between the membranes and substances outside the membranes were observed. When RBC treated with neuraminidase to remove 85-90% of sialic acid were treated with the cationic reagents, both adhesion between RBC and morphological change were reduced. When RBC were pretreated with polyclonal antibody against human RBC membrane band 3 protein, treatment with the cationic reagents did not induce adhesion and morphological change of RBC. Further, when RBC induced to adhere by the cationic reagents were treated with the polyclonal antibody against band 3, in the case of weak adhesion, the adhesion was released and the RBC resumed its original morphology. However, in the case of strong adhesion, the morphology did not return to normal although the adhesion was released. These results suggest that the adhesion between RBC induced by cationic reagents was due to changes in the charge on the membrane surface, involving polysaccharide chains and membrane surface proteins.

Pre-steady state transport by erythrocyte band 3 protein: uphill countertransport induced by the impermeant inhibitor H2DIDS.

Pre-steady state Cl- efflux experiments have been performed to test directly the idea that the transport inhibitor H2DIDS (4,4'-diisothiocyanatodihydrostilbene-2,2'-disulfonate) binds preferentially to the outward-facing state of the transporter. Cells were equilibrated with a medium consisting of 150 mM sodium phosphate, pH 6.2, N2 atmosphere, and 80-250 microM 36Cl-. Addition of H2DIDS (10-fold molar excess compared with band 3) induces a transient efflux of Cl-, as expected if H2DIDS binds more tightly to outward-facing than to inward-facing states. The size of the H2DIDS-induced efflux depends on the Cl- concentration and is about 700,000 ions per cell at the highest concentrations tested. The size of the transient efflux is larger than would be expected if the catalytic cycle for anion exchange involved one pair of exchanging anions per band 3 dimer. These results are completely consistent with a ping-pong mechanism of anion exchange in which the catalytic cycle consists of one pair of exchanging anions per subunit of the band 3 dimer.

Band 3 peptides block the adherence of sickle cells to endothelial cells in vitro.

Malaria-parasitized erythrocytes have increased endothelial adherence due to exposure of previously buried intramembranous sites of band 3. Because sickle erythrocytes also show increased adhesiveness and because the membrane portion of band 3 is aggregated in both types of cells, we examined the role of band 3 in sickle cell adhesiveness. Synthetic peptides derived from the second and third exofacial, interhelical regions of band 3 completely inhibited the abnormal adherence of sickle cells to an endothelial monolayer in a static assay. This effect was observed independently of plasma factors, required micromolar levels of peptide, was sequence-specific, and was found with both L- and D-isomers. The active peptides also inhibited the increased adherence induced by low-dose calcium loading of normal red blood cells. Finally, a monoclonal antibody against an active peptide specifically immunostained a fraction of sickle cells. These findings implicate a role for band 3 in at least one type of sickle cell adhesiveness via the exposure of normally cryptic membrane sites.

T-helper 1 dominated responses to erythrocyte Band 3 in NZB mice.

Band 3, the red blood cell (RBC) anion channel protein, is the target autoantigen for the pathogenic RBC autoantibodies and T-helper (Th) cells in New Zealand Black (NZB) mice with autoimmune haemolytic anaemia (AIHA). To determine the subpopulation of these Th cells, they were stimulated with Band 3 and the profile of the cytokines elaborated by the responding cells was measured. NZB T cells stimulated with Band 3 produced high levels of the Th1 cytokine, interferon-gamma (IFN-gamma), but little or no interleukin-4 (IL-4), IL-5 or IL-10. Similar patterns were produced by NZB T cells responding to a spectrin preparation from the RBC membrane skeleton, or to mycobacterial heat-shock protein (hsp) 65 following immunization of mice with hsp 65 in incomplete adjuvant. By contrast, T cells from CBA mice similarly immunized with hsp 65 produced high levels of IL-4 and IL-5 in response to hsp 65. Examination of the isotype of the RBC-bound immunoglobulins in NZB mice revealed that immunoglobulin G2a (IgG2a) autoantibodies were the first to be detected in most mice and that later in the disease, IgG3 autoantibodies were often prominent. It is concluded that, contrary to expectation, the development of RBC autoantibodies in NZB mice is associated with Th1 cytokine-dominated responses.

Plasmodium falciparum: the adherence of erythrocytes infected with human malaria can be mimicked using pfalhesin-coated microspheres.

Infection of human erythrocytes with the malaria parasite, Plasmodium falciparum, results in the exposure of amino acid residues 542-555 of the anion-exchange protein, band 3, in a conformation that enables the cell to adhere to C32 amelanotic melanoma cells. Attempts to isolate this adhesive form from infected cells by immunoaffinity were unsuccessful, and so other approaches were utilized. Chinese hamster ovary (CHO) cells transfected with cDNA encoding the first 578 amino acid residues of human band 3 protein transiently expressed the protein efficiently. A murine monoclonal antibody (MAb) that specifically recognizes the adhesin exposed on the surface of erythrocytes bearing mature stages of P. falciparum immunostained some transfected cells, confirming that the first 578 amino residues are sufficient for the adhesive conformation. As a more efficient alternative to transgenic expression of the adhesin, microspheres with covalently bound peptides fashioned on band 3 sequences previously found to be adherent (residues 546-553 and 820-829 and called pfalhesin) were produced. The pfalhesin-coated microspheres specifically bound to C32 amelanotic melanoma cells, whereas microspheres coupled with a scrambled version of residues 546-553 had little binding capacity for melanoma cells. These results demonstrate that the previously identified band 3-related peptides that inhibit cytoadherence interact directly with target cells and suggest that microspheres with covalently coupled peptides might constitute novel 'artificial' P. falciparum-infected erythrocytes for use in in vitro and in vivo studies.

Inhibition of hemoglobin S polymerization by N-terminal band 3 peptides: new class of inhibitors: solubility studies.

Two synthetic peptides corresponding to the N-terminal amino acids (AA) of band 3 were designed to inhibit deoxyhemoglobin S (deoxy S) polymerization through two different mechanisms. Peptide I, an N:1-15AA fragment, was employed to bind to the 2,3-diphosphoglycerate (2,3-DPG) receptor locus of single deoxy S molecules with 5-7 AA extending internally and the remaining 10-8 AA projecting external to hemoglobin (Hb) S, thereby inhibiting polymerization by steric hindrance. Peptide II consisted of two N:1-8AA + K (lysine) sequences linked by a coupler through the lysine, and it was employed to bind to the 2,3-DPG loci of two deoxy S molecules, tethering them together to form "binary hemoglobin complexes" incapable of entering the polymer chains. Decreased polymerization would result from reduction in effective concentration of deoxy S. Binding of peptides to the 2,3-DPG receptor loci was demonstrated by a progressive rightward shift in the hemoglobin oxygen binding curves as a function of increasing peptide concentrations. Inhibition of deoxy S polymerization was studied by equilibrium solubility measurements of purified, stripped solutions of Hb S. Physiologically significant inhibition was demonstrated for both peptides with near-maximum increases in solubility achieved by Peptide II at 1:1 peptide:Hb S ratios. These peptides represent a new class of inhibitors of deoxy S polymerization.

Band 3 peptides inhibit deoxy S polymerization: viscosity studies.

We have previously obtained evidence that N-terminal band 3 peptides inhibited deoxyhemoglobin S (deoxy S) polymerization as determined by equilibrium solubility assays. An N:1-15AA fragment binds to the 2,3-diphosphoglycerate (2,3-DPG) receptor locus of deoxy S with five to seven amino acids (AA) extending internally, while ten to eight AA remained external to deoxy S and inhibited polymerization by steric hindrance. A true mirror-image peptide, corresponding to two N:1-8AA + lysine (K) linked by coupler, binds to the 2,3-DPG loci of two deoxy S molecules, tethering them together to form "binary complexes" incapable of entering the polymer chains. The reduction in the concentration of deoxy S available for extended chain formation decreased polymerization. We now report time:viscosity profiles of the sol-gel transformation of purified solutions of deoxy S with and without peptides and studies of the gel solidity at equilibrium. Samples with peptides had longer lag times than controls of similar deoxy S concentrations. The mirror-image peptide was a more effective inhibitor than the N:1-15AA peptide. When the mirror-image peptide was present in peptide:hemoglobin molar ratios of 0.25-1:1, the increases in lag time were equivalent to decreasing the deoxy S concentrations by 15-25%, comparable to projected major therapeutic effects. Gel solidity, determined by yield temperature, was less in the sample with mirror-image peptide compared to control. These results support the proposed mechanisms of inhibition of deoxy S polymerization by band 3 peptides.

Dynamic association of band 3 with triton shells in human erythrocyte ghosts.

To test a possibility that free band 3 and ankyrin-linked band 3 are exchanged in situ, band 3 was labeled with 125I, using intact red blood cells and lactoperoxidase. The cytoplasmic surface of this labeled band 3 was considered to be intact. When Triton shells were incubated with Triton supernatants prepared from 125I-labeled intact erythrocytes at 37 degrees C in the presence of Mg-ATP under isotonic conditions, the incorporation of free 125I-labeled band 3 to shells was observed. This incorporation was affected by the presence of Triton X-100 in the incubation mixture, and significantly decreased when the content of Triton X-100 was less than 0.04% (v/v). On the other hand, ankyrin-linked 125I-labeled band 3 was released when shells prepared from 125I-labeled intact erythrocytes were incubated with the Triton supernatants at 37 degrees C under the same condition as when free 125I-labeled band 3 incorporation was observed. These results strongly suggest that free and ankyrin-linked band 3 exchanged with each other in the presence of Triton X-100. A water-soluble 43 kDa fragment of band 3 inhibited the incorporation of free 125I-labeled band 3 to the shells and also inhibited the Mg-ATP-dependent shape change of ghosts in the absence of Triton X-100. Both of these inhibitory effects remained, even after 10 min of heat treatment at 100 degrees C, but drastically decreased by treatment with trypsin. Our results strongly suggest that a dynamic exchange of the free band 3 for ankyrin-linked band 3 may occur in intact erythrocytes, and it may even contribute to the shape change of erythrocytes.

Asymmetry of the Na+/H+ antiport of dog red cell ghosts. Sidedness of inhibition by amiloride.

Amiloride is a potent inhibitor of the Na+/H+ antiport. Inhibition is generally competitive with extracellular Na+ and therefore believed to result from binding to the outward-facing transport site. It is not known whether amiloride can interact with the internal aspect of the antiport. This question was addressed by trapping the drug inside resealed dog red cell ghosts. The antiport, which is quiescent in resting ghosts, was activated by acid-loading the cytoplasm. This was accomplished by exchanging extracellular Cl- for internal HCO-3 through capnophorin, the endogenous anion exchanger. The activity of the Na+/H+ antiport was detected as an increase in cell volume, resulting from the net osmotic gain associated with coupled Na+/H+ and Cl-/HCO-3 exchange, or as the uptake of 22Na+. Intracellular amiloride, at concentrations in excess of 100 microM, failed to inhibit Na+/H+ exchange. This is approximately 10 times higher than the concentration required for half-maximal inhibition when amiloride is added externally. Independent experiments demonstrated that failure of internal amiloride to inhibit exchange was not due to leakage of the inhibitor, to differences in pH, or to binding or inactivation of amiloride by the soluble contents. It was concluded that the antiport is functionally asymmetric with respect to amiloride. This implies that the transport site undergoes a conformational change upon translocation across the membrane or, alternatively, that a second site required for amiloride binding is only accessible from the outside.

Inhibition of erythrocyte membrane shape change by band 3 cytoplasmic fragment.

The ATP-dependent transformation of crenated white human erythrocyte ghosts into smoothed disc and cup forms is inhibited by the soluble 40-45-kilodalton (kDa) cytoplasmic portion of the major transmembrane protein, band 3. The band 3 fragment was prepared by chymotryptic treatment of inverted vesicles stripped of peripheral proteins. When present at greater than or equal to 0.2 mg per mg membrane protein (ie, greater than or equal to 2 mol fragment per mol endogenous band 3), the fragment significantly reduced the rate of shape change but did not alter the proportion of membranes that were ultimately converted into smoothed forms (greater than 90%). The inhibitory activity of the fragment could not be attributed to contamination of the fragment preparation by actin or proteolytic enzymes. ATP-independent shape transformation was not inhibited. The band 3 fragment may compete with endogenous, intact band 3 for an association with the spectrin-actin network required for ATP-dependent smoothing of crenated membranes.