Free Heme and the Polymerization of Sickle Cell Hemoglobin

In search of novel control parameters for the polymerization of sickle cell hemoglobin (HbS), the primary pathogenic event of sickle cell anemia, we explore the role of free heme, which may be excessively released in sickle erythrocytes. We show that the concentration of free heme in HbS solutions typically used in the laboratory is 0.02-0.04 mole heme/mole HbS. We show that dialysis of small molecules out of HbS solutions arrests HbS polymerization. The addition of 100-260 μM of free heme to dialyzed HbS solutions leads to rates of nucleation and polymer fiber growth faster by two orders of magnitude than before dialysis. Toward an understanding of the mechanism of nucleation enhancement by heme, we show that free heme at a concentration of 66 μM increases by two orders of magnitude the volume of the metastable clusters of dense HbS liquid, the locations where HbS polymer nuclei form. These results suggest that spikes of the free heme concentration in the erythrocytes of sickle cell anemia patients may be a significant factor in the complexity of the clinical manifestations of sickle cell anemia. The prevention of free heme accumulation in the erythrocyte cytosol may be a novel avenue to sickle cell therapy.     

Membrane interactions of hemoglobin variants, HbA, HbE, HbF and globin subunits of HbA: Effects of aminophospholipids and cholesterol

The interaction of hemoglobin with phospholipid bilayer vesicles (liposomes) has been analyzed in several studies to better understand membrane-protein interactions. However, not much is known on hemoglobin interactions with the aminophospholipids, predominantly localized in the inner leaflet of erythrocytes, e.g., phosphatidylserine (PS), phosphatidylethanolamine (PE) in membranes containing phosphatidylcholine (PC). Effects of cholesterol, largely abundant in erythrocytes, have also not been studied in great details in earlier studies. This work therefore describes the study of the interactions of different hemoglobin variants HbA, HbE and HbF and the globin subunits of HbA with the two aminophospholipids in the presence and absence of cholesterol. Absorption measurements indicate preferential oxidative interaction of HbE and alpha-globin subunit with unilamellar vesicles containing PE and PS compared to normal HbA. Cholesterol was found to stabilize such oxidative interactions in membranes containing both the aminophospholipids. HbE and alpha-globin subunits were also found to induce greater leakage of membrane entrapped carboxyfluorescein (CF) using fluorescence measurements. HbE was found to induce fusion of membrane vesicles containing cholesterol and PE when observed under electron microscope. Taken together, these findings might be helpful in understanding the oxidative stress-related mechanism(s) involved in the premature destruction of erythrocytes in peripheral blood, implicated in the hemoglobin disorder, HbE/beta-thalassemia.     

Membrane interactions of hemoglobin variants, HbA, HbE, HbF and globin subunits of HbA: effects of aminophospholipids and cholesterol

The interaction of hemoglobin with phospholipid bilayer vesicles (liposomes) has been analyzed in several studies to better understand membrane-protein interactions. However, not much is known on hemoglobin interactions with the aminophospholipids, predominantly localized in the inner leaflet of erythrocytes, e.g., phosphatidylserine (PS), phosphatidylethanolamine (PE) in membranes containing phosphatidylcholine (PC). Effects of cholesterol, largely abundant in erythrocytes, have also not been studied in great details in earlier studies. This work therefore describes the study of the interactions of different hemoglobin variants HbA, HbE and HbF and the globin subunits of HbA with the two aminophospholipids in the presence and absence of cholesterol. Absorption measurements indicate preferential oxidative interaction of HbE and alpha-globin subunit with unilamellar vesicles containing PE and PS compared to normal HbA. Cholesterol was found to stabilize such oxidative interactions in membranes containing both the aminophospholipids. HbE and alpha-globin subunits were also found to induce greater leakage of membrane entrapped carboxyfluorescein (CF) using fluorescence measurements. HbE was found to induce fusion of membrane vesicles containing cholesterol and PE when observed under electron microscope. Taken together, these findings might be helpful in understanding the oxidative stress-related mechanism(s) involved in the premature destruction of erythrocytes in peripheral blood, implicated in the hemoglobin disorder, HbE/beta-thalassemia.     

Cation Modulation of Hemoglobin Interaction with Sodium <Emphasis Type="Italic">n</Emphasis>-Dodecyl Sulfate (SDS). I: Calcium Modulation at pH 7.20

A comparative denaturation of HbA and HbS in the R states using sodium n-dodecyl sulfate (SDS) was carried out at pH 7.20 in the presence and absence of Calcium (0–40 μM) and monitored by UV–Vis spectrophotometry in the range of 250–650 nm. In the HbS spectra, the calcium alone caused little or no perturbation of the aromatic region but caused a decrease in oxygen affinity when compared to the HbA. The combinations of [SDS] and [Ca] perturbed the HbS the most, relative to the individual spectra of the [SDS] and [Ca]. However, the presence of Ca appeared to diminish the adverse effects of the SDS on HbA. The denaturation pathway of the HbA involved mainly the formation of heme dimers and some ferryl heme species. For the HbS, heme monomers and a large amount of ferryl species were formed. It is suggested that the greater monomer species formed by the HbS denaturation pathway would result in both Fenton and enhanced enzymatic reactions, compared to the dimer. This could lead ultimately to the formation of ferryl radicals. Thus, at physiological pH for the HbS, the Ca–SDS interaction increases the tendency for protein denaturation in comparison to the HbA.     

Dynamic light scattering and optical absorption spectroscopy study of pH and temperature stabilities of the extracellular hemoglobin of Glossoscolex paulistus

The extracellular hemoglobin of Glossoscolex paulistus (HbGp) is constituted of subunits containing heme groups, monomers and trimers, and nonheme structures, called linkers, and the whole protein has a minimum molecular mass near 3.1 × 10⁶ Da. This and other proteins of the same family are useful model systems for developing blood substitutes due to their extracellular nature, large size, and resistance to oxidation. HbGp samples were studied by dynamic light scattering (DLS). In the pH range 6.0-8.0, HbGp is stable and has a monodisperse size distribution with a z-average hydrodynamic diameter (D_h) of 27 ± 1 nm. A more alkaline pH induced an irreversible dissociation process, resulting in a smaller D_h of 10 ± 1 nm. The decrease in D_h suggests a complete hemoglobin dissociation. Gel filtration chromatography was used to show unequivocally the oligomeric dissociation observed at alkaline pH. At pH 9.0, the dissociation kinetics is slow, taking a minimum of 24 h to be completed. Dissociation rate constants progressively increase at higher pH, becoming, at pH 10.5, not detectable by DLS. Protein temperature stability was also pH-dependent. Melting curves for HbGp showed oligomeric dissociation and protein denaturation as a function of pH. Dissociation temperatures were lower at higher pH. Kinetic studies were also performed using ultraviolet-visible absorption at the Soret band. Optical absorption monitors the hemoglobin autoxidation while DLS gives information regarding particle size changes in the process of protein dissociation. Absorption was analyzed at different pH values in the range 9.0-9.8 and at two temperatures, 25°C and 38°C. At 25°C, for pH 9.0 and 9.3, the kinetics monitored by ultraviolet-visible absorption presents a monoexponential behavior, whereas for pH 9.6 and 9.8, a biexponential behavior was observed, consistent with heme heterogeneity at more alkaline pH. The kinetics at 38°C is faster than that at 25°C and is biexponential in the whole pH range. DLS dissociation rates are faster than the autoxidation dissociation rates at 25°C. Autoxidation and dissociation processes are intimately related, so that oligomeric protein dissociation promotes the increase of autoxidation rate and vice versa. The effect of dissociation is to change the kinetic character of the autoxidation of hemes from monoexponential to biexponential, whereas the reverse change is not as effective. This work shows that DLS can be used to follow, quantitatively and in real time, the kinetics of changes in the oligomerization of biologic complex supramolecular systems. Such information is relevant for the development of mimetic systems to be used as blood substitutes.     

Nitrite reductase activity of hemoglobin S (sickle) provides insight into contributions of heme redox potential versus ligand affinity

Hemoglobin A (HbA) is an allosterically regulated nitrite reductase that reduces nitrite to NO under physiological hypoxia. The efficiency of this reaction is modulated by two intrinsic and opposing properties: availability of unliganded ferrous hemes and R-state character of the hemoglobin tetramer. Nitrite is reduced by deoxygenated ferrous hemes, such that heme deoxygenation increases the rate of NO generation. However, heme reactivity with nitrite, represented by its bimolecular rate constant, is greatest when the tetramer is in the R quaternary state. The mechanism underlying the higher reactivity of R-state hemes remains elusive. It can be due to the lower heme redox potential of R-state ferrous hemes or could reflect the high ligand affinity geometry of R-state tetramers that facilitates nitrite binding. We evaluated the nitrite reductase activity of unpolymerized sickle hemoglobin (HbS), whose oxygen affinity and cooperativity profile are equal to those of HbA, but whose heme iron has a lower redox potential. We now report that HbS exhibits allosteric nitrite reductase activity with competing proton and redox Bohr effects. In addition, we found that solution phase HbS reduces nitrite to NO significantly faster than HbA, supporting the thesis that heme electronics (i.e. redox potential) contributes to the high reactivity of R-state deoxy-hemes with nitrite. From a pathophysiological standpoint, under conditions where HbS polymers form, the rate of nitrite reduction is reduced compared with HbA and solution-phase HbS, indicating that HbS polymers reduce nitrite more slowly.     

Plasmodium falciparum: physiological interactions with the human sickle cell.

The malaria parasite, Plasmodium falciparum, enhances the rate and extent of sickling of infected hemoglobin S heterozygous human erythrocytes. Upon sickling of the host cell, the parasite is killed. Parasite-free lysates of highly infected cells were analyzed to determine the mechanism by which sickling is enhanced. The intraerythrocytic pH of the infected cell was estimated to be 0.4 units below that of the uninfected cell, a difference which could result in a 20-fold increase in the extent of sickling under physiological conditions. Sickle-cell hemoglobin (HbS) heterozygous (AS) erythrocytes had decreased intracellular potassium after 24 hr of culture under conditions which cause sickling and parasite death. When infected AS cells were cultured in high-potassium medium under these conditions the parasites were protected. The medium did not prevent sickling but did maintain normal intracellular potassium levels. It is suggested that sequestration of trophozoite-infected AS cells in the venules leads to the sickling of the host cell, loss of erythrocytic potassium, and parasite death. The resulting attenuation of parasite multiplication would favor the survival of the HbS heterozygote and maintain the HbS gene at high frequencies in areas endemic for falciparum malaria.     

Mode of transport and possible mechanism of action of l-phenylalanine benzyl ester as an anti-sickling agent

l-Phenylalanine benzyl ester (Phe-Bz) and a number of ester analogues prevent sickling of erythrocytes from sickle cell disease patients. The compounds tested exhibit anti-sickling activity in the concentration range 0.5–3.0 mM. A general feature of these compounds is the presence of two aromatic rings in their molecular structure. The anti-sickling agents rapidly enter the erythrocyte and are hydrolysed to their component molecules. Incubation of human erythrocytes with 3.0 mM l-phenylalanine for 30 min at 37°C results in accumulation of 2.0 mmol l-phenyalanine/l cells, while incubation of erythrocytes with 3.0 mM Phe-Bz under similar conditions results in the production of 4.0 mmol l-phenylalanine/l cells and an equivalent amount of benzyl alcohol. Both l-phenylalanine and benzyl alcohol are inhibitors of the gelation of deoxyhaemoglobin S (deoxy-HbS) in vitro. Moreover, Phe-Bz and related anti-sickling agents fluidize the lipid bilayer of the erythrocyte membrane, inhibiting several transport systems, including those for l-phenylalanine, uridine and sulphate ions, as well as the Na⁺ pump and the Na⁺/K⁺ cotransporter, but increasing the passive influx and efflux of both cations and anions. The accumulation of Phe-Bz hydrolysis products within the erythrocyte together with the effects of Phe-Bz on cation permeability result in the influx of water causing the cell to swell. Thus, treatment of erythrocytes with 3.0 mM Phe-Bz at 37°C for 30 min causes an increase in mean cell volume of 14.8%, decreasing the mean intracellular haemoglobin concentration from 34 to 29.6 g%. The increase in cell volume caused by Phe-Bz and its analogues together with the direct effects of their hydrolysis products on HbS probably act in concert to bring about the anti-sickling effect.     

Ultrastructural damage to the malaria parasite in the sickled cell.

The process by which malaria parasites are killed in sickled erythrocytes was studied by electron microscopy. In vitro cultures of Plasmodium falciparum in sickle cell hemoglobin (HbS) homozygous (SS) and heterozygous (SA) red cells were deoxygenated for up to 6 h and fixed under anaerobic conditions. Parasites in SS cells appeared to be disrupted by intrusions of needle-like deoxyHbS aggregates; disintegration of cytoplasm and membranes followed. In SA red cells, the parasites were generally not disrupted. Instead, extensive vacuolization occurred, a sign of metabolic inhibition. The resistance of HbS gene carriers to malaria results partly from these causes of intracellular parasite death.     

Hemoglobin E Prevalence among Ethnic Groups Residing in Malaria-Endemic Areas of Northern Thailand and Its Lack of Association with Plasmodium falciparum Invasion In Vitro

Hemoglobin E (HbE) is one of the most common hemoglobin variants caused by a mutation in the β-globin gene, and found at high frequencies in various Southeast Asian groups. We surveyed HbE prevalence among 8 ethnic groups residing in 5 villages selected for their high period malaria endemicity, and 5 for low endemicity in northern Thailand, in order to uncover factors which may affect genetic persistence of HbE in these groups. We found the overall HbE prevalence 6.7%, with differing frequencies from 0% in the Pwo Karen, the Lawa, and the Skaw Karen to 24% in the Mon. All HbE genes were heterozygous (AE). Differences in HbE prevalence among the studied ethnic groups indirectly documents that ancestries and evolutionary forces, such as drift and admixture, are the important factors in the persistence of HbE distribution in northern Thailand. Furthermore, the presence of HbE in groups of northern Thailand had no effect on the in vitro infectivity and proliferation of Plasmodium falciparum, nor the production of hemozoin, a heme crystal produced by malaria parasites, when compared to normal red-blood-cell controls. Our data may contribute to a better understanding on the persistence of HbE among ethnic groups and its association with malaria.     

Ultrastructural Damage to the Malaria Parasite in the Sickled Cell

The process by which malaria parasites are killed in sickled erythrocytes was studied by electron microscopy. In vitro cultures of Plasmodium falciparum in sickle cell hemoglobin (HbS) homozygous (SS) and heterozygous (SA) red cells were deoxygenated for up to 6 h and fixed under anaerobic conditions. Parasites in SS cells appeared to be disrupted by intrusions of needle-like deoxyHbS aggregates; disintegration of cytoplasm and membranes followed. In SA red cells, the parasites were generally not disrupted. Instead, extensive vacuolization occurred, a sign of metabolic inhibition. The resistance of HbS gene carriers to malaria results partly from these causes of intracellular parasite death.     

Crystal structures of HbA2 and HbE and modeling of hemoglobin delta 4: interpretation of the thermal stability and the antisickling effect of HbA2 and identification of the ferrocyanide binding site in Hb

Hemoglobin A(2) (alpha(2)delta(2)) is an important hemoglobin variant which is a minor component (2-3%) in the circulating red blood cells, and its elevated concentration in beta-thalassemia is a useful clinical diagnostic. In beta-thalassemia major, where there is beta-chain production failure, HbA(2) acts as the predominant oxygen deliverer. HbA(2) has two more important features. (1) It is more resistant to thermal denaturation than HbA, and (2) it inhibits the polymerization of deoxy sickle hemoglobin (HbS). Hemoglobin E (E26K(beta)), formed as a result of the splice site mutation on exon 1 of the beta-globin gene, is another important hemoglobin variant which is known to be unstable at high temperatures. Both heterozygous HbE (HbAE) and homozygous HbE (HbEE) are benign disorders, but when HbE combines with beta-thalassemia, it causes E/beta-thalassemia which has severe clinical consequences. In this paper, we present the crystal structures of HbA(2) and HbE at 2.20 and 1.74 A resolution, respectively, in their R2 states, which have been used here to provide the probable explanations of the thermal stability and instability of HbA(2) and HbE. Using the coordinates of R2 state HbA(2), we modeled the structure of T state HbA(2) which allowed us to address the structural basis of the antisickling property of HbA(2). Using the coordinates of the delta-chain of HbA(2) (R2 state), we also modeled the structure of hemoglobin homotetramer delta(4) that occurs in the case of rare HbH disease. From the differences in intersubunit contacts among beta(4), gamma(4), and delta(4), we formed a hypothesis regarding the possible tetramerization pathway of delta(4). The crystal structure of a ferrocyanide-bound HbA(2) at 1.88 A resolution is also presented here, which throws light on the location and the mode of binding of ferrocyanide anion with hemoglobin, predominantly using the residues involved in DPG binding. The pH dependence of ferrocyanide binding with hemoglobin has also been investigated.     

Structure-function relation in hemoglobin Köln (β98 val → met)

Hemoglobin Köln, an unstable hemoglobin resulting from the substitution of normal valine by methionine at FG 5 (β98) is the most commonly encountered unstable hemoglobin. In Hb Köln from a hitherto undetected family, we confirmed earlier observations of heme depletion and high oxygen affinity, with the absence of co-operative interactions. In an effort to elucidate the basis of the altered oxygen equilibria, sedimentation velocity and the kinetics of the reactions of the abnormal hemoglobin with ligands were studied. The results of ultracentrifuge studies indicated that at pH 7 hemoglobin Köln, in the liganded as well as in the deoxy form, existed largely as dimers. The ratio of optical densities at 540 nm and 280 nm indicate that the abnormal β chains were heme depleted. Hb Köln reacted with

approximately 20 times faster than did hemoglobin A (Hb A). However, the corresponding rate constants for O₂ dissociation

are similar for Hb Köln and Hb A. For Hb Köln the two rate constants, l′ and k show little pH or concentration dependence. Thus, the high oxygen affinity of Hb Köln (P_1/2 = 0.2 mm Hg at 10 °C, pH 6.8) arises in part from a larger combination rate constant for the reaction with oxygen. Addition of a 20-fold excess of 2,3-diphosphoglyceric acid did not affect the kinetics of CO-combination. However, in the presence of a sixfold excess of heme, the fast monophasic CO-combination reaction was replaced by a biphasic one. The rate constant of the slow phase was approximately the same as the corresponding rate constant for Hb A. The fast and slow phases were presumably due to the reaction of CO with Hb Köln dimers (α^hβ^o heme-saturated tetramers, respectively. The results of the preeent study are explained in terms of weakened α?β and heme-globin contacts in the mutant.     

The effect of organic compounds on the crystal habit and crystallization of normal and sickle cell hemoglobin in phosphate buffer

Comparative studies were made on the effect of numerous organic compounds in promoting the crystallization of human hemoglobin in 1.9 m phosphate, pH 7.0. It was found that alicyclic or benzenoid structures are essential for promoting crystallization of hemoglobin under these conditions. Hemoglobin crystals prepared in the presence of toluene differed in habit from crystals prepared in its absence. It is suggested that steric factors determine the effectiveness of organic substances in promoting the crystallization of hemoglobin and that the heme group is the binding site involved in the complex formation.The solubility of homozygous sickle cell hemoglobin HbS was found to be less than the heterozygous hemoglobins AS and AC or normal hemoglobin HbA in the presence of organic substances promoting the crystallization of hemoglobin.     

Interactions of apomyoglobin with membranes: mechanisms and effects on heme uptake

The last step of the folding reaction of myoglobin is the incorporation of a prosthetic group. In cells, myoglobin is soluble, while heme resides in the mitochondrial membrane. We report here an exhaustive study of the interactions of apomyoglobin with lipid vesicles. We show that apomyoglobin interacts with large unilamellar vesicles under acidic conditions, and that this requires the presence of negatively charged phospholipids. The pH dependence of apomyoglobin interactions with membranes is a two-step process, and involves a partially folded state stabilized at acidic pH. An evident role for the interaction of apomyoglobin with lipid bilayers would be to facilitate the uptake of heme from the outer mitochondrial membrane. However, heme binding to apomyoglobin is observed at neutral pH when the protein remains in solution, and slows down as the pH becomes more favorable to membrane interactions. The effective incorporation of soluble heme into apomyoglobin at neutral pH suggests that the interaction of apomyoglobin with membranes is not necessary for the heme uptake from the lipid bilayer. In vivo, however, the ability of apomyoglobin to interact with membrane may facilitate its localization in the vicinity of the mitochondrial membranes, and so may increase the yield of heme uptake. Moreover, the behavior of apomyoglobin in the presence of membranes shows striking similarities with that of other proteins with a globin fold. This suggests that the globin fold is well adapted for soluble proteins whose functions require interactions with membranes.     

Clotrimazole enhances lysis of human erythrocytes induced by t-BHP

Clotrimazole (CLT) is an antifungal and antimalarial agent also effective as a Gardos channel inhibitor. In addition, CLT possesses antitumor properties. Recent data provide evidence that CLT forms a complex with heme (hemin), which produces a more potent lytic effect than heme alone. This study addressed the effect of CLT on the lysis of normal human erythrocytes induced by tert-butyl hydroperoxide (t-BHP). For the first time, it was shown that 10 μM CLT significantly enhanced the lytic effect of t-BHP on erythrocytes in both Ca²⁺-containing and Ca²⁺-free media, suggesting that the effect is not related to Gardos channels. CLT did not affect the rate of free radical generation, the kinetics of GSH degradation, methemoglobin formation and TBARS generation; therefore, we concluded that CLT does not cause additional oxidative damage to erythrocytes treated with t-BHP. It is tempted to speculate that CLT enhances t-BHP-induced changes in erythrocyte volume and lysis largely by forming a complex with hemin released during hemoglobin oxidation in erythrocytes: the CLT–hemin complex destabilizes the cell membrane more potently than hemin alone. If so, the effect of CLT on cell membrane damage during free-radical oxidation may be used to increase the efficacy of antitumor therapy.     

Studies on an activator of the (Ca2+ plus Mg2+)-ATPase of human erythrocyte membranes.

1. An activator of the (Ca2+ plus Mg2+)-stimulated ATPase present in the human erythrocytes (membrane) has been isolated in soluble form from hemolysates of these cells. Partial purification has been achieved through use of carboxymethyl-Sephadex chromatography. The resulting activator fraction contained no hemoglobin and only 0.3% of the total adenylate kinase activity of the cell. 2. Whereas the activator was released from erythrocytes subjected to hemolysis in 20 miosM buffer at pH 7.6 or at pH 5.8, only the membranes prepared at pH 7.6 were affected by it. 2. Whereas the activator was released from erythrocytes subjected to hemolysis in 20 miosM buffer at pH 7.6 or at pH 5.8, only the membranes prepared at pH 7.6 were affected by it. 3. When (Ca2+ plus Mg2+)-ATPase activity was measured by 32Pi release from (gamma-32P)ATP, freeze-thawed erythrocytes, as well as membranes prepared at pH 5.8 and at pH 7.6, expressed lower values than noted by assay for total Pi release. When ADP instead of ATP was used as substrate, significant amount of Pi were released by these erythrocyte preparations. Further study revealed (a) production of ATP and AMP from ADP with membranes and hemolysate alone, and (b) exchange of the gamma-and B-position phosphate on (gama-32P)ATP in the presence of membranes plus hemolysates. These observations established the presence of adenylate kinase activity in the (membrane-free) hemolysates and in membranes. It further supports the conclusion that Pi release from ADP by human erythrocytes (freeze-thawed) and by their isolated membranes is due to formation of ATP by adenylate kinase and hydrolysis of this generated ATP by (Ca2+ plus Mg2+)-ATPase. 4. The following points were also established: (a) absence of an ADPase in human erythrocytes; (b) the (Ca2+ plus Mg2+)-ATPase activator enhanced cleavage only of the gama-position of ATP and (c) the (Ca2+ plus Mg2+)-ATPase activator is neither adenylate kinase nor hemoglobin.     

Generation of a membrane-bound, oligomerized pre-pore complex is necessary for pore formation by Clostridium septicum alpha toxin

Low-temperature inhibition of the cytolytic activity of alpha toxin has facilitated the identification of an important step in the cytolytic mechanism of this toxin. When alpha toxin-dependent haemolysis was measured on erythrocytes at various temperatures it was clear that at temperatures ≤15°C the haemolysis rate was significantly inhibited with little or no haemolysis occurring at 4°C. Alpha toxin appeared to bind to and oligomerize on erythrocyte membranes with similar kinetics at 4°C and 37°C. The slight differences in these two processes at 4°C and 37°C could not account for the loss of cytolytic activity at low temperature. At 4°C alpha toxin neither stimulated potassium release from erythrocytes nor formed pores in planar membranes. In contrast, at temperatures ≥25°C both processes proceeded rapidly. Pores that were opened in osmotically stabilized erythrocytes could not be closed by low temperature. Therefore, low temperature appeared to prevent the oligomerized complex from forming a pore in the membrane. These data support the hypothesis that alpha toxin oligomerizes into a membrane-bound, pre-pore complex prior to formation of a pore in a lipid bilayer.     

Cytosol-Membrane Interface of Human Erythrocytes: A Resonance Energy Transfer Study

The resonance energy transfer from donors embedded in the membrane of erythrocytes to the cytosol hemoglobin has been measured by comparing the donors' fluorescence decay in ghosts and in intact cells. A series of n - (9-anthroyloxy) stearic acids (n-AS) (n = 2, 6, 9, 12) and similar probes were used as donors, and their locations within the outer leaflet of the phospholipid bilayer were determined from their average efficiency of energy transfer, <T>. The energy transfer data for several membrane probes were analyzed according to a simple semiempirical model, in which the heme acceptors are assumed to form a semiinfinite continuum beyond a plane, whose normal distance (d) from particular donors may be determined if the heme density in the cytosol boundary layer is known. The hemoglobin concentration in the erythrocytes was varied by suspending the cells in buffers of different ionic strengths. This made it possible to study the ionic strength dependence of the heme concentration averaged over the cell (h_c), as well as that in the boundary layer (h_b). Both level off above approximately 600 mosM, as does the ratio h_b/h_c. By using the maximum heme concentration that can be obtained in osmotically shrunken cells as a limiting value, h_b is estimated to be 17 mM or less, under physiological conditions; and from the measured <T> for various probes, the distance d was found to range from 40 Å for 2-AS to 31 Å for 12-AS and 26 Å for 9-vinyl anthracene (9-VA). It is concluded that the hydrophobic probe 9-VA is located near the center of the phospholipid bilayer and that the cytosol hemoglobin is in contact with the inner membrane surface, or nearly so. This conclusion is valid for oxy- and deoxy-hemoglobin, and is shown to be independent of several systematic errors that might arise from the simple assumptions of the model used. The steady-state fluorescence anisotropy of the probes was found to decrease as they approach the bilayer's central plane. The methodology developed here may be used to extend studies of cytosol membrane interactions in ghost systems to intact cells, and is useful in the investigation of the morphology of normal and pathological intact erythrocytes.     

Differential Thermal Stability and Oxidative Vulnerability of the Hemoglobin Variants,HbA2 and HbE

Apart from few early biophysical studies, the relative thermal instability of HbE has been only shown by clinical investigations. We have compared in vitro thermal stability of HbE with HbA₂ and HbA using optical spectroscopy. From absorption measurements in the soret region, synchronous fluorescence spectroscopy and dynamic light scattering experiments, we have found thermal stability of the three hemoglobin variants following the order HbE<HbA<HbA₂ in terms of structural unfolding and aggregation pattern. We have found formation of intermolecular dityrosine fluorophores with characteristic fluorescence signature, at pH >11.0 in all the three variants. Under oxidative stress conditions in presence of hydrogen peroxide, HbE has been found to be more vulnerable to aggregation compared to HbA and HbA₂. Taken together, these studies have shown thermal and oxidative instability of HbE and points towards the role of HbE in the upregulation of redox regulators and chaperone proteins in erythrocyte proteome of patients suffering from HbEbeta thalassemia.