Dissociation and oxygen equilibrium properties of the extracellular hemoglobin of Eisenia foetida

The dissociation and oxygen equilibrium properties of whole blood and the purified hemoglobin from Eisenia foetida were compared. Oxygen affinities agreed approximately with each other in the range of pH 6.0 to 9.5. The values of n1/2 were higher in whole blood than in the purified hemoglobin between pH 7.0 and 9.5. The maximum values, obtained near pH 8, were about 6 in whole blood and 3.5 in the purified hemoglobin. In the purified hemoglobin, alkaline dissociation started at pH 7.8, and the approximately 60 S whole molecule dissociated completely into approximately 10 S and 5-6 S components at pH 9.1. In whole blood, however, the dissociation started at pH 8.2 and the complete disappearance of the approximately 60 S molecule occurred at pH 9.6. The values of n1/2 for the dissociation products were lower than those of the purified hemoglobin between pH 7.0 and 9.0. The value of n1/2 decreased with increasing dissociation of the approximately 60 S whole molecule with a pH rise in both whole blood and the purified hemoglobin. Addition of CaCl2 or MgCl2 up to 10 mM to the purified hemoglobin at pH 8.0-8.1 induced increases in oxygen affinity and cooperativity and in the stability of the approximately 60 S whole molecule. The effect on the oxygenation properties was greater with CaCl2 than MgCl2 at the same molar concentration. The stabilizing effect on the approximately 60 S molecule was almost the same with both CaCl2 and MgCl2. These results suggest that the dissociation of property of the hemoglobin in whole blood is controlled by both Ca2+ and Mg2+, and that its oxygenation property is controlled by Ca2+.     

Localization of pyridoxal-5-phosphate, covalently bound with human hemoglobin. Spectrofluorimetric studies]

Human apohemoglobin tryptophan residues were localized in the regions of the protein globule with restricted mobility. By the method of dynamic quenching of phosphopyridoxyl chromophore fluorescence, the heterogeneity of pyridoxal-5-phosphate molecules covalently bound to the human hemoglobin molecules was determined from the accessibility to solvent. The first four pyridoxal-5-phosphate molecules are localized in the hydrophobic regions of the hemoglobin molecule; at the same time, they have a high mobility. One of these molecules is situated at the site inaccessible to the solvent, which coincides with the anion-binding center of the oxyhemoglobin molecule. The next pyridoxal-5-phosphate molecules modify the surface amino groups of the protein. In the apohemoglobin molecule, the pyridoxal-5-phosphate binding sites are more exposed to the solvent, as compared to hemoglobin. In the hemoglobin molecule modified by pyridoxal-5-phosphate, an effective electron excitation energy transfer from tryptophan residues to phosphopyridoxyl chromophores occurs. The effective distances between tryptophanyls of single subunits of hemoglobin and the covalently bound pyridoxal-5-phosphate molecule were estimated to be 19 A for the alpha-subunit and 17 A for the beta-subunit.     

Correlation of the internal microviscosity of human erythrocytes to the cell volume and the viscosity of hemoglobin solutions

The microviscosity of the cytoplasm of human erythrocytes as well as of membrane-free hemoglobin solutions was investigated measuring the rotation of the small spin-label molecule, Tempone. The dependence of the intracellular microviscosity on the extracellular pH and osmotic pressure which was varied by NaCl or sucrose was sufficiently explained on the basis of alterations of the red blood cell volume. The intracellular microviscosity depended exclusively on the hemoglobin concentration. It did not differ from that of comparable membrane-free hemoglobin solutions. It was not necessary to take into account long-range interactions between hemoglobin molecules. The conclusion therefore was that the intracellular viscosity is not modified by cytoplasmic structures or the cell membrane. Above a hemoglobin concentration of 6 mM the viscosity of hemoglobin solutions increased much faster than the microviscosity. From measurements obtained with different spin-labels it followed that also the charge of these molecules is of importance.     

Interaction between Protein Subunits from Model Studies

A molecular model of hemoglobin was constructed which made it possible to visualize the relation between various amino acid residues in the molecule. The model indicates that electrostatic forces might play a significant role in holding the subunits of hemoglobin together. This would explain why myoglobin does not form a tetramer while four β-chains, which are structurally similar to myoglobin, do assemble into a hemoglobin H molecule. Also, as far as the primary structures of hemoglobin chains of various species are known, the proposed ionic links between subunits are consistent with the fact that mammalian hemoglobins form stable tetramers while the peptide chains of lamprey hemoglobin are only weakly associated. The different behavior of hemoglobin H and of normal hemoglobin upon oxygen uptake is briefly discussed in terms of allosteric effects.     

Binding of hemoglobin to red cell membranes with eosin-5-maleimide-labeled band 3: analysis of centrifugation and fluorescence data

We have studied the binding of hemoglobin to the red cell membrane by centrifugation and fluorescence methods. The intact red cell was labeled with eosin-5-maleimide (EM), which specifically reacts with lysine 430 of band 3. Even though this residue is not part of the cytoplasmic domain of band 3 (cdb3) associated with hemoglobin binding, fluorescence quenching was observed when hemoglobin bound to inside-out vesicles (IOVs). The use of fluorescence quenching to measure band 3 binding was quantitatively compared with the binding determined by centrifugation, which measures binding to band 3 and non-band 3 sites. For the centrifugation it was necessary to include the non-band 3 association constants determined from chymotrypsin-treated IOVs. The binding of hemoglobin to band 3 was interpreted in terms of the binding of two hemoglobin tetramers to each band 3 dimer. An anticooperative interaction associated with the conformational change produced when hemoglobin binds results in a 2.8-fold decrease in the intrinsic constant of (1.54 +/- 0.25) x 10(7) M(-1) for the binding of the second hemoglobin molecule. From the changes in lifetime produced by binding the first and second hemoglobin molecules, it was possible to show that the conformational change associated with binding the second hemoglobin molecule results in a decrease of the heme-eosin distance from 47.90 to 44.78 A. Reaction of cyanate with the alpha-amino group of hemoglobin (HbOCN) is shown to produce a very dramatic decrease in the binding of hemoglobin to both the band 3 and non-band 3 sites. The intrinsic constant for binding the first hemoglobin molecule to band 3 decreases by a factor of 29 to (5.34 +/- 0.15) x 10(5) M(-1). The anticooperative interaction is greater with the intrinsic constant decreasing by a factor of 3.8 for the binding of the second hemoglobin tetramer to band 3. In addition, the nature of the conformational change produced by binding hemoglobin is very different with the second HbOCN increasing the heme-eosin distance to 55.99 A. The utilization of eosin-5-maleimide-reacted red cell membrane to study hemoglobin binding makes it possible to directly study the binding to band 3. At the same time a sensitive probe of the conformational changes, which occur when hemoglobin binds to band 3, is provided.     

High-resolution proton nuclear magnetic resonance studies of sickle cell hemoglobin.

High-resoluiton proton nuclear magnetic resonance spectroscopy at 250 MHz has been used to investigate sickle cell hemoglobin. The hyperfine shifted, the ring-current shifted, and the exchangeable proton resonances suggest that the heme environment and the subunit interfaces of the sickle cell hemoglobin molecule are normal. These results suggest that the low oxygen affinity in sickle cell blood is not due to conformational alterations in the heme environment or the subunit interfaces. The C-2 proton resonances of certain histidyl residues can serve as structural probes for the surface conformation of the hemoglobin molecule. Several sharp resonances in sickle cell hemoglobin are shifted upfield from their positions in normal adult hemoglobin. These upfield shifts, which are observed in both oxy and deoxy forms of the molecule under various experimental conditions, suggest that some of the surface residues of sickle cell hemoglobin are altered and they may be in a more hydrophobic environment as compared with that of normal human adult hemoglobin. These differences in surface conformation are pH and ionic strength specific. In particular, upon the addition of organic phosphates to normal and sickle cell hemoglobin samples, the differences in their aromatic proton resonances diminish. These changes in the surface conformation may, in part, be responsible for the abnormal properties of sickle cell hemoglobin.     

Hemoglobin radiolabeling: In vitro and in vivo comparison of iodine labeling with iodogen and a new method for technetium labeling

Radiolabeled hemoglobin may be a useful tool in the study of the body distribution of hemoglobin solutions developed as plasma expanders with oxygen-transporting capacity. The present investigation compares the suitability of two radiolabeling techniques for hemoglobin. ¹²⁵I labeling of hemoglobin with Iodogen® as iodinating agent caused major changes in the chromatographic behaviour and an accelerated plasma clearance of the labeled hemoglobin in rats. A recently developed two-step procedure for ^99mTc labeling gave better results. The label had only minimal influence on the chromatographic behaviour of hemoglobin. In vivo, no free label occurred in the circulation and no transfer of the label to other plasma proteins took place. The plasma clearance of ^99mTc-labeled hemoglobin in rats was slowed. However, this could be explained entirely by diminishing glomerular filtration, probably by inhibition of the dissociation of the hemoglobin molecule into dimers. The plasma clearance of hemoglobin modified by intramolecular cross-linking, which prevents dissociation of the molecule into dimers and thus excretion by the kidney, was not influenced by the label.We conclude that the ^99mTc labeling procedure is suitable for in vivo distribution studies of hemoglobin when it is taken into account that the urinary excretion is underestimated. For cross-linked hemoglobin, which is more promising as plasma expander, no such restriction exists.     

The alkylation of hemoglobin S by nitrogen mustard. High resolution proton nuclear magnetic resonance studies.

Sickle cell hemoglobin (Hb S) treated with nitrogen mustard (bis(beta-chloroethyl)methylamine hydrochloride) gives two reaction products, one labile and one stable. After dialysis against buffer solution, the remaining stable product is found to inhibit the polymerization of deoxyhemoglobin S. High resolution proton nuclear magnetic resonance has been used to study the structure and function of this stable product and to investigate the nature of the binding sites of nitrogen mustard to the hemoglobin molecule. The NMR results suggest that the nitrogen mustard treatment of Hb S does not alter the heme environment or the subunit interfaces of the hemoglobin molecule. Moreover, the NMR spectra have also shown that the nitrogen mustard reacts with the beta2 histidines of the hemoglobin molecule and have suggested that several other surface amino acid residues of the hemoglobin molecule are also affected by the nitrogen mustard alkylation. These NMR findings are in good agreement with the data obtained from biochemical studies of nitrogen mustard-treated Hb S. The NMR spectra also indicate that nornitrogen mustard (which is also effective in inhibiting sickling) binds with the hemoglobin molecule in a manner identical with nitrogen mustard. Sulfur mustard, on the other hand, produces no observable changes in the aromatic proton resonances, which is consistent with the fact that it does not inhibit the polymerization of deoxy-Hb S.     

Production, Purification, and Characterization of Recombinant Human Hemoglobin Rainier Expressed inSaccharomyces cerevisiae

Hemoglobin Rainier is a naturally occurring hemoglobin variant in which the β145 tyrosine is substituted with cysteine. The α and β^Rainierglobin cDNAs were cloned in a high copy number vector and expressed inSaccharomyces cerevisiaeunder the control of galactose-regulated hybrid promoters. Using this system, we have expressed individual α and β^Rainierglobin chains. Coexpression of both α and β^RainiercDNAs resulted in the production of a functional hemoglobin molecule. Purification of the recombinant protein was accomplished by ion exchange chromatography. The N-termini of the α and β chains were correctly processed, and the molecular mass, as determined by mass spectrometry, indicated amino acid composition identical to that of natural hemoglobin Rainier. The chromatographic properties of the recombinant hemoglobin Rainier were similar to human-derived hemoglobin A₀. The purified recombinant hemoglobin molecule was shown to have an elevated oxygen affinity and a reduced cooperativity as previously reported for natural hemoglobin Rainier. Production of recombinant hemoglobin and especially hemoglobin variants like hemoglobin Rainier has the potential to facilitate use of hemoglobin as a blood substitute as well as in specific applications, such as for use as a therapeutic agent in the treatment of hypotension associated with septic shock.     

Keto acids as regulators of hemoglobin reversible oxygenation

Several ketocarbonic acids covalently attached to the protein moiety of hemoglobin were tested as reversible oxygenation regulators. Two monocarbonic acids (glycoxylic and piruvic) and bicarbonic--alpha-ketoglutaric-acid were used for remoglobin modification. Functional properties and isoelectrical characteristics of modified hemoglobin were recorded. The binding of these acids to hemoglobin was shown to affect the net charge of hemoglobin molecule and the nature of its interaction with allosteric effectors (O2; CI-; H+). Under the influence of glyoxylic acid, the gas-transporting characteristics of hemoglobin underwent most distinct changes approaching those of the human whole blood.     

猪血红蛋白(Hb)脉冲酶解效果比较研究

目的寻找一种高效快捷有效地降解猪血红蛋白(Hb)新方法。方法在波型为双向方波,电极间距离为1.2 cm,脉冲频率为200 kHz的脉冲电场下,利用胰蛋白酶在温度为37℃,水解时间为4 h条件下水解猪血红蛋白。结果在脉冲电场作用下,胰蛋白酶水解血红蛋白获得的降解产物,利用高效凝胶色谱、紫外可见扫描及SDS-PAGE蛋白质电泳检测,发现其吸收峰或色带明显多于单一利用胰蛋白酶降解血红蛋白所得降解产物的吸收峰或色带。结论当脉冲电场通过血红蛋白时,血红蛋白内部的分子结构便产生斯塔克效应(Stark effect),引起血红蛋白分子剧烈振动,从而改变其分子结构振辐、吸收峰和偶极矩,并分别引起斯塔克频率、偶极矩、极化率的改变、使血红蛋白分子结构的极化跃迁和超极化,因此,在脉冲电场作用下,促进了血红蛋白酶解反应。     

Kinetic studies on the binding affinity of human hemoglobin for the 4th carbon monoxide molecule, L4.

L4, the affinity of hemoglobin for the 4th CO molecule, has been determined for human adult hemoglobin (HbA) as a function of pH and the presence of organic phosphates by measuring the kinetic parameters for the reaction. l'4, the rate of combination of CO with the triliganded molecule, was measured by flash photolysis while l4, the rate of CO dissociation for the ligand-saturated molecule, was measured by ligand replacement. L4 is pH-dependent and affected by 2,3-diphosphoglycerate. Additionally, this pH dependence of the high affinity state is largely eliminated by carboxypeptidase A digestion. L4 for human fetal hemoglobin (HbF) in phosphate buffers was also determined and found to be pH-dependent. These results cannot be reconciled within the framework of the two-state allosteric model. Additional structures in the conformational equilibrium due to either intermediates in the T to R transition or two or more R states must exist.     

Reaction of haptoglobin with hemoglobin covalently cross-linked between the alpha beta dimers.

Hemoglobin tetramers which cannot split into alphabeta dimers, because they are covalently cross-linked between the beta chains across the polyphosphate binding site, form complexes with haptoglobin. The reaction is biphasic as measured by fluorescence quenching and peroxidase activity. A complex in which one of the alpha beta dimers of the cross-linked hemoglobin is bound to one of the sites in the divalent haptoglobin molecule, is formed reversibly during the initial fast phase. In the subsequent slower step, this product then either polymerizes, adds another cross-linked hemoglobin molecule or, in the presence of excess haptoglobin, combines with a second haptoglobin molecule. This latter complex, in which two haptoglobin molecules are bridged by a cross-linked hemoglobin tetramer, can still combine with normal alpha beta dimers at the vacant haptoglobin combining sites. In spite of the very low oxygen affinity of the cross-linked hemoglobin, combination with haptoglobin shifts if oxygen affinity to the very high value of the normal hemoglobin-haptoglobin complex.     

Immunocytochemical mapping of the hemoglobin biosynthesis site in amphibian erythroid cells.

During the past 25 years, several studies have attempted to determine the site of integration of the heme and the four globin chains in vertebrate erythroid cells that is important in the formation of the hemoglobin molecule. Mitochondrion-like organelles or hemosomes were pointed out as responsible for this task. We performed several experiments to investigate this hypothesis. The intracellular distribution of hemoglobin in amphibian erythroid cells was detected by post-embedding immuno-electron microscopy, using a polyclonal anti-human hemoglobin-proteinA-gold complex. Hemoglobin mapping showed an intense labeling in the cell cytoplasm, but none in cytoplasmic structures such as endoplasmic reticulum, mitochondria, mitochondrion-like organelles, Golgi complex, ribosomes or ferruginous inclusions. The mitochondrial fraction obtained according to the protocol described for some authors, showed by ultrastructural examination that this fraction has a heterogeneous content, also composed by microvesicles rich in cytoplasmic hemoglobin, an artifact generated by mechanical action during cell fractionation. Thus, when this fraction is lysed and its content submitted to electrophoresis, hemoglobin bands would be found inevitably, causing false-positive results, erroneously attributed to hemoglobin content of mitochondrion-like organelles. Our data do not confirm the hypothesis that the final hemoglobin biosynthesis occurs inside mitochondrion-like organelles. They suggest that the hemoglobin molecule be assembled in the erythrocyte cytoplasm outside of mitochondria or hemosomes.     

Implication of the alpha 1 beta 1 interface in the hemoglobin affinity changes. A comparative study between normal and San Diego fully ligated hemoglobins

The alpha 1 beta 1 interface of normal and mutated San Diego hemoglobins in their fully liganded form was investigated, through the SH vibrational absorption of beta-112 cysteine, by Fourier-transform infrared spectroscopy. The center frequency of this thiol group was significantly shifted in San Diego hemoglobin compared with normal human hemoglobin. Different dimer organization between the two proteins was also revealed by circular dichroism of the heme. These findings agree well with assessment that the alpha 1 beta 1 interface, far from being inert, is involved in the affinity changes of the hemoglobin molecule.     

A simulation study of the anomalous osmotic behavior of red cells

The factors responsible for movements of water across cell membranes were described mathematically and incorporated into a model which simulates water balance in the cell. Included in the model are a variable charge and osmotic coefficient of hemoglobin, a Na/K pump whose rate varies with ionic concentrations, and the standard electroneutrality and osmotic equilibrium assumptions. The model was used to investigate the phenomena whereby human red cells placed in media of varying tonicities exhibit steady state volume changes less than those predicted by van't Hoff's Law. The model results showed that this anomalous osmotic behavior was primarily due to changes in the osmotic coefficient of hemoglobin as its concentration in the cell varied. A second factor accounting for a part of this behavior was the alteration in the rate of the Na/K pump due to intracellular ionic concentration changes as cell volume varied. The effect of variable electrical charge on the hemoglobin molecule was found to be in the wrong direction to account for the observed osmotic behavior. Also, this effect was seen to produce relatively large changes in cell membrane potential, a result inconsistent with experimental data. It was concluded from the model results that the anomalous osmotic behavior of human red cells is primarily due to the variation in the osmotic coefficient of hemoglobin as the cell volume changes, and that the variable charge effect on the hemoglobin molecule, if it exists, does not play a role in this response.     

PHYSICOCHEMICAL PROPERTIES OF THE PROTEOLYTIC ENZYME FROM THE LATEX OF THE MILKWEED,ASCLEPIAS SPECIOSA TORR. SOME COMPARISONS WITH OTHER PROTEASES : II. KINETICS OF PROTEIN DIGESTION BY ASCLEPAIN

1. The kinetics of milk clotting by asclepain, the protease of Asclepias speciosa, were investigated. At higher concentrations of enzyme, the clotting time was inversely proportional to the enzyme concentration. 2. The digestion of casein and hemoglobin in 6.6 M urea by asclepain follows the second order reaction rate. The rate was roughly second order for casein in water. 3. Evaluation of the nature of the enzyme-substrate intermediate indicates that one molecule of asclepain combines with one molecule of casein or hemoglobin in urea solution. 4. Inhibition by the reaction products was deduced from the fact that the digestion velocity of hemoglobin in urea solution varied with the asclepain concentration in agreement with the Schütz-Borissov rule.     

Studies of oxygen binding energy to hemoglobin molecule.

The fractional oxygen saturation of hemoglobin and of its isolated α-chains have been determined by the application of the technique of Mossbauer effect while the oxygen equilibrium pressure was measured directly. By comparing the experimental data so obtained with theoretically derived oxygen saturation curves for hemoglobin and isolated α-chains the values of the oxygen pairing energy and oxygen binding energy to hemoglobin molecule have been found to be 0.043 ± 0.004 and 0.60 ± 0.06 eV respectively.     

Binding reaction of hemin to globin

Binding of hemin to globin was studied in the presence of 25 mM caffeine by measuring CD and optical absorption changes in the Soret region. CD and optical absorption spectra after mixing equimolar amounts of hemin and globin were the same as those of ferric hemoglobin. In contrast, addition of excess globin to hemin formed a complex that was distinguishable from ferric hemoglobin in terms of the CD and optical absorption spectra. By comparing the spectra of the complex with those of various hemoglobin derivatives, it was concluded that the complex was globin which carried a hemin exclusively on the alpha chain. This means that the alpha chain of the globin molecule has a greater affinity for hemin than the beta chain, as observed by other investigators using hemin-cyanide. The rate of binding of hemin to globin was estimated by the use of CD and optical absorption stopped-flow apparatus. The rate of hemin binding to the alpha chain of globin was obtained by mixing hemin and excess globin, and that to the beta chain was obtained by mixing equimolar concentrations of hemin and globin. The results showed that hemin was bound to the alpha chain in the globin molecule to form a transient intermediate, followed by its transformation into another intermediate, the transformation was the rate-limiting step, and the beta chain in the globin molecule had a greater affinity for hemin after hemin binding to the alpha chain than before.     

Thermal stability and functional properties of human hemoglobin in the presence of aliphatic alcohols]

Differential scanning microcalorimetry was used to study thermal stability of the ferro- and ferriforms of hemoglobin at pH 7.4 in phosphate buffer and in buffer mixtures of methanol, ethanol, 1-propanol. Denaturation of the human hemoglobin molecule composed of four subunits was cooperative transition. The thermostability of the hemoglobin forms decreased in the order of carboxyhemoglobin (TD = 82.0 degrees C) > oxyhemoglobin (71.0 degrees C) > methemoglobin (67.0 degrees C). The aliphatic alcohols as cosolvents decreased the hemoglobin stability because of loosening the structure of the globin moiety by disturbing its hydrophobic contacts and hydrogen bonds. These alcohols reduced the oxygen affinity for hemoglobin probably due to perturbation of the R<-->T equilibrium by the decreased bulk dielectric constant of the solvent. Oxyhemoglobin and methemoglobin was converted to hemichrome by high alcohol concentrations.