Gas exchange properties of goat hemoglobins A and C

Hypoxic or anemic goats with the A hemoglobin genotype switch to the production of hemoglobin C, resulting in a reduced blood oxygen affinity. However, the physiologic consequences of this switch are not clear. We therefore studied the gas exchange properties of the two hemoglobin types. We found that purified hemoglobins A and C have very similar oxygen affinities and H+ Bohr effects, but in the presence of CO2, the affinity of hemoglobin C is substantially less than that of hemoglobin A. That this is not a nonspecific ionic effect is suggested by identical effects of NaCl on O2 binding to the two proteins and by a 2-fold higher capacity of hemoglobin C to bind CO2. The data can be explained by a class of CO2 binding sites in the beta C chain whose affinity is much higher than that of either of the primary sites or of those in Hb A. Our results suggest that in hemoglobin C-containing red cells CO2 acts as a potent allosteric effector, analogous to the role played by 2,3-diphosphoglycerate in human red blood cells. Goat hemoglobin C may have advantages over hemoglobins A or B in O2 transport under hypoxic conditions or in anemia.     

新型人工红细胞的制备

目的:接枝淀粉包裹血红蛋白制备新型人造红细胞的代替品。方法:利用油酸接枝淀粉,在超声条件下下自组装,包裹天然牛血红蛋白,并鉴定其物理化学及生物学性能。测定包封率、红外光谱分析(FTIR)、电镜观察形态学及粒径,测定P50和Hill系数。结果:人工红细胞呈圆球形,平均粒径250nm,包封率高,具有良好的携氧、释氧能力。结论:成功制备了人工纳米红细胞,为进一步临床应用提供了基础。     

Solid-phase extraction of phospholipids from hemoglobin solutions using Empore styrene–divinylbenzene disks

Styrene–divinylbenzene Empore disks were investigated for the extraction of phospholipids from red blood cells or aqueous solutions of hemoglobin as a means to reduce the time and solvent use required in sample preparation. Red blood cells are the source for hemoglobin used in the preparation of a hemoglobin-based oxygen carrier which is being developed to replace blood in transfusion therapy. Phospholipids are a major component of the membrane of red blood cells, and are toxic when administered directly into the vasculature. Sensitive analytical methods are required to detect phospholipids to ensure that concentrations in purified hemoglobin are well below toxic levels. This requires isolation from large volumes of purified hemoglobin solutions. The method described utilizes Empore disks to extract phospholipids from 30 ml of stroma free Hb preparations. Phosphatidylethanolamine, phosphatidylinositol, phosphatidylcholine and sphingomyelin were recovered with an average of 92% yield. The recovery of phosphatidylserine was 65%. The use of solvent and time required for sample preparation were reduced by an average of 80% relative to liquid–liquid extraction. The capacity of the 47-mm disk for the total of five phospholipids exceeds 0.3 mg. The method has been used for quantitation of phospholipids in red blood cells and stroma free hemoglobin solutions.     

Ligand reactivity and allosteric regulation of hemoglobin-based oxygen carriers

Historically, exogenous administration of hemoglobin solutions to implement the oxygen transport capacity for clinical applications suffered from dramatic drawbacks, resulting in the failure of many attempts. In the last decades, the biochemical and physiological basis responsible for the therapeutic failures has been extensively investigated. It is now widely accepted that they mostly arise because, out of the confined and controlled environment of the red blood cell, hemoglobin exhibits tetramer instability, increased auto-oxidation rate, higher oxygen affinity, altered cooperativity and nitric oxide reactivity. Moreover, it became evident that the design of a hemoglobin-based oxygen carrier that exactly reproduces the "physiological" oxygen-binding curve is not only an overly ambitious task, but may also represent a wrong approach for many potential clinical applications. Under these premises, and given the complex chemical nature of blood, it is obvious that any strategy undertaken to modify the stability and function of the hemoglobin tetramer for clinical use should be driven by a detailed knowledge of its structure, dynamics and mechanism of allosteric regulation. We briefly review the most recent theories and experiments that increased our understanding of the mechanism of homo- and heterotropic effects in human hemoglobin, trying to interpret, on a biophysical basis, how diverse approaches like polymerization, cross-linking, site-directed mutagenesis, surface decoration and encapsulation may affect ligand affinity and allosteric regulation.     

The Secretion of Oxygen into the Swim-bladder of Fish : II. The simultaneous transport of carbon monoxide and oxygen

Toadfish, Opsanus tau, L., were maintained in sea water equilibrated with gas mixtures containing a fixed proportion of oxygen and varying proportions of carbon monoxide. The swim-bladder was emptied by puncture, and, after an interval of 24 or 48 hours, the newly secreted gases were withdrawn and analyzed. Both carbon monoxide and oxygen are accumulated in the swim-bladder at tensions greater than ambient. The ratio of concentrations, carbon monoxide (secreted): carbon monoxide (administered) bears a constant relation to the ratio, oxygen (secreted): oxygen (administered). The value of the partition coefficient describing this relation is (α = 5.44). The two gases are considered to compete for a common intracellular carrier mediating their active transport. The suggestion is advanced that the intracellular oxygen carrier is a hemoglobin. Comparison of the proportions of carboxy- and oxyhemoglobin in the blood with the composition of the secreted gas proves that the secreted gases are not evolved directly from combination with blood hemoglobin. The suggestion is advanced that cellular oxygen secretion occurs in the rete mirabile: the rete may build up large oxygen tensions in the gas gland capillaries. It is suggested that the gas gland acts as a valve impeding back diffusion of gases from the swim-bladder.     

Biophysical study on the interaction of cartap hydrochloride and hemoglobin: Heme degradation and functional changes of protein

Cartap hydrochloride is a mildly perilous insecticide known as “Padan” which is used largely in agricultural farms to control weevil and caterpillars. The over use of cartap causes harmful effects on human health. Since the blood may acts as a target and carrier for insecticides, the effect of these compounds on blood in mammalian toxicology is very important. Hemoglobin is a tetramer protein that play critical role in oxygen transport. The aim of this study was to analyze and compare the function and structural changes of hemoglobin in the presence of different concentrations of cartap by employing different spectroscopic techniques. The obtained results show that cartap has a high hemolytic effect which is increased with cartap concentration and reduces the thermal midpoint of hemoglobin. Fluorescence measurements reveal heme degradation at different concentrations of cartap. In consequence of theoretical and experimental results, cartap has an undesirable effect on hemoglobin structure and function.     

Chemical characterization of pyridoxalated hemoglobin polyoxyethylene conjugate

Pyridoxalated hemoglobin polyoxyethylene conjugate (PHP) was developed in the 1980s as an oxygen carrier and is now under development for treatment of nitric oxide-dependent, volume refractory shock. PHP is made by derivatizing human stroma-free hemoglobin with pyridoxal-5-phosphate and polyoxyethylene (POE). A unique aspect of using POE for modification is that unlike its mono-methoxy polyethylene glycol (PEG) relatives, POE is bifunctional. The result of derivatization of stroma-free hemoglobin is a complex mixture of modified hemoglobin and other red cell proteins. The molecular weight profile, based on size exclusion chromatography, is bimodal and has a number average molecular weight of approximately 105? omitted?000 and a weight average molecular weight of approximately 187? omitted?000. The mixture of hemoglobin molecules has on average 3.3 pyridoxal and 5.0 polyoxyethylene units per tetramer. A portion of the tetramers are linked by POE crosslinks. The hemoglobin tetramers retain their ability to dissociate into dimer pairs and only a small percentage of the dimer pairs are not modified with POE. The SDS-PAGE profile exhibits the ladder-like appearance commonly associated with polyethylene glycol-modified proteins. The isoelectric focusing profile is broad, demonstrating a pI range of 5.0-6.5. The hydrodynamic size of PHP was determined to be approximately 7.2 nm by dynamic light scattering. Soluble red blood cell proteins, such as catalase, superoxide dismutase, and carbonic anhydrase, are present in PHP and are also modified by POE.     

Fixation of aldehydic dextrans onto human deoxyhemoglobin.

A procedure commonly used to transform native adult human hemoglobin (Hb) into a physiological oxygen carrier consists of a pyridoxylation of the protein to lower its oxygen affinity, followed by its polymerization in the presence of glutaraldehyde, with or without further reduction, to increase its circulating half-life. This series of reactions yields derivatives presenting a great molecular heterogeneity that have to be fractionated for use in vivo. Hemoglobin derivatives with low oxygen affinity and a narrow distribution of molecular weights were obtained by linking a dextran polyaldehydic derivative to deoxyhemoglobin at pH 8. From oxygen-binding measurements carried out in the presence of inositolhexaphosphate, a strong effector of hemoglobin, it appeared that the allosteric site of hemoglobin was blocked, probably by crosslinking bonds, which stabilizes its deoxy structure. On the other hand, when the reaction was performed in the presence of inositolhexaphosphate, the resulting conjugates exhibited an oxygen affinity identical to that of unmodified hemoglobin. After treatment with NaBH4, the polymer-hemoglobin derivatives were stable and possessed a reversible oxygen-carrying capacity similar to that of blood. The conjugates prepared from oxyhemoglobin all possessed a lower P50 than native hemoglobin whatever the reaction conditions.     

Steady-State, Hemoglobin-Facilitated O2 Transport in Human Erythrocytes

We measured the rate of oxygen transport through thin (165 µ) films of packed erythrocytes (Hb concentration = 30 g/100 ml). Under optimal conditions steady-state O₂ diffusion was nearly three times that found when the hemoglobin was prevented from acting as a carrier molecule by carbon monoxide binding or high oxygen back pressure. After each experiment we measured hemolysis and found that it averaged less than 1%. Hemolysis could not account for the facilitation, thus proving that facilitated transport of O₂ by hemoglobin can occur in red blood cells. The rate of facilitated transport was identical for Hb solutions of equal concentration to the cells. We interpret this to mean that under the conditions of our experiments the red cell membrane offers no detectable diffusion resistance to O₂ and that the mobility of Hb in intact red cells is the same as in concentrated Hb solution.     

Insensitivity of cerebral oxygen transport to oxygen affinity of hemoglobin-based oxygen carriers

The cerebrovascular effects of exchange transfusion of various cell-free hemoglobins that possess different oxygen affinities are reviewed. Reducing hematocrit by transfusion of a non-oxygen-carrying solution dilates pial arterioles on the brain surface and increases cerebral blood flow to maintain a constant bulk oxygen transport to the brain. In contrast, transfusion of hemoglobins with P50 of 4-34 Torr causes constriction of pial arterioles that offsets the decrease in blood viscosity to maintain cerebral blood flow and oxygen transport. The autoregulatory constriction is dependent on synthesis of 20-HETE from arachidonic acid. This oxygen-dependent reaction is apparently enhanced by facilitated oxygen diffusion from the red cell to the endothelium arising from increased plasma oxygen solubility in the presence of low or high-affinity hemoglobin. Exchange transfusion of recombinant hemoglobin polymers with P50 of 3 and 18 Torr reduces infarct volume from experimental stroke. Cell-free hemoglobins do not require a P50 as high as red blood cell hemoglobin to facilitate oxygen delivery.     

Maternal-Fetal Oxygen Transfer in Lower Vertebrates

There exists a difference in oxygen affinity between fetal andmaternal bloods in almost all vertebrates examined and thisdifference in affinities probably facilitates oxygen transferto the fetus. It is likely that the high oxygen affinity offetal blood represents a biochemical pre-adaptation from anancestral oviparous embryo for oxygen uptake in a relativelyhypoxic environment. In most cases, the maternal-fetal differencein blood oxygen affinities is due to the characteristics ofthe fetal red cell and not due to any changes in the adult redcell during pregnancy. These characteristics are based on thepresence of a unique fetal hemoglobin with an intrinsicallyhigh affinity for oxygen or on the absence of high red cellconcentrations of organic phosphates—allosteric modulatorsof hemoglobin function. However, in several species of snake,representing different families, it appears that pregnancy isassociated with apronounced decrease in the oxygen affinityof the adult red cell. This suggests that the blood of the pregnantfemale is better able to unload oxygen to the fetus than couldthe blood of thenonpregnant adult. The maternal-fetal differencein blood oxygen affinities in these species isprobably due tothe characteristics of the fetal red cell as well as to thechange in the affinity of the adult cell during pregnancy. Nonetheless,although the magnitude of the pregnancy-associated change inoxygen affinity of the adult cell in these snakes suggests thatit is physiologically significant, the actual significance remainsto be determined.     

On the Oxygen Affinity of Bird Blood

In oxygen affinity characteristics bird blood appears to haveseveral features that distinguish it from mammalian blood. Fordomesticated species at least the range of oxygen half saturationvalues is extremely wide. A difference in the shape of the oxygendissociation curve has been recorded by several authors withan increase in sigmoidocity with increasing oxygen saturation.There is evidence that the oxygen affinity determining organicphosphate of bird red blood cells inositol pentaphosphate (IP5)is relatively metabolically inert. This suggests that modulationof blood oxygen affinity is primarily achieved by altering theIP5 hemoglobin interaction rather than varying IP5 levels perse. In contrast to mammals carbon dioxide has no direct effecton whole blood oxygen affinity for some bird species (hen chickgoose) or it may cause the oxygen affinity to increase (pigeonflamingo). Carbon dioxide is a blood oxygen affinity modulatorof some flexibility its effect in both direction and magnitudebeing dependent on the hemoglobin type red cell pH and organicphosphate levels. The physiological significance of these distinguishingfeatures is discussed.     

1H-NMR investigation of the oxygenation of hemoglobin in intact human red blood cells.

Using improved selective excitation methods for protein nuclear magnetic resonance (NMR), we have conducted measurements of the oxygenation of hemoglobin inside intact human red blood cells. The selective excitation methods use pulse shape-insensitive suppression of the water signal, while producing uniform phase excitation in the region of interest and, thus, are suitable for a wide variety of applications in vivo. We have measured the areas of 1H-NMR resonances of the hyperfine-shifted, exchangeable N delta H protons of the proximal histidine residues of the alpha- and beta-chains in deoxyhemoglobin (63 and 76 ppm downfield from the proton resonance of 2,2-dimethyl-2-silapentane-5-sulfonate (DSS), respectively), which are sensitive to the paramagnetic state of the iron, and for which the alpha- and beta-chain resonances are resolved, and from the ring current-shifted gamma 2-CH3 protons of the distal valine residues in oxyhemoglobin (2.4 ppm upfield from DSS), which are sensitive to the conformation of the heme pocket in the oxy state. We have found that the proximal histidine resonances are directly correlated with the degree of oxygenation of hemoglobin, whereas the distal valine resonances appear to be correlated with the conformation in the heme pocket that occurs after the binding of oxygen, in both the presence and absence of 2,3-diphosphoglycerate. In addition, from the proximal histidine resonances, we have observed a preference for the binding of oxygen to the alpha-chain (up to about 10%) of hemoglobin over the beta-chain in both the presence and absence of 2,3-diphosphoglycerate. These new results obtained in intact erythrocytes are consistent with our previous 1H-NMR studies on purified human normal adult hemoglobin. A unique feature of our 1H-NMR method is the ability to monitor the binding of oxygen specifically to the alpha- and beta-chains of hemoglobin both in solution and in intact red blood cells. This information is essential to our understanding of the molecular basis for the hemoglobin molecule serving as the oxygen carrier in vertebrates.     

Limited synthesis of labile hemoglobin A1 in vivo and in vitro by the preexisting hemoglobin A1 in diabetic subjects

The synthesis of labile hemoglobin A1 in vivo was studied in subjects with non-insulin dependent diabetes mellitus, impaired and normal glucose tolerance. The labile hemoglobin A1 index defined as delta labile hemoglobin A1 divided by delta plasma glucose at 30 min after oral glucose load, representing the rate of labile hemoglobin A1 synthesis in vivo, was low in diabetic subjects and high in normal subjects, showing an inverse correlation with the amount of preexisting hemoglobin A1. The study on the synthesis of labile hemoglobin A1 in vitro showed a lower initial rate of synthesis and a smaller increase in labile hemoglobin A1 at saturation in red blood cells from diabetic subjects with a relatively large amount of preexisting hemoglobin A1, as opposed to red blood cells from normal subjects. Although the further study is necessary in which delta plasma glucose levels are kept relatively constant in each of 3 groups by glucose-clamp methods, our data suggest that the synthesis of labile hemoglobin A1 is limited in vivo and in vitro in diabetic subjects by the preexisting hemoglobin A1 due to the saturability of its synthesis.     

Unloading oxygen in a capillary vessel under a pathological condition

In this work, we study theoretically the unloading of oxygen from a hemoglobin molecule to the wall of a typical capillary vessel, considering that the hemoglobin under pathological conditions, obeys the rheological Maxwell model. Based on recent experimental evidences in hypertension, we consider that the red blood cells (RBCs) are composed by a single continuous medium in contrast with the classical particulate or discrete RBC models, which are only valid under normal physiological conditions. The analysis considers the hemodynamic interactions between the plasma and the hemoglobin, both circulating in a long horizontal capillary. We apply numerical and analytical methods to obtain the main fluid-dynamic characteristics for both fluids in the limit of low Reynolds and Womersley numbers. A diffusion boundary layer formulation for the oxygen transport in the combined plasma-hemoglobin core region is presented. The main aspects derived are the time and spatial evolution of the membrane. The hemoglobin and plasma velocities and the pressure distributions are shown. For the oxygen unloading the results are the oxy-hemoglobin saturation, the oxygen flux and the oxygen concentration in the cell-free plasma layer. The volume fraction of red blood cells and the Strouhal number have a great influence on the hemodynamic interactions.     

Finite Element Model of Oxygen Transport for the Design of Geometrically Complex Microfluidic Devices Used in Biological Studies

Red blood cells play a crucial role in the local regulation of oxygen supply in the microcirculation through the oxygen dependent release of ATP. Since red blood cells serve as an oxygen sensor for the circulatory system, the dynamics of ATP release determine the effectiveness of red blood cells to relate the oxygen levels to the vessels. Previous work has focused on the feasibility of developing a microfluidic system to measure the dynamics of ATP release. The objective was to determine if a steep oxygen gradient could be developed in the channel to cause a rapid decrease in hemoglobin oxygen saturation in order to measure the corresponding levels of ATP released from the red blood cells. In the present study, oxygen transport simulations were used to optimize the geometric design parameters for a similar system which is easier to fabricate. The system is composed of a microfluidic device stacked on top of a large, gas impermeable flow channel with a hole to allow gas exchange. The microfluidic device is fabricated using soft lithography in polydimethyl-siloxane, an oxygen permeable material. Our objective is twofold: (1) optimize the parameters of our system and (2) develop a method to assess the oxygen distribution in complex 3D microfluidic device geometries. 3D simulations of oxygen transport were performed to simulate oxygen distribution throughout the device. The simulations demonstrate that microfluidic device geometry plays a critical role in molecule exchange, for instance, changing the orientation of the short wide microfluidic channel results in a 97.17% increase in oxygen exchange. Since microfluidic devices have become a more prominent tool in biological studies, understanding the transport of oxygen and other biological molecules in microfluidic devices is critical for maintaining a physiologically relevant environment. We have also demonstrated a method to assess oxygen levels in geometrically complex microfluidic devices.     

Oxygen binding and other physical properties of human hemoglobin made in yeast.

Wagenbach et al. (1991, BioTechnology, 9, 57-61) have recently developed a system for producing soluble recombinant tetrameric hemoglobin in yeast: hemoglobin begins to appear 4-5 h after induction with galactose, alpha- and beta-globin chains fold in vivo and endogeneously produced heme is incorporated into hemoglobin tetramers. We have further characterized the oxygen-binding properties, as well as the tetramer stability, of recombinant human Hb A made in yeast. After purification by ion-exchange chromatography, a single band at the same position as normal human Hb A was obtained using cellulose acetate electrophoresis. Although the oxy and deoxy forms of purified recombinant Hb A made in yeast were spectrophotometrically identical to native human Hb A, the oxygen-binding curve was shifted slightly left of that for native human Hb A. Further purification of recombinant hemoglobin by FPLC revealed two fractions: one (fraction B) with low cooperativity and high oxygen affinity, and the other (fraction A) with almost identical cooperativity and oxygen affinity compared with native human Hb A. The Bohr effect of fraction A was also identical to native human Hb A. Hemoglobin in fraction B with lowered cooperativity precipitated approximately 1.5 times faster than normal human Hb A during mechanical agitation, while hemoglobin in fraction A with normal cooperativity precipitated with kinetics identical to native human Hb A. These results suggest that some of the recombinant molecules made in yeast fold improperly, and that these molecules may exhibit decreased cooperativity for oxygen binding and decreased stability.(ABSTRACT TRUNCATED AT 250 WORDS)     

Footstrike is the major cause of hemolysis during running.

There is a wide body of literature reporting red cell hemolysis as occurring after various forms of exercise. Whereas the trauma associated with footstrike is thought to be the major cause of hemolysis after running, its significance compared with hemolysis that results from other circulatory stresses on the red blood cell has not been thoroughly addressed. To investigate the significance of footstrike, we measured the degree of hemolysis after 1 h of running. To control for the potential effects of oxidative and circulatory stresses on the red blood cell, the same subjects cycled for 1 h at equivalent oxygen uptake. Our subjects were 10 male triathletes, who each completed two separate 1-h sessions of running and cycling at 75% peak oxygen uptake, which were performed in random order 1 wk apart. Plasma free hemoglobin and serum haptoglobin concentrations were measured as indicators of hemolysis. We also measured methemoglobin as a percentage of total hemoglobin immediately postexercise as an indicator of red cell oxidative stress. Plasma free hemoglobin increased after both running (P < 0.01) and cycling (P < 0.01), but the increase was fourfold greater after running (P < 0.01). This was reflected by a significant fall in haptoglobin 1 h after the running trials, whereas no significant changes occurred after cycling at any sample point. Methemoglobin increased twofold after both running and cycling (P < 0.01), with no significant differences between modes of exercise. The present data indicate that, whereas general circulatory trauma to the red blood cells associated with 1 h of exercise at 75% maximal oxygen uptake may result in some exercise-induced hemolysis, footstrike is the major contributor to hemolysis during running.     

Hemoglobin system of golden mullet (Liza aurata,Risso) at adaptation to conditions of outer hypoxia

Under conditions of experiment, effect of outer hypoxia on the hemoglobin heterogeneous system and respiratory blood characteristics were studied in the golden mullet Lisa aurata R. The control fish group was maintained at oxygen pressure of 158–162 gPa, the experimental group at 54–55 gPa. The exposure was 15 days, the water temperature—15°C. Under conditions of oxygen deficit in the mullet body there is noted development of a complex of compensatory reactions directed to maintenance of the oxygen blood capacity. Initially (the 1st–2nd day), the release of erythrocytes from spleen is noted, which increases the number of red blood cells and the hemoglobin concentration in blood (the emergency adaptation). Subsequently (the 10–15th day), there occur quantitative readjustments at the level of the hemoglobin system, which lead to an increase in the blood affinity to oxygen and to a decrease in its sensitivity to pH (the long-term adaptation). The revealed changes take place on the background of a decrease in volume of circulating erythrocytes, which reflects the character of change of erythrocytic parameters (MCV, MCHC) and seems to be a consequence of partial dehydration of blood plasma.