Oxygen Equilibrium Curves Research Articles

The functioning of the haemocyanin of the terrestrial christmas island red crab gecarcoidea natalis and roles for organic modulators

Gecarcoidea natalis is a land crab that migrates annually several kilometres to breed. The O2-binding properties of haemocyanin in G. natalis were investigated in vitro to test the idea that the O2-binding properties of the haemocyanin of land crabs are not dependent on circulating modulators and to provide a model of haemocyanin functioning during exercise. The affinity of the haemocyanin for O2 decreased with increasing temperature (change in the heat of oxygenation; capdelta H=-59 kJ mol-1). The haemocyanin of G. natalis apparently differs from that of other terrestrial crabs in showing haemocyanin O2 modulation by both organic and inorganic molecules. Haemocyanin O2-affinity was not affected by Mg2+ but was sensitive to changes in Ca2+ concentration ( capdelta logP50/ capdelta log[Ca]=-0.61, where P50 is the partial pressure of O2 required for half-maximal O2 binding). The Bohr factor was modest ( &phgr; =-0.26+/-0.03, N=4, in whole haemolymph at 25 degreesC) and there was no specific effect of CO2 on the O2-binding properties of the haemocyanin. An increase in urate concentration increased haemocyanin O2-affinity, but the effect was linear ( capdelta logP50/ capdelta [urate]=-0.06) and not logarithmic as is the case in other species. The effect of l-lactate on the haemocyanin O2-affinity in G. natalis was unique among the crustaceans, because an increase in l-lactate concentration decreased the haemocyanin O2-affinity. The effect of l-lactate on haemocyanin O2-affinity ( capdelta logP50/ capdelta log[lactate]) was time-dependent and decreased from a maximum of 0.044 on day 1 to 0.001 after 4 days of storage at 4 degreesC. The presence of an unknown dialysable and unstable factor in the haemolymph is postulated to explain the time-dependent effect of l-lactate on haemocyanin O2-binding properties. Model oxygen equilibrium curves constructed for in vivo conditions showed that the reverse effect of l-lactate was advantageous by decreasing the O2-affinity of the haemocyanin beyond that predicted by the Bohr shift alone and assisted in O2 off-loading at the tissues. This effect of lactate can only provide an advantage if the gas-exchange organs maintain arterial O2 loading and thus is dependent on lung function in land crabs and must have occurred coincident with the evolution of these other features.

Effects of hyperchloremia on blood oxygen binding in healthy calves.

Three different levels of hyperchloremia were induced in healthy Friesian calves to study the effects of chloride on blood oxygen transport. By infusion, the calves received either 5 ml/kg of 0.9% NaCl (low-level hyperchloremia; group A), 5 ml/kg of 7.5% NaCl (moderate hyperchloremia; group B), or 7.5 ml/kg of 7.5% NaCl (high-level hyperchloremia; group C). Blood was sampled from the jugular vein and the brachial artery. Chloride concentration, hemoglobin content, arterial and venous pH, PCO2, and PO2 were determined. At each time point (0, 15, 30, 60, and 120 min), the whole blood oxygen equilibrium curve (OEC) was measured under standard conditions. In groups B and C, hyperchloremia was accompanied by a sustained rightward shift of the OEC, as indicated by the significant increase in the standard PO2 at 50% hemoglobin saturation. Infusion of hypertonic saline also induced relative acidosis. The arterial and venous OEC were calculated, with body temperature, pH, and PCO2 values in arterial and venous blood taken into account. The degree of blood desaturation between the arterial and the venous compartments [O2 exchange fraction (OEF%)] and the amount of oxygen released at tissue level by 100 ml of bovine blood (OEF vol%) were calculated from the arterial and venous OEC combined with the PO2 and hemoglobin concentration. The chloride-induced rightward shift of the OEC was reinforced by the relative acidosis, but the altered PO2 values combined with the lower hemoglobin concentration explained the absence of any significant difference in OEF (% and vol%). We conclude that infusion of hypertonic saline induces hyperchloremia and acidemia, which can explain the OEC rightward shift observed in arterial and peripheral venous blood.

In vitro study of alcohol dehydrogenase and acetaldehyde dehydrogenase encapsulated into human erythrocytes by an electroporation procedure

The optimal conditions for electroporated/resealed loading of alcohol dehydrogenase (ADH) and/or acetaldehyde dehydrogenase (ALDH) into human erythrocytes were established prior to the study, with the following characteristics: 300 V, 1 ms pulse time, eight pulses every 15 min and 1 h resealing at 37°C. High encapsulation yield and carrier cell recoveries were achieved. Cell volumes increase while hemoglobin contents decrease; in consequence a decrease in cell hemoglobin concentration was observed. A lower hypotonic resistance of loading erythrocytes (throughout osmotic fragility curves) and unaltered oxygen transport capability (as given by oxygen equilibrium curves) were observed. The stability against time (up to 168 h–7 days) of encapsulated individual enzymes, either ADH- or ALDH-red blood cells (RBCs), was studied at 4°C and 37°C, in comparison with that of free enzyme solutions. Both enzymes were released from carrier RBCs to the incubation medium. The stability of carrier RBCs was studied under similar conditions. Non-significant variations in hematological parameters were observed. However, the hemoglobin derivative forms showed modifications. The continuous degradation of ethanol by ADH-RBCs and coencapsulated ADH- and ALDH-RBCs, as a function of time (up to 70 h) suggests the use of these carrier RBCs as agents for complete metabolization of ethanol. The mentioned properties bare the possibility of using ADH and ALDH as carrier systems in in vivo situations.

Modulating the oxygen affinity of human fetal haemoglobin with synthetic allosteric modulators.

Improving the delivery of oxygen to the tissues by decreasing the oxygen affinity of haemoglobin has been a major aim of several laboratories over recent years because this may reduce the consequences of anaemia and/or improve tissue oxygenation in cases of decreased blood perfusion. Within the same context, lowering the oxygen affinity may prove valuable in the application of native or recombinant haemoglobin solutions as a blood substitute. The shift of the oxygen equilibrium curve to the right is obtained by various modulators. Among them, the bezafibrate derivatives are considered as a most interesting group. These principles are of the utmost importance in thalassaemia and other haemoglobinopathies where the beneficial effects of the compensatory synthesis of fetal haemoglobin are diminished by the increased oxygen affinity of this pigment. In this paper we present the results of a study initiated to determine whether a potent oxygen affinity modifier, RSR-4, could satisfactorily decrease the oxygen affinity of fetal haemoglobin, thus improving tissue oxygenation. The experiments were carried out on whole blood and on purified haemoglobin solutions and showed that the effector markedly decreased the oxygen affinity of HbF (from 18.7 to 3.73 mmHg in whole blood). At the same time the cooperativity index (n50) and the oxygen saturation levels remained within normal limits under the conditions of the main experiment. These observations have important implications for the potential application of oxygen affinity modifiers in vivo.

Cooperative mechanism in the homodimeric myoglobin from Nassa mutabilis.

Oxygen binding and spectroscopic properties of the homodimeric myoglobin (Mb) from the prosobranchia sea snail Nassa mutabilis have been investigated. Oxygen equilibrium curves are pH-independent and cooperative with P50 = 5 +/- 1 mmHg and n approximately 1.5. Circular dichroism spectra of the oxygenated and deoxygenated form of N. mutabilis Mb are superimposable between 190 and 250 nm, suggesting a mechanism for cooperative ligand binding that does not involve changes in the alpha-helical content of the whole protein. The oxygen dissociation process is biphasic and pH-dependent, with different pKa values (=6.7 +/- 0.2 and 8.5 +/- 0.3) for the two phases. Moreover, the activation energy is essentially the same for both oxygen dissociation processes (Ea = 56.4 +/- 2.1 kJ/mol for the fast phase, and Ea = 53.8 +/- 1.9 kJ/mol for the slow phase), indicating that the rate difference for O2 dissociation between the diliganded and the monoliganded species is mostly dependent on a variation of the activation entropy. Ferrous nitrosylated N. mutabilis Mb shows, at alkaline and neutral pH, axial and rhombic X-band EPR signals, respectively, which display below pH 6 a three-hyperfine pattern typical of five-coordination. The results presented here suggest that in N.mutabilis Mb the kinetic control of cooperativity operates through a mechanism never observed before in other hemoproteins, which requires a ligand-linked large enhancement for the value of the oxygen association process in a molecule not undergoing changes in quaternary structure.

Hemoglobin–Oxygen Equilibrium Curves Measured during Enzymatic Oxygen Consumption

A rapid, new method to measure hemoglobin–oxygen equilibrium curves is described using the protocatechuic acid/protocatechuic acid 3,4-dioxygenase system [C. Bull and D. P. Ballou (1981)J. Biol. Chem.256, 12673–12680] to deoxygenate hemoglobin solutions enzymatically. The reaction is followed by simultaneous measurements of hemoglobin spectra using a diode array spectrophotometer and oxygen tensions using a polarographic O2microelectrode. Multicomponent analysis allows the determination of fractions of oxyhemoglobin, deoxyhemoglobin, and high-spin and low-spin methemoglobins in each spectrum collected as the reaction proceeds. Fractional saturation as a function of oxygen partial pressure is calculated as the ratio of oxyhemoglobin to oxy- plus deoxyhemoglobin. Several advantages are offered by this method: (i) Hemoglobin–O2binding curves are obtained rapidly and reproducibly; (ii) the speed of the reaction limits methemoglobin formation by autooxidation; (iii) there is no gas–liquid interface, eliminating protein denaturation at the surface; and (iv) direct calculations of fractional saturation are made using spectral analysis, thus avoiding the assumption of a linear transition between deoxy- and oxyhemoglobin.

Effect of an allosteric modifier of hemoglobin, RSR-4, on oxygen affinity and oxygen saturation of hemoglobin in rabbits.

Theoretically, if the arterial partial oxygen pressure (PaO2) does not change, a right shift in the oxygen equilibrium curve (OEC) of hemoglobin should reduce arterial oxygen saturation. In this study we investigate whether a right shift in the OEC of hemoglobin decreases transcutaneous oxygen saturation (Tc-SO2) following the administration of an allosteric effector, 2-[4-(((3, 5-dichloroanilino)-carbonyl) methyl) phenoxy]-2-methylpropionic acid (RSR-4). The effect of RSR-4 on hemoglobin oxygen affinity was studied in four New Zealand white male rabbits. Following intraperitoneal administration of RSR-4, Tc-SO2 decreased in a dose-dependent manner. P50 (partial oxygen pressure at 50% hemoglobin oxygen saturation) in whole blood increased as the concentration of RSR-4 increased. Tc-SO2 decreased as whole-blood affinity (1/P50) decreased. There was no positive correlation between Tc-SO2 and PaO2. We concluded that a decrease in hemoglobin oxygen affinity following RSR-4 administration reduced arterial oxygen saturation. This decrease in the presence of an allosteric effector such as RSR-4 in vivo can be detected and monitored as a reduction in Tc-SO2.

An improved biotonometric method for determination of haemoglobin oxygen equilibrium curves

A new biotonometric method for the determination of haemoglobin oxygen equilibrium curves is described. The procedure is based on the mixing of an oxygen-consuming organism, the yeast cell ( Saccharomyces cerevisiae), with an oxidized blood/plasma mixture. The yeast cell consumes oxygen at a uniform rate, thus reducing the partial pressure of oxygen in the mixture. This in turn induces the dissociation of oxygen in a characteristic manner. The study of the whole blood samples from 26 healthy volunteer subjects gave the following results: p50=3.63 kPa±0.23 kPa (mean±1 S.D.); Hill slope n=2.44±0.16; and CO 2 Bohr factor=−0.47±0.11. For the within-run imprecision the coefficients of variation for the different parameters were: p50 C.V.=4.4%; Hill slope n C.V.=4.7%; and CO 2 Bohr factor C.V.=19%. The determination can be carried out with simple equipment: a blood gas analyzer with a coupled recorder.

Characterization of the embryonic globin chains of the marsupial Tammar wallaby, Macropus eugenii.

The embryonic hemoglobins of the marsupial Tammar wallaby (Macropus eugenii) are known to aggregate, which was shown by the finding that the Hill coefficient, h, was greater than 4.0 in the upper part of the oxygen equilibrium curve. Here, we have undertaken a detailed primary structure analysis of the Tammar wallaby pouch young hemoglobin complement, which we hoped might provide clues into the residues that cause aggregation and a high embryonic h. The Tammar wallaby embryonic hemoglobin complement is principally four major hemoglobins each with a different isoelectric point. Two early expressed hemoglobins contain the same embryonic beta-like chain, epsilon (epsilon), but two separate alpha-like chains, termed zeta and zeta prime (zeta and zeta') both of which are N-terminally blocked. The later two expressed hemoglobins contain the same adult alpha-chain, but different beta-like chains. The latest expressed hemoglobin contains the same beta-like chain, epsilon, as the two early expressed forms, but the third expressed hemoglobin contains a unique beta-like chain which we have termed omega (omega). A protein database similarity search using the first 54 N-terminal amino acids of the omega-chain showed a range of sequence identities of 57-72% to all known mammalian beta-like chains, including the other marsupial epsilon-chains. The closest identity, reflected by both the highest percentage identity and Smith-Waterman score, was with the embryonic beta-chains of the aves. While the primary structures of the hemoglobins reported here do not explain the low hemoglobin-oxygen affinity in embryonic marsupial blood, the finding of the similarity with the bird globin-like sequence with one of the marsupial chains has implications on mammalian globin evolution. How many other marsupials and placental mammals are harboring a bird-like globin in their embryos?

Oxygen Binding and Aggregation of Hemoglobin from the Common European Frog, Rana temporaria

The hemoglobin from the European frog, Rana temporaria, consists of one major and three minor components. The tetramers aggregate upon deoxygenation notably at pH 7.3. Aggregation due to formation of disulphide bridges, as occurs in related species, was observed only in polyacrylamide gels. The hemolysate showed a pronounced Bohr effect. Oxygen affinity decreased with increasing hemoglobin concentration, indicating that aggregation affects the functional properties of the hemolysate. Oxygen binding equilibria of unfractionated hemolysate are insensitive to chloride and show low sensitivity to ATP. Analysis of oxygen equilibrium curves in terms of the two-state allosteric model (MWC) showed that pH change exerted a greater effect on the association constant of the oxygenated state (KR) than that of the deoxy state (KT). The number of interacting binding sites (q) increased with hemoglobin concentration. Cooperativity of oxygen binding, evaluated as Hill coefficient n, never exceeded the value of 3.0. Earlier studies on hemoglobin and blood from this and related species, report significantly higher n values at high O2 saturation. Molecular adaptive aspects are discussed.

The anodic hemoglobin of Anguilla anguilla. Molecular basis for allosteric effects in a root-effect hemoglobin.

The functional and structural basis for the Root effect has been investigated in the anodic hemoglobin of the European eel, Anguilla anguilla. This hemoglobin exhibits a large Bohr effect, which is accounted for by oxygen-linked binding of seven to eight protons in the presence of GTP at pH 7.5. Oxygen equilibrium curves show nonlinear lower asymptote of Hill plots, indicating the occurrence of heme-heme interactions within the T state. Analysis of the curves according to the co-operon model (Brunori, M., Coletta, M., and Di Cera, E. (1986) Biophys. Chem. 23, 215-222) reveals that T state cooperativity is positive at high pH and in the stripped hemoglobin (where the T --> R allosteric transition is operative) and negative at low pH and in the presence of organic phosphate (where the molecule is locked in the low affinity structure), indicating site heterogeneity. The complete amino acid sequence of eel anodic hemoglobin has been established and compared with that of other fish hemoglobins. The presence of the Root effect correlates with a specific configuration of the alpha1beta2 switch interface, which at low pH would stabilize subunit ligation in the T state without changing the quaternary structure. We propose that the major groups involved in the binding of oxygen-linked protons in eel anodic hemoglobin are located on the beta chain and comprise His-HC3 at the C terminus, His-FG4 at the switch interface, and Lys-EF6 and the N terminus at the phosphate-binding site.

Influence of age and breed on the binding of oxygen to red blood cells of bovine calves.

The influence of somatic growth and genetic selection on the whole blood oxygen equilibrium curve (OEC) was measured under standard conditions in double-muscled and dairy calves during their first 3 mo of life. Crossbreed animals were also investigated. Hemoglobin, 2,3-diphosphoglycerate (DPG), Cl, and Pi concentrations were also measured. The percentage of fetal hemoglobin (HbF) was determined. The influence of exogenous Cl, Pi, and pH on the OEC was also assessed. The PO2 at 50% hemoglobin saturation (P50) increased during somatic growth, probably because of the increase in DPG recorded in double-muscled neonates and to the progressive disappearance of HbF in both breeds. The oxygen exchange fraction (OEF%) was used to assess the combined influence of the OEC shift and OEC shape changes on blood oxygen desaturation under standard conditions, when the PO2 decreases within a physiological range. The OEF% showed an increase during the first month, then a stabilization. The effects of Cl, Pi, and pH in Friesian calves were similar as in adult cattle. Double-muscled neonates had a lower P50, OEF% values, and DPG concentrations and higher hemoglobin and Cl concentrations than Friesian neonates. The Pi concentration and the percentage of HbF were similar in both breeds. The pH and the Cl concentration had significantly less effect on the OEC in double-muscled than in Friesian calves. Crossbreed animals exhibited intermediate parameter values, between those recorded for double-muscled and Friesian calves. All differences between breeds progressively disappeared during the first month. These data show that blood function changes markedly in calves during the first month of life and that genetic selection can alter blood function.

The Optimal Oxygen Equilibrium Curve: A Comparison Between Environmental Hypoxia and Anemia

SYNOPSIS. Internal hypoxia in vertebrates occurs during anemia, when blood oxygen (02) carrying capacity is reduced, or during exposure to environmental hypoxia. In non-altitude adapted vertebrates, exposure to environmental hypoxia results in a change in blood O2 affinity which, in some cases is beneficial to tissue O2 delivery. In contrast, the elevation in blood O2 carrying capacity observed in almost all vertebrates is always beneficial to tissue O2 delivery (assuming no large changes in blood viscosity) and may be more important than changes in blood O2 affinity in maintaining tissue O2 delivery. Experimental anemia in vertebrates results in a decrease in blood O2 affinity which is always beneficial to tissue O2 delivery. The reduction in affinity is brought about by an increase in the organic phosphate to hemoglobin ratio (NTP:Hb) within the red cell. In fish NTP:Hb decreases during environmental hypoxia but increases during anemia indicating that NTP regulation is quite different between these treatments despite the similarity of these treatments at the tissue level.

Tissue Oxygenation in Patients with Hemoglobinopathy H

To evaluate, the degree of tissue hypoxia in patients with hemoglobinopathy H disease, whole blood oxygen affinity was estimated and analyzed in 33 patients. Twenty patients with iron deficiency anemia, matched for degree of anemia, served as controls. The results were as follows: Whole blood oxygen equilibrium curves of patients with HbH disease are biphasic because of a combination of the rectangular hyperbolic curve of HbH and the normal sigmoid curve of HbA and are shifted toward the left (P50 3.66 ± 0.33 kPa). Patients with iron deficiency anemia have right-shifted oxygen equilibrium curves (P50 4.02 ± 0.13 kPa) compared with normal. Oxygen release to the tissues in HbH disease is decreased (1.4 ± 0.3 mmol/L) as compared with iron-deficient patients (1.6 ± 0.2 mmol/L) with a similar degree of anemia. Red cell indices vary between the two groups. In patients with HbH disease the mean corpuscular hemoglobin concentration was 268 ± 17 g/L as compared with 294 ± 18 g/L in iron deficiency anemia. These findings indicate that whole blood oxygen affinity is a reliable index of tissue oxygenation in patients with hemoglobinopathy H.

The decrease of maximal oxygen consumption during hypoxia in man: a mirror image of the oxygen equilibrium curve.

1. Endurance athletes (E) undergo a marked reduction of arterial O2 saturation (Sa,O2) at maximal exercise in normoxia, which disappears when they breathe hyperoxic mixtures. In addition, at a given level of hypoxia, the drop in maximal O2 consumption (VO2,max) is positively related to the individual normoxic VO2,max. 2. These data suggest that the curve relating VO2,max to PI,O2 may be steeper and perhaps less curved in E than in sedentary subjects (S) with low VO2,max values because of the greater hypoxaemia in the latter, whence the hypotheses that (i) the relationship between VO2,max and PI,O2 may be set by the shape of the oxygen equilibrium curve; and (ii) the differences between E and S may be due to the different position on the oxygen equilibrium curve on which these subjects operate. These hypotheses have been tested by performing a systematic comparison of the VO2,max or Sa,O2 vs. PI,O2 relationships in E and S. 3. On ten subjects (five S and five E), VO2,max was measured by standard procedure during cycloergometric exercise. Sa,O2 was measured by finger-tip infrared oximetry. Arterialized blood PO2 (Pa,O2) and PCO2 (Pa,CO2) were determined in 80 microliters blood samples from an ear lobe. The subjects breathed ambient air or a N2-O2 mixture with an inspired O2 fraction (FI,O2) of 0.30, 0.18, 0.16, 0.13 and 0.11, respectively, VO2,max was normalized with respect to that obtained at the highest FI,O2. 4. The relationships between Sa,O2 or normalized VO2,max and FI,O2 (or PI,O2) had similar shapes, the data for E being systematically below and significantly different from those for S. Linear relationships between Sa,O2 and normalized VO2,max, statistically equal between E and S, were found. 5. We conclude that the relationships between either VO2,max or Sa,O2 and FI,O2 (or Pa,O2) may indeed be the mirror images of one another, implying a strict link between the decrease of VO2,max in hypoxia and the shape of the oxygen equilibrium curve, as hypothesized.

Significance of Oxygen Affinity of Fetal and Adult Human Hemoglobins

Abstract The oxygen equilibrium curves of human fetal and adult hemoglobins were reconstructed from the published Adair constants. The curves were then analyzed theoretically with respect to the amount of transferred oxygen, which is directly related to the saturation difference (▵S) of hemoglobin with oxygen in the artery and vein. In fetal blood, the oxygen affinity is optimized so as to provide the maximal ▵ S value in the fetus oxygen environment. In adult blood, on the other hand, the ▵ S value is far smaller than the theoretically obtained maximum, but it is most sensitive to the P50 changes around its physiological value of 27 torr. The present results imply that adult blood reserves an oxygen transport capacity for increased oxygen demands under resting conditions, and that the oxygen affinity is optimized so as to make the Bohr effect most effective to gaseous exchange.

Expression Studies of δ-Globin Gene Alleles Associated with Reduced Hemoglobin A2 Levels in Greek Cypriots

We previously identified five delta-globin gene alleles associated with reduced hemoglobin (Hb) A2 (Trifillis, P., Ioannou, P., Schwartz, E., and Surrey, S. (1991) Blood 78, 3298-3305). We have now evaluated functional consequences of the changes after expression in COS-1 cells to monitor effects on RNA splicing. In addition, variant Hb A2 tetramers were expressed in yeast to assess effects of amino acid changes on oxygen binding and stability to heat and mechanical agitation. The G --> T change at codon 27 and the A --> G change in IVS-2 both affect RNA splicing, whereas the C --> T change at codon 97 and the AT deletion in IVS-2 have no effect. Oxygen equilibrium curves of the Hb A2 variants expressed in yeast were similar to that of wild type Hb A2. None of the three variant Hb A2 tetramers (Thr --> Ile at codon 4 (Hb deltaT4I), Ala --> Ser at codon 27 (Hb deltaA27S), and Arg --> Cys at codon 116 (Hb deltaR116C)) showed decreased heat stability compared with Hb A2, whereas the Hb deltaT4I variant showed highest instability to mechanical agitation. Co-expression in yeast of alpha-globin chain and the delta-chain variant containing a Leu --> Pro change at codon 141 yielded no identifiable tetramers, suggesting lack of assembly or severe tetramer instability. These studies show the probable cause for decreased Hb A2 for two alleles is due to defective splicing, whereas decreased protein stability, increased tetramer association with red cell membranes, increased interdisulfide bond formation of delta-chains, which inhibits assembly with alpha-chains, and/or reduced assembly is suggested for the other three alleles.

Hb Bruxelles, Deletion of Pheβ42, Shows a Low Oxygen Affinity and Low Cooperativity of Ligand Binding

Functional studies of partially purified hemoglobin (Hb) Bruxelles, Phebeta42 (CD1) --> 0 indicate a major shift in the allosteric equilibrium toward the deoxy (T state) conformation. While Hb A shows a roughly symmetrical oxygenation curve with maximum cooperativity near half-saturation, Hb Bruxelles shows mainly properties of the low affinity (T state) form. The oxygen equilibrium curves for purified (>80%) Hb Bruxelles show little cooperativity and a P50 (without 2,3-diphosphoglycerate) about twice that of Hb A. The low cooperativity for Hb Bruxelles is partially compensated by an increase in oxygen affinity of the deoxy conformation and a lower 2,3-diphosphoglycerate effect. The beta chains of normal Hb have consecutive phenylalanine residues at positions 41 and 42. DNA sequencing studies of Hb Bruxelles showed a deletion of the codon TTT, which corresponds to residue Phe42. The CO rebinding kinetics after flash photolysis show mainly the slow phase, characteristic of CO binding to the deoxy conformation. In phosphate buffer at pH 7, the slow phase dominates even at low photolysis levels, where the main reaction is ligand binding to the triply liganded form. This indicates a switchover point, from the deoxy to oxy conformation, occurring beyond three ligands for Hb Bruxelles. There are few natural mutants that show a change in the oxygen affinity and cooperativity as large as that observed for Hb Bruxelles.

Oxygen Equilibrium Properties of Chromium(III)-Iron(II) Hybrid Hemoglobins

Cr(III)-Fe(II) hybrid hemoglobins, alpha 2(Cr) beta 2(Fe) and alpha 2(Fe) beta 2(Cr), in which hemes in either the alpha- or beta-subunits were substituted with chromium(III) protoporphyrin IX (Cr(III)(PPIX), were prepared and characterized by oxygen equilibrium measurements. Because Cr(III)PPIX binds neither oxygen molecules nor carbon monoxide, the oxygen equilibrium properties of Fe(II) subunits within these hybrids can be analyzed by a two-step oxygen equilibrium scheme. The oxygen equilibrium constants for both hybrids at the second oxygenation step agree with those for human adult hemoglobin at the last oxygenation step (at pH 6.5-8.4 with an without inositol hexaphosphate at 25 degrees C). The similarity between the effects of the Cr(III)PPIX and each subunits' oxygeme on the oxygen equilibrium properties of the counterpart Fe(II) subunits within hemoglobin indicate the utility of Cr(III)PPIX as a model for a permanently oxygenated heme within the hemoglobin molecule. We found that Cr(III)-Fe(II) hybrid hemoglobins have several advantages over cyanomet valency hybrid hemoglobins, which have been frequently used as a model system for partially oxygenated hemoglobins. In contrast to cyanomet heme, Cr(III)PPIX within hemoglobin is not subject to reduction with dithionite or enzymatic reduction systems. Therefore, we could obtain more accurate and reasonable oxygen equilibrium curves of Cr(III)-Fe(II) hybrids in the presence of an enzymatic reduction system, and we could obtain single crystals of deoxy-alpha 2(Cr) beta 2(Fe) when grown in low salt solution in the presence of polyethylene glycol 1000 and 50 mM dithionite.

Oxygen binding properties of Eudistylia vancouverii chlorocruorin and its dodecamer subunit

The oxygen equilibrium curves of the extracellular chlorocruorin of the polychaete Eudistylia vancouverii and its dodecamer subunit were determined over the pH range from 7.1 to 8.1 and in the presence and absence of 100 mM Mg 2+. Although the chlorocruorin has a very low oxygen affinity, high cooperativity and a moderate alkaline Bohr effect ( P 50 = 145 mmHg, n max = 6.9, φ = -0.44 at pH 7.1 and 25° C), the dodecamer subunit has higher affinity and lower cooperativity and Bohr coefficient ( P 50 = 58 mmHg, n max = 1.7, φ = -0.22). The presence of 100 mM Mg 2+ increased the oxygen affinity and cooperativity of the chlorocruorin but had no significant effect on the dodecamer subunit. The oxygen binding properties of the chlorocruorin reassociated subsequent to complete dissociation in 4 M urea at neutral pH were similar to the properties of the dodecamer and not to those of the native chlorocruorin. Fitting to the Monod-Wyman-Changeux allosteric model gave K T of 0.0013 mmHg −1, K R of 0.22 mmHg −1 and L o of 2.5 x 10 13 together with a size of the allosteric unit, N = 9.