Red cells of newborn rats have low bisphosphoglyceromutase and high pyruvate kinase activities in association with low 2,3-bisphosphoglycerate

2,3-Bisphosphoglycerate is a physiologically important regulator of red cell oxygen affinity during mammalian development. The rat has no fetal hemoglobin, but the newborn red cell has low 2,3-bisphosphoglycerate and high ATP concentrations, and high oxygen affinity. This report shows that red cell bisphosphoglyceromutase activity increases from near zero in the newborn rat to very high levels by four weeks of age. This increase roughly parallels the increase in red cell 2,3-bisphosphoglycerate concentration. Red cell pyruvate kinase activity declines ten-fold from birth to four weeks of age. This decrease is associated with a changeover in red cell populations from larger to smaller cells. The glycolytic rate is at least 50% higher in newborn than adult rat red cells. The data suggest that high pyruvate kinase activity and glycolytic rate contribute to the high ATP concentration in newborn rat red cells, but that their low 2,3-bisphosphoglycerate concentration is due primarily to low bisphosphoglyceromutase activity.     

Refinement and evaluation of a model of Mg2+ buffering in human red cells.

The total Mg2+ content of human red cells ([Mg]T,i) is partitioned between free and bound forms. The main cytoplasmic Mg2+ buffers are ATP and 2,3 bisphosphoglycerate. Haemoglobin binds free ATP and bisphosphoglycerate, preferentially in the deoxygenated state. Thus, the free ionized Mg2+ concentration ([Mg2+]i) oscillates with the oxy-deoxy condition of the cells. The binding reactions are also modulated by the pH changes that accompany the oxygenation-deoxygenation transitions. The complex interactions between Mg2+, its ligands and Hb can be encoded in a set of equilibrium equations representing all the known binding reactions of the system. To develop a comprehensive understanding of the Mg2+ homeostasis of intact red cells it is necessary to correct and refine the equations and parameters of the model by systematic comparisons between model predictions and measured cytoplasmic Mg2+ buffering curves under a variety of experimental conditions. Earlier models largely underestimated total Mg2+ binding in intact cells. We carried out experiments in which [Mg]T,i and [Mg2+]i were controlled over a wide range ([Mg]T,i between 0.1 and 23 mM) by the use of the ionophore A23187, under diverse metabolic conditions, and the results were used to interpret the adjustments required for good model fits. By the inclusion of low-affinity Mg2+ binding to ATP and bisphosphoglycerate, and also binding of Mg2+ to haemoglobin (four ions per tetramer) with an apparent dissociation constant of 45 mM we were able to realistically model, for the first time, all the experimentally observed changes in [Mg2+]i in human red cells under diverse metabolic conditions.     

NTP pattern of avian embryonic red cells: role of RNA degradation and AMP deaminase/5'-nucleotidase activity

During terminal erythroid differentiation, degradation of RNA is a potential source for nucleotide triphosphates (NTPs) that act as allosteric effectors of hemoglobin. In this investigation, we assessed the developmental profile of RNA and purine/pyrimidine trinucleotides in circulating embryonic chick red blood cells (RBC). Extensive changes of the NTP pattern are observed which differ significantly from what is observed for adult RBC. The biochemical mechanisms have not been identified yet. Therefore, we studied the role of AMP deaminase and IMP/GMP 5'-nucleotidase, which are key enzymes for the regulation of the purine nucleotide pool. Finally, we tested the effect of major NTPs on the oxygen affinity of embryonic/adult hemoglobin. The results are as follows. 1) Together with ATP, UTP and CTP serve as allosteric effectors of hemoglobin. 2) Degradation of erythroid RNA is apparently a major source for NTPs. 3) Developmental changes of nucleotide content depend on the activities of key enzymes (AMP deaminase, IMP/GMP 5'-nucleotidase, and pyrimidine 5'-nucleotidase). 4) Oxygen-dependent hormonal regulation of AMP deaminase adjusts the red cell ATP concentration and therefore the hemoglobin oxygen affinity.     

Red blood cell function and haematology in two tropical freshwater fishes from Australia

Salmon catfish and tarpon occur in habitats that periodically become deficient in oxygen resulting in high mortalities of other fish species. The water-breathing catfish, Arius leptaspis, and the facultative air-breathing tarpon, Megalops cyprinoides, both have high haemoglobin and haematocrit, and the oxygen carrying capacity in the air-breather is exceptionally high (15.6+/-1.2 vol%). Iso-pH oxygen equilibria of the red blood cells at 25 degrees C revealed high affinity (P(50)=9 mmHg, pH 7.4) and co-operativity (n(50)>2.2, pH 7.4) in the catfish, and contrasted with low affinity (P(50)=32 mmHg, pH 7.4) and co-operativity (n(50) approximately 1) in the air-breathing tarpon. Oxygen binding was further distinguished by relative pH insensitivity (Bohr factor, ?=Deltalog P(50)/Deltalog pH=-0.22) in the catfish, compared with a significant Bohr effect in the tarpon (?=-0.96). The potential for modulation of haemoglobin-oxygen affinity was indicated by a high ratio of GTP to ATP in the erythrocytes of the catfish, whereas regulation in the tarpon appeared due to ATP alone. Differences in blood respiratory functions between the two species are likely to reflect reduced opportunity for activity under extreme hypoxia in the catfish.     

Fractionation in two-phase systems of red cells during rat development: Changes in pyruvate kinase and bisphosphoglycerate mutase activities in relation to red cell switching

Summary An inverse relationship between 2,3-bisphosphoglycerate levels and the ratio calculated from pyruvate kinase and bisphosphoglycerate mutase activities has been observed in red populations of rats during animal development. Counter-current distribution in aqueous two-phase systems of these cells populations shows a displacement of distribution profiles towards the high-numbered cavities of the rotor as animal ages. Heterogeneity of cells after distribution is only observed during the switching process from fetal to adult red cells taking place along the postnatal stage of development. Values for the pyruvate kinase/bisphosphoglycerate mutase ratio in these fractions suggest the separation of fetal (liver) from adult (bone marrow) red cells.     

Lactate interferes with ATP release from red blood cells

Upon exposure to low Po(2), the red blood cells of most species, including humans, release increased amounts of ATP that ultimately serves as a regulator of vascular tone matching oxygen supply with demand. In pathological conditions such as malaria and sepsis, a maldistribution of perfusion exists with its severity often correlated with the extent of elevation of serum lactate frequently in the absence of an alteration in pH. We hypothesized that the increased levels of lactate might impair the ability of red blood cells to appropriately respond to conditions of low Po(2), thus preventing its important blood flow regulatory role. Using an in vitro system and rabbit red blood cells, we evaluated the capacity of cells incubated with lactate to release increased amounts of ATP in response to acute exposure to low Po(2). We found that in the presence of lactate, the red blood cells did not release ATP. However, when sodium dichloroacetate, a drug used clinically to lower blood lactate levels, was added, ATP release was restored to levels that were not different from that of control cells (no lactate), even though intracellular levels of ATP were not. These results support the presence of a distinct flow regulatory pool of ATP within the red blood cell that can be independently regulated, and that lactate interferes with the ATP production within this pool, thereby diminishing the amount of ATP available for release on exposure to low Po(2). Therefore, if lactate levels can be reduced, the vascular regulatory capacity of the red blood cell should be restored, thus enabling the appropriate matching of oxygen supply with oxygen demand.     

The hemoglobin system of the brown moray Gymnothorax unicolor: structure/function relationships.

The Gymnothorax unicolor hemoglobin system is characterized by two components, called cathodic and anodic on the basis of their isoelectric point, which were separated by ion-exchange chromatography. The oxygen-binding properties of the purified components were studied in the absence and presence of chloride and/or GTP or ATP in the pH range 6.5-8.0. Stripped cathodic hemoglobin showed a small reverse Bohr effect, high oxygen affinity, and low co-operativity; the addition of chloride only caused a small decrease in oxygen affinity. In the presence of GTP or ATP, the oxygen affinity was dramatically reduced, the co-operativity increased, and the reverse Bohr effect abolished. Stripped anodic hemoglobin is characterized by both low oxygen affinity and co-operativity, and displayed a normal Bohr effect; the addition of chloride increased co-operativity, whereas ATP and GTP significantly modulated oxygen affinity at acidic pH values, enhancing the Bohr effect and giving rise to the Root effect. The complete amino-acid sequences of the alpha and beta chains of both hemoglobins were established; the molecular basis of the functional properties of the hemoglobins is discussed in the light of the primary structure and compared with those of other fish hemoglobins.     

The identification of glycolate-2-P as a constituent of normal red blood cells.

Glycolate-2-P has been isolated from two samples of normal human blood at levels of 2.56 and 5.16 μM. The compound appears to be confined to the red cells. These levels of glycolate-2-P can contribute significantly to the activation of red cell bisphosphoglycerate phosphatase.     

Allosteric modifiers of fish hemoglobins: in vitro and in vivo studies of the effect of ambient oxygen and pH on erythrocyte ATP concentrations.

Fundulus heteroclitus decreases erythrocyte adenosine triphosphate and increases blood hematocrit when acclimated to hypoxic conditions. A defined medium has been developed which allows isolated F. heteroclitus erythrocytes to be maintained for several hours without an appreciable loss of cellular ATP. The effect of oxygen tension, pH and metabolic inhibitors on the cellular concentration of ATP of fish red cells has been investigated as an in vitro model to explain in vivo responses to environmental changes. The isolated red cells significantly decrease their ATP/Hb molar ratio when exposed either to anaerobiosis or metabolic inhibitors. It is concluded that the in vivo response is mediated at the red cell level via decreased oxidative phosphorylation in the presence of low environmental oxygen. The length of time necessary to elicit the responce both in vivo and in vitro is also discussed.     

Cryopreservation of cyanate-treated sickle erythrocytes

Metabolic features and in vivo recovery of cryopreserved cyanate-treated erythrocytes from patients with sickle cell anemia were studied. Red cells were treated with the anti-sickling agent sodium cyanate, glycerolized, and frozen at ?80 °C. Cyanate increased post-thaw hemolysis of both normal and sickle erythrocytes. The thawed carbamylated sickle erythrocytes maintained high oxygen affinity but lost more than half of their ATP content. Addition of the metabolic nutrients adenine, pyruvate, and inosine (rejuvenation) during cyanate incubation prevented ATP loss. Rejuvenation also increased red cell 2,3-DPG and opposed the cyanate effect by lowering oxygen affinity. Yet cyanate improved by nearly 50% the intravascular recovery of thawed rejuvenated sickle erythrocytes in a rat transfusion model. Cryopreservation of autologous cyanate-treated erythrocytes could lead to their use as an extracorporeal treatment of sickle cell disease.     

Evidence that 1,3-bisphosphoglycerate dissociation from phosphoglycerate kinase is an intrinsically rapid reaction step

The steady-state kinetics of 1,3-bisphosphoglycerate formation through the action of phosphoglycerate kinase on 3-phosphoglycerate and ATP have been examined. The results show that initial velocities determined by the standard method of coupling bisphosphoglycerate production to NADH reduction in the presence of glyceraldehyde-3-phosphate dehydrogenase do not differ significantly from those determined in the absence of the latter enzyme. This observation invalidates the proposal that bisphosphoglycerate dissociation from phosphoglycerate kinase is much too slow to account for the high rates of phosphoglycerate turnover observed in the coupled two-enzyme system. The capacity for rapid bisphosphoglycerate production and release is an intrinsic catalytic property of phosphoglycerate kinase that does not require the presence of other enzymes or the involvement of a mechanism of channelized (non-diffusional) transfer of bisphosphoglycerate from the producing enzyme to the consuming one.     

Glycerated hemoglobin, alpha 2A beta 2(82) (EF6) N epsilon-glyceryllysine. A new post-translational modification occurring in erythrocyte bisphosphoglyceromutase deficiency

A new minor Hb fraction initially designated Hbx, has been found in the hemolysate of an erythremic patient that we have previously described with a complete erythrocyte bisphosphoglycerate mutase (EC 5.4.2.4) deficiency. Hbx (3.5% of the total) was detected by isoelectric focusing and exhibited electrophoretic and chromatographic properties similar to those of several variants of the Hb central cavity. By density fractionation of red cells, it was demonstrated that Hbx was an aging hemoglobin as in the case of glycated Hb A1c. Functional studies revealed a low oxygen affinity and almost complete inhibition of the allosteric effect of the organic phosphate effectors. Structural studies demonstrated an absence of tryptic cleavage between the peptides beta T9 and beta T10 suggesting the presence of an adduct on Lys beta 82 or on a neighboring residue. Fast atom bombardment mass spectrometry and a specific enzymatic assay with glyoxylate reductase demonstrated that the beta 82 adduct was a glycerate moiety. It was concluded that Hbx was a glycerylated Hb, alpha 2A beta 2(82) (EF6) N epsilon-glyceryllysine, to our knowledge the first example of glycerylated protein. The mechanism of formation of glyceryl Hb, which was found in the four studied subjects with a bisphosphoglyceromutase deficiency, remains to be determined.     

Effect of Cl- and H+ on the oxygen binding properties of glutaraldehyde-polymerized bovine hemoglobin-based blood substitutes

Bovine hemoglobin was cross-linked with glutaraldehyde, resulting in high oxygen affinity polymeric hemoglobin dispersions of varying molecular weight distributions. High oxygen affinity acellular oxygen carriers were designed in order to exhibit oxygen release profiles closer to that of human red blood cells (RBCs), without exhibiting the inherent increased vasoactivity that occurs with low oxygen affinity acellular oxygen carriers (1, 2). Oxygen dissociation curves were measured for polymerized hemoglobin dispersions at various pH values (7.0, 7.4, and 8.0) and chloride ion concentrations. Unmodified hemoglobin showed an increase in oxygen affinity with increased chloride ion concentration and a decrease in oxygen affinity with increased pH, as was previously demonstrated in the literature (3). For glutaraldehyde-polymerized hemoglobin dispersions, the ability of the oxygen affinity to respond to changes in Bohr H+ and Cl- concentration was weakened. However, at acidic physiological pH (pH = 7), the Bohr effect was still present at high Cl- concentrations. Thus, the Bohr effect maintained some dependency on the Cl- concentration.     

Temperature acclimation and oxygen-binding properties of blood and multiple haemoglobins of rainbow trout.

Acclimation of rainbow trout to 5, 15 and 22 degrees C for periods exceeding 4 months had no significant effect on the oxygen affinity of whole blood or on the concentration of ATP, which is the main organic phosphate in red cells. Slight differences were, however, found in the oxygenation properties of the haemolysates, which correlate with changes in the relative concentration of the multiple haemoglobins. The oxygen-binding properties of the main haemoglobin components account for the observed differences in the haemolysates. The possible thermoacclimatory significance of changes in haemoglobin multiplicity and co-factor concentrations is discussed.     

The ATP dependence of a ouabain-sensitive sodium efflux activated by external sodium, potassium and lithium in human red cells.

The stimulation of ouabain-sensitive Na+ efflux by external Na+, K+ and Li+ was studied in control and ATP-depleted human red cells. In the presence of 5 mM Na+, with control and depleted cells, Li+ stimulated with a lower apparent affinity than K+, and gave a smaller maximal activation than K+. The ability of Na+, K+ and Li+ to activate Na+ efflux was a function of the ATP content of the cells. Relative to K+ both Na+ and Li+ became more effective activators when the ATP was reduced to about one tenth of the control values. At this low ATP concentration Na+ was absolutely more effective than K+.     

Regulation of Hemoglobin Function in Mammals

This survey of hemoglobin function in mammals reveals a broadrange in oxygen affinity. The concentration of red cell 2,3-DPGvaries widely among groups of mammals. Those animals (feloidsand ruminants) that have very low levels of this intracellularmediator have hemoglobins of intrinsically low oxygen affinitywhich fail to respond to the addition of 2,3-DPG. Mammals whichhave adapted to various types of hypoxia tend to have increasedoxygen affinity, primarily mediated through reduced levels ofred cell 2,3 DPG. In contrast mammals who are experimentallysubjected to low oxygen tensions develop decreased oxygen affinityowing to increased red cell 2,3-DPG. Mammals employ one of threedifferent mechanisms for the maintenance of higher oxygen affinityof fetal red cells, compared to maternal red cells. Many of these phenomena can be satisfactorily explained at themolecular level but their adaptational significance is lessclear.     

Effects of free ATP, citrate, and bicarbonate on rat liver mitochondrial ATPase.

The effects of citrate, free ATP, and bicarbonate on the activity of isolated rat liver mitochondrial ATPase have been studied. Citrate behaved as a weak noncompetitive inhibitor; free ATP at low concentrations was found to be an activator, whereas at high concentrations behaved as an inhibitor. Citrate competed with free ATP. Neither citrate nor free ATP competed with bicarbonate. The results obtained suggest the existence of at least two catalytic sites with ATP hydrolyzing activity and at least three regulatory sites: one for bicarbonate, and two for free ATP, one with low and another with high affinity. Citrate would compete with free ATP for the same sites. The interaction of free ATP with the high affinity site activated the enzyme, whereas its interaction with the low affinity site would lead to an inhibition.     

Studies on avian erythrocyte metabolism. Effect of organic phosphates on oxygen affinity of embryonic and adult-type hemoglobins of the chick embryo.

The effects of 2,3 diphosphoglyceric acid (2,3-DPG), adenosine triphosphate (ATP), and inositol hexaphosphate (IHP) on the oxygen affinity of whole “stripped” hemoglobin (WSH), hemoglobin H (Hb-H), hemoglobin A (Hb-A) and hemoglobin D (Hb-D) isolated from 18-day chick embryo blood have been determined. The effect of the three organic phosphates upon the oxygen dissociation curves is similar and the following order of decreasing oxygen affinity of the organic phosphates was observed for each hemoglobin: 2,3-DPG < ATP < IHP. 2,3-DPG appears to have a slightly greater effect upon the P₅₀ of Hb-H than upon that of either of the two adult-type hemoglobins. However, this effect seems insufficient to suggest a preferential interaction of 2,3-DPG with Hb-H which would account for either the large amounts of 2,3-DPG in the erythrocytes of embryos or the higher oxygen affinity of the whole blood. The effects of the organic phosphates upon the Hill constant of the purified hemoglobins are variable. It is concluded that since the distribution of hemoglobins H, A, and D in the erythrocytes during the developmental period from 18-day embryos to 6-day chicks remains fairly constant, the previously described progressive decrease in oxygen affinity of the whole blood during this period results from changes in the total amount and distribution of the intraerythrocytic organic phosphates.²     

Hemoglobin-oxygen-affinity and acid-base properties of blood from the fossorial mole-rat, Cryptomys hottentotus pretoriae

Oxygen affinity and other hematological parameters in strictly subterranean mole-rats, Cryptomys hottentotus (subspecies pretoriae) were measured immediately upon capture and after 14-21 days in captivity. The pH, hematocrit, hemoglobin (Hb) concentration, blood oxygen content, 2,3 bisphosphoglycerate (2,3 BPG) concentration and oxygen dissociation curves (ODC), as well as tonometric measurements, were determined using whole blood. Additionally ODCs were also determined for stripped hemolysates of individual animals. Compared to other mammals, blood of freshly caught animals had low pH (7.32+/-0.22), elevated hematocrits (48.4+/-3.8 %) and significantly lower P50 values for whole blood (21.1+/-1.6 mm Hg at pH 7.4) than those reported for other similar-sized fossorial and terrestrial mammals. Blood carbon dioxide content (22.4+/-3.9 mMol L(-1)), hemoglobin concentration (1.9+/-0.15 mMol L(-1)), oxygen content (164.8+/-26 mL L(-1)), bicarbonate concentrations (22.5+/-3.5 mMol L(-1)) were within the range of values reported for similar-sized mammals. We conclude that high blood-oxygen affinity, low body temperature and possibly also high hematocrit enable C. h. pretoriae to maintain an adequate oxygen supply to the tissues in a potentially hypoxic burrow atmospheres, but that the blood of this species shows no exceptional CO2 sensitivity or buffering capacity.