Intraerythrocytic organic phosphates of fetal and adult seaperch (Embiotoca lateralis): Their role in maternal-fetal oxygen transport

Summary The viviparous seaperch,Embiotoca lateralis, has unique fetal and adult hemoglobins. Stripped fetal hemoglobin has a higher oxygen affinity than stripped adult hemoglobin at pH 6.5–7.1. The oxygen affinities of both adult and fetal hemoglobins are lowered allosterically by ATP at pH 7.1. Both fetal and adult seaperch erythrocytes include approximately 82% ATP and 18% GTP of the total nucleotide triphosphates (NTP) with a trace of AMP. No 2,3-diphosphoglycerate or inositol polyphosphate was detected. Mid- and late-gestation erythrocytes contain less NTP/mole hemoglobin tetramer than do adult cells. The effective NTP concentration in adult cells is higher than that of the fetal erythrocytes even when the intracellular concentration of Mg²⁺, which complexes with NTP, is accounted for. The difference in adult and fetal intraerythrocytic NTP concentration should enhance transfer of oxygen from maternal to fetal blood. Thus, the teleostEmbiotoca lateralis may employ a dual mechanism in maternal-fetal oxygen transfer. A difference in fetal and maternal hemoglobin structure and oxygen affinities is enhanced by a difference in their respective intraerythrocytic organic phosphate concentrations.     

Presence and possible function of root effect hemoglobins in fishes lacking functional swim bladders

The adult hemoglobins of 15 species of teleost and the midgestation fetal hemoglobin of the seaperch Embiotoca lateralis show a pronounced decrease in oxygen-carrying capacity at low pH, a Root effect. All of these fishes lack a functional swim bladder, which is generally thought to be the likely site of Root effect hemoglobin function. All of the teleosts examined, including the fetal sea perch, however, have a choroid rete, a structure that is proposed to be involved in oxygen secretion to the eye. The data are inconsistent with the generalization that only fishes with swim bladders possess Root effect hemoglobins, and that the only function of Root effect hemoglobins is in the secretion of oxygen to a swim bladder. The data for the fishes examined in this study suggests that a better correlation may exist between Root effect hemoglobins and the presence of a choroid rete. This is consistent with the hypothesis that Root effect hemoglobins may be involved in the physiology of the eye in many fishes.     

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     

Oxygen equilibria and structural characteristics of the tetrameric and polymeric intracellular hemoglobins from the bivalve molluscBarbatia reeveana

Summary The arcid bivalveBarbatia reeveana contains within its erythrocytes two hemoglobins with remarkably different structures and oxygen equilibrium properties. A tetrameric hemoglobin (M _r about 60,000) with non-identical subunits (₂₂) constitutes about 60% of the erythrocytic heme protein. This hemoglobin has a relatively low oxygen affinity (P ₅₀=19 Torr at 20°C, pH 7.2), shows cooperativityn _H=2.2, shows no Bohr effect between pH 6.8 and 7.6 and a heat of oxygenation (H) of –5.4 kcal/mole between 15 and 35°C. Its oxygen affinity appears to be insensitive to ATP.B. reeveana erythrocytes also contain another hemoglobin withM _r=430,000, the largest intracellular hemoglobin known in any organism. The subunit of this hemoglobin is unusual, having aM _r of 32–34,000 and two heme oxygen binding sites per polypeptide chain. The large hemoglobin has a very low oxygen affinity (P ₅₀=33 Torr at 20°C, pH 7.2), shows slight cooperativity,n _H=1.8, and no Bohr effect (Grinich and Terwilliger 1980). The H at pH 7.2 equals –2.9 kcal/mole, a low value for most hemoglobins, and its O₂ affinity appears to be insensitive to ATP. The two hemoglobins ofB. reeveana, so different in their structure, are also different in their functional properties.     

Adult and fetal hemoglobins in the oviparous swell shark,Cephaloscyllium ventriosum

Cephaloscyllium ventriosum is an oviparous, bottom-dwelling shark inhabiting shallow waters from central California to Chile. Hemoglobin oxygen affinities for adult, juvenile (5 and 8 months old), and pre- and posthatch (fetal up to 10 days posthatching) individuals were determined using thin-layer spectrophotometry of hemoglobin solutions stripped of organic phosphates. Adult hemogiobin had a P₅₀ of 4.72± 0.30 mm Hg (N = 4, mean ± SE), juvenìle hemoglobin had a P₅₀ of 3.77 ± 0.65 mmHg (N = 3), and pre- and posthatch hemoglobin had a P₅₀ of 2.51 ± 0.19 mmHg (N = 6)—significantly (P < 0.05) higher than adult hemoglobin oxygen affinity. Adult blood was slightly alkaline (7.60–8.04; N = 4), had low venous P_O2 values (0.5–14.5 mmHg; N = 4), and hematocrit and hemoglobin concentration increased with age. SDS-polyacrylamide gel electrophoresis revealed slight structural differences between the hemoglobin of adult and prehatch individuals. A hemoglobin with a higher intrinsic oxygen affinity may enable fetuses of C. ventriosum to more efficiently extract oxygen from the relatively stagnant environment within the egg case.     

Direct measurement of equilibrium constants for high-affinity hemoglobins

The biological functions of heme proteins are linked to their rate and affinity constants for ligand binding. Kinetic experiments are commonly used to measure equilibrium constants for traditional hemoglobins comprised of pentacoordinate ligand binding sites and simple bimolecular reaction schemes. However, kinetic methods do not always yield reliable equilibrium constants with more complex hemoglobins for which reaction mechanisms are not clearly understood. Furthermore, even where reaction mechanisms are clearly understood, it is very difficult to directly measure equilibrium constants for oxygen and carbon monoxide binding to high-affinity (K(D) < 1 micro M) hemoglobins. This work presents a method for direct measurement of equilibrium constants for high-affinity hemoglobins that utilizes a competition for ligands between the "target" protein and an array of "scavenger" hemoglobins with known affinities. This method is described for oxygen and carbon monoxide binding to two hexacoordinate hemoglobins: rice nonsymbiotic hemoglobin and Synechocystis hemoglobin. Our results demonstrate that although these proteins have different mechanisms for ligand binding, their affinities for oxygen and carbon monoxide are similar. Their large affinity constants for oxygen, 285 and approximately 100 micro M(-1) respectively, indicate that they are not capable of facilitating oxygen transport.     

Hemoglobins, XXVIII. Phosphate-protein-interaction, gene expression and function: the genetic and allosteric control of the oxygen affinity of the fetal blood (author's transl)

This work describes possible molecular mechanisms concerning the control of oxygen affinity in fetal blood of mammalia. There is a genetic control of oxygen affinity through a fetal gene: at constant phosphate concentration (Hb less than P2-glycerate) in humans there is a hemoglobin with only five binding sites to 2,3-bisphosphoglycerate, resulting in an increased oxygen affinity. In several species (sheep, cattle, goat) with Met-Leu as the N-terminal group of the beta-chains, the 2,3-bisphosphoglycerate binding sites are deleted in positions beta 1 and beta 2, so that the regulation is phosphate-independent and thus providing a fetal hemoglobin with an increased oxygen affinity. The allosteric control is observed in pigs. In the postembryonal development "adult" hemoglobin with seven contacts (beta-chains) is demonstrated. The increased oxygen affinity is achieved here by a reduced biosynthesis of 2,3-bisphosphoglycerate (Hb greater than P2-glycerate) (Rapoport-Luebering-cycle). The functional control is discussed with respect to the ontogeny of the hemoglobins.     

The enhancement of the alkaline Bohr effect of some fish hemoglobins with adenosine triphosphate.

The oxygen equilibria of the hemoglobins of one holostean fish, the spotted gar (Lepisosteus osculatus), and of four teleost fish, the carpsucker (Carpiodes carpio), the small mouth buffalo fish (Ictiobus bubalus), the Rio Grande cichlid (Cichlasoma cyanoguttatum), and the redear sunfish (Lepomis microlophus), have been measured as a function of pH in the presence and absence of ATP. The oxygen equilibria of the teleost hemoglobins in the presence of 200 μm ATP can be superimposed within experimental error upon the data obtained in the absence of ATP by a simple downward shift of the pH scale by 0.5 unit. Thus the effects of proton and ATP binding appear equivalent: Both can be interpreted in terms of a two-state allosteric model in which binding occurs preferentially to the low-affinity T-state. The oxygen affinities of each of the teleost hemoglobins approach asymptotically a maximal value at high pH. Although these high affinities are associated with decreased cooperativity of oxygen binding, as reflected by the Hill coefficient n, the asymptotic value of n never appears lower than 1.2 to 1.4. This indicates that the data cannot be completely described in terms of a single high-affinity R-state in alkaline solution: At least two different conformations are required. The oxygen affinity of the spotted gar hemoglobin, like that of each of the teleost hemoglobins, reaches a maximal value (minimal value of log PO₂ for half-saturation) above pH 8, but unlike teleost hemoglobins, the Hill coefficient reaches maximal values of 2.6 to 2.7 at high pH. The data in the absence of ATP are superimposable on the data in its presence by a downward shift of the pH scale by 0.25 unit. The measurement of the Bohr effect ($\text{Δlog}\text{P}{}_{30}\text{ΔpH}$) in the presence and absence of ATP shows that the Bohr effect in each of the hemoglobins is substantially enhanced by organic phosphates, as it is in mammalian hemoglobins. The extent of the enhancement of the Bohr effect by 200 μm ATP for each of the hemoglobins is approximately the same in the range pH 6.7 to 7.3 (increase in $\text{Δlog}\text{P}{}_{50}\text{ΔpH}\text{~ 0.3}$). This is a direct consequence of the equivalence of the linked-function relationship to the effects of ATP and proton binding on oxygenation.     

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.     

Discrimination between adaptive and neutral amino acid substitutions in vertebrate hemoglobins

Summary A discriminant analysis on the basis of the physicochemical properties of amino acid residues is developed to investigate the accumulation pattern of amino acid substitutions in a family of proteins. The application of this analysis to vertebrate hemoglobins reveals the following new results. (1) The major components of teleost fish and amphibian hemoglobins showing the Root effect are sharply discriminated from mammalian hemoglobins in several regions of the and chains, whereas shark, minor components of teleost fish and amphibian, reptile, and bird hemoglobins showing no Root effect exhibit a gradual change to mammalian hemoglobin in a straightforward way. This result suggests at least two lines of molecular evolution in vertebrate hemoglobins. (2) The nonadult hemoglobin chains are allocated to the latter line, i.e., tadpole, , and chains are similar to shark and trout I chains, and and chains are similar to some of the reptile chains. (3) In any case, most of the amino acid residues causing the discrimination are located near the sites that carry the amino acid residues conserved well throughout all classes of vertebrates, suggesting that modifications adapting to the respective living conditions or respiratory organs have taken place effectively near the amino acid residues essential for the manifestation of cooperative oxygen binding. (4) The amino acid residues at other sites are changed from one to another species even within the same class, showing a constant substitution rate as a whole. These amino acid substitutions may be nearly neutral, being under a weak functional constraint. The number of sites allowing such neutral substitutions is rather small, less than one-half of all the sites in the adult hemoglobins of bird and mammal, whereas it amounts to two-thirds in teleost fish hemoglobins.     

Effect of nitric oxide on the transport and release of oxygen in fetal blood

It is well known that nitric oxide (NO), the most important vasodilator agent, plays an important role in lowering vascular resistance in the human umbilical-placental circulation and that its deficiency is related to the pathogenesis of pre-eclamptic disorder. Besides it has recently been demonstrated that human hemoglobin (HbA) is able to transport nitric oxide, as S-nitrosohemoglobin (SNO-Hb), from the arterial to the venous blood. In the present study we examine the functional properties of the adult and fetal nitrosated hemoglobins to see if the double transport of oxygen and NO may influence the fetal oxygenation and the relation between maternal and fetal blood. Our results show that S-nitrosation significantly increases the oxygen affinity of the adult Hb (HbA) with respect to native protein (no-nitrosated) while the functional properties of HbF are less influenced. The oxygen affinity modification, found for SNO-HbA, was ascribed to the nitrosation of cysteine beta 93: really, the same residue is also present in the gamma chains of fetal hemoglobin, while the increase of affinity is less evidenced; hence, it is probable that the 39 aminoacidic substitutions between beta and gamma chains allay the effects of S-nitrosation. As regards the physiological modulators (protons, chloride ions, 2,3-diphosphoglyceric acid, and temperature), they influence the oxygen affinity of the two hemoglobins S-nitrosated, in equal mode with respect to the native forms determining the same variation on the oxygen affinity. Hence, our results evidence the fact that the NO release by SNO-HbA "in vivo" would be limited to regions of extremely low oxygen tension (such as hypoxic regions), while in fetus, SNO-HbF would unload nitric oxide and oxygen at pressure values close to normal.     

The effect of organic cosolvents on the oxygen affinity of fetal hemoglobin. Relevance of protein-solvent interactions to the functional properties.

We have studied the effects of organic cosolvents (monohydric alcohols and formamide) on the oxygen affinity of human fetal hemoglobin stripped of phosphates and have compared them with the effects of the same cosolvents on the oxygen affinity of human adult hemoglobin under the same experimental conditions. Our results confirm that, in fetal hemoglobin, the T in equilibrium R conformational equilibrium is more displaced toward the T conformation than in the adult form and indicate that increased electrostatic and hydrophobic protein-solvent interactions contribute to this effect. The data reported are discussed in terms of the known amino acid substitutions between the beta- and gamma-chains and an attempt is made to rationalize the results with a molecular mechanism based on the crystallographic structure of fetal deoxyhemoglobin.     

Mouse hemoglobin during gestation. Absence of fetal hemoglobin

A "fetal hemoglobin' has been reported to exist during mouse gestation, Investigations using CMC chromatography, starch gel electrophoresis or isoelectric focusing have shown a hemoglobin band from fetal tissues, and blood was obtained which was different from the adult hemoglobin and designated a "fetal hemoglobin'. In the current study isoelectric focusing was used to study the hemoglobins existing in the tissues and blood during fetal and neonatal development and the results suggest there is no "fetal hemoglobin' present during gestation. It appears that the hemoglobin designated as "fetal' in our laboratory was a methemoglobin formed by an incomplete reaction of KCN with the hemoglobin. The additional hemoglobin bands which were obtained from fetal liver or neonatal spleen tissues appeared to be a modified adult hemoglobin.     

Characterization by polyacrylamide gel electrophoresis of hemoglobins in rabbit embryo, fetus, and adult

The hemoglobin species of rabbit embryo, fetus, and adult were characterized by quantitative polyacrylamide gel electrophoresis (PAGE). Special statistical methods, including joint confidence envelopes for the slope (K_R) and intercept (Y₀) of the Ferguson plot and analysis of covariance were utilized to identify the hemoglobin species. Five embryonic rabbit hemoglobins could be distinguished. Their relative proportions varied with developmental stage. No specific fetal hemoglobin was detected. The two previously known adult hemoglobins were characterized, prepared by isoclectric focusing on polyacrylamide gel (IFPA) and shown to differ by two amino acid substitutions in the β-chain.A general strategy for testing molecular identity by PAGE is outlined.     

The functional, oxygen-linked chloride binding sites of hemoglobin are contiguous within a channel in the central cavity

Chloride ion is a major allosteric regulator for many hemoglobins and particularly for bovine hemoglobin. A site-directed reagent for amino groups, methyl acetyl phosphate, when used forglobal rather thanselective modification of R (oxy) and T (deoxy) state bovine hemoglobin, can acetylate those functional amino groups involved in binding of chloride; the extensively acetylated hemoglobin tetramer retains nearly full cooperativity. The chloride-induced decrease in the oxygen affinity parallels the acetylation of bovine hemoglobin (i.e., their effects are mutually exclusive), suggesting that methyl acetyl phosphate is a good probe for the functional chloride binding sites in hemoglobins. Studies on theoverall alkaline Bohr effect indicates that the part of the contribution dependent on chloride and reduced by 60% after acetylation is due to amino groups, Val-1() and Lys-81(); the remaining 40% is contributed by the imidazole side chain of His-146(), which is not acetylated by methyl acetyl phosphate, and is not dependent on chloride. The five amino groups—Val-1(), Lys-99(), Met-1(), Lys-81(), and Lys-103()—of bovine hemoglobin that are acetylated in an oxygen-linked fashion are consideredfunctional chloride binding sites. Molecular modeling indicates that these functional chloride binding sites are contiguous from one end of the central cavity of hemoglobin to the other; some of them are aligned within a chloride channel connecting each end of the dyad axis. A generalization that can be made about hemoglobin function from these studies is that the blocking of positive charges within this channel either by binding of chloride or other anions, by covalent chemical modification such as acetylation, or by site-specific mutagenesis to create additional chloride binding sites each accomplish the same function of lowering the oxygen affinity of hemoglobin.     

Interaction of allosteric effectors (ATP,CO2, H+) modulating oxygen affinity of the hemoglobin in the carp,Cyprinus carpio,in vitro

Summary The interaction of allosteric effectors (CO₂, ATP, H⁺) with respect to the oxygen affinity of carp hemoglobin was analyzed by determining oxygen binding curves spectrophotometrically in dilute solutions of stripped hemoglobin at 20°C. The pH range studied was 6.8–8.2.P _CO2 was 0, 10 and 70 mmHg (0, 1.33 and 9.3 kPa). ATP/Hb₄ was 0, 8 and 24. In the presence of either CO₂ or ATP, the effects of the cofactors onP ₅₀ were as expected over the whole pH range. In contrast to other published data, each cofactor also had a significant effect onP ₅₀ in the presence of the other cofactor. Evidence was obtained that oxylabile carbamate is formed by carp hemoglobin and that the formation of carbamate persists at a lower level in the presence of ATP. The results support the view that the binding of ATP to carp hemoglobin requires only one terminal amino group, leaving the other N-terminal of the -chain free to react with CO₂.     

Hemoglobin function in the developing goat and sheep

Comparative studies of the blood of newly born goats and sheep have indicated a number of mechanisms which are responsible for a decreasing affinity for molecular oxygen in these developing animals during the first 40 to 60 days after birth.
The concentration of 2,3-DPG in the red cells of young goats increases four to sixfold during the first 3 to 4 days of life, and this increase is associated with a marked decrease in the cellular pH; 2,3-DPG does not bind to hemoglobins of goats and the decreased affinity for oxygen of goat blood at this period is apparently due to the lowered pH produced by the large increase of intracellular anions. Similar changes occur in young lambs.
After 15 to 20 days the changes of the dissociation curve are related more to structural differences between adult and fetal hemoglobins; cellular pH moves closer to the values of adult red cells. In goats of this age the predominate hemoglobins are those with β chains and these have dissociation curves shifted further to the right than other adult hemoglobins.
In young lambs Hb-C is found only in association with Hb-A but the amount present seldom exceeds 5 to 10%. The oxygen affinities of sheep Hb-A and Hb-C are identical but higher than that of sheep Hb-B.     

Anpassungen der H?moglobine von Streifengans (Anser indicus), Andengans (Chloephaga melanoptera) und Sperbergeier (Gyps rueppellii) an hypoxische Bedingungen

Zusammenfassung Das Phänomen ungewöhnlicher Hypoxietoleranz bei Vögeln wird auf der Basis von Struktur-Funktionsbeziehungen der Hämoglobine dargestellt. Die Hämoglobine der Streifengans (Anser indicus), der Andengans (Chloephaga melanoptera) und des Sperbergeiers (Gyps rueppellii) wurden untersucht. Dabei zeigt sich, daß die Hypoxietoleranz auf jeweils eine definierte Aminosäuresubstitution zurückzuführen ist, welche die Wechselwirkung zwischen den Untereinheiten des Hämoglobins schwächt. Dadurch ergeben sich für die einzelnen Hämoglobine unterschiedliche Affinitäten zum Sauerstoff. Für die Streifengans (Austausch 119 Pro Ala) und den Sperbergeier (Austausch 34 Thr/Ile; multiple Hämoglobine) entsteht eine zweibzw. dreifache Kaskade von Hämoglobinen unterschiedlicher Sauerstoffaffinität, für die Andengans (Austausch 55 Leu Ser) eine erhöhte intrinsische Affinität des Gesamtblutes. Diese beiden molekularen Muster entsprechen der Unterscheidung zwischen transitorischer und permanenter Hypoxietoleranz. Auffällig ist, daß die Sauerstoffaffinität der Hämoglobine der Andengans und der Streifengans über die gleiche Wechselwirkung zwischen den Untereinheiten reguliert werden; die Mutationen liegen jedoch auf verschiedenen Globinketten.

---

Adaptation of the hemoglobins of Barheaded Goose (Anser indicus), Andean Goose (Chloephaga melanoptera) and Rüppell's Griffon (Gyps rueppellii) to life under hypoxic conditions

Summary The phenomenon of unusual hypoxic tolerance of birds is elucidated on the basis of structural and functional relationships of hemoglobins. Hemoglobins of Barheaded Goose (Anser indicus) flying over the Himalayan mountains at 8848 m, of Andean Goose (Chloephaga melanoptera) living at 6000 m in the Andes and of Rüppell's Griffon (Gyps rueppellii) reaching altitudes of 11 300 m were investigated. Hypoxic tolerance turned out to be the result of clearcut amino-acid substitutions weakening the interaction of the subunits of the hemoglobin. This entails different affinities of the single hemoglobins. For the Barheaded Goose (mutation 119 Pro Ala) and the Rüppell's Griffon (mutation 34 Thr/Ile; multiple hemoglobins) there is a two-stage resp. a three-stage cascade of hemoglobins of graded oxygen affinities, for Andean Goose (mutation 55 Leu Ser) the affinity of whole blood is raised. These two molecular patterns correspond to the distinction between transitory and permanent hypoxic stress. It is worth mentioning that the oxygen affinities of the hemoglobins of Barheaded Goose and Andean Goose are regulated via the same interface of the molecule; the substitutions, however, are found on different globin chains.

     

Hemoglobin of the lung fish Clarias lazera: isolation and oxygen equilibrium studies

The hemoglobin of the lung fish Clarias lazera has a single component on starch gel electrophoresis. The hemoglobin has a molar mass of c. 68,000 similar to HbA on column chromatography. Clarias hemoglobin has a high oxygen affinity with a low Bohr effect. There is a haem-haem interaction, n, which is pH dependent. The R-state is more stable than the T-state, unlike in most fish hemoglobins.