Functional studies on the separated hemoglobin components of an air-breathing catfish,Hoplosternum littorale (Hancock)

• 1. The two hemoglobins, Hb I and II, of the obligate air-breathing catfish,Hoplosternum littorale have been isolated.
• 2. The unfractionated stripped hemoglobin has a high oxygen affinity, a normal alkaline Bohr effect, and a Root effect.
• 3. Both the Bohr and Root effects are enhanced by 1 mM ATP.
• 4. Stripped Hb I has a relatively high oxygen affinity, a reversed Bohr effect between pH 6.0 and 8.0 (Δlog P₅₀2DpH> 0), but no Root effect. Addition of 1 mM ATP to Hb I causes a marked reduction in the oxygen affinity, a change to a normal alkaline Bohr effect (Δlog P₅₀ΔpH< 0), but no Root effect.
• 5. Stripped Hb II has a lower oxygen affinity at low pH and a higher oxygen affinity at high pH than does Hb I. Hb II shows a large alkaline Bohr effect which is only slightly increased by 1 mM ATP and a Root effect at low pH which is enhanced by 1 mM ATP.
• 6. The observed rates of O₂ dissociation and of CO combination with Hbs I and II show differences which parallel those observed in the oxygen equilibrium measurements.

     

The isolation and characterization of the hemoglobin ofBrachyplatystoma sp.: A tropical catfish

• 1. The single hemoglobin component ofBrachyplatystoma sp. has been isolated. The CO-hemoglobin has an apparent molecular weight of 69,000 as determined by gel filtration.
• 2. The hemoglobin displays both acid and alkaline Bohr effects, as organic phosphate effect and no Root effect. The whole bloodp_1/2 for oxygen shifts from 10.7 mm Hg in air equilibrated solutions to 25.1 mm Hg after the addition of 5.6% CO₂ to the equilibration gas. Thep_1/2 of purified hemoglobin varies from 0.3 mm Hg at pH 8.4 to 4.5 mm Hg at pH 5.9. The Bohr effect measured for stripped hemoglobin between pH 8.0 and 7.0 isΔlog p_1/2/ΔpH= −0.23. Additions of 1 mM ATP induce a shift in the Bohr effect toΔlog p_1/2/ΔpH= −0.58 over the same pH range.
• 3. Then value of stripped hemoglobin solutions varies from 1 at pH 5.9 to 1.7 at pH 7.0. Additions of 1 mM ATP shift the variation inn to higher pH values, and cause an increase in then value (n = 2 at pH 7.4).
• 4. The kinetics of carbon monoxide binding and oxygen dissociation are pH dependent. The CO_on rate becomes autocatalytic as the pH is lowered, indicating positive subunit interactions. The O_2off rate was homogeneous at all pH values.
• 5. The Bohr effects ofBrachyplatystoma hemoglobin and other pimelodid hemoglobins are greater than those determined for the unfractionated hemoglobins of more sedentary species from other catfish families such as the Loricariidae and Callichthyidae.

     

Functional studies on the single component hemoglobin from an Amazon knife fish,Sternopygus macrurus

• 1. The whole blood of the non-air-breathing gymnotid teleost,Sternopygus macrurus, is half-saturated with oxygen at 5.2 mm Hg (apparent value) at 30°C in the absence of CO₂. Addition of 5.6% CO₂ causes the apparentP₅₀ value to increase over 3-fold.
• 2. The oxygen affinity of the stripped single-component hemoglobin at 20°C increases about 20-fold between pH 5.8 and 8.6 in the absence of ATP. This difference increases to 100-fold in the presence of 1 mM ATP.
• 3. A substantial Root effect is present: the stripped hemoglobin is only 70% saturated with O₂ at pH less than 6 when equilibrated with air.
• 4. The value of the Hill coefficient,n, is maximal near pH 7.0–7.5, and approaches 1.0 at high pH. The value is about 1.5 at low pH in the absence of ATP and 1.0 in the presence of 1 mM ATP.
• 5. The O₂ dissociation kinetics are heterogeneous at all pH values but most heterogeneous at low pH. The rate increases substantially as the pH decreases.
• 6. The CO combination kinetics as measured by the stopped flow technique are largely homogeneous except at high pH, but the CO combination kinetics after flash photolysis are markedly heterogeneous.

     

A fetal-maternal shift in the oxygen equilibrium of hemoglobin from the viviparous caecilian,Typhlonectes compressicauda

• 1. The equilibria and kinetics of oxygen binding by blood and hemoglobin from adult and fetal caecilians,Typhlonectes compressicauda, have been measured.
• 2. The oxygen affinity of fetal blood is higher than that of adult blood.
• 3. Electrophoresis of adult and fetal hemoglobins suggests that they may be identical: a major and minor component occurs in each.
• 4. Adult and fetal hemoglobins have identical oxygen equilibria. Stripped hemoglobins have a high oxygen affinity and no Bohr effect between pH 6.5 and 10.0. An “acid”, reversed Bohr effect is present below pH 6.5. The addition of 1 mM ATP reduces the oxygen affinity markedly and produces a moderate, normal Bohr effect.
• 5. The major nucleoside triphosphate in fetal and adult erythrocytes is adenosine triphosphate: about 10% of the nucleoside triphosphates is guanosine triphosphate. Adult erythrocytes contain 3 times as much ATP as do the fetal erythrocytes.
• 6. The fetal to maternal shift in the oxygen equilibrium is mediated entirely by the difference in ATP content of the maternal and fetal red blood cells.

     

The hemoglobin ofpseudodoras,a South American catfish: Isolation,characterization and ligand binding studies

• 1. The hemoglobin of the Amazonian catfishPseudodoras sp. was isolated and characterized; it comprises a single component.
• 2. The hemoglobin's subunit composition is similar to that of other teleost hemoglobins. The apparent native molecular weight as determined by gel filtration is 66,000. The apparent subunit molecular weight is 14,300 by sodium dodecyl sulfate electrophoresis. The hemoglobin does not polymerize after oxidation by potassium ferricyanide.
• 3. The hemoglobin lacks a Root effect. A small Bohr effect is evident in the phosphate-free hemoglobin:Δlog p_1/2/ΔpH is no more than about −0.1 to −0.2 and increases toΔlog p_1/2/ΔpH = −0.4 in the presence of 1 mM ATP. The cooperativity, as determined byn of the Hill equation, is low, varying from 0.8 to 1.7 between pH 6.1 and 8.6.
• 4. Thep_1/2 values of stripped hemoglobin solutions are extremely low, less than 0.5 mm Hg at all pH values examined between pH 6.1 and 9.0. The high oxygen affinity is reflected primarily in the CO combination rate which resembles that found in myoglobins and isolated subunits of human hemoglobin.
• 5. Both the CO combination rate and the O₂ dissociation rate determined by stopped-flow spectrophotometry are pH and phosphate sensitive. Between pH 6.2 and 8.1 the CO_on rate increases about 5-fold in the phosphate-free hemoglobin. Addition of 1 mM ATP causes a depression in the rate at all pH values examined. The O_2off rate decreases 7-fold going from pH 6.0 to 8.2 in stripped hemoglobin solutions. Addition of 1 mM ATP induces a 10-fold decrease over the same range. At pH values below 6.0 a depression in the O_2off rate occurs in the stripped hemoglobin, indicative of an acid Bohr effect.

     

A comparative study of the oxygen equilibria of blood from 40 genera of Amazonian fishes

• 1. We have examined the oxygen-affinity of the fresh, whole blood from representatives of 40 genera of Amazonian fishes.
• 2. When all the air-breathing fishes and all the water-breathing fishes were considered, no differentiation in oxygen affinity could be distinguished, although in two cases of closely related species, i.e.Osteoglossum, a water breather, vsArapaima, an air breather, andHoplias, a water breather, vsHoplerythrinus, an air breather; the air breathers have bloods with lower oxygen affinity than do the water breathers.
• 3. Significant differences in the oxygen affinity were found when fishes were considered by habitat: the oxygen affinities were in general correlated with available environmental oxygen and relative oxygen demand of the fishes.

     

Oxygen binding of intact coelomic cells and extracted hemoglobin of the echiuran Urechis caupo

• 1.1. The oxygen affinity of Urechis caupo coelomic cells is the same in normoxic and in hypoxic animals. There is no Bohr effect between pH 6.8 and 8.0.
• 2.2. The oxygen affinity of intact coelomic cells is the same as that of extracted, stripped hemoglobin. The oxygen binding properties of stripped hemoglobin are not affected by 1 mM ATP, IMP, or hydrogen ions between pH 6.8 and 8.0, nor do they clearly show cooperativity. The heat of oxygenation. ΔH, = −13.1 kcal/mol between 10 and 25 C.
• 3.3. Although U. caupo coelomic cell hemoglobin is tetrameric and intracellular, it apparently exhibits neither heterotropic nor homotropic interactions.

     

Kinetics of oxygen and carbon monoxide binding to the hemoglobins of the water snakes Liophis miliaris and Helicops modestus

• 1.1. Liophis miliaris and Helicops modestus are water snakes having different respiratory adaptiations to their specific habitats. L. miliaris is more active and spends more time on land than H. modestus. Knowledge of the equilibrium and kinetics of ligand binding to their hemoglobins leads to better understanding of molecular aspects of this adaptation.
• 2.2. Both snakes contain several hemoglobin types in their blood. Studies on the kinetics of oxygen dissociation and carbon monoxide combination with these hemoglobins were performed by stopped-flow and flash-photolysis experiments at various pH values, both in the presence and absence of adenosine triphosphate.
• 3.3. The oxygen dissociation kinetics of L. miliaris hemoglobins show a strong pH dependence and cooperative interactions between chains are indicated by autocatalytic time-courses at pH 7.0. In contrast, H. moledstus hemoglobins show nearly pH independent rate constants for oxygen dissociation and cooperative interactions between chains were not apparent. The hemoglobins of H. modestus show increased pH dependence in the presence of adenosine triphosphate.
• 4.4. The carbon monoxide combination kinetics differ for the hemoglobins of L. miliaris and H. modestus in general agreement with the differences found in the kinetics and equilibria of oxygen binding. Both the kinetic and steady-state difference between these hemoglobins may be advantageous in light of the behavioral differences of these two water snakes.

     

Effect of pH on the kinetics of oxygen and carbon monoxide reactions with hemoglobin from the air-breathing fish,Loricariichthys

• 1.Loricariichthys sp., an air-breathing fish from the Amazon River has one major hemoglobin component.
• 2. Quantitative studies on the kinetics of O₂ dissociation and CO combination to the protein were performed by stopped-flow experiments at different pH values and a constant ATP concentration of 1.25 mM.
• 3. The oxygen dissociation shows a simple first order behavior and a strong pH dependence.
• 4. The CO combination kinetics, on the other hand, were homogeneous and fast at higher pH values and slow and clearly autocatalytic at pH values below 7.0.

     

Oxygenation characteristics of the polymorphic hemoglobins of coho salmon (Oncorhynchus kisutch) at different developmental stages

• 1.1. The oxygen equilibria of the multiple hemoglobin of the fry and adult life stages of coho salmon (Oncorhynchus kisutch) were investigated. Components A 6–8 comprise 50–55% and >95% of the total hemoglobins of coho adults and fry respectively.
• 2.2. Fry hemoglobins exhibited a high oxygen affinity (P₅₀ = 3.9 mm Hg at 9.8°C, pH 8.5), a very large Bohr shift (ø = Δlog ₅₀/ΔpH = −1.729 at pH 7.1–7.5) which was non-linear in the pH range 6.8–8.5 and a large heat of oxygenation (ΔH = −20.8 kcal/mol).
• 3.3. Adult hemoglobins, however, exhibited a moderate oxygen affinity (P₅₀ = 14.0 mm Hg at 9.8°C, pH 8.2), a very small linear Bohr shift (ø = −0.172 at pH 7.0 −8.2) and a low heat of oxygenation (ΔH = −5.6- −7.5kcal/mol). Adenosine triphosphate had only minor influence on the oxygenation characteristics of adult heolyzates.
• 4.4. The results are discussed in terms of functional adaptation to environmental stresses and metabolic requirements.

     

Functional properties of the two major hemoglobin components from Leporinus friderici (Pisces)

• 1.1. The hemoglobins of Leporinus friderici were separated by liquid chromatography on DEAE-Sepharose in order to isolate the two major electrophoretic components.
• 2.2. The chromatographic fraction I (electrophoretically slow anodic) showed no Bohr effect and no nucleoside triphosphate modulation.
• 3.3. The chromatographic fraction III (electrophoretically fast anodic) showed a normal Bohr effect and addition of nucleoside triphosphate decreased oxygen affinity but did not alter the Bohr effect.
• 4.4. The whole hemolysate showed a normal Bohr effect and phosphate modulation altered both Bohr effect and oxygen affinity.
• 5.5. No or little difference between the effect of adenosine or guanosine triphosphates on hemoglobin function was observed.

     

Separation and characterization of the hemoglobin components ofPterygoplichthys pardalis,the acaribodo

• 1. The four main hemoglobin components of the hemolysate ofPterygoplichthys pardalis have been isolated and characterized.
• 2. The functional properties investigated for the isolated components comprise the effect of pH and ATP on (i) the O₂ equilibrium, (ii) the O₂ dissociation kinetics, (iii) the CO combination kinetics.
• 3. Component I, corresponding to approx 50% of the total hemoglobin, is characterized by functional properties which are distinctly different from those of Components II, III and IV, which are alike
• 4. Thus it is shown, once more, that multiple components in an hemolysate fall into categories of hemoglobins characterized by distinct and complementary functional properties

     

The effect of temperature on the oxygen equilibria of fish hemoglobins in relation to environmental thermal variability

• 1. We have measured the temperature dependence of the oxygen equilibria of blood and hemoglobin solutions from four neotropical and three temperate zone fishes.
• 2. Significant differences exist in the heats of oxygenation of the bloods but not the hemoglobin solutions from different species.
• 3. The differences in thermal sensitivity of the oxygenation of the bloods appear to depend on differences in intracellular pH, organic phosphates and other ligand-linked variables and not the intrinsic enthalpies of the oxygenation of the hemoglobins themselves.

     

Patterns of hemoglobin production in the adult newt (Triturus cristatus) erythron following induction of anemia

• 1.1. Changes in the hemoglobins present in many vertebrates have been observed during development and during anemic episodes.
• 2.2. A change in the number of hemoglobins present and their relative amounts was observed when adult Triturus cristalus newts were made anemic by injection of acetylphenylhydrazine.
• 3.3. Hemoglobin IV, which is a minor hemoglobin in healthy adults, was found to be a major component during the subsequent erythropoietic response to hemolytic anemia.
• 4.4. No new hemoglobin not already present in the non-anemic state was detected during the response to induced anemia.

     

Effects of erythrocytic nucleoside triphosphates on oxygen equilibria of composite and fractionated hemoglobins from the facultative air-breathing amazonian catfish,Hypostomus andPterygoplichthys

• 1. Oxygen equilibria ofHypostomus andPterygoplichthys hemoglobins and their sensitivities to the erythrocytic nucleotide triphosphates (NTP), ATP and guanosine triphosphate (GTP) are studied to investigate the mechanisms by which blood adapts to air- and water-breathing (cf. Weberet al., 1979).
• 2. Hemoglobins of both species are heterogeneous. All hemoglobin fractions isolated by iso-electric focusing reveal a high sensitivity to NTP, but GTP depresses O₂ affinity about twice as effectively as ATP. A cathodal hemoglobin component with a reversed Bohr effect was found inPterygoplichthys but not inHypostomus.
• 3. The data are discussed in relation to thein vivo cofactor modulation of blood O₂ affinity and the adaptive significance of functional heterogeneity of fish hemoglobins.

     

Respiration in the eastern water dragon,Physignathus lesueurii (agamidae)

• 1.1. Some aspects of the gas exchange system of a diving lizard, Physignathus lesuewii were studied.
• 2.2. Breathing patterns were analysed.
• 3.3. Breathing rate increases logarithmically with temperature and Q₁₀ = 1.8. LogBR = −0.237 + 0.0256 T.
• 4.4. Gas tensions in lung air and arterial and venous blood were measured. Arterial pH declines with increasing temperature.
• 5.5. Temperature has a marked effect on oxygen affinity of the blood (ΔH = −10.1 kcal mol⁻). A Bohr effect was also noted.
• 6.6. CO₂ equilibrium curves were drawn.
• 7.7. The results are considered with a view to anticipating the efficiency of the gas exchange system of this species under conditions of variable temperature and during diving.

     

Characterization of hemoglobin from Phoronis architecta (phoronida)

• 1.1. Phoronis architecta hemoglobin is composed of four distinct hemoglobin subunits with minimum MW's of 16–17,000 or 17–19,000 daltons. All four hemoglobins are monomeric when oxygenated. Two of the monomers combine to form dimers when bound with carbon monoxide.
• 2.2. In cellulo, Phoronis architecta hemoglobin has a half-saturation (P₅₀) value of 1.3 ± 0.1 mm Hg, shows cooperative oxygen binding (Hill coefficient = 2.7 ± 0.3), and no Bohr effect from pH 6.6 to 7.9. In vitro, the hemoglobin has a P₅₀ of 0.76 ± 0.21 mm Hg but shows no cooperativity (0.90 ± 0.15 (SD)).
• 3.3. The oxygen dissociation constant (K_off) from hemoglobin is 2.7 ± 0.2 sec⁻¹, and the computed oxygen association constant (K_on) is 2.5 × 10⁶ M⁻¹ · sec⁻¹ (1.9–3.6 × 10⁶ M⁻¹ · sec⁻¹).

     

Respiratory properties of blood and hemoglobin solutions from the piranha

• 1. Respiratory properties of piranha blood are distinguished from those of other fish primarily by the high CO₂ buffering capacity (ΔHCO₃/⁻ΔpH= 19.6mmol/l for oxygenated blood and 39.1 mmol/l for deoxygenated blood).
• 2. The concentration of nucleoside triphosphates (NTP) and the half-saturation tension (P₅₀) of whole blood were found to be inversely related to body size.
• 3. The higherP₅₀ in smaller fish, analogous to values obtained in previous studies involving interspecies comparisons, could be adaptive to a higher weight-specific metabolic rate.
• 4. Both ATP and guanosine triphosphate (GTP) lowered the oxygen affinity of purified hemoglobin solutions, accounting for the size-dependent correlation ofP₅₀ and NTP concentration in whole blood.
• 5. While similar in concentration in red cells, GTP is more potent than ATP as an allosteric modifier of hemoglobin function.

     

The subunit structure of Daphnia pulex hemoglobin

• 1.1. The extracellular hemoglobin of Daphnia pulex has an apparent molecular weight of 430,000–470,000 by gel chromatography and an S_20,w = 16.9 at pH 7.0.
• 2.2. Purified hemoglobin contains one heme per 18,000–20,000 g protein. The polypeptide chains are heterogeneous with mol. wts between 31,000–37,000. Some high mol. wt (M_r = 53,000–86,000) material is also present.
• 3.3. The hemoglobin dissociates at pH 10.5 in EDTA into 3S material which can be digested with subtilisin into 16,000 mol wt heme-containing polypeptide chains.
• 4.4. The amino acid composition of the intact hemoglobin is identical to that of the heme-containing fragments generated by proteolytic digestion of the 3S material.
• 5.5. These results are consistent with the hypothesis that D. pulex hemoglobin is composed of subunits containig two heme groups per 35,000 mol. wt polypeptide chain.

     

Aerobic and anaerobic respiration of adult Artemia salina L., acclimated to different oxygen concentrations

• 1.1. Adult male Atremia salina L. were acclimated to five different oxygen concentrations and their respiration in response to environmental oxygen concentrations was determined.
• 2.2. Anemia is a respiratory regulator over a wide range of partial O₂ pressures. A critical oxygen tension exists and decreases with acclimation to lower pO₂.
• 3.3. Hypoxic conditions induce the production of hemoglobin III.
• 4.4. Lactic acid is produced during anaerobiosis.
• 5.5. Production of Hb III and lactic acid, being inversely proportional to the acclimation level, has to be considered as a long term or short term adaptation to hypoxic conditions.