Interactions of nicotinamide adenine dinucleotides with varied states and forms of hemoglobin.

Spectrofluorometric techniques were used to quantify NADPH-hemoglobin interactions based on the quenching of NADPH fluorescence upon binding to hemoglobin. Fluorometric titrations were carried out with hemoglobin in varied states and with hemoglobins in which the beta-chain anion site is altered. At pH 6.5 in 0.05 M 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffer, NADPH binds with high affinity, Kd = 1.03 microM, to deoxy human hemoglobin tetramers. Lower affinity binding of NADPH occurs as the beta-chain anion-binding site is discharged by increasing the pH. Moreover, the cofactor binds in a 1:1 ratio to deoxy tetramers, inositol hexaphosphate binds competitively, and binding is decreased in hemoglobins whose structural alterations result in decreased effects of 2,3-diphosphoglycerate. The cofactor binds to oxidized (met) hemoglobin with an estimated Kd of 33.3 microM but has little or no affinity for the oxy form. These results indicate that NADPH binds at the beta-chain anion-binding site and can be considered as a fluorescent analog of 2,3-diphosphoglycerate. Fluorescence measurements gave no indication of NADPH binding to deoxygenated ferrous or ferric myoglobin. Reductive processes within the erythrocyte, such as reduction of met hemoglobin and hemoglobin-catalyzed enzymatic reactions, may be affected by the significant binding of the reduced cofactor to both deoxygenated and oxidized hemoglobin. Cofactor-hemoglobin interactions predict a shift in redox potential as red cells become oxygenated, which may account for unexplained oxygen-linked shifts in red cell metabolism.

Redox properties of components I and IV of trout hemoglobins: kinetic and potentiometric studies.

Redox properties of component I and IV from trout hemoglobin (Salmo irideus) have been studied kinetically and at equilibrium. In the case of component I of trout hemoglobin, the mid-point potential (Eh) is pH independent below the acid-alkaline transition (pKa approximately equal to 8.6) and decreases at higher pH, following the deprotonation of the water molecule. Similarly to human hemoglobin, the mid-point potential of component IV of trout hemoglobin is pH-dependent, but the redox Bohr effect is extended to more acid pH. Moreover, the cooperativity of the redox equilibrium process is higher than in human hemoglobin. These features parallel the oxygen-binding properties of the same hemoglobin components from trout hemolysate. Differently from human hemoglobin, the oxidation kinetics of the two hemoglobins from trout by potassium ferricyanide show markedly biphasic progress curves with pH-independent second-order rate constants. This behavior suggests a different energy barrier for the interaction with ferricyanide in the two types of subunit of both Hb components from trout.

Dimer-tetramer transition in hemoglobins from Liophis miliaris--I. Effect of organic polyphosphates.

Hemoglobin from the water-snake Liophis miliaris in the stripped form presents high oxygen affinity of about P50 = 1 mmHg and Hill coefficient of about 1.0 at pH from 6.8 to 8.5. In the presence of ATP such values become P50 = 20 mmHg and nH about 2.0, respectively, at low pH from 6.5 to 7.5. When the pH increases an abrupt decrease of both P50 and nH values occurs falling close to those found for the stripped hemoglobin. Gel-filtration in Sephadex G-100 equilibrated with 0.05 M Tris-HCl buffer containing 1 mM EDTA of the stripped hemoglobin show the presence of only one component of mol. wt of about 32,500 dt similar to the dimer of human hemoglobin A. The deoxy form of the dimer previously treated with ATP and placed on Sephadex column in the same condition but containing 1 mM IHP emerges as tetramer with mol. wt similar to that found for human hemoglobin, i.e. of about 65,000 dt. Results of the multiplicity of the snake hemoglobin, as well as the large alkaline Bohr effect in the presence of ATP previously reported, seems to be inconsistent due to the dimer-tetramer transition that occurs when ATP is bound to the stripped hemoglobin. A molecular mechanism involving the dimer-tetramer transition is proposed to described the oxygen transport in these animals.

The nicotinamide adenine dinucleotides as allosteric effectors of human hemoglobin.

The oxygen binding properties of human hemoglobin are appreciably altered by the nicotinamide dinucleotides NADH, NADP+, and NADPH. These cofactors are important in the control of many metabolic pathways and in providing reductive potential for a number of enzymatic reactions, including in vivo reduction of methemoglobin. Specific binding of these cofactors to hemoglobin and their potential for acting as allosteric modifiers of hemoglobin function have not been previously recognized. Detailed oxygen binding studies utilizing a thin-layer method suggest that the nicotinamide dinucleotides bind with high affinity to the deoxyhemoglobin tetramer at the beta chain anion-binding site and stabilize the low affinity "T-state" conformation. Stripped Hb A in 0.05 M N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES) buffer, pH 6.5, at 20 degrees C is half-saturated at a pO2 of 1.6 mm Hg. In the presence of 0.5 mM NADH, NADP+, or NADPH, the P50 is raised to 3.8, 7.1, and 12.5 mm Hg, respectively. The Bohr factor for stripped Hb A in 0.05 M HEPES buffer is sensitive to these effectors and is raised from 0.25 to about 0.65 by the addition of NADPH. The data suggest that routine use of these effectors in studies of human hemoglobin variants or the allosteric mechanism of Hb A be considered carefully. The relatively low intraerythrocytic levels of the nicotinamide dinucleotides in relation to hemoglobin dictate that these cofactors cannot significantly affect in vivo oxygen delivery. However, the converse is theoretically possible. The binding of the cofactors to hemoglobin and the preferential binding of their reduced forms may affect cofactor-dependent metabolic processes in red blood cells.

Haemoglobin Bohr effect and lactic acid content of the blood of 2 water-snakes with different degrees of aquatic adaptation.

H. modestus, a water-snake with morphological respiratory adaptation to its habitat, presents haemoglobins with a lower Bohr effect than those of L. miliaris, an aquatic snake without such respiratory adaptations. The difference in blood lactic acid content of the 2 snakes submitted to mechanical stimuli appears to be compatible with the properties of their haemoglobins.

The role of the glucose-6-phosphate in the phosphorylase b kinase activation found in perfused rat hearts treated by dinitrophenol.

In order to explain the phosphorylase b kinase activation found in perfused rat hearts treated by dinitrophenol, the glucose-6-phosphate levels and the enzyme activity were determined. Experiments were also done to determine the phosphorylase b kinase inhibition by the ester. The low glucose-6-phosphate levels and the enzyme inhibition found, suggested that the phosphorylase b kinase is activated by a mechanism that involves phosphofructokinase.

Kinetics of binding of carbon monoxide to lumbricus erythrocruorin: a possible model.

This paper represents a kinetic study of the binding of carbon monoxide by Lumbricus erythrocruorin. Observations on the quantum and the relaxation of the system both to equilibrium and to the steady state realized in the presence of constant illumination under various conditions are reported. The results, besides indicating the existence of at least two types of binding sites, give indications as to the behavior of a complex polyfunctional molecule, such as an enzyme, working under steady-state conditions.

On the mechanism of the glycogenolytic effect of dinitrophenol. Activity of phosphofructokinase in perfused hearts.

To explain the mechanism of DNP action the contents of ATP, ADP, AMP and G-6-P were determined in perfused rat hearts in a period of time in which the rate of the glycogenolysis was increased. The levels of these metabolytes in the extract were consistent with an increase of the phosphofructokinase activity. On the other hand, the finding of higher activity of phosphyrylase beta kinase in DNP-poisoned animals could be explained as due to the low content of G-6-P in the perfused hearts subjected to the action of the drug.