Functional properties of the hemoglobin from the South American snake Mastigodryas bifossatus.

The hemolysate of Mastigodryas bifossatus shows two major hemoglobins with very close isoelectric points, and four different globin chains. The stripped hemolysate exhibits a low alkaline Bohr effect (delta log P50/delta pH = -0.30 between pH 7 and 8) and a decrease of the co-operativity from 2.3 to unity when the pH increases from 6.15 to 8.5. In the presence of ATP, large changes in the oxygen affinity and co-operativity are observed. The Bohr effect rises to -0.46 and the n50 values stay at around 3 in the pH range 6-9. An increase in temperature induces a large decrease in the oxygen affinity for the stripped hemolysate. In the pH range between 7.5 and 8.5, the values of delta H in kcal/M are around 10 fold larger for the stripped protein than for the protein in the presence of ATP. Measurements of rapid kinetics of oxygen dissociation and carbon monoxide binding reflect the ATP sensitivity observed in equilibrium experiments.

Polyphosphate binding sites in Liophis miliaris hemoglobin. Evidence with reduced nicotinamide adenine dinucleotide phosphate.

The water-snake Liophis miliaris presents hemoglobin which binds organic polyphosphate through a simple single-site per tetramer (Mol. Wt. 64500) as judged by titration curves of reduced nicotinamide adenine dinucleotide phosphate either in the presence or absence of inositol hexaphosphate. The site seems to have the same structural nature of that found on other hemoglobins and is able to strongly bind most of the known protein effectors such as inositol hexaphosphate, adenosine triphosphate or 2,3-diphosphoglicerate. The high association constant at pH 7 of reduced nicotinamide for the deoxy hemoglobin of about K(D) = 7 x 10(6) M-1 compared to human hemoglobin (K(D) = 7 x 10(5) M-1), and to that of adenosine triphosphate (its natural erythrocytic polyphosphate) still higher of about K(D) = 10(11) M-1, shows clearly the very high affinity of this snake hemoglobin for such allosteric effector. The results besides corroborating the dimer-tetramer transition mechanism proposed to describe the oxygen transport by the hemoglobin of Liophis miliaris--may explain the difficulties to obtain the oxy dimeric conformation of the protein by usual hemolysis and stripped off procedures.

Fluorescence studies on the binding of reduced nicotinamide adenine dinucleotide phosphate to human hemoglobin A and its variant hemoglobin Providence.

The affinity constants for the binding of NADPH to human hemoglobin A were directly determined by fluorescence analysis since nucleotide fluorescence is quenched on binding to the protein. The binding constants 6.1 x 10(5), 5.02 x 10(5) and 1.2 x 10(5) were found for deoxyhemoglobin at pH 6.5, 7.0 and 7.5, respectively. Oxyhemoglobin does not bind NADPH significantly. These results are consistent with those found in oxygen-hemoglobin equilibrium experiments. The human hemoglobin variant, Providence-Asp, which has a marked decrease in 2,3 DPG affinity was also investigated. NADPH does not bind to the variant suggesting that the Lys B 82 residue is of fundamental importance to nucleotide binding and showing that the binding site is the same as that of 2,3 DPG or other organic polyphosphate, allosteric modulators of hemoglobins. Experiments of inositol hexaphosphate (IHP)-NADPH site competition corroborate these results.

Further evidence of dimer-tetramer transition in hemoglobin from Liophis miliaris.

Liophis miliaris hemoglobins in the stripped form exhibit a high oxygen affinity, a small alkaline Bohr effect, a pronounced organic polyphosphate effect and a pH-dependent Hill coefficient, close to 2 below pH 7.5 and near 1 at higher pHs. Molecular weight determinations indicate 2 forms, a dimeric form of MW 32000 d. and a tetrameric form of about 64000 d. The deoxyhemoglobin is tetrameric. Ion-exchange chromatography shows two components which may bind to each other being eluted as a single component of MW 32000 d. The oxygen alkaline Bohr effect observed for the stripped hemoglobin may be explained by the transition from the tetramer to the dimer during oxygen addition experiments. The phenomenon appears to be unique among animals. beta-Chain sequencing determinations show that abnormal human hemoglobin with similar properties has a glutamic acid residue substituted at the alpha 1-beta 2 interface by valine in snake hemoglobin.

Fluorescence studies on the binding of reduced nicotinamide adenine dinucleotide phosphate to human hemoglobin A and its variant hemoglobin providence

The affinity constants for the binding of NADPH to human hemoglobin A were directly determined by fluorescence analyssis since nucleotide fluorescence is quenched on binding to the protein. The binding constants 6.1 x 10**5, 5.02 x 10**5 and 1.2 x 10**5 were found for deosyhemoglobin at pH 6.5, 7.0,respectively. Oxyhemoglobin does not bind NADPH significantly. These results are consistent with those found in oxygen-hemoglobin equilibrium experiments. The human hemoglobin variant, Providence-Asp, which has a marked decrease in 2,3 DPG affinity was also investigated. NADPH does not bind to the variant suggesting that the Lys B 82 residues is of fundamental importance to nucleotide binding and showing that the binding site is the same as that of 2,3 DPG or other organic polyphosphate, aloosteric modulators of hemoglobins. Experiments of inositol hexaphosphate (IHP)-NADPH site competition corroborate these results

Further evidence of dimer-tetramer transition in hemoglobin from Liophis miliaris

Liophis miliaris hemoglobins in the stripped form exhibit a high oxigen affinity, a small alkaline Bohr effect, a pronounce organic polyphosphate effect and a pH-dependent Hill coefficient, close to 2 below pH 7.5 and near 1 at higher pHs. Molecular weight determinations indicate 2 forms, a dimeric form of MW 32000 d. and a tetrameric form of about 64000 d. The deoxyhemoglobin is tetrameric. Ion-exchange chromatography shows two components which may bind to each other being eluted as a single component of MW 32000 d. The osygen alkaline Bohr effect observed for the stripped hemoglobin may be explained by the transition from the tetramer to the dimer during oxygen addition experiments. The phenomenon appears to be unique among animals. ß-Chain sequencing determinations show that abnormal human hemoglobin with similar properties has a glutamic acid residue substituted at the alfa1-ß2 interface by valine in snake hemoglobin

Some functional and structural properties of Bufus paracnemis and Pipa pipae hemoglobins.

1. Hemoglobin from terrestrial and an aquatic amphibia Bufo paracnemis and Pipa pipae respectively both living in the same region (Belém, Pará) were compared. 2. The number of hemolysate components were determined by starch-gel electrophoresis and CMC-chromatography. P. pipae hemoglobin presented 4 components and B. paracnemis 2, all of anodic mobility. 3. Functional properties of the hemoglobins (oxygen affinity. Bohr effect, carbon monoxide equilibrium) were determined and compared. 4. The differences found in the functional properties were correlated with the different habitat: aquatic or terrestrial for the amphibia. 5. The study of the oxygen functional properties of the hemoglobin showed in the stripped proteins of P. pipae in the presence of ATP, an oxygen affinity (P50 = 7.24 mmHg) that of B. paracnemis at the same pH (P50 = 15.84 mmHg). At high pH the P50 values are different being 15.84 mmHg for the terrestrial frog and 5 mmHg for P. pipae haemoglobin both at pH 8. In addition Bohr effect was noted only in P. pipae hemolysate in the presence of ATP. 6. The CO-equilibrium affinity constant in the presence of ATP are similar in both frogs, of about, log C50 = -6.9. The ratio Pco/Po2 for B. paracnemis hemoglobin was about 300 whereas for that of P. pipae was about 100 only. 7. The kinetic study of reactive sulfhydryl groups in both frog hemoglobin with 4-PDS (specific SH group reagent was used and shown high pseudo-first order constant for B. paracnemis hemoglobin) (k' = 0.46/min) either in presence or not of ATP, compared for that of P. pipae where values were K' = 0.003/min in the stripped protein and k' = 0.014/min in the presence of ATP. 8. Denaturation kinetic studies of the hemoglobin with sodium benzoate was performed and the results were compared with that of Rana catesbeiana, i.e. the pseudo-first order of the hemoglobin denaturation reaction are low for the aquatic P. pipae adult although for the B. paracnemis high molecular resistant was also noted. For P. pipae hemoglobin, nevertheless with ATP such resistance becomes higher. This does not occur with B. paracnemis hemoglobins.