The reaction of deoxy-sickle cell hemoglobin with hydroxyurea.

In addition to its capacity to increase fetal hemoglobin levels, other mechanisms are implicated in hydroxyurea's ability to provide beneficial effects to patients with sickle cell disease. We hypothesize that the reaction of hemoglobin with hydroxyurea may play a role. It is shown that hydroxyurea reacts with deoxy-sickle cell hemoglobin (Hb) to form methemoglobin (metHb) and nitrosyl hemoglobin (HbNO). The products of the reaction as well as the kinetics are followed by absorption spectroscopy and electron paramagnetic resonance (EPR) spectroscopy. Analysis of the kinetics shows that the reaction can be approximated by a pseudo-first order rate constant of 3.7x10(-4) (1/(s.M)) for the disappearance of deoxy-sickle cell hemoglobin. Further analysis shows that HbNO is formed at an observed average rate of 5.25x10(-5) (1/s), three to four times slower than the rate of formation of metHb. EPR spectroscopy is used to show that the formation of HbNO involves the specific transfer of NO from the NHOH group of hydroxyurea. The potential importance of this reaction is discussed in the context of metHb and HbNO being able to increase the delay time for sickle cell hemoglobin polymerization and HbNO's vasodilating capabilities through conversion to S-nitrosohemoglobin.     

On the pH-dependence of the reaction of hemoglobin with carbon monoxide.

Flash-photolysis experiments were performed on solutions of carbonmonoxy hemoglobin (human Hb A) as function as pH. The fraction of fast reaction and the amount of photodissociation as produced by a given amount of light quanta has been analyzed in terms of the allosteric model of ligand binding by Monod, Wyman and Changeux. It is shown how the switch-over point of the allosteric transition from the T or R state is controlled by the protons, which act as allosteric effectors.     

Chain equivalence in reaction of nitric oxide with hemoglobin.

Mixtures of nitric oxide and hemoglobin were prepared in a rapid freeze apparatus and analyzed by EPR spectroscopy. Spectra from samples at various degrees of saturation showed that the two subunits bound NO at equal rates. Identical results were observed in 0.1 M phosphate at pH 6.5 and 0.1 M 2,2'-bis(hydroxymethyl)-2,2',2'-nitrilotriethanol, 0.1 M NaCl at pH 7.0, both in the presence and absence of inositol hexaphosphate at either buffer condition. At subsaturating levels of NO (less than 60%), or at all levels of saturation in the presence of inositol hexaphosphate, it was found that the EPR spectrum of nitrosylhemoglobin varied with the length of time before freezing. This change was characterized by the development of a hyperfine structure at g = 2.01 which appeared with a half-time of approximately 0.4 s. Maxwell and Caughey (Maxwell, J. C., and Caughey, W. S. (1976) Biochemistry 15, 388-395) have attributed this three-line EPR hyperfine structure to the formation of a pentacoordinate ferroheme-NO complex. Corresponding slow changes were observed in the visible absorption spectrum following the binding of low levels of NO to deoxyhemoglobin or inositol hexaphosphate to fully saturated nitrosylhemoglobin. Thus it appears that NO binding to the alpha and beta subunits of deoxyhemoglobin takes place at equal rates and, under conditions favoring the T quaternary state (low saturation, presence of inositol hexaphosphate), a further slow structural change takes place, resulting in the cleavage of the iron--proximal histidine bond.     

Ionizable groups linked to the reaction of 2,2'-dithiobispyridine with hemoglobin.

The pH-dependence of the second-order rate-constant for the reaction of 2,2'-dithiobispyridine with the CysF9(93) beta sulphydryl group of hemoglobin in the R quaternary structure is analyzed in terms of a tentative model based on the observation that this sulphydryl exists as a mixture of two tertiary conformations in dynamic equilibrium. For the four aquomethemoglobins studied (human A and S, dog and rabbit), the equation derived from this model gives a better fit than a simpler equation based on the assumption of only one tertiary conformation. For the corresponding carbonmonoxyhemoglobins the simpler equation gives a better fit. The dog and rabbit oxy and azidomet data are better fitted by the model equation, whereas the data for the corresponding human A and S derivatives are better fitted by the simpler equation. From the analysis pKa values of 6.1 and 8.7 are obtained for the ionization of groups coupled to the presumed conformational transition. The pKa of 6.1 is assigned to HisHC3(146) beta; the pKa of 8.7 is assigned to the CysF9(93) beta sulphydryl group in its external conformation. It is estimated that the pKa of this sulphydryl may be as high as 12.9 in its internal conformation.     

Computerized scheme for the reaction of hemoglobin with ligands

A scheme for the reaction of hemoglobin with ligands is described, which postulates the functional heterogeneity of the chains, considers all possible combinations of the distribution of the ligand on the four chains of hemoglobin, and does not require simplifying assumptions about the hemoglobin reactivity. Ten tetrameric species are considered, together with 16 reactions between these species, each with an on and an off rate constant. The dissociation of hemoglobin tetramers into dimers is also considered, with four on and four off rate constants for the reactions between dimers, and ten equilibrium constants for the reactions between tetramers and dimers. Moreover, some side reactions, such as the trapping of ligands by a hemoglobin competitor, are included. A FORTRAN program, suitable for microcomputers, is described for handling this scheme, with some examples showing its advantages.     

Effect of some organic cosolvents on the reaction of hemoglobin with oxygen

We studied the effects of some organic cosolvents (monohydric alcohols and amides) on the reaction of hemoglobin with oxygen. We present evidence showing that our data can be analyzed within the framework of the Monod-Wyman-Changeux model and that the main effect of cosolvents is to alter the T ? R conformational equilibrium of hemoglobin, without significantly affecting the intrinsic oxygen dissociation constants. Following a previously described phenomenological approach, the overall effects have been separated into effects related to the variation of the bulk dielectric constant of the solvent and effects not related to the variation of this constant.     

Solid phase reaction of hemoglobin with spillover hydrogen

The reaction of high-temperature solid-state catalytic isotope exchange (HSCIE) between bovine hemoglobin and spillover hydrogen (SH) was studied. It was shown that, in the field of subunit contact, there is a significant decrease in ability for hydrogen exchange by SH. A comparison of the distribution of the isotope label in the hemoglobin α-subunit was carried out for the HSCIE reaction with the hemoglobin complex and with the free α-subunit. To this end, enzymatic hydrolysis of protein under the action of trypsin was carried out. The separation of tritium-labeled tryptic peptides was achieved by HPLC. Changes in availability of polypeptide chain fragments caused by complex formation were calculated using a molecular model. The formation of the protein complex was shown to lead to a decrease in the ability of fragments of α-subunits MFLSFPTTK (A_32?40) and VDPVNFK (A_93?99) for hydrogen replacement by tritium by almost an order of magnitude; hence, their availability to water (1.4 Å) twice decreased on the average. The decrease in ability to an exchange of hydrogen by spillover tritium on the formation of hemoglobin complex was shown to be connected with a reduction in availability of polypeptide chain fragments participating in spatial interactions of subunits with each other. Thus, the HSCIE reaction can be used not only for the preparative obtaining of tritium-labeled compounds, but also for determining the contact area in the formation of protein complexes.     

The reaction between hemoglobin alpha-subunit and haptoglobin.

The interaction between human hemoglobin alpha-subunit and porcine haptoglobin was investigated by polyacrylamide gel electrophoresis, gel filtration chromatography, sedimentation through excess alpha-subunit and gel filtration in an alpha-subunit-containing medium. No interaction was detected by the first two methods indicating dissociation of the complex during the application of these separation techniques. The latter two methods, in which the complex is studied in a medium of excess subunits, showed that haptoglobin became saturated with the binding of two alpha-subunits.     

Formation of intermediate products in the reaction of hemoglobin with cyanide

Interaction between methemoglobin and cyanide was studied by low temperature inhibition method in combination with ESR. A new, not earlier described in literature ESR signal of low spin cyanide complex of this protein was recorded.