Pregelation aggregation of sickle cell hemoglobin

Alprazolam induced conformational change in hemoglobin

Alprazolam (ALP) is a widely prescribed sedative and antidepressant benzodiazepine group of drugs. The wide uses of this drug lead us to investigate its possible interaction with hemoglobin (Hb). Spectrophotometric and spectofluorimetric studies showed strong binding of ALP with Hb. Circular dichroic spectra showed that alpha-helical structure of Hb-subunits has been largely changed. On ALP treatment partial pressure of O(2) is increased in the blood indicating release of O(2) from erythrocytes. Further, the binding of ALP-induced conformational changes in Hb resulting in larger Hb particle size was demonstrated by dynamic light scattering experiment. Thus, the present study unambiguously raises question of danger of random usage of ALP, which binds with and changes the function of Hb.

Allowance for thermodynamic non-ideality in the characterization of protein self-association by frontal exclusion chromatography: hemoglobin revisited

This investigation re-examines theoretical aspects of the allowance for effects of thermodynamic non-ideality on the characterization of protein self-association by frontal exclusion chromatography, and thereby provides methods of analysis with greater thermodynamic rigor than those used previously. Their application is illustrated by reappraisal of published exclusion chromatography data for hemoglobin on the controlled-pore-glass matrix CPG-120. The equilibrium constant of 100/M that is obtained for dimerization of the alpha(2)beta(2) species by this means is also deduced from re-examination of published studies of concentrated hemoglobin solutions by osmotic pressure and sedimentation equilibrium methods.

Saturation transfer electron paramagnetic resonance detection of sickle hemoglobin aggregation during deoxygenation

Spin-label saturation transfer EPR (ST-EPR) methods have been used to study the sickle hemoglobin (HbS) aggregation behaviors induced by slow deoxygenation at a constant temperature of 30 degrees C, and by a rapid temperature increase from 1 degree to 30 degrees C for fully deoxygenated HbS. For slow deoxygenation at 30 degrees C, we find that the effective HbS correlation time exhibits a continuous increase, without any abrupt transitions, suggesting that polymer formation in concentrated HbS at high temperature occurs even at high oxygenation levels. Upon a rapid temperature increase, fully deoxygenated HbS exhibits a short delay time, then an abrupt increase in effective correlation time. These results also indicate that ST-EPR provides a useful method for probing the molecular dynamics of HbS aggregation.

Exclusion chromatography of concentrated hemoglobin solutions. Comparison of the self-association behavior of the oxy and deoxy forms of the alpha 2 beta 2 species

Theory pertaining to the interpretation of partition chromatography results obtained with self-associating protein systems studied at high total concentrations is extended to permit consideration of situations in which both monomeric and dimeric states partition. This development, which includes considerations of thermodynamic nonideality effects, permits a quantitative correlation of human oxyhemoglobin results reported previously and obtained in this work employing a different stationary matrix of controlled-pore glass beads. The two sets of results, obtained at pH 7.3 and 20 degree C, indicate that the alpha 2 beta 2 species of oxyhemoglobin self-associates. Two types of association pattern, discrete dimerization and an indefinite self-association, are examined. This is done for a realistic range of values for the radius, r. of the effective hard sphere appropriate to the calculation of the covolume of the alpha 2 beta 2 species in the assessment of the thermodynamic nonideality contribution. Assessed values of the isodesmic association constant range from 66 +/- 23 M-1 (r - 2.84 nm) to 154 +/- 26 M-1 (r = 3.13 nm). This mode of indefinite association is marginally favored over dimerization when the larger value of r is considered, the two patterns becoming virtually indistinguishable for the lower value of r. Partition chromatography results are also presented for human deoxyhemoglobin up to a total concentration of 225 g/l, and are analyzed in a similar fashion to show that the indefinite self-association pattern is favored, governed by an isodesmic constant in the range 91 +/- 9 M-1 (r = 2.84 nm) to 223 +/- 84 M-1 (r = 3.13 nm). Comparison of the constants assessed for the oxy and deoxy systems permits discussion of the concept that oxygen binds preferentially to the alpha 2 beta 2 species of deoxyhemoglobin in comparison with its polymers.

Diffusion coefficients of hemoglobin by intensity fluctuation spectroscopy: effects of varying pH and ionic strength

Measurements of the mutual diffusion coefficients (D) of the liganded human hemoglobins (Hb) oxy-HbA and oxy-HbS were performed as a function of Hb concentration (CHb), pH, and ionic strength (tau) by intensity fluctuation spectroscopy (IFS). Average diffusion coefficients, (D), and normalized variances, ((D/(D) - 1)2), were recorded. Results are reported and select features are discussed quantitatively. (a) for tau = 0.15 M, the shape of the (d) vs. CHb curve is found to vary with pH. We developed a precise description of this effect in the form of an algebraic relationship between (D), CHb, and Z, the titration charge. (b) only slight differences between the (D) values of oxy-HbS and oxy-HbA are observed, at tau = 0.15 M, for CHb Less Than or Equal To 10 g%. These differences are explained by the theory of part a. (c) No evidence of aggregation is found in solutions of oxy-HbA or oxy-HbS, at tau = 0.15 M, for CHb Less Than or Equal To 10 g%. (d) Indications of aggregation appear in oxy-HbA solutions at very low concentrations of salt. An estimate is made of the extent of aggregation, and the average radius of a cluster is determined.

Chromatographic evidence of the self-association of oxyhemoglobin in concentrated solutions: its biological implications

Expressions that take into account the effects of thermodynamic non-ideality, described in terms of a high-order virial expansion, are derived for the concentration-dependence of the weight-average partition coefficient in exclusion chromatography of a single solute and of a solute undergoing reversible self-association. Comparison of the concentration-dependences predicted by those expressions with results obtained for bovine and human oxyhemoglobins on CPG-10-120 porous glass beads in 0.156 I phosphate-chloride buffer, pH 7.3, shows that neither oxyhemoglobin conforms with the concept of it being a single alpha 2 beta 2 entity with Stokes radius of 3.13 nm, the experimental value. Previously published osmotic pressure and sedimentation equilibrium results are also shown to be inconsistent with this concept. On the other hand, both sets of exclusion chromatography results are consistent with the joint operation of thermodynamic non-ideality and reversible association of the alpha 2 beta 2 species. From the magnitude of the equilibrium constant, derived for either of two possible modes of association, it is calculated that only half of the oxyhemoglobin would be in the alpha 2 beta 2 states under conditions of oxygen saturation and a concentration of 320 g/liter, that pertaining in the red blood cell. The consequences of this association phenomenon are discussed in relation to the oxygen binding curves obtained by others in the presence and absence of 2,3-diphosphoglycerate (DPG). An explanation is provided of the observed dependence on hemoglobin concentration of oxygen-binding in the presence of DPG, and of the absence of such an effect in DPG-free solutions. It is concluded that the control of oxygen binding to hemoglobin in the physiological situation involves the joint operation of self-association and allosteric effects.

Spin label detection of intermolecular interactions in carbonmonoxy sickle hemoglobin

With recently developed spin label techniques for monitoring macromolecular rotational motion, heme-liganded sickle cell hemoglobin in the presence of inositol hexaphosphate is shown to exhibit restricted motional freedom as compared to liganded normal adult human hemoglobin. This motional restriction is dependent on both hemoglobin concentration and temperature.

Dynamic light scattering of biopolymers and biocolloids

Widespread applications of dynamic light scattering techniques to the study of macromolecular Brownian motion have yielded not only a valuable store of factual information concerning solution conformations and conformational changes, but have also provided an important window through which to view the dynamics of internal modes of motion. These techniques have coincided with a resurgence of interest in the solution physical chemistry of macromolecules, including hydrodynamic properties, and the profound effect of intermolecular interactions on both the disposition and dynamics of macromolecules in solution.

Circular Dichroism Studies of Cyanate-Induced Conformational Changes in Hemoglobins A and S

Circular dichroism and difference spectroscopy have been used to study dilute aqueous solutions of oxygenated, deoxygenated, and carbamoylated deoxygenated hemoglobins A and S (HbA and HbS, respectively). The spectra of HbA and HbS, in comparable state of oxygenation or carbamoylation, are identical, strongly implying identical conformations about the heme groups of the respective proteins. The spectra of the oxygenated forms change little upon addition of KCNO, which is known to carbamoylate the NH2 terminals of the individual chains (Cerami and Manning, 1971). The spectra of the deoxygenated forms, on the other hand, are markedly altered. The decreased magnitude of the 430-nm extremum with increased cyanate concentration can be used to calculate an addition curve which becomes asymptotic at a cyanate:heme molar ratio of approximately 10(3). This conformational change occurs in the absence of O2 and has been predicted (Njikam et al.,1973); it can also be demonstrated by difference spectroscopy techniques, whereby a comparable addition curve can be constructed from changes in the 555-nm absorption, while the 541-nm absorption remains invariant. The change described corresponds to the formation of a new conformation, corresponding to carbamoyldeoxyhemoglobin, carrying one carbamoyl group per chain. In the presence of a small quantity of oxygen, however, the above reported changes in CD are accompanied by a concomitant rise in the 415-nm peak-corresponding to the formation of oxyhemoglobin-while those in the difference spectra reflect not only a change in the 555-nm band but also a parallel one at 541 nm, confirming the formation of oxyhemoglobin. Thus the conformation achieved upon carbamoylation of deoxyhemoglobin has the higher oxygen affinity predicted by Nigen et al. (1974) for carbamoyldeoxyhemoglobin. Cyanate has been used (Cerami and Manning, 1971) as an antisickling reagent in vivo and in vitro, but, although it has been shown that it binds covalently to the NH2-terminal residues of hemoglobin (Lee and Manning, 1973), its effect on hemoglobin conformation has not been previously shown nor has its mechanism of action been fully clarified. The results presented here show that the effect of cyanate on hemoglobin is the formation of a new conformation with heightened oxygen affinity. Since oxyHbS does not aggregate while deoxyHbS does, in a temperature-dependent fashion, the formation of carbamoyldeoxyHbS interferes with such aggregation in vitro in deoxygenated samples. In vivo, where there are generally low residual concentrations of O2, the formation of oxyHb is favored by the higher O2 affinity of carbamoyldeoxyHbS, and aggregation with concomitant red cell sickling is therefore disfavored.

Intermolecular interactions of oxygenated sickle hemoglobin molecules in cells and cell-free solutions

We have measured the intermolecular interactions of oxygenated sickle hemoglobin molecules in cells and in cell-free solutions, and have compared the results with similar data for liganded normal adult hemoglobin. The experiments involve the measurement of the spin-lattice relaxation time T1 of protons of solvent water molecules, as a function of an externally applied static magnetic field. From such data, one can derive a correlation time tauc, for each sample, which is a measure of the time taken for a hemoglobin molecule to randomize its orientation due to Brownian motion. Thus tauc is a measure of the freedom of rotational motion, on a molecular or microscopic level, of hemoglobin molecules. Intermolecular interactions will reduce this freedom of motion and lengthen tauc. We find that oxygenated sickle hemoglobin molecules have an additional intermolecular interaction not found for normal hemoglobin. This extra interaction is increased by the presence of either inorganic phosphate or diphosphoglycerate, and is greater for sickle hemoglobin within cells than in cell-free solutions. By comparing the present results with published data on the viscosity of oxygenated sickle and normal hemoglobin, we conclude that, at concentrations comparable to intracellular values, oxygenated sickle hemoglobin molecules form aggregates several tetramers in size. The possibility exists that these aggregates are the earliest stage of fiber formation itself, the physical basis of the sickling phenomena.

The concentration dependence of the hemoglobin mutual diffusion coefficient

Laser correlation spectroscopy was used to measure the mutual diffusion coefficient, D, of human cyanomethemoglobin (Fe+++:CN) at varying protein concentrations. These measurements were made at 20 degrees C in a 0.1 M phosphate buffer solution at pH 7.0. For low protein concentrations we find D = (6.43 +/- 0.26) X 10(-7) cm2/s and that there is a near linear decrease from this value at higher concentrations. The linear relation between the diffusion coefficient and protein concentration allows us to deduce the value of the linear frictional volume fraction coefficient, Kf=7.75, and to extrapolate to hemoglobin concentrations equivalent to that in the red blood cell where we estimate D = 4.25 X 10(-7) cm2/s. Various theoretical predictions of the dependence of the mutual diffusion coefficient on concentration are tested; we find that the generalized Stokes-Einstein relation can be made to fit our high concentration data if we assume a hard-sphere model and if we include a term involving a hydrodynamic interaction integral.