A new mode for heme-heme interactions in hemoglobin associated with distal perturbations

The distal side of the heme pocket, known to regulate ligand affinity, is shown to be directly involved in subunit interactions. Valency hybrids with oxygen or carbon monoxide bound to the reduced chain are used to model R-state hemoglobin with different distal perturbations. Electron paramagnetic resonance of the oxidized chains shows that the carbon monoxide perturbation is transmitted between subunits to the distal histidine and the oxidized iron center. A comparison of hybrids with only one type of chain oxidized and hybrids with a single alpha beta dimer oxidized is consistent with this perturbation being transmitted across the alpha 1 beta 1 interface. This represents a new mode of subunit interactions in hemoglobin.

Studies on cytosolic guanylate cyclase from human placenta

We have purified the soluble form of guanylate cyclase from human placenta greater than 2400-fold. The enzyme shared several characteristics with the enzyme purified from other sources including molecular mass and subunit composition, activation by divalent cations, inhibition by ATP and Michaelis constants. The enzyme, however, had a lower absorption maximum in the Soret region (417 +/- 1 nm) than the enzyme from other sources and was activated only one-fifth as much by nitric oxide as the bovine lung enzyme. It appears that the heme prosthetic group in the human placental enzyme may be hexa-coordinate and in the bovine lung enzyme the heme group may be penta-coordinate.

Double-mixing kinetic studies of the reactions of monoliganded species of hemoglobin: alpha 2(CO)1 beta 2 and alpha 2 beta 2(CO)1

The kinetics of CO association to and dissociation from the two isomers of monoliganded species alpha ICO beta I(alpha II beta II) and alpha I beta I (alpha II beta COII) has been studied by double-mixing stopped-flow and microperoxidase methods. The monoliganded species were generated by hybridization between excess ferric Hb and alpha CO2 beta +2 or alpha +2 beta CO2 prepared by high-pressure liquid chromatography (HPLC). The results indicated that: 1) there were no significant differences in the reactivities of alpha and beta chains in the first step of ligation; 2) in the second step of ligation there was significant cooperativity in the reaction of deoxyhemoglobin with 0.05 or 0.1 equivalent of CO. Diliganded species were therefore formed in significant amounts. The double-mixing HPLC results suggested that in the second step of ligation alpha chains reacted faster than the beta chains, and the main diliganded species formed was alpha I beta ICO (alpha IICO beta II) or its isomer alpha ICO I(alpha II beta IICO). These results seem to indicate that the reaction of the first CO is mostly random and in the second step of ligation CO binds more to the tetramers in which one beta chain is already ligated: alpha I beta I (alpha II beta II) + CO----alpha ICO beta I (alpha II beta II) and alpha I beta ICO (alpha II beta II) + CO----alpha I beta ICO (alpha IICO beta II).

Double mixing stopped-flow method for the study of equilibria and kinetics of dimer-tetramer association of hemoglobins: studies on Hb Carp, Hb A, and Hb Rothschild

A double mixing stopped-flow method is described for studying the dimer-tetramer equilibria of oxyhemoglobins and the kinetics of association of unliganded dimers. The three hemoglobins studied were: Hb Carp, Hb A, and Hb Rothschild (Trp beta 37 (C3)----Arg). The new method reproduces the data obtained for oxyHb A by other established methods. In agreement with previous studies, the new method indicates little, if any, dissociation of oxyHb carp into dimers even in 2 M urea solutions (0.1 M Bis-Tris pH 7.0). OxyHb Rothschild, on the other hand, is extensively dissociated into dimers (K(Hb4L4 in equilibrium with 2Hb2) = 37.3 x 10(-6) M) and the rate constant for the association of deoxy dimers of Hb Rothschild is about one-tenth of the value for Hb A indicating that the deoxy tetramer of Hb Rothschild is at least 10 times more dissociated into dimers than deoxyHb A.

Double-mixing kinetic studies of the reactions of methyl isocyanide and CO with diliganded intermediates of hemoglobin: alpha 2CO beta 2 and alpha 2 beta 2CO

Kinetics of the reactions of CO and methyl isocyanide with two diliganded intermediates of hemoglobin, alpha 2CO beta 2 and alpha 2 beta 2CO, have been studied by double-mixing and microperoxidase methods. The valency hybrids were prepared by high-pressure liquid chromatography. The reaction time courses of ligand combination and dissociation with both of the ligands were biphasic, and in CO combination reaction the zero-time amplitudes of the two phases were independent of the protein concentration. In the presence of 2 M urea the reaction time course was clearly dependent on protein concentration, as the zero-time amplitude of the fast phase increased at lower protein concentrations. These two observations indicate that little dissociation of tetramers into dimers occurs in the absence of urea. Consistent with this, the kinetic data for the reactions of CO best fit a reaction model consisting of two tetrameric species not in rapid equilibrium with each other. Various considerations, however, suggest that the reaction model is more appropriately described as 2D in equilibrium R in equilibrium T. The reaction of triliganded species (Hb4(CO)2Me1) with methyl isocyanide was monophasic, and the reaction model suggested a fast T in equilibrium R structural change after the binding of the third ligand. Although the precise structural nature of the two species remains undefined, it is concluded that the biphasicity in the reactions of the two hybrids is characteristic of the diliganded species only and is independent of the nature of the ligand.

Quaternary structure and the geminate recombination of carp hemoglobin with methylisocyanide

The kinetics of geminate recombination were studied for the methylisocyanide derivative of carp hemoglobin. Carp hemoglobin is of interest because it has been established that the fully liganded form switches between a high affinity R state at pH 9 and a low affinity T state at pH 6 in the presence of IHP. Geminate recombination was observed on both the picosecond and the nanosecond time scales under all conditions; however, only a small variation is observed in the rates and the yields of geminate recombination as the protein switches from the R to the T state. Taken together with overall "on" and "off" rates, the data indicate that the change from the R to the T configuration affects bond breaking most, but also influences subsequent escape from the protein as well as both entry into the protein and bond formation. There is some reason to postulate tertiary conformational change in the T state on the microsecond time scale following ligand escape from the protein.

Kinetic studies on partially liganded species of carboxyhemoglobin: (alpha 1CO-beta 1CO)alpha 2 beta 2 or (alpha 2CO beta 2CO)alpha 1 beta 1

Kinetics of CO combination with and dissociation from isomer III, (alpha 1CO beta 1CO)alpha 2 beta 2 or alpha 1 beta 1 (alpha 2CO beta 2CO), and Hb Rothschild have been studied using the double mixing and microperoxidase methods. Isomer III was prepared in a manner so that it was the only reactive species in the reaction mixture. The biphasic reaction time course in both the "on" and "off" reactions of isomer III and the CO combination reaction of Hb Rothschild are attributed to slow relaxation between the fast and slow CO-reacting species in the two proteins: isomer III: l'f = 6 x 10(6) M-1 s-1, l'dimer = 1.7 x 10(6) M-1 s-1, l's = 2.2 x 10(5) M-1 s-1, lf = 0.15 s-1, ls = 0.01 s-1; Hb Rothschild: l'f = 2.8 x 10(6) M-1 s-1; l's = 2.7 x 10(5) M-1 s-1.

Kinetic studies on partially liganded species of carboxyhemoglobin: alpha 2 CO beta 2 and alpha 2 beta 2CO

The valency hybrids of Hb A, alpha 2CO beta 2+, and alpha 2+ beta 2CO have been prepared by a new high pressure liquid chromatography method, and the kinetics of their CO-combination and dissociation reactions have been studied by double mixing and microperoxidase methods. Both reactions are biphasic. The slow phase in CO-combination and the fast phase in CO-dissociation are due to the reactions of alpha CO2 beta T2 or alpha 2 beta 2CO,T. The fast phase in CO-combination reaction has two components, one due to the dimers of the hybrid and the other due to the R-state tetramer. Immediately after the reduction of the valency hybrids, the overall system is represented by the equation: 2 alpha CO beta in equilibrium alpha 2CO beta 2R in equilibrium alpha 2CO beta 2T or (formula: see text) If the solutions are aged for 3-11 s, the R-state population is reduced gradually to a very small size, and the main species after 11 s of aging are dimers and T-state tetramers. Analysis of the kinetic data indicates slow R in equilibrium T equilibria in the absence of phosphates and significant dissociation of the T-state tetramer. It is concluded that the subunit contacts alpha 1-beta 2 (or alpha 2-beta 1) are impaired seriously in the hybrids. Very slow R in equilibrium T relaxation makes these hybrids unlikely intermediates in the sequential binding of CO to Hb tetramer.

Reaction of nitric oxide with heme proteins and model compounds of hemoglobin

Rates for the reaction of nitric oxide with several ferric heme proteins and model compounds have been measured. The NO combination rates are markedly affected by the presence or absence of distal histidine. Elephant myoglobin in which the E7 distal histidine has been replaced by glutamine reacts with NO 500-1000 times faster than do the native hemoglobins or myoglobins. By contrast, there is no difference in the CO combination rate constants of sperm whale and elephant myoglobins. Studies on ferric model compounds for the R and T states of hemoglobin indicate that their NO combination rate constants are similar to those observed for the combination of CO with the corresponding ferro derivatives. The last observation suggests that the presence of an axial water molecule at the ligand binding site of ferric hemoglobin A prevents it from exhibiting significant cooperativity in its reactions with NO.

Picosecond geminate recombination of nitrosylmyoglobins

The kinetics of NO geminate recombination to sperm whale and elephant myoglobins has been studied on the picosecond time scale using an amplified colliding-pulse mode-locked ring dye laser. The dynamics of ligand rebinding are shown to be affected by the distal structure of the protein surrounding the heme pocket.

Hepatic transport and binding of rose bengal in the presence of albumin and gamma globulin

Gamma globulin and albumin are compared with respect to their effects on the hepatic transport of rose bengal and with respect to the rates and affinities with which they bind this dye. The apparent intrinsic clearance of rose bengal is greater in the presence of albumin than in the presence of gamma globulin, and this difference increases with the protein concentration. Because the binding affinities of these proteins also differ, however, it cannot be concluded decisively that the mechanisms of dye removal are distinct. For both proteins the binding reaction rates as measured by stopped-flow spectrophotometry are much faster than the rate of convection along the sinusoid or the rate of removal of free dye by liver cells. The transport data and the binding rate constants are the basis for an extended theoretical model developed and analyzed in an accompanying report.

Geminate recombination of CO in rabbit, opossum, and adult hemoglobins

The geminate recombination of CO with Hb following dissociation by a 10-ns laser pulse has been studied as a function of pH (9.2 and 7.0 without inositol hexaphosphate and 6.0 with inositol hexaphosphate) and temperature (5-35 degrees C). The hemoglobins studied included adult, Rothschild, rabbit, opossum, and carp. Despite significant differences in their structural and functional properties, the first four of these hemoglobins show similar trends in the yields, rates, and activation energies of the geminate recombination. The nature of the "cage recombination" in hemoglobin is discussed in the light of such findings. Neither a slow diffusion model nor a model based upon a specific non-heme binding site accounts for the observations.

Geminate recombination in carboxy hemoglobin A and its relation to overall carbon monoxide reactivity

The geminate recombination of CO with carboxy hemoglobin (Hb4(CO)3) following a ten nanosecond laser pulse and the overall combination of the fourth CO with Hb4(CO)3 has been studied as a function of pH in the presence and absence of inositol hexaphosphate. The results indicate that the kinetics of both reactions are independent of pH and phosphate concentration. The results are discussed in terms of a two-step mechanism: a pre-equilibrium step followed by heme--ligand bond formation. The latter is also known as the geminate recombination reaction (Hb + CO in equilibrium Hb X CO in equilibrium HbCO).

Reaction of nitric oxide with heme proteins: studies on metmyoglobin, opossum methemoglobin, and microperoxidase

Kinetic and EPR studies show that the first step in the reaction of NO with ferric myoglobin, opossum hemoglobin, and microperoxidase is the reversible formation of the H-NO complex: H + NO in equilibrium H-NO (where H = Mb+, or Hb+ OP, or MP+). The NO-combination rates are markedly affected by the presence or absence of the distal histidine. The distal histidine significantly reduces the NO-combination rates, perhaps by interaction between the distal histidine and the ferric iron. Thus the beta-chains of Hb+ OP and metmyoglobin show similar combination rates. In the absence of a distal histidine, the NO-combination rates in the alpha-chains of Hb+ OP are much faster and similar to those observed for the five-coordinate heme in microperoxidase. The loss of a water molecule from the six-coordination site is assumed to be the rate-limiting step.

Studies of human hemoglobin intermediates. The double mixing method for studying the reactions of the species Hb4(CO) and Hb4(CO)2

Using the double mixing method we have studied the reactions of the partially liganded species (Hb4, Hb4L1, Hb4L2, Hb4L3) of normal human hemoglobin with carbon monoxide. In the first mixing, oxygen is removed from the species Hb4(O2) chi (CO) gamma and at the second mixing the species Hb4(CO) gamma reacts with CO. At 90% saturation of oxyHb with CO the main intermediate species are Hb4(CO)3 and Hb4(CO)2, and at 10% saturation Hb4 and Hb4(CO). The four CO-combination rate constants determined are: l'1 = 1 X 10(5) M-1 S-1, l'2 = 7 X 10(5) M-1 S-1, l'3 = 2 X 10(5) M-1 S-1 and l'4 = 4.8 X 10(6) M-1 S-1. The results indicate that there is no monotonic increase in the successive CO-combination rate constants. It is difficult to explain these results on the basis of the two-state model (Monod et al., 1965) or the stereochemical model of Perutz (1970).

Functional studies on hemoglobin opossum. Conclusions drawn regarding the role of the distal histidine

In the hemoglobin of the opossum, the alpha chains have different residues at positions E7 and E11 than do most other mammalian hemoglobins. In the opossum, the usual histidine at alpha E7 is replaced by glutamine, the valine at alpha E11 by isoleucine, and the hemoglobin is known to have a low oxygen affinity and a low Hill coefficient. Comparison of kinetic studies of opossum hemoglobin with normal human hemoglobin shows that alpha chains in Hb opossum, despite the lack of distal histidine, do not differ significantly in CO-combination rates in either the T or R states. These rates are much slower than the rates reported for Hb Zurich, the hemoglobin from Chironomus thumi thumi, or the monomeric components of glycera hemoglobin, all of which also have a different residue at E7. As compared with Hb A, the changes in ligand affinities in the T and R states are small and cannot account for the unusually high values of p50 for Hb opossum. The equilibrium and kinetic data indicate that the L = (T)/(R) is about 100 times higher for Hb opossum than for Hb A; CCO = KR/KT approximately equal to 0.014. The kinetic data on l'4 and l also indicate that the R leads to T equilibrium for Hb4(CO)4 and Hb4(CO)2 can be shifted in either direction by adding inositol hexaphosphate or by changing the pH.

The interaction of heme-hemopexin with CO

The equilibria and kinetics of the reaction of heme-hemopexin with CO were studied. A stoichiometry of one CO/heme was determined, and the affinity of heme-hemopexin for CO was found to be pH-dependent. At pH 8.0, the affinity constant was 4.5 X 10(5) M-1 compared with 4 X 10(6) M-1 at pH 6.1. The kinetics of CO binding were also pH-dependent. A biphasic reaction at neutral pH could be resolved into a faster phase (kon = 2.2 X 10(3) M-1 s-1) solely found at pH 6.0, and a slower phase (kon = 2.0 X 10(2) M-1 s-1) solely found at pH 8.0. The dissociation reaction on the other hand was found to be independent of pH in the range examined (koff = 5 X 10(-4) s-1).

Interaction of sickle cell hemoglobin with erythrocyte membranes

The interactions of hemoglobin S with the erythrocyte membrane were compared with the corresponding interactions of hemoglobin A by measuring in both steady-state and kinetic experiments the quenching of the fluorescence of a probe embedded in erythrocyte membranes. Whereas hemoglobin A could be dissociated from membranes, a fraction of hemoglobin S was irreversibly bound even in the oxy state. Deoxyhemoglobin S interacted much more strongly with erythrocyte membranes than did deoxyhemoglobin A: a portion of the deoxyhemoglobin S was irreversibly bound, and the reversibly bound fraction of hemoglobin S dissociated more slowly than did deoxyhemoglobin A. It is suggested that the binding of deoxyhemoglobin S is a two-step reaction in which the first step involves electrostatic interaction with band III erythrocyte membrane protein and the second step involves a hydrophobic interaction with membrane lipids. The latter reaction reflects the greater hydrophobicity of hemoglobin S. The unique interaction of hemoglobin S with erythrocyte membranes may be important in the formation of irreversibly sickled cells.

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.

Kinetic study of the interaction of oxy- and deoxyhemoglobins with the erythrocyte membrane

Changes in fluorescence intensity of a membrane-embedded probe were used to study the kinetics of binding of oxy- and deoxyhemoglobin to erythrocyte membranes. For these studies, stopped-flow fluorimetric techniques were utilized. Both binding and dissociation of hemoglobin from membranes followed heterogeneous first-order kinetics. The rate constants for binding of oxyhemoglobin were about 10 times larger than those of deoxyhemoglobin; the dissociation rate constants of oxyhemoglobin were about one-quarter those of the unliganded form. The results are discussed in light of the steady-state binding constants previously derived for both oxy- and deoxyhemoglobin.