Cooperative cyanide dissociation from ferrous hemoglobin.

Rapid reduction of cyano-met hemoglobin (Hb+CN-) leads to the formation of an intermediate species, the cyanide derivative of ferrous hemoglobin, which dissociates to unliganded hemoglobin because of the extremely low affinity of the ligand for the ferrous heme iron. The properties of the intermediate were studied by transient spectroscopy in human hemoglobin and its isolated alpha and beta chains, in the presence and absence of CO. When mixing with dithionite, the time courses of reduction of the heme iron and dissociation of cyanide overlap considerably; addition to the reaction mixture of the redox indicator methyl viologen considerably increases the rate of reduction and allows unequivocal determination of the spectroscopic and kinetic properties of the intermediate. The results show that (i) the dissociation of cyanide from the isolated alpha and beta chains (as well as the (alpha CO)2(beta + CN-)2 hybrid) is a simple process; (ii) the two chains display similar rate parameters, but show spectroscopic inequivalence, both in the Soret and the visible regions; (iii) cooperative effects are shown to control the rate of dissociation of cyanide from hemoglobin, similarly to what happens for oxygen; and (iv) allosteric effectors (typically inositol hexaphosphate) increase the overall rate of dissociation by stabilization of the T state. We have, therefore, shown for the first time that the dissociation of cyanide from ferrous hemoglobin is controlled by the quaternary state, thereby adding one more ligand to the analysis of the structure-function relationships in hemoglobin.     

Gelation of sickle hemoglobin. III. Nitrosyl hemoglobin.

Sickle cell nitrosyl hemoglobin was examined for gelation by an ultracentrifugal method previously described (Briehl &; Ewert, 1973) and by birefringence. In the presence of inositol hexaphosphate gelation which exhibited the endothermic temperature dependence seen in gels of deoxyhemoglobin S was observed by both techniques. In the absence of inositol hexaphosphate no gelation was observed, nor did nitrosyl hemoglobin A exhibit gelation. On the assumption that gelation is dependent on the deoxy or T (low ligand affinity) as opposed to the oxy or R (high ligand affinity) quaternary structure this supports the conclusion that nitrosyl hemoglobin S in inositol hexaphosphate assumes the T structure, in contrast to the other liganded ferrohemoglobin derivatives oxy and carbon monoxide hemoglobin. Assuming further that the quaternary structures and isomerizations are the same in hemoglobins A and S it can also be concluded that nitrosyl hemoglobin A in inositol hexaphosphate assumes the T state. Since no gelation was seen in stripped nitrosyl hemoglobin S, inositol hexaphosphate serves to effect an R to T switch in this derivative. Thus R-T isomerization in nitrosyl hemoglobin occurs without change in ligand binding at the sixth position of the heme group confirming the conclusion of Salhany (1974) and Salhany et al. (1974).Lowering of the pH toward 6 favors gelation of NO hemoglobin S as it does of deoxy and aquomethemoglobin S (Briehl &; Ewert, 1973,1974), consistent with a favoring of the T structure due to strengthening of the interchain salt bridges and the binding of inositol hexaphosphate and/or changes in site-to-site interactions on which gelation depends.     

Quantitation of methylated hemoglobin via hydrolysis of methyl esters to yield methanol

Methyl esters formed by methylation of carboxylic acid groups on hemoglobin can be quantitated via GC/MS negative-ion chemical ionization analysis of the pentafluorobenzoate derivative of the methanol released from the hemoglobin upon base hydrolysis. Although the method requires extensive cleanup of extracting solvents because of the ubiquitous presence of trace levels of methanol, it is possible to quantitate adducted hemoglobin at levels as low as 4 ng per gram of hemoglobin using [13C, 2H3]methyl alcohol as the internal standard. In principle this method can be used in humans as a dosimeter for exposure to environmental methylating or alkylating agents.     

Near-infrared spectra of Scapharca homodimeric hemoglobin: characterization of the deoxy and photodissociated derivatives.

The near-infrared charge transfer band at 760 nm (band III) has been investigated in deoxy and photodissociated dimeric Scapharca hemoglobin. At 300 K, the 10-ns spectrum of the carbonmonoxy derivative photoproduct is shifted by about 6 nm toward longer wavelengths with respect to the deoxy spectrum, both in buffer and in glycerol/buffer solutions. Moreover, the band III peak occurs at about the same wavelength at 300 K and at 10 K for the 10-ns photodissociated derivative, whereas in the deoxy derivative large changes in peak position and linewidth are observed as a function of temperature. These findings suggest that in dimeric Scapharca hemoglobin the photoproduct has not relaxed after 10 ns. The complete time dependence of the relaxation process has been studied both in buffer and in glycerol/buffer solutions at room temperature. The relaxation from the photoproduct to the deoxy species occurs on a microsecond time scale, in line with recent optical absorption and resonance Raman measurements.     

Fitting abnormal oxygen equilibrium curves of hemoglobin

A growing number of oxygen equilibrium curves for hemoglobin (Hb) mutants, post-translational modifications, or the binding of potent new effectors of Hb cannot be fitted adequately with the two-state model. Examples are curves showing double maxima in the derivative of the Hill plot, or slopes of less than unity. We present such examples of modified hemoglobins and strong effectors in this study and calculate at which substate level the two-state model differs from the data. Analysis of hemoglobin oxygen equilibrium curves is reconsidered using the two-state model extended to allow variation of the individual substate probabilities. In this way the effect on the equilibrium due to perturbations in energy of each substate can be studied as a diagnostic tool.     

Intrinsic fluorescence of carp hemoglobin: a study of the R----T transition

The intrinsic fluorescence of hemoglobins is known to respond to ligand-induced changes in the quaternary structure of the protein. Carp hemoglobin is an interesting model to study the quaternary transition since its R----T equilibrium is pH-dependent and at low pH, in the presence of organic phosphate, it remains in the T or 'deoxy' quaternary structure, even when saturated with ligand. In this study, using front-face fluorometry, we show that the intrinsic fluorescence intensity exhibited by carp carboxyhemoglobin increases as the pH is lowered below 6.5 in the presence of inositol hexaphosphate. At low pH, carp methemoglobin is less affected by the addition of inositol hexaphosphate than is the CO derivative, while little or no change is observed in the met-azide derivative. We conclude: (1) the exact nature of the R to T state transition induced by inositol hexaphosphate differs for carp carboxy-, met- and met-azide hemoglobin derivatives; (2) the chromophores responsible for the changes observed with absorption spectroscopy may not be the same as those chromophores responsible for the fluorescence differences; and (3) alpha 46-Trp is tentatively assigned as one source of fluorescence emission. Furthermore, fluorescence properties of carp hemoglobin are compared to those of human hemoglobin.     

Properties of carboxymethylated cross-linked hemoglobin A

The selective carboxymethylation of the N-terminal amino groups of hemoglobin A with glyoxylic acid and sodium cyanoborohydride has been studied as a function of the state of ligation of hemoglobin. The N-terminal residues have been established as the primary sites of reaction by peptide mapping of the tryptic digest of each chain and subsequent amino acid analysis of the modified peptides. With oxyhemoglobin, the desired derivatives with a carboxymethyl group at the N-terminal of either or both chains amounted to 55% [Di Donato, A., Fantl, W. J., Acharya, A. S., & Manning, J. M. (1983) J. Biol. Chem. 258, 11890-11895]. In the present study it is shown that with deoxyhemoglobin the amount of the desired derivative is increased to 75%. The oxygen equilibrium curve of hemoglobin A carboxymethylated on its four N-terminal residues [0.5 mM as tetramer in 50 mM [bis(2-hydroxyethyl)amino]tris(hydroxymethyl)methane (Bis-Tris), pH 7.5, 37 degrees C] had a P50 value of 30 mmHg (Hill coefficient n = 2.8, alkaline Bohr value = 0.4) compared to a P50 of 9 mmHg for unmodified hemoglobin under the same conditions (n = 2.5, alkaline Bohr value = 0.5). In carboxymethylated oxyhemoglobin A, cross-linked with the mild agent glycolaldehyde for 3.5 h, there was 85% of Mr 64,000 species and 15% of Mr 128,000 or higher species. For the former, the extent of cross-linking between two subunits was 19%. For the latter, there was 29% of two cross-linked subunits and 13% of three cross-linked subunits. Termination of cross-linking, which may be desirable in some circumstances, can be successfully achieved with isonicotinic acid hydrazide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multiplicity of interactions between dromedary hemoglobin and solvent components. A structural and functional study

The interaction of dromedary hemoglobin with various solvent components [2-(p-chlorophenoxy)-2-methylpropionic acid (CFA), 2,3-bisphospho-D-glycerate (glycerate-2,3-P2) and chloride] has been studied. 1. CFA greatly lowers the oxygen affinity of dromedary hemoglobin. 2. The oxygen-linked CFA binding sites are probably located in the deoxy derivative at the alpha cleft, while in the oxy form and in the presence of two other effectors (glycerate-2,3-P2 and chloride) additional, structurally and possibly functionally relevant binding site(s) should be considered. 3. Both CFA and glycerate-2,3-P2 stabilize the deoxy-like tertiary structure in the oxy derivative. 4. Chloride appears to be fundamental to obtain quaternary structural changes. 5. Interaction energy, retained in the protein when the three ligands (CFA, glycerate-2,3-P2 and chloride) are bound to the oxy form, favours intermediates not stable if only one or two allosteric effector(s) is (are) present on the protein. 6. The oxygen affinity appears to be related to both tertiary and quaternary structural changes, while cooperatively is largely invariant with solvent conditions. In conclusion, the functional properties of dromedary hemoglobin do not depend in any simple way on the variety of stabilized conformations.     

Limited synthesis of labile hemoglobin A1 in vivo and in vitro by the preexisting hemoglobin A1 in diabetic subjects

The synthesis of labile hemoglobin A1 in vivo was studied in subjects with non-insulin dependent diabetes mellitus, impaired and normal glucose tolerance. The labile hemoglobin A1 index defined as delta labile hemoglobin A1 divided by delta plasma glucose at 30 min after oral glucose load, representing the rate of labile hemoglobin A1 synthesis in vivo, was low in diabetic subjects and high in normal subjects, showing an inverse correlation with the amount of preexisting hemoglobin A1. The study on the synthesis of labile hemoglobin A1 in vitro showed a lower initial rate of synthesis and a smaller increase in labile hemoglobin A1 at saturation in red blood cells from diabetic subjects with a relatively large amount of preexisting hemoglobin A1, as opposed to red blood cells from normal subjects. Although the further study is necessary in which delta plasma glucose levels are kept relatively constant in each of 3 groups by glucose-clamp methods, our data suggest that the synthesis of labile hemoglobin A1 is limited in vivo and in vitro in diabetic subjects by the preexisting hemoglobin A1 due to the saturability of its synthesis.     

Interaction of chlorpromazine with hemoglobin

Binding of chlorpromazine (CPZ), a widely used antidepressant tranquilizer, with hemoglobin has been studied by equilibrium dialysis method. r/Cf versus r plot was typically concave downwards revealing the positive cooperative nature of binding. Binding parameters, namely the affinity constant (K) and the degree of cooperativity (nH) were determined from the Hill plot. Oxygen was found to be released gradually from hemoglobin with gradual addition of CPZ, the extent of oxygen release depending on the stoichiometric ratio of CPZ: hemoglobin (D/P).     

Adduct formation between hemoglobin and 5-deoxy-D-xylulose-1-phosphate

5-deoxy-D-xylulose-1-phosphate, which is formed in human erythrocytes from added acetaldehyde and endogenous dihydroxyacetone phosphate, reacts with hemoglobin Ao to form an adduct that is stable to repeated precipitation by trichloracetic acid and to prolonged dialysis against dilute phosphate buffer. Formation of this hemoglobin derivative in individuals who consume alcohol would serve to integrate the blood acetaldehyde concentration and thereby reflect a dose-time record of alcohol consumption.     

Stabilization of the T-state of human hemoglobin by proflavine, an antiseptic drug.

The effect of proflavine (3,6-diaminoacridine), an antiseptic drug, on the spectroscopic and oxygen binding properties of ferrous human adult hemoglobin (Hb) has been investigated. Upon binding of proflavine to the nitric oxide derivative of ferrous human adult hemoglobin (HbNO), the X-band EPR spectrum displays the characteristics which have been attributed to the T-state of the ligated tetramer. In parallel, oxygen affinity for the deoxygenated derivative of ferrous human adult Hb decreases in the presence of proflavine. The effect of proflavine on the spectroscopic and ligand binding properties of ferrous human adult Hb is reminiscent that of 2,3-D-glycerate bisphosphate, the physiological modulator of Hb action.     

Improved production of human hemoglobin in yeast by engineering hemoglobin degradation

With the increasing demand for blood transfusions, the production of human hemoglobin (Hb) from sustainable sources is increasingly studied. Microbial production is an attractive option, as it may provide a cheap, safe, and reliable source of this protein. To increase the production of human hemoglobin by the yeast Saccharomyces cerevisiae, the degradation of Hb was reduced through several approaches. The deletion of the genes HMX1 (encoding heme oxygenase), VPS10 (encoding receptor for vacuolar proteases), PEP4 (encoding vacuolar proteinase A), ROX1 (encoding heme-dependent repressor of hypoxic genes) and the overexpression of the HEM3 (encoding porphobilinogen deaminase) and the AHSP (encoding human alpha-hemoglobin-stabilizing protein) genes — these changes reduced heme and Hb degradation and improved heme and Hb production. The reduced hemoglobin degradation was validated by a bilirubin biosensor. During glucose fermentation, the engineered strains produced 18% of intracellular Hb relative to the total yeast protein, which is the highest production of human hemoglobin reported in yeast. This increased hemoglobin production was accompanied with an increased oxygen consumption rate and an increased glycerol yield, which (we speculate) is the yeast's response to rebalance its NADH levels under conditions of oxygen limitation and increased protein-production.     

Synthesis and properties of an organophosphorous regulator of hemoglobin oxygenation

Racemic 1-O-(epsilon-aminohexanoyl)-2,3-diphosphoglycerol (ADPG) was synthesized. The pH dependence of the 31P-NMR spectra was studied for the ADPG cyclohexylammonium salt. ADPG binding to hemoglobin and its functional activity as a regulator of human hemoglobin reversible oxygenation were assayed.     

Transport of gases through hemoglobin solution

A mathematical theory is developed to explain the observed enhancement of O₂ transport through solutions by hemoglobin. At high partial pressures of O₂, ordinary diffusion through the solvent accounts for all transport of O₂, but at low partial pressures the transport may be increased manyfold by the presence of hemoglobin. This phenomenon is explained and its possible role in living organisms is discussed. The theory also indicates a new method of determining dissociation curves from diffusion experiments.     

Reactions of para-substituted nitrosobenzenes with human hemoglobin

Bio-monitoring the covalent binding of nitrosoarenes to the SH groups of human hemoglobin has been proposed as a reliable approach to get an integral parameter for exposure control and possibly risk assessment of persons exposed to aromatic amines and nitro compounds. Availability of nitrosoarenes to bind to the cysteine residues is greatly influenced by the competition of hemoglobin iron with nitrosoarenes. In contrast to earlier reports, we found that nitrosobenzene has a 14 fold higher affinity for "stripped" human hemoglobin than oxygen. The binding mode is similar to gaseous ligands and exhibits the same free energy of cooperation and sensitivity to heterotropic effectors like inositol hexaphosphate. To elucidate the electronic influence of para substituents, 4-chloronitrosobenzene, 4-nitrosotoluene and 4-nitrosophenetole were tested. A linear free energy relationship was found for all equilibrium parameters with a reaction constant rho = 3, when using Hammett sigma p constants. Similarly, the apparent second order rate constants for binding of para-substituted nitrosobenzenes to the cysteine residues (Cys beta 93) in hemoglobin followed the Hammett relationship with lg k-lg k0 = 1.7 X sigma p (r2 = 0.99). In case of 4-chloronitrosobenzene covalent binding proceeded biphasically and a "semimercaptal"-like intermediate was observed. The affinities for hemoglobin iron and for the SH groups were highest with 4-chloronitrosobenzene and lowest with 4-nitrosophenetole. All nitrosobenzenes were capable to produce ferrihemoglobin. In the absence of oxygen, 4-chloronitrosobenzene hemoglobin decayed with formation of ferrihemoglobin. Presumably the nitroxide radical anion is formed as an intermediate which comproportionates into the azoxy derivative. It is assumed that the efficiency of the microscopic compartmentation of nitrosoarenes by binding to hemoglobin iron has important impacts on the toxicokinetics of these compounds.     

Studies on the heterotropic interaction of hemoglobin. I. Mass spectrometric method for determination of the pKa of the beta-146 histidine residue in human hemoglobin.

A mass spectrometric method was developed to determine pH-dependent hydrogen-deuterium exchange at the C-2 position of the imidazole ring of histidine, after converting the amino acid to the methylthiohydantoin derivative. The amount of deuterium exchange in N-acetyl-histidine estimated by the present method was confirmed to be in good agreement with that determined by NMR spectrometry. N-Acetylhistidine was deuterated at various pH's. From the amount of deuterium exchange, a pseudo-first order rate constant (kpsi) was calculated. A pKa value of 7.2 for the amino acid was obtained from the relation between kpsi and pH. This method was applied to estimate the pKa value of beta-146 histidine in human hemoglobin. Human hemoglobin deuterated at various pH's was digested with carboxypeptidase A [EC 3.4.12.2] to release the beta-146 histidine. The amount of deuterium exchange in the isolated histidine was determined to obtain kpsi. From these measurements pKa values of 7.0 for the histidine in oxyhemoglobin and of 8.2 for that in deoxyhemoglobin were found at 36.5 degrees, respectively.     

Pseudo cross-link of human hemoglobin with mono-(3,5-dibromosalicyl)fumarate

The reaction of human oxyhemoglobin with mono(3,5-dibromosalicyl)fumarate, produces a derivative specifically acylated at the two lysines beta 82, which can be purified with a 70% yield. The oxygen affinity of this derivative at 37 degrees C at pH 7.4, 0.1 M Cl- is of 12 mm Hg, and is not affected by organic phosphate. In the presence of 5% CO2, the oxygen affinity decreases to 25 mm Hg. In all cases the cooperativity is lowered, with a value of n in the Hill plots near 2. Sedimentation velocity measurements indicate that, contrary to normal hemoglobin, this derivative fails to dissociate into dimers upon exposure to pH 5.5. The stability of the tetrameric structure is probably due to a modification of the beta-beta interface, resulting from electrostatic and hydrophobic interactions introduced in the beta cleft by the fumaryl residues. These new interactions are probably the origin of a new reverse Bohr effect group at alkaline pH. Consistent with the stabilization of the tetrameric structure, the half-time of retention of this compound in the rat is increased 4-fold with respect to that of normal hemoglobin. These characteristics cast a favorable light on the usage of this compound as an oxygen carrier in transfusional and perfusional fluids.     

Quantitative determination of hemoglobin A1c by thin-layer isoelectric focusing

A method for the quantitation of hemoglobin A₁c using isoelectric focusing is reported.Hemolysates were prepared and stabilised with carbon monoxide and with potassium cyanide before the quantitation. The two preparations gave identical results. The potassium cyanide method is simple and adequate for routine purposes, but the cyanohemiglobin compound remains stable for one week only. The carbon monoxide method is more laborious, but the carboxyhemoglobin derivative remains stable for up to one year.Quantitations of the separated fractions emerging after isoelectric focusing were made with spectrophotometry or with densitometry. No significant difference in the results could be shown. Reproducibility tests were improved by introducing transferrin as an internal standard.The specificity of the method was checked by the in vitro addition of oral hypoglycemic drugs and of insulin.     

Arenicola marina extracellular hemoglobin: a new promising blood substitute

The need to develop a blood substitute is now urgent because of the increasing concern over Europe's BSE outbreak and the worldwide HIV/AIDS epidemic, which have cut blood supplies. Extracellular soluble hemoglobin has long been studied for its possible use as a safe and effective alternative to blood transfusion, but this has met with little success. Clinical trials have revealed undesirable side effects-oxidative damage and vasoconstriction-that hamper the application of cell-free hemoglobin as a blood substitute. We have addressed these problems and have found a new promising extracellular blood substitute: the natural giant extracellular polymeric hemoglobin of the polychaete annelid Arenicola marina. Here we show that it is less likely to cause immunogenic response; its functional and structural properties should prevent the side effects often associated with the administration of extracellular hemoglobin. Moreover, its intrinsic properties are of interest for other therapeutic applications often associated with hemorrhagic shock (ischemia reperfusion, treatment of septic shock and for organ preservation prior to transplantation). Moreover, using natural hemoglobin is particularly useful since recombinant DNA techniques could be used to express the protein in large quantities.