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.     

Spot hemoglobin. Studies on the Root effect hemoglobin of a marine teleost.

The Spot, Leiostomus xanthrus, has a single tetrameric hemoglobin. Structural studies indicate the presence of alpha- and beta-like chains with COOH-terminal sequences of --Arg and --TYR-His, respectively, the same as is found in human hemoglobin. Spot hemoglobin possesses a Root effect: a heterotropic control mechanism like the Bohr effect but with more extreme pH dependence in the equilibria and kinetics of O2 and CO binding. The Root effect seems to be a molecular adaptation, in that pH- and anion-sensitive hemoglobins may help fish achieve neutral buoyancy by facilitating O2 delivery to the swim bladder. Changes in the kinetics of both "on" and "off" processes contribute to the greatly decreased ligand affinity of Spot hemoglobin at low pH. The time course ofligand combination at low pH is biphasic and wavelength dependent, suggesting a differential effect of pH on the alpha- and beta-like chains. The change in the shape of the ligand-binding curve with pH may be interpreted in terms of a proton-dependent transition between low (T) and high (R) affinity conformations. However, this may not be the only mechanism, since differential pH effects on the two types of chains may also contribute to the observed pH dependence.     

Oxygen equilibria of hemoglobin A and hemoglobin S valency hybrids.

Oxygen equilibrium determinations with “unsymmetrical” MetHb/Hb hybrids derived from human hemoglobins A and S are reported. All four of the possible hybrids have higher oxygen affinity than the parent hemoglobins. The α₂^Metβ₂^S hybrid has a lower oxygen affinity than that of α₂^Metβ₂^S. However, both the β^Met hybrids have similar oxygen affinity. The Bohr value of α₂^Metβ₂^S is more negative than that of α₂^Metβ₂^A while the β^Met hybrids appear to have almost identical Bohr values. These findings favor the view that α and β chains in hemoglobin A have different conformations and indicate that hemoglobin S has a β-chain conformation different from that of β-chain of hemoglobin A. This difference is probably carried into the oxygenation properties of the α-chain in such a way as to be reflected only when the β chain is oxidized.     

Specifically carboxymethylated hemoglobin as an analogue of carbamino hemoglobin. Solution and X-ray studies of carboxymethylated hemoglobin and X-ray studies of carbamino hemoglobin

Hemoglobin can be specifically carboxymethylated at its NH2-terminal amino groups (i.e. HbNHCH2COO-) to form the derivatives alpha 2Cm beta 2, alpha 2 beta 2Cm, and alpha 2Cm beta 2Cm, where Cm represents carboxymethyl. Previous studies (DiDonato, A., Fantl, W. J., Acharya, A. S., and Manning, J. M. (1983) J. Biol. Chem. 258, 11890-11895) suggested that these derivatives could be used as stable analogues of the corresponding carbamino (Hb-NHCOO-) forms of hemoglobin, adducts that are generated reversibly in vivo when CO2 combines with alpha-amino groups. In this paper we present x-ray diffraction studies of both carbamino hemoglobin and carboxymethylated hemoglobin that verify this proposal and we use the carboxymethylated derivatives to study the functional consequences of placing a covalently bound carboxyl group at the NH2 terminus of each hemoglobin subunit. Our studies also provide additional information concerning the oxygen-linked binding of anions and protons to Val-1 alpha. Difference electron density analysis of deoxy alpha 2Cm beta 2Cm versus the unmodified deoxyhemoglobin tetramer (deoxy alpha 2 beta 2) shows that the covalently bound carboxyl moieties replace inorganic anions that are normally bound to the free NH2-terminal amino groups in crystals of native deoxyhemoglobin grown from solutions of concentrated (2.3 M) ammonium sulfate. In the case of the beta-subunits, the carboxymethyl group replaces an inorganic anion normally bound between the alpha-amino group of Val-1 beta, the epsilon-amino group of Lys-82 beta, and backbone NH groups at the NH2-terminal end of the F'-helix. In the case of the alpha-subunits, the carboxymethyl group replaces an anion that is normally bound between the alpha-amino group of Val-1 alpha and the beta-OH group of Ser-131 alpha. A corresponding difference electron map of carbamino deoxyhemoglobin in low-salt (50 mM KCl) crystals shows that CO2 bound in the form of carbamate occupies the same two anion binding sites. The alkaline Bohr effect of alpha 2Cm beta 2 is only marginally lower (approximately 7%) than that of alpha 2 beta 2. Previous studies (Kilmartin, J. V., 1977) have shown that about 30% of the alkaline Bohr effect is the result of an oxygen-linked change in the pK alpha of Val-1 alpha, and O'Donnell et al., 1979, found that this portion of the Bohr effect is the result of the oxygen-linked binding of chloride to Val-1 alpha.(ABSTRACT TRUNCATED AT 400 WORDS)     

The hemoglobins of Artemia salina. V. Genetic variation in hemoglobin 1, hemoglobin 2, and hemoglobin 3

Electrophoretic mobilities of three hemoglobins (Hb1, Hb2, and Hb3) were studied in 15 populations of brine shrimps. Genetic segregation data support the model that Hb2 contains n -polypeptides and n -polypeptides; Hb1 contains 2n -polypeptides. Hb3 contains neither - nor -polypeptides. There is no evidence of linkage of and loci with each other or with the locus (or loci) which governs Hb3 or with the nonhomologous portion of the sex chromosomes. Hemoglobins of different populations may be hybridized in vitro by incubation at high temperature. Reversible dissociation to subunits which contain only one ( or ) polypeptide occurs at 40 C (for Hb1) and at 50 C (for Hb2).Supported by Grant HD-11445 from the National Institutes of Health.     

Mouse hemoglobin during gestation. Absence of fetal hemoglobin

A "fetal hemoglobin' has been reported to exist during mouse gestation, Investigations using CMC chromatography, starch gel electrophoresis or isoelectric focusing have shown a hemoglobin band from fetal tissues, and blood was obtained which was different from the adult hemoglobin and designated a "fetal hemoglobin'. In the current study isoelectric focusing was used to study the hemoglobins existing in the tissues and blood during fetal and neonatal development and the results suggest there is no "fetal hemoglobin' present during gestation. It appears that the hemoglobin designated as "fetal' in our laboratory was a methemoglobin formed by an incomplete reaction of KCN with the hemoglobin. The additional hemoglobin bands which were obtained from fetal liver or neonatal spleen tissues appeared to be a modified adult hemoglobin.     

The hemoglobins of Artemia salina. IV. A model for genetic control of hemoglobin 1, hemoglobin 2, and hemoglobin X

Two loci account for all genetic variation resulting in difference in electrophoretic mobility in three hemoglobins (Hb1, Hb2, and HbX) in the hemolymph of the brine shrimp. Four alleles and nine alleles have been studied. In shrimps of all genotypes and in electrophoresis in media with varying degrees of molecular sieving, Hb2 is approximately equidistant from Hb1 and HbX. A shrimp heterozygous at both loci has a three-banded Hb1, a four-banded Hb2, and a three-banded HbX. We conclude that Hb2 contains n -polypeptides and n -polypeptides. Hb1 contains 2n -polypeptides. HbX contains 2n -polypeptides. During electrophoresis, the three native hemoglobins undergo reversible dissociation to n subunits. Subunits with the same charge reassemble to migrate as molecules of the same size as the native molecules. Although there is no evidence for an additional polypeptide in the three hemoglobins, we cannot exclude such a possibility. If it exists, it is under three constraints: (1) it must be present in equal amounts in each of the three hemoglobins; (2) it must have the same molecular weight as the - and -polypeptides; and (3) it must be free of genetic variation (detectable by electrophoresis).Supported by National Institutes of Health Grant HE-11445.     

Blood pressure changes after intravenous administration of cell-free hemoglobin A and hemoglobin H in the rat.

Hemoglobin H (HbH) is a tetramer of four beta chains (present in erythrocytes of alpha thalassemia), whereas hemoglobin A is a tetramer of two alpha and two beta chains. Since HbH is known to bind four times more nitric oxide (a vasodilator) at its sulfhydryls compared to HbA, the present studies were conducted to see the effect of HbH and HbA on rat blood pressure. The acute administration (20-2000 nmol/kg) of both HbH and HbA produced a dose-dependent effect on blood pressure. The net change in mean arterial pressure was significantly higher with HbH compared to HbA. Partially nitrosylated (in which SH groups are occupied with NO) HbH retained the property of raising blood pressure to some extent while HbA lost this property. Completely nitrosylated (in which both heme and SH groups are occupied with NO) derivatives of both HbH and HbA reduced the blood pressure to the same extent. The preliminary studies with chronic administration of HbA and HbH resulted in nonsignificant increase in blood pressure. It is concluded that these findings may explain the earlier observations of increased risk of hypertension in individuals with alpha thalassemia.     

Covalent binding of glutathione to hemoglobin. I. Inhibition of hemoglobin S polymerization

Thiol reagents react with cysteine beta 93 of hemoglobin and as a result increase the oxygen affinity of hemoglobin. In the present studies we have used a thiol-disulfide exchange between mixed disulfides of hemoglobin and reduced glutathione to attach intracellular glutathione to hemoglobin and to study its antisickling properties. The rates of production of glutathionyl hemoglobin (G-Hb) depend on the structure of the thiol reagent linked to cysteine beta 93. Up to 25% G-Hb can be produced in normal and sickle red cells because of the high intracellular concentration of reduced glutathione. This high level of G-Hb in normal cells increases the oxygen affinity by about 35% and reduces heme-heme interactions. In sickle cells the increased oxygen affinity is associated with an inhibition of sickling of about 70% at 21 mm Hg. Inhibition of polymerization of deoxy HbS is also due to a direct inhibition of intermolecular contacts in the fibers as demonstrated by the increased solubility and the increased delay time of G-HbS compared to deoxy HbS.     

Conformation and cooperativity in hemoglobin.

19-F and 31-P nuclear magnetic resonance (NMR) spectroscopy have been used to study the ligand binding process in human hemoglobin. 19-F nuclear magnetic resonance studies of hemoglobin specifically trifluoroacetonylated at cysteine-beta93 have permitted observation and characterization of molecular species containing two and three ligands. The behavior of these intermediate species in response to changes in pH and organic phosphate concentration is not completely consistent with any of the current theories of allostery. A model consistent with the 19-F and 31-P NMR data is proposed.     

Structural analysis of polymers of sickle cell hemoglobin. II. Sickle hemoglobin macrofibers

Sickle cell hemoglobin macrofibers are an important intermediate in the low pH crystallization pathway of deoxygenated hemoglobin S that link the fiber to the crystal. Macrofibers are a class of helical particles differing primarily in their diameters but are related by a common packing of their constituent subunits. We have performed three-dimensional reconstructions of three types of macrofibers. These reconstructions show that macrofibers are composed of rows of Wishner-Love double strands in an arrangement similar to that in the crystal. We have measured the orientation and co-ordinates of double strands in macrofibers using cross-correlation techniques. In this approach, the electron density projections of double strands calculated from the known high-resolution crystal structure are compared with regions along the length of the particles in which the distinct pattern of double strands in c-axis projection may be observed. Contrary to assertions by Makinen & Sigountos (1984), our results unambigously demonstrate that adjacent rows of double strands in macrofibers are oriented in an antiparallel manner, as in the Wishner-Love crystal. Adjacent rows of antiparallel double strands are displaced along the helical axis relative to their co-ordinates in the crystal. Electron density models of macrofibers based on the crystallographic structure of the sickle hemoglobin double strand are in good agreement with the projections of macrofibers observed in electron micrographs. We have studied the structure of a closely related crystallization intermediate, the sickle hemoglobin paracrystal. The arrangement of double strands in paracrystals is similar to that in Wishner-Love crystals, except that they are displaced along the a-axis of the crystal. Measurements of the double strand co-ordinates reveal that the distribution of strand positions is bimodal. These results further establish the close structural relationship between macrofibers and paracrystals as intermediates in the crystallization of deoxygenated sickle hemoglobin.