Letter: Equilibrium and kinetic studies of hemoglobin I: a functionally silent amino acid substitution at an invariant residue;

Hemoglobin I is an uncommon hemoglobin variant in which the lysine residue at position 16 of the a chain has been replaced by glutamic acid. Lysine is the invariant residue in all myoglobin and hemoglobin subunits that have been sequenced, with the exception of the hemoglobin of the lamprey. Replacement of invariant residues is generally reflected in altered functional properties of the hemoglobin molecule and such invariance may be indicative of a unique functional role. However, a study of the oxygen equilibrium and kinetic properties of hemoglobin I showed the functional properties of this hemoglobin to be indistinguishable from those of normal adult hemoglobin.     

聚合牛血红蛋白抗原性的初步研究

对乙醇醛聚合的牛血红蛋白的抗原性进行了研究。将聚合的牛血红蛋白桉兔血量的10％和20％分别输入兔耳缘静脉,间隔7天后重复输液,共输注3次。ELISA检测未显示抗体产生。将聚合的牛血红蛋白、人血红蛋白和兔血红蛋白分别与免疫佐剂混合常规免疫家兔3次,并用上述抗原包被聚乙烯板,用ELISA方法检测抗体滴度,结果显示聚合牛血红蛋白和人血红蛋白加佐剂免疫家兔后均产生抗体,且有交叉反应,表明这两种血红蛋白有同源性,存在相似的抗厚决定簇。兔血红蛋白免疫家兔后无抗体产生,且无交叉反应,表明机体对自体蛋白有天然的耐受。     

PROTEIN COAGULATION AND ITS REVERSAL : THE REVERSAL OF THE COAGULATION OF HEMOGLOBIN

1. The preparation from completely coagulated hemoglobin of crystalline soluble hemoglobin is described. 2. This soluble hemoglobin by all the tests tried has been indistinguishable from normal native hemoglobin which has never been coagulated. 3. The coagulation of hemoglobin is probably reversible. 4. Since hemoglobin is a typical coagulable protein, protein coagulation in general is probably reversible.     

A new hemoglobin variant. HB Yatsushiro alpha 2 A beta 2 60 Val replaced by Leu

This study was performed to establish the structural abnormality of a new hemoglobin variant discover-d in a Japanese patient with angina pectoris. The hybridization of the separated hemoglobin with canine hemoglobin revealed a beta-chain anomaly. Peptide betaTp-6 was found to be abnormally located on the peptide map of tryptic digests of the S-carboxymethylated beta-chain from the variant hemoglobin. A structural study on the abnormal betaTp-6 revealed that the variant hemoglobin differs from hemoglobin A by substitution of leucine for valine at residue 60 of the beta-chain. This new variant hemoglobin is designated as hemoglobin Yatsushiro after the name of the city where the propositus lived. The patient is hematologically healthy and his clinical history has nothing to do with this abnormal hemoglobin.     

The crystal structure of bar-headed goose hemoglobin in deoxy form: the allosteric mechanism of a hemoglobin species with high oxygen affinity

The crystal structure of a high oxygen affinity species of hemoglobin, bar-headed goose hemoglobin in deoxy form, has been determined to a resolution of 2.8 A. The R and R(free) factor of the model are 0.197 and 0.243, respectively. The structure reported here is a special deoxy state of hemoglobin and indicates the differences in allosteric mechanisms between the goose and human hemoglobins. The quaternary structure of the goose deoxy hemoglobin shows obvious differences from that of human deoxy hemoglobin. The rotation angle of one alphabeta dimer relative to its partner in a tetramer molecule from the goose oxy to deoxy hemoglobin is only 4.6 degrees, and the translation is only 0.3 A, which are much smaller than those in human hemoglobin. In the alpha(1)beta(2) switch region of the goose deoxy hemoglobin, the imidazole ring of His beta(2)97 does not span the side-chain of Thr alpha(1)41 relative to the oxy hemoglobin as in human hemoglobin. And the tertiary structure changes of heme pocket and FG corner are also smaller than that in human hemoglobin. A unique mutation among avian and mammalian Hbs of alpha119 from proline to alanine at the alpha(1)beta(1 )interface in bar-headed goose hemoglobin brings a gap between Ala alpha119 and Leu beta55, the minimum distance between the two residues is 4.66 A. At the entrance to the central cavity around the molecular dyad, some residues of two beta chains form a positively charged groove where the inositol pentaphosphate binds to the hemoglobin. The His beta146 is at the inositol pentaphosphate binding site and the salt-bridge between His beta146 and Asp beta94 does not exist in the deoxy hemoglobin, which brings the weak chloride-independent Bohr effect to bar-headed goose hemoglobin.     

Reductive hydroxyethylation of the α-amino groups of amidated hemoglobin S

Val-6(β) of hemoglobin S forms the primary site of intertetrameric interaction in the polymerization of deoxy hemoglobin S. However, a number of other intermolecular interactions contribute significantly to the polymerization process as well as to the stability of the polymerized gel. The strong stabilizing influence of Val-6(β) in the polymerization process is reflected in the fact that although a number of mutations at any one of the intermolecular contact regions (or perturbation of these contact regions by chemical modification) result in some increase in the solubility of deoxy hemoglobin S, none of these mutations and/or chemical modifications completely neutralize the polymerizing influence of Val-6(β), i.e., restores the solubility to that of hemoglobin A. Additivity and/or synergy of the solubilizing influence of two or more chemical modification reactions each of which independently increases the solubility may be considered as a possible strategy to restore the solubility of deoxy hemoglobin S to that of hemoglobin A. In the present study, the cumulative solubilizing influence of amidation of Glu-43(β) and hydroxyethylation of α-amino groups of hemoglobin S has been investigated by preparing hemoglobin S with double modification. Modification of Glu-43(β) by amidation with glycine ethyl ester did not influence the reactivity of the α-amino groups of hemoglobin S toward reductive hydroxyethylation, thus permitting the preparation of hemoglobin S with the two modifications. The reductive hydroxyethylation increased the oxygen affinity of amidated hemoglobin S to nearly the same degree as it does on modification of unmodified hemoglobin. In addition, hemoglobin S with double modification has a Hill coefficient that is the same as that of unmodified hemoglobin S, suggesting that the overall quaternary interaction of hemoglobin S with a double modification is nearly the same as the unmodified protein. However, the reductive hydroxyethylation of the amidated hemoglobin S increased the solubility of the protein further. The solubility of hemoglobin S with a double modification is nearly twice that of the unmodified protein and is close to that of 1:1 mixture of hemoglobin S and hemoglobin F. The results demonstrate the additivity of the solubilizing influence of perturbing the quinary interactions at the intermolecular contact regions of deoxy hemoglobin S.     

Net charge and oxygen affinity of human hemoglobin are independent of hemoglobin concentration

The dependence of net charge and oxygen affinity of human hemoglobin upon hemoglobin concentration was reinvestigated. In contrast to earlier reports from various laboratories, both functional properties of hemoglobin were found to be independent of hemoglobin concentration. Two findings indicate a concentration-independent net charge of carbonmonoxy hemoglobin at pH 6.6: (A) The pH value of a given carbonmonoty hemoglobin solution remains constant at 6.6 when the hemoglobin concentration is raised from 10 to 40 g/dl, indicating that there is no change in protonation of titratable groups of hemoglobin: (b) the net charge of carbonmonoxy hemoglobin as estimated from the Donnan distribution of 22Na+ shows no dependence on hemoglobin concentration in this concentration range. The oxygen affinity of human hemoglobin was determined from measurements of oxygen concentrations in equilibrated samples using a Lex-O2-Con apparatus (Lexington Instruments, Waltham, Mass.). P50 averaged 11.4 mm Hg at 37 degrees C, pH = 7.2, and ionic strength approximately 0.15. Neither P50 nor Hill's n showed any variation with hemoglobin concentrations increasing from 10 to 40 g/dl.     

Benzyl alcohol alters the hemoglobin phenotype of mouse erythroleukemia cells

The hemoglobin minor/hemoglobin major ratio expressed in mouse erythroleukemia (MEL) cells grown in vitro varies according to the differentiation inducer utilized. For example, butyrate and hemin induce higher hemoglobin minor/hemoglobin major ratios than do dimethyl sulfoxide (DMSO) or hexamethylene bisacetamide (HMBA). Benzyl alcohol in non-toxic concentrations was found to markedly reduce the hemoglobin minor/hemoglobin major ratio and to moderately reduce the total hemoglobin induced by DMSO or HMBA in MEL cells, while only slightly decreasing the ratio induced by hemin or butyrate. The addition of dexamethasone (another and more potent inhibitor of the induction of hemoglobin synthesis than benzyl alcohol) to the media during HMBA induction of differentiation increased the hemoglobin minor/hemoglobin major ratio. This is similar to other "inhibitory" treatments (i.e., treatments that result in sub-optimal hemoglobin production) that have been previously reported. Therefore, although benzyl alcohol and dexamethasone both partly inhibit the induction of total hemoglobin production, they have opposite effects on the induced hemoglobin phenotype: benzyl alcohol decreases the hemoglobin minor/hemoglobin major ratio while dexamethasone increases it. The mechanism(s) of the alteration in the hemoglobin phenotype is unknown as is the mechanism of induction by any of the various inducing agents or of the inhibition of induction by any treatment. However, it appears that if the signal for the induction of hemoglobin minor is sufficiently potent (as it is during butyrate or hemin induction), it cannot be overcome by benzyl alcohol at a "non-toxic" concentration.     

Hemoglobin Richmond. Subunit dissociation and oxygen equilibrium properties.

In hemoglobin Richmond (beta102 leads to Lys), amino acid substitution has occurred at the same site as the mutation in hemoglobin Kansas (beta102 Asn leads to Thr), a variant with very low oxygen affinity. Although hemoglobin Richmond has been shown to have increased tetramer-dimer dissociation, its oxygen affinity has been inferred to be normal from studies on hemolysates of carriers. We have isolated hemoglobin Richmond and have further studied its properties. We confirm that the oxygen affinity of pure hemoglobin Richmond under conditions similar to those found in vivo is normal. However, the Bohr effect of the variant hemoglobin is markedly abnormal. Its oxygen affinity is low at high pH and high at low pH, relative to hemoglobin A. The tetramer-dimer equilibrium displays a strong pH dependence such that protons promote dissociation. A model is presented in which the structural change in hemoglobin Richmond results in low oxygen affinity, like hemoglobin Kansas. However, the close linkage between tetramer-dimer dissociation and proton concentration seen with hemoglobin Richmond results in normal oxygen affinity at intracellular pH and hemoglobin concentration, and carriers display no hematological abnormalities.     

Cobalt-substituted hemoglobin Zürich (alpha 2 beta 263His leads Arg). Oxygen equilibria and EPR spectra.

Cobalt hemoglobin Zürich (alpha 2 beta 263His leads to Arg) has been successfully reconstituted from the apohemoglobin Zürich and cobaltous protoporphyrin IX. The oxygen affinity of cobalt hemoglobin Zurich, as well as that of iron hemoglobin Zürich, were measured in the absence and presence of organic phosphate and Cl-. The overall oxygen affinity of cobalt hemoglobin Zürich was found to be higher and the cooperativity as measured by the n value was smaller than those of cobalt hemoglobin A. Organic phosphate and Cl- affect the oxygen equilibrium properties of cobalt hemoglobin Zürich in a manner similar to that of cobalt hemoglobin A, but to a lesser extant than cobalt hemoglobin A. The EPR spectrum of oxy cobalt hemoglobin Zürich is less sensitive to the replacement of the buffer system from H2O to 2H2O, indicating that the hydrogen bond between the distal amino acid residue and the bound oxygen is not formed in the abnormal beta subunits. The deoxy EPR spectrum of cobalt hemoglobin Zürich is similar to that of deoxy cobalt hemoglobin A, suggesting that the deoxy cobalt hemoglobin Zürich is predominantly in the deoxy quaternary structure (T state).     

The interaction between phosphate and protein, and the respiration of the llama, the human fetus and the horse (author's transl)

The sequence analysis of llama (Lama glama, Camelidae) hemoglobin is described. The chains were separated, cleaved by trypsin as previously described, quantitatively characterized and sequenced in the sequenator. The llama hemoglobin differs from the human hemoglobin in that it has 25 different amino acids in the alpha chain and 24 different amino acids in the beta chain. The interaction between protein and phosphate is discussed. The earlier finding that the O2 affinity of the llama hemoglobin is dependent on its content of 2, 3-bisphosphoglycerate is interpreted here as a mutation of the 2, 3-bisphosphoglycerate contact position beta2 His in human hemoglobin to beta2 Asn in llama hemoglobin, whereby one of the four 2, 3-bisphosphoglycerate contact points is interrupted. This interruption gives rise to a diminished reduction of intrinsic oxygen affinity in the hemoglobin molecule and explains, on a molecular basis, the increased oxygen affinity of the llama hemoglobin, and consequently, the high-altitude respiration of the llama. By analogy, the increased O2 affinity of human fetal hemoglobin is interpreted according to previous physiological investigations on blood and fetal hemoglobin by the inactivation of the phosphoglycerate contact point beta143 His in the adult hemoglobin by mutation to gamma 143 Ser in the fetal hemoglobin. With respect to respiration in horses (2, 3-bisphosphoglycerate contact beta2 Gln), measurement of atomic parameters show that the amido group of the glutamine is situated close enough to the 2, 3-bisphosphoglycerate oxygen to build a hydrogen bond with the phosphate. Consequently, the explanation of the low-altitude respiration of the horse lies in the fact that glutamine and histidine fulfill sterochemically an identical function.     

The process of hypoxic induction of Daphnia magna hemoglobin: subunit composition and functional properties

The process of oxygen-dependent hemoglobin induction in Daphnia magna was studied over an 11-day period of hypoxia (ambient oxygen partial pressure: 3 kPa). Along with the increase of hemoglobin concentration in the hemolymph, hemoglobin became the dominant protein fraction in gel filtration experiments using extracts of whole animals. The size of the native aggregates was constant. However, subunit composition depended on the duration of hypoxia: the pattern of predominantly expressed subunits under hypoxia deviated from that of normoxic individuals. The varying degree of hypoxic induction for different hemoglobin subunits was confirmed by autoradiography. Along with changes in hemoglobin subunit composition, oxygen affinity of the respiratory protein increased. The dynamics of the hemoglobin induction process was analysed. Newly synthesized hemoglobin can be detected within 18 h after the onset of hypoxia. A marked increase in hemoglobin concentration is evident from the third day of hypoxia, and a steady state of hemoglobin concentration is reached within 11 days. The changes of hemoglobin subunit expression in response to hypoxia form the structural basis for the observed adjustments of hemoglobin function leading to enhanced oxygen transport at low ambient oxygen concentrations.     

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.     

Differential control of the synthesis of two hemoglobin beta chains in normal mice

A fetal-to-adult switch in the proportion of the mouse minor hemoglobin is described. Although mice have no fetal hemoglobin per se, the timing of this switch in the mouse suggests that the mechanism of its control may directly parallel that of the human switch from fetal to adult hemoglobin expression. The mouse minor hemoglobin is expressed only in strains with the "diffuse" allele for the beta chain complex locus. Fetal liver cells of these mice synthesize a much greater proportion of the betaminor globin chain that do adult hematopoietic cells. Consequently, circulating fetal erythrocytes carry a high level of the minor hemoglobin containing it. By the time of birth, a lowered proportion of betaminor is synthesized in the liver. This low proportion continues to be expressed during early erythroid maturation in the adult. The fetal-to-adult switch is the first indication that in normal mice, the two beta chain loci can be expressed noncoordinately. The similarity between the patterns of the decline of the minor hemoglobin in mice and of the disappearance of fetal hemoglobin in humans suggests that the minor hemoglobin in the "diffuse" mouse may function to some degree as a fetal hemoglobin in the period between the disappearance of the embryonic hemoglobins and the time of birth.     

Iodination-Coupled Tetrazonium and Ferric Ferricya-Nide Reduction Stains for Differentiating Red Blood Cells Containing Fetal or Adult Hemoglobin

Either the iodination-coupled tetrazonium reaction or the ferric ferricyanide reduction procedure can be used to differentiate red blood cells containing fetal hemoglobin (hemoglobin F) from those containing adult hemoglobin (hemoglobin A) in blood smears. Oxalated blood is diluted with 3 parts of physiological saline, and smears are made on slides. The air-dried slides are treated with absolute ethanol for 2 min, dried, and placed in phosphate-citrate buffer of pH 3.2-3.6 for 1 min at 37°C. They are then rinsed in distilled water, and dried for storage or stained at once by either the iodination-coupled tetrazonium or the ferric ferricyanide reduction procedure. Adult hemoglobin is extracted by the buffer, so that red blood cells containing fetal hemoglobin give a much darker stain than those containing adult hemoglobin. The hemoglobin S of patients with sickle-cell anemia behaves like adult hemoglobin.     

An electrochemical study of hemoglobin in water-glycerol solutions

The effect the composition of a water-glycerol mixture has on the electrochemical properties of hemoglobin (Hb) is studied. With the increased glycerol concentrations, the peak-to-peak separation of hemoglobin is found to increase from approximately 40 to 200 mV, with the apparent standard potential of hemoglobin negatively shifted, which demonstrate that the electron-transfer activity of hemoglobin will decrease at relatively high glycerol concentrations and the oxidized state of hemoglobin will be more stable with the increasing glycerol concentrations. Meanwhile, the electrocatalytic activity of hemoglobin to hydrogen peroxide, as well as the binding of ligands or effectors to hemoglobin in the presence of glycerol, are also been investigated. Our studies indicate that glycerol will decrease the electrocatalytic activity of hemoglobin, while have little effect on the microenvironment around the heme site.     

Mouse fetal hemoglobin.

Using isoelectric focusing, a fetal hemoglobin was found in the peripheral blood of C57BL/6 fetal mouse during the 14 to 20 days gestational period. In acid-urea polyacrylamide gel the pattern of this fetal hemoglobin was different from that of the adult hemoglobin. The mouse fetal hemoglobin was differentiated from the mouse adult hemoglobin by immunodiffusion reaction. It suggests that there is a transient fetal hemoglobin in the C57BL/6 mouse during gestational age.     

Rate of nitric oxide scavenging by hemoglobin bound to haptoglobin

Cell-free hemoglobin, released from the red cell, may play a major role in regulating the bioavailability of nitric oxide. The abundant serum protein haptoglobin, rapidly binds to free hemoglobin forming a stable complex accelerating its clearance. The haptoglobin gene is polymorphic with two classes of alleles denoted 1 and 2. We have previously demonstrated that the haptoglobin 1 protein–hemoglobin complex is cleared twice as fast as the haptoglobin 2 protein–hemoglobin complex. In this report, we explored whether haptoglobin binding to hemoglobin reduces the rate of nitric oxide scavenging using time-resolved absorption spectroscopy. We found that both the haptoglobin 1 and haptoglobin 2 protein complexes react with nitric oxide at the same rate as unbound cell-free hemoglobin. To confirm these results we developed a novel assay where free hemoglobin and hemoglobin bound to haptoglobin competed in the reaction with NO. The relative rate of the NO reaction was then determined by examining the amount of reacted species using analytical ultracentrifugation. Since complexation of hemoglobin with haptoglobin does not reduce NO scavenging, we propose that the haptoglobin genotype may influence nitric oxide bioavailability by determining the clearance rate of the haptoglobin–hemoglobin complex. We provide computer simulations showing that a twofold difference in the rate of uptake of the haptoglobin–hemoglobin complex by macrophages significantly affects nitric oxide bioavailability thereby providing a plausible explanation for why there is more vasospasm after subarachnoid hemorrhage in individuals and transgenic mice homozygous for the Hp 2 allele.     

Hemoglobin transition in relation to metamorphosis in normal and isogenicXenopus

Summary Electrophoretic separation of hemoglobins of normalXenopus laevis and of isogenic animals derived from female hybrids ofXenopus laevis×Xenopus gilli revealed 5–9 components in premetamorphic larvae, and 3–4 components in adult toads. InXenopus laevis the number of larval hemoglobin components showed considerable variation, but this variation was absent in isogenic tadpoles, suggesting a genetic basis for hemoglobin polymorphism in larvae.Electrophoretic separation of larval and adult hemoglobins at different concentrations of acrylamide and treatment of these solutions with mercaptoethanol revealed that larval hemoglobin components are charge isomers, whereas adult hemoglobin was found to contain a minor dimeric component.Estimation of hemoglobin components showed that the main increase in adult hemoglobin, i.e from 30–90% of total hemoglobin, occurs within 4 weeks after completion of metamorphosis. By incroporation of³H amino acids in vivo a switch to preferential synthesis of adult hemoglobin and a corresponding decrease in larval hemoglobin production could be demonstrated during early climax stages. This suggests that thyroid hormones are involved in the hemoglobin transition. Yet chemical inhibition of the larval thyroid by thiourea resulted in a delayed but complete hemoglobin transition without morphological transformation. It is concluded that hemoglobin transition and morphological transformation of theXenopus tadpole require different concentrations of thyroid hormones.Abbreviations Hb hemoglobin - Hb_A adult hemoglobin - Hb_L larval hemoglobin