Analyses of In Vitro Nonenzymatic Glycation of Normal and Variant Hemoglobins by MALDI-TOF Mass Spectrometry

MALDI-TOF mass spectrometry is used here to differentiate different glycoisoforms of normal and variant hemoglobins (Hbs) in nonenzymatic in vitro glycation. Single, double, and/or multiple glycation of the α-globin, β-globin, and/or γ-globin is observed. Different glycation rates are observed for various Hbs, and the normal Hb A has the slowest rate. Although the Hb A is relatively stable upon condensation with glucose at 37°C, the variants Hb C, Hb E, Hb F, Hb Leiden, and Hb San Diego are less stable. In addition, data reveal that the number of glucose attached/Hb molecule (state of glycation) increases with longer incubation time, higher glucose concentration, and higher temperature. The pH dependence of the state of glycation is more complex and varies for different Hbs. Although pH has little effect on the state of glycation for Hb C, Hb E, and Hb Leiden, it increases for Hb A and Hb F upon changing the pH of the solution from phosphate buffer saline (pH 7.4) to carbonate buffer (pH 10). Results obtained in this study could lead to the inference that the linkage of Hbs with glucose occurs in diabetic conditions in vivo (37°C, ∼neutral pH, ∼0.007 M glucose), and the state of glycation is more severe in the individuals who carry abnormal Hbs.     

Functional properties of hemoglobin leiden (α2Aβ26 or7 Glu deleted)

Hemoglobin Leiden is an abnormal human hemoglobin in which a glutamic acid residue has been deleted from the β-chain at position 6 or 7. The α-amino groups of the β-chain N-termini in tetrameric hemoglobin A are thought to be directly involved in the binding of simple anions and organic phosphates (1). The deletion of the 4th or 5th residue of the A helix in hemoglobin Leiden shortens the N-terminus of the β-chain, and the results reported here show that the anion binding site has been affected. Hemoglobin Leiden shows a decreased response to inorganic phosphate, chloride, 2,3-diphosphoglycerate, and inositol hexaphosphate, both in equilibria and kinetics of ligand binding. Although hemoglobin Leiden shows an altered response to anions, neither the cooperativity of ligand binding nor the Bohr effect are significantly altered by the deletion. The decreased effect of cofactors seems to be due to a decrease in the strength of anion binding which may be attributed to the altered geometry of the anion binding site.     

Molecular evidences of single mutational events followed by recurrent crossing-overs in the common delta-globin alleles in the Mediterranean area

The human delta-globin gene (HBD) is one of the beta-like globin genes expressed in adults. In the Mediterranean countries the carriers of delta-thalassemia defects or Hb A2-variants are >1% and about 40/70 known alleles have been found in families with this ethnic origin. The scope of this study was to investigate the variability of the gene and of the chromosomal background in order to highlight the origin and spreading of the delta-globin gene alleles in the Mediterranean area. We carried out the characterization of the delta-globin gene alleles and of RFLP-haplotypes, SNPs and one microsatellite associated with them in 231 carriers originating principally from East Sicily. Seventeen alleles were identified, of which five were new. The chromosomes associated with mutated alleles from unrelated carriers were 158; the allele Hb A2-Yialousa accounted for about 75% of relative frequency, Hb A2-Mitsero for about 8%. The alleles were associated with RFLP 5'-haplotypes "- - - -" or "+ - + +", prevalent in the Mediterranean area, except Hb A2-Mitsero associated with the 5'-haplotype "Benin" "- - - +" and the Hb A2' associated with "+ - - +", both of African origin. Each allele showed linkage with one haplotype with these exceptions. The Hb A2-Yialousa showed heterogeneity of the 5'-haplotype in 2/58 chromosomes; the Hb A2-Mitsero showed SNPs and (A)gamma-microsatellite typical of a "Benin" haplotype found associated with the Hb C and Hb S chromosomes; the Hb A2-Yialousa (14/58 chromosomes), Hb A2-Mitsero, Hb A2-Pylos, Hb A2-Fitzroy showed heterogeneity in the 3'-haplotypes and beta-globin gene SNPs. The Hb A2-Coburg was found associated with the haplotype "+ - + +/+ +" different from that already reported "- - - -/+ -". With the exception of this last allele, the linkage of each mutation with a core of RFLPs or SNPs around or inside the delta-globin locus suggested the unicentric origin of the mutations followed by recurrent recombination events causing the chromosomal background heterogeneity.     

Increased risk of venous thrombosis by AB alleles of the ABO blood group and Factor V Leiden in a Brazilian population

Most cases of a predisposition to venous thrombosis are caused by resistance to activated protein C, associated in 95% of cases with the Factor V Leiden allele (FVL or R506Q). Several recent studies report a further increased risk of thrombosis by an association between the AB alleles of the ABO blood group and Factor V Leiden. The present study investigated this association with deep vein thrombosis (DVT) in individuals treated at the Hemocentro de Pernambuco in northeastern Brazil. A case-control comparison showed a significant risk of thrombosis in the presence of Factor V Leiden (OR = 10.1), which was approximately doubled when the AB alleles of the ABO blood group were present as well (OR = 22.3). These results confirm that the increased risk of deep vein thrombosis in the combined presence of AB alleles and Factor V Leiden is also applicable to the Brazilian population suggesting that ABO blood group typing should be routinely added to FVL in studies involving thrombosis.     

Heme redox properties of S-nitrosated hemoglobin A0 and hemoglobin S: implications for interactions of nitric oxide with normal and sickle red blood cells

S-Nitrosated hemoglobin is remarkably stable and can be cycled between deoxy, oxygenated, or oxidized forms without significant loss of NO. Here we show that S-nitrosation of adult human hemoglobin (Hb A(0)) or sickle cell Hb (Hb S) results in an increased ease of anaerobic heme oxidation, while anions cause redox shifts in the opposite direction. The negatively charged groups of the cytoplasmic domain of Band 3 protein also produce an allosteric effect on S-nitrosated Hb. Formation and deoxygenation of a SNO-Hb/Band 3 protein assembly does not in itself cause NO release, even in the presence of glutathione; however, this assembly may play a role in the migration of NO from the red blood cells to other targets and may be linked to Heinz body formation. Studies of the anaerobic oxidation of Hb S revealed an altered redox potential relative to Hb A(0) that favors met-Hb formation and may therefore underlie the increased rate of autoxidation of Hb S under aerobic conditions, the increased formation of Heinz bodies in sickle cells, and the decreased lifetime of red cells containing Hb S. A model for the interrelationships between the deoxy, oxy, and met forms of Hb A(0) and Hb S, and their S-nitrosated counterparts, is presented.     

The inhibition of hemoglobin C crystallization by hemoglobin F

We have reported that circulating CC erythrocytes containing HbO2 C crystals exhibit little or no Hb F suggesting that Hb F may inhibit the crystallization of Hb C. We report now that Hb F inhibits in vitro crystallization of HbO2 and HbCO C when compared to the effect of Hb A in a wide range of mixture proportions. For example, while HbCO C solutions form tetragonal C crystals within 25 min, no crystals form within 2 h with 30% Hb F, whereas 550 crystals/mm3 form with 30% Hb A. Furthermore, an increase in the percent of Hb A is correlated with a greater number of orthorhombic crystal formation rather than the tetragonal morphology observed with 100% Hb C. We also report that Hb A2 (containing delta chains that exhibit 10 sequence differences with beta chains) and Hb Lepore Boston-Washington (a fusion mutant of delta and beta chains that contains only six of these differences) both inhibit Hb C crystallization. By comparing the sequences of the three inhibitory hemoglobins, we conclude that position Gln-87 in the gamma chains is, at least partially, the cause of the inhibitory effect of Hb F on the crystallization of Hb C.     

Changes in the gamma chain heterogeneity of hemoglobin F of the baboon (Papio cynocephalus) postnatally and after partial switching to hemoglobin F production by various stimuli

The postnatal switch from hemoglobin (Hb) F to Hb A in the baboon (Papio cynocephalus) occurs somewhat more rapidly than in humans. Minor components which are related to Hb F and Hb A are also present and show reciprocal rise and fall. The baboon produces two types of gamma chain presumably from nonallelic genes. These have either an isoleucyl (I gamma) or a valyl (V gamma) residue in position 75. As in the human case with G gamma and A gamma chains, the ratio I gamma to V gamma chains changes during the postnatal switch. Production of Hb F in the baboon may be stimulated by phenylhydrazine or more effectively by 5-azacytidine. With phenylhydrazine, the ratio of I gamma to V gamma chains in the Hb F is the same as in the traces of Hb F in the juvenile or adult baboon. However, with 5-azacytidine, at least some of the Hb F that is produced probably has been synthesized with an I gamma to V gamma ratio that is present prenatally and in the newborn baboon.     

Multiplex PCR-RFLP assay for detection of factor V Leiden and prothrombin G20210A

Factor V Leiden and prothrombin G20210A are clinically relevant genetic risk factors for venous thrombosis. Molecular diagnostic testing for factor V Leiden and prothrombin G20210A is widespread, and laboratories use a variety of technical approaches. Here we introduce a multiplex polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) based on single (Mn/l) restriction endonuclease digestion. The assay was shown to simultaneously and accurately detect factor V Leiden and prothrombin G20210A mutations.     

Involvement of Glu G3(101)beta in the function of hemoglobin. Comparative O2 equilibrium studies of human mutant hemoglobins

The glutamyl residue at G3(101)beta of normal hemoglobin (Hb A) is one of the alpha 1 beta 2 subunit contacts which are vital to O2 binding properties of the molecule. The O2 equilibrium properties of the four mutants with different substitutions at this site are studied in order to elucidate the role of this residue. Under stripped conditions with minimum chloride the order of O2 affinity is: Hb A (Glu) much less than Hb Rush (Gln) less than or equal to Hb British Columbia (Lys) less than or equal to Hb Potomac (Asp) less than or equal to Hb Alberta (Gly). The first Adair constants, K1, for the mutant hemoglobins are greater than that for Hb A whereas the fourth, K4, are similar, indicating that the allosteric constants (L) of these mutants are greatly reduced. Therefore, the G3(101)beta residue contributes intrinsically to the strengthening of the structural constraints that are imposed upon the deoxy (T) forms but not the oxy (R) form. On addition of 0.1 M Cl- and further addition of 2,3-diphosphoglycerate or inositol hexaphosphate, their O2 affinities and cooperativities are altered, reflecting different responses to anionic ligands. Hb Rush exhibits a stronger chloride effect than Hb A and the other variants and, as a result, an increased Bohr effect and a smaller heat of oxygenation at pH 6.5. These changes are consistent with an increased positive net charge in the central cavity of Hb Rush and subsequent extra anion binding in the deoxy form. The tetramer to dimer dissociation constants are estimated to be greater than normal for Hb British Columbia and less than normal for Hb Alberta. This comparative study of the G3(101)beta mutants indicates that the size and the charge of this residue may influence the switching of two neighboring interchain hydrogen bonds that occurs during oxygenation of normal hemoglobin.     

Reactions involving superoxide and normal and unstable haemoglobins.

Superoxide ions (O2-) oxidized oxyhaemoglobin to methaemoglobin and reduced methaemoglobin to oxyhaemoglobin. The reactions of superoxide and H2O2 with oxyhaemoglobin or methaemoglobin and their inhibition by superoxide dismutase or catalase were used to detect the formation of superoxide or H2O2 on autoxidation of oxyhaemoglobin. The rate of autoxidation was decreased at about 35% in the presence of both enzymes. The copper-catalysed autoxidation of Hb (haemoglobin) was also shown to involve superoxide production. Superoxide was released on autoxidation of three unstable haemoglobins and isolated alpha and beta chains, at rates faster than with Hb A. Reactions of superoxide with Hb Christchurch and Hb Belfast were identical with those with Hb A, and occurred at the same rate. Hb Koln contrasted with the other haemoglobins in that the thiol groups of residue beta-93 as well as the haem groups reacted with superoxide. Haemichrome formation from methaemoglobin occurred very rapidly with Hb Christchurch and Hb Belfast, as well as the isolated chains, compared with Hb A. The process did not involve superoxide production or utilization. The relative importance of autoxidation and superoxide production compared with haemichrome formation in the haemolytic process associated with these abnormal haemoglobins and thalassaemia is considered.     

The solubility of sickle and non-sickle hemoglobins in concentrated phosphate buffer.

A new turbidimetric method for the direct measurement of the solubility of oxy- and deoxyhemoglobins (Hb) in concentrated phosphate buffer has been established. The principle of the method is the formation of a homogeneous emulsion when hemoglobin is introduced in concentrated phosphate buffer. The solubility of the oxy and deoxy forms of Hb A, Hb S, Hb C, Hb F, and Hb CHarlem (beta 6Glu leads to Val, beta 73Asp leads to Asn) has been studied. The solubility of deoxy-Hb S was the lowest and the solubility curve was broader than those of the other hemoglobins indicating that the aggregates of deoxy Hb S require more water to be dissolved. The solubility of oxy- and deoxyhemoglobins depends on temperature and pH. The solubility of hemoglobins is increased as the temperature is lowered and the pH is raised. The pH dependency of the solubility of deoxy-Hb S in high phosphate buffer was opposite to that of the minimum gelling concentration of deoxy-Hb S. The order of the solubility of Hb CHarlem, Hb FS, Hb AS, Hb CS, and Hb S in concentrated phosphate buffer corresponds to the order of minimum gelling concentration of these hemoglobins or hemoglobin mixtures. Solubility studies of a 1:1 mixture of deoxy-Hb A and deoxy-Hb S show that deoxy-Hb A aggregates in 2.42 M phosphate buffer in which pure deoxy-Hb A is totally soluble. This result indicates that deoxy-Hb S interacts with deoxy-Hb A and decreases its solubility.     

Protection afforded by sickle-cell trait (Hb AS): what happens when malarial selection pressures are alleviated?

A study of reproductive outcome in Mobile, AL was conducted among a large maternal cohort with sickle-cell disease (Hb SS), sickle-cell trait (Hb AS), and no hemoglobinopathies (Hb AA). It was found that mean gravidity and live births among Hb AS women were significantly higher than among Hb AA women. These findings were surprising since it is generally held that once malarial pressure is alleviated, any reproductive advantage that might be conferred by Hb AS would disappear and fertility levels would reach levels similar to or slightly less than that of Hb AA women. A search of the literature was subsequently conducted and a large cohort study of an African-derived population was found in the United Kingdom. Results from this study also showed that parity was significantly higher among Hb AS women compared to Hb AA women. If survivorship is similar among Hb AS and Hb SS women, findings from these two studies raise doubts whether directional selection is occurring against the Rb S allele in nonmalarial environments. Balancing selection may still be occurring.     

Structure and function of hemoglobin variants at an internal hydrophobic site: consequences of mutations at the beta 27 (B9) position

We have studied the structure-function relationships in newly discovered hemoglobin (Hb) mutants with substitutions occurring at the tight and highly hydrophobic cluster between the B and G helices in the beta chains, namely, Hb Knossos or beta A27S and Hb Grange-Blanche or beta A27V. The beta A27S mutant has a 50% decrease in oxygen affinity relative to native human Hb A, while the beta A27V mutant has an increased oxygen affinity. We have also engineered the artificial beta A27T mutation through site-directed mutagenesis. This new mutant exhibits functional properties similar to those of Hb A. None of these mutants is unstable. X-ray analyses show that the substitution of Val for Ala may reduce the relative stability of the T structure of the molecule through packing effects in the beta chains; for the beta A27S mutant a new hydrogen bond between serine and the carbonyl O at beta 23 (B5) Val is observed and is likely to increase the relative stability of the T structure in the mutant hemoglobin. However, no significant changes in the crystals were observed for these mutants between the quaternary R and T structures relative to native Hb A. We conclude that small tertiary structural changes in the tight hydrophobic B-G helix interface are sufficient to induce functional abnormalities resulting in either low or high intrinsic oxygen affinities.     

Glycosylated minor components of human adult hemoglobin. Purification, identification, and partial structural analysis

Human hemolysate contains several minor components designated Hb A1a, Hb A1b, Hb A1c, which are post-translational modifications of the major hemoglobin component A0. Individuals with diabetes mellitus have elevated levels of Hb A1c, a hemoglobin modified with a glucose moiety at the NH2 terminus of each beta chain. A new chromatographic technique using Bio-Rex 70 is described which not only allows complete separation of Hb A1a from Hb A1b but also resolution of Hb A1a into two components, designated Hb A1a1 and Hb A1a2. Carbohydrate determinations with the thiobarbituric acid procedure revealed that Hb A1a1, Hb A1a2, and Hb A1b as well as Hb A1c were glycosylated. Total phosphate analysis revealed 2.06 and 1.01 mol of phosphorus/alphabeta dimer for Hb A1a1 and Hb A1a2 respectively; Hb A1b and Hb A1c contained no detectable phosphate. Hemoglobin incubated with D-[14C]glucose-6-P co-chromatographs precisely with Hb A1a2, strongly suggesting that Hb A1a2 is glucose-6-P hemoglobin. Levels of Hb A1a1 and Hb A1a2 are normal in individuals with diabetes mellitus. Furthermore, diabetic red cells contain normal levels of glucose-6-P. Therefore, glucose-6-P hemoglobin does not serve as a significant precursor to Hb A1c. Instead Hb A1c is formed by the direct reaction of hemoglobin with glucose. This suggests that hemoglobin can serve as a model system for nonenzymatic glycosylation of protein.     

Stability of asymmetrical hybrid hemoglobins. Determination by anaerobic high performance liquid chromatography

Asymmetrical hybrid hemoglobins formed in mixtures of Hb A and Hb S, Hb F and Hb S, Hb S and Hb York(beta 146 His----Pro), and Hb A and Hb York were separated by high performance liquid chromatography on cation and anion exchange columns under anaerobic conditions. The ratio of the hybrid hemoglobin to the total mixture was consistently lower than that theoretically expected and decreased with longer elution times. The hybrid tetramer appears to be unstable even under anaerobic conditions and dissociates into alpha beta dimers. The time course of dissociation of the hybrid hemoglobins was determined by varying the separation programs and thus separating the hybrid hemoglobin at different elution times. The rate of the dissociation of the hybrid hemoglobins studied follows first order kinetics. The lines representing the time course of dissociation of hybrid hemoglobins were extrapolated to time 0 to determine the fraction of the hybrid hemoglobin in the mixture prior to separation. The values obtained for equimolar mixtures of Hb A and Hb S and Hb York and Hb S or Hb A were in agreement with the expected theoretical value (50%). In contrast, the value obtained for hybrid hemoglobin FS was slightly less (about 40%). AY and SY hybrid hemoglobins dissociated into dimers at a considerably faster rate than did AS and FS hybrid hemoglobins, possibly because of the mutation at the beta 146-position in hybrid hemoglobins containing alpha beta Y dimers. This mutation hinders the formation of salt bridges that normally stabilize the "T" quaternary conformation. Since such hybrid hemoglobins have a partial "R" conformation even when deoxygenated, their rate of dissociation to dimers is expected to increase.     

The Effect of Hemoglobin A and S on the Volume- and pH-Dependence of K-Cl Cotransport in Human Erythrocyte Ghosts

K-Cl cotransport is abnormally active in erythrocytes containing positively charged hemoglobins such as Hb S (SS: β6 Glu → Val) or Hb C (CC: β6 Glu → Lys). The relatively younger age of erythrocytes in these diseases cannot completely account for the increased K-Cl cotransport activity. It has been suggested that these positively charged Hb may interact with the K-Cl cotransport system or one of its regulators and induce changes in its functional activity. We report here data on the volume- and pH-dependence of K-Cl cotransport in ghosts obtained from normal and sickle erythrocytes, and on the effect of addition of either Hb A or Hb S before resealing. In erythrocyte ghosts prepared with the gel column method to contain minimal amounts of Hb, (white ghosts, WG), K-Cl cotransport has similar magnitude in normal and sickle erythrocytes, is not inhibited by alkaline pH and it is volume-independent. Addition of low concentrations of Hb A to WG from normal erythrocytes decreases the magnitude of K-Cl cotransport and restores its volume dependency, but not its pH sensitivity. Addition of Hb S to WG from either normal or sickle erythrocytes restores the volume-dependent component of K-Cl cotransport and increases the magnitude of flux mediated by this transporter. Thus, Hb A and Hb S seem to affect in different manners the functional properties of K-Cl cotransport. Received: 29 May 1998/Revised: 3 November 1998     

The X-ray structure determination of bovine carbonmonoxy hemoglobin at 2.1 A resoultion and its relationship to the quaternary structures of other hemoglobin crystal froms

Crystallographic studies of the intermediate states between unliganded and fully liganded hemoglobin (Hb) have revealed a large range of subtle but functionally important structural differences. Only one T state has been reported, whereas three other quaternary states (the R state, B state, and R2 or Y state) for liganded Hb have been characterized; other studies have defined liganded Hbs that are intermediate between the T and R states. The high-salt crystal structure of bovine carbonmonoxy (CO bovine) Hb has been determined at a resolution of 2.1 A and is described here. A detailed comparison with other crystallographically solved Hb forms (T, R, R2 or Y) shows that the quaternary structure of CO bovine Hb closely resembles R state Hb. However, our analysis of these structures has identified several important differences between CO bovine Hb and R state Hb. Compared with the R state structures, the beta-subunit N-terminal region has shifted closer to the central water cavity in CO bovine Hb. In addition, both the alpha- and beta-subunits in CO bovine Hb have more constrained heme environments that appear to be intermediate between the T and R states. Moreover, the distal pocket of the beta-subunit heme in CO bovine Hb shows significantly closer interaction between the bound CO ligand and the Hb distal residues Val 63(E11) and His 63(E7). The constrained heme groups and the increased steric contact involving the CO ligand and the distal heme residues relative to human Hb may explain in part the low intrinsic oxygen affinity of bovine Hb.     

Erythropoiesis in normal and mutant chick embryos

Hemoglobin D_Davis (Hb D_D), an autosomal codominant in chickens, the α^D-globin chain of Hb M of primitive cells and Hb D of definitive erythrocytes. Erythropoiesis and Hb synthesis was investigated in normal, heterozygous, and homozygous Hb D_D mutant embryos (stages 15–44) and adults. The time of appearance, morphology, relationships to developmental changes, and number of primitive and definitive cells were determined. Primitive hemoglobins between stages 17 and 44 showed four components, P1, P2, E, and M (or M_D), on high-resolution isoelectric focusing gels. Comparison of $\text{P1}\text{P2}$ ratios in the four phenotypes indicated that homozygous Hb D_D embryos had an increased proportion of Hb P2 relative to Hb P1 between stages 17 and 35. This difference coincided with an increase in the number of large primitive cells. In all phenotypes the proportions of primitive hemoglobins decreased after stage 25 and they were not detected after stage 40. Basophilic definitive erythroblasts were present in cell suspensions from all phenotypes between stages 24 and 25. Hb A, the major Hb and Hb D, the minor Hb, of definitive cells of embryos and adults were detected by isoelectric focusing of lysates by stage 29. Definitive cells from late embryos of all phenotypes had higher proportions of Hb D (or Hb D_D) than did red cells from corresponding adult birds. Heterozygous Hb D_D embroys and adults had both Hb D and Hb D_D. Hb D_D comprises about 30% of the total minor Hb rather than 50% expected for heterozygosity at a single locus. In this respect heterozygous Hb D_D chick embryos and adult birds are similar to certain heterozygous α-chain variants in humans. A minor Hb, H, found in lysates of later embryos disappears in lysates of normal chicks 65 days after hatching, but was present in the circulation of homozygous Hb D_D chicks until at least 195 days after hatching. Additionally, several minor Hb components which may be asymmetrical hybrids or derived precursors of Hb A and Hb D (or Hb D_D) were observed. This study provides the precise developmental stages when the switchover of erythroid cell populations and hemoglobins in the chick embryo occurs. This is the first investigation of an α-globin chain mutant which is synthesized during all stages of red cell development and may be a useful animal model for the study of hemoglobinopathies in vertebrates.     

Hemoglobin Saint Mandé [beta 102 (G4) Asn----Tyr]. Functional studies and structural modeling reveal an altered T state

Oxygen equilibrium studies of purified hemoglobin Saint Mandé (Hb SM) [beta 102 (G4) Asn----Tyr] reveal a decreased oxygen affinity and cooperativity but to a lesser extent than found for Hb Kansas (beta 102 Thr). The low affinity of Hb SM depends on environmental conditions: eliminating chloride or raising the pH greatly elevated the ratio of p50 of Hb SM to that of Hb A. The alkaline Bohr effect is reduced by about 40%. The effects of anions (chloride, organophosphates) binding to deoxy Hb SM are also reduced. These data indicate that the functional properties of Hb SM are intermediary between Hb A and Hb Kansas. In addition, molecular graphics modeling of Hb SM in the oxy and deoxy structures indicate the possibility of a new hydrogen bond in the T state between beta(1)102 Tyr and alpha(2)42 Tyr. Stabilisation of the T state in this manner is a plausible explanation for several of the effects observed.     

Cyclic nucleotides and haemoglobin concentration in rabbit bone marrow cell suspensions stimulated by purified erythropoietin

This study was conducted to determine the possible correlations between cyclic nucleotides cyclic adenosine monophosphate (cAMP) and cyclic guanine monophosphate (cGMP), and haemoglobin (Hb) concentration in nucleated cell suspensions of rabbit bone marrow incubated with erythropoietin (Ep). The levels of cAMP and cGMP were measured following the addition of different Ep concentrations to the suspensions. The Hb concentration was also measured in suspensions treated with Ep, dibutyryl cAMP (db-cAMP) or dibutyryl cGMP (db-cGMP), respectively. The following results were obtained: (1) upon the addition of 1 IU ml-1 Ep, an increase of cAMP levels was related to an increase in Hb concentration; while a decrease of Hb concentration was related to an increase of cGMP levels obtained when 0.1 IU ml-1 Ep was present in the incubation mixture. (2) A mimetic effect on Hb concentration was obtained upon the addition of db-cAMP or db-cGMP to the suspensions. (3) A quantitative correlation was found between the cAMP/cGMP ratio and Hb levels in cellular suspensions. This rapport was reviewed with respect to the controls as a decrease in Hb concentration when the ratio is less than one and an increase in Hb concentration when the ratio is greater than one.