Specific antibodies to hemoglobin A1 (anti-Glu) and hemoglobin S (anti-Val) in the guinea pig: immunologic and structural correlations.

Like goats and sheep, guinea pigs can produce, in response to human sickle cell hemoglobin (beta6 Glu leads to Val), an antibody population (anti-Val) that will bind sickle cell hemoglobin but not normal hemoglobin HbA. Unlike goats and sheep, guinea pigs can produce in response to human hemoglobin A1 an antibody fraction, anti-Glu, that will not react with human sickle cell hemoglobin. These anti-Glu antibodies have been isolated by affinity chromatography and their specificity confirmed by fluorescence-quenching titrations. The sequence of the first 10 amino acids of the beta-chain of guinea pig hemoglobin has been determined. This sequence differs from those of both hemoglobin HbA and sickle cell hemoglobin by two residues, those at positions 5 and 6. This explains the similarity of the immunogenicity of this site on the two human hemoglobins when administered to guinea pigs. Both goats and sheep are identical to hemoglobin A1 at the beta-6 position.     

Interaction of triethyltin with cat hemoglobin: Identification of binding sites and effects on hemoglobin function

Binding of triethyltin to the cat hemoglobins (HbA and HbB) results in the “masking” of two of the freely reactive sulfhydryl groups (SH) within the hemoglobin tetramer. That the “masked” SH groups occur in position 13α of each α-subunit was demonstrated by the lack of labeling of cysteine 13α with [¹⁴C]N-ethylmaleimide when triethyltin is present. Studies with cat-human hybrid hemoglobins indicate that the α-subunit of the cat hemoglobins alone is involved in the formation of a complex with triethyltin. Using available data on the primary as well as three dimensional structures of animal hemoglobins, it is suggested the cysteine 13α and histidine 20α serve as axial ligands in the formation of a pentacoordinate triethyltin cat hemoglobin complex. The binding of triethyltin results in an increase in the oxygen affinity of the two cat hemoglobins.     

A comparison of the functional properties of two lepore hemoglobins with those of hemoglobin A1.

Lepore hemoglobins result from crossovers between normal beta and delta chain genes. Structural investigation of two newly discovered examples of Lepore hemoglobins revealed one of them to be structurally identical to hemoglobin Lepore Hollandia α₂^Aδ²² -x- β⁵⁰, a rarely occurring Lepore variant, while the second had the structure of hemoglobin Lepore Boston α₂^Aδ⁸⁷ -x- β¹¹⁶. Studies of the equilibrium and kinetic properties of the liganding reactions of these two Lepore hemoglobins, which differ only in three amino acid residues, and comparison of these with the known properties of hemoglobin A₁ (α₂β₂) and hemoglobin A₂ (α₂δ₂) have been carried out. A high value of n, the Hill coefficient, indicating normal heme-heme interaction, was observed in each hemoglobin along with a normal Bohr effect. However, a slight but definite increase in oxygen affinity was observed for each Lepore hemoglobin. Furthermore, kinetic studies indicated a slight but consistently increased rate of ligand combination and a somewhat decreased rate of oxygen dissociation for hemoglobins Lepore Hollandia and Lepore Boston at pH 7 and 20 °C. Apparently, the higher oxygen affinity of these Lepore hemoglobins over those of the normal hemoglobins A₁ and A₂ reflects changes of sequence that are common to both types of hemoglobin Lepore.     

Observation of allosteric transition in hemoglobin

Two conclusions have been drawn from NMR studies of mixed state hemoglobins. First the α and β subunits in hemoglobin are not equivalent in their conformational properties. Second the mixed state hemoglobin (α^IIICN β^II)₂ can take two different quaternary structures without changing the degree of ligation. One of the two structures is similar to that of deoxyhemoglobin and the other to that of oxyhemoglobin.     

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.     

Novel approach for the analysis of glycated hemoglobin using capillary isoelectric focusing with chemical mobilization

In this work, a novel CIEF methodology for the analysis of the glycated hemoglobin, HbA(1c), in dimethylpolysiloxane coated fused-silica capillaries (DB-1, 50 microm I.D., 27 cm, 0.20 microm coating thickness), using a narrow pH ampholyte mixture (4% pH 6-8:pH 3-10, 10:1, v/v) in 0.30% methylcellulose, was developed. In the focusing procedure, a 0.100-mol l(-1) phosphoric acid solution was used as anolyte and a 0.040-mol l(-1) NaOH solution was used as catholyte. During method development, two types of mobilization of the focused hemoglobins were tested: pressure and chemical mobilization. Chemical mobilization performed better, allowing the complete baseline resolution of the hemoglobin of interest, HbA(1c), from its adjacent peak, HbA, in less than 8 min. In the chemical mobilization procedure, the catholyte was replaced by a 0.040-mol l(-1) NaOH solution containing 0.080 mol l(-1) NaCl. The proposed methodology was applied to the analysis of 31 hemolysate samples and validated with respect to the selectivity, inter-assay and intra-assay precision (both migration time and hemoglobin percentage concentration). In addition, HbA(1c) determinations were compared for the CIEF method and a chromatographic standardized procedure using cation-exchanger columns (Variant, Bio-Rad), adopted in a local clinical laboratory, showing excellent correlation (r(2)=0.872, n=31). The slope was found to be statistically equal to one but the intercept differed from zero. Also the Bland-Altman plot indicates bias, implying that the CIEF method yields HbA(1c) concentration higher than the reference method. The separation of the hemoglobins HbA, HbA(2), HbF and HbA(1c) and the variants HbS and HbC was also demonstrated (8 min run). The resolving power of the proposed CIEF method allowed baseline resolution of hemoglobins with a pI difference as small as ca. 0.03, as it is the case for the pairs HbC/HbA(2) and HbA/HbA(1c).     

Differential resistance to calcium-induced bilirubin-dependent hemolysis in mammalian erythrocytes

Washed erythrocytes from human, buffalo, sheep and goat preincubated with different concentrations of calcium chloride (16.7–1830 μM) showed significantly different rates of hemolysis (up to 62%) after addition of bilirubin (72 μM). Goat erythrocytes displayed marked resistance to hemolysis with only 11% hemolysis observed at the highest calcium concentration. Similar trend in hemolysis was also observed when the concentration of CaCl₂ was fixed (330 μM) and bilirubin concentration varied (0–72 μM). (Ca²⁺–Mg²⁺)-ATPase levels were found significantly lower in goat and sheep erythrocyte membranes compared to human and buffalo erythrocyte membranes. This was correlated well with the observed hemolysis in various mammalian erythrocytes.     

Studies on avian erythrocyte metabolism. Effect of organic phosphates on oxygen affinity of embryonic and adult-type hemoglobins of the chick embryo.

The effects of 2,3 diphosphoglyceric acid (2,3-DPG), adenosine triphosphate (ATP), and inositol hexaphosphate (IHP) on the oxygen affinity of whole “stripped” hemoglobin (WSH), hemoglobin H (Hb-H), hemoglobin A (Hb-A) and hemoglobin D (Hb-D) isolated from 18-day chick embryo blood have been determined. The effect of the three organic phosphates upon the oxygen dissociation curves is similar and the following order of decreasing oxygen affinity of the organic phosphates was observed for each hemoglobin: 2,3-DPG < ATP < IHP. 2,3-DPG appears to have a slightly greater effect upon the P₅₀ of Hb-H than upon that of either of the two adult-type hemoglobins. However, this effect seems insufficient to suggest a preferential interaction of 2,3-DPG with Hb-H which would account for either the large amounts of 2,3-DPG in the erythrocytes of embryos or the higher oxygen affinity of the whole blood. The effects of the organic phosphates upon the Hill constant of the purified hemoglobins are variable. It is concluded that since the distribution of hemoglobins H, A, and D in the erythrocytes during the developmental period from 18-day embryos to 6-day chicks remains fairly constant, the previously described progressive decrease in oxygen affinity of the whole blood during this period results from changes in the total amount and distribution of the intraerythrocytic organic phosphates.²     

Phase separation and crystallization of hemoglobin C in transgenic mouse and human erythrocytes

Individuals expressing hemoglobin C (β6 Glu→Lys) present red blood cells (RBC) with intraerythrocytic crystals that form when hemoglobin (Hb) is oxygenated. Our earlier in vitro liquid-liquid (L-L) phase separation studies demonstrated that liganded HbC exhibits a stronger net intermolecular attraction with a longer range than liganded HbS or HbA, and that L-L phase separation preceded and enhanced crystallization. We now present evidence for the role of phase separation in HbC crystallization in the RBC, and the role of the RBC membrane as a nucleation center. RBC obtained from both human homozygous HbC patients and transgenic mice expressing only human HbC were studied by bright-field and differential interference contrast video-enhanced microscopy. RBC were exposed to hypertonic NaCl solution (1.5-3%) to induce crystallization within an appropriate experimental time frame. L-L phase separation occurred inside the RBC, which in turn enhanced the formation of intraerythrocytic crystals. RBC L-L phase separation and crystallization comply with the thermodynamic and kinetics laws established through in vitro studies of phase transformations. This is the first report, to the best of our knowledge, to capture a temporal view of intraerythrocytic HbC phase separation, crystal formation, and dissolution.     

Conformational requirements for the polymerization of hemoglobin S: studies of mixed liganded hybrids

Gelation experiments with artificially formed half-liganded hybrid tetramers of hemoglobin S demonstrate that when either the α chains or the β^s chains are fixed in the cyanmet (CNmet) liganded state, gelation occurs upon deoxygenation of the ferrous chains. The minimum concentration of hemoglobin required for gelation is equivalent for both hybrids (α₂^cnmetβ₂^s and α₂β₂^scnmet), is considerably higher than the concentration required to gel deoxy-Hb S (α₂β₂^s), and can be restored to the lower minimum gelling point of α₂β₂^s by reduction of the CNmet chains with dithionite. These results suggest that the most important conformational determinant of the deoxy state for polymerization of Hb S is the quaternary deoxy structure rather than the tertiary structural effect of the ligand state of the α or the β^s chains, and are furthermore consistent with the notion that asymmetric deoxy-CNmet hybrid tetramers assume a conformation which resembles, but is not identical to that of deoxyhemoglobin.The results of gelation experiments with mixtures of hemoglobins S and A in which selected chains of one or both hemoglobins are in the CNmet form support the concept that certain non-S hemoglobins may participate in the sickling process by forming hybrid tetramers with Hb S (such as α₂β^aβ^s). The conformational requirement for participation of these hybrids in polymers also appears to be a quaternary deoxy-like structure.     

Evaluation of Diverse Antisera, Conjugates, and Support Media for Detecting Bradyrhizobium japonicum by Indirect Enzyme-Linked Immunosorbent Assay

We evaluated three antisera and four enzyme conjugates for the detection of Bradyrhizobium japonicum by an indirect enzyme-linked immunosorbent assay in microtiter plates. Nitrocellulose membrane sheets were then evaluated as an alternative support medium by using some combinations. Partially purified immunoglobulin G (IgG) or unpurified antisera to strain USDA 110 raised in rabbits, goats, or sheep was reacted in microtiter plates with alkaline phosphatase conjugated to protein A, goat anti-rabbit (GAR), sheep anti-rabbit (SAR), or rabbit anti-goat (RAG) IgG. Cultures or nodules containing homologous rhizobia were detected with equal sensitivity when protein A, GAR, or SAR was reacted with 5 μg of protein IgG per ml or a 1:800 titer of antisera from rabbits, but not goats or sheep. RAG reacted with IgG or antisera from goats or sheep. The detection limit was 2 × 10⁵ rhizobia per well. Rhizobia were spotted on nitrocellulose sheets as an alternative support medium, followed by soaking in 5 μg of protein per ml as IgG and 1:4,000 dilutions of protein A or GAR conjugate. Rhizobia in serogroup 110 were detected with the dye combination Nitro Blue Tetrazolium-5-bromo-4-chloro-3-indolyl phosphate (NBT-BCIP), and rhizobia in serogroup 122 were detected with fast red-naphthol phosphate (FR-NP). At the conclusion of the 5-h assay, purple (NBT-BCIP) or red (FR-NP) spots were visible in positive reactions. The sensitivity of detection was about 1,000 rhizobial cells or 3 μg of nodules tissue.     

The metamorphic switch in hemoglobin phenotype ofXenopus laevis involves erythroid cell replacement

Summary To elucidate the cellular basis of hemoglobin transition inXenopus laevis the distribution of larval and adult hemoglobins was analyzed by indirect immunofluorescence in the circulating erythrocytes during metamorphosis. In addition, the morphological characteristics as well as the capacity for synthesis of DNA and hemoglobin in the erythrocytes were followed during the same developmental period. Our quantitative analysis on the distribution of larval and adult hemoglobins suggests that they are localized in different cells. Hemoglobin transition, therefore, most likely reflects replacement of the larval erythrocyte population by new cells which are committed to adult globin synthesis. Since hemoglobin transition is not accompanied by an increase in the abundance of immature erythroid cells with active DNA synthesis, we assume that the presumptive adult erythroid cells are released into circulation at a relatively advanced stage of maturation. The decline in the synthesis of DNA and larval hemoglobin further indicates that cessation of cell renewal in the larval erythrocyte population may represent a decisive step in hemoglobin transition.     

Characterization of hemoglobin from Phoronis architecta (phoronida)

• 1.1. Phoronis architecta hemoglobin is composed of four distinct hemoglobin subunits with minimum MW's of 16–17,000 or 17–19,000 daltons. All four hemoglobins are monomeric when oxygenated. Two of the monomers combine to form dimers when bound with carbon monoxide.
• 2.2. In cellulo, Phoronis architecta hemoglobin has a half-saturation (P₅₀) value of 1.3 ± 0.1 mm Hg, shows cooperative oxygen binding (Hill coefficient = 2.7 ± 0.3), and no Bohr effect from pH 6.6 to 7.9. In vitro, the hemoglobin has a P₅₀ of 0.76 ± 0.21 mm Hg but shows no cooperativity (0.90 ± 0.15 (SD)).
• 3.3. The oxygen dissociation constant (K_off) from hemoglobin is 2.7 ± 0.2 sec⁻¹, and the computed oxygen association constant (K_on) is 2.5 × 10⁶ M⁻¹ · sec⁻¹ (1.9–3.6 × 10⁶ M⁻¹ · sec⁻¹).

     

Development of in vivo somatic mutation system using antibody against hemoglobin Preparation and use of an anti-hemoglobin antibody for identifying C57BL/6 red cells in artificial mixture of DBA/2 and C57BL/6 red cells

A cellular specific-locus mutation test is described for detecting mutant cells in mammals. The test is based upon the use of specific anti-C57BL/6J mouse hemoglobin antibody that binds hemoglobin “single” (hemoglobin s, present in C57BL/6J mouse) and not hemoglobin “diffuse” (hemoglobin d, present in DBA/2J mouse). Attempts to purify such antibody from pony and rabbit antisera through cross-absorption were unsuccessful. Immunization of LP/J mouse with C57BL/6J hemoglobin produced antiserum that reacted with s hemoglobin but not with d hemoglobin. In a fluorescent antibody technique, this antibody was found to label fixed red blood cells from C57BL/6J mice but not from DBA/2J mice. In a mixture of C57BL/6J and DBA/2J red cells, the C57BL/6J cells could be differentiated by their bright fluorescence from the non-fluorescent DBA/2J cells. Reconstruction experiment with artificial mixtures of DBA/2J and C57BL/6J cells showed that s hemoglobin bearing cells could be detected in DBA/2J red cells at frequencies as small as 0.4×10^?6. Thus, the system is sensitive enough to detect d → s mutation in DBA/2J mice. Amino acid comparison of the globin chains of s and d hemoglobins shows that our antibody can probably detect mutations leading to a substitution of serine or proline by alanine at β²⁰ position and/or a substitution of threonine by alanine at β¹³⁹ position.     

Hemoglobin switching in sheep: commitment of erythroid stem cells to expression of the betaC-globin gene and accumulation of betaC-globin mRNA

The switch from HbA (α₂β₂^A) to HbC (α₂β₂^C) synthesis was induced by injection of erythropoietin into a lamb homozygous for HbA. Serial samples of bone marrow were analyzed to detect the initial commitment of erythroid stem cells (CFU-E) to form colonies which made HbC in vitro, and to detect the initial accumulation of β^C-globin mRNA and the onset of HbC synthesis in erythroblasts in vivo. CFU-E-derived erythroid colonies were formed in plasma clot culture at a low erythropoietin concentration, and the relative amounts of β^A- and β^C-globin synthesized were determined after a 24 hr pulse of ³H-leucine, added after 84 hr in culture. RNA was extracted from nuclei and cytoplasm of “early” and “late” populations of bone marrow erythroblasts which had been fractionated by Ficoll-Hypaque density centrifugation. The concentration of β^A- and β^C-globin mRNA was determined by annealing to purified synthetic DNAs (cDNAs) complementary to β^A and β^C mRNA. No β^C-globin was synthesized in erythroblasts or in CFU-E-derived erythroid colonies prior to the injection of erythropoietin. An increase in the concentration of CFU-E in the bone marrow and the appearance of β^C-globin synthesis in CFU-E-derived colonies were detected 12 hr after the erythropoietin injection. In contrast, β^C mRNA was not detected in either “early” or “late” erythroid cells until 36 hr later. The first measurable β^C-globin mRNA was accompanied by the appearance of β^C-globin synthesis in bone marrow erythroblasts. Our results suggest that the accumulation of β^C-globin mRNA is a relatively late event following induction of HbA to HbC switching by erythropoietin. The expansion of the compartment of erythroid stem cells and the commitment of CFU-E to β^C-globin synthesis appear to precede the detectable accumulation of β^C mRNA by 24–36 hr.     

Ontogeny of hemoglobins: Evidence for hemoglobin M

A new autosomal codominant hemoglobin mutation alters hemoglobin M of the primitive red cell line and hemoglobin D found in definitive cells. That Hb M and Hb D are altered by the same gene mutation supports the idea that Hb M shares a polypeptide chain with Hb D. It is concluded that in the switch from primitive hemoglobins to those of the definitive type, there are at least two α chains conserved; α^A of Hb E in Hb A and α^D of Hb M in Hb D.     

The oxidation of cat,human, and the cat-human hybrid hemoglobins α2Humanβ2Cat and α2Catβ2Human by copper(II)

The heme iron of the β chains of mammalian hemoglobins are rapidly and selectively oxidized in the presence of excess Cu(II) ions in a reaction that requires the presence of a free -SH groups on the β globin chain. The presence of freely reactive -SH groups on the α chains of cat and sheep hemoglobins does not alter the course of this reaction: only the β hemes are oxidized rapidly by Cu(II) in these hemoglobins. Two equivalents of copper are required for the rapid oxidation of the two β chain hemes per mole of cat hemoglobin, in contrast with the four equivalents that are required for reaction with human hemoglobin. The human-cat hybrid hemoglobins, α₂^Humanβ₂^Cat and α₂^Catβ₂^Human, required two and four equivalents of copper/mol, respectively, for the reaction. Thus, the kinetics and stoichimetry of the reaction are determined by the nature of the β subunit. Analysis of the esr spectra of the products of the reaction of Cu(II) with these hemoglobins indicate that human hemoglobin and the hybrid α₂^Catβ₂^Human contain tight binding sites for two equivalents of Cu(II) that are not involved in the oxidation reaction and are not present in cat hemoglobin or α₂^Humanβ₂^Cat. Cat β globin like others (sheep, bovine) that lack the tight binding site, has no histidine residue at 2β. It has phenylalanine in this position. These results support the suggestion of Rifkind et al. (Biochemistry 15,5337[1976]) that the tight binding site is near the amino terminal region of the β chain and is associated with histidine 2β.     

Diagnosis of caseous lymphadenitis by ELISA in naturally infected goats from Venezuela

Due to the absence of previous reports, the goal of this work was to detect caseous lymphadenitis (CLA) in goat flocks from Venezuela using an indirect immunoenzymatic assay (ELISA). Eighteen farms were randomly selected in Falcon State, North-Western Venezuela. Blood samples were taken from 259 goats, 65 of them with abscesses. Experimental inoculations were made to healthy kids with 0.5 mL inocula containing 4.7 × 10⁵ of Corynebacterium pseudotuberculosis to observe the kinetics of antibody response. Immunoenzymatic assays were carried out using exotoxin of C. pseudotuberculosis as antigen. Antibody response in experimentally inoculated animals was detected 2 weeks after infection. Of 259 field goat sera, 55.98% were positive by ELISA. Of 65 goats with abscesses, 67.69% had CLA demonstrated by bacteriological methods; from these, 72.73% showed antibodies by ELISA. Of the remaining goats negative to CLA, 47.62% had antibodies by ELISA. Sensitivity was calculated in 72.73% and specificity in 67.74%. The immunoenzymatic assay applied in this research could be useful to detect CLA in naturally infected goat flocks from Venezuela.     

Evidence of a humoral immune response against the prokaryotic expressed N-terminal autoprotease (N<Superscript>pro</Superscript>) protein of bovine viral diarrhoea virus

Bovine viral diarrhoea virus (BVDV) is an economically important pathogen of cattle and sheep belonging to the genus Pestivirus of the family Flaviviridae. Although the BVDV non-structural N-terminal protease (N^pro) acts as an interferon antagonist and subverts the host innate immunity, little is known about its immunogenicity. Hence, we expressed a recombinant BVDV N^pro-His fusion protein (28 kDa) in E. coli and determined the humoral immune response generated by it in rabbits. The antigenicity of the N^pro protein was confirmed by western blot using anti-BVDV hyperimmune cattle, sheep and goat serum, and anti-N^pro rabbit serum. When rabbits were immunized with the N^pro protein, a humoral immune response was evident by 4 weeks and persisted till 10 weeks post immunization as detected by ELISA and western blot. Despite N^pro-specific antibodies remaining undetectable in 80 serum samples from BVDV-infected sheep and goats, BVDV hyperimmune sera along with some of the field cattle, sheep and goat sera with high BVDV neutralizing antibody titres were found positive for N^pro antibodies. Our results provide evidence that despite the low immunogenicity of the BVDV N^pro protein, a humoral immune response is induced in cattle, sheep and goats only with repeated BVDV exposure.