Primary structure and functional properties of the hemoglobin from the free-tailed bat Tadarida brasiliensis (Chiroptera). Small effect of carbon dioxide on oxygen affinity

The hemoglobin of the Free-Tailed Bat Tadarida brasiliensis (Microchiroptera) comprises two components (Hb I and Hb II) in nearly equal amounts. Both hemoglobins have identical beta-chains, whereas the alpha-chains differ in having glycine (Hb I) or aspartic acid (Hb II) in position 115 (GH3). The components could be isolated by DEAE-Sephacel chromatography and separated into the globin chains by chromatography on carboxymethyl-cellulose CM-52. The sequences have been determined by Edman degradation with the film technique or the gas phase method (the alpha I-chains with the latter method only), using the native chains and tryptic peptides, as well as the C-terminal prolyl-peptide obtained by acid hydrolysis of the Asp-Pro bond in the beta-chains. The comparison with human hemoglobin showed 18 substitutions in the alpha-chains and 24 in the beta-chains. In the alpha-chains one amino-acid exchange involves an alpha 1/beta 1-contact. In the beta-chains one heme contact, three alpha 1/beta 1- and one alpha 1/beta 2-contacts are substituted. A comparison with other chiropteran hemoglobin sequences shows similar distances to Micro- and Megachiroptera. The oxygenation characteristics of the composite hemolysate and the two components, measured in relation to pH, Cl-, and 2,3-bis-phosphoglycerate, are described. The effect of carbon dioxide on oxygen affinity is considerably smaller than that observed in human hemoglobin, which might be an adaptation to life under hypercapnic conditions.     

The primary structure of the mandrill (Mandrillus sphinx, Primates) hemoglobin

The complete primary structure of the hemoglobin from the Mandrill (Mandrillus sphinx, Primates) is presented. This hemoglobin comprises two components in approximately equal amounts (HB I and Hb II). The alpha-chains differ in positions 5 (A3) and 9 (A7) having Ala and Asn in the alpha I-chains and Asp and His in the alpha II-chains. The beta-chains are identical. The components could be separated by DEAE-Sephacel chromatography. The globin chains were obtained by carboxymethylcellulose chromatography or high-performance liquid chromatography. The sequences were established by automatic liquid or gas phase Edman degradation of the chains and their tryptic peptides. The alpha-chains show 9 and 11 and the beta-chains 8 exchanges compared with the corresponding human chains, respectively. In the beta-chains one alpha 1/beta 1- and one alpha 1/beta 2-contact is substituted. A comparison of the primary structures of the Mandrill hemoglobin chains with those of other species of the Cercopithecidae family shows that Mandrillus sphinx should be placed between Cercopithecus and Macaca on one side and Papio, Theropithecus and Cercocebus on the other.     

The primary structure of the hemoglobin of the Rock-Hopper penguin (Eudyptes crestatus, Sphenisciformes)

The blood of the Rock-Hopper Penguin contains only one hemoglobin component, corresponding to the Hb A of other birds. The primary structures of the alpha- and beta-chains are presented. The chains were separated by high-performance liquid chromatography and cleaved either enzymatically (alpha) or both enzymatically and chemically (beta). Both the native chains and their peptides were sequenced using liquid and gas phase sequenators. The peptides were aligned using their homology to the sequence of human hemoglobin and other bird hemoglobins. As compared to human hemoglobin, 44 amino-acid replacements are found in the alpha-chains (68% homology) and 47 in the beta-chains (67.8% homology). These exchanges involve seven alpha 1/beta 1 and one alpha 1/beta 2 contact in the alpha-chains, whereas in the beta-chains eight alpha 1/beta 1, one alpha 1/beta 2 and one hem contact are substituted. The influence of these replacements on the structure-function relationships in hemoglobin, as well as their importance for the diving ability of penguins, are discussed.     

Carnivora: the primary structure of the Pacific Walrus (Odobenus rosmarus divergens, Pinnipedia) hemoglobin

The primary structure of the alpha- and beta-chains of the hemoglobin from the Pacific Walrus (Odobenus rosmarus divergens, Pinnipedia) is presented. Sequence analysis revealed only one hemoglobin component whereas two bands were found in polyacrylamide gel electrophoresis. The globin chains were separated by high-performance liquid chromatography and the sequences determined by automatic liquid- and gas-phase sequencing of the chains and their tryptic peptides. The alpha-chains show 20 and the beta-chains 12 exchanges compared to the corresponding human chains. In the alpha-chains one heme- and two alpha 1/beta 1-contacts were exchanged whereas in the beta-chains one alpha 1/beta 1-, one alpha 1/beta 2-and one heme-contact are substituted. Compared to Harbour Seal (Phoca vitulina) the Walrus hemoglobin shows 9 amino-acid replacements in the alpha-chains and 5 in the beta-chains. The relation between Pinnipedia and Arctoidea is discussed.     

Cooperative ligand binding of crosslinked hemoglobins at very high temperatures

Human hemoglobin was reacted with the bifunctional reagent bis(3,5-dibromosalicyl) fumarate to yield a derivative (Hb alpha alpha) crosslinked between the two alpha-chains; when the reaction was carried out with HbA already crosslinked between the two beta-chains by 2-nor-2-formylpyridoxal 5'-phosphate, a doubly crosslinked derivative (Hb alpha alpha beta beta) was obtained. We have observed that both modified hemoglobins are extremely stable up to temperatures of at least 85 degrees C. The carbon monoxide binding kinetics of both crosslinked hemoglobins, studied at temperatures between 15 and 85 degrees C, by means of stopped flow and flash photolysis techniques, show that the ligand-linked allosteric transition is maintained even at the highest temperatures. These results are also relevant to the mechanism of thermal unfolding of human hemoglobin, since they show that dissociation into alpha beta dimers (and exposure of the relatively hydrophobic dimer-dimer interfaces) is an obligatory step in the irreversible denaturation of deoxy and carbon monoxy hemoglobin.     

The primary structure of the pallid bat (Antrozous pallidus, Chiroptera) hemoglobin

The complete primary structure of the hemoglobin from the Pallid Bat (Antrozous pallidus, Microchiroptera) is presented. This hemoglobin consists of two components with identical amino-acid sequences, differing, however, in the N-terminus which is formylated in 12.5% of the beta-chains. The alpha- and beta-chains were separated by reversed phase high performance liquid chromatography. The sequences of both chains were established by automatic Edman degradation with the film technique or gas phase method using the native chains and the tryptic peptides. The formylation of a part of the N-terminal peptide of the beta-chains was determined by mass spectrometric examination. Compared to the corresponding human chains we found 14 substitutions in the alpha-chains and 21 in the beta-chains. One substitution in the alpha-chains and three in the beta-chains are involved in alpha 1/beta 1-contacts. Among these the exchange beta 123(H1)Thr----Cys is unusual because cysteine was so far not found in this position of mammalian beta-chains. Compared to the hemoglobin of Myotis velifer, another representative of the family Vespertilionidae, 5 residues are replaced in the alpha-chains and 18 in the beta-chains.     

Hemoglobin of tree sparrows (Passer montanus, Passeriformes): Sequence of the major (Hb A) and minor (Hb D) components

Blood of the adult Tree Sparrow (Passer montanus) contains two hemoglobin components, Hb A (ca. 85%), Hb D (ca. 15%). They differ in their alpha-chains (alpha A, alpha D), the beta-chains are identical. The complete primary structures of alpha A-, alpha D- and beta-chains are presented. Comparison with the Greylag Goose (Anser anser) hemoglobin (Hb A) showed that the alpha A-chains differ by 22 amino-acid exchanges, the beta-chains by 16. Comparison with the minor component of the Pheasant (Phasianus colchicus colchicus) hemoglobin (Hb D) showed that the alpha D-chains differ by 34 amino-acid exchanges. Proline is found incorporated in an internal position of an alpha-helix (pos. 124, H7). In comparison to that of the Starling (Sturnus vulgaris) the ratio of amino-acid exchanges for beta: alpha A: alpha D chains is 1 : 7 : 4; in comparison to other birds this ratio is found to be 1 : 2 (1.4-2.2):3 (2.2-4).     

Carnivora: the primary structure of Weddell Seal (Leptonychotes weddelli, Pinnipedia) hemoglobin

The hemoglobin of Weddell Seal (Leptonychotes weddelli, Pinnipedia) comprises two components with identical beta-chains. The alpha-chains differ in positions 15 (Gly/Asp) and 57 (Ala/Thr). We present the primary structure of the chains which have been separated by reversed-phase high-performance liquid chromatography. The sequences have been determined by automatic Edman-degradation with the film-technique or the gas-phase method, using the native chains and the tryptic peptides of the oxidized chains. Compared to the corresponding human chains we found 22 substitutions in the alpha-chains and 14 in the beta-chains. In the alpha-chains exchanges involve one heme- and three alpha 1/beta 1-contacts. In the beta-chains one heme contact, one alpha 1/beta 1- and one alpha 1/beta 2-contacts are substituted. The sequences are compared to those of other Pinnipedia and Arctoidea hemoglobins.     

Carnivora: primary structure of the hemoglobins from ratel (Mellivora capensis)

The erythrocytes of adult ratel contain two hemoglobin components, with two alpha- and one beta-chains. In this paper, their complete amino acid sequences are presented. The two alpha-chains differ in one residue at position 34 (Ala----Val) only. The primary structure of the chains was determined by sequencing the N-terminal regions (45 steps) and the tryptic peptides after their isolation from the digests by reversed-phase high-performance liquid chromatography. The alignment of these peptides was deduced from homology with other carnivora globins. The alpha-chains show 21 and the beta-chains 11 exchanges compared with human globin chains. In the alpha-chains, one heme- and two alpha 1/beta 1 contacts are exchanged. In the beta-chains there are three exchanges which involve one alpha 1/beta 1-, one alpha 1/beta 2- and one heme-contact. Between the ratel hemoglobin and those of carnivora a high degree of homology was found.     

Carnivora: primary structure of the hemoglobin from the spotted hyena (Crocuta crocuta, Hyenidae)

The primary structure of the alpha- and beta-chains of hemoglobin from spotted hyena (Crocuta crocuta, Hyenidae) is presented. The structure-function relationship is discussed. The separation of the chains directly from hemoglobin was performed by RP-HPLC. After tryptic digestion of the chains, the peptides were isolated by RP-HPLC. Amino-acid sequences were determined by Edman degradation in liquid- and gas-phase sequencers. The alignment of the tryptic peptides was made by homology with human and other Carnivora hemoglobins. The hemoglobin from spotted hyena (Crocuta crocuta) exhibits in its alpha- and beta-chains 22 and 20 exchanges, respectively, compared to human hemoglobin. In the alpha-chains, two alpha 1 beta 1-contacts are exchanged. In the beta-chains five exchanges involve one alpha 1 beta 1-contact, one alpha 1 beta 2-contact, one heme contact, and two 2,3-DPG-binding sites.     

Ligand binding kinetic studies on the hybrid hemoglobin alpha (human):beta (carp): a hemoglobin with mixed conformations and sequential conformational changes

Oxygen and CO ligand binding kinetics have been studied for the hybrid hemoglobin (Hb) alpha (human):beta (carp), hybrid II. Valency and half-saturated hybrids were used to aid in the assignment of the conformations of both chains. In hybrid II, an intermediate S state occurs, in which one chain has R- and the other T-state properties. In HbCO at pH 6 (plus 1 mM inositol hexaphosphate), the human alpha-chain is R state and the carp beta-chain is T state. We have no evidence at this pH that the carp beta-chain ever assumes the R conformation. At pH 6, the human alpha-chain shows human Hb R-state kinetics at low fractional photolysis and T-state rates for CO ligation by stopped flow. At pH 7, the human-chain R-state rate slows toward a carp hemoglobin rate. The carp beta-chains, on the other hand, react 50% more rapidly in the liganded conformation than in carp hemoglobin, and while the human alpha-chains are in the R state, the two beta-chains appear to function as a cooperative dimer. In this hemoglobin, the chains appear to be somewhat decoupled near pH 7, allowing a sequential conformational change from the R state in which the beta-chains first assume T-state properties, followed by the alpha-chains. The rate of the R-T conformational change for the carp beta-chains is at least 300 times greater than that for the human alpha-chains. At pH 9, the R----T conformational transition rate is at least 200 times slower than that for human hemoglobin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Carnivora: the primary structure of the giant otter (Pteronura brasiliensis, Mustelidae) hemoglobin

The hemoglobin of the Giant Otter (Pteronura brasiliensis, Carnivora) contains only one component. The complete primary structures of the alpha- and beta-chains are presented. The globin chains were separated by high-performance liquid chromatography and the sequences determined by automatic liquid- and gas-phase Edman degradation of the chains and their tryptic peptides. The alpha-chains show 18 and the beta-chains 12 exchanges compared with human alpha- and beta-chains, respectively. In the alpha-chains, two substitutions involve alpha 1/beta 1-contacts and one a heme-contact. In the beta-chains one alpha 1/beta 1-, one alpha 1/beta 2- and one heme-contact are exchanged. The alpha- and beta-chains of the Giant Otter are compared to those of the Common Otter and other Carnivora hemoglobins.     

Assembly of gamma- with alpha-globin chains to form human fetal hemoglobin in vitro and in vivo

Soluble gamma-globin chains were expressed in bacteria and purified to assess the mechanism of gamma- and alpha-chain assembly to form Hb F. Formation of Hb F in vitro following incubation of equimolar mixtures of gamma and alpha chains was about 4 x 10(5)-fold slower than assembly of alpha and beta chains to form Hb A in vitro. Results of assembly for gamma(116Ile-->His) and gamma(112Thr-->Asp) chains with alpha chains were similar to that of beta chains, whereas assembly of gamma(112Thr-->Cys) and alpha chains was similar to wild type gamma chains, indicating that amino acid differences at alpha1beta1 and alpha1gamma1 interaction sites between gamma116 Ile and beta116 His are responsible for the different assembly rates in vitro in the formation of Hb F and Hb A. Homoassembly in vitro of individual gamma chains as assessed by size-exclusion chromatography shows that gamma and gamma(112Thr-->Cys) chains form stable dimers like alphabeta and alphagamma that do not dissociate readily into monomers like beta chains. In contrast, gamma(116Ile-->His) chains form monomers and dimers upon dilution. These results are consistent with the slower assembly rate in vitro of gamma and gamma(112Thr-->Cys) with alpha chains, whereas the faster rate of assembly of gamma(116Ile-->His) and gamma(112Thr-->Asp) chains with alpha chains, like beta chains, may be caused by dissociation to monomers. These results suggest that dissociation of gamma(2) dimers to monomers limits formation of Hb F in vitro. However, yields of soluble Hb F expressed in bacteria were similar to Hb A, and no unassembled alpha and gamma chains were detected. These results indicate that gamma chains assemble in vivo with alpha chains prior to forming stable gamma(2) dimers, possibly binding to alpha chains as partially folded nascent gamma-globin chains prior to release from polyribosomes.     

The primary structure of pale-throated three-toed sloth (Bradypus tridactylus, Xenarthra) hemoglobin

The hemoglobin of the Pale-Throated Three-Toed Sloth (Bradypus tridactylus, Xenarthra) was separated into two components (ratio 4:1) with identical amino-acid analyses for the alpha- and beta-chains. The primary structures of both chains from the major component are given. They could be isolated by chromatography on carboxymethyl cellulose CM-52. The sequences have been determined by automatic Edman degradation of the native chains and their tryptic peptides. The comparison with human hemoglobin showed 27 substitutions in the alpha-chains and 33 in the beta-chains. In the alpha-chains one amino-acid exchange involves an alpha 1/beta 1-contact. In the beta-chains two heme- and four alpha 1/beta 1-contacts are substituted. The hemoglobin of the Sloth is compared to that of the Nine-Banded Armadillo (Dasypus novemcinctus), another representative of the order Xenerthra.     

A "living fossil" sequence: primary structure of the coelacanth (Latimeria chalumnae) hemoglobin--evolutionary and functional aspects

The coelacanth (Latimeria chalumnae, Actinistia) has a single hemoglobin component. The primary structures of the alpha- and beta-chains are presented. They could be separated by reversed-phase HPLC. Peptides obtained by tryptic digestion of the native and oxidized chains were isolated by reversed-phase HPLC and sequenced in liquid and gas-phase sequenators. The alignment was achieved by employing the N-terminal sequences of the native chains and those of a beta-chain cyanogen bromide peptide as well as fragments obtained by acid hydrolysis. The Latimeria alpha-chains consist of 142 amino-acid residues, due to a fish-specific insertion between positions 46 and 47, whereas the beta-chains are of normal length (146 residues). Latimeria alpha- and beta-chains share 72 (51.1%) and 70 (47.9%) identical residues with human hemoglobin, respectively. Numerous heme contacts and positions involved in subunit interface contacts are replaced. The most interesting of them were studied by molecular modeling. The loss of an alpha 1/beta 2-contact by the exchanges alpha 92(FG4)Arg----Leu and beta 43(CD2)Glu----Lys might be responsible for the easy dissociation of the tetrameric hemoglobin molecule. A comparison of the residues replaced in contact positions with fishes and amphibians revealed the highest number of matches between Latimeria and tadpoles. The same result was obtained by the evaluation of other regions relevant for structure and function of the molecule, like exon-intron boundary regions, phosphate binding sites and salt bridges responsible for the Bohr effect.     

Association of alpha- and beta-subunits during the biosynthesis of beta-hexosaminidase in cultured human fibroblasts

Subunit association of beta-hexosaminidase was studied in intact fibroblasts using antisera that discriminate between free and associated alpha-chains. These were anti-beta-hexosaminidase A (anti-alpha beta), which precipitated all alpha-chains, free or associated; anti-beta-hexosaminidase B (anti-beta beta), which precipitated those alpha-chains that were associated with beta; and anti-alpha-chains, which recognized only monomeric alpha-chains. After biosynthetic labeling, beta-hexosaminidase or its free alpha-subunit were immuno-precipitated from extracts of cells and medium with the aid of protein A-bearing Staphylococcus aureus, subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and visualized by fluorography. Pulse-chase labeling showed that the alpha-chains existed predominantly in the monomeric precursor form during the first 5 h, and then began to accumulate in the mature (lysosomal) associated alpha beta form. Precursor alpha beta complexes were secreted, along with some precursor alpha monomers; the latter were catalytically inert. Both alpha- and beta-chains were phosphorylated (a Golgi modification) prior to association. Thus alpha-beta association probably occurred in the Golgi area before transfer to lysosomes and before secretion. Cycloheximide inhibited the association and subsequent maturation of preformed alpha-chains, perhaps by causing a depletion of a pool of beta-chain precursor upstream from the site of subunit association. In fibroblasts from a patient with Sandhoff disease, that produced no beta-chains, the alpha-chains self-associated but their maturation was markedly decreased. We suggest that association with beta-chains is necessary not only for acquisition of catalytic activity but also for transport of alpha-chains to lysosomes.     

Carnivora: the primary structure of the common otter (Lutra lutra, Mustelidae) hemoglobin

The hemoglobin of the Common Otter (Lutra lutra, Carnivora) contains only one component. The complete primary structures of the alpha- and beta-chains are presented. They were separated by high-performance liquid chromatography and the sequences determined by automatic liquid and gas-phase Edman degradation of the chains and their tryptic peptides. The alpha-chains show 18 and the beta-chains 13 substitutions compared to human alpha- and beta-chains, respectively. In the alpha-chains one heme- and two alpha 1/beta 1-contacts are exchanged. In the beta-chains the replacements involve one heme-, one alpha 1/beta 1-, and one alpha 1/beta 2-contact. The alpha- and beta-chains of the Common Otter are compared to those of other Carnivora hemoglobins. The unexpected low number of substitutions between Common Otter hemoglobin and that of Lesser Panda as well as of Harbor Seal is discussed.     

Functional consequences of mutations at the allosteric interface in hetero- and homo-hemoglobin tetramers.

A seminal difference exists between the two types of chains that constitute the tetrameric hemoglobin in vertebrates. While alpha chains associate weakly into dimers, beta chains self-associate into tightly assembled tetramers. While heterotetramers bind ligands cooperatively with moderate affinity, homotetramers bind ligands with high affinity and without cooperativity. These characteristics lead to the conclusion that the beta 4 tetramer is frozen in a quaternary R-state resembling that of liganded HbA. X-ray diffraction studies of the liganded beta 4 tetramers and molecular modeling calculations revealed several differences relative to the native heterotetramer at the "allosteric" interface (alpha 1 beta 2 in HbA) and possibly at the origin of a large instability of the hypothetical deoxy T-state of the beta 4 tetramer. We have studied natural and artificial Hb mutants at different sites in the beta chains responsible for the T-state conformation in deoxy HbA with the view of restoring a low ligand affinity with heme-heme interaction in homotetramers. Functional studies have been performed for oxygen equilibrium binding and kinetics after flash photolysis of CO for both hetero- and homotetramers. Our conclusion is that the "allosteric" interface is so precisely tailored for maintaining the assembly between alpha beta dimers that any change in the side chains of beta 40 (C6), beta 99 (G1), and beta 101 (G3) involved in the interface results in increased R-state behavior. In the homotetramer, the mutations at these sites lead to the destabilization of the beta 4 hemoglobin and the formation of lower affinity noncooperative monomers.     

The first sequenced normal hemoglobin lacking histidine in position 146 of the beta-chains. The primary structures of the major and minor hemoglobin components of the great crested newt (Triturus cristatus, Urodela, Amphibia)

The hemoglobin of the Great Crested Newt (Triturus cristatus), an animal maintaining the gas exchange to about 85% through the skin, consists of a major (HbM = 65%) and a minor (Hbm = 35%) component. The primary structures of the four chains are presented. They could be separated by reversed-phase HPLC and were cleaved with trypsin and additionally by acid hydrolysis. Both the native chains and their peptides were sequenced by liquid and gas phase sequenators. At the N-terminus the alpha M-chains are by one amino-acid residue longer and the beta M-chains by one residue shorter, resulting in a chain length of 142 and 145, respectively. The alpha m-chains are of normal length whereas in the beta m-chains the C-terminal histidine in position 146 is missing. Both alpha-chains differ by 50 residues (35.2%) and the beta-chains by 63 (43.2%). The alpha-chains were compared with those of other salamandroid hemoglobins. The difference to human hemoglobin is marked by 61 (43.3%) amino-acid substitutions in both alpha-chains and by 78 (53.4%) in both beta-chains. Numerous heme contacts and positions involved in the subunit interface are affected by replacements. The most interesting of them were studied by molecular modeling. The importance of the missing beta m-146(HC3)His and of the substitution of several amino-acid residues involved in the binding of organic phosphates is discussed with respect to the reduced Bohr effect of Triturus cristatus hemoglobin.     

The primary structure of the hemoglobin of an Indian flying fox (Cynopterus sphinx, Megachiroptera)

The hemoglobin of the Indian flying fox Cynopterus sphinx contains only one component. In this work, we are presenting its primary structure. The globin chains were separated by high-performance liquid chromatography and the sequences determined by automatic liquid and gas-phase Edman degradation of the chains and their tryptic peptides, as well as of the peptide obtained by acid hydrolysis of the Asp-Pro bond in the beta-chains. The alpha-chains show 14 and the beta-chains 19 exchanges compared with the human alpha- and beta-chains, respectively. In the alpha-chains one amino-acid exchange involves an alpha 1/beta 1 contact. In the beta-chains one heme contact, three alpha 1/beta 1- and one alpha 1/beta 2-contacts are exchanged. The functional and evolutionary aspects of these findings are discussed.