The expression of alpha D-chains in the hemoglobin of adult ostrich (Struthio camelus) and American rhea (Rhea americana). The different evolution of adult bird alpha A-, alpha D- and beta-chains

The hemoglobin of adult American rhea (Rhea americana) and ostrich (Struthio camelus) contains two components identified to be HbA (alpha 2A beta 2) and HbD (alpha 2D beta 2). The amino-acid sequence of alpha D-chains from HbD of adult American rhea and ostrich has been determined. The sequence was studied by Edman degradation of tryptic peptides and chemical cleavage products in a liquid phase sequencer. By homologous comparison with pheasant HbD (Phasianus colchicus colchicus), the alpha D-chains of American rhea differ by 28 amino-acid exchanges, the alpha D-chains of ostrich by 23 residues. These differences are higher than those observed for alpha A- as well as for beta-chains of HbA from the same species. The ratio of amino-acid exchanges for beta:alpha A:alpha D for American rhea and ostrich is found to be 1:5.5:6.5. At present the reason for the differences in evolution rates for the beta-, alpha A- and alpha D-chains of bird hemoglobins is still unclear.     

Hemoglobins of reptiles. The primary structure of the major and minor hemoglobin component of adult Western Painted Turtle (Chrysemys picta bellii)

Red blood cells of adult Western Painted Turtles (Chrysemys picta bellii) contain two hemoglobin components: HbA (alpha A2 beta 2) and HbD (alpha D2 beta 2). We present the complete amino-acid sequences of the alpha A-chains from the major component and of the beta-chains common to both components. Structural features are discussed with respect to the animals extreme tolerance of severe hypoxic conditions during hibernation which is accompanied by a high oxygen affinity of the hemoglobin. The strong ATP dependence of Western Painted Turtle hemoglobin oxygen affinity is contrasted by the loss of one ATP-binding site, beta 143(H21)-Arg----Leu. The primary structure of the beta-chains excludes an allosteric control mechanism by hydrogencarbonate as it was found in crocodiles. Except in turtles a hemoglobin pattern with HbA and HbD sharing the same beta-subunits has been found only in birds. In comparison to other vertebrate hemoglobins there is a surprising similarity of the sequences to those of bird hemoglobins. alpha A- as well as alpha D-chains show larger homologies to chains of the same type in different species than alpha A- and alpha D-chains to each other in the same species. This indicates a duplication of the alpha-gene preceding the divergence of turtles and birds.     

The amino-acid sequence of Northern Mallard (Anas platyrhynchos platyrhynchos) hemoglobin

The complete amino-acid sequence of the major hemoglobin component (HbA) of the adult Northern Mallard (Anas platyrhynchos platyrhynchos) is presented. A minor component HbD was also detected but in low concentrations. The sequences of alpha A- and beta-chains were established by automatic Edman degradation on tryptic peptides and peptides obtained by specific chemical cleavages. The alignment of the peptides was performed by comparison with the alpha A- and beta-chains of Greylag Goose hemoglobin (Anser anser). Thereby an exchange of five positions in the alpha A-chains and three in the beta-chains was observed. No exchanges were found in the surroundings of the heme, in alpha 1 beta 2-contact points, or allosteric regulatory sites. In the alpha 1 beta 1-subunit interface one amino-acid residue in alpha A-chains and one in beta-chains are exchanged. By comparison with the amino-acid sequence derived from globin genes of Domestic Duck (Anas platyrhynchos), the alpha A-chains differ by two exchanges in the N-terminal region and the beta-chains by five exchanges the in C-terminal region. The comparison of the amino-acid sequence derived from alpha A-globin gene of the Moscovy Duck (Cairina moschata) and alpha A-chains of the Northern Mallard, shows only one replacement.     

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).     

Hemoglobin of the adult white stork (Ciconia ciconia, ciconiiformes). The primary structure of alpha A- and beta-chains from the only present hemoglobin component

The hemolysate obtained from erythrocytes of the adult White Stork (Ciconia ciconia) contains only one hemoglobin component, identified to be HbA. The complete primary structures of alpha A- and beta-chains are presented. The minor hemoglobin component HbD with alpha D-chains usually present in adult avian species was not detected by the White Stork. The sequence was determined by automatic Edman degradation of tryptic peptides and in the case of beta-chains additionally of the C-terminal peptide obtained by chemical cleavage at the Asp-Pro bond. Homologous comparison with the Greylag Goose (Anser anser) hemoglobin showed that the alpha A-chains differ by 23 amino-acid exchanges, the beta-chains by 17. Four of the substitutions in the alpha A-chains are in the alpha 1 beta 1-contact points, one in the alpha 1 beta 2-contacts and one in the amino acids near the heme. The amino-acid substitutions of the White Stork hemoglobin as compared to the other avian hemoglobins are discussed. We suggest that alpha D-chain is persistence of an embryonic gene.     

High-altitude respiration of birds. Structural adaptations in the major and minor hemoglobin components of adult Rüppell's Griffon (Gyps rueppellii, Aegypiinae): a new molecular pattern for hypoxic tolerance

The primary structures of the hemoglobins Hb A, Hb A', Hb D and Hb D' of Rüppell's Griffon (Gyps rueppellii), which can fly as high as 11,300 m, are presented. The globin chains were separated on CM-Cellulose in 8M urea buffers, the four hemoglobin components by FPLC in phosphate buffers. The amino-acid sequences of five globin chains were established by automatic Edman degradation of the globin chains and of the tryptic peptides in liquid-phase and gas-phase sequenators. The sequences are compared with those of other Falconiformes. A new molecular pattern for survival at extreme altitudes is presented. For the first time four hemoglobins are found in blood of a bird; they show identical beta-chains and differ in the alpha A- and alpha D-chains by only one replacement. These four hemoglobins cause a gradient in oxygen affinities. The two main components Hb A and Hb A' differ at position alpha 34 Thr/Ile. In case of Ile as found in Hb A' an alpha 1 beta 1-interface is interrupted raising oxygen affinity compared to Hb A. In addition the hemoglobins of the A- and D-groups differ at position alpha 38 Pro or Gln/Thr (alpha 1 beta 2-interface). Expression of Gln in Hb D/D' raises the oxygen affinity of these components compared to Hb A/A' by destabilization of the deoxy-structure. The physiological advantage lies in the functional interplay of four hemoglobin components. Three levels of affinity are predicted: low affinity Hb A, Hb A' of intermediate affinity, and high affinity Hb D/D'. This cascade tallies exactly with oxygen affinities measured in the isolated components and predicts oxygen transport by the composite hemoglobins over an extended range of oxygen affinities. It is contended that the mechanisms of duplication of the alpha-genome (creating four hemoglobins) and of nucleotide replacements (creating different functional properties) are responsible for this remarkable hypoxic tolerance to 11,300 m. Based on this pattern the hypoxic tolerances of other vultures are predicted.     

The primary structure of alpha A- and beta-chains from blue-and-yellow macaw (Ara ararauna, Psittaci) hemoglobin. No evidence for expression of alpha D-chains

The hemoglobin A of the Blue-and-Yellow Macaw (Ara ararauna) was isolated and characterized. The complete amino-acid sequence of alpha A- and beta-chains is presented. In contrast to some adult avian hemoglobins already investigated, Blue-and-Yellow Macaw hemoglobin is homogenous and contains only one component: HbA. The minor component, HbD, which is usually present in the hemolysate of avian erythrocytes, could not be detected. There is no evidence for the expression of the alpha D-globin gene. Comparison of alpha A- and beta-chains from Blue-and-Yellow Macaw hemoglobin with corresponding chains from Greylag Goose hemoglobin shows 19 amino-acid exchanges between alpha A-chains and 6 between beta-chains. The structure-function relationships of hemoglobin chains and the evolutionary aspects are discussed in view of these results.     

The primary structure of the hemoglobin of the Cormorant (Phalacrocorax carbo, Pelecaniformes)

The erythrocytes of the adult Cormorant contain two hemoglobin components in a ratio of 83% Hb A to 17% Hb D. The primary structures of the alpha A-, alpha D- and beta-chains are presented. The globin chains were separated by high-performance liquid chromatography and cleaved enzymatically and/or chemically. The native chains and their fragments were sequenced using liquid- or gas-phase sequencers, and the peptides aligned using the homology to human and to avian hemoglobin sequences. Compared to human hemoglobin, there are 46 amino-acid replacements in the alpha A-chains (67.4% homology), 65 replacements in the alpha D-chains (53.9% homology) and 45 replacements in the beta-chains (69.2% homology). In the functionally important regions, the percentage of amino-acid substitutions, as compared to human hemoglobin, is 13.2% in the alpha A-, 19.0% in the alpha D - and 16.0% in the beta-chains. The importance of the replacement beta 135 arginine (other birds)----glycine (Cormorant) in the phosphate-binding pocket and its effect on phosphate binding will be discussed.     

The hemoglobin of adult Andean condors (Vultur gryphus, Cathartiformes). The amino acid sequence of the major (HbA) and minor component (HbD)

The complete amino-acid sequence of the alpha A- and the beta-chains of the major component (HbA) and the alpha D- and the beta-chains of the minor component (HbD) of Andean Condor (Vultur gryphus) is presented. The minor component with the alpha D-chains is present in smaller amounts (17%) than in other birds (25%). The comparison with the corresponding chains of Greylag Goose (Anser anser) shows 17 different amino acids (17 nucleotides, only one-point mutations) in the alpha A-chains and 8 (8 nucleotides) in the beta-chains. The alpha D-chains differ from those of the pheasant (Phasanius cholchicus cholchicus) in 24 amino acids (27 nucl., 3 two-point mutations). Seven alpha 1 beta 1-, one alpha 1 beta 2-, three alpha 1 alpha 1-contacts and one beta 1 beta 1-contact are exchanged. The systematy of Cathartiformes, Ciconiiformes and Phoenicopteriformes is discussed, based on the amino-acid exchanges of all known adult hemoglobins of birds.     

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.     

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.     

Amino-acid sequence of gayal hemoglobin (Bos gaurus frontalis, Bovidae)

The amino-acid sequences of the alpha- and beta-chains of gayal hemoglobin have been determined and compared with those of bovine and yak hemoglobins. The gayal alpha-chain differs from the alpha-chains of bovine by 3 amino-acid residues and from yak I alpha- and II alpha-hemoglobins by 4 and 2 residues, respectively. The gayal beta-chain differs from bovine beta A- and beta B-chains by 3 and 4 residues, respectively and from yak beta-chains by 2 residues.     

Amino-acid sequences and functional differentiation of hemoglobins A and D from swift (Apus apus, Apodiformes)

The blood of the adult swift contains one major (HbA = alpha 2A beta 2) and two minor components (HbD = alpha 2D beta 2 and HbD'). The components were separated by FPLC with a TSK SP-5 PW-column in phosphate buffers, and were eluted with a linear NaCl gradient. HbD' could be detected only in freshly prepared hemolysates with the sensitive FPLC separation method. The globin chains were separated on a cation exchanger (CM-cellulose), the tryptic peptides by HPLC with a RP-2 LiChrosorb column. Their amino-acid sequences were determined by automatic Edman degradation with the film- or gas-phase method. For the alpha A-, alpha D- and beta-chains, peptide alignment was achieved by homologous comparison with the corresponding chains of the greylag goose (Anser anser). The structural significance of the substitutions was examined with the aid of molecular graphics. The oxygen-binding properties of the stripped hemolysate and of HbA and HbD and their dependence on pH, temperature and inositol polyphosphate are presented and discussed with reference to molecular structures and hypothermy that occurs during torpidity.     

The primary structure and functional properties of the hemoglobins of a ground squirrel (Spermophilus townsendii, Rodentia)

The hemoglobin of the ground squirrel Spermophilus townsendii consists of two components which are present in a ratio of ca. 2:1. The two hemoglobins have identical alpha-chains, but differ in their beta-chains. We present the primary structures of the alpha- and the two beta-globin chains. Following chain separation by chromatography on carboxymethyl-cellulose CM-52, the amino-acid sequences were established by automatic Edman degradation of the globin chains and the tryptic peptides, as well as of a peptide obtained by acid hydrolysis of the Asp-Pro bond of the beta-chains. The two beta-chains differ by only one amino-acid residue, Ala being present in the main and Asp in the minor component in position 58 (E2). The comparison with human hemoglobin showed only 14 exchanges in the alpha-chains but 33 in the beta-chains. Whereas no contact positions are affected in the alpha-chains, we found four such substitutions in the beta-chains, including one heme contact, two alpha 1/beta 1-contacts, and one alpha 1/beta 2-contact. It seems however, that the substitution found in the beta-chains has no effect on the oxygen affinity.     

Hemoglobin of the golden eagle (Aquila chrysaetos, Accipitriformes): amino acid sequence of the alpha A- and beta chains of the principal component

The primary structures of the alpha A- and beta-chains from the major hemoglobin component of Golden Eagle (Aquila chrysaetos) are given. By homologous comparison, Greylag Goose (Anser anser) hemoglobin and Golden Eagle alpha A-chains differ by 17 amino acids or 19 nucleotides (2 two-point mutations), beta-chains by 9 exchanges. Five substitutions have modified alpha 1 beta 1-contacts, one substitution, one alpha 1 beta 2-contact and one alpha 1 alpha 1-contact. Differences by homologous comparison to other hemoglobins of birds 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.     

The hemoglobins of the adult blackbird (Turdus merula, Passeriformes). The sequence of the major (HbA) and minor component (HbD)

The blood of the adult blackbird contains one major hemoglobin component (HbA = alpha A2, beta 2, ca. 80%) and one minor one (HbD = alpha D2 beta 2, ca. 20%). The Hb-components were separated by FPLC on a TSK SP-5 PW column, and eluted with a linear NaCl gradient, while the globin chains were purified on a cation exchange (CM-Cellulose). Tryptic peptides from the globin chains were separated by HPLC on an RP-2 Lichrosorb column. The complete amino acid sequence was determined by automatic Edman degradation, using film and gas phase methods. For the alpha A-, alpha D- and beta-chains, peptide alignment was carried out relative to the corresponding chains of the greylag goose (Anser anser). The close phylogenetic relationship between blackbird, tree sparrow and starling is verified by the hemoglobin sequence. The O2-affinities of the major and minor hemoglobin components of the blackbird are not yet known. Thus, the results were interpreted on the basis of primary structure. Substitutions of possible structural significance were examined with the help of molecular graphics/modelling.     

The primary structure of a mouse-eared bat (Myotis velifer, Chiroptera) hemoglobin

The hemoglobin of the Mouse-Eared Bat Myotis velifer consists of one component. We present the primary structures of the alpha- and beta-globin chains which have been separated by chromatography on carboxymethyl-cellulose CM-52. The sequences have been determined by Edman-degradation with the film technic or the gas phase method, using the native chains and the tryptic peptides, as well as the C-terminal prolyl-peptides obtained by acid hydrolysis of the Asp-Pro-bonds. Compared to the corresponding human chains we found only 13 substitutions in the alpha-chains, but 27 in the beta-chains. The amino-acid residues substituted in the alpha-chains are not involved in any contacts, whereas in the beta-chains, one exchange involves a heme contact, three alpha 1/beta 1- and one alpha 1/beta 2-contacts, the latter [beta 43(CD2)-Glu----Thr] brings for the first time threonine in this position of the beta-chains. Comparison with the Egyptian Fruit Bat (Rousettus aegyptiacus) shows 12 and 25 substitutions in the alpha- and beta-chains, respectively, suggesting a large phylogenetic distance between Micro- and Megachiroptera. We consider this primary structure as a contribution towards solving the problem of the origin of bats and their relation to primates.     

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.     

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.