Amino acid sequence of myoglobin from the chitonLiolophura japonica and a phylogenetic tree for molluscan globins

Myoglobin was isolated from the radular muscle of the chitonLiolophura japonica, a primitive archigastropodic mollusc.Liolophura contains three monomeric myoglobins (I, II, and III), and the complete amino acid sequence of myoglobin I has been determined. It is composed of 145 amino acid residues, and the molecular mass was calculated to be 16,070 D. The E7 distal histidine, which is replaced by valine or glutamine in several molluscan globins, is conserved inLiolophura myoglobin. The autoxidation rate at physiological conditions indicated thatLiolophura oxymyoglobin is fairly stable when compared with other molluscan myoglobins. The amino acid sequence ofLiolophura myoglobin shows low homology (11–21%) with molluscan dimeric myoglobins and hemoglobins, but shows higher homology (26–29%) with monomeric myoglobins from the gastropodic molluscsAplysia, Dolabella, andBursatella. A phylogenetic tree was constructed from 19 molluscan globin sequences. The tree separated them into two distinct clusters, a cluster for muscle myoglobins and a cluster for erythrocyte or gill hemoglobins. The myoglobin cluster is divided further into two subclusters, corresponding to monomeric and dimeric myoglobins, respectively.Liolophura myoglobin was placed on the branch of monomeric myoglobin lineage, showing that it diverged earlier from other monomeric myoglobins. The hemoglobin cluster is also divided into two subclusters. One cluster contains homodimeric, heterodimeric, tetrameric, and didomain chains of erythrocyte hemoglobins of the blood clamsAnadara, Scapharca, andBarbatia. Of special interest is the other subcluster. It consists of three hemoglobin chains derived from the bacterial symbiont-harboring clamsCalyptogena andLucina, in which hemoglobins are supposed to play an important role in maintaining the symbiosis with sulfide bacteria.     

Abalone myoglobins evolved from indoleamine dioxygenase: The cDNA-derived amino acid sequence of myoglobin fromNordotis madaka

The cDNA for the unusual 41 kD myoglobin of the abaloneNordotis madaka was amplified by polymerase chain reaction (PCR), and the cDNA-derived amino acid sequence of 378 residues was determined. As with the myoglobin of the related abaloneSulculus diversicolor (Suzuki and Takagi,J. Mol. Biol. 228, 698–700, 1992), the sequence ofNordotis myoglobin showed no significant homology with any other globins, but showed high homology (35% identity) with vertebrate indoleamine 2,3-dioxygenase, a tryptophan degrading enzyme containing heme. The amino acid sequence homology betweenNordotis andSulculus myoglobins was 87%. These results support our previous idea that the abalone myoglobins evolved from a gene for indoleamine dioxygenase, but not from a globin gene, and therefore all of the hemoglobins and myoglobins are not homologous. Thus, abalone myoglobins appear to be a typical case of convergent evolution.     

Amino acid sequence of myoglobin from the molluscBursatella leachii

The complete amino acid sequence of myoglobin from the triturative stomach of gastropodic molluscBursatella leachii has been determined. It is composed of 146 amino acid residues, is acetylated at the N-terminus, and contains a single histidine residue at position 95 which corresponds to the heme-binding proximal histidine. The E7 distal histidine, which is conserved widely in myoglobins and hemoglobins, is replaced by valine inBursatella myoglobin. The amino acid sequence ofBursatella myoglobin shows strong homology (73–84%) with those ofAplysia andDolabella myoglobins.     

Abalone myoglobins evolved from indoleamine dioxygenase: The cDNA-derived amino acid sequence of myoglobin fromNordotis madaka

The cDNA for the unusual 41 kD myoglobin of the abaloneNordotis madaka was amplified by polymerase chain reaction (PCR), and the cDNA-derived amino acid sequence of 378 residues was determined. As with the myoglobin of the related abaloneSulculus diversicolor (Suzuki and Takagi,J. Mol. Biol. 228, 698–700, 1992), the sequence ofNordotis myoglobin showed no significant homology with any other globins, but showed high homology (35% identity) with vertebrate indoleamine 2,3-dioxygenase, a tryptophan degrading enzyme containing heme. The amino acid sequence homology betweenNordotis andSulculus myoglobins was 87%. These results support our previous idea that the abalone myoglobins evolved from a gene for indoleamine dioxygenase, but not from a globin gene, and therefore all of the hemoglobins and myoglobins are not homologous. Thus, abalone myoglobins appear to be a typical case of convergent evolution.     

Amino acid sequence of myoglobin from the molluscBursatella leachii

The complete amino acid sequence of myoglobin from the triturative stomach of gastropodic molluscBursatella leachii has been determined. It is composed of 146 amino acid residues, is acetylated at the N-terminus, and contains a single histidine residue at position 95 which corresponds to the heme-binding proximal histidine. The E7 distal histidine, which is conserved widely in myoglobins and hemoglobins, is replaced by valine inBursatella myoglobin. The amino acid sequence ofBursatella myoglobin shows strong homology (73–84%) with those ofAplysia andDolabella myoglobins.     

The cDNA-derived amino acid sequence of indoleamine dioxygenase like-myoglobin from the gastropod molluscOmphalius pfeifferi

Myoglobin was isolated from the radular muscle of the archaegastropod molluscOmphalius pfeifferi (Trochidae). The molecular mass was estimated by SDS-PAGE to be about 40 kDa, 2.5 times larger than that of usual myoglobin. The cDNA forOmphalius myoglobin was amplified by polymerase chain reaction, and the cDNA-derived amino acid sequence of 375 residues was determined, of which 73 residues were identified directly by the chemical sequencing of internal peptides. The amino acid sequence ofOmphalius myoglobin showed no significant homology with any other usual 16-kDa globins, but showed 84% and 36% identities with indoleamine dioxygenase-like myoglobins fromBattilus (Turbinidae) andSulculus (Haliotiidae), respectively. It also shows significant homology (26% identity) with human indoleamine 2,3-dioxygenase, a tryptophan-degrading enzyme containing heme. The distribution of indoleamine dioxygenase-like myoglobins suggests that they must have arisen exclusively along the specified lineage including the three families Haliotiidae, Turbinidae, and Trochidae of Archaegastropoda in molluscan evolution.     

The cDNA-derived amino acid sequence of indoleamine dioxygenase like-myoglobin from the gastropod molluscOmphalius pfeifferi

Myoglobin was isolated from the radular muscle of the archaegastropod molluscOmphalius pfeifferi (Trochidae). The molecular mass was estimated by SDS-PAGE to be about 40 kDa, 2.5 times larger than that of usual myoglobin. The cDNA forOmphalius myoglobin was amplified by polymerase chain reaction, and the cDNA-derived amino acid sequence of 375 residues was determined, of which 73 residues were identified directly by the chemical sequencing of internal peptides. The amino acid sequence ofOmphalius myoglobin showed no significant homology with any other usual 16-kDa globins, but showed 84% and 36% identities with indoleamine dioxygenase-like myoglobins fromBattilus (Turbinidae) andSulculus (Haliotiidae), respectively. It also shows significant homology (26% identity) with human indoleamine 2,3-dioxygenase, a tryptophan-degrading enzyme containing heme. The distribution of indoleamine dioxygenase-like myoglobins suggests that they must have arisen exclusively along the specified lineage including the three families Haliotiidae, Turbinidae, and Trochidae of Archaegastropoda in molluscan evolution.     

Evidence of met-form myoglobin from Theliostyla albicilla radular muscle

Gastropod mollusc myoglobins provide interesting clues to the evolution of this family of proteins. In addition to conventional monomeric myoglobins, this group also has dimeric and unusual indoleamine dioxygenase-like myoglobins. We isolated myoglobin from the radular muscle of living gastropod mollusc Theliostyla albicilla. The myoglobin appeared to be present in an oxidized met-form, a physiologically inactive form that is not capable of binding oxygen. Under the same extraction conditions, myoglobins mainly of the physiologically active oxy-form have been isolated from other molluscs. The complete amino acid sequence of 157 residues of Theliostyla myoglobin shows that it has a long N-terminal extension of seven residues and contains three functional key residues: CD1-Phe, E7-His, and F8-His. The metmyoglobin can easily be reduced to a ferrous state with Na(2)S(2)O(4). The autoxidation rate of the oxy-form was comparable to other molluscan myoglobins over a wide pH range, and Theliostyla myoglobin was shown to be stable as an oxygen-binding protein. Thus, the predominantly met-form of myoglobin in Theliostyla can be attributed to the incomplete functioning of the myoglobin reduction system in the radular muscle. Although the function of Theliostyla myoglobin is unclear, it may be a scavenger of H(2)O(2).     

The hemoglobins of phoronopsis viridis, of the primitive invertebrate phylum phoronida: characterization and subunit structure.

The primitive invertebrate, Phoronopsis viridis, of the phylum Phoronida, has intra-cellular hemoglobins composed of four unique polypeptide chains, two of which associate to form hetero- and homodimers and two which do not associate at all. The CO-derivatives of the associating chains are completely dimeric; removal of the ligand does not result in further aggregation as it does in several other invertebrate hemoglobins. Oxidation of the associating hemoglobins is accompanied by dissociation to monomers, but the cyanide derivative of the methemoglobin is dimeric. The four polypeptide chains all have molecular weights of about 16,000 as determined by iron content and gel electrophoresis with sodium dodecyl sulfate. The two associating chains form three components with isoelectric points at pH 5.6, 5.9, and 6.9 whereas those for the two monomeric chains are at pH 6.2 and 7.9. The chains have been characterized by amino acid composition, tryptic peptide patterns, and the amino acid sequence of the NH₂-terminal segment. The oxygen equilibrium of a dimeric fraction has been determined at pH 7.5 and 20 °C; the pressure of half-saturation is 2.3 mm Hg.     

Primary structure of chain I of the heterodimeric hemoglobin from the blood clamBarbatia virescens

The blood clamBarbatia virescens has a heterodimeric hemoglobin in erythrocytes. Interestingly, the congeneric clamsB. reeveana andB. lima contain quite different hemoglobins: tetramer and polymeric hemoglobin consisting of unusual didomain chain. The complete amino acid sequence of chain I ofB. virescens has been determined. The sequence was mainly determined from CNBr peptides and their subpeptides, and the alignment of the peptides was confirmed by sequencing of PCR-amplified cDNA forB. virescens chain I. The cDNA-derived amino acid sequence matched completely with the sequence proposed from protein sequencing.B. virescens chain I is composed of 156 amino acid residues, and the molecular mass was calculated to be 18,387 D, including a heme group. The sequence ofB. virescens chain I showed 35–42% sequence identity with those of the related clamAnadara trapezia and the congeneric clamB. reeveana. An evolutionary tree forAnadara andBarbatia chains clearly indicates that all of the chains are evolved from one ancestral globin gene, and that the divergence of chains has occurred in each clam after the speciation. The evolutionary rate for clam hemoglobins was estimated to be about four times faster than that of vertebrate hemoglobin. We suggest that blood clam hemoglobin is a physiologically less important molecule when compared with vertebrate hemoglobins, and so it evolved rapidly and resulted in a remarkable diversity in quaternary and subunit structure within a relatively short period.     

Studies on the evolutionary relationships between hemoglobins inChironomus pallidivittatus andC. Tentans

Summary The monomeric hemoglobins ofChironomus tentans andC. pallidivittatus have been isolated and separated into their respective components by gel chromatography on Sephadex G-75 and ion-exchange chromatography on DEAE-Sephacel. The amino acid compositions of the purified components are given. The sequence of the 30 N-terminal amino acid residues of one of the monomeric components (Hb I fromC. pallidivittatus) was determined and found to be identical in almost all of its parts with the monomeric hemoglobins ofC. thummi (CTT III and CTT IV).Antibodies against the monomeric hemoglobins Hb I and Hb IIc and the dimeric fraction were highly specific and no cross reaction between dimeric and monomeric hemoglobins could be demonstrated. The antibodies against the monomers crossreact with the monomeric hemoglobins CTT III and CTT IV ofC. thummi. Taken together with genetic data, the immunological results indicate that divergence of monomeric from dimeric forms was an early event in the evolution of the various hemoglobins inChironomus.     

Aplysia myoglobins with an unusual amino acid sequence

The complete amino acid sequence of the myoglobin from Aplysia juliana, a species distributed world-wide, has been determined and compared with the sequence of the myoglobin of Aplysia limacina, a Mediterranean species, and of Aplysia kurodai, a Japanese and Asian species. Unlike mammalian myoglobins, Aplysia myoglobins contain only a single histidine residue, lacking the distal one, the homology being 76% between A. juliana and A. limacina, 74% between A. juliana and A. kurodai, and 83% between A. limacina and A. kurodai. The hydropathy profiles of the Aplysia myoglobins are very similar, but completely different from that of sperm whale myoglobin, taken as the reference.     

Primary structure of chain I of the heterodimeric hemoglobin from the blood clamBarbatia virescens

The blood clamBarbatia virescens has a heterodimeric hemoglobin in erythrocytes. Interestingly, the congeneric clamsB. reeveana andB. lima contain quite different hemoglobins: tetramer and polymeric hemoglobin consisting of unusual didomain chain. The complete amino acid sequence of chain I ofB. virescens has been determined. The sequence was mainly determined from CNBr peptides and their subpeptides, and the alignment of the peptides was confirmed by sequencing of PCR-amplified cDNA forB. virescens chain I. The cDNA-derived amino acid sequence matched completely with the sequence proposed from protein sequencing.B. virescens chain I is composed of 156 amino acid residues, and the molecular mass was calculated to be 18,387 D, including a heme group. The sequence ofB. virescens chain I showed 35–42% sequence identity with those of the related clamAnadara trapezia and the congeneric clamB. reeveana. An evolutionary tree forAnadara andBarbatia chains clearly indicates that all of the chains are evolved from one ancestral globin gene, and that the divergence of chains has occurred in each clam after the speciation. The evolutionary rate for clam hemoglobins was estimated to be about four times faster than that of vertebrate hemoglobin. We suggest that blood clam hemoglobin is a physiologically less important molecule when compared with vertebrate hemoglobins, and so it evolved rapidly and resulted in a remarkable diversity in quaternary and subunit structure within a relatively short period.     

Primary structure of hemoglobin from cobraNaja naja naja

Cobra snakeNaja naja naja hemoglobin shows four bands on Triton electrophoresis. We present the primary structure of oneα and oneβ chain. The separation of polypeptide chains was achieved by ion exchange chromatography on carboxymethyl cellulose column. The amino acid sequence was established by automatic Edman degradation of the native chains and tryptic and hydrolytic peptides in a gas-phase sequencer. The structural data are compared with those of human and other reptile hemoglobins and reveal not only large variations from human but within reptiles. The amino acid exchanges involve several subunit contacts and heme binding sites. This is the first study on the hemoglobin of a land snake. There are only two amino acid sequences of sea snake hemoglobin (Microcephalophis gracilis gracilis andLiophis miliaris) reported in the literature.     

Comparative Studies of the Indoleamine Dioxygenase-like Myoglobin from the Abalone Sulculus diversicolor

The abalone Sulculus diversicolor contains abundant myoglobin in its buccal mass. The myoglobin is homodimeric and the molecular mass of the constituent polypeptide chain is 41,000 Da. The amino acid sequence and gene structure are highly homologous with those of a vertebrate tryptophan-degrading enzyme, indoleamine dioxygenase (IDO). Thus Sulculus myoglobin evolved from an IDO gene, and represents a typical case of functional convergence. The oxygen equilibrium properties of Sulculus myoglobin were examined and compared with those of myoglobins from other sources. It binds oxygen reversibly, and the P₅₀ was determined to be 3.8 mmHg at 20°C and pH 7.4, showing that the oxygen affinity of Sulculus myoglobin is significantly lower than those of usual 16 kDa myoglobins. It also displays no cooperativity (n_max: 1.02–1.06) and no alkaline Bohr effect between pH 7.0 and 7.9. The cDNA-derived amino acid sequences of vertebrate IDOs, molluscan IDO-like myoglobins and a homolog in the yeast Saccharomyces were aligned, and several amino acid residues were proposed as candidates for key residues to control the function of IDO or myoglobin.     

Isolation and cDNA-derived amino acid sequences of hemoglobin and myoglobin from the deep-sea clam Calyptogena kaikoi

The heterodont clam Calyptogena kaikoi, living in the cold-seep area at a depth of 3761 m of the Nankai Trough, Japan, has abundant hemoglobins and myoglobins in erythrocytes and adductor muscle, respectively. Two types of hemoglobins (Hb I and Hb II) were isolated, and the complete amino acid sequences of Hb I (145 residues) and Hb II (137 residues) were obtained with combination of cDNA and protein sequencing. The amino acid sequences of C. kaikoi Hbs I and II differed from homologous chains of the congeneric clam Calyptogena soyoae in eight and five positions, respectively. The distal (E7) His, one of the functionally important residues in hemoglobin and myoglobin, was replaced by Gln in hemoglobins of C. kaikoi. A phylogenetic analysis of clam hemoglobins indicates that the evolutionary rate of Calyptogena hemoglobins is rather faster than those of other clams, suggesting that the mutation rate might be accelerated in the deep-sea animals around the areas of cold seeps or hydrothermal vents. On the other hand, it was found unexpectedly that two myoglobins Mbs I and II, isolated from the red adductor muscle, are identical in amino acid sequence Hbs I and II, respectively. Thus it was assumed that genes for Hbs I and II are also expressed in the muscle of C. kaikoi in substitution for myoglobin gene. This suggests that the major physiological role of globins in C. kaikoi is storage of oxygen under the low oxygen conditions, rather than circulating of oxygen.     

A myoglobin evolved from indoleamine 2,3-dioxygenase.

Hemoglobins and myoglobins are some of the best studied proteins. They are distributed in animals, plants and bacteria, and the characteristic two intron-three exon structure is widely conserved in animal globin genes (Jhiang et al., 1988). To date, all of the hemoglobins and myoglobins are believed to have a common origin, and so they are considered to be homologous. We have isolated a completely new type of myoglobin from the red muscle of the abalone Sulculus diversicolor aquatilis. The myoglobin consists of an unusual 41 kDa polypeptide chain, contains one heme per chain and forms a homodimer under physiological conditions. The cDNA-derived amino acid sequence of Sulculus myoglobin showed no significant homology with any other globins, but, surprisingly, showed high homology (35% identity) with human indoleamine 2,3-dioxygenase, a tryptophan degrading enzyme containing heme. This clearly indicates that Sulculus myoglobin evolved from a gene for indoleamine dioxygenase, but not from a globin gene. Sulculus myoglobin lacks the enzyme activity of indoleamine dioxygenase. However, in the presence of tryptophan, the autoxidation rate of oxymyoglobin was greatly accelerated, suggesting that a tryptophan binding site remains near or in the heme cavity as a relic of the molecular evolution.     

A theoretical method for evaluating the relative importance of positive selection and neutral drift from observed base changes

To evaluate the relative importance of positive selection and neutral drift from the nucleotide base changes observed in the homologous alignment of genes, a theoretical equation of base changes is formulated by including both the influence of selection and the base substitutions due to mutations. Under the assumption that the average rate of base substitutions estimated from synonymous changes is the ``true' mutation rate applicable at all positions, this method is applied to the vertebrate globin gene family, and evaluates the departures of base change rates from the ``true' mutation rate at the first and second codon positions as a consequence of preferential selection for the conservation of important function. In addition to the strong effect of selection on the amino acid residues in the internal region mostly common to myoglobin and hemoglobin chains, the distinctive directions of selective parameter values are seen at sites on the globin surface, distinguishing the subunit contact residues of hemoglobins from the polar residues on the surface of myoglobins. Moreover, this effect of selection distinguishing between the myoglobin and hemoglobin chain genes becomes weaker in cold-blooded vertebrates, especially in fish, strongly suggesting the possibility that the clear distinction between these globins is a result of selection out of the changes regarded as neutral ones in an ancestor of vertebrates. Thus, the present method may also serve to investigate the homology of many other proteins from the aspect of molecular evolution, mainly focusing on the evolution of their biological functions. Received: 2 January 1996 / Accepted: 20 February 1997     

Effect of urea on the kinetics of ligand combination reactions of hemoglobins A and H, alphaSH chains and myoglobin.

In O₂ equilibrium studies of hemoglobin it was observed that the presence of urea increases f₅₀2 and decreases co-operativity. The results were interpreted on the basis of unfolding and swelling of the peptide chains. The results of the present kinetic investigation indicate that while the CO combination rate constants for α^SH chains, hemoglobin H and myoglobin do not change with increasing concentrations of urea, the corresponding rate constants for deoxy hemoglobin A increase continuously with urea concentration. At urea concentrations of 4 m or more, the reaction time course becomes biphasic. The fast component of the reaction time course yields CO combination rate constants which are in close agreement with the rate constants of dimeric and monomeric hemoglobins. These results indicate that up to 4 m-urea the kinetic and equilibria parameters increase due to weakened constraints imposed by intersubunit contacts and bonds. At higher urea concentrations Hb₄ is significantly dissociated into dimers and monomers, and hence the high ligand affinity and decreased co-operativity of the system. The implications of higher ligand combination rate constants of the deoxyhemoglobin tetramer in the presence of urea on the reaction mechanism are discussed.     

CD studies on the reversed heme orientation in monomeric Glycera dibranchiata hemoglobins

Circular dichroism spectra of three monomeric components of Glycera dibranchiata hemoglobins are reported. Contrary to what is found for most hemoglobins and myoglobins, G. dibranchiata hemoglobins display largely negative dichroic spectra in the Soret region. Independent NMR measurements have shown that the same monomeric hemoglobin components contain the heme moiety predominantly (greater than 85%) oriented in a reversed way with respect to the orientation which occurs in most hemoglobins and myoglobins. On the basis of these independent NMR studies, and also of previous data on other invertebrate hemoproteins, a correlation appears evident between reversed heme orientation in hemoglobins and negative ellipticity in the Soret CD spectrum. This represents a simple tool to evaluate this aspect of heme asymmetric environment.