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.     

Primary structure of a dimeric haemoglobin from the deep-sea cold-seep clam Calyptogena soyoae.

The heterodont clam Calyptogena soyoae, living in the cold-seep area of the upper bathyal depth of Sagami Bay, Japan, has two homodimeric haemoglobins (Hb I and Hb II) in erythrocytes. The complete amino acid sequence of 136 residues of C. soyoae Hb II was determined. The sequence showed low homology with any other globins (at most 20% identity) and lacked the N-terminal extension of seven to nine amino acid residues characteristic of all the molluscan haemoglobins sequenced hitherto. Although the subunit assembly of molluscan haemoglobin is known to be 'back-to-front' relative to vertebrate haemoglobin, C. soyoae Hb II is unlikely to undergo such a subunit assembly because it lacks homology in the sequence involving subunit interaction. These structural features suggest that C. soyoae haemoglobin may have accomplished a unique molecular evolution. The distal (E7) histidine residue of C. soyoae Hb II is unusually replaced by glutamine. However, the oxyhaemoglobin is stable enough to act as an O2 carrier, since the autoxidation rate at near physiological temperature (3 degrees C) is about 3 times lower than that of human haemoglobin at 37 degrees C. H.p.l.c. patterns of peptides (Figs. 5-7), amino acid compositions of intact protein and peptides (Table 1) and amino acid sequences of intact protein and peptides (Tables 2 and 3) have been deposited as Supplementary Publication SUP 50150 (11 pages) at the British Library Document Supply Centre, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies may be obtained on the terms indicated in Biochem. J. (1989) 257, 5.     

Amino acid sequence of a major globin from the sea cucumber Paracaudina chilensis

The sea cucumber Paracaudina chilensis (Echinodermata) contains three major globins I, II and III in coelomic cells. The complete amino acid sequence of globin I has been determined. It is composed of 157 amino acid residues, is acetylated at the N-terminus, and has a characteristic N-terminal extension of 9-10 residues when compared with vertebrate globins. The sequence of Paracaudina globin I showed slightly higher homology with human alpha globin (25%) rather than with the invertebrate Anadara alpha globin (22%). Paracaudina globin I also showed strong homology (59%) with globin D from another sea cucumber, Molpadia arenicola (Mauri, F.C. (1985) Ph.D. dissertation, University of Texas). The globin sequences from the phylum Echinodermata have an important position in the molecular evolution of the globins, because they are the invertebrate group most closely related to the vertebrates.     

Axolotl hemoglobin: cDNA-derived amino acid sequences of two alpha globins and a beta globin from an adult Ambystoma mexicanum

Erythrocytes of the adult axolotl, Ambystoma mexicanum, have multiple hemoglobins. We separated and purified two kinds of hemoglobin, termed major hemoglobin (Hb M) and minor hemoglobin (Hb m), from a five-year-old male by hydrophobic interaction column chromatography on Alkyl Superose. The hemoglobins have two distinct alpha type globin polypeptides (alphaM and alpham) and a common beta globin polypeptide, all of which were purified in FPLC on a reversed-phase column after S-pyridylethylation. The complete amino acid sequences of the three globin chains were determined separately using nucleotide sequencing with the assistance of protein sequencing. The mature globin molecules were composed of 141 amino acid residues for alphaM globin, 143 for alpham globin and 146 for beta globin. Comparing primary structures of the five kinds of axolotl globins, including two previously established alpha type globins from the same species, with other known globins of amphibians and representatives of other vertebrates, we constructed phylogenetic trees for amphibian hemoglobins and tetrapod hemoglobins. The molecular trees indicated that alphaM, alpham, beta and the previously known alpha major globin were adult types of globins and the other known alpha globin was a larval type. The existence of two to four more globins in the axolotl erythrocyte is predicted.     

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.     

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.     

The hemoglobin gene of the deep-sea clam Calyptogena soyoae has a novel intron in A-helix

The cDNAs encoding two dimeric hemoglobins, Hbs I and II, of the deep-sea clam Calyptogena soyoae were amplified by PCR and the complete nucleotide sequences determined. The cDNA-derived amino acid sequences agreed completely with those determined chemically. Many of the molluscan intracellular globin genes have a characteristic four-exon/three-intron structure, with the precoding and two conventional introns conserved widely in animal globin genes. In this work we have determined the exon/intron organization of two hemoglobin genes of the deep-sea clam C. soyoae. Surprisingly, this gene has no precoding intron but instead contains an additional intron in the A-helix (A3.1), together with the two conventional introns (B12.2 and G6.3). This observation suggests that the precoding intron has been lost and the insertion of intron in A-helix occurred in the genes of Calyptogena. Alternatively, the sliding of intron from precoding to A-helix might have occurred.     

The hemoglobin gene of the deep-sea clam Calyptogena soyoae has a novel intron in A-helix

The cDNAs encoding two dimeric hemoglobins, Hbs I and II, of the deep-sea clam Calyptogena soyoae were amplified by PCR and the complete nucleotide sequences determined. The cDNA-derived amino acid sequences agreed completely with those determined chemically. Many of the molluscan intracellular globin genes have a characteristic four-exon/three-intron structure, with the precoding and two conventional introns conserved widely in animal globin genes. In this work we have determined the exon/intron organization of two hemoglobin genes of the deep-sea clam C. soyoae. Surprisingly, this gene has no precoding intron but instead contains an additional intron in the A-helix (A3.1), together with the two conventional introns (B12.2 and G6.3). This observation suggests that the precoding intron has been lost and the insertion of intron in A-helix occurred in the genes of Calyptogena. Alternatively, the sliding of intron from precoding to A-helix might have occurred.     

Prosimian hemoglobins. III. The primary structures of the duplicated alpha-globin chains of Lemur variegatus

The amino acid sequences of the alpha chains of hemoglobins purified from Lemur variegatus erythrocytes have been determined. The sequences were determined primarily from peptides generated from treatment of the isolated alpha chains with cyanogen bromide or warm formic acid. The ordering of the peptides from both alpha globins was based on the homology between lemur hemoglobins and those of other primates. The genetic difference at position 15 (Asn vs. Lys) explains the phenotypic characteristic of two hemoglobin species during alkaline electrophoresis. The function of certain residues is discussed in the context of other known sequences. The dispersion of the amino acid changes noted in lemur species falls mostly within the first 75 residues of the alpha chain (exons 1 and 2). The extent of divergence of the L. variegatus alpha-globin chains from the Lemur fulvus alpha globin is similar to that seen for the beta-globin chains of these species. This degree of separation (11-16 residues) is consistent with an extended period of independent evolution by these congeneric species after their divergence.     

Variant subunit specificity in the quaternary structure of Artemia hemoglobin

The brine shrimp Artemia has three extracellular hemoglobins (Hbs) that are developmentally expressed and exhibit distinct oxygen-binding characteristics (Heip, Moens, and Kondo 1978; Heip et al. 1978 ). These Hbs are composed of two polymers, each of which comprises nine covalently linked globin domains. Although the cDNA sequences of two nine-domain globins from Artemia have been published, there is evidence for the existence of further expressed globin genes (Manning, Trotman, and Tate 1990 ). In the present study extensive analysis at the cDNA and genomic levels was performed in order to determine the globin gene copy number in Artemia. Sequence and Southern analysis suggest that four Hb polymers (T1, T2, C1, and C2) are expressed in Artemia. In addition, there is also at least one globin pseudogene. Protein sequencing of the native Hbs revealed that there are limitations on which two polymers can associate. The composition of the Hbs has been determined to be: Hb I, C1C2; Hb II, C1T2; and Hb III, T1T2. These pairings allow the levels of the three Artemia Hbs to be regulated independently by polymer expression alone, therefore explaining the previously inconsistent developmental and hypoxia-induced expression patterns.     

A structural domain of the covalent polymer globin chains of artemia. Interpretation of amino acid sequence data

Artemia is unusual in having extracellular hemoglobins of Mr 260,000 comprising two globin chains (Mr 130,000), each of which is a polymer of eight covalently linked domains of about Mr 16,000. The amino acid sequence of one of these domains (E1) has been determined. It has 147 residues and Mr of 17,574 including heme. Sequence alignment revealed 19.0% identity with sperm whale myoglobin, whereas other vertebrate and invertebrate globins had between 13 and 24% identity. However, a much higher percentage of residues has a similar side chain character, suggesting that the domain E1 is very similar to other globins in showing the myoglobin fold. Template model building based on the known three-dimensional structure of myoglobin further supports this conclusion. Conversely, the differences between E1 and other globins are believed to reflect differences in the packing of the domains, first in a covalent polymeric subunit containing eight hemes and subsequently by association of two of these subunits as dimers. These findings provide further evidence for the versatility of the myoglobin fold.     

The complete amino acid sequences of four globins from the land leech Haemadipsa zeylanica var. japonica

The amino acid sequences of four globins from the land leech, Haemadipsa zeylanica var. japonica, were determined using nucleotide sequencing and protein sequencing. The mature globin-molecules were composed of 146 amino acid residues for M-1 globin, 156 for M-2 globin, 143 for D-1 globin, and 149 for D-2 globin. Alignment of the four kinds of globins by Clustal X revealed 22 invariant amino acids. The four globins were 26–33% identical. A striking feature of amino acid alteration was: the replacement of the E7 distal-His of D-1 globin by phenylalanine because histidine is conserved among the rest of the globins of H. zeylanica, those of other representative species (Lumbricus and Tylorrhynchus) of Annelida and most other hemoglobins. A phylogenetic tree constructed of 18 globin structures including two species of leeches, H. zeylanica (a land leech) and Macrobdella decora (a freshwater leech), T. heterochaetus (a representative species of polychaetes), L. terrestris (a representative species of oligochaetes), and human α and β globins strongly indicated that the leech globins first separated from globin lineage of annelids.     

Unique features of the hemoglobin system of the Antarctic notothenioid fish Gobionotothen gibberifrons.

The hemolysate of the Antarctic teleost Gobionotothen gibberifrons (family Nototheniidae) contains two hemoglobins (Hb 1 and Hb 2). The concentration of Hb 2 (15-20% of the total hemoglobin content) is higher than that found in most cold-adapted Notothenioidei. Unlike the other Antarctic species so far examined having two hemoglobins, Hb 1 and Hb 2 do not have globin chains in common. Therefore this hemoglobin system is made of four globins (two alpha- and two beta-chains). The complete amino-acid sequence of the two hemoglobins (Hb 1, alpha2(1)beta2(1); Hb 2, alpha2(2)beta2(2)) has been established. The two hemoglobins have different functional properties. Hb 2 has lower oxygen affinity than Hb 1, and higher sensitivity to the modulatory effect of organophosphates. They also differ thermodynamically, as shown by the effects on the oxygen-binding properties brought about by temperature variations. The oxygen-transport system of G. gibberifrons, with two functionally distinct hemoglobins, suggests that the two components may have distinct physiological roles, in relation with life style and the environmental conditions which the fish may have to face. The unique features of the oxygen-transport system of this species are reflected in the phylogeny of the hemoglobin amino-acid sequences, which are intermediate between those of other fish of the family Nototheniidae and of species of the more advanced family Bathydraconidae.     

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.     

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.     

Globin gene family evolution and functional diversification in annelids

Globins are the most common type of oxygen-binding protein in annelids. In this paper, we show that circulating intracellular globin (Alvinella pompejana and Glycera dibranchiata), noncirculating intracellular globin (Arenicola marina myoglobin) and extracellular globin from various annelids share a similar gene structure, with two conserved introns at canonical positions B12.2 and G7.0. Despite sequence divergence between intracellular and extracellular globins, these data strongly suggest that these three globin types are derived from a common ancestral globin-like gene and evolved by duplication events leading to diversification of globin types and derived functions. A phylogenetic analysis shows a distinct evolutionary history of annelid extracellular hemoglobins with respect to intracellular annelid hemoglobins and mollusc and arthropod extracellular hemoglobins. In addition, dehaloperoxidase (DHP) from the annelid, Amphitrite ornata, surprisingly exhibits close phylogenetic relationships to some annelid intracellular globins. We have characterized the gene structure of A. ornata DHP to confirm assumptions about its homology with globins. It appears that it has the same intron position as in globin genes, suggesting a common ancestry with globins. In A. ornata, DHP may be a derived globin with an unusual enzymatic function.     

Amino acid sequence of the monomer subunit of the giant multisubunit hemoglobin from the earthworm Pheretima sieboldi

The giant extracellular hemoglobin of the earthworm Pheretima sieboldi is mainly composed of two heme-containing subunits: a monomer; chain I and a disulfide-bonded trimer of chains II, III and IV. Both subunits can be separated easily by gel filtration under alkaline conditions. The amino acid sequence of chain I has been determined. It is composed of 141 residues, has two half-cystine residues forming a intrachain disulfide bridge, and has a molecular mass of 16911 Da including a heme group. Heterogeneity was found at position 37 (His or Ser). The amino acid sequence of Pheretima chain I showed 30-50% identity with those of eight heme-containing chains of Lumbricus and Tylorrhynchus hemoglobins. The sequences of nine chains of annelid giant hemoglobins were compared separately in the functionally essential central exonic region and structurally essential side exonic regions, and a phylogenetic tree was constructed. The amino acid substitution rate for the central exon was found to be about 1.5 times slower than that for the side exons.     

The heterogeneity of the polymeric intracellular hemoglobin of Glycera dibranchiata and the cDNA-derived amino acid sequence of one component

The erythrocytes of the marine polychaete Glycera dibranchiata contain a number of different, single-chain hemoglobins, some of which self-associate into a 'polymeric' fraction. An oligodeoxynucleotide probe was synthesized based on partial amino acid sequences determined by chemical methods, and used to screen a cDNA library constructed from the poly(A+)mRNA of Glycera erythrocytes (Simons, P.C. and Satterlee, J.D. (1989) Biochemistry 28, 8525-8530). The longest positive inserts found were sequenced using the dideoxy nucleotide chain termination method. One complete clone was obtained: clone 5A, 816 bases long, contained 59 bases of 5'-untranslated RNA, an open reading frame of 441 bases coding for 147 amino acids and a 3'-untranslated region of 316 bases. The derived amino acid sequence of Glycera globin P1 was in agreement with the partial amino acid sequences obtained by chemical methods. Three additional inserts obtained in the screening were also sequenced: the inferred amino acid sequences proved to be partial globin sequences which were different from each other and from the sequence of P1. Thus, the 'polymeric' fraction of the intracellular hemoglobin of Glycera probably consists of at least four different globin chains much like the 'monomeric' fraction. Comparison of the 'polymeric' sequence with the two known 'monomeric' sequences, M-II and M-IV, shows that they share 54 identical residues. At 74 positions, the identical residues in M-II and M-IV differ from the corresponding residue in P1, including at E-7, where P1 has a distal His, in contrast to Leu in M-II and M-IV. The alignment of Bashford et al. ((1987) J. Mol. Biol. 196, 199-216) and their templates were used to examine the principal differences between the two types of Glycera globin sequences. They appear to consist of uncommon surface amino acid residues at positions C6 (Phe vs. Ala), E10 (Val vs. Lys), E17 (Lys vs. Val), G1 (Arg vs. Lys), G10 (Met vs. Ala) and H5 (Arg vs. Lys). One or more of these residues could be responsible for the self-association exhibited by the 'polymeric' Glycera globins.     

The primary structures of the major and minor hemoglobin-components of adult Andean goose (Chloephaga melanoptera, Anatidae): the mutation Leu----Ser in position 55 of the beta-chains

The primary structures of the hemoglobin components Hb A and Hb D of the adult Andean Goose (Chloephaga melanoptera) are presented. The globin chains were separated on CM-Cellulose in 8M urea buffer. The amino-acid sequences were established by automatic Edman degradation of the globin chains and of the tryptic peptides in liquid- and gas-phase sequenators. The sequences are aligned with those of Greylag Goose (Anser anser) as a biological reference and other sequences of birds. A detailed evaluation of all residues of Andean Goose hemoglobins on the basis of the 12000 known avian globin sequences leads to a molecular pattern for high-altitude respiration of geese. The replacement of functional and structural importance is the unique occurrence of the residue beta 55 Leu----Ser (all other exchanges are functionally neutral), interrupting the same alpha 1 beta 1-interface contact (alpha 119-beta 55) that accounts for high-altitude respiration of the Barheaded Goose (Anser indicus); there the mutation is found on alpha A 119. Loosening the constraints of this interface must be interpreted as a destabilization of the low-affinity T-structure in favour of the high-affinity R-structure. The structural and functional significance of this interface for the molecular biology of high-altitude respiration of the Andean Goose and Barheaded Goose is discussed. Since Hb A consists of alpha A2 beta 2 and Hb D consists of alpha D2 beta 2 the mutation occurring in blood of the Andean Goose affects both hemoglobins whereas in the case of the Barheaded Goose only Hb A is affected. These results show that Hb D can be considered a biological reserve to enlarge situatively the normal hemoglobin function. A general molecular pattern for permanent (selective advantage of high intrinsic oxygen affinity) and transitory (selective advantage of graded oxygen affinities) adaptation to hypoxia is discussed. A survey on the sequence homology of the globin chains of geese (Anserinae) and ducks (Anatinae) is given.