Primary structure of the common polypeptide chain b from the multi-hemoglobin system of the hydrothermal vent tube worm Riftia pachyptila: An insight on the sulfide binding-site

The deep-sea tube worm Riftia pachyptila Jones possesses a multi-hemoglobin system with three different extracellular Hbs: two dissolved in the vascular blood, V1 (ca. 3,500 kDa) and V2 (ca. 400 kDa), and one in the coelomic fluid, C1 (ca. 400 kDa). V1 Hb consists of four heme-containing, globin chains (b–e) and four linker chains (L1–L4). V2 and C1 Hbs are exclusively built from globin chains, six for V2 (a–f) and five for C1 (a–e). The complete amino acid sequence of the isolated monomeric globin chain b, common to all Riftia Hbs, has been determined by automated Edman degradation sequencing of the peptides derived by digestion with trypsin, chymotrypsin, thermolysin, and CNBr. This polypeptide chain is composed of 144 amino acid residues, providing a Mr of 16, 135.0 Da. Moreover, the primary sequence of chain b revealed 3 Cys residues at position 4, 75, and 134. Cys-4 and Cys-134 are located at positions where an intra-chain disulfide bridge is formed in all annelid, vestimentiferan, or pogonophoran chains, but Cys-75 is located at a unique position only found in three globin chains belonging to Lamellibrachia and Oligobrachia, a vestimentiferan and a pogonophoran. In both groups, Hbs can bind sulfide reversibly to fuel the chemosynthetic process of the symbiotic bacteria they harbor. Sulfide-binding experiments performed on purified Hb fractions (i.e., V1, V2, and C1 Hbs) suggest that free Cys residues on globin chains, and the numerous Cys found in linker chains, as determined previously by ESI-MS, may be the sulfide binding-sites. Blocking the free Cys by N-ethylmaleimide, we confirmed that free cysteines were involved in sulfide-binding but did not account for the whole sulfide-binding capacity of V1 Hb. Furthermore, a phylogenetic tree was constructed from 18 globin-like chains of annelid, vetimentiferan, and pogonophoran extracellular Hbs to clarify the systematic position of tubeworms. Riftia chain b clearly belongs to the “strain A” family with 30 to 80% identity with the other sequences analyzed. Its position in the tree confirmed a close relationship between vestimentiferan, pogonophoran, and annelid Hbs. Proteins 29:562–574, 1997. © 1997 Wiley-Liss, Inc.     

Amino acid sequence of the monomer subunit of the extracellular hemoglobin of Lumbricus terrestris

The giant extracellular hemoglobin (3,800 kDa) of the oligochaete Lumbricus terrestris consists of four subunits: a monomer (chain I), two subunits each of about 35 kDa (chains V and VI), and a disulfide-bonded trimer (50 kDa) of chains II, III, and IV. The complete amino acid sequence of chain I was determined: it consists of 142 amino acid residues and has a molecular weight of 16,750 including a heme group. Fifty-nine residues (42%) were found to be identical with those in the corresponding positions in Lumbricus chain II (Garlick, R. L., and Riggs, A. F. (1982) J. Biol. Chem. 257, 9005-9015); 45 (32%), 56 (40%), 44 (31%), and 45 (32%) residues were found to be in identical positions in the sequences of chains I, IIA, IIB, and IIC, respectively, of Tylorrhynchus heterochaetus hemoglobin (Suzuki, T., and Gotoh, T. (1986) J. Biol. Chem. 261, 9257-9267). When the sequences of all six annelid chains are compared, 18 invariant residues are found in the first 104 residues of the molecule; very little homology exists among the annelid chains in the carboxyl-terminal 38-residue region. Nine of the 18 invariant residues are also found in the human beta-globin chain.     

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.     

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.     

Recombination of embryonic haemoglobin chains during the development of the chick.

Embryonic differentiation is at present interpreted as the expression of variable gene activity. It is commonly thought that derepression of operator gene groups is the main cause of progress during development. However it is equally possible that gene repression plays a role in the appearance of new phenotypic characteristics. This paper illustrates such a possibility. It is known that in chickens embryonic haemoglobins exist which are replaced by other haemoglobins at about the sixth day of incubation. Analyses of globin chain composition of these haemoglobins by chromatography and urea/starch gel electrophoresis as well as TLC-fingerprinting and amino acid analyses of the individual globin chains showed that the haemoglobin switch was not associated with appearance of new globin chains but rather with disappearance of a number of embryonic chains. Moreover the relative proportion of the various chains changed at that time. From these findings we conclude that new haemoglobins arise from a recombination ('hybridization in vivo') of those globin chains which remain after the repression of a gene coding for embryonic chains.     

Primary structure of a linker subunit of the tube worm 3000-kDa hemoglobin

The deep-sea tube worm Lamellibrachia contains two giant extracellular hemoglobins, a 3000-kDa hemoglobin and a 440-kDa hemoglobin. The former consists of four heme-containing chains (AI-AIV) and two linker chains (AV and AVI) for the assembly of the heme-containing chains. The 440-kDa hemoglobin consists of only four heme-containing chains (Suzuki, T., Takagi, T., and Ohta, S. (1988) Biochem. J. 255, 541-545). The complete amino acid sequence of a linker subunit (chain AV) has been determined by automated Edman sequencing of the peptides derived by digestions with lysyl endopeptidase and endoproteinase Asp-N. The chain is composed of 224 amino acid residues, and the molecular mass for the protein moiety was calculated to be 24,894 Da. An Asn-X-Thr sequence which is possible as a glycosylation site was suggested at positions 108-110. A computer-assisted homology search showed that the sequence shows no notable homology with any other globins and proteins. However a careful alignment of the linker sequence with a heme-containing chain sequence suggested that there is a slight, but significant homology between the two sequences. The alignment also suggested that the linker resulted from gene duplication of a heme-containing chain with a three exon-two intron structure, and that the first exon of domain 1 and the last exon of domain 2 had been lost during evolution. In our alignment, domain 1 has the heme-binding proximal histidine, but domain 2 does not. This is the first linker subunit to be sequenced completely.     

Haemoglobins of invertebrate tissues. Nerve haemoglobins of Aphrodite, Aplysia and Halosydna

1. The occurrence of haemoglobin in invertebrate nerves is surveyed. Haemoglobin was observed in the nerves and ganglia of the marine nematode Amphiporus sp. and of the polychaet annelid Halosydna sp. 2. Haemoglobins from the nerve and ganglia of the polychaet annelid Aphrodite aculeata L. and from the nerve of the gastropod mollusc Aplysia californica have been partially purified. The haem in each case was identified as iron protoporphyrin IX. 3. The minimum molecular weight of Aphrodite nerve haemoglobin deduced from the haem content and amino acid analysis is 17090, in agreement with the molecular weight 15600+/-1000 determined by sedimentation equilibrium. 4. The molecular weight of Aplysia nerve haemoglobin was determined by sedimentation equilibrium to be 16400+/-1000. 5. The oxygen dissociation curves are hyperbolic. Half-saturation is achieved at 1.1mm. Hg for Aphrodite nerve haemoglobin and at 4.0mm. Hg for Aplysia nerve haemoglobin. The coefficients for partition between carbon monoxide and oxygen are: Aphrodite nerve haemoglobin, 167; Aplysia nerve haemoglobin, 116. 6. The ferrous haemoglobins combine with cyanide. 7. We conclude that the intracellular haemoglobins of muscle and nerve are similar.     

Protein and gene structure of a chlorocruorin chain of Eudistylia vancouverii

The polychaete annelid, Eudistylia vancouverii, contains as oxygen carrier a hexagonal bilayer (HBL) chlorocruorin. One of the globin chains, chain a1, has 142 amino acids (Mr 16,054.99) and its sequence deviates strongly from other nonvertebrate globin sequences. Unprecedented, it displays a Phe at the distal position E7 as well as at position B10, creating a very hydrophobic heme pocket probably responsible for the low oxygen affinity of the native molecule. Phylogenetic analysis of annelid globin chains clearly proves that globin chain a1 belongs to type I of globin chains having a pattern of 3 cysteine residues essential for the aggregation into a HBL structure. The gene coding for globin chain a1 is interrupted by 2 introns at the conserved positions B12.2 and G7.0. Based on protein and gene structure it can therefore be concluded that the globin chains of chlorocruorins are not fundamentally different from other annelid globin chains.     

Rat haemoglobin heterogeneity. Two structurally distinct alpha chains and functional behaviour of selected components.

Six haemoglobins were separated analytically from haemolysates of adult Wistar rats (Rattus norvegicus) by cellulose acetate electrophoresis and preparatively by DEAE-cellulose chromatography. The globin chains were separated from unfractionated haemolysates by CM-cellulose chromatography by using a non-linear formic acid-pyridine gradient followed by CM-cellulose chromatography in 8M-urea by using a gradient of increasing Na+ concentration in phosphate buffer, pH 6.7. Two alpha chains and three non-alpha chains were identified. Chains isolated from purified haemoglobins were correlated with chains isolated from unfractionated haemolysates by electrophoresis on urea-starch gels to make presumptive assignments of the subunit composition of the six haemoglobin tetramers. Partial amino acid sequences were determined for the major and minor alpha chains. The oxygen equilibria of two of the major haemoglobin components and of the unfractionated haemolysate were examined at pH 7.5 and 8.0. The two purified haemoglobins exhibited similar oxygen affinities; the haemolysate, however, had a lower oxygen affinity than either of the two purified haemoglobins. Both the haemolysate and the two haemoglobins showed an alkaline Bohr effect larger than that of human haemoglobin A.     

Chimpanzee foetal haemoglobin: structure and heterogeneity of the gamma chain

The amino acid compositions of soluble tryptic and chymotryptic peptides of the gamma chain of chimpanzee foetal haemoglobin have been determined. The peptides, accounting for all 146 residues of the gamma chain, were found to be identical in composition to the corresponding human gamma chain peptides. As in man, position gamma 136 can be occupied by glycine (G gamma chain) as well as alanine (A gamma chain). The ratio of G gamma to A gamma chains in the infant chimpanzee is approx. 2:1, and in the adult approx. 1:2.     

Amino acid sequence of the beta-chain of the tetrameric haemoglobin of the bivalve mollusc, Anadara trapezia

The amino acid sequence of the beta-chain of the principal haemoglobin from A. trapezia has been determined. The sequence was deduced from the sequences of tryptic peptides, which were fractionated using highperformance liquid chromatography and peptide mapping. Additional sequence data, particularly for the large tryptic peptides, was obtained from enzyme digests of both cyanogen bromide fragments and large citraconyltryptic peptides. The beta-chain has 151 residues which is longer than all the other sequenced haemoglobin chains except the alpha-chain of A. trapezia, which is 153 residues in length. The residues corresponding to those normally in the D helix are absent in this beta-chain. The additional residues are contributed by an extension of the N-terminal region, which was also found to be acetylated. Comparison of the beta-chain amino acid sequence with that of the alpha-chain of A. trapezia, the dimeric chain of A. trapezia, and the dimeric chain of A. broughtonii showed 53% identity in each case. In the E and F helices, the homology is particularly noticeable. There is 100% homology in the F helix of all four chains. The dimeric globin of A. trapezia also shows 100% homology with the beta-chain in the E helix, while the alpha-chain shows 75%. If the tertiary structure of the alpha- and beta-chains of A. trapezia haemoglobin is the same as that of horse haemoglobin, then there are many changes in the alpha 1 and beta 2 contact site residues.     

Amino acid sequence of polypeptide chain IIB of extracellular hemoglobin from the polychaete Tylorrhynchus heterochaetus

The giant extracellular hemoglobin from the polychaete Tylorrhynchus heterochaetus consists of two types of subunits: a "monomeric" chain (chain I) and a disulfide-bonded trimer of chains IIA, IIB, and IIC. The complete amino acid sequence of chain IIB was determined. This chain has 148 amino acid residues and a molecular weight of 17,236 including a heme group. Of the residues in chain IIB, 74 (50%) and 34 (30%) were found to be identical with those in the corresponding positions in Tylorrhynchus chains IIC and I, respectively (Suzuki, T., Furukohri, T., and Gotoh, T. (1985) J. Biol. Chem. 260, 3145-3154). Marked differences were found between the chains of Tylorrhynchus and Lumbricus in the COOH-terminal regions. Significant differences were predicted between the monomeric chain I and the "trimeric" chains (IIB and IIC) in the hydropathy profiles and alpha-helical contents.     

Two new haemoglobins: haemoglobin Perspolis (alpha 64 (E13) Asp leads to Tyr) and haemoglobin J-Kurosh (alpha 19 (AB) Ala leads to Asp).

Two new haemoglobins are described which were found during a regular survey on voluntary blood donors in Iran. They are haemoglobin Perspolis [alpha 64 (E13) Asp leads to Tyr] and haemoglobin J-Kurosh [alpha 19 (AB) Ala leads to Asp]. The amino acid substitution in these two variants was determined by fingerprinting and amino acid analysis of the tryptic peptides and thermolytic peptides derived from abnormal tryptic peptides. Neither haemoglobin was associated with clinical symptoms.     

Primary structure of two linker chains of the extracellular hemoglobin from the polychaete Tylorrhynchus heterochaetus

Two types of linker subunits (linkers 1 and 2) of the extracellular hemoglobin of Tylorrhynchus heterochaetus have been isolated as disulfide-linked homodimers by C18 reverse-phase chromatography. These subunits constituted 6 and 13%, respectively, of total protein area on the chromatogram. The complete amino acid sequences of linkers 1 and 2 were determined by automated Edman sequencing of the peptides derived by digestions with lysyl endopeptidase, trypsin, chymotrypsin, Staphylococcus aureus V8 protease, pepsin, and endoproteinase Asp-N. The linker 1 consisted of 253 amino acid residues (the calculated molecular mass, 28,200 Da), while the linker 2 consisted of 236 residues (26,316 Da). The two chains showed 27% sequence identity. The amino acid sequences of Tylorrhynchus linkers 1 and 2 also showed 23-27% homology with the recently determined sequence of a linker chain of Lamellibrachia hemoglobin (Suzuki, T., Takagi, T., and Ohta, S. (1990) J. Biol. Chem. 265, 1551-1555). In the three linker chains, half-cystine residues were highly conserved; 8 out of 13 residues are identical, suggesting that such residues would contribute to the formation of intrachain disulfide bonds essential for the protein folding of the linker polypeptides. Based on the exact molecular masses of the linker and the heme-containing subunits, the molar ratios estimated for the subunits and the minimum molecular weights per 1 mol of heme, a model is proposed for the subunit structure of the Tylorrhynchus hemoglobin, consisting of 216 polypeptide chains, 192 heme-containing chains, and 24 linker chains.     

Modification by simetryn sulphoxide of a specific thiol group in rat haemoglobin.

Native rat haemoglobins were found to bind simetryn sulphoxide to an extent 40-fold greater than human haemoglobin. This specific behaviour was studied by using only high-pressure ('performance') liquid chromatography for the preparative separation of globin chains and the isolation of peptides resulting from chemical and enzymic degradation. High recoveries (greater than 80%) of peptides throughout the procedures in combination with microsequence techniques, allow a definitive assignment of the residue undergoing modification. The haemoglobin beta-chain cystine-125 residue, with a stoichiometry of one per tetramer of rat haemoglobin, was found to be modified. Stereochemical implications of this finding are discussed. Simetryn sulphoxide would appear to be useful as a specific reagent for the mapping of exposed thiol residues in proteins.     

Different functional modulation by heterotropic ligands (2,3-diphosphoglycerate and chlorides) of the two haemoglobins from fallow-deer (Dama dama).

Two haemoglobin components have been identified and purified from fallow-deer (Dama dama) erythrocytes. They are present in similar amounts and the two tetrameric molecules share the same alpha chain, while two different beta chains are detected in the two components. The beta chains differ by 14 residues, even though they both have 145 amino-acid residues, which account for a molecular mass of 16,023 and 16,064 Da, respectively, while alpha chain has 141 residues, yielding a molecular mass of 15,142 Da. Compared with human Hb, the N-terminal region of both beta chains shows deletion of Val beta 1 and the replacement of His beta 2 by a methionyl residue, a modification which is common to most ruminant haemoglobins. Although both isolated components show a low intrinsic affinity for oxygen, meaningful differences between the two haemoglobins have been found with respect to the effect of heterotropic effectors, such as 2,3-diphosphoglycerate and chloride ions. In view of the high sequence homology between the two components, the different effect of heterotropic ligands has been tentatively correlated to possible localized structural variations between beta chains of the two haemoglobin components.     

A comparative approach to protein-and ligand-dependence of the Root effect for fish haemoglobins

Ligand-binding equilibria, kinetics and (13)C n.m.r. spectra of bound (13)CO, of the haemoglobins from two fishes that are very distant on the evolutionary scale, i.e. the fourth haemoglobin component from Salmo irideus and the single component from Osteoglossum bicirrhosum, were studied. The C-terminal sequence was also determined for the haemoglobin from Osteoglossum. The results show that (i) the C-terminal residues of both chains are not directly responsible for the characteristic heterotropic effect known as Root effect, since for both fish haemoglobins these residues are identical with those of human haemoglobins. (ii) In all haemoglobins characterized by the Root effect a dependence of the (13)CO n.m.r. resonances on pH is observed. However, the extent of the shift(s) depends on the particular protein, and is probably the result of a combination of both tertiary and quaternary conformational changes. (iii) Both haemoglobins from trout and Osteoglossum manifest a functional heterogeneity between the two types of chains in the tetramer, which increases with proton activity. For CO, the effect is very small for trout haemoglobin IV, and very marked for Osteoglossum haemoglobin; for O(2) strongly heterogeneous binding curves were obtained at approx. pH6.2 with both haemoglobins. (iv) Estimations of the relative values of the affinity constants for the alpha and beta chains in the tetramer were obtained for both haemoglobins from (13)CO n.m.r. spectra at low fractional saturation. On the basis of these findings the molecular mechanism underlying the Root effect is discussed.     

Amino acid sequences around the cysteine residue of calf lens α-crystallin

1. Calf lens alpha-crystallin was carboxymethylated with radioactive sodium iodoacetate to label the thiol group. 2. The protein was then digested with trypsin or alternatively fractionated in urea to obtain the acidic (A) chains, which were then digested with trypsin. Either procedure gave two radioactive peptides containing carboxymethylcysteine. 3. These two peptides were closely related: the longer form contained 28 amino acid residues, and the shorter lacked two residues at the N-terminal end of the longer form. 4. The amino acid sequence of the peptides have been determined. 5. No evidence for the presence of more than one cysteine residue/chain was found. 6. The question of the molecular weight of the chains is discussed.     

A partial amino acid sequence for sheep haemoglobin A

Amino acid analysis and terminal-group analysis of tryptic and chymotryptic peptides from sheep haemoglobin A have enabled a partial amino acid sequence to be worked out. By comparing this partial sequence with the known amino acid sequences of human haemoglobins A and F as well as horse slow haemoglobin the most probable sequence of sheep haemoglobin has been deduced.     

Subunit assembly of giant haemoglobin from the polychaete Tylorrhynchus heterochaetus

The subunit assembly of the giant haemoglobin of the polychaete Tylorrhynchus heterochaetus is presented. Tylorrhynchus haemoglobin consists of two types of subunits: a "monomeric" chain I and a disulphide-bonded "trimer" of chains IIA, IIB and IIC. The molar ratio of the four constituent chains was determined by statistical comparison of the accurate amino acid composition calculated from the sequence of each chain and the observed composition measured by amino acid analysis of the whole molecule. On the basis of the molar ratio and the molecular weight of each chain, deduced from the amino acid sequence, a symmetrical model for the molecular assembly of the haemoglobin was constructed. The proposed model consists of four species of chains of 192 polypeptides and has a molecular weight of 3,275,808. The minimum structural entity is a "tetramer" consisting of the "monomeric" chain and the disulphide-bonded "trimer". Each chain contains one haem.