Structural Features of Glycera dibranchiata Monomer Hemoglobins. Primary Sequences of Monomer Hemoglobin Components II and III

Primary sequences for the remaining two members (GMH2, GMH3) of the group of three major monomeric hemoglobins from the marine annelid Glycera dibranchiata have been obtained. Full sequences of each 147-amino acid globin were achieved with a high degree of confidence using standard Edman technology in combination with molecular mass determinations of the intact globins and of the cyanogen bromide cleavage fragments using electrospray ionization mass spectrometry. When minor assumptions concerning Q/E identities are made these new results indicate the likely correspondence of GMG2 with the protein represented by the first Glycera dibranchiata monomer hemoglobin complete sequence [Imamura et al., (1972), J. Biol. Chem. 247, 2785–2797]. When these new sequences are combined with the previously determined primary sequence for the third major monomer hemoglobin, GMH4 [Alam et al., J. Protein Chem. (1994), 13, 151–164], it becomes clear that these three (GMG2–4) are truly distinct proteins, contrary to previous suggestions. Surprisingly, our results show that none of these three primary sequences is identical to the published sequence of the refined monomer hemoglobin crystal structure protein; however, there is a strong correspondence to the GMG2 sequence. The present sequencing results, in combination with the published GMH4 sequence, confirm the presence of a distal Leu in place of the more commonly encountered distal His in all three of the major monomer hemoglobins isolated in this laboratory and indicate that the unusual B10 Phe occurs only in GMH4. Analysis of the sequences presented here, along with comparison of amino acid content for Glycera dibranchiata monomer hemoglobins isolated from three different laboratories, and comparison of NMR results from two laboratories suggest further correspondences which unify disparate published isolations.     

Complete amino acid sequence of theGlycera dibranchiata monomer hemoglobin Component IV: Structural implications

The globin derived from the monomer Component IV hemoglobin of the marine annelid,Glycera dibranchiata, has been completely sequenced, and the resulting information has been used to create a structural model of the protein. The most important result is that the consensus sequence of Component IV differs by 3 amino acids from a cDNA-predicted amino acid sequence thought earlier to encode the Component IV hemoglobin. This work reveals that the histidine (E7), typical of most heme-containing globins, is replaced by leucine in Component IV. Also significant is that this sequence is not identical to any of the previously reportedGlycera dibranchiata monomer hemoglobin sequences, including the sequence from a previously reported crystal structure, but has high identity to all. A three-dimensional structual model for monomer Component IV hemoglobin was constructed using the published 1.5 å crystal structure of a monomer hemoglobin fromGlycera dibranchiata as a template. The model shows several interesting features: (1) a Phe31 (B10) that is positioned in the active site; (2) a His39 occurs in an interhelical region occupied by Pro in 98.2% of reported globin sequences; and (3) a Met41 is found at a position that emerges from this work as a previously unrecognized heme contact.Abbreviations used GMHX the holo-protein (including b-type heme, Glycera dibranchiata monomer hemoglobin Component X (X=2, 3, or 4) - GMGX the apo-protein, or globin, Glycera dibranchiata monomer globin derived from Component X (X=2, 3, or 4) - rec-gmg the globin derived from a recombinant holoprotein of a Glycera dibranchiata monomer hemoglobin, rec-gmh, whose sequence has been inferred from an isolated cDNA insert - CB label refers to peptides generated from cyanogen bromide cleavage of GMG4 - HPLC high-performance liquid chromatography - T label refers to peptides generated from trypsin digests of GMG4 - Mb myoglobin - MCS monomer hemoglobin crystal structure from Glycera dibranchiata. H, N-terminal sequence of GMG4 - SWMb sperm whale myoglobin     

Crystal structures of unligated and CN-ligated Glycera dibranchiata monomer ferric hemoglobin components III and IV

Erythrocytes of the marine annelid, Glycera dibranchiata, contain a mixture of monomeric and polymeric hemoglobins. There are three major monomer hemoglobin components, II, III, IV (also called GMH2, 3, and 4), that have been highly purified and well characterized. We have now crystallized GMH3 and GMH4 and determined their structures to 1.4-1.8 A resolution. The structures were determined for these two monomer hemoglobins in the oxidized (Fe3+, ferric, or met-) forms in both the unligated and cyanide-ligated states. This work differs from two published, refined structures of a Glycera dibranchiata monomer hemoglobin, which has a sequence that is substantially different from any bona fide major monomer hemoglobins (GMH2, 3, or 4). The high-resolution crystal structures (presented here) and the previous NMR structure of CO-ligated GMH4, provide a basis for interpreting structure/function details of the monomer hemoglobins. These details include: (1) the strong correlation between temperature factor and NMR dynamics for respective protein forms; (2) the unique nature of the HisE7Leu primary sequence substitutions in GMH3 and GMH4 and their impact on cyanide ion binding kinetics; (3) the LeuB10Phe difference between GMH3 and GMH4 and its impact on ligand binding; and (4) elucidation of changes in the structural details of the distal and proximal heme pockets upon cyanide binding.     

Complete amino acid sequence of theGlycera dibranchiata monomer hemoglobin Component IV: Structural implications

The globin derived from the monomer Component IV hemoglobin of the marine annelid,Glycera dibranchiata, has been completely sequenced, and the resulting information has been used to create a structural model of the protein. The most important result is that the consensus sequence of Component IV differs by 3 amino acids from a cDNA-predicted amino acid sequence thought earlier to encode the Component IV hemoglobin. This work reveals that the histidine (E7), typical of most heme-containing globins, is replaced by leucine in Component IV. Also significant is that this sequence is not identical to any of the previously reportedGlycera dibranchiata monomer hemoglobin sequences, including the sequence from a previously reported crystal structure, but has high identity to all. A three-dimensional structual model for monomer Component IV hemoglobin was constructed using the published 1.5 å crystal structure of a monomer hemoglobin fromGlycera dibranchiata as a template. The model shows several interesting features: (1) a Phe31 (B10) that is positioned in the active site; (2) a His39 occurs in an interhelical region occupied by Pro in 98.2% of reported globin sequences; and (3) a Met41 is found at a position that emerges from this work as a previously unrecognized heme contact.     

Electrospray Ionization Mass Spectrometric Study of the Multiple Intracellular Monomeric and Polymeric Hemoglobins of Glycera dibranchiata

The intracellular hemoglobin (Hb) of the marine polychaete Glycera dibranchiata is comprised of two groups of globins differing in their primary structures and state of aggregation. About six electrophoretically and chromatographically distinct monomeric Hbs which have Leu as the distal residue, and an equal number of polymeric Hbs which have the usual distal His, have been identified to date. Deconvolution of the electrospray ionization mass spectra (ESI-MS) of the Hbs and of their carbamidomethylated, reduced, and reduced/carbamidomethylated forms, using a maximum entropy-based approach (MaxEnt), showed the presence of at least 18 peaks attributable to monomer Hbs (14,500–15,200 Da) and an approximately equal number of polymer Hb peaks (15,500–16,400 Da). Although the ratio of the monomer to polymer components in pooled Hb preparations remained constant at 60:40, Hb from individuals had generally less than 6 monomer and 6 polymer components; 2 of the 19 individuals appeared to be deficient in polymer Hbs. Taking into account possible fragmentations of the known monomeric and polymeric globin sequences, we estimate conservatively that there are 10 monomeric and an equal number of polymeric Hbs, the majority comprising a single free Cys. Surprisingly, the calculated mass of the sequence deduced from the high-resolution monomer Hb crystal structures does not correspond to any of the observed masses. ESI-MS of the monomer Hb crystal revealed 11 components, of which 5, accounting for 67% of total, were related to the three major sequences GMG2–4. These findings underline the need for routine mass spectrometric characterization of all protein preparations. The complete resolution of the Glycera Hb ESI-MS using MaxEnt processing illustrates the power of this method to resolve complex protein mixtures.     

STUDIES ON INVERTEBRATE HEMOGLOBINS (ERYTHROCRUORINS)

1. Two high molecular invertebrate hemoglobins (the erythrocruorins of Lumbricus terrestris and of Nereis virens) as well as the low molecular erythrocruorin of Glycera dibranchiata Ehlers were studied. Their physical chemical properties were compared with those of vertebrate hemoglobin. 2. The hemin of the blood pigment of Glycera dibranchiata Ehlers was shown to be identical with that of vertebrate hemoglobin. 3. The dissociation rates of Glycera and human oxyhemoglobin were measured in the reaction meter of DuBois and t ₅₀ (half time of the reaction) was found to be identical (0.027 second) for the two pigments. The t ₅₀ value for the high molecular Lumbricus erythrocruorin was 0.070 second. 4. The chemical constitution and physical chemical properties of erythrocruorins were compared with those of vertebrate hemoglobin and of hemocyanin.     

Electrospray Ionization Mass Spectrometric Study of the Multiple Intracellular Monomeric and Polymeric Hemoglobins of Glycera dibranchiata

The intracellular hemoglobin (Hb) of the marine polychaete Glycera dibranchiata is comprised of two groups of globins differing in their primary structures and state of aggregation. About six electrophoretically and chromatographically distinct monomeric Hbs which have Leu as the distal residue, and an equal number of polymeric Hbs which have the usual distal His, have been identified to date. Deconvolution of the electrospray ionization mass spectra (ESI-MS) of the Hbs and of their carbamidomethylated, reduced, and reduced/carbamidomethylated forms, using a maximum entropy-based approach (MaxEnt), showed the presence of at least 18 peaks attributable to monomer Hbs (14,500–15,200 Da) and an approximately equal number of polymer Hb peaks (15,500–16,400 Da). Although the ratio of the monomer to polymer components in pooled Hb preparations remained constant at 60:40, Hb from individuals had generally less than 6 monomer and 6 polymer components; 2 of the 19 individuals appeared to be deficient in polymer Hbs. Taking into account possible fragmentations of the known monomeric and polymeric globin sequences, we estimate conservatively that there are 10 monomeric and an equal number of polymeric Hbs, the majority comprising a single free Cys. Surprisingly, the calculated mass of the sequence deduced from the high-resolution monomer Hb crystal structures does not correspond to any of the observed masses. ESI-MS of the monomer Hb crystal revealed 11 components, of which 5, accounting for 67% of total, were related to the three major sequences GMG2–4. These findings underline the need for routine mass spectrometric characterization of all protein preparations. The complete resolution of the Glycera Hb ESI-MS using MaxEnt processing illustrates the power of this method to resolve complex protein mixtures.     

Anomalous pH dependence of the heme-bound carbon monoxide spectroscopic properties in the Glycera dibranchiata monomer hemoglobin fraction compared to vertebrate hemoglobins

The pH dependence of infrared and NMR spectroscopic parameters for carbon monoxide bound to human, equine, rabbit and Glycera dibranchiata monomer fraction hemoglobins has been examined. In all cases, the vertebrate hemoglobins exhibit CO vibrations and 13CO chemical shifts which are pH dependent, whereas the invertebrate hemoglobin does not. The Glycera dibranchiata monomer fraction exhibits the highest wavenumber CO vibration (1970 cm-1) and the most shielded chemical shift (206.2 ppm). The pH behavior of the vertebrate CO-hemoglobins is that the heme-coordinated carbon monoxide chemical shifts and principal infrared vibrations tend toward the values observed for the G. dibranchiata CO-hemoglobin fraction. These results are interpreted as originating in protonation of the distal histidine (E-7) in the vertebrate hemoglobins. The anomalous values for Glycera dibranchiata are concluded to be due to the absence of a distal histidine (E-7 His----Leu) in the heme pocket and not to gross structural dissimilarities between the proteins of the different species examined. Primary sequence similarity matrices have been constructed to compare the functional classes of amino acids at homologous positions for the CD and E helices and for the primary heme contacts in human, equine, sperm whale myoglobin, and the Glycera dibranchiata monomer hemoglobin to illustrate this point. They reveal a high correspondence for all globins and do not correlate with the spectroscopic parameters of heme-coordinated CO.     

Purification and Characterization of Recombinant Polymeric Hemoglobin P1 of Glycera dibranchiata

The apoprotein of component P1 of the polymeric fraction of the intracellular hemoglobin of the marine polychaete Glycera dibranchiata has been expressed at a high level in Escherichia coli. The expressed globin was reconstituted with heme and purified. The N-terminal sequence of the recombinant P1 is identical to the cDNA-derived sequence of cloned P1 (Zafar et al., Biochem. Biophys. Acta, 1041, 117-123, 1990). Gel filtration, SDS-PAGE, optical spectra over the range 200-650 nm, and circular dichroism over the range 200-250 nm of the purified recombinant P1 were very similar to the polymeric fraction of native Glycera hemoglobin. The molar ellipticity at 222 nm provided an estimate of 77% for the α-helical content of the recombinant P1, in excellent agreement with that calculated from the crystal structure of Glycera monomeric component M-II. Although the oxygen binding affinity of the recombinant P1 is higher than that of the polymeric fraction of Glycera hemoglobin (3-4 torr vs 7-13 torr), which consists of at least six different single-chain hemoglobins, the Hill coefficient is lower (1.0-1.2 vs 1.2-1.4).     

cDNA cloning and predicted amino acid sequence of Glycera dibranchiata monomer hemoglobin IV

The three major monomer hemoglobins from Glycera dibranchiata erythrocytes isolated in this laboratory were sequenced from their N-termini. A stretch of amino acid sequence identity was used to determine the sequence of a mixed oligodeoxynucleotide that would be complementary to all 12 possible mRNA sequences coding for the amino acids. A cDNA library was constructed by using poly(A+) RNA from G. dibranchiata erythrocytes, the library was probed with the oligonucleotide, and the longest positive inserts found were subcloned into a sequencing plasmid and then sequenced. The first one was 745 bases long, containing 85 bases of 5'-untranslated RNA, an open reading frame of 444 bases coding for 148 amino acids, and a 3'-untranslated region of 216 bases. The predicted amino acid sequence matches the first 25 amino acids of G. dibranchiata monomer globin component IV. The sequence contains an N-terminal methionine plus 18 other mostly conservative sequence changes compared to the published sequence of Imamura et al. (1972), which appears from our partial sequencing to be monomer globin component II. We confirm the presence of leucine in the E7 position, which is histidine in most myoglobins and hemoglobins.     

Influences of predatory polychaetes and epibenthic predators on the structure of a soft-bottom community in a maine estuary

Field manipulations were used to determine the importance of two predatory polychaetes, Nereis virens Sars and Glycera dibranchiata Ehlers, and epibenthic predators in structuring an intertidal soft-bottom community in Maine. Epibenthic predators were excluded from portions of the soft bottom using cages which also enclosed elevated densities of the predatory polychaetes. The experiments ran 10 wk and 20 wk beginning in June 1979. Exclusion of epibenthic predators had no effect on infaunal densities after 10 wk but produced ≈ 1.5-fold increase in total density after 20 wk. Since gulls (Larus spp.) avoided all cages, including those not designed to exclude epibenthic predators, the effect of gull predation on infaunal abundances was not tested using exclusion cages. Crabs, Carcinus maenas (Linnaeus) and Cancer irroratus Say were observed in cages not designed to exclude predators.Densities of Nephtys incisa Malmgren, Polydora ligni Webster, Streblospio benedicti Webster, Scoloplos robustus Verrill, phyllodocids, and bivalves were highest in cages containing elevated Glycera dibranchiata density and lowest in cages containing elevated Nereis virens density. N. virens was the only taxon whose abundance was reduced in the presence of Glycera dibranchiata which may account for high infaunal densities in the G. dibranchiata treatment. Laboratory experiments demonstrated that G. dibranchiata are capable of preying on Nereis virens. Additional field experiments revealed that the presence of N. Virens reduced the abundance of some taxa within the first 10 days of colonization. N. virens may have reduced infaunal densities by predation and/or disturbance at the sediment surface. These results suggest that complex interactions within the infauna are important in structuring marine soft-bottom communities.     

NMR studies of the heme pocket conformations of monomeric hemoglobins from Glycera dibranchiata. Implications for ligand binding

Two-dimensional 1H-NMR methods have been used to assign side-chain resonances for the tryptophan residues and for several amino acids located in the heme pockets of the carbon monoxide complexes of the major monomeric hemoglobins from Glycera dibranchiata. The NMR spectra reveal a high degree of conservation of the heme pocket structure in the different hemoglobins. However some conformational differences are evident and residues at positions B10 and G8 on the distal side of the heme pocket are not conserved. From the present NMR studies it appears that the monomeric G. dibranchiata hemoglobin examined by X-ray crystallography [Padlan, E. A. & Love, W. (1974) J. Biol. Chem. 249, 4067-4078] corresponds to HbC. Except that the orientation of the heme in solution is the reverse of that reported in the crystal structure, there is a close correspondence between the heme pocket structure in the crystal and in solution. The proximal histidine coordination geometry is almost identical in the CO complexes of the three monomeric hemoglobins studied. Distal residues are strongly implicated in determining the observed kinetic differences in ligand binding reactions. In particular, steric crowding of the ligand binding site in hemoglobin A is probably a major factor in the slower kinetics of this component.     

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.     

Isoelectric focusing purity criteria and 1H NMR detectable spectroscopic heterogeneity in the major isolated monomer hemoglobins from Glycera dibranchiata

Three major monomeric hemoglobins have been isolated from the erythrocytes of Glycera dibranchiata. Their importance to structure-function studies of heme proteins lies in the fact that they have been shown to possess an exceptional amino acid substitution. In these proteins, the E-7 position is occupied by leucine rather than the more common distal histidine. This substitution alters the polarity of the heme ligand binding environment compared to myoglobin. Due to this, the G. dibranchiata monomer hemoglobins are attracting much attention. However, until now no purity criterion has been developed. Here we demonstrate that, for all of the Glycera monomer hemoglobins, multiple line patterns are shown on high-voltage isoelectric focusing (IEF) gels. Most of these lines are shown to be a consequence of heme-related phenomena and can be understood on the basis of changes in oxidation and ligation state of the heme iron. The multiple line pattern does not indicate significant impurities in the monomer hemoglobin preparations. Similar behavior is also demonstrated for horse heart myoglobin. The multiple line patterns on IEF gels disappear when gels of the apoproteins alone are focused. Single bands occur in this case for all of the monomer hemoglobins except component II, which displays two bands, one major and one minor. The minor band is found to be a modified apoprotein form. It is sensitive to apoprotein handling prior to focusing and depends upon whether the IEF gel is prefocused or not. From this analysis, IEF is shown to be a valuable purity criterion, and the purity of our monomer hemoglobin component II preparation is 97% one globin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Artemia hemoglobins: Increase in net synthesis of the β-polypeptide (relative to the α-polypeptide) in hypoxia

Previous studies have shown that in the brine shrimp there are three dimeric hemoglobins with polypeptide composition α₂, αβ, β₂. Concentrations of the α- and β-polypeptides increase in hypoxia. We now report a two-dimensional electrophoretic method for assay of radiolabelled polypeptidesin each hemoglobin. Net synthesis (synthesis minus degradation) of the β-chain, relative to that of the α-chain, increases more than 3-fold (in male and female adults) within 3 days following a downshift in oxygen concentration from 0.2 to 0.1 mM in the culture medium. 3 days after downshift (2 days after in vivo incorporation of radiolabelled leucine), the β-homodimer contained 10–20% of the radiolabel in the three hemoglobins although β₂ was usually not detectable in the protein stain of an overloaded gel. The amount of radioactive leucine incorporated per unit amount of protein was more than 300-times greater in the β₂ homodimer than in the β-subunit of the heterodimer, suggesting that β₂ does not dissociate rapidly during electrophoresis on the first dimension non-denaturing gel. This evidence for stable association of the two β-monomers and the 5–8 heme-binding domains within each monomer (in vivo and during electrophoresis on non-denaturing gels) allows us to exclude one of two alternative interpretations of genetic data published previously. We present an independent line of evidence for the dimer model of the native hemoglobins (which states that each polypeptide has many heme-binding domains).     

A comparison of the functional properties of two lepore hemoglobins with those of hemoglobin A1.

Lepore hemoglobins result from crossovers between normal beta and delta chain genes. Structural investigation of two newly discovered examples of Lepore hemoglobins revealed one of them to be structurally identical to hemoglobin Lepore Hollandia α₂^Aδ²² -x- β⁵⁰, a rarely occurring Lepore variant, while the second had the structure of hemoglobin Lepore Boston α₂^Aδ⁸⁷ -x- β¹¹⁶. Studies of the equilibrium and kinetic properties of the liganding reactions of these two Lepore hemoglobins, which differ only in three amino acid residues, and comparison of these with the known properties of hemoglobin A₁ (α₂β₂) and hemoglobin A₂ (α₂δ₂) have been carried out. A high value of n, the Hill coefficient, indicating normal heme-heme interaction, was observed in each hemoglobin along with a normal Bohr effect. However, a slight but definite increase in oxygen affinity was observed for each Lepore hemoglobin. Furthermore, kinetic studies indicated a slight but consistently increased rate of ligand combination and a somewhat decreased rate of oxygen dissociation for hemoglobins Lepore Hollandia and Lepore Boston at pH 7 and 20 °C. Apparently, the higher oxygen affinity of these Lepore hemoglobins over those of the normal hemoglobins A₁ and A₂ reflects changes of sequence that are common to both types of hemoglobin Lepore.     

Dissociation of hemoglobin into subunits. Monomer formation and the influence of ligands

The formation of monomer from several hemoglobins has been investigated by sedimentation equilibrium. The use of the split-beam photoelectric scanning absorption optical system has enabled observations to be made routinely down to 1 μg/ml. (6.2 × 10⁻⁸m-heme) with strict spectral control of the integrity of the hemoglobin molecule. The results show that the dissociation constant of dimer to monomer at neutral pH and moderate ionic strength is so small that monomer is present in reversible equilibrium with dimer only in fractions too small to be detectable. Any appreciable monomer formation is irreversible and accompanied by usually pronounced spectral changes. This irreversible monomer formation is probably a consequence of the presence of heavy-metal ions in solution and may be inhibited by 10⁻³m-EDTA. Hemoglobin ligands possessing chelating ability also inhibit monomer formation.     

The amino acid sequence of hemoglobin III from the symbiont-harboring clamLucina pectinata

The cytoplasmic hemoglobin III from the gill of the symbiont-harboring clamLucina pectinata consists of 152 amino acid residues, has a calculated M_m of 18,068, including heme, and has N-acetyl-serine as the N-terminal residue. Based on the alignment of its sequence with other vertebrate and nonvertebrate globins, it retains the invariant residues Phe45 at position CD1 and His98 at the proximal position F8, as well as the highly conserved Trp16 and Pro39 at positions A12 and C2, respectively. The most likely candidate for the distal residue at position E7 is Gln66.Lucina hemoglobin III shares 95 identical residues with hemoglobin II (J. D. Hockenhull-Johnsonet al., J. Prot. Chem. 10, 609–622, 1991), including Tyr at position B10, which has been shown to be capable of entering the distal heme cavity and placing its hydroxyl group within a 2.8 Å of the water molecule occupying the distal ligand position, by modeling the hemoglobin II sequence using the crystal structure of sperm whale metmyoglobin. The amino acid sequences of the twoLucina globins are compared in detail with the known sequences of mollusc globins, including seven cytoplasmic and 11 intracellular globins. Relative to 75% homology between the twoLucina globins (counting identical and conserved residues), both sequences have percent homology scores ranging from 36–49% when compared to the two groups of mollusc globins. The highest homology appears to exist between theLucina globins and the cytoplasmic hemoglobin ofBusycon canaliculatum.     

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.     

Solution studies on heme proteins. Circular dichroism and optical rotation of Glycera dibranchiata hemoglobins

Circular dichroism (CD) and optical rotatory dispersion (ORD) spectra of several liganded derivatives of the monomer and polymer hemoglobin components of the marine annelid, Glycera dibranchiata were measured over the wavelength range 650--195 nm. The differences observed between the monomer and polymer components for the heme dichroic bands in the visible, Soret and ultraviolet wavelength regions seem to result from changes in the heme environment, geometry and coordination state of the central heme iron in these proteins. Within the Soret region, the liganded derivatives of the monomer hemoglobin exhibit predominantly negative circular dichroic bands. The heme band at 260 nm is also absent for the monomer hemoglobin. The ORD and CD spectra in the far-ultraviolet, peptide absorbing region suggest also differences in the alpha-helix content of the monomer and polymer hemoglobins. The values for the single-chain G. dibranchiata hemoglobin are in the expected range (about 70% alpha-helix) as predicted by the X-ray structure of this protein. The lower estimates of the alpha-helix content for the polymer hemoglobin (approx. 50%), may reflect the differences in amino acid composition, primary structure and polypeptide chain foldings. Changes in oxidation state and ligand binding appears to have no pronounced effect on the helicity of either the monomer or polymer hemoglobins. The removal of the heme moiety from the monomer hemoglobin did result in a major decrease in its helix content similar to the loss of heme from myoglobin.