Evolution of the sulfide-binding function within the globin multigenic family of the deep-sea hydrothermal vent tubeworm Riftia pachyptila

The giant extracellular hexagonal bilayer hemoglobin (HBL-Hb) of the deep-sea hydrothermal vent tube worm Riftia pachyptila is able to transport simultaneously O(2) and H(2)S in the blood from the gills to a specific organ: the trophosome that harbors sulfide-oxidizing endosymbionts. This vascular HBL-Hb is made of 144 globins from which four globin types (A1, A2, B1, and B2) coevolve. The H(2)S is bound at a specific location (not on the heme site) onto two of these globin types. In order to understand how such a function emerged and evolved in vestimentiferans and other related annelids, six partial cDNAs corresponding to the six globins known to compose the multigenic family of R. pachyptila have been identified and sequenced. These partial sequences (ca. 120 amino acids, i.e., 80% of the entire protein) were used to reconstruct molecular phylogenies in order to trace duplication events that have led to the family organization of these globins and to locate the position of the free cysteine residues known to bind H(2)S. From these sequences, only two free cysteine residues have been found to occur, at positions Cys + 1 (i.e., 1 a.a. from the well-conserved distal histidine) and Cys + 11 (i.e., 11 a.a. from the same histidine) in globins B2 and A2, respectively. These two positions are well conserved in annelids, vestimentiferans, and pogonophorans, which live in sulfidic environments. The structural comparison of the hydrophobic environment that surrounds these cysteine residues (the sulfide-binding domain) using hydrophobic cluster analysis plots, together with the cysteine positions in paralogous strains, suggests that the sulfide-binding function might have emerged before the annelid radiation in order to detoxify this toxic compound. Moreover, globin evolutionary rates are highly different between paralogous strains. This suggests that either the two globin subfamilies involved in the sulfide-binding function (A2 and B2) have evolved under strong directional selective constraints (negative selection) and that the two other globins (A1 and B1) have accumulated more substitutions through positive selection or have evolved neutrally after a relaxation of selection pressures. A likely scenario on the evolution of this multigenic family is proposed and discussed from this data set.     

Molecular evidence that Sclerolinum brattstromi is closely related to vestimentiferans, not to frenulate pogonophorans (Siboglinidae, Annelida)

Siboglinids, previously referred to as pogonophorans, have typically been divided into two groups, frenulates and vestimentiferans. Adults of these marine protostome worms lack a functional gut and harbor endosymbiotic bacteria. Frenulates usually live in deep, sedimented reducing environments, and vestimentiferans inhabit hydrothermal vents and sulfide-rich hydrocarbon seeps. Taxonomic literature has often treated frenulates and vestimentiferans as sister taxa. Sclerolinum has traditionally been thought to be a basal siboglinid that was originally regarded as a frenulate and later as a third lineage of siboglinids, Monilifera. Evidence from the 18S nuclear rDNA gene and the 16S mitochondrial rDNA gene presented here shows that Sclerolinum is the sister clade to vestimentiferans although it lacks the characteristic morphology (i.e., a vestimentum). The rDNA data confirm the contention that Sclerolinum is different from frenulates, and further supports the idea that siboglinid evolution has been driven by a trend toward increased habitat specialization. The evidence now available indicates that vestimentiferans lack the molecular diversity expected of a group that has been argued to have Silurian or possibly Cambrian origins.     

The Position of Arthropods in the Animal Kingdom: A Search for a Reliable Outgroup for Internal Arthropod Phylogeny

Morphological evidence for the phylogeny of the animal kingdom has been discussed by numerous authors. DNA sequencing and phylogenetic methods for analyzing these data are alternative approaches to animal phylogeny, but the phenomenon of long branch attraction and poor taxonomic sampling have caused misinterpretations of metazoan relationships. Here we report a cladistic approach to metazoan evolution including 133 18S rDNA sequences of 31 animal phyla. Despite the difficulties associated with analyzing large data sets, our data suggest that the Bilateria and Protostomia are monophyletic. The internal phylogeny of the protostomes is divided into two main clades. One clade includes the classical protostome worms (annelids, sipunculans, echiurans, pogonophorans, and vestimentiferans), mollusks, nemerteans, “lophophorates,” platyhelminths, rotiferans, and acanthocephalans, although the internal resolution of the clade is very low. The second clade includes arthropods and other molting animals: tardigrades, onychophorans, nematodes, nematomorphans, kinorhynchs, and priapulans. The arthropods and related phyla lack a ciliated larvae, lack a multiciliate (locomotory) epithelium, and share many features, notably, a reduced coelomic cavity and the presence of a cuticle which molts. The use of these outgroups within the molting clade to root arthropod phylogenies is recommended instead of using annelids or other spiralians. The data are quite conclusive in those phyla with a good taxonomic sampling (i.e., platyhelminths and arthropods).     

Three-dimensional reconstruction of Lumbricus terrestris hemoglobin at 22 A resolution: intramolecular localization of the globin and linker chains.

A 3D reconstruction of the hemoglobin (Hb) of the earthworm Lumbricus terrestris was carried out by the 3D projection alignment method from electron microscopy images of a frozen-hydrated specimen at 22 A resolution. The results were analyzed by a new approach taking into account the evolution of the 210 densities forming the 3D volume as a function of the threshold of surface representation. The whole oligomer with D6point-group symmetry is comprised of 12 hollow globular substructures (HGS) with local 3-fold symmetry tethered to a complex network of linking subunits (linker complex). The 12 globin subunits of each HGS are distributed around local 3-fold axis in four layers of three subunits. The first layer, the most external, contains monomeric globin chains 2A, 3A, and 5A. The three trimers corresponding to the nine remaining subunits have one subunit in each of the second (2B, 3B, 5B), third (1A, 4A, 6A), and fourth (1B, 4B, 6B) layer. The distances between the centers of the globin chains forming the trimers are in the ranges 20-32 A and 45-52 A. The linker complex is made up of two types of linking units. The first type forms three loops connecting globin chains of the second, third and fourth layers. The average molecular mass (Mm) of these subunits was 25 kDa. The second type forms the central structure, termed hexagonal toroid, and its 12 connections to the HGS. This structure corresponds to a hexamer of a single linking unit with a Mm (31.2 kDa), size and a shape different from those of the HGS loops. A careful study of 3D volume architecture shows that each toroid linking unit is bound to the three loops of a HGS pair located in the upper and lower hexagonal layers, respectively. As shown in a model of architecture, hexagonal bilayered (HBL) Hbs can be built very simply from 144 globin chains and 42 linker chains belonging to two different types. We also propose a simple assembly sequence for the construction of HBL Hbs based on the architecture model.     

The sulfide binding function of annelid hemoglobins: relic of an old biosystem?

Invertebrates living in sulfide-rich environments have developed different strategies of coping with sulfide toxicity. Some bivalves and annelids have hemoglobins that are capable of binding sulfide for detoxification and/or transporting it to internal bacterial symbionts. Annelids living in the sulfide-rich environments have giant (approximately 3.6 MDa) hemoglobin, consisting of 144 globin chains arranged in a hexagonal bilayer structure held together by 36 nonglobin linker chains. Some globin chains contain either a free cysteine residue at positions Cys+1 or at position Cys+11 relative to the E7 distal residue in the E helix and EF interhelical region, respectively, which bind sulfide. The hexagonal bilayer hemoglobins of annelids living in environments lacking sulfide, do not have the corresponding free cysteine residues and cannot bind sulphide. Given that the early stages of life occurred under anoxic conditions in the presence of sulfide, it is possible that the sulfide binding function from modern annelid globins inhabiting sulphide rich habitats is an evolutionary relic. This proposal seems supported by the recent finding of "protoglobins" which also have a corresponding cysteine residue in Archea known to exist in hyperthermophilic and sulfide-rich environments.     

The multigenic family of the extracellular hemoglobin from the annelid polychaete Arenicola marina

The extracellular hemoglobin of the lugworm Arenicola marina which inhabits on the intertidal area, a sulfide-rich environment, comprises eight globin chains previously determined by mass spectrometry. We have cloned and sequenced five of the globin components. The deduced amino-acid sequences exhibit an extracellular signal peptide and two cysteine residues involved in an internal disulfide bond. The molecular weights calculated from the globin primary structures obtained from complete cDNA sequences are in good agreement with the mass spectrometry values obtained with the native hemoglobin. Phylogenetic analysis has allowed assigning the five A. marina sequences to the different globin sub-families. Two of the globins were found to be A2 globin chains lacking the cysteine residues proposed to be involved in the binding of hydrogen sulfide by such hemoglobin. We discuss the unusual absence of these cysteines in the light of their invariant occurrence in the A2 subfamily of hemoglobins from annelids inhabiting sulfide-rich environments.     

Polypeptide chain composition diversity of hexagonal-bilayer haemoglobins within a single family of annelids, the alvinellidae.

Following previous analysis of the structure of Alvinella pompejana heaxagonal-bilayer haemoglobin (HBL Hb) [1], we report in this paper the structure of three other HBL Hbs belonging to Alvinella caudata, Paralvinella grasslei and Paralvinella palmiformis, members of the Alvinellidae, annelid family strictly endemic to deep-sea hydrothermal vents located on the ridge crests in the Pacific ocean. The multi-angle laser light scattering (MALLS) and fast protein liquid chromatography (FPLC) analysis revealed a broad range of molecular masses for the extracellular Hb molecules, 3517 +/- 14 kDa (A. caudata), 3822 +/- 28 kDa (P. grasslei) and 3750 +/- 150 kDa (P. palmiformis). Native and derivative Hbs (reduced, carbamidomethylated and deglycosylated) were analysed by electrospray ionization mass spectroscopy (ESI-MS) and the data was processed by the maximum entropy deconvolution system (MaxEnt). The most important difference between alvinellid HBL Hbs was the variation in their composition, from two to four monomeric globin chains, and from one to four linker chains. Therefore, despite the fact that all these species belong to a single family, notable differences in the polypeptide chain composition of their HBL Hbs were observed, probably accounting for their different functional properties as previously reported by this group Toulmond, A., El Idrissi Slitine, F., De Frescheville, J. & Jouin, C. (1990) Biol. Bull. 179, 366-373.     

Observation of large, non-covalent globin subassemblies in the approximately 3600 kDa hexagonal bilayer hemoglobins by electrospray ionization time-of-flight mass spectrometry

A non-covalent globin subassembly comprising 12 globin chains (204 to 214 kDa) was observed directly by electrospray ionization time-of-flight mass spectrometry in the native hexagonal bilayer hemoglobins from the oligochaetes Lumbricus terrestris and Tubifex tubifex, the polychaetes Tylorrhynchus heterochaetus, Arenicola marina, Amphitrite ornata and Alvinella pompejana, the leeches Macrobdella decora, Haemopis grandis and Nephelopsis oscura and the chlorocruorin from the polychaete Myxicola infundibulum, over the pH range 3.5-7.0. The Hb from the deep-sea polychaete Alvinella exhibited in addition, peaks at approximately 107 kDa and at approximately 285 kDa, which were assigned to subassemblies of six globin chains and of 12 globin chains with three non-globin linker chains, respectively. The experimental masses decreased slightly with increased de-clustering potential (60 to 160 V) and were generally 0.1 to 0.2 % higher than the calculated masses, due probably to complexation with cations and water molecules.     

Reassembly of Lumbricus terrestris hemoglobin: a study by matrix-assisted laser desorption/ionization mass spectrometry and 3D reconstruction from frozen-hydrated specimens

Dodecamers and four types of linker chains (L1-L4) were purified from dissociated hemoglobin of the earthworm Lumbricus terrestris. Various preparations comprising dodecamer of globin chains and linker chains were allowed to reassemble at neutral pH. They produced various oligomers that were purified by gel filtration, analyzed in matrix-assisted laser desorption/ionization mass spectrometry and submitted to 3D reconstruction from isolated particles observed in cryoelectron microscopy. Despite the impossibility to completely free the L2, L3, and L4 preparations from L1, the following conclusions were obtained. First, hemoglobin molecules indistinguishable from native hemoglobin at 25 A resolution were obtained in the absence of linker chains L2, L3, or L4. Second, the 3D reconstruction volumes of reassembled hemoglobins containing dodecamers and L1+L3 or dodecamers and L1+L4 demonstrate that reassembly of native-like structures can be obtained from at most two linker chains and dodecamers. Third, the 3D reconstruction volumes of native and reassembled hemoglobins containing dodecamers and (1) L1, L2, and L4, (2) L1, L3, and L4, (3) L1 and L4, and (4) L1 and L3 were highly similar. Since these structures comprise two types of substructures (one involved in the c3a, c3b, and c4 linking units of the hollow globular substructure and the other in the c5 connection and the toroid), it seems highly probable that the minimal number of linker chains required to reassemble native-like hemoglobin is at most two.     

Gene Structure and Molecular Phylogeny of the Linker Chains from the Giant Annelid Hexagonal Bilayer Hemoglobins

Giant extracellular hexagonal bilayer hemoglobin (HBL-Hb), found only in annelids, is an ∼3500-kDa heteropolymeric structure involved in oxygen transport. The HBL-Hbs are comprised of globin and linker chains, the latter being required for the assembly of the quaternary structure. The linker chains, varying in size from 225 to 283 amino acids, have a conserved cysteine-rich domain within their N-terminal moiety that is homologous to the cysteine-rich modules constituting the ligand binding domain of the low-density lipoprotein receptor (LDLR) protein family found in many metazoans. We have investigated the gene structure of linkers from Arenicola marina, Alvinella pompejana, Nereis diversicolor, Lumbricus terrestris, and Riftia pachyptila. We found, contrary to the results obtained earlier with linker genes from N. diversicolor and L. terrestris, that in all of the foregoing cases, the linker LDL-A module is flanked by two phase 1 introns, as in the human LDLR gene, with two more introns in the 3′ side whose positions varied with the species. In addition, we obtained 13 linker cDNAs that have been determined experimentally or found in the EST database LumbriBASE. A molecular phylogenetic analysis of the linker primary sequences demonstrated that they cluster into two distinct families of linker proteins. We propose that the common gene ancestor to annelid linker genes exhibited a four-intron and five-exon structure and gave rise to the two families subsequent to a duplication event.     

Towards a resolution of the long-standing controversy regarding the molecular mass of extracellular erythrocruorin of the earthworm Lumbricus terrestris

The published molecular mass of erythrocruorin of Lumbricus terrestris and related earthworm species covers a bewildering range of 3.23-4.5 MDa. A critical reexamination reveals that some mass determinations were underestimated and the results do cluster, not at one, but at two values of the molecular mass. One cluster corresponds to approximately 3.6 MDa, as predicted for a stoichiometry of 144 globin and 36 linker chains-the Vinogradov model for the hexagonal bilayer (HBL) assembly of Lumbricus erythrocruorin-and as estimated from the crystal structure of HBL at 5.5 A resolution [Proc. Natl. Acad. Sci. U. S. A. 97 (2000) 7107]. The other cluster corresponds to approximately 4.4 MDa. In addition, a molecular mass of 4.1 MDa, determined by multiangle laser light scattering (MALLS), stands apart of the two clusters, separated from the masses obtained by other methods of molecular mass determination.We propose a stoichiometry of 192 globin and 36 linker chains for the 4.4-MDa molecule. The 36 linkers and 144 out of 192 globin chains are identified with the HBL and the remaining 48 globins are allotted equally to the two halves of the axial cavity above and below the central torus of the structure. The proposed model is supported by the occurrence in some annelid species of erythrocruorin with centrally placed subunits [Biochim. Biophys. Acta 359 (1974) 210], and by the oxidation-dependent shedding of subunits in Lumbricus erythrocruorin. We propose further that the 4.1 MDa determination represents the weight average molecular mass of a population of molecules resulting from a partial dissociation of 4.4-MDa erythrocruorin. This interpretation seems reasonable on the background of the very low protein concentrations ( approximately 100 microg/ml and lower) prevailing at the MALLS experiment.     

Molecular phylogeny of siboglinid annelids (a.k.a. pogonophorans): a review

Siboglinid, or pogonophoran, annelids are tubicolous worms that rely on chemoautotrophic endosymbionts for nutrition. Three clades within the siboglinids are recognized: Frenulata, Vestimentifera, and Monilifera. As a group, these worms have received considerable attention from molecular phylogenetists. Most studies have focused either on the evolutionary origins of the group or on the relationships within vestimentiferans, which live at hydrocarbon seeps and hydrothermal vents. Here I review the literature to date on siboglinid molecular phylogeny and summarize the clade’s evolution. The vestimentiferans have been well studied, especially in the eastern Pacific. The seep taxon Lamellibrachia is basal in the clade with vent species being more derived. Recent studies of seeps are finding new species and suggest that habitat depth can be correlated with species boundaries. In contrast to the vestimentiferans, frenulate evolution has been poorly studied. Despite their greater apparent diversity, frenulate specimens have not been sampled so extensively, and thus little is known about their evolution. Sclerolinum, also referred to as Monilifera, is a recognized genus of siboglinids that forms the sister group to Vestimentifera. Like the frenulates, little is known about the history of this group. Our present understanding of siboglinid phylogeny has, in large part, been dictated by insufficient sampling effort.     

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.     

The primary structure of globin and linker chains from the chlorocruorin of the polychaete Sabella spallanzanii

Annelid hemoglobins are organized in a very complex supramolecular network of interacting polypeptides, the structure of which is still not wholly resolved. We have separated by two-dimensional electrophoresis the 4-MDa chlorocruorin of Sabella spallanzanii and identified its components by amino-terminal sequencing. This work reveals a high rate of heterogeneity of constituent chains in a single animal as well as in the Sabella population. Using a cDNA library prepared from the hematopoietic tissue of this worm, we have isolated and fully sequenced most globin and linker cDNAs. The primary structure features of these polypeptides have been characterized by comparison with model globin and linker sequences.     

Globin and linker sequences of the giant extracellular hemoglobin from the leech Macrobdella decora

A detailed electrospray ionization mass spectrometric study of the 3.5-MDa hexagonal bilayer hemoglobin (HBL Hb) from the pond leech Macrobdella decora has shown it to consist of at least six 17-kDa globin chains, of which two are monomeric and the remaining four occur as disulfide-bonded heterodimers, and three 24-kDa nonglobin linker chains (Weber et al., J. Mol. Biol. 251: 703–720, 1995). The cDNA sequences of the five major constituent chains, globin chains IIA, IIB, B, and C and linker chain L1, are reported here. The globins and linkers share 30%–50% and 20%–30% identity, respectively, with other annelid sequences. Furthermore, IIB and C align with strain A of annelid sequences, whereas IIA and B align with the strain B sequences. Although chains B and C are monomeric, chains IIA and IIB form the main disulfide-bonded dimer. They also have some unusual features: the distal His (E7) is replaced by Phe in IIA, and the highly conserved CD1Phe is replaced by Leu in IIB. In spite of these unusual features, the functional properties of Macrobdella Hb are comparable to those of other HBL Hbs. A phylogenetic analysis of the globin sequences from Macrobdella, the polychaete Tylorrhynchus, the oligochaete Lumbricus, and the vestimentiferan Lamellibrachia, indicates that the two strains originated by gene duplication followed by additional duplication of each of the two strains. The mutation rate of the linkers appeared to be faster than that of the globin chains. The phylogenetic trees constructed using the Maximum Likelihood, Neighbor-Joining and Fitch methods showed the Macrobdella globin sequences to be closest to Lumbricus, in agreement with a view of annelid evolution in which the divergence of the polychaetes occurred before the divergence of the leeches from oligochaetes.     

The phylogeny of human globin genes investigated by the maximum parsimony method

Gene phylogenetic trees were constructed by the maximum parsimony method for various sets of ninety six globin chain amino acid sequences spanning plant and animal kingdoms. The method, executed by several computer programs, constructed ancestor and descendant globin messengers on tree topologies which required the least number of nucleotide replacements to account for the evolution of the globins. The human myoglobin-hemoglobin divergence was traced to a gene duplication which occurred either in the first vertebrates or earlier yet in the common ancestor of chordates and annelids, the alpha-beta divergence to a gene duplication in the common ancestor of teleosts and tetrapods, the gamma divergence from typical beta chains to a gene duplication in basal therian mammals, and the delta separation from beta to a duplication in the basal catarrhine primates. Evidence was provided by the globin phylogenies for the hominoid affinities of the gibbon and the close phyletic relationship of the African apes to man. Over the period of teleos-tetrapod divergence the globin messengers evolved at an average rate of 18.5 nucleotide replacements per 100 codons per 10⁸ years, a faster rate than most previous estimates. Very fast and very slow rates were encountered in different globin lineages and at different stages of descent, reducing the effectiveness of globins as molecular clocks. Rates increased with gene duplication and decreased after selection discovered useful specializations in the products of genes which had previously been freer to accept mutations. The early eutherian radiation was characterized by rapid rates of globin evolution, but the later hominoid radiation by extremely slow rates. This pattern was related to more complicated grades of internal organization evolving in human ancestors. The types of nucleotide replacements in the globin messengers over the long course of globin evolution did not seem indicative of any special mutational mechanisms.     

Inhibition of heparan sulfate and chondroitin sulfate proteoglycan biosynthesis

Proteoglycans (PGs) are composed of a protein moiety and a complex glycosaminoglycan (GAG) polysaccharide moiety. GAG chains are responsible for various biological activities. GAG chains are covalently attached to serine residues of the core protein. The first step in PG biosynthesis is xylosylation of certain serine residues of the core protein. A specific linker tetrasaccharide is then assembled and serves as an acceptor for elongation of GAG chains. If the production of endogenous GAG chains is selectively inhibited, one could determine the role of these endogenous molecules in physiological and developmental functions in a spatiotemporal manner. Biosynthesis of PGs is often blocked with the aid of nonspecific agents such as chlorate, a bleaching agent, and brefeldin A, a fungal metabolite, to elucidate the biological roles of GAG chains. Unfortunately, these agents are highly lethal to model organisms. Xylosides are known to prime GAG chains. Therefore, we hypothesized that modified xylose analogs may able to inhibit the biosynthesis of PGs. To test this, we synthesized a library of novel 4-deoxy-4-fluoroxylosides with various aglycones using click chemistry and examined each for its ability to inhibit heparan sulfate and chondroitin sulfate using Chinese hamster ovary cells as a model cellular system.     

Ligand binding in a hierarchy of globin complexes. The hexagonal bilayer hemoglobin of Lumbricus terrestris and its heme-containing subunits

The kinetics of CO and NO recombination with the giant approximately 3600-kDa hexagonal bilayer hemoglobin of Lumbricus terrestris and its subunits, the approximately 200-kDa dodecamer of globin chains (3 x chains (I + II + III + IV] (see preceding paper (Vinogradov S.N., Sharma, P.K., Qabor, A.N., Wall, J.S., Westrick, J.A., Simmons, J.H., and Gill, S.J. (1991) J. Biol. Chem. 266, 13091-13096], the 50-kDa disulfide-bonded trimer (chains II-IV), the monomer (chain I), and the approximately 30-kDa linker (chains VA, VB, and VI), were measured following photolysis over time scales ranging from picosecond to millisecond. CO recombination at 436 nm subsequent to excitation (9 ns) at 532 nm showed three phases covering a 100-fold range for the Hb, dodecamer, trimer, and linker protein. The proportion of the fast phase was 0.1-0.2 for the trimer, dodecamer, and Hb. The relative rates and amplitudes of the phases were not affected by changes in CO concentration or excitation intensity. The monomer showed a single phase with a rate of 2 x 10(6) M-1 s-1. The second-order reaction with NO showed two rates. The faster rate was 90 x 10(6) M-1 s-1 and accounted for approximately 0.7 of the reaction for all species except the monomer, where it accounted for the full reaction. The slower rate was 15 x 10(6) M-1 s-1 for all species except the monomer.     

Haemoglobins, LX. Primary structure of the major haemoglobin of the sea lamprey Petromyzon marinus (var. Garonne, Loire)

Lampreys belong to the class of Cyclostomata; practically no evolution of these Vertebrates can be noted since Paleozo?c times; lampreys thus appear as a choice material for studying several problems in the field of biochemical evolution. Several monomeric haemoglobins can be characterized in the erythrocytes of the sea lamprey (Petromyzon marinus). The major constituent was isolated by chromatography, and submitted to tryptic digestion; soluble tryptic peptides were separated by gel filtration into 5 fractions; the peptides of each fraction were isolated either by Dowex-50 chromatography or by HPLC; the insoluble core was oxidized and submitted to HPLC fractionation. The primary structure of the whole chain and of the purified tryptic peptides was determined using automatic sequencing; alignment of the peptides was achieved by homology with the previously established covalent structure of the globin of Lampetra fluviatilis. The sequence we established confirms the crystallographic data of Hendrickson and Love. Globin/haem contacts are discussed; a tentative explanation of the absence of tetramerization can be proposed after comparison with the aminoacid residues involved in alpha 1 beta 1 and alpha 1 beta 2 contacts. Petromyzon globin differs at three locations (Thr/Ser3, Leu/Met58, Thr/Ser60) from Lampetra fluviatilis globin. The monomeric chain of another Cyclostomata Myxine glutinosa, differs more considerably (88 residues). Our results corroborate recent paleontologic data which favour the separation of lampreys from hagfishes; Cyclostomata cannot be considered as a monophylic group. Finally, there is a closer relation between lamprey globin and alpha chains than between this monomeric globin and beta chains, and furthermore apomyoglobins of higher vertebrates.     

Daphnia pulex didomain hemoglobin: structure and evolution of polymeric hemoglobins and their coding genes.

The high-molecular-weight extracellular hemoglobin of Daphnia pulex is composed of at least three different didomain globin chains. The primary structure of one of these chains was determined at the protein and cDNA levels. Each globin domain of the polypeptide chain displays the standard structural characteristics. The first domain is preceded by a 30-residue extension containing an 18-residue unprecedented threonine-rich segment and a 12-residue preA segment which is homologous to the preA segments of other nonvertebrate globin chains. Both domains are linked together by a preA' segment, which is homologous to other preA segments and lacks the threonine-rich segment. Dimerization of the globin chains by the formation of a disulphide bridge linking the unique cysteines near the amino-termini results in a covalent, vertebrate-like tetradomain structure. The flexible amino-terminal extension most likely facilitates dimerization. The gene coding for this globin chain is interrupted by six small introns. Each domain displays two intradomain introns at the conserved positions B12.2 and G7.0. A precoding intron occurs at position preA(-27.0) and a bridge intron at occurs preA'(-13.2). We propose a crossover event as the most likely mechanism for duplication. Arthropod globin trees reflect the added effects of gene diversification, gene duplication, and species evolution. The position of monodomain intracellular globins in the tree suggests that they resemble the ancestral globin more than the derived didomain extracellular globins do.