Aplysia myoglobins with an unusual amino acid sequence

Structure-Function Relationships in Unusual Nonvertebrate Globins

Based on the literature and our own results, this review summarizes the most recent state of nonvertebrate myoglobin (Mb) and hemoglobin (Hb) research, not as a general survey of the subject but as a case study. For this purpose, we have selected here four typical globins to discuss their unique structures and properties in detail. These include Aplysia myoglobin, which served as a prototype for the unusual globins lacking the distal histidine residue; midge larval hemoglobin showing a high degree of polymorphism; Tetrahymena hemoglobin evolved with a truncated structure; and yeast flavohemoglobin carrying an enigmatic two-domain structure. These proteins are not grouped by any common features other than the fact they have globin domains and heme groups. As a matter of course, various biochemical functions other than the conventional oxygen transport or storage have been proposed so far to these primitive or ancient hemoglobins or myoglobins, but the precise in vivo activity is still unclear. In this review, special emphasis is placed on the stability properties of the heme-bound O2. Whatever the possible roles of nonvertebrate myoglobins and hemoglobins may be (or might have been), the binding of molecular oxygen to iron(II) must be the primary event to manifest their physiological functions in vivo. However, the reversible and stable binding of O2 to iron(II) is not a simple process, since the oxygenated form of Mb or Hb is oxidized easily to its ferric met-form with the generation of superoxide anion. The metmyoglobin or methemoglobin thus produced cannot bind molecular oxygen and is therefore physiologically inactive. In this respect, protozoan ciliate myoglobin and yeast flavohemoglobin are of particular interest in their very unique structures. Indeed, both proteins have been found to have completely different strategies for overcoming many difficulties in the reversible and stable binding of molecular oxygen, as opposed to the irreversible oxidation of heme iron(II). Such comparative studies of the stability of MbO2 or HbO2 are of primary importance, not only for a full understanding of the globin evolution, but also for planning new molecular designs for synthetic oxygen carriers that may be able to function in aqueous solution and at physiological temperature.

1H-NMR study of dynamics and thermodynamics of Cl− binding to ferric hemoglobin of a midge larva (Tokunagayusurika akamusi)

The functional properties of the Arg residue at the E10 helical position in myoglobin and hemoglobin lacking the highly conserved His residue at the E7 position have received considerable interest as to the structure-function relationship of the oxygen-binding hemoproteins, because Arg E10 in such proteins has been shown to play similar roles to those His E7 plays in ordinary proteins. One of the components of hemoglobin from the larval hemolyph of Tokunagayusurika akamusi is also a naturally occurring E7 genetic variant with Ile E7 and Arg E10. This study demonstrated, for the first time, that the positively charged, elongated, and flexible side-chain of Arg E10 in T.akamusi hemoglobin contributes to stabilization of the coordination of biologically relevant Cl(-) to heme iron. Determination of the dynamics of the Cl(-) binding to T. akamusi ferric hemoglobin involving paramagnetic 1H-NMR indicated that the Cl(-) affinity increases with decreasing pH as a result of the fact that the binding rate increases with decreasing pH, whereas the dissociation rate is almost completely independent of pH. The pH-dependent character of the Cl(-) binding rate correlated well with the ionization state of heme peripheral side-chain propionate groups, which was clearly manifested in the pH-dependent shift changes of heme methyl proton signals, suggesting that negative charges of heme propionate groups constitute a kinetic barrier for Cl(-) entry into the heme pocket. These findings provide an insight into the pH-dependent ligand binding properties of T. akamusi hemoglobin.

Evidence of met-form myoglobin from Theliostyla albicilla radular muscle

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

1H NMR study of dynamics and thermodynamics of acid-alkaline transition in ferric hemoglobin of a midge larva (Tokunagayusurika akamusi)

One of the components of hemoglobin from the larval hemolyph of Tokunagayusurika akamusi possesses naturally occurring substitution at the E7 helical position (Leu E7) [M. Fukuda, T. Takagi, K. Shikama, Biochim. Biophys. Acta 1157 (1993) 185-191]. Its oxygen affinity is almost comparable to those of mammalian myoglobins and it exhibits Bohr effect. Both acidic and alkaline forms of the ferric hemoglobin have been investigated using 1H NMR in order to gain insight into molecular mechanisms for relatively high oxygen affinity and Bohr effect of this protein. The NMR data indicated that the acidic form of the protein possesses pentacoordinated heme, and that the alkaline form possessing OH- appears with increasing the pH value. pH titration yielded a pK value of 7.2 for the acid-alkaline transition, and this value is the lowest among the values reported so far for various myoglobins and hemoglobins. The kinetic measurements of the transition revealed that the activation energy for the dissociation of the Fe-bound OH-, as well as the dissociation and association rates, decrease with increasing the pH value. These pH dependence properties are likely to be related to the Bohr effect of this protein.

Aplysia limacina myoglobin cDNA cloning: an alternative mechanism of oxygen stabilization as studied by active-site mutagenesis

The isolation and cloning of the cDNA coding for myoglobin (Mb) from the mollusc Aplysia limacina is reported here. Five amino acid differences from the previously published protein sequence have been found in positions 22, 26, 27, 77 and 80 by back transplanting the cDNA; some of these may be relevant for overall structure stabilization in this Mb. High-level expression of the holoprotein in Escherichia coli has been achieved in the presence of the haem precursor delta-aminolevulinic acid, underlying the importance of tuning haem and apoprotein biosynthesis to achieve high-level expression of haemproteins in bacteria. The recombinant protein is identical to the protein purified from the mollusc buccal muscle. Native A. limacina Mb has an oxygen dissociation rate constant of 70 s(-1) [as compared with the value of 15 s(-1) for sperm whale Mb, which displays His(E7) and Thr(E10)] (amino acid positions are referred to within the eight helices A-H of the globin fold). In order to understand the mechanism of oxygen stabilization in A. limacina Mb, we have prepared and investigated three active-site mutants: two single mutants in which Val(E7) and Arg(E10) have been replaced by His and Thr, respectively, and a double mutant carrying both mutations. When Arg(E10) is substituted with Thr, the oxygen dissociation rate constant is increased from 70 s(-1) to more than 700 s(-1), in complete agreement with the previously proposed role of the former residue in ligand stabilization. In the His(E7)-containing single and double mutants, both displaying high oxygen dissociation rates, the stabilization of bound oxygen by the distal His is insufficient to slow down the ligand dissociation rate constant to the value of sperm whale Mb. These results essentially prove the hypothesis that in A. limacina Mb a mechanism of oxygen stabilization involving Arg(E10), and thus different from that mediated by His(E7), has evolved.

The pH-dependent swinging-out of the distal histidine residue in ferric hemoglobin of a midge larva (Tokunagayusurika akamusi)

Hemoglobin VII (TaVII) is a major component in the larval hemolymph of Tokunagayusurika akamusi, a common midge (Diptera) found in Japan. This protein contains 150 amino-acid residues including the usual distal histidine at position 64. When the aquomet-form was placed in acidic pH range, its Soret peak was considerably blue-shifted and accompanied by a marked decrease in intensity, indicative of the protein being converted into a structure quite similar to that of Aplysia myoglobin lacking the distal histidine residue. The pH-dependent magnetic circular dichroism spectra in the Soret region have also revealed that TaVII hemoglobin is in an equilibrium between a hexacoordinate and a pentacoordinate structure for its ferric heme iron. We attribute this to a transition from an iron-ligated water molecule that is hydrogen-bonded to the distal histidine, to a water-free iron with the histidine swung-out of the heme pocket. Furthermore, this process was described by the involvement of a single dissociable group with pKa = 6.3 in 0.1 M KCl at 25 degrees C.

Nemoglobins: Divergent nematode globins

Globins are proteins commonly associated with oxygen transport in vertebrate blood, but the invertebrate phyla display a wide variety of globin types that reflect their disparate life styles and evolutionary history. It has been known for over 100 years that parasitic nematodes contain globins, but recent molecular investigations are only now beginning to shed some light on their curious properties. Mark Blaxter here describes the diversity of the different globins found in nematodes, and reviews emerging data on their evolution and function.

Adventitious variability? The amino acid sequences of nonvertebrate globins

1. The more than 140 amino acid sequences of non-vertebrate hemoglobins (Hbs) and myoglobins (Mbs) that are known at present, can be divided into several distinct groups: (1) single-chain globins, containing one heme-binding domain; (2) truncated, single-chain, one-domain globins; (3) chimeric, one-domain globins; (4) chimeric, two-domain globins; and (5) chimeric multi-domain globins. 2. The crystal structures of eight nonvertebrate Hbs and Mbs are known, all of them monomeric, one-domain globin chains. Although these molecules represent plants, prokaryotes and several metazoan groups, and although the inter-subunit interactions in the dimeric and tetrameric molecules differ from the ones observed in vertebrate Hbs, the secondary structures of all seven one-domain globins retain the characteristic vertebrate "myoglobin fold". No crystal structures of globins representing the other four groups have been determined. 3. Furthermore, a number of the one-, two- and multi-domain globin chains participate in a broad variety of quaternary structures, ranging from homo- and heterodimers to highly complex, multisubunit aggregates with M(r) > 3000 kDa (S. N. Vinogradov, Comp. Biochem. Physiol. 82B, 1-15, 1985). 4. (1) The single-chain, single-domain globins are comparable in size to the vertebrate globins and exhibit the widest distribution. (A) Intracellular Hbs include: (i) the monomeric and polymeric Hbs of the polychaete Glycera; (ii) the tetrameric Hb of the echiuran Urechis; (iii) the dimeric Hbs of echinoderms such as Paracaudina and Caudina; and (iv) the dimeric and tetrameric Hbs of molluscs, the bivalves Scapharca, Anadara, Barbatia and Calyptogena. (B) Extracellular Hbs include: (i) the multiple monomeric and dimeric Hbs of the larva of the insect Chironomus; (ii) the Hbs of nematodes such as Trichostrongylus and Caenorhabditis; (iii) the globin chains forming tetramers and dodecamers and comprising approximately 2/3 of the giant (approximately 3600 kDa), hexagonal bilayer (HBL) Hbs of annelids, e.g. the oligochaete Lumbricus and the polychaete Tylorrhynchus and of the vestimentiferan Lamellibrachia; and (iv) the globin chains comprising the ca 400 kDa Hbs of Lamellibrachia and the pogonophoran Oligobrachia. (C) Cytoplasmic Hbs include: (i) the Mbs of molluscs, the gastropods Aplysia, Bursatella, Cerithedea, Nassa and Dolabella and the chiton Liolophura; (ii) the three Hb of the symbiont-harboring bivalve Lucina; (iii) the dimeric Hb of the bacterium Vitreoscilla; and (iv) plant Hbs, including the Hbs of symbiont-containing legumes (Lgbs), the Hbs of symbiont-containing non-leguminous plants and the Hbs in the roots of symbiont-free plants.(ABSTRACT TRUNCATED AT 400 WORDS)

Polymorphic hemoglobin from a midge larva (Tokunagayusurika akamusi) can be divided into two different types

The hemoglobin from the 4th-instar larva of Tokunagayusurika akamusi, a common midge found in eutrophic lakes in Japan, was composed of as many as 11 separable components (IA, IB, II, III, IV, V, VIA, VIB, VII, VIII, IX) on a DEAE-cellulose column. However, we have found that these components can be divided into two groups on the basis of their spectroscopic properties, one being named as the normal type (N-type) and the other being referred to as the low type (L-type). Since the major difference between them seemed to be the presence or absence of the distal (E7) histidine residue, which plays an important role in the stability properties of the bound dioxygen, the complete amino acid sequence was then determined for each typical component, namely, VII (N-type) and V (L-type): the former hemoglobin contained the usual distal histidine residue at position 64, whereas the latter one replaced it by isoleucine at position 66. The homology test for 40 N-terminal amino acid residues of all components also demonstrates that T. akamusi hemoglobin is composed of two different clusters showing a very early separation in the phylogenetic tree.

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

The cytoplasmic hemoglobin III from the gill of the symbiont-harboring clam Lucina pectinata consists of 152 amino acid residues, has a calculated Mm 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-Johnson et 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 A 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 two Lucina 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 two Lucina 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 the Lucina globins and the cytoplasmic hemoglobin of Busycon canaliculatum.

Amino-acid sequence of the cooperative dimeric myoglobin from the radular muscles of the marine gastropod Nassa mutabilis

The complete amino-acid sequence of the dimeric and cooperative myoglobin from the radular muscles of Nassa mutabilis, a common edible gastropod mollusc on the Italian coast, has been determined. The molecule is a homodimer. The monomer is composed of 147 amino-acid residues, with a molecular mass of 15,760 Da. Its sequence is homologous with those of the dimeric myoglobins of the gastropod molluscs of the Prosobranchia subclass Busycon canaliculatum (63% conserved residues) and Cerithidea rhizophorarum (46% conserved residues). The rate of autoxidation to met-myoglobin of N. mutabilis oxymyoglobin at 25 degrees C is strongly pH-dependent with relative minimal rate values in the pH range 7 to 8.

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

Myoglobin was isolated from the radular muscle of the chiton Liolophura 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 in Liolophura myoglobin. The autoxidation rate at physiological conditions indicated that Liolophura oxymyoglobin is fairly stable when compared with other molluscan myoglobins. The amino acid sequence of Liolophura myoglobin shows low homology (11-21%) with molluscan dimeric myoglobins and hemoglobins, but shows higher homology (26-29%) with monomeric myoglobins from the gastropodic molluscs Aplysia, Dolabella, and Bursatella. 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 clams Anadara, Scapharca, and Barbatia. Of special interest is the other subcluster. It consists of three hemoglobin chains derived from the bacterial symbiontharboring clams Calyptogena and Lucina, in which hemoglobins are supposed to play an important role in maintaining the symbiosis with sulfide bacteria.

Molecular mechanism for ligand stabilization in the mollusc myoglobin possessing the distal Val residue

Myoglobin extracted from the triturative stomach of Dolabella auricularia, a common mollusc found on the Japanese coast, possesses naturally occurring substitution at the distal E7 position (Val-E7) and its oxygen affinity is only slightly lower than those of the common mammalian myoglobins possessing the usual His-E7. 1H nuclear magnetic resonance studies of Dolabella met-cyano myoglobin have revealed that a guanidino NH proton of Arg-E10 is hydrogen-bonded to the Fe-bound CN-. The role of Arg-E10 as a hydrogen-bond donor for Fe-bound ligand in the present myoglobin appears to be responsible for its relatively high ligand affinity.

The Soret magnetic circular dichroism of ferric high-spin myoglobins. A probe for the distal histidine residue

To find a simple criterion for the presence of the distal (E7) histidine residue in myoglobins and hemoglobins, the Soret magnetic-circular-dichroic spectra were examined for ferric metmyoglobins from various species. A distinct and symmetric dispersion-type curve was obtained for myoglobins containing the distal histidine, whereas a relatively weak and unsymmetric pattern was observed for myoglobins lacking this residue, such as those from three kinds of gastropodic sea molluscs, a shark and the African elephant. The magnetic-circular-dichroic spectra obtained would thus be a direct reflection of the presence or absence of a water molecule at the sixth coordinate position of the heme iron(III), this axial water ligand being stabilized by hydrogen-bond formation to the distal histidine residue. On the basis of these Soret magnetic-circular-dichroic signals, we also examined the structure of a protozoan myoglobin (or a monomeric hemoglobin) from Paramecium caudatum of particular interest for the evolution of these proteins from protozoa to higher animals.

Stability properties of Aplysia oxymyoglobin: effect of esterification of the heme propionates

When compared with sperm whale MbO2 as a reference Aplysia MbO2 is extremely susceptible to autoxidation, and its pH dependence for the reaction is also unusual. Kinetic and thermodynamic analyses have shown that two types of carboxyl group with pKa = 4.3 and 6.1 at 25 degrees C are involved in the stability property of Aplysia MbO2, the protonation of these groups being responsible for an increase in its autoxidation rate in the acidic pH range. Since protoheme has two carboxyl groups of the propionic acid side-chains, we have prepared Aplysia myoglobin containing the dimethylester of protohemin. The autoxidation of this derivative was found to be described by the involvement of only one type of carboxyl group with pKa = 4.4. A possible candidate for the protein residue was therefore discussed on the basis of the known amino acid sequences of three Aplysia myoglobins: it is suggested that Glu-94, next to the proximal His-95, is the most likely candidate.

The amino acid sequence of hemoglobin II from the symbiont-harboring clam Lucina pectinata

The cytoplasmic hemoglobin II from the gill of the clam Lucina pectinata consists of 150 amino acid residues, has a calculated Mm of 17,476, including heme and an acetylated N-terminal residue. It retains the invariant residues Phe 44 at position CD1 and His 65 at the proximal position F8, as well as the highly conserved Trp 15 at position A12 and Pro 38 at position C2. The most likely candidate for the distal residue at position E7, based on the alignment with other globins, is Gln 65. However, optical and EPR spectroscopic studies of the ferri Hb II (Kraus, D. W., Wittenberg, J. B., Lu, J. F., and Peisach, J., J. Biol. Chem. 265, 16054-16059, 1990) have implicated a tyrosinate oxygen as the distal ligand. Modeling of the Lucina Hb II sequence, using the crystal structure of sperm whale aquometmyoglobin, showed that Tyr 30 substituting for the Leu located at position B10 can place its oxygen within 2.8 A of the water molecule occupying the distal ligand position. This structural alteration is facilitated by the coordinate mutation of the residue at position CD4, from Phe 46 in the sperm whale myoglobin sequence to Leu 47 in Lucina Hb II.

Amino acid sequence of myoglobin from the mollusc Bursatella leachii

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

Amino acid sequence of the dimeric hemoglobin (Hb I) from the deep-sea cold-seep clam Calyptogena soyoae and the phylogenetic relationship with other molluscan globins

The deep-sea cold-seep clam Calyptogena soyoae has two homodimeric hemoglobins (Hbs I and II) in erythrocytes. The complete amino acid sequence of Hb I has been determined. It is composed of 144 amino acid residues, has a high content of hydrophobic residues, and a calculated molecular weight of 16,350 including a heme group. The sequence of Calyptogena Hb I showed high homology (42% identity) with that of Calyptogena Hb II (Suzuki, T., Takagi T. and Ohta, S. (1989) Biochem. J. 260, 177-182), although it has a long insertion of seven residues in the C-terminal region compared with Hb II. On the other hand, it showed low homology (12-20% identity) with other molluscan globins. As well as Hb II, Calyptogena Hb I lacked the N-terminal extension of 7-9 residues characteristic of molluscan intracellular hemoglobins, and the distal (E7) histidine was replaced by glutamine. A phylogenetic tree was constructed from 13 molluscan globins belonging to the five families Aplysiidae, Galeodidae, Potamididae, Arcidae and Vesicomyidae. The globin sequences of Calyptogena (Vesicomyidae) were found to be rather distant from other globin sequences, suggesting that they might conserve a primitive form of molluscan globins.

Spectral properties unique to the myoglobins lacking the usual distal histidine residue

Myoglobins can be divided into two groups. One group contains the usual myoglobins that have histidine at the distal (E7) position, and the other contains a few, but interesting myoglobins that lack the usual distal histidine residue. Spectroscopic examinations have shown that there is a remarkable difference in the Soret band between the two types of myoglobin, and an absorbance ratio of the Soret peak of the acidic met-form to that of the oxy-form seems to be very useful as a simple criterion for predicting whether or not a myoglobin has the usual distal histidine residue.

Surface topography of histidine residues: a facile probe by immobilized metal ion affinity chromatography

Immobilized metal ion affinity chromatography (IMAC) has been explored as a probe into the topography of histidyl residues of a protein molecule. An evaluation of the chromatographic behavior of selected model proteins--thioredoxin, ubiquitin, calmodulin, lysozyme, cytochrome c, and myoglobin on immobilized transition metal ions (Co2+, Ni2+, Cu2+, and Zn2+)--allows establishment of the following facets of the histidyl side chain distribution: (i) either interior or surface; (ii) when localized on the surface, accessible or unaccessible for coordination; (iii) single or multiple; (iv) when multiple, either distant or vicinal. Moreover, proteins displaying single histidyl side chains on their surfaces may, in some instances, be resolved by IMAC; apparently, the microenvironments of histidyl residues are sufficiently diverse to result in different affinities for the immobilized metal ions. IMAC, previously introduced as an approach to the fractionation of proteins, has become also, upon closer examination, a facile probe into the topography of histidyl residues. This is possible because of the inherent versatility of IMAC; an appropriate metal ion (M2+) can be selected to suit the analytical purpose and a particular chromatographic protocol can be applied (isocratic pH, falling pH, and imidazole elution).

Aplysia limacina myoglobin. Crystallographic analysis at 1.6 A resolution

The crystal structure of the ferric form of myoglobin from the mollusc Aplysia limacina has been refined at 1.6 A resolution, by restrained crystallographic refinement methods. The crystallographic R-factor is 0.19. The tertiary structure of the molecule conforms to the common globin fold, consisting of eight alpha-helices. The N-terminal helix A and helix G deviate significantly from linearity. The distal residue is recognized as Val63 (E7), which, however, does not contact the heme directly. Moreover the sixth (distal) co-ordination position of heme iron is not occupied by a water molecule at neutrality, i.e. below the acid-alkaline transition point of A. limacina myoglobin. The heme group sits in its crevice in the conventional orientation and no signs of heme isomerism are evident. The iron atom is 0.26 A out of the porphyrin plane, with a mean Fe-N (porphyrin) distance of 2.01 A. The co-ordination bond to the proximal histidine has a length of 2.05 A, and forms an angle of 4 degrees with the heme normal. A plane containing the imidazole ring of the proximal His intersects the heme at an angle of 29 degrees with the (porphyrin) 4N-2N direction. Inspection of the structure of pH 9.0 indicates that a hydroxyl ion is bound to the Fe sixth co-ordination position.

Aplysia oxymyoglobin with an unusual stability property: involvement of two kinds of carboxyl groups

Unlike mammalian oxymyoglobins, Aplysia MbO2 is extremely susceptible to autoxidation, and its pH dependence is also unusual. Kinetic formulation has revealed that two kinds of dissociable group with pK1 = 4.3 and pK2 = 6.1, respectively, at 25 degrees C are involved in the stability property of Aplysia MbO2. In order to characterize thermodynamically these dissociation processes involved, the effect of temperature on K1 and K2 was studied by analyzing the pH dependence for the autoxidation rate of Aplysia MbO2 in 0.1 M buffer over the pH range of 4-11, and at 15, 25 and 35 degrees C. The resulting thermodynamic parameters for each group were both those to be expected for the ionization of a carboxyl group; the delta H degrees value being numerically much less than 1 kcal.mol-1, or zero in practice, but being associated with a large negative value of delta S degrees of the order of -20 cal.mol-1.K-1. Taking into account the fact that Aplysia myoglobin contains only a single histidine residue corresponding to the heme-binding proximal one, we can unequivocally conclude that the two kinds of the dissociable group involved in the unusual stability of Aplysia MbO2 must both be carboxyl groups, the protonation of these groups being responsible for an increase in its autoxidation rate in the acidic pH range.

An evolutionary tree for invertebrate globin sequences

A phylogenetic tree was constructed from 245 globin amino acid sequences. Of the six plant globins, five represented the Leguminosae and one the Ulmaceae. Among the invertebrate sequences, 7 represented the phylum Annelida, 13 represented Insecta and Crustacea of the phylum Arthropoda, and 6 represented the phylum Mollusca. Of the vertebrate globins, 4 represented the Agnatha and 209 represented the Gnathostomata. A common alignment was achieved for the 245 sequences using the parsimony principle, and a matrix of minimum mutational distances was constructed. The most parsimonious phylogenetic tree, i.e., the one having the lowest number of nucleotide substitutions that cause amino acid replacements, was obtained employing clustering and branch-swapping algorithms. Based on the available fossil record, the earliest split in the ancestral metazoan lineage was placed at 680 million years before present (Myr BP), the origin of vertebrates was placed at 510 Myr BP, and the separation of the Chondrichthyes and the Osteichthyes was placed at 425 Myr BP. Local "molecular clock" calculations were used to date the branch points on the descending branches of the various lineages within the plant and invertebrate portions of the tree. The tree divided the 245 sequences into five distinct clades that corresponded exactly to the five groups plants, annelids, arthropods, molluscs, and vertebrates. Furthermore, the maximum parsimony tree, in contrast to the unweighted pair group and distance Wagner trees, was consistent with the available fossil record and supported the hypotheses that the primitive hemoglobin of metazoans was monomeric and that the multisubunit extracellular hemoglobins found among the Annelida and the Arthropoda represent independently derived states.

Stability properties of oxymyoglobin from chicken gizzard smooth muscle

1. Oxymyoglobin (MbO2) was isolated directly from the smooth muscle of chicken gizzard and was examined for its spectral and stability properties. 2. When compared with sperm whale MbO2 as a reference, chicken gizzard MbO2 was found to be much more susceptible to autoxidation. Its pH-dependence was therefore analyzed in terms of an "acid-catalyzed three-state model". 3. The complete amino acid sequence of the myoglobin was also determined. Its hydropathy profile revealed that the region corresponding to the distal side of the heme iron appears to be less hydrophobic.