Crystallization and preliminary X-ray analysis of neural haemoglobin from the nemertean worm Cerebratulus lacteus.

The nemertean worm Cerebratulus lacteus neural tissue haemoglobin (109 amino acids, the shortest known haemoglobin) has been overexpressed in Escherichia coli, purified and crystallized. A highly redundant native data set has been collected at the Cu K(alpha) wavelength to 2.05 A resolution. The crystals belong to the orthorhombic P2(1)2(1)2(1) space group, with unit-cell parameters a = 42.5, b = 43.1, c = 60.2 A and one molecule per asymmetric unit. The anomalous difference Patterson map clearly reveals the position of the haem Fe atom, thus paving the way for MAD/SAD structure determination.

Nitric-oxide dioxygenase activity and function of flavohemoglobins. sensitivity to nitric oxide and carbon monoxide inhibition.

Widely distributed flavohemoglobins (flavoHbs) function as NO dioxygenases and confer upon cells a resistance to NO toxicity. FlavoHbs from Saccharomyces cerevisiae, Alcaligenes eutrophus, and Escherichia coli share similar spectra, O(2), NO, and CO binding kinetics, and steady-state NO dioxygenation kinetics. Turnover numbers (V(max)) for S. cerevisiae, A. eutrophus, and E. coli flavoHbs are 112, 290, and 365 NO heme(-1) s(-1), respectively, at 37 degrees C with 200 microm O(2). The K(M) values for NO are low and range from 0.1 to 0.25 microm. V(max)/K(M)(NO) ratios of 900-2900 microm(-1) s(-1) indicate an extremely efficient dioxygenation mechanism. Approximate K(M) values for O(2) range from 60 to 90 microm. NO inhibits the dioxygenases at NO:O(2) ratios of > or =1:100 and makes true K(M)(O(2)) values difficult to determine. High and roughly equal second order rate constants for O(2) and NO association with the reduced flavoHbs (17-50 microm(-1) s(-1)) and small NO dissociation rate constants suggest that NO inhibits the dioxygenase reaction by forming inactive flavoHbNO complexes. Carbon monoxide also binds reduced flavoHbs with high affinity and competitively inhibits NO dioxygenases with respect to O(2) (K(I)(CO) = approximately 1 microm). These results suggest that flavoHbs and related hemoglobins evolved as NO detoxifying components of nitrogen metabolism capable of discriminating O(2) from inhibitory NO and CO.

Lamprey hemoglobin. Structural basis of the bohr effect.

Lampreys, among the most primitive living vertebrates, have hemoglobins (Hbs) with self-association and ligand-binding properties very different from those that characterize the alpha(2)beta(2) tetrameric Hbs of higher vertebrates. Monomeric, ligated lamprey Hb self-associates to dimers and tetramers upon deoxygenation. Dissociation to monomers upon oxygenation accounts for the cooperative binding of O(2) and its pH dependence. Honzatko and Hendrickson (Honzatko, R. B., and Hendrickson, W. A. (1986) Proc. Natl. Acad. Sci. U. S. A 83, 8487-8491) proposed that the dimeric interface of the Hb resembles either the alpha(1)beta(2) interface of mammalian Hbs or the contacts in clam Hb where the E and F helices form the interface. Perutz (Perutz, M. F. (1989) Quart. Rev. Biophys. 2, 139- 236) proposed a version of the clam model in which the distal histidine swings out of the heme pocket upon deoxygenation to form a bond with a carboxyl group of a second monomer. The sedimentation behavior and oxygen equilibria of nine mutants of the major Hb component, PMII, from Petromyzon marinus have been measured to test these models. The results strongly support a critical role of the E helix and the AB corner in forming the subunit interface in the dimer and rule out the alpha(1)beta(2) model. The pH dependence of both the sedimentation equilibrium and the oxygen binding of the mutant E75Q indicate that Glu(75) is one of two groups responsible for the Bohr effect. Changing the distal histidine 73 to glutamine almost completely abolishes the self-association of the deoxy-Hb and causes a large increase in O(2) affinity. The recent x-ray crystallographic determination of the structure of deoxy lamprey Hb, reported after the completion of this work (Heaslet, H. A., and Royer, W. E. (1999) Structure 7, 517-526), shows that the dimer interface does involve the E helix and the AB corner, supporting the measurements and interpretations reported here.

The structural and functional analysis of the hemoglobin D component from chicken.

Oxygen binding by chicken blood shows enhanced cooperativity at high levels of oxygen saturation. This implies that deoxy hemoglobin tetramers self-associate. The crystal structure of an R-state form of chicken hemoglobin D has been solved to 2.3-A resolution using molecular replacement phases derived from human oxyhemoglobin. The model consists of an alpha2 beta2 tetramer in the asymmetric unit and has been refined to a R-factor of 0.222 (R-free = 0.257) for 29,702 reflections between 10.0- and 2.3-A resolution. Chicken Hb D differs most from human oxyhemoglobin in the AB and GH corners of the alpha subunits and the EF corner of the beta subunits. Reanalysis of published oxygen binding data for chicken Hbs shows that both chicken Hb A and Hb D possess enhanced cooperativity in vitro when inositol hexaphosphate is present. The electrostatic surface potential for a calculated model of chicken deoxy-Hb D tetramers shows a pronounced hydrophobic patch that involves parts of the D and E helices of the beta subunits. This hydrophobic patch is a promising candidate for a tetramer-tetramer interface that could regulate oxygen binding via the distal histidine.

Identification of myoglobin in human smooth muscle.

Myoglobin (Mb) has been believed to be absent generally from mammalian smooth muscle tissue. Examination of human rectal, uterine, bladder, colon, small intestine, arterial, and venous smooth muscle by immunohistochemical techniques shows that each of these tissues is immunopositive for both smooth muscle myosin and human Mb. Mb-specific primers were used for the polymerase chain reaction to generate cDNA from smooth muscle tissues. Southern hybridization with a Mb-specific probe gave a very strong signal with the cDNA from rectum, weaker signals from small intestine and uterus, a faint signal from colon, and no signal from bladder tissue. High performance liquid chromatography analysis coupled with sequence determination has shown that contaminating heme-binding serum albumin as well as hemoglobin in extracts of smooth muscle seriously compromise any heme-based or spectrophotometric assay of Mb. Combined affinity and size exclusion chromatography, however, provide the necessary resolution. The cDNA-derived amino acid sequence of human smooth muscle Mb was found to be identical to that of Mb from striated muscle.

The mini-hemoglobins in neural and body wall tissue of the nemertean worm, Cerebratulus lacteus.

Hemoglobin (Hb) occurs in circulating red blood cells, neural tissue, and body wall muscle tissue of the nemertean worm, Cerebratulus lacteus. The neural and body wall tissue each express single major Hb components for which the amino acid sequences have been deduced from cDNA and genomic DNA. These 109-residue globins form the smallest stable Hbs known. The globin genes have three exons and two introns with splice sites in the highly conserved positions of most globin genes. Alignment of the sequences with those of other globins indicates that the A, B, and H helices are about one-half the typical length. Phylogenetic analysis indicates that shortening results in a small tendency of globins to group together regardless of their actual relationships. The neural and body wall Hbs in situ are half-saturated with O2 at 2.9 and 4.1 torr, respectively. The Hill coefficient for the neural Hb in situ, approximately 2.9, suggests that the neural Hb self-associates in the deoxy state at least to tetramers at the 2-3 mM (heme) concentration estimated in the cells. The Hb must dissociate upon oxygenation and dilution because the weight-average molecular mass of the HbO2 in vitro is only about 18 kDa at 2-3 microM heme concentration. Calculations suggest that the Hb can function as an O2 store capable of extending neuronal activity in an anoxic environment for 5-30 min.

Self-association, cooperativity and supercooperativity of oxygen binding by hemoglobins.

Cooperative ligand binding by tetrameric vertebrate hemoglobins (Hbs) makes possible the delivery of oxygen at higher pressures than would otherwise occur. This cooperativity depends on changes in dimer-dimer interactions within the tetramer and is reflected in a 50 000-fold increase in the tetramer-dimer dissociation constant in human Hb upon oxygenation at pH 7.4, from approximately 2x10(-11)mol l-1 to approximately 10(-6)mol l-1. Hbs that undergo such ligand-dependent changes in association are widespread in non-vertebrates, where the mechanisms are very different from those in vertebrates. Oligomeric Hbs have been identified in organisms in five phyla (molluscs, echinoderms, annelids, phoronids and chordates) that dissociate to subunits upon oxidation of the heme iron and reassociate with the binding of ferric iron ligands such as CN-, N3- or NO2-. Thus, the valence and ligand state of the heme iron control the stability of a critical subunit interface. The broad distribution of this phenomenon suggests a common mechanism of communication between heme and interface that may be almost universal among non-vertebrate Hbs. This interaction may be similar to that known for the homodimeric Hb of the mollusc Scapharca inaequivalvis. Although muscle tissue Hbs or myoglobins (Mbs) are usually monomeric, with non-cooperative O2 binding, the radular muscles of gastropod molluscs and chitons have homodimeric Mbs that bind O2 cooperatively. Cooperative non-muscle tissue Hbs have also been identified. These include the neural Hb of the nemertean worm Cerebratulus lacteus and the Hb of the diving beetle Anisops assimilis, which exhibit deoxygenation-dependent self-association of monomers that is associated with high Hill coefficients. Calculations suggest that the 2-3 mmol l-1 concentration of Hb on a heme basis in the brain of Cerebratulus should substantially extend the time as an active predator in an anaerobic or hypoxic environment. Oxygen from the Hb of Anisops is delivered to a gas bubble and thereby controls the buoyant density. Many Hbs of amphibians, reptiles, birds and some embryonic mammals exhibit a further 'supercooperativity' of O2 binding which depends on reversible deoxygenation-dependent tetramer-tetramer association to form an assemblage with a very low affinity for O2. This phenomenon results in steeper O2-binding curves than exhibited by tetramers alone. The increased cooperativity should result in an increase in the amount of O2 delivered to the tissues and should be especially valuable for avian flight muscles.

Structure of chain d of the gigantic hemoglobin of the earthworm.

The extracellular hemoglobin of the earthworm has four major O2-binding chains, a, b, c and d, together with additional non-heme structural chains that are required for assembly. Although the abc trimer self-associates extensively at least to (abc)10, addition of chain d results in the formation of a discrete 280 kDa complex corresponding to (abcd)4. Thus a primary function of chain d is to cap the abc association and convert an abc trimer that binds O2 with weak cooperativity to a highly cooperative (abcd)4 complex. Amino-acid sequences of the major globin chains a, b, c have been determined previously by peptide and cDNA analysis. However, the peptide sequence reported for the major chain d (Shishikura, F., Snow, J.W., Gotoh, T., Vinogradov, S.N. and Walz, D.A. (1987) J. Biol. Chem., 262. 3123-3131), has a calculated molecular mass 134-167 Da higher than masses for components of chain d determined by mass spectrometry (Owrby, D.W., Zhu, H., Schneider, K., Beavis, R.C., Chait, B.T. and Riggs, A.F. (1993) J. Biol. Chem. 268, 13539-13547). Reverse-phase HPLC confirms the presence of two distinct polypeptides, d1 and d2, together with d'1, a variant of d1, cDNA derived amino acid sequences have been determined for chains d'1 and d2 by application of the polymerase chain reaction with primers based on the NH2-terminal sequences and oligo-dT. Each of the two cDNA-derived sequences has 140 residues and they differ by 28 substitutions. The data show that the sequence originally reported had been derived from peptides generated from both polypeptides.

Stoichiometry of subunits and heme content of hemoglobin from the earthworm Lumbricus terrestris.

The extracellular hemoglobin (Hb) of the earthworm, Lumbricus terrestris, has four major O2-binding chains, a, b, c (forming a disulfide-linked trimer), and d ("monomer"). Additional structural chains, "linkers," are required for the assembly of the approximately 200-polypeptide molecule. The proportion of linker chains had been reported to be one-third of the total mass on the basis of densitometry of Coomassie Blue-stained SDS-gels. Reverse-phase high performance liquid chromatography (HPLC), however, gave 16.3% linkers on the basis of both 220-nm absorbance and amino acid analysis (Ownby, D. W., Zhu, H., Schneider, K., Beavis, R. C., Chait, B. C., and Riggs, A. F. (1993) J. Biol. Chem. 268, 13539-13547). The subunit proportions have now been redetermined by SDS capillary electrophoresis as a test of the HPLC results. The electrophoresis, monitored at 214 nm, avoided the use of Coomassie Blue and provided results identical with those obtained by HPLC. Capillary electrophoresis monitored at both 214 and 415 nm was used to show that linker chains do not bind heme. Heme content has been found to be 2.9% by determination of hemin, amino acid analysis and dry weight. Measurement of the rate of hemin loss from oxidized L. terrestris Hb shows that high rates of loss can account for values of heme content significantly below 2.9% (or 0.26% iron).

Assembly of the gigantic hemoglobin of the earthworm Lumbricus terrestris. Roles of subunit equilibria, non-globin linker chains, and valence of the heme iron.

The extracellular hemoglobin of the earthworm Lumbricus terrestris has four major kinds of O2-binding chains: a, b, and c (forming a disulfide-linked trimer), and chain d. Non-heme, non-globin structural chains, "linkers," are also present. Light-scattering techniques have been used to show that the ferrous CO-saturated abc trimer and chain d form an (abcd)4 complex of 285 kDa at neutral pH. Formation of the full-sized 4-MDa molecule requires the addition of linker chains in the proportion of two linkers per (abcd)4 and occurs much more rapidly in the presence of 10 mM calcium. This stoichiometry is supported not only by direct quantitative analysis of the intact hemoglobin but also by the fact that the addition of 50% of the proposed stoichiometric quantity of linkers results in the conversion of 50% of the (abcd)4 to full-sized molecules. Isolated CO-saturated abc trimers self-associate to (abc)2 and higher aggregates up to an apparent limit of (abc)10 approximately 550 kDa. The CO-saturated chain d forms dimers, (d)2, and tetramers, (d)4. Oxidation of the (abcd)4 complex with ferricyanide causes complete dissociation of chain d from the abc trimer, but addition of CN- maintains the (abcd)4 complex. Valence hybrids have also been studied. The ferrous CO-saturated abc trimer and met (ferric) chain d also associate to form (abcd)4, but the met abc trimer and ferrous CO-saturated chain d do not. Oxidation of the abc trimer and chain d to the ferric form causes the formation of a characteristic hemichrome spectrum with a maximum at 565 nm and a shoulder near 530 nm. These results show that interactions between the abc trimer and chain d are strongly dependent on the ligand and valence state of the heme iron. Light-scattering measurements reveal that oxidation of the intact Hb produces a significant drop in molecular mass from 4.1 to 3.6 MDa. Inclusion of CN- prevents this drop. These experiments indicate that oxidation causes the Hb to shed subunits. The observations provide an explanation for the wide variations in the molecular mass of L. terrestris Hb that have been observed previously.

Structural analysis of Urechis caupo hemoglobin.

The structure of Urechis caupo hemoglobin in the cyanomet state has been refined to R = 0.148 at 2.5 A resolution. Although the tertiary structure is similar to that of other vertebrate and invertebrate hemoglobins the quaternary structures of this tetramer is unique as suggested by the earlier determination of the 5.0 A resolution structure. The G and H helices of the hemoglobin are on the outside of the tetramer facing the solvent in contrast to human hemoglobin where the G and H helices form inter-subunit contacts. A substantial number of tightly bound water molecules help mediate interactions between subunits. The unusual arrangement of subunits is consistent with the general lack of co-operativity of oxygen uptake for Urechis caupo hemoglobin.

The hemoglobins of the bullfrog, Rana catesbeiana. The cDNA-derived amino acid sequences of the alpha chains of adult hemoglobins B and C: their roles in deoxygenation-induced aggregation.

The adult bullfrog (Rana catesbeiana) has two major tetrameric hemoglobins, B and C, which share a common beta chain but have different alpha chains. Components B and C associate upon deoxygenation to form a complex of the form BC2, a trimer of tetramers that depends on contacts between the alpha B and alpha C chains. Nucleotide sequences of cDNA transcripts for these chains have been determined. Transcripts were identified by analysis of the amino acid compositions of the tryptic peptides of the components and by partial amino acid sequencing. These results, together with the amino acid sequence of the beta chain (Tam, L.-T., Gray, G. P., and Riggs, A. F. (1986) J. Biol. Chem. 261, 8290-8294), permit an analysis of the structures of the alpha 2 beta 2 tetramers of hemoglobins B and C. Molecular modeling suggests possible residues at the alpha B-alpha C interfaces in the BC2 trimer and additional alpha C-alpha C contacts that would form a closed ring of six alpha chain subunits that would further stabilize the BC2 trimer. Phylogenetic analysis of the alpha B sequence suggests that it may be a "tadpole" chain, the temporal expression of which has shifted from larva to adult.

The hemoglobins of the bullfrog, Rana catesbeiana. Deoxygenation-linked association of tetrameric components B and C to form the trimer BC2: sedimentation analysis and oxygen equilibria.

Hemolysates from the adult bullfrog, Rana catesbeiana, show an unusually high degree of cooperativity of oxygen binding with Hill coefficients greater than 4. The principal components of the tetrameric hemoglobin, B and C, do not show this high cooperativity when isolated, but it reappears when the components are mixed. Sedimentation velocity measurements show that the unusual behavior results from the mixed association of components B and C to form complexes larger than tetramers. Computer simulation of the sedimentation behavior of mixtures of deoxygenated B and C components shows that the gradient profiles can be satisfactorily described in terms of an equilibrium between the B and C tetramers and a BC2 trimer. The simplest model consistent with the results is the mixed association: B + C<-->BC and BC + C<-->BC2, with the second binding constant being higher than the first, indicating significant cooperativity. The extent of association is highest at low pH and low temperature. The dissociation of the B.C complex with low oxygen affinity to higher affinity B and C molecules during oxygenation results in greatly increased cooperativity of oxygen binding with higher Hill coefficients than possessed by either component alone in equilibria measured between 5 and 25 degrees C and between pH 6 and 8.

The extracellular hemoglobin of the earthworm, Lumbricus terrestris. Determination of subunit stoichiometry.

The giant extracellular hemoglobin of the earthworm, Lumbricus terrestris, has four major O2-binding chains, a, b, and c (forming a disulfide-linked trimer) and d ("monomer"). Participation of additional "linker" chains L1, L2, and L3 is necessary for the assembly of the approximately 3,900+ kDa two-tiered hexagonal structure. We have determined the proportions of linker chains, trimer, and chain d in the hemoglobin by reverse phase high performance liquid chromatography which resolves all of the components and also permits simultaneous determination of the heme content. The proportions of components were determined by two independent procedures: integration of the absorbance peaks at 220 nm and amino acid analysis of the peak fractions. The results indicate that the weight proportion of linker chains is 0.163 +/- 0.023. This value, together with molecular masses determined both by amino acid sequence analysis and by matrix-assisted laser desorption mass spectrometry, gives a molar ratio of abcd chains to linkers of 8:1, corresponding to the minimal unit (abcd)2.L. This ratio suggests that 24 (abcd)2 units and 24 linker chains form the complete structure with a total calculated mass of polypeptide of 3,975 kDa with hemes on chains a, b, c and d and on one linker. The calculated heme content is 3.1% not including carbohydrate. This accounts for a measured heme content of 3.0% on a polypeptide basis. Additional mass (approximately 133 kDa, 3.4%), attributed to carbohydrate, brings the total mass to 4,108 kDa with a minimum molecular mass/heme of 20,500 Da. The presence of equimolar quantities of three unique linker chains means that the apparent one-twelfth structural units seen by electron microscopy cannot all be identical.

Linker chain L1 of earthworm hemoglobin. Structure of gene and protein: homology with low density lipoprotein receptor.

The extracellular hemoglobins (Hbs) of annelids and tube worms are giant multisubunit proteins of up to approximately 200 polypeptides and molecular masses to at least 3,900 kDa. They differ from all other Hbs in having both O2-binding chains and "linker" chains. The latter are required for assembly and structural integrity of the protein and are deficient in or lack heme. We have determined the nucleotide sequences of the cDNA and gene for linker chain L1 of the hemoglobin of Lumbricus terrestris. The cDNA-derived amino acid sequence has 225 residues and a calculated molecular mass of 25,847 Da. The chain is 21-28% identical to linker chains of the related annelid Tylorrhynchus heterochaetus and the deep-sea tube worm Lamellibrachia sp. A remarkable feature of the linker chains is a conserved 38-39-residue segment that contains a repeating pattern of cysteinyl residues: (Cys-X6)3-Cys-X5-Cys-X10-Cys. This pattern, not present in any globin sequence, corresponds exactly to the cysteine-rich repeats of the ligand binding domains of the low density lipoprotein (LDL) receptors of man and Xenopus laevis. Furthermore, the cysteine-rich segment of linker chain L1 has the sequence Asp-Gly-Ser-Asp-Glu which is characteristic of LDL receptor repeats. Similar cysteine-rich sequences also occur in two other mammalian proteins, complement C9 and renal glycoprotein GP330. The results support the conclusion that the cysteine-rich motif of the LDL receptor and annelid Hbs is a multipurpose protein-binding unit of ancient origin which has been incorporated into diverse unrelated proteins, presumably by the process of exon shuffling.

Yeast flavohemoglobin is an ancient protein related to globins and a reductase family.

The hemoglobin of yeast is a two-domain protein with both heme and flavin prosthetic groups. The nucleotide sequences of the cDNA and genomic DNA encoding the protein from Saccharomyces cerevisiae show that introns are absent and that both domains are homologous with a flavoheme protein from Escherichia coli. The heme domains are also homologous with those of O2-binding heme proteins from several other distantly related bacteria, plants, and animals; all appear to be members of the same globin superfamily. Although the homologous hemoglobin of the bacterium Vitreoscilla sp. is a single-domain protein, several bacteria have related O2-binding heme proteins whose second domains have different structures and enzymatic activities: dihydropteridine reductase (E. coli), cytochrome c reductase (Alcaligenes eutrophus), and kinase in the O2 sensor of Rhizobium meliloti. This indicates that one evolutionary pathway of hemoglobin is that of a multipurpose domain attached to a variety of unrelated proteins to form molecules with different functions. The flavin domain of yeast hemoglobin is homologous with members of a flavoprotein family that includes ferredoxin reductase, nitric oxide synthase, and cytochrome P-450 reductase. The correspondence of yeast and E. coli flavohemoglobins indicates that the two-domain protein has been conserved intact for as long as 1.8 billion years, the estimated time of divergence of prokaryotes and eukaryotes provided that cross-species gene transfer has not occurred.

Deoxygenation-linked association of a tetrameric component of chicken hemoglobin.

Deoxygenation-dependent association of hemoglobin tetramers appears to be widespread among amphibians, reptiles, and possibly all or most birds. The evidence for this conclusion depends largely on oxygen equilibria of whole blood which have Hill coefficients that reach values as high as 5-7 at 80-90% oxygenation. Computer simulation of the sedimentation velocity behavior of the major components A and D of chicken hemoglobin shows that component D but not A self-associates to form dimers of tetramers. The gradient profiles at pH 7.5 were satisfactorily fitted with an association constant of 1.26 x 10(4) M-1 and sedimentation coefficients of 4.63 and 7.35 S for tetramer and (tetramer)2, respectively. Since components A and D share common beta chains we conclude that tetramer-tetramer contacts must depend on surface residues of the alpha chains. Comparison of the amino acid sequences of the alpha D and alpha A chains of the hemoglobins from 12 avian species ranging from sparrow to ostrich shows that 20 residues are conserved in the alpha D chains but not in the alpha A chains. Nine of these (45%) are clustered between positions E20 and FG2. Four of the latter, Lys71 (E20), Asn75 (EF4), Gln78 (EF7), and Glu82 (F3) are conserved in all alpha D chains even though they do not appear to participate in intratetramer contacts. Molecular modeling indicates that residues Lys71, Gln78, and Glu82 of the alpha chain are strong candidates for the primary tetramer-tetramer contacts.

Origin of a "bridge" intron in the gene for a two-domain globin.

Red cells of the clam Barbatia reeveana express two hemoglobins, one composed of 16- to 17-kDa chains and the other of 35-kDa chains. The nucleotide sequence of the cDNA encoding the 35-kDa chain shows that the polypeptide has two very similar heme-binding domains, which are joined without use of an additional bridging sequence. Two novel introns occur in the gene for the two-domain globin: one, the "precoding" intron, is located two bases 5' from the start codon, and the other, a "bridge" intron, separates the DNA sequences encoding the two domains. Close correspondence exists between the 3' end of the precoding intron and the 3' end of the bridge intron and between parts of the 3' noncoding region of the cDNA for the two-domain globin and the 5' end of the bridge intron. These observations indicate that the bridge intron arose by unequal crossing-over between two identical or very similar genes for a single-domain globin. This conclusion, together with the proposal that exons were initially independent "minigenes" [Gilbert, W. (1987) Cold Spring Harbor Symp. Quant. Biol. 52, 901-905], suggests that many introns may have evolved from the 5' noncoding region of one gene and/or the 3' noncoding region of a second gene. This hypothesis implies that splice junctions would be associated with the original NH2 and COOH termini of proteins and provides an explanation for the observation that splice junctions usually map to protein surfaces. They do so because most NH2- and COOH-terminal residues are usually located on or near the surfaces of proteins.

The extracellular hemoglobin of the earthworm, Lumbricus terrestris. Oxygenation properties of isolated chains, trimer, and a reassociated product.

The extracellular hemoglobin of the earthworm Lumbricus terrestris has a two-tiered hexagonal structure that can be dissociated into 1/12 subunits. The Hb contains four major kinds of oxygen-binding chains, a, b, c, and d, of which a-c form a disulfide-linked trimer. Additional non-heme chains are necessary for the assembly of the intact 3800-kDa molecule of approximately 200 subunits. Oxygen equilibria have been measured for chains c and d, the abc trimer, the partially reassembled product of addition of chain d to the trimer, and the intact molecule. The results show that oxygenation of the trimer but not the isolated c or d subunits is modulated by both pH and Ca2+ ions. Cooperativity of oxygen binding by the trimer is low (Hill coefficient approximately 1.3). However, addition of chain d results in a substantial decrease in oxygen affinity and a large increase in cooperativity so that the oxygen equilibrium becomes indistinguishable from that of the intact native molecule at pH 6.8. Light-scattering data show that the smallest observed trimeric abc unit is the dimer (abc)2 at pH 6.8. Analysis of the major sedimentation velocity boundary of the product of the abc unit and chain d in the CO form in the absence of calcium surprisingly can be accounted for entirely in terms of a nondissociating dimer, (abc)2, and chain d. The data for the CO form in the presence of calcium are best fitted in terms of (abc)2.d. Although both subunits c and d also form dimers, oxygen binding by subunit c, but not d, is highly cooperative. These observations, taken together, suggest that the two dimers (abc)2 and d2 are likely to be the major participants in forming the primary functional unit, (abcd)2, which at pH 7.4 is partially dissociated when in the CO form. Subunit d is clearly necessary for the formation of a cooperative unit. The hypothesis that (abcd)2 is a primary functional unit is consistent with a stoichiometry of 2 (abcd)2 units per 1/12 subunit or 24 such units in each molecule of Hb which would contain, in all, 192 heme-containing chains.

The structure of the gene encoding chain c of the hemoglobin of the earthworm, Lumbricus terrestris.

The complete nucleotide sequence of the gene for chain c of hemoglobin of the earthworm Lumbricus terrestris has been determined. The sequence of 4037 base pairs (bp) includes about 310 bp of 5'-flanking sequence and 110 bp 3' to the poly(A) site. Comparison of cDNA and genomic sequences shows four silent differences in codons that suggest the presence of at least two genes. The coding sequence is split by two introns of 1344 and 1169 bp at highly conserved positions (Jhiang, S. M., Garey, J. R., and Riggs, A. F. (1988) Science 240, 334-336). The first intron possesses the unusual 5' splice junction sequence GC instead of GT. Many tandem triplet repeats based on (GAT) and (CCT) are present in the first intron. The second intron has nine tandem repeats based on the consensus sequence AAGGAAGGAGGTC. Each intron has several exact inverted repeats of 9-10 bp that might result in loops of 78-140 nucleotides in the RNA prior to splicing. The sequences in the second intron, at positions 2423-2644 are about 65% identical with parts of several genes found in yeast mitochondria and in DNA from several other organisms.