Primary structure of hemoglobin from cobraNaja naja naja

Cobra snakeNaja naja naja hemoglobin shows four bands on Triton electrophoresis. We present the primary structure of one and one chain. The separation of polypeptide chains was achieved by ion exchange chromatography on carboxymethyl cellulose column. The amino acid sequence was established by automatic Edman degradation of the native chains and tryptic and hydrolytic peptides in a gas-phase sequencer. The structural data are compared with those of human and other reptile hemoglobins and reveal not only large variations from human but within reptiles. The amino acid exchanges involve several subunit contacts and heme binding sites. This is the first study on the hemoglobin of a land snake. There are only two amino acid sequences of sea snake hemoglobin (Microcephalophis gracilis gracilis andLiophis miliaris) reported in the literature.     

Partial sequence of hemoglobin from cobra (Naja naja naja)

Hemoglobin from the cobra snake, Naja naja naja, was isolated and its chains separated on a CM-cellulose column. The separation profile revealed an and two chains having the molar proportions of []₂,[ ₁]₁,[ ₂]₁. The N-terminal amino acid sequence of the intact chains and of the CNBr peptides were carried out. The ₂ chain was found to be heterogeneous comprising a minor component amounting to 11%. This later showed changes at two positions 9 and 14 in the first 30 residues sequenced.     

Primary structure and functional properties of cobra (Naja naja naja) venom Kunitz-type trypsin inhibitor.

A trypsin inhibitor from the venom of the cobra Naja naja naja has been isolated by a single step of reverse-phase high-performance liquid chromatography. The protein strongly inhibits trypsin (Ki = 3.5 pM). The primary structure was determined by peptide analysis of the [14C]carboxymethylated inhibitor. The 57-residue polypeptide chain belongs to the family of Kunitz-type inhibitors, and exhibits 42% residue identity with bovine pancreatic trypsin inhibitor. The structure shows only 70% identity with the corresponding peptide from the Capa cobra (Naja nevia), establishing that the inhibitor molecule exhibits extensive variations. Functionally, a basic residue at position P3' correlates with strong inhibition.     

Primary structure of abnormal E-like hemoglobin]

An E-like abnormal hemoglobin was detected in a hematological patient and one of the members of her family. The composition of blood hemolyzates was characterized using acetate cellulose electrophoresis. The abnormal beta-chain was isolated by ion-exchange chromatography of total globin on CM-cellulose. Using peptide mapping of the abnormal beta-chain trypsin hydrolysates, it was shown that the amino acid substitution occurs in peptide beta T3. The amino acid analysis and determination of the abnormal fragment C-terminal amino acid allowed to establish the locus and type of this substitution. The first case of hemoglobin E(alpha 2 beta 2 26Glu leads to Lys) identification on the territory of the USSR is reported.     

Primary structure of hemoglobin from monitor lizard (Varanus exanthematicus albigularis--Squamata)

The primary structure of the major hemoglobin component from the Monitor Lizard Varanus exanthematicus albigularis is presented. The polypeptide subunits were separated by reversed-phase high-performance liquid chromatography on Nucleosil C-4 column. The amino-acid sequence was established by automatic Edman degradation of the native polypeptide and its tryptic and hydrolytic cleavage products in a spinning cup sequencer. The structural data are discussed with reference to other reptiles.     

Primary structure of hemoglobin from gray partridge (Francolinus pondacerianus, Galliformes)

The complete amino acid sequence of the ^A-chain of major hemoglobin component from gray partridgeFrancolinus pondacerianus is presented. The major component HbA accounts for 75% of the total hemolysate. Separation of the globin subunits was achieved by ion-exchange chromatography on CM-Cellulose in 8 M urea. The sequence was studied by automatic Edman degradation of the native chain and its tryptic peptides in a gas-phase sequencer. The phylogenetic relationship of Galliformes with other avian orders is discussed.     

Primary structure of chain I of the heterodimeric hemoglobin from the blood clamBarbatia virescens

The blood clamBarbatia virescens has a heterodimeric hemoglobin in erythrocytes. Interestingly, the congeneric clamsB. reeveana andB. lima contain quite different hemoglobins: tetramer and polymeric hemoglobin consisting of unusual didomain chain. The complete amino acid sequence of chain I ofB. virescens has been determined. The sequence was mainly determined from CNBr peptides and their subpeptides, and the alignment of the peptides was confirmed by sequencing of PCR-amplified cDNA forB. virescens chain I. The cDNA-derived amino acid sequence matched completely with the sequence proposed from protein sequencing.B. virescens chain I is composed of 156 amino acid residues, and the molecular mass was calculated to be 18,387 D, including a heme group. The sequence ofB. virescens chain I showed 35–42% sequence identity with those of the related clamAnadara trapezia and the congeneric clamB. reeveana. An evolutionary tree forAnadara andBarbatia chains clearly indicates that all of the chains are evolved from one ancestral globin gene, and that the divergence of chains has occurred in each clam after the speciation. The evolutionary rate for clam hemoglobins was estimated to be about four times faster than that of vertebrate hemoglobin. We suggest that blood clam hemoglobin is a physiologically less important molecule when compared with vertebrate hemoglobins, and so it evolved rapidly and resulted in a remarkable diversity in quaternary and subunit structure within a relatively short period.     

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

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

Primary structure of adult hemoglobin of white-throated capuchin, Cebus capucinus

The alpha and beta chains of White-Throated Capuchin (Cebus capucinus) hemoglobin were separated and digested by trypsin. The tryptic peptides were isolated and sequenced by conventional methods. The peptides in each chain were aligned by the homology of their sequences with those of human adult hemoglobin. The primary structures thus deduced are compared with those of other primate hemoglobins, and we discuss the molecular evolution of hemoglobins, in particular the rate of evolution in New World monkey hemoglobins.     

Primary structure of chain I of the heterodimeric hemoglobin from the blood clamBarbatia virescens

The blood clamBarbatia virescens has a heterodimeric hemoglobin in erythrocytes. Interestingly, the congeneric clamsB. reeveana andB. lima contain quite different hemoglobins: tetramer and polymeric hemoglobin consisting of unusual didomain chain. The complete amino acid sequence of chain I ofB. virescens has been determined. The sequence was mainly determined from CNBr peptides and their subpeptides, and the alignment of the peptides was confirmed by sequencing of PCR-amplified cDNA forB. virescens chain I. The cDNA-derived amino acid sequence matched completely with the sequence proposed from protein sequencing.B. virescens chain I is composed of 156 amino acid residues, and the molecular mass was calculated to be 18,387 D, including a heme group. The sequence ofB. virescens chain I showed 35–42% sequence identity with those of the related clamAnadara trapezia and the congeneric clamB. reeveana. An evolutionary tree forAnadara andBarbatia chains clearly indicates that all of the chains are evolved from one ancestral globin gene, and that the divergence of chains has occurred in each clam after the speciation. The evolutionary rate for clam hemoglobins was estimated to be about four times faster than that of vertebrate hemoglobin. We suggest that blood clam hemoglobin is a physiologically less important molecule when compared with vertebrate hemoglobins, and so it evolved rapidly and resulted in a remarkable diversity in quaternary and subunit structure within a relatively short period.     

Primary structure of the hemoglobin beta-chain of rose-ringed parakeet (Psittacula krameri)

The primary structure of Rose-ringed Parakeet hemoglobin -chain was established, completing the analysis of this hemoglobin. Comparisons with other avian -chains show variations smaller than those for the corresponding -chains. There are 11 amino acid exchanges in relationship to the only other characterized psittaciform -chain, and a total of 35 positions are affected by differences among all avian -chains analyzed (versus 61 for the -chains). At three positions, the Psittacula -chain has residues unique to this species. Three ₁₁ contacts are modified, by substitutions at positions 51, 116, and 125.     

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

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

Primary structure of the hemoglobin alpha-chain of rose-ringed parakeet (Psittacula krameri)

The structure of the hernoglobin -chain of Rose-ringed Parakeet was determined by sequence degradations of the intact subunit, the CNBr fragments, and peptides obtained by digestion with staphylococcal Glu-specific protease and trypsin. Using this analysis, the complete -chain structure of 21 avian species is known, permitting comparisons of the protein structure and of avian relationships. The structure exhibits differences from previously established avian -chains at a total of 61 positions, five of which have residues unique to those of the parakeet (Ser-12, Gly-65, Ser-67, Ala-121, and Leu-134). The analysis defines hemoglobin variation within an additional avian order (Psittaciformes), demonstrates distant patterns for evaluation of relationships within other avian orders, and lends support to taxonomic conclusions from molecular data.     

The refined crystal structure of alpha-cobratoxin from Naja naja siamensis at 2.4-A resolution

The crystal structure of the "long" alpha-neurotoxin alpha-cobratoxin was refined to an R-factor of 19.5% using 3271 x-ray data to 2.4-A resolution. The polypeptide chain forms three loops, I, II, III, knotted together by four disulfide bridges, with the most prominent, loop II, containing another disulfide close to its lower tip. Loop I is stabilized by one beta-turn and two beta-sheet hydrogen bonds; loop II by eight beta-sheet hydrogen bonds, with the tip folded into two distorted right-handed helical turns stabilized by two alpha-helical and two beta-turn hydrogen bonds; and loop III by hydrophobic interactions and one beta-turn. Loop II and one strand of loop III form an antiparallel triple-pleated beta-sheet, and tight anchoring of the Asn63 side chain fixes the tail segment. In the crystal lattice, the alpha-cobratoxin molecules dimerize by beta-sheet formation between strands 53 and 57 of symmetry-related molecules. Because such interactions are found also in a cardiotoxin and alpha-bungarotoxin, this could be of importance for interaction with acetylcholine receptor.     

Primary structure, biochemical and physiological aspects of hemoglobin from South American lungfish (Lepidosiren paradoxus, Dipnoi)

The South American Lungfish has only one hemoglobin component. The complete amino-acid sequence of this hemoglobin is presented. A large quantity of carbonate dehydratase from the lungfish erythrocytes was also isolated. The carboxymethylated chains, obtained by separation of globin on DEAE-Sephacel, were submitted to tryptic digestion and chemical cleavage. The isolation of tryptic peptides was achieved either by Dowex-50 chromatography or by high performance liquid chromatography. The alignment of peptides was performed by homology with the previously established sequences of the carp and goldfish hemoglobins. The overlapping peptides confirmed this sequence. The alpha chains have 143 residues, the beta chains 147. The relation between the primary structure and the physiological properties of lungfish hemoglobin are discussed.     

Characterization of a cytotoxin-like basic protein from the cobra (Naja naja naja) venom

A cytotoxin-like basic protein has been isolated from the venom of the nominate race of cobra (Naja naja naja from Pakistan) by a single step of high-performance liquid chromatography. The primary structure was determined and consists of 62 amino acid residues in a single polypeptide chain. It is highly similar to that of the cytotoxin-like basic proteins isolated from other Naja species, but differs in two of the SS-loop structures from that of cytotoxins.