Ligand-dependent Bohr effect of Chrionomus hemoglobins.
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The O2 and CO Bohr effects of monomeric and dimeric hemoglobins of the insect Chironomus thummi thummi were determined as proton releases upon ligation. For the O2 Bohr effect of the monomeric hemoglobin III a maximum value of 0.20 H+/heme was obtained at pH 7.5. Upon ligation with CO, however, only 0.04 H+/heme were released at the same pH. In agreement with this finding isoelectric focusing experiments revealed different isoelectric points for O2-liganded and CO-liganded states of hemoglobin III. Analogous results were obtained in the cases of the monomeric hemoglobin IV and the dimeric hemoglobins of Chironomus thummi thummi; here O2 Bohr effects of 0.43 and 0.86 H+/heme were observed. For the corresponding CO Bohr effects values of 0.08 and 0.31 H+/heme were obtained respectively. On the basis of the available structural data the reduced CO Bohr effect in hemoglobin III is discussed as arising from a steric hindrance of the CO ligand by the side chain of isoleucine-E11, obstructing the movement of the heme-iron upon reaction with carbon monoxide. It should, however, be noted that ligands, according to their different electron donor and acceptor properties, may generally induce different conformational changes and thus different Bohr effects, in those hemoglobins in which distinct tertiary and/or quaternary constraints have not evolved. The general utilization of CO instead of O2 as allosteric effector is ruled out by the results reported here. (+info)
Mass distributions of a macromolecular assembly based on electrospray ionization mass spectrometric masses of the constituent subunits.
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Macromolecular assemblies containing multiple protein subunits and having masses in the megadalton (MDa) range are involved in most of the functions of a living cell. Because of variation in the number and masses of subunits, macromolecular assemblies do not have a unique mass, but rather a mass distribution. The giant extracellular erythrocruorins (Ers), approximately 3.5 MDa, comprised of at least 180 polypeptide chains, are one of the best characterized assemblies. Three-dimensional reconstructions from cryoelectron microscopic images show them to be hexagonal bilayer complexes of 12 subassemblies, each comprised of 12 globin chains, anchored to a subassembly of 36 nonglobin linker chains. We have calculated the most probable mass distributions for Lumbricus and Riftia assemblies and their globin and linker subassemblies, based on the Lumbricus Er stoichiometry and using accurate subunit masses obtained by electrospray ionization mass spectrometry. The expected masses of Lumbricus and Riftia Ers are 3.517 MDa and 3.284 MDa, respectively, with a possible variation of approximately 9% due to the breadth of the mass distributions. The Lumbricus Er mass is in astonishingly good agreement with the mean of 23 known masses, 3.524 +/- 0.481 MDa. (+info)
Low resolution crystal structure of Arenicola erythrocruorin: influence of coiled coils on the architecture of a megadalton respiratory protein.
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Annelid erythrocruorins are extracellular respiratory complexes assembled from 180 subunits into hexagonal bilayers. Cryo-electron microscopic experiments have identified two different architectural classes. In one, designated type I, the vertices of the two hexagonal layers are partially staggered, with one hexagonal layer rotated by about 16 degrees relative to the other layer, whereas in the other class, termed type II, the vertices are essentially eclipsed. We report here the first crystal structure of a type II erythrocruorin, that from Arenicola marina, at 6.2 A resolution. The structure reveals the presence of long continuous triple-stranded coiled-coil "spokes" projecting towards the molecular center from each one-twelfth unit; interdigitation of these spokes provides the only contacts between the two hexagonal layers of the complex. This arrangement contrasts with that of a type I erythrocruorin from Lumbricus terrestris in which the spokes are broken into two triple-stranded coiled coils with a disjointed connection. The disjointed connection allows formation of a more compact structure in the type I architecture, with the two hexagonal layers closer together and additional extensive contacts between the layers. Comparison of sequences of the coiled-coil regions of various linker subunits shows that the linker subunits from type II erythrocruorins possess continuous heptad repeats, whereas a sequence gap places these repeats out of register in the type I linker subunits, consistent with a disjointed coiled-coil arrangement. (+info)
Crystallization and preliminary structural analysis of the giant haemoglobin from Glossoscolex paulistus at 3.2 A.
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Quaternary structure of erythrocruorin from the nematode Ascaris suum. Evidence for unsaturated haem-binding sites.
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The quaternary structure of erythrocruorin from the nematode Ascaris suum was studied. The native protein had a sedimentation coefficient, at a protein concentration of 1 mg/ml, of 11.6 +/- 0.3 S and an Mr, as determined by sedimentation equilibrium, of 332,000 +/- 17,000. SDS/polyacrylamide-gel electrophoresis gave one band with a mobility corresponding to an Mr of 43,000 +/- 2000. The Mr of the polypeptide chain was determined to be 41,600 +/- 1,500 by sedimentation equilibrium in 6 M-guanidinium chloride and 0.1 M-2-mercaptoethanol. Cross-linking with glutaraldehyde followed by SDS/polyacrylamide-gel electrophoresis yielded a maximal number of eight bands. The haem content of Ascaris erythrocruorin was observed to vary from one preparation to another. This finding was shown to be due to non-realization of the full binding capacity for haem. By titration with haemin, the haem content was found to attain a maximal value of 2.86 +/- 0.14%, corresponding to a minimal Mr per haem group of 21,000 +/- 1,000. Our findings indicate that Ascaris suum erythrocruorin is composed of eight identical polypeptide chains, carrying two haem sites each. (+info)
Molecular symmetry of Lumbricus erythrocruorin.
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X-ray diffraction data to a minimum Bragg spacing of 5.5 A have been collected from crystals of Lumbricus terrestris erthrocruorin, a 3.9 x 10(6)-dalton respiratory protein. Self-rotation function calculations from these data reveal D6 symmetry to a resolution of at least 6 A. These calculations show that erythrocruorin molecules pack in their crystals with molecular diads coincident with crystallographic diads along the a axis. Packing constraints limit the position of the molecular center to within 40 A of x = 1/4a. (+info)
Principles in the assembly of annelid erythrocruorins.
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Erythrocruorins are giant extracellular respiratory proteins found freely dissolved in the blood of annelids. We present here results from our ultracentrifugation, electron microscopy, spectroscopy, and diffraction experiments on these erythrocruorins. These data are rationalized in terms of a three-dimensional model of the quaternary structure. The proposed structure is arranged in a hierarchy of symmetry. The implications of this structure for the assembly process are considered with special attention to uniqueness and self-limitation. The hypothesis is consistent with observations not used in its construction and it serves as a working hypothesis to focus further experimentation. (+info)
The amino acid sequence of a major polypeptide chain of earthworm hemoglobin.
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The amino acid sequence has been determined for polypeptide chain AIII of the major component of the hemoglobin (erythrocruorin) from the earthworm, Lumbricus terrestris. The chain has 157 residues and a molecular weight of 17,496. Although the extent of sequence identity with other globin chains is only 17-18%, analysis of the sequence leads to the conclusion that the secondary structure of the chain is very similar to those of vertebrate globins and that about 60-70% of the amino acid residues are in alpha helices. The D helix appears to be missing, as it is from the alpha chain of human hemoglobin and from the monomeric hemoglobin of Glycera dibranchiata, another annelid worm. This is the first sequence obtained from one of the "giant" extracellular hemoglobins of invertebrate animals. (+info)