Studies on erythrocruorin. IV. Circular dichroism of earthworm erythrocruorin.

Circular dichroism spectra of Lumbricus erythrocruorin in the absence and in the presence of heme ligands have been analyzed under a variety of experimental conditions in view of the peculiarities in ligand binding displayed by this high molecular weight heme protein (M_r = 3 × 10⁶).The undisaociated molecule exists in a “metastable” form with high cooperativity in oxygen binding, which can be converted into a stable form with low co-operativity either by changes in pH or temperature; circular dichroism spectra of oxyerythrocruorin in the Soret region give direct evidence of a local alteration in the heme environment under the conditions which affect co-operativity in oxygen binding of the undissociated molecule. Similar, although more pronounced changes in the same spectral region are observed in the dissociated molecule of M_r = 270,000, which displays low co-operativity in oxygen binding.Deoxygenation is accompanied by an inversion in the double Soret-Cotton effect, which indicates a substantial rearrangement in the heme environment upon removal of the ligand.The double peak in the Soret region found in all erythrocruorin derivatives can be taken as an indication of a distinctive distribution of the aromatic side-chains interacting with the heme chromophore.     

Studies on erythrocruorin. VII. Reconstitution of earthworm erythrocruorin from the apoprotein.

Apoerythrocruorin prepared from the giant respiratory hemoprotein of the earthworm (60 S, Mr = 3 X 10(-6)) is an electrophoretically homogeneous molecule which sediments as a single peak of low molecular weight (3.5 S) and has a lower alpha-helical content (approx. 30%) than the native protein. Titration of globin with ferric heme indicates the presence of different binding sites; however, after purification by ion exchange chromatography, the reconstitution product contains 1 haem/23 000 g of protein as the native molecule. Reconstituted ferric erythrocruorin is a low molecular weight hemichrome with the same optical and physicochemical properties of the hemichrome formed by natural ferric erythrocruorin. Reconstituted ferrous erythrocruorin reacquires the alpha-helical content and the quaternary structure of the native molecule. Reassociation into 10-S speices (1/12 of the whole molecules) is fast and easy, while that into whole molecules is slow and somewhat erratic. The functional properties of reconstituted ferrous erythrocruorin (oxygen affinity, cooperativity in oxygen binding, magnitude of Bohr effect) are very similar to those of the "stable" low cooperativity form of the undissociated protein.     

Assembly of erythrocruorin from the earthworm Octolasium complanatum

The spontaneous assembly of the earthworm erythrocruorin molecule (60 S) from its 1/12 subunits (10 S) obtained by alkaline dissociation is a long debated problem, since the 60 S to 10 S dissociation step has been regarded as essentially irreversible or as only partially reversible when freshly dissociated solutions are used. Erythrocruorin from the earthworm Octolasium complanatum has been reassembled from its 10 S subunits. "Age" of the subunits, pH, and divalent cation concentration are the factors that influence the assembly reaction. Of primary importance is the age of the subunits, i.e. their exposure time to the alkaline dissociating pH. Parallel sedimentation velocity and sodium dodecyl sulfate/polyacrylamide gel electrophoresis experiments on the dissociated and reassembled solutions indicate that two processes take place at alkaline pH values: disulfide exchange and limited proteolysis. These processes, whose relative importance differs in the various preparations, might be responsible for the loss of reassociating capacity of the 10 S subunits. With freshly dissociated subunits, reassembly up to 80% may be achieved at pH 6.2 to 6.5 in the absence of divalent cations; the presence of 25 to 50 mM-Ca2+ renders the reaction essentially pH-independent in the range 6.2 to 8. The effect of Ca2+ is discussed in the light of the presence of structure-stabilizing binding sites for divalent cations at the 10 S intersubunit's contact regions.     

Subunits of Limnodrilus erythrocruorin.

The dissociation of the erythrocruorin of the oligochaete $\text{Limnodrilus gotoi}$ was investigated using polyacrylamide gel electrophoresis at neutral pH. In the presence of 0.1% SDS, the erythrocruorin dissociated into five subunits possessing molecular weights of 13,000 (1), 20,000 (2), 23,000 (3), 25,000 (4) and 47,000 (5). In the presence of SDS and mercaptoethanol, the erythrocruorin dissociated into two subunits, whose molecular weights were 13,000 (I) and 28,000 (II). Subunit I accounts for 70–80% of the whole molecule. SDS electrophoresis of the isolated subunits 1 through 5 in the presence of mercaptoethanol showed that subunit I was derived from both subunits 1 and 5, while subunit II was derived from subunits 2–4. These results suggest that $\text{Limnodrilus}$ erythrocruorin consists of at least five polypeptide chains: two chains of 13,000 and three chains of 28,000.     

Studies on erythrocruorin. V. Nuclear magnetic resonance quadrupole relaxation study of sodium, calcium and chloride binding.

Metabolically labeled non-histone chromosomal proteins of high specific activity were fractionated on the basis of their sequential extractability from Krebs II chromatin with urea/salt solutions according to Bekhor et al. (1974a). The binding of each of these NHCP² classes to protein-free DNA and histone-DNA complexes (nucleohistone) was measured and compared to the binding to DNA substituted with 5-bromo-2′-deoxyuridine. After reconstitution of the interacting components, the binding of NHCP and histones was measured according to Scatchard formalism by titration of fixed amounts of DNA with increasing inputs of protein ligands under stringent conditions of 0.25 ionic strength, pH 8.0. Histone binding to either native DNA or BrUrd-substituted DNA was found to be essentially the same. In the presence of histones, the binding for all NHCP classes, except for medium 3 NHCP, was enhanced by an order of magnitude over the binding values for NHCP to DNA in the absence of histones. The binding of NHCP to DNA was thus strongly influenced by histones bound to DNA. A general and significant decrease in histone content in the complexes relative to increased NHCP binding was also apparent, with medium 3 NHCP having the greatest activity to weaken histone interaction with DNA and medium 0 the least. Enhancement in NHCP binding to BrUd-substituted DNA in the presence of histones was decreased to about 50% of the binding to control DNA. The distribution and quantity of DNA binding and non-DNA binding NHCP was also estimated by photochemical attachment to 33% BrUrd-substituted DNA in tryptophan-labeled chromatin and by direct binding assays. We have obtained 30% crosslinking for either histones or NHCP to DNA in stringently formed complexes. In histone-NHCP-DNA complexes, histone crosslinking remained unchanged, while that of NHCP increased to 70%. This is further evidence for a modification in the binding of NHCP to DNA in the presence of histones. The percentage of NHCP crosslinked to DNA in native chromatin ranged from 24% for medium 0 NHCP to 50% for medium 1 and 3 NHCP with an average of 35% for total NHCP. These results plus the direct binding assays indicate that NHCP, in addition to high affinity DNA binding, also interacts non-specifically to DNA and to proteins in chromatin. A mechanism is also being proposed to account for the observed BrUrd effects in chromatin.     

Physicochemical properties of Planorbis corneus erythrocruorin.

The erythrocruorin from the snail Planorbis corneus had a sedimentation coefficient, so/20,w, of 33.5 +/- 0.31 S, and a molecular weight of 1.65 x 10(6) +/- 0.04 x 10(6) by high-speed sedimentation-equilibrium ultracentrifugation. The amino acid composition and absorption spectrum of the protein are reported. A very low number of half-cystine residues was found, corresponding to 0.4 residue per haem group. The haem content was 2.76 +/- 0.22%, corresponding to a protein molecular weight of about 22300. Under both acid and alkaline conditions partial dissociation took place to yield mixtures of products that could not be identified. A subunit corresponding to that containing one haem group was not obtained under any of the dossociating conditions tried. Electron microscopy revealed a ring-shaped molecule about 12.2 +/- 0.5 nm in diameter. The native erythrocruorin bound O2 co-operatively, the intermediate value of h in Hill plots having values between 1.7 and 3.4 depending on the conditions.     

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.