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

Glutaraldehyde cross-linking increases the stability of Lumbricus terrestris erythrocruorin

Since donated red blood cells must be constantly refrigerated, they are not available in remote areas and battlefields. We have previously shown that the hemoglobin of the earthworm Lumbricus terrestris (LtEc) is an effective and safe substitute for donated blood that is stable enough to be stored for long periods at the relatively high temperatures that may be encountered in remote areas. The goal of this study was to further increase the thermal stability of LtEc by covalently cross-linking LtEc with glutaraldehyde (gLtEc). Our results show that the melting temperatures of the gLtEc samples steadily increase as the molar ratio of glutaraldehyde to heme increases (from T_m  = 57°C for native LtEc up to T_m  = 68°C at a ratio of 128:1). In addition, while native LtEc is susceptible to subunit dissociation at alkaline pH (8-10), cross-linking with glutaraldehyde completely prevents dissociation of gLtEc at pH 10. Increasing the molar ratio of glutaraldehyde:heme also significantly increased the oxygen affinity of gLtEc, but this effect was decreased by cross-linking gLtEc in the deoxygenated T state. Finally, while gLtEc samples cross-linked at low G:H ratios (e.g., 2:1) exhibited slight increases in oxidation rate in Tris buffer, no significant difference in oxidation rate was observed between native LtEc and the gLtEc samples in Ringer's Solution, which contains antioxidants. Overall, cross-linking LtEc with glutaraldehyde significantly increases its thermal and structural stability without any loss of function, making gLtEc an attractive blood substitute for deployment in remote areas and battlefields. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 34:521-528, 2018.

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.

Subunit distribution of calcium-binding sites in Lumbricus terrestris hemoglobin

The giant, approximately 3.6-MDa hexagonal bilayer hemoglobin (Hb) of Lumbricus terrestris consist of twelve 213-kDa globin subassemblies, each comprised of three disulfide-bonded trimers and three monomer globin chains, tethered to a central scaffolding of 36-42 linkers L1-L4 (24-32 kDa). It is known to contain 50-80 Ca and 2-4 Cu and Zn; the latter are thought to be responsible for the superoxide dismutase activity of the Hb. Total reflection X-ray fluorescence spectrometry was used to determine the Ca, Cu, and Zn contents of the Hb dissociated at pH approximately 2.2, the globin dodecamer subassembly, and linker subunits L2 and L4. Although the dissociated Hb retained 20 Ca2+ and all the Cu and Zn, the globin subassembly had 0.4 to approximately 3 Ca2+, depending on the method of isolation, and only traces of Cu and Zn. The linkers L2 and L4, isolated by reversed-phase high-pressure liquid chromatography at pH approximately 2.2, had 1 Ca per mole and very little Cu and Zn. Electrospray ionization mass spectrometry of linker L3 at pH approximately 2.2 and at neutral pH demonstrated avid binding of 1 Ca2+ and additional weaker binding of 7 Ca2+ in the presence of added Ca2+. Based on these and previous results which document the heterogeneous nature of the Ca2+-binding sites in Lumbricus Hb, we propose three classes of Ca2+-binding sites with affinities increasing in the following order: (i) a large number of sites (>100) with affinities lower than EDTA associated with linker L3 and dodecamer subassembly, (ii) approximately 30 sites with affinities higher than EDTA occurring within the cysteine-rich domains of linker L3 and dodecamer subassembly, and (iii) approximately 25 very high affinity sites associated with the linker subunits L1, L2, and L4. It is likely that the low-affinity type (i) sites are the ones involved in the effects of 1-100 mM Group IIA cations on Lumbricus Hb structure and function, namely increased stability of its quaternary structure and increased affinity and cooperativity of its oxygen binding.

Oxygen binding properties of Eudistylia vancouverii chlorocruorin and its dodecamer subunit

The oxygen equilibrium curves of the extracellular chlorocruorin of the polychaete Eudistylia vancouverii and its dodecamer subunit were determined over the pH range from 7.1 to 8.1 and in the presence and absence of 100 mM Mg2+. Although the chlorocruorin has a very low oxygen affinity, high cooperativity and a moderate alkaline Bohr effect (P50 = 145 mmHg, nmax = 6.9, phi = -0.44 at pH 7.1 and 25 degrees C), the dodecamer subunit has higher affinity and lower cooperativity and Bohr coefficient (P50 = 58 mmHg, nmax = 1.7, phi = -0.22). The presence of 100 mM Mg2+ increased the oxygen affinity and cooperativity of the chlorocruorin but had no significant effect on the dodecamer subunit. The oxygen binding properties of the chlorocruorin reassociated subsequent to complete dissociation in 4 M urea at neutral pH were similar to the properties of the dodecamer and not to those of the native chlorocruorin. Fitting to the Monod-Wyman-Changeux allosteric model gave KT of 0.0013 mmHg-1, Kr of 0.22 mmHg-1 and L(o) of 2.5 x 10(13) together with a size of the allosteric unit, N = 9.

Hierarchy of globin complexes. The quaternary structure of the extracellular chlorocruorin of Eudistylia vancouverii

The molecular dimensions of the extracellular, hexagonal bilayer chlorocruorin of the polychaete Eudistylia vancouverii, determined by scanning transmission electron microscopy (STEM) of negatively stained specimens, were diameter of 27.5 nm and height of 18.5 nm. STEM mass measurements of unstained, freeze-dried specimens provided a molecular mass (Mm) of 3480 +/- 225 kDa. The chlorocruorin had no carbohydrate and its iron content was 0.251 +/- 0.021 wt%, corresponding to a minimum Mm of 22.4 kDa. Mass spectra and nuclear magnetic resonance spectra of the prosthetic group confirmed it to be protoheme IX with a formyl group at position 3. SDS/polyacrylamide gel electrophoresis, reversed-phase chromatography and N-terminal sequencing suggested that the chlorocruorin consists of at least three chains of approximately 30 kDa and five chains of approximately 16 kDa; the two types of subunits occur in the ratio 0.26:0.74(+/- 0.08). Complete dissociation of the chlorocruorin at neutral pH in the presence of urea or guanidine hydrochloride, followed by gel filtration, produced elution profiles consisting of three peaks, B, C and D. Fractions B and C consisted of the approximately 16 kDa chains and fraction D consisted of the approximately 30 kDa subunits. Mass measurements of particles in STEM images of unstained, freeze-dried fractions B and C provided Mm of 208 +/- 23 kDa and 65 +/- 12 kDa, respectively, in agreement with 191 +/- 13 kDa and 67 +/- 5 kDa obtained by gel filtration. Particles with Mm = 221 +/- 21 kDa were also observed in STEM images of unstained, freeze-dried chlorocruorin. These results imply that the chlorocruorin structure, in addition to the approximately 30 kDa linker subunits that have 0.26 to 0.47 heme groups/chain, comprises approximately 65 kDa tetramers and approximately 200 kDa dodecamers (trimers of tetramers) of globin chains. The stoichiometry of the tetramer and linker subunits calculated from molar amino acid compositions was 34 +/- 4 and 43 +/- 9. The complete dissociation of the chlorocruorin was accompanied by a 50 to 75% loss of the 55 +/- 14 Ca2+/mol protein, and was decreased to approximately 35% by the presence of 10 to 25 mM-Ca2+. Reassociation of dissociated chlorocruorin was maximal in the presence of 2.5 to 5 mM-Ca2+. The dodecamer and/or tetramer subunits in the absence or presence of Ca2+ exhibited very limited (less than 10%) reassociation into hexagonal bilayer structures, only in the presence of the linker subunit.(ABSTRACT TRUNCATED AT 400 WORDS)

The calcium, copper and zinc content of some annelid extracellular haemoglobins

The extracellular haemoglobins of Lumbricus and Tylorrhynchus contain 50 and 61 tightly bound calcium atoms per molecule, respectively. In addition, they contain one to four tightly bound copper and zinc atoms. Although the role of the latter is unknown, that of calcium is probably structural, assisting in the maintenance of the native hexagonal bilayer structure.

The effect of alkaline earth cations and of ionic strength on the dissociation of earthworm hemoglobin at alkaline pH

1. The effect of alkaline earth cations on the dissociation of the extracellular hemoglobin of Lumbricus terrestris and the effect of ionic strength on the dissociation of the hemoglobins of L. terrestris and Tubifex tubifex at concentrations of ca 2.5 mg/ml, over the pH range 9.0-10.5 was investigated using ultracentrifugation to separate the dissociated from the undissociated molecules. 2. Mg(II), Ca(II) and Sr(II) at concentrations of up to 0.2 M, decreased the dissociation of Lumbricus oxyhemoglobin from 70% at pH 9.0 and 100% at pH 9.5 and higher, to 20-30% at 0.05 M. The three cations were equally effective in decreasing the extent of dissociation of L. terrestris oxyhemoglobin over the pH range 9.0-10.5, with a K1/2 of ca 10 mM. 3. The dissociation of L. terrestris oxyhemoglobin over the pH range 9.0-10.5 was decreased only to 50-60% in the presence of up to 0.5 M NaCl or KCl; there was no further decrease in dissociation at concentrations of the two salts up to 1.5 M. 4. The dissociation of T. tubifex oxyhemoglobin over the pH range 9.0-10.0 was decreased from 100% to ca 40-50% in the presence of 0.5 M NaCl or KCl with little or no change at higher concentrations. At pH 10.5 and 11.0 the decrease in dissociation was more gradual, reaching ca 50% at 1.5 M NaCl.

Oxygen binding to Octolasium complanatum erythrocruorin. Modulation of homo- and heterotropic interactions by cations

The functional properties of erythrocruorin from Octolasium complanatum (a common earthworm of Central Italy) have been characterized in great detail. Special attention has been given to the reciprocal effects of the various ligands, namely oxygen, cations and protons. The data obtained under a variety of experimental conditions bring out the dominant role played by cations in the modulation of both homotropic and heterotropic interactions. In this respect, the most interesting observation concerns the unusual interplay between protons and cations that occurs in this erythrocruorin, the first respiratory pigment in which the Bohr effect is due totally to the O2-linked binding of an allosteric effector. The oxygen binding data collected under the various experimental conditions have been analyzed in terms of a modified two-state model, which takes into account the fact that allosteric effectors may also influence the ligand binding properties of the state that they stabilize. The analysis shows that the number of interacting sites necessary for the observed co-operativity in O2 binding is much smaller than the number of heme groups carried by the whole molecule, in accordance with previous findings on hemocyanins, the other class of giant respiratory pigments. Moreover, the analysis indicates that the dimensions of these "functional constellations" are under the control of allosteric effectors.

The dissociation of the extracellular hemoglobin of Tubifex tubifex at extremes of pH and its reassociation upon return to neutrality

The dissociation of the extracellular hemoglobin of Tubifex tubifex at alkaline and acid pH, and its reassociation upon return to neutral pH, was investigated using gel filtration, ultracentrifugation, and polyacrylamide gel electrophoresis in sodium dodecyl sulfate (SDS-PAGE). Tubifex hemoglobin dissociated at pH above 8 and below 6; both dissociations appeared to be equilibrium processes. The extent of dissociation increased as the pH moved away from neutrality; although dissociation was virtually complete at pH 11, its extent at acid pH did not exceed 50-60% at pH 4. Ca(II), Mg(II), and Sr(II) cations over the range 1-100 mM decreased the extent of the dissociation only at alkaline pH. The visible absorption spectrum of the oxyhemoglobin remained unaltered in the pH range 4-9. At more extreme pH, it changed with time, altering irreversibly to that of the aquo ferri form. Gel filtration of the hemoglobin at both extremes of pH showed that it dissociated into two heme-containing fragments; one consisting of subunit 1 (Mr approximately 17,000) and the other containing subunits 2, 3, and 4 of the hemoglobin (Mr approximately 60,000). Upon return to neutral pH, the dissociated fragment reassociated to the extent of 50 to 80% to whole hemoglobin molecules. The reassociation decreased with increase in alkaline pH, and with decrease in acid pH to which the hemoglobin had been exposed; it increased in the presence of Ca(II), Sr(II), and Mg(II) only subsequent to dissociation at alkaline pH. The SDS-PAGE patterns, gel-filtration elution volumes, and alpha-helical contents, determined from circular dichroism at 222 nm, of the reassociated whole molecules were identical to those of the native hemoglobin.

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.

Dissociation and oxygen equilibrium properties of earthworm (Pheretima hilgendorfi) hemoglobin

The dissociation and oxygen equilibrium properties of the purified hemoglobin and whole blood obtained from the earthworm Pheretima hilgendorfi were compared. Above pH 8.0, P1/2's were higher in the purified hemoglobin than in whole blood, while below pH 8.0, nearly identical P1/2's were observed in both materials and P1/2 was at a maximum at pH 6.5. The values of n1/2 were higher in whole blood than in the purified hemoglobin at alkaline pH. The maximum values of n1/2 were observed around pH 8.1 in the purified hemoglobin and pH 8.7 in whole blood, and the values were 5.3 and 9.5, respectively. In the purified hemoglobin, a small amount of dissociation component was already observed at pH 8.0, while in whole blood, no dissociation occurred up to pH 9.1. Dialysis of whole blood or addition of 10 mM EDTA to whole blood at alkaline pH induced the loss of the enhanced cooperativity, the increased oxygen affinity and the high stability of the 60 S whole molecule. These results strongly suggest that divalent cations are participating in the functional and dissociation properties of the whole blood of this species.

X-ray fluorescence spectrometric determination of the metal content of the extracellular hemoglobin of Tubifex tubifex

X-ray fluorescence spectrometric analysis of Tubifex hemoglobin, using the energy-dispersive and wavelength-dispersive spectrometers, demonstrated that in addition to Fe, Ca and small amounts of Zn, Cu and Pb were also present. Assuming that Tubifex hemoglobin contains 160 atoms of Fe per molecular weight of 3.9 10(6), the molar ratios of Fe:Ca:Zn:Cu:Pb were calculated to be 160:70:2:8: 2. The iron content of the hemoglobin was also determined spectrophotometrically using the formation of Fe(II)-1,10-phenanthroline and Fe(II)-4-(2-pyridylazo)-resorcinol complexes: it was found to be 0.240+/-0.010% by weight and was unaffected by prior dialysis against 10 mM EDTA solution at neutral pH. Thus, it is unlikely that Tubifex hemoglobin contains any non-heme iron.

The physico-chemical and functional properties of Abarenicola affinis affinis (Ashworth) extracellular haemoglobin (erythrocruorin)

The purified erythrocruorin from the Arenicolid polychaete, Abarenicola affinis affinis (Ashworth) has an S020,w of 57.5 S, and a molecular weight of 3.29 . 10(6) as determined by sedimentation equilibrium at pH 7.0. In the electron microscope it displays a two-tiered hexagonal array characteristic of other annelid erythrocruorins and chlorocruorins, with dimensions of approximately 25.5 nm diameter and 17.0 nm height. The isoelectric point of the molecule is at pH 4.63, and its amino acid composition and absorption spectrum are similar to those of other annelid erythrocruorins. The haem and iron contents are 2.77% and 0.23%, corresponding to minimum molecular weights of 22 250 and 24 800, respectively. In pH-induced dissociation studies, the erythrocruorin is found to be stabilized by Ca2+ up to pH 8.6, while in the presence of EDTA, dissociation begins at pH 7.8. In discontinuous gel electrophoresis, dissociated erythrocruorin gives subunits with molecular weights 263 000, 117 500, 68 400, 35 900 and 28 800, while, in detergent electrophoresis in the presence of 2-mercaptoethanol, polypeptide chains with molecular weights 13 700, 15 800, 24 700, 27 800 and 33 600 are obtained. Abarenicola erythrocruorin is also shown to bind oxygen cooperatively with a Hill coefficient h = 4.0 and P50 = 6.0 mmHg at pH 7.0 and 25 degrees C. Over the pH range of 7.0 to 7.8 the molecule lacks an alkaline Bohr effect.

Physicochemical and functional properties of Perinereis cultrifera (Grübe) erythrocruorin

Perinereis erythrocruorin has the following physicochemical properties: So20,w = 55S, corresponding to a molecular weight around 2.7-10(6); minimum molecular weight (on the basis of the heme content) 23 700 +/- 500; isoelectric point 5.1; alpha-helix content approximately 40%. At alkaline pH values in the oxygenated form the 55-S molecules dissociate into subunits with a weight average sedimentation coefficient of 3S, corresponding to a molecular weight approximately 35 000. Deoxygenation of partially dissociated samples promotes association of the 3-S subunits into a 9S component. The functional properties of Perinereis erythrocruorin are characterized by a low cooperativity in oxygen binding (n 1/2 = 1.5) at neutral pH. Cooperativity increases reversibly towards both the acid and alkaline pH range, irrespective of changes in molecular weight. This finding, taken together with the ultracentrifuge results, suggests that a subunit may represent the functional unit of the protein. The pH dependence of the oxygen affinity can be accounted for in terms of a single oxygen linked group with a pK of 8.