Structure, function, and assembly in the hemocyanin system of the scorpion, Androctonus australis

Arachnid Hemocyanins

Hemocyanin (Hc), a copper-containing extracellular multimeric protein, is the major protein component of hemolymph in different arachnid groups. Hc possesses 7 or 8 very well-characterized types of monomers with molecular weights ranging from 70 to 85 kDa, organized in hexamers or multiple of hexamers. The present chapter compiles the existing data with relation to the function of this protein in the arachnids. Hc has as main function the reversible transport of O₂, but it shows many secondary though not less important functions. With reference to this, it has been described that Hc can transport hydrophobic molecules (lipid-derived hormones and lipids) to the different organs, having a key role in the lipid transport system. In arachnids, like in other arthropods and invertebrates, Hc has phenoloxidase function which is related to different metabolic processes such as melanin formation and defense against pathogens. In addition, Hc has additional defensive functions since it can serve as precursor for the production of antimicrobial peptides. In short, the evolution of this protein has led to the development of multiple functions essential for organisms possessing this protein.

Regulation of air and blood flow through the booklungs of the desert scorpion, Paruroctonus mesaensis

Injections of dye, latex and India ink were used to reveal the path of hemolymph circulation through the scorpion booklungs. Fine, branched arteries carry blood directly to muscle and other organs. The blood returns through venous channels to the ventral mesosoma where it passes laterally through the booklungs and into the pneumocardial veins just beneath the pleural cuticle. Blood flows dorsally through these veins to the pericardial sinus and heart. The scorpion has four pairs of booklungs located in the anterior segments of the ventral mesosoma. Each booklung has a spiracle which opens into an atrium enclosed by cuticular membrane. Air passes from the atrium into the booklung lamellae. Agitation of the animal or application of CO(2) causes retraction of the anterior and posterior atrial membrane. This expands the atrial chamber and allows gas exchange in the booklung lamellae. The posterior atrial membrane has a specialized region which forms a springy valve. This normally closes the spiracle unless pulled open by contraction of the attached poststigmaticus muscle. The pectens and receptors within the atrium may mediate the responses to CO(2). Slender hypocardial ligaments containing muscle fibers extend from the heart (dorsal mesosoma) to the booklungs in the ventral mesosoma. Heart movements thus cause dorso-ventral movement of the booklungs. The significance of these movements is as yet unclear. They may increase ventilation, help force blood to the heart and/or agitate the blood and booklung lamellae and thereby aid gas exchange. Passage of blood through the booklungs is regulated by dorsal and ventral muscles attached to the atrium at the lateral edge of the booklung. Contraction of the ventral atrial muscle closes the excurrent channel for passage of blood from the booklung into the pneumocardial vein. Electrical stimulation of the segmentai nerves from the subesophageal and first three abdominal ganglia causes spiracle opening and contraction of muscles attached to the atrial membrane. A previous study showed that these same segmental nerves also modulate heart activity. They thus provide a major pathway for regulation of the respiratory and circulatory systems.

Allostery in very large molecular assemblies

In contrast to small allosteric systems (like hemoglobin) those containing very large numbers (n) of binding sites never exhibit cooperativity (as measured by the Hill coefficient, nH) even approaching the potential limit, n. The reason for this appears to be that in such macromolecules the cooperative unit always represents some sub-structure of the entire structure. On the other hand, it is frequently observed that such sub-structures, when isolated, do not exhibit cooperativity at all. This paper describes studies of some molluscan hemocyanins that explore this apparent anomaly. It is concluded that it is the higher order structure of the molecule that provides a framework within which the sub-structures may exhibit their allosteric behavior.

Oxygen transport proteins: III. Structural studies of the scorpion (Buthus sindicus) hemocyanin, partial primary structure of its subunit Bsin1

The hemocyanin (Hc) from Buthus sindicus, studied in the native state, demonstrated to be an aggregate of eight different types of subunits arranged in four cubic hexamers. Both, the 'top' and the 'side' views of the native molecule have been identified from the negatively stained specimens using transmission electron microscopy. Out of these, eight different polypeptide chains, the partial primary structure (68%) of a subunit Bsin1 (Mr = 72422.7 Da) was established using a combination of automated Edman degradation and mass spectrometry. A multiple sequence alignment with other closely related cheliceratan Hc subunits revealed average identities of ca. 60%. Most of the structurally important residues, i.e. copper and calcium-binding ligands, as well as the residues involved in the presumed oxygen entrance pathway, proved to be strictly conserved in Bsin1. Sequence variations have been observed around the functionally important chloride-binding site, not only for the B. sindicus subunit Bsin1, but also for the subunit Aaus-6 of the scorpion A. australis and the subunit Ecal-a from the spider Eurypelma californicum Hcs. Deviation in the primary structure related to the chloride-binding site suggest that the effect of chloride ions may vary in different hemocyanins. Furthermore, the secondary structural contents of the Hc subunit Bsin1 were determined by circular dichroism revealing ca. 33% alpha-helix, 18%, beta-sheet, 19% beta-turn, and 30% random coil composition. These values are in good agreement with the crystal structure of the closely related Hc subunit Lpol-II from horseshoe crab L. polyphemus. Electron microscopic studies of the purified Hc subunit under native conditions revealed that Bsin1 has self aggregation properties. Results of these studies are discussed.

Low-resolution molecular structures of isolated functional units from arthropodan and molluscan hemocyanin

Synchrotron x-ray scattering measurements were performed on dilute solutions of the purified hemocyanin subunit (Bsin1) from scorpion (Buthus sindicus) and the N-terminal functional unit (Rta) from a marine snail (Rapana thomasiana). The model-independent approach based on spherical harmonics was applied to calculate the molecular envelopes directly from the scattering profiles. Their molecular shapes in solution could be restored at 2-nm resolution. We show that these units represent stable, globular building blocks of the two hemocyanin families and emphasize their conformational differences on a subunit level. Because no crystallographic or electron microscopy data are available for isolated functional units, this study provides for the first time structural information for isolated, monomeric functional subunits from both hemocyanin families. This has been made possible through the use of low protein concentrations (< or = 1 mg/ml). The observed structural differences may offer advantages in building very different overall molecular architectures of hemocyanin by the two phyla.

Identification of two antibody-interaction sites on the surface of Panulirus interruptus hemocyanin

Negatively stained complexes of Panulirus interruptus (spiny lobster) hemocyanin with two different monoclonal antibodies, named E and J, were studied by electron microscopy and image processing. The attachment site of the antibodies to the hexameric hemocyanin molecule was deduced from two perpendicular views of hemocyanin/antibody complexes, in which either the threefold axis or one of the twofold axes was oriented perpendicular to the supporting film. Images of complexes in these orientations were searched with reference images simulated from the known X-ray structure of P. interruptus hemocyanin. The two sites were further characterized by combining our results from electron microscopy with structural data obtained by X-ray diffraction and other methods. These two antibodies recognize different non-overlapping epitopes. The epitope for clone E is located on domain 3 at the surface of the beta barrel and consists of certain loops, which form connections between beta-strand structures. The epitope for clone J is situated on domain 1 at the surface of an alpha-helical region and consists mainly of certain alpha-helices connecting loops. The orientation of the hemocyanin hexamers in the two complexes is very different, as is demonstrated most clearly when they form chains. Clone E forms complexes with the threefold axes perpendicular to the chain direction, while for clone J the threefold axes seem to be parallel to the main direction. The angle between the Fab part of an IgG molecule and the threefold axis of the hexamer is 60 +/- 5 degrees for clone E and 35 +/- 7 degrees for clone J. This observation is clearly related to the difference in orientation of the hexamers for the two complexes.

Role of oligomeric interactions in the cooperativity of crayfish hemocyanin

To examine the effect of interactions between the hexameric units in the dodecameric hemocyanin, crayfish (Procambarus clarki) hemocyanin was partially dissociated. Gel-filtration yielded fractions containing the undissociated dodecamer and a mixture of the hexamer and heptamer (referred to as 'half-dodecamer'). Their O2 equilibria were compared and were analyzed by curve fitting of cooperativity models. The partial dissociation of the dodecamer significantly lowered the cooperativity but little affected the O2 affinities. The O2 equilibrium of the half-dodecamer could be described by the two-state allosteric model of Monod-Wyman-Changeux on the assumption that the cooperative unit is composed of six subunits. We tested the applicability of allosteric models for the dodecamer that deal with the interactions between the hexamers. To reduce the arbitrariness of the fitting, we presumed that some parameters are equal to the two-state model parameters for the half-dodecamer. It was found that the 'nesting model', which assumes allosteric equilibria at two different hierarchical levels, could be applied successfully to the dodecamer.

Three-dimensional reconstruction of native Androctonus australis hemocyanin

A sample of native 4 x 6-meric hemocyanin of Androctonus australis was negatively stained with the double-layer technique, and was observed by transmission electron microscopy under low-dose conditions with a 50 degree and 0 degree tilt. The three-dimensional reconstruction method from "Single-exposure, random conical tilt series" was then applied. Independent three-dimensional reconstructions were obtained from the top, side and 45 degree views. Despite a pronounced flattening effect, presumably due to the specimen preparation technique, the positions of the 24 subunits composing the oligomer were unequivocally determined. This experiment definitely solves the problem of the architectural organization of the subunits in the cheliceratan 4 x 6-meric hemocyanins. Moreover, distinction between the flip and flop faces and an attenuated rocking effect were observed.

Nested allostery in scorpion hemocyanin (Pandinus imperator)

The oxygen-binding behavior of the 24-meric hemocyanin of the scorpion Pandinus imperator and its dependence on allosteric effectors such as protons can be successfully described by the nesting model; the MWC model is not acceptable. The affinities of the four assumed conformations of the allosteric unit, the 12-meric half-molecule, are not dependent on pH whereas the three allosteric equilibrium constants decrease with decreasing proton concentration. Comparison with the oxygen-binding behavior of the 24-meric tarantula hemocyanin (Eurypelma californicum) reveals that the affinity values for the various conformations seem to be conserved for chelicerata hemocyanin.

Nested allostery of arthropodan hemocyanin (Eurypelma californicum and Homarus americanus). The role of protons

Continuous oxygen binding curves for two arthropodan hemocyanins were performed at different pH values ranging from 7.0 to 8.7 and in the presence of physiological concentrations of the bivalent ions Ca2+ and Mg2+. The arthropods Eurypelma californicum and Homarus americanus are classified as chelicerata and crustaceans, respectively. Their structurally well-characterized hemocyanins are composed of, in the case of E. californicum 24 subunits, and in the case of H. americanus 12 subunits. The role of protons as allosteric effectors of the oxygen binding was analysed in terms of the nesting model, which assumes hierarchies of allosteric equilibria that are based on obvious structural hierarchies. For each hemocyanin, the smallest structural repeating unit, the 12-mer or the 6-mer, respectively, was regarded as the "allosteric unit". Two allosteric units are allosterically coupled within the native molecules. The analysis revealed that in accordance with the postulations of the classical Monod-Wyman-Changeux model protons as allosteric effectors do not change the oxygen affinities of the four postulated conformations, but influence the allosteric equilibria between them at two different hierarchical levels. Model-independent determination of the affinity constants for the binding of the first and the last oxygen molecule to the native hemocyanins and to the isolated half-molecules confirmed the affinities calculated according to the nesting model. The stepwise establishment of new conformations during the assembly process from monomers to the structurally identical repeating unit and further on to the native molecule is shown. Possible physiological advantages of allosterically coupled allosteric units in contrast to allosterically uncoupled ones are thought to be (1) the option to regulate oxygen binding on different levels of structural hierarchy and (2) the increase of the oxygen-carrying capacity.

Heterogeneous binding of oxygen and carbon monoxide to dissociated molluscan hemocyanin

Functional heterogeneity in O2 or CO binding of sites of dissociated molluscan hemocyanin polypeptide chains (Helix pomatia and Octopus vulgaris) has been estimated by an analysis of accurate noncooperative binding curves. Three types of experiments were performed: pure O2 or CO binding, competitive displacement of one ligand by the other, and simultaneous removal of both gases from protein partially saturated with O2 and CO. The data were analyzed in terms of a model which has two fractions of sites with different properties for O2 and CO. The relative proportion of the different binding sites and their affinity constant values were found by the combined use of the three different procedures. All species show a marked functional heterogeneity of sites for O2 binding, while for CO binding it has been observed only in the case of H. pomatia beta-hemocyanin. Moreover, in all three molluscan hemocyanins examined, the two classes of O2-binding sites, although present in different proportions within the polypeptide chains, display similar affinity constant values. The data reported show a good consistency with results obtained using digested and isolated domains, providing confidence in the analytical procedure used. From comparison of the O2/CO affinity ratios (KO2, KCO) of each class it may be suggested that the difference in O2 affinity of two kinds of binding sites is related to a different local structure of the active sites. The results, moreover, unequivocally confirm that binding and displacement of two gaseous ligands to hemocyanin occur by a simple competitive mechanism, although the binding site is structurally complex and the two ligands are bound with different geometries.

Cell-free synthesis of hemocyanin from the scorpion Androctonus australis. Characterization of the translation products by monospecific antisera

Translation of Androctonus australis poly(A)-RNA in vitro led to a number of polypeptides products (8-10) of 70-73 kDa analyzed by two-dimensional gel electrophoresis and identified by immunoprecipitation with an anti-(dissociated hemocyanin) antiserum. The translated hemocyanin polypeptides have the same physico-chemical characteristics as authentic hemocyanin subunits. Subunits Aa 2 and Aa 4 have been identified with monospecific antisera characterized (a) by their capability of reacting with their homologous subunit and (b) by their inability of binding to cross-reacting subunits. Each polypeptide chain is coded by a different messenger without significant post-translational events. Hemocyanin could be detected among the translation products of the poly(A)-RNA isolated from the cuticle under the carapace.

Immunological correlates between multiple isolated subunits of Androctonus australis and Limulus polyphemus hemocyanins: an evolutionary approach

Immunological cross-reactivities between isolated subunits of the scorpion Androctonus australis (Aa) and of the horseshoe crab Limulus polyphemus (Lp) hemocyanins were studied using subunit-specific antibodies prepared through immunoadsorption to pure immobilized subunits. Rocket immunoelectrophoreses of the various subunits of both hemocyanins were carried out at constant antigen concentration against the various subunit-specific antibody preparations. Then the data were analyzed through factorial correspondence analysis and compared to the respective intramolecular locations of the subunits in both hemocyanins. The results show that the dimeric subunits located in the central part of each (4 X 6)meric structure (Aa whole molecule and Lp half molecule) were strongly preserved. In addition, the (8 X 6)mer-forming subunit of Lp hemocyanin (LpIV) and the subunit occupying the same intramolecular position in Aa hemocyanin (Aa5A) were also strongly preserved. Besides the strong antigenic relatedness, less pronounced crossed immunoprecipitations or no precipitation at all were observed between subunits with homologous positions suggesting a minor structural and/or functional roles for these subunits. All the antigen-antibody combinations leading to an absence of immunoprecipitation were screened for the presence of soluble immunocomplexes by radioimmunological tests. In all cases, soluble immunocomplexes were observed. These results suggest the following evolution scenario. First, the central dimeric subunits, responsible of the dodecamer aggregation (Aa3C and 5B and LpV and VI) were already differentiated when Merostomata diverged from Arachnida. Second, the differentiation of the (8 X 6)mer-forming subunit occurred in the Merostomata ramification in a preserved subunit already possessing a functional advantage. Third, the differentiation of subunits Aa3A and Aa3B recently occurred in the scorpion ramification.

Detection of antibody secreting hybridomas with diazobenzyloxymethyl paper: an easy, sensitive and versatile assay

A sensitive and universal assay for the detection of monoclonal antibodies is described. One microliter of each hybrid cell supernatant is transferred to activated diazobenzyloxymethyl paper and, after coating the uncovered activated sites by incubation with bovine serum albumin, the paper is dipped in a solution of 125I-labeled antigen. After incubation to allow for fixation of antigen to antibody present in the supernatants, the paper is rinsed and autoradiographed. As many as 96 wells can be tested on one paper and more than 20 papers can be treated in 1 day (approximately 2000 wells). The sensitivity and reliability of the method were tested with monoclonal antibodies against a subunit of scorpion (Androctonus australis) hemocyanin. Unlike other immunobinding assays the test depends only on antigen-antibody interaction and not on class or subclass of immunoglobulin. It is suitable for a variety of hybridomas.

A refined quaternary structure of Androctonus australis Hemocyanin

The quaternary structure of the (4 X 6)-mer hemocyanin from the Scorpion Androctonus australis previously published [Lamy, J., Bijlholt, M. M. C., Sizaret, P.-Y., Lamy, J., and van Bruggen, E. F. J. (1981) Biochemistry, 20, 1849-1856] has been refined. The relative positions in the half molecule of subunits Aa 3A and Aa 3B compared to those of Aa 3C and Aa 5B have been established by double labeling of the (2 X 6)-mer with binary mixtures of subunit-specific Fab fragments. The results show that subunits Aa 3B and Aa 5B are located in the same hexamer while Aa 3A and Aa 3C are in the other half of the (2 X 6)-mer. The choice of the enantiomer was deduced from a careful examination of electron micrographs of the native molecule. Finally a position was assigned to each of the 24 subunits on the flip and flop faces as defined by Van Heel and Frank [Ultramicroscopy, 6, 187-194 (1981)].

Haemocyanins

About ten years ago, one of the authors participated in a review of haemocyanin structure and function (van Holde & van Bruggen, 1971). At that time, it was possible to describe the field in terms of a limited amount of exciting new structural information, and a long list of unanswered questions. While the stoichiometry of oxygen binding was understood, virtually nothing was known about the active site. Even the oxidation state of the copper was a matter of conjecture. The size of the haemocyanin polypeptide chains was the subject of intense debate, with very little substantive knowledge available. While the haemocyanins were known to be allosteric proteins, there were virtually no experimental studies of oxygen binding on a level that could be meaningfully interpreted in terms of extant theories.