Switch between tyrosinase and catecholoxidase activity of scorpion hemocyanin by allosteric effectors

Phenoloxidases and hemocyanins have similar type 3 copper centers although they perform different functions. Hemocyanins are oxygen carriers, while phenoloxidases (tyrosinase/catecholoxidase) catalyze the initial step in melanin synthesis. Tyrosinases catalyze two subsequent reactions, whereas catecholoxidases catalyze only the second one. Recent results indicate that hemocyanins can also function as phenoloxidases and here we show for the first time that hemocyanin can be converted to phenoloxidase. Furthermore, its substrate specificity can be switched between catecholoxidase and tyrosinase activity depending on effectors such as hydroxymethyl-aminomethan (Tris) and Mg(2+)-ions. This demonstrates that substrate specificity is not caused by a chemical modification of the active site.     

cDNA cloning of a developmentally regulated hemocyanin subunit in the crustacean Cancer magister and phylogenetic analysis of the hemocyanin gene family

The complete cDNA sequence and protein reading frame of a developmentally regulated hemocyanin subunit in the Dungeness crab (Cancer magister) is presented. The protein sequence is aligned with 18 potentially homologous hemocyanin-type proteins displaying apparent sequence similarities. Functional domains are identified, and a comparison of predicted hydrophilicities, surface probabilities, and regional backbone flexibilities provides evidence for a remarkable degree of structural conservation among the proteins surveyed. Parsimony analysis of the protein sequence alignment identifies four monophyletic groups on the arthropodan branch of the hemocyanin gene tree: crustacean hemocyanins, insect hexamerins, chelicerate hemocyanins, and arthropodan prophenoloxidases. They form a monophyletic group relative to molluscan hemocyanins and nonarthropodan tyrosinases. Arthropodan prophenoloxidases, although functionally similar to tyrosinases, appear to belong to the arthropodan hexamer- type hemolymph proteins as opposed to molluscan hemocyanins and tyrosinases.      

Minireview: Recent progress in hemocyanin research

This review summarizes recent highlights of our joint work on the structure, evolution, and function of a family of highly complex proteins, the hemocyanins. They are blue-pigmented oxygen carriers, occurring freely dissolved in the hemolymph of many arthropods and molluscs. They are copper type-3 proteins and bind one dioxygen molecule between two copper atoms in a side-on coordination. They possess between 6 and 160 oxygen-binding sites, and some of them display the highest molecular cooperativity observed in nature. The functional properties of hemocyanins can be convincingly described by either the Monod-Wyman-Changeux (MWC) model or its hierarchical extension, the Nested MWC model; the latter takes into account the structural hierarchies in the oligomeric architecture. Recently, we applied these models to interpret the influence of allosteric effectors in detailed terms. Effectors shift the allosteric equilibria but have no influence on the oxygen affinities characterizing the various conformational states. We have shown that hemocyanins from species living at different environmental temperatures have a cooperativity optimum at the typical temperature of their natural habitat. Besides being oxygen carriers, some hemocyanins function as a phenoloxidase (tyrosinase/catecholoxidase) which, however, requires activation. Chelicerates such as spiders and scorpions lack a specific phenoloxidase, and in these animals activated hemocyanin might catalyse melanin synthesis in vivo. We propose a similar activation mechanism for arthropod hemocyanins, molluscan hemocyanins and tyrosinases: amino acid(s) that sterically block the access of phenolic compounds to the active site have to be removed. The catalysis mechanism itself can now be explained on the basis of the recently published crystal structure of a tyrosinase. In a series of recent publications, we presented the complete gene and primary structure of various hemocyanins from different molluscan classes. From these data, we deduced that the molluscan hemocyanin molecule evolved ca. 740 million years ago, prior to the separation of the extant molluscan classes. Our recent advances in the 3D cryo-electron microscopy of hemocyanins also allow considerable insight into the oligomeric architecture of these proteins of high molecular mass. In the case of molluscan hemocyanin, the structure of the wall and collar of the basic decamers is now rapidly becoming known in greater detail. In the case of arthropod hemocyanin, a 10-? structure and molecular model of the Limulus 8 × 6mer shows the amino acids at the various interfaces between the eight hexamers, and reveals histidine-rich residue clusters that might be involved in transferring the conformational signals establishing cooperative oxygen binding.     

Tyrosinase localization in mollusc shells

In molluscan shellfish, pigmentation is frequently observed in the calcified shell, but the molecular basis of this process is not understood. Here, we report two tyrosinase proteins (Pfty1 and Pfty2) found in the prismatic shell layer of the pearl oyster Pinctada fucata; this layer is recognized as the pigmented region in P. fucata. The protein sequences were deduced from the corresponding cDNAs and confirmed by MALDI-TOF/TOF analysis. The sequences suggest that both tyrosinases have two copper-binding sites in similar N-terminal domains that are homologous to tyrosinases of cephalopods and hemocyanins of gastropods. In turn, this suggests that bivalve tyrosinases are evolved from a common ancestral copper-binding protein in the mollusc. Pfty1 and Pfty2 were specifically expressed in the mantle, and their expression in the mantle is different from each other, suggesting that these tyrosinases have distinctive roles in melanogenesis in shells.     

Molecular evolution of the arthropod hemocyanin superfamily

Arthropod hemocyanins are members of a protein superfamily that also comprises the arthropod phenoloxidases (tyrosinases), crustacean pseudohemocyanins (cryptocyanins), and insect storage hexamerins. The evolution of these proteins was inferred by neighbor-joining, maximum-parsimony, and maximum-likelihood methods. Monte Carlo shuffling approaches provided evidence against a discernible relationship of the arthropod hemocyanin superfamily and molluscan hemocyanins or nonarthropodan tyrosinases. Within the arthropod hemocyanin superfamily, the phenoloxidase probably emerged early in the (eu-)arthropod stemline and thus form the most likely outgroup. The respiratory hemocyanins evolved from these enzymes before the radiation of the extant euarthropodan subphyla. Due to different functional constraints, replacement rates greatly vary between the clades. Divergence times were thus estimated assuming local molecular clocks using several substitution models. The results were consistent and indicated the separation of the cheliceratan and crustacean hemocyanins close to 600 MYA. The different subunit types of the multihexameric cheliceratan hemocyanin have a rather conservative structure and diversified in the arachnidan stemline between 550 and 450 MYA. By contrast, the separation of the crustacean (malacostracan) hemocyanin subunits probably occurred only about 200 MYA. The nonrespiratory pseudohemocyanins evolved within the Decapoda about 215 MYA. The insect hemocyanins and storage hexamerins emerged independently from the crustacean hemocyanins. The time of divergence of the insect proteins from the malacostracan hemocyanins was estimated to be about 430-440 MYA, providing support for the notion that the Hexapoda evolved from the same crustacean lineage as the Malacostraca.     

Common origin of arthropod tyrosinase,arthropod hemocyanin,insect hexamerin,and dipteran arylphorin receptor

Dipteran arylphorin receptors, insect hexamerins, cheliceratan and crustacean hemocyanins, and crustacean and insect tyrosinases display significant sequence similarities. We have undertaken a systematic comparison of primary and secondary structures of these proteins. On the basis of multiple sequence alignments the phylogeny of these proteins was investigated. Hexamerin subunits, hemocyanin subunits, and tyrosinases share extensive similarities throughout the entire amino acid sequence. Our studies suggest the origin of arthropod hemocyanins from ancient tyrosinase-like proteins. Insect hexamerins likely evolved from hemocyanins of ancient crustaceans, supporting the proposed sister-group position of these subphyla. Arylphorin receptors, responsible for incorporation of hexamerins into the larval fat body of diptera, are related to hexamerins, hemocyanins, and tyrosinase. The receptor sequences display extensive similarities to the first and third domains of hemocyanins and hexamerins. In the middle region only limited amino acid conservation was observed. Elements important for hexamer formation are deleted in the receptors. Phylogenetic analysis indicated that dipteran arylphorin receptors diverged from ancient hexamerins, probably early in insect evolution. Correspondence to: T. Burmester     

Complete amino-acid sequence of a functional unit from a molluscan hemocyanin (Helix pomatia)

From the beta c-hemocyanin (beta c-Hc) of the vineyard snail, Helix pomatia, the functional unit d (Mr approximately equal to 50,000-55,000) was isolated by limited proteolysis and gel chromatography. A small quantity of functional unit d was obtained intact, but the major part in the form of two peptides (Mr approximately equal to 43,000 and 10,000, respectively) connected by a disulfide bridge. After reduction and carboxymethylation, these were separated from each other and cleaved by conventional methods. The peptides were isolated by gel chromatography and HPLC, and sequenced manually or automatically. The complete sequence of Helix beta c-Hc d comprises 410 residues plus 3 residues at the N-terminus seemingly resulting from incomplete cleavage. There is apparently only one carbohydrate side-chain. Comparison of this gastropodan hemocyanin sequence to the partial sequence of a cephalopodan Hc C-terminal unit revealed sufficient identities to state that the functional units of molluscan hemocyanins have arisen by a series of gene duplications. On the other hand, there is practically no homology with arthropodan hemocyanins except for one section of 42 residues which is clearly homologous. This section corresponds to the "Copper B" site of Panulirus interruptus hemocyanin. It is also found in tyrosinases from Neurospora crassa, Streptomyces glaucescens, and mouse. In the N-terminal half of Helix beta c-Hc d there are other sections clearly homologous to the tyrosinases, but overall homology is limited. The second copper-binding site was not identified but must be completely distinct from the "Copper A" binding site of arthropodan hemocyanins. It is suggested that molluscan and arthropodan hemocyanins have evolved independently from a common ancestral mononuclear copper protein.     

Luminescence of deoxyhemocyanin and deoxytyrosinase

The deoxy form of hemocyanins and tyrosinases from certain species displays a weak low-energy luminescence when solutions of the protein are irradiated with light at approximately 290 nm. The emission most likely results from a copper-to-imidazole charge transfer state as shown by studies with a synthetic copper(I) complex having three imidazole ligands.     

Bacterial tyrosinases

Tyrosinases are nearly ubiquitously distributed in all domains of life. They are essential for pigmentation and are important factors in wound healing and primary immune response. Their active site is characterized by a pair of antiferromagnetically coupled copper ions, CuA and CuB, which are coordinated by six histidine residues. Such a "type 3 copper centre" is the common feature of tyrosinases, catecholoxidases and haemocycanins. It is also one of several other copper types found in the multi-copper oxidases (ascorbate oxidase, laccase). The copper pair of tyrosinases binds one molecule of atmospheric oxygen to catalyse two different kinds of enzymatic reactions: (1) the ortho-hydroxylation of monophenols (cresolase activity) and (2) the oxidation of o-diphenols to o-diquinones (catecholase activity). The best-known function is the formation of melanins from L-tyrosine via L-dihydroxyphenylalanine (L-dopa). The complicated hydroxylation mechanism at the active centre is still not completely understood, because nothing is known about their tertiary structure. One main reason for this deficit is that hitherto tyrosinases from eukaryotic sources could not be isolated in sufficient quantities and purities for detailed structural studies. This is not the case for prokaryotic tyrosinases from different Streptomyces species, having been intensively characterized genetically and spectroscopically for decades. The Streptomyces tyrosinases are non-modified monomeric proteins with a low molecular mass of ca. 30kDa. They are secreted to the surrounding medium, where they are involved in extracellular melanin production. In the species Streptomyces, the tyrosinase gene is part of the melC operon. Next to the tyrosinase gene (melC2), this operon contains an additional ORF called melC1, which is essential for the correct expression of the enzyme. This review summarizes the present knowledge of bacterial tyrosinases, which are promising models in order to get more insights in structure, enzymatic reactions and functions of "type 3 copper" proteins in general.     

Structure–function correlations in tyrosinases

Tyrosinases are metalloenzymes belonging to the type-3 copper protein family which contain two copper ions in the active site. They are found in various prokaryotes as well as in plants, fungi, arthropods, and mammals and are responsible for pigmentation, wound healing, radiation protection, and primary immune response. Tyrosinases perform two sequential enzymatic reactions: hydroxylation of monophenols and oxidation of diphenols to form quinones which polymerize spontaneously to melanin. Two other members of this family are catechol oxidases, which are prevalent mainly in plants and perform only the second oxidation step, and hemocyanins, which lack enzymatic activity and are oxygen carriers. In the last decade, several structures of plant and bacterial tyrosinases were determined, some with substrates or inhibitors, highlighting features and residues which are important for copper uptake and catalysis. This review summarizes the updated information on structure–function correlations in tyrosinases along with comparison to other type-3 copper proteins.     

A Cladistic Analysis of the Evolutionary Relationships of the Members of the Tyrosinase Gene Family Using Sequence Data

Recently, DNA sequence data have been published on tyrosinase and tyrosinase-related proteins (TRPs) in a wide variety of vertebrates ranging from Rana to Homo. These proteins are in turn members of a larger family of binuclear copper-binding proteins, which all contain two highly conserved copper-binding domains. This gene family also includes tyrosinases from fungi and bacteria as well as arthropodan and molluscan hemocyanins. Parsimony-based alignment and tree construction algorithms (Malign, vl.85 and PAUP, 3.1.1) were used to analyze the diversification of both the evolutionarily conserved copper-binding domains i6n copper-binding proteins in general as well as the diversification of the vertebrate tyrosinase gene family more specifically. These analyses show that the diversification of the vertebrate tyrosinase gene family minimally predates the diversification of vertebrates. Vertebrate tyrosinases proper first diverged from an ancestral tyrosinase-related protein (TRP) that then subsequently diverged to form tyrosinase-related protein-Is (TRP-1s) and tyrosinase-related protein-2s (TRP-2s).     

Kinetic properties of catecholoxidase activity of tarantula hemocyanin

Phenoloxidases occur in almost all organisms, being essentially involved in various processes such as the immune response, wound healing, pigmentation and sclerotization in arthropods. Many hemocyanins are also capable of phenoloxidase activity after activation. Notably, in chelicerates, a phenoloxidase has not been identified in the hemolymph, and thus hemocyanin is assumed to be the physiological phenoloxidase in these animals. Although phenoloxidase activity has been shown for hemocyanin from several chelicerate species, a characterization of the enzymatic properties is still lacking. In this article, the enzymatic properties of activated hemocyanin from the tarantula Eurypelma californicum are reported, which was activated by SDS at concentrations above the critical micellar concentration. The activated state of Eurypelma hemocyanin is stable for several hours. Dopamine is a preferred substrate of activated hemocyanin. For dopamine, a K(M) value of 1.45 +/- 0.16 mm and strong substrate inhibition at high substrate concentrations were observed. Typical inhibitors of catecholoxidase, such as l-mimosine, kojic acid, tyramine, phenylthiourea and azide, also inhibit the phenoloxidase activity of activated hemocyanin. This indicates that the activated hemocyanin behaves as a normal phenoloxidase.     

Hemocyanin of the horseshoe crab, Limulus polyphemus. Structural differentiation of the isolated components.

The high molecular weight hemocyanin found in the hemolymph of the horseshoe crab, Limulus polyphemus, is composed of at least eight different kinds of subunits. Ion exchange chromatography at high pH in the presence of EDTA yields five major zones, hemocyanins I to V, three of which are electrophoretically heterogeneous. The subunits have similar molecular weights, 65,000 to 70,000, and their amino acid compositions are remarkably similar to each other and to other arthropod and molluscan hemocyanins. Digestion of the native subunits of Limulus hemocyanin by formic acid or trypsin shows considerable structural diversity which is supported by cyanogen bromide cleavage patterns and by peptide mapping of the tryptic peptides prepared from denatured hemocyanin subunits. The structural differentiation of the subunits is accompanied by functional differentiation, as shown in previous investigations of their O2 and CO affinities (Sullivan, B., Bonaventura, J., and Bonaventura, C. (1974) Proc. Natl. Acad. Sci. U.S.A. 71, 2558-2562; Bonaventura, C., Bonaventura, J., Sullivan, B., and Bourne, S. (1975) Biochemistry 13, 4784-4789). The subunit diversity of Limulus hemocyanin suggests that other electrophoretically heterogeneous hemocyanins may be composed of structurally distinct subunits.     

Presence of functional domains in Limulus polyphemus hemocyanin

In an attempt to isolate structural domains of arthropod hemocyanins and possibly to investigate their functional properties, we have undertaken proteolytic digestion experiments of isolated subunits from Panulirus interruptus and Limulus polyphemus oxy-hemocyanin. Satisfactory results have been obtained using trypsin at high concentration and short digestion times. Results show that, in the case of Panulirus hemocyanin, only subunit alpha is susceptible to trypsin digestion, but that proteolytic cleavage is associated with the loss of the copper-oxygen band; on the other hand, in the case of Limulus hemocyanin, four subunits (I, II, III and IV) show a significant susceptibility to trypsin, and their fragmentation takes place with preservation of the oxygen-binding capacity. A more detailed study of the digestion products of subunit IV from Limulus hemocyanin reveals that the proteolytic fragments keep together in a single non-covalent complex. Attempts to separate the native fragments result in the precipitation of the digestion products. Subunit IV of Limulus with proteolytic cuts binds O2 and CO with the same affinity as the native subunit, suggesting that the copper site is still preserved structurally and is functionally active in a 37 kDa trypsin-resistant domain.     

Luminescence from the carbon monoxide derivative of Agaricus bispora tyrosinase

The luminescence of the CO adduct of two isozymic tyrosinases isolated from Agaricus bispora, an edible white mushroom, has been studied. At room temperature the emission appears as a single smooth peak centered at 530 nm with FWHM of 2700 cm-1 and a lifetime of 36 microseconds. The lifetime and wavelength of the emission are virtually unchanged on lowering the temperature from 298 to 77 degrees K. Solvent composition affects the wavelength of emission minimally. The emission is quenched by oxygen but not by a series of substrate analogs, inhibitors, or Lewis bases. The emission further appeared independent of aggregation state of the enzyme or isozyme type. A comparison of these data is made with those obtained by other researchers for the tyrosinase from Neurospora crassa and for several hemocyanins. The comparison supports the hypothesis that regulation of enzymatic activity does not take place within the coordination sphere of the copper atom observed. In addition, it suggests that the 550- to 560-nm emissions previously observed may not be considered characteristic of all CO derivatives of coupled binuclear copper proteins.     

Similar enzyme activation and catalysis in hemocyanins and tyrosinases

This review presents the common features and differences of the type 3 copper proteins with respect to their structure and function. In spite of these differences a common mechanism of activation and catalysis seems to have been preserved throughout evolution. In all cases the inactive proenzymes such as tyrosinase and catecholoxidase are activated by removal of an amino acid blocking the entrance channel to the active site. No other modification at the active site seems to be necessary to enable catalytic activity. Hemocyanins, the oxygen carriers in many invertebrates, also behave as silent inactive enzymes and can be activated in the same way. The molecular basis of the catalytic process is presented based on recent crystal structures of tyrosinase and hemocyanin. Minor conformational differences at the active site seem to decide about whether the active site is only able to oxidize diphenols as in catecholoxidase or if it is also able to o-hydroxylate monophenols as in tyrosinase.     

Identification, structure, and properties of hemocyanins from Diplopod myriapoda.

Hemocyanins are copper-containing, respiratory proteins that occur in the hemolymph of many arthropod species. Here we report for the first time the presence of hemocyanins in the diplopod Myriapoda, demonstrating that these proteins are more widespread among the Arthropoda than previously thought. The hemocyanin of Spirostreptus sp. (Diplopoda: Spirostreptidae) is composed of two immunologically distinct subunits in the 75-kDa range that are most likely arranged in a 36-mer (6 x 6) native molecule. It has a high oxygen affinity (P(50) = 4.7 torr) but low cooperativity (h = 1.3 +/- 0.2). Spirostreptus hemocyanin is structurally similar to the single known hemocyanin from the myriapod taxon, Scutigera coleoptrata (Chilopoda), indicating a rather conservative architecture of the myriapod hemocyanins. Western blotting demonstrates shared epitopes of Spirostreptus hemocyanin with both chelicerate and crustacean hemocyanins, confirming its identity as an arthropod hemocyanin.     

Cloning and characterization of cDNAs coding for Vicia faba polyphenol oxidase

Three cDNA clones were isolated which code for the ubiquitous chloroplast enzyme, polyphenol oxidase (PPO), from Vicia faba. Analysis of the cloned DNA reveals that PPO is synthesized with an N-terminal extension of 92 amino acid residues, presumed to be a transit peptide. The mature protein is predicted to have a molecular mass of 58 kDa which is in close agreement to the molecular mass estimated for the in vivo protein upon SDS-PAGE. Differences in the DNA sequence of two full-length and one partial cDNA clones indicate that PPO is encoded by a gene family. Analysis of the deduced amino acid sequence shows that the chloroplast PPO shares homology with the 59 kDa PPOs in glandular trichomes of solanaceous species. A high degree of sequence conservation was found with the copper-binding domains of the 59 kDa tomato PPO as well as hemocyanins and tyrosinases from a wide diversity of taxa.     

Recent aspects of the subunit organization and dissociation of hemocyanins

1. The hemocyanins of the arthropod phylum are built of multiples of hexamers consisting of 1,2,4,6 and 8 of such basic assemblies. Their molecular weights range from about 0.45 x 10(6) to 3.9 x 10(6) daltons. The basic hexameric unit consists of bean-shaped monomers organized in the form of two layers of trimers placed on top of one another. The subunits are heterogeneous, in most cases consisting of four or more electrophoretically different polypeptide chains. 2. Molluscan hemocyanins have an entirely different structure and pattern of assembly from the arthropodan hemocyanins. The basic assembly of the molluscan hemocyanins are decamers organized in the form of right-handed cylinders approximately 300 A in diameter and 140-190 A in height. Different species have one, two and sometimes more than two such assemblies forming correspondingly longer cylindrical particles with molecular weights ranging from about 3.3 x 10(6) to 13 x 10(6) daltons. Cephalopod and chiton hemocyanins consist of single decameric particles, while gastropods have hemocyanins organized of di-decamers or higher assemblies. The subunits of these hemocyanins are elongated protein chains with seven or eight folded globular domains, each housing a binuclear copper center capable of binding and delivering oxygen. 3. The dissociation behavior of the arthropod hemocyanin hexamers and di-hexamers with the hydrophobic urea series of reagents suggest polar and ionic interactions as the main sources of stabilization of the hexamers and the hexamer to hexamer contacts within the di-hexamers. 4. Dissociation studies with the same urea probes with the molluscan hemocyanins, however, suggest a different pattern of stabilization. The stabilization of the decamer to decamer contacts within the gastropod di-decamers appear to be predominantly polar and ionic with relatively few hydrophobic interaction sites. The dimer contacts within the decamers and the monomer to monomer contacts within the dimers observed in the octopus and chiton hemocyanins appear to be predominantly hydrophobic in nature. 5. The urea and the pH dissociation profiles of the single decameric assemblies of some of the octopus and chiton hemocyanins investigated by light-scattering molecular weight methods, have been fitted using either a two-species, decamer to dimer and decamer to monomer scheme of subunit dissociation or a three-species, decamer to dimer to monomer scheme of dissociation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Higher order assemblies of molluscan hemocyanins

1. The hemocyanins of the Fissurellidae, Naticidae and Melongenidae families of marine gastropods as well as some other molluscs including some members of the Opistobranchia and Bivalvia groups have hemocyanins which exist in solution as tri-decameric and mixed, multi-decameric aggregates characterized by sedimentation coefficients close to 100 S, 130 S, 150 S, 170 S and 200 S to 230 S. 2. The particle masses of the molluscan hemocyanins appear to be integral multiples close to 4.4 x 10(6) daltons. Thus, particle mass values of 4.47 x 10(6), 8.67 x 10(6) and 13.40 x 10(6) daltons were obtained for representative decameric, di-decameric, and tri-decameric components of Stenoplax conspicua, Fasciolaria tulipa and Euspira (Lunatia) heros hemocyanins. For Busycon contrarium, a gastropod with a mixed multidecameric hemocyanin, scanning transmission electron microscopic (STEM) measurements gave particle masses ranging from 8.89 x 10(6) and 13.20 x 10(6) for the di- and tri-decameric components to 38.87 x 10(6) and 43.40 x 10(6) daltons for highest nano- and deca-decameric aggregates. 3. The electron microscopic images of both uranyl acetate-stained and unstained specimens of hemocyanin aggregates indicate a non-random mode of assembly of the multi-decameric particles. This is most apparent from the electron micrographs of the moon snail hemocyanins. The tri-decameric and tetra-decameric particles seem to be assembled from a single di-decameric unit of the Mellema and Klug arrangement, with the collar ends facing outward, to which decameric units have been added from one or both ends, in a unidirectional tail-to-head to tail-to-collar manner. Consequently, all the aggregates including the higher, Melongenidae polymers have the appearance of closed cylinders terminating with the collar ends. 4. The radial distribution of the end-on views of the hemocyanin of the moon-snail Calinatioina oldroydii, show that the radial mass drops to zero at the center of the cylindrical particles consisting of one, two, or three decamers. This suggests that no caps are present at the ends of the hemocyanin particles which would inhibit or terminate their linear assembly. 5. The light-scattering behavior of B. contrarium and Marisa cornarietis hemocyanins examined as a function of increasing reagent concentration using the hydrophobic urea and Hofmeister salt series of reagents, show distinct aggregation and increase in molecular weights at low concentrations of reagent. Together with the stabilizing influence of Mg2+ and Ca2+ ions, this suggests polar and ionic stabilization of the inter-decameric contacts between the central di-decamers and the added decameric units of the higher aggregates of molluscan hemocyanins.(ABSTRACT TRUNCATED AT 400 WORDS)