Immunological correspondence between arthropod hemocyanin subunits. II. Xiphosuran (Limulus) and spider (Eurypelma, Cupiennius) hemocyanin

The hemocyanins of the horseshoe crab Limulus polyphemus (48-mer), the tarantula Eurypelma californicum (24-mer), and the lycosid spider Cupiennius salei (dodecamer, hexamer) were dissociated into subunits, the subunits isolated and studied by two-dimensional immunoelectrophoresis for interspecific cross-reactivities. Among the subunits a to g of Eurypelma on the one side, and I to VI of Limulus on the other, a number of cross-reactions were obtained which agree with the topologic subunit positions in the published models of quaternary structure: a = II, b-c = V-VI, d = IV, e = I, f = IIIb, g = IIIa (IIa). However, cross-reactivity was only strong in the following combinations: a/II, d/IV, b-c/V-VI (the monomers of the two heterodimers could not be correlated individually). A rather weak cross-reaction was obtained in the case of e/I and g/IIIa (IIa); a cross-reaction between f and IIIb was almost undetectable. On the other hand, f/IV clearly cross-reacted, and so did e/IIIa (IIa), which apparently is not in agreement with the two models of quaternary structure. These unexpected relationships, however, indicate the possible phylogeny of the subunits. Antiserum against Cupiennius hemocyanin precipitated subunit f of Eurypelma and subunit IV of Limulus and, moreover, revealed common antigen determinants present on these subunits. Denaturation of hemocyanin subunits of the three species with 8M urea yielded a completely different immunological behavior in that in all intra- and interspecific combinations the reaction of immunological identity was obtained. The published models of quaternary structure and a possible subunit phylogeny of cheliceratan hemocyanins is discussed in view of the present results and the results of the preceding paper. [Markl, J. et al. (1984) Hoppe-Seyler's Z. Physiol. Chem. 365, 619-631.]     

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.     

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.     

Subunit-specific monoclonal antibodies to tarantula hemocyanin,and a common epitope shared with calliphorin

Summary Three murine hybridoma cell lines secreting IgG₁ antibodies to 4×6 tarantula (Eurypelma californicum) hemocyanin were isolated, and the monoclonal antibodies Ec-7, Ec-8 and Ec-24 characterized by immunoblotting, immunoelectrophoresis and ELISA. WholeEurypelma hemocyanin, and the isolated subunitsa tog served as probes. For the subunits a novel, quick purification scheme on FPLC combined with immuno-affinity chromatography was established.Additionally, two cell lines secreting IgM antibodies were isolated. These antibodies showed irrelevant cross reactivities.Ec-7 strongly reacts with subunitd and weakly withb. Ec-8 and Ec-24 are specifically directed againstEurypelma subunitsa ande, respectively. The epitopes of Ec-7 and Ec-8 are sequence-dependent, whereas the Ec-24 epitope is conformation-dependent. Ec-8 and Ec-24 are specific forEurypelma hemocyanin. Ec-7 is not reactive to crustacean, centipede or gastropod hemocyanins, but binds to scorpion hemocyanin and to the immunological correlates of subunitsd andf in the hemocyanins of the spiderCupiennius salei and the xiphosuranLimulus polyphemus.In immunoblots with different polyclonal antisera,Eurypelma andAstacus hemocyanin cross-reacted with calliphorin, a larval serum protein from the blowflyCalliphora vicina. Calliphorin and chelicerate hemocyanins share the Ec-7 epitope. Sedimentation coefficients, pH stability regions, subunit size, and electron microscopical appearance of calliphorin are indiscernable from a typical 1×6 arthropod hemocyanin. This relationship is discussed in the context of hemocyanin evolution.Abbreviations FPLC fast performance liquid chromatography - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulphate A preliminary account of this work was presented in June 1987 at the annual meeting of the Deutsche Zoologische Gesellschaft at Ulm (Markl 1987a)     

Spider hemocyanin binds ecdysone and 20-OH-ecdysone

Fluorescence quenching studies and binding experiments with [(3)H]ecdysone reveal that the respiratory protein, hemocyanin, of the tarantula Eurypelma californicum binds ecdysone. The binding constant for ecdysone ranges between 0.5 and 5 mM, indicating a low affinity binding. However, it is comparable with those found for the ecdysone binding to hexamerins from insects. Based on a comparison of sequences and x-ray structures of arthropodan hemocyanins, we propose an evolutionary conserved hydrophobic pocket in domain 1 of the hemocyanin subunit that may bind ecdysone.     

Subunit sequences of the 4 x 6-mer hemocyanin from the golden orb-web spider, Nephila inaurata.

The transport of oxygen in the hemolymph of many arthropod and mollusc species is mediated by large copper-proteins that are referred to as hemocyanins. Arthropod hemocyanins are composed of hexamers and oligomers of hexamers. Arachnid hemocyanins usually form 4 x 6-mers consisting of seven distinct subunit types (termed a-g), although in some spider taxa deviations from this standard scheme have been observed. Applying immunological and electrophoretic methods, six distinct hemocyanin subunits were identified in the red-legged golden orb-web spider Nephila inaurata madagascariensis (Araneae: Tetragnathidae). The complete cDNA sequences of six subunits were obtained that corresponded to a-, b-, d-, e-, f- and g-type subunits. No evidence for a c-type subunit was found in this species. The inclusion of the N. inaurata hemocyanins in a multiple alignment of the arthropod hemocyanins and the application of the Bayesian method of phylogenetic inference allow, for the first time, a solid reconstruction of the intramolecular evolution of the chelicerate hemocyanin subunits. The branch leading to subunit a diverged first, followed by the common branch of the dimer-forming b and c subunits, while subunits d and f, as well as subunits e and g form common branches. Assuming a clock-like evolution of the chelicerate hemocyanins, a timescale for the evolution of the Chelicerata was obtained that agrees with the fossil record.     

Complete hemocyanin subunit sequences of the hunting spider Cupiennius salei: recent hemocyanin remodeling in entelegyne spiders

Hemocyanins are large copper-containing respiratory proteins found in many arthropod species. Scorpions and orthognath spiders possess a highly conserved 4 x 6-mer hemocyanin that consists of at least seven distinct subunit types (termed a to g). However, many "modern" entelegyne spiders such as Cupiennius salei differ from the standard arachnid scheme and have 2 x 6-mer hemocyanins. Here we report the complete primary structure of the 2 x 6-mer hemocyanin of C. salei as deduced from cDNA sequencing, gel electrophoresis, and matrix-assisted laser desorption spectroscopy. Six distinct subunit types (1 through 6) and three additional allelic sequences were identified. Each 1 x 6-mer half-molecule most likely is composed of subunits 1-6, with subunit 1 linking the two hexamers via a disulfide bridge located in a C-terminal extension. The C. salei hemocyanin subunits all belong to the arachnid g-type, whereas the other six types (a-f) have been lost in evolution. The reconstruction of a complex hemocyanin from a single g-type subunit, which commenced about 190 million years ago and was completed about 90 million years ago, might be explained by physiological and behavioral changes that occurred during the evolution of the entelegyne spiders.     

The hemocyanin of the ramshorn snail, Marisa cornuarietis (Linné)

1. The hemocyanin of the freshwater snail, Marisa cornuarietis exists predominantly as a di-decamer with the approximate mol. wt of 8.5 x 10(6) and a sedimentation coefficient of 100 S. Sedimentation and scanning transmission electron microscopy experiments indicate that about 15-20% of the hemocyanin forms tri-decameric and possibly higher aggregates with mol. wts of 12.5 x 10(6) and 130 S. 2. The fully dissociated subunits in 8.0 M urea and 6.0 M GdmCl have mol. wts of 4.1 to 4.7 x 10(5) which is close to one-twentieth of the major di-decameric component of the native hemocyanin. 3. Subunit dissociation by the urea series and the Hofmeister salt series of reagents suggests hydrophobic stabilization of the decamers or half-molecules of the parent hemocyanin. As with the other molluscan hemocyanins the order of effectiveness of the ureas as dissociating agents shows increased efficacy with increasing hydrophobicity or chain-length of the urea substituents. 4. Denaturation of the hemocyanin subunits by the ureas and Hofmeister salt series, investigated by circular dichroism measurements, essentially follow the same trend in effectiveness as observed by changes in subunit dissociation followed by light-scattering mol. wt measurements. 5. The observed denaturation transitions are shifted to much higher ranges of reagent concentration than the concentrations required for the dissociation of the hemocyanin subunits.     

Subunit composition of a high molecular weight oligomer: Limulus polyphemus hemocyanin

The hemocyanin of Limulus polyphemus is a 48-subunit aggregate. This 3.3 × 10⁶-dalton oligomer is composed of structurally and functionally heterogeneous subunits. Using polyacrylamide electrophoresis J. Markl, A. Markl, W. Schartau, and B. Linzen (J. Comp. Physiol. Ser. B130,283–292, 1979) observed 12 bands; while using immunoelectrophoresis, M. Hoylaerts, G. Preaux, R. Witters, and R. Lontie (Arch. Int. Physiol. Biochem.87, 417–418, 1979) and J. Lamy, J. Lamy, J. Weill, J. Bonaventura, C. Bonaventura, and M. Brenowitz. (Arch. Biochem. Biophys.196, 324–339, 1979) observed 8 subunits. To proceed with an analysis of subunit roles in assembly it is first necessary to determine the number of distinct subunits. Refinement of the chromatographic separation procedures has led to the isolation of 8 immunologically distinct subunits as well as additional charge isomers which cannot be distinguished immunologically. Alkaline electrophoresis revealed 15 bands and isoelectric focusing up to 17. On the basis of extensive control experiments, including composit acrylamide-agarose immunoelectrophoresis and checks for conformational isomers, aggregation, proteolysis, and other types of degradation, we conclude that the electrophoretic heterogeneity of immunologically identical subunits is not artifactual. We have extended the nomenclature used by Lamy et al. (1979) to include the electrophoretic heterogeneity by using primes (′) to denote electrophoretically distinguishable subunits which are immunologically identical. A number of patterns have become apparent by correlating the results obtained by the different techniques. For example, immunologically pure subunit II, which shows 3 bands on alkaline electrophoresis, is in fact a mixture of electrophoretically distinct subunits II, II′, II″. Except for subunits II, II′, and II″ immunoelectrophoretically identical subunits are typically homogeneous on sodium dodecyl sulfate-gels. However, slight differences in the apparent molecular weight are observed on high-resolution gels between immunologically unrelated subunits. The immunological identity and electrophoretic differences suggest that the charge isomers which are immunologically identical have similar antigenic surfaces. If a charge substitution is not in a critical location, we would expect the electrophoretically distinct but immunologically identical subunits to have identical assembly roles. Comparison of the results for Limulus hemocyanin with the hemocyanin of related species Eurypelma californicum and Androctanus australis, which have 7 and 8 immunologically distinct subunits, respectively, suggests that the calcium-mediated aggregation from 24 to 48 subunits of Limulus does not require more extensive subunit complexity.     

Complete sequence of the 24-mer hemocyanin of the tarantula Eurypelma californicum. Structure and intramolecular evolution of the subunits

Hemocyanins are large oligomeric respiratory proteins found in many arthropods and molluscs. The hemocyanin of the tarantula Eurypelma californicum is a 24-mer protein complex with molecular mass of 1, 726,459 Da that consists of seven different polypeptides (a-g), each occupying a distinct position within the native molecule. Here we report the complete molecular structure of the E. californicum hemocyanin as deduced from the corresponding cDNAs. This represents the first complex arthropod hemocyanin to be completely sequenced. The different subunits display 52-66% amino acid sequence identity. Within the subunits, the central domain, which bears the active center with the copper-binding sites A and B, displays the highest degree of identity. Using a homology modeling approach, the putative three-dimensional structure of individual subunits was deduced and compared. Phylogenetic analyses suggest that differentiation of the individual subunits occurred 400-550 million years ago. The hemocyanin of the stemline Chelicerata was probably a hexamer built up of six distinct subunit types a, b/c, d, e, f, and g, whereas that of the early Arachnida was originally a 24-mer that emerged after the differentiation of subunits b and c.     

Hemocyanins in spiders, VII. Immunological comparison of the subunits of Eurypelma californicum hemocyanin.

The isolated subunites of Eurypelma californicum hemocyanin were studied by aid of antibodies raised against whole, dissociated hemocyanin. The proportion of impurities was found to be low in almost all subunits. There was no cross reaction between the individual chains, and the total number of antigenically different subunits was found to be seven, confirming results obtained by different methods. If an artificial mixture prepared from purified subunits is compared to whole, dissociated hemocyanin, an overall very similar pattern is obtained but differences appear which are due to specific interaction.--The dimeric subunit 4D was shown to be a heterodimer (asymmetric dimer) composed of chains b and c4.     

Characterization of hemocyanin from the peacock mantis shrimp Odontodactylus scyllarus (Malacostraca:Hoplocarida)

Hemocyanin is the blue respiratory protein of many arthropod species. While its structure, evolution, and physiological function have been studied in detail in Decapoda, there is little information on hemocyanins from other crustacean taxa. Here, we have investigated the hemocyanin of the peacock mantis shrimp Odontodactylus scyllarus, which belongs to the Stomatopoda (Hoplocarida). O. scyllarus hemocyanin forms a dodecamer (2 × 6-mer), which is composed of at least four distinct subunit types. We obtained the full-length cDNA sequences of three hemocyanin subunits, while a fourth cDNA was incomplete at its 5′ end. The complete full-length cDNAs of O. scyllarus hemocyanin translate into polypeptides of 650–662 amino acids, which include signal peptides of 16 or 17 amino acids. The predicted molecular masses of 73.1–75.1 kDa correspond well with the main hemolymph proteins detected by SDS-PAGE and Western blotting using various anti-hemocyanin antibodies. Phylogenetic analyses show that O. scyllarus hemocyanins belong to the β-type of malacostracan hemocyanin subunits, which diverged from the other subunits before the radiation of the malacostracan subclasses around 520 million years ago. Molecular clock analysis revealed an ancient and complex pattern of hemocyanin subunit evolution in Malacostraca and also allowed dating divergence times of malacostracan taxa.     

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.     

Allosteric oxygen-binding properties of reassembled tarantula (Eurypelma californicum) hemocyanin with incorporated apo- or met-subunits

4x6-meric hemocyanin of the tarantula Eurypelma californicum was dissociated into subunits; one type of subunit was removed by immunoaffinity chromatography and replaced by its apo- or met-form. The mixture was reassembled and the reconstituted 4x6-mers were isolated. This was performed for subunits a, bc, d, e, f and g, respectively. It was verified by crossed immunoelectrophoresis that each type of subunit including the modified one, was incorporated in the reassembled 4x6-mers. Oxygen binding curves of the purified reconstituted 4x6-mers were recorded at different pH values (pH 7.0-9.0; 20 degrees C). Half-saturation pressures (P50) and the cooperativities were calculated using unmodified, reassembled 4x6-mers as reference. In all cases, incorporation of a met-subunit increased oxygen affinity. In contrast, incorporation of an apo-subunit either slightly decreased oxygen affinity (bc, f and d) or had no detected influence (others). The Bohr effect remained more or less unchanged in every case. Cooperativity was generally decreased. The met-modification of subunit d had the strongest effect. No significant differences could be observed between the respective met- and apomodification, except for experiments with subunit d. Generally, the value of hmax exceeded h50 by a factor of 1.3 to 1.5. pH-sensitivity of cooperativity was distinctly influenced depending on the modified subunit. The strongest effect was observed for subunit bc. Our results demonstrate, for the first time, that each subunit of tarantula hemocyanin is involved in the allosteric processes. Apparently, they uniformly contribute to oxygen affinity and Bohr effect, but distinctly to cooperativity and pH sensitivity of the latter.     

The cDNA sequence of three hemocyanin subunits from the garden snail Helix lucorum

Hemocyanins are blue copper containing respiratory proteins residing in the hemolymph of many molluscs and arthropods. They can have different molecular masses and quaternary structures. Moreover, several molluscan hemocyanins are isolated with one, two or three isoforms occurring as decameric, didecameric, multidecameric or tubule aggregates. We could recently isolate three different hemocyanin isopolypeptides from the hemolymph of the garden snail Helix lucorum (HlH). These three structural subunits were named α_D-HlH, α_N-HlH and β-HlH. We have cloned and sequenced their cDNA which is the first result ever reported for three isoforms of a molluscan hemocyanin. Whereas the complete gene sequence of α_D-HlH and β-HlH was obtained, including the 5′ and 3′ UTR, 180 bp of the 5′ end and around 900 bp at the 3′ end are missing for the third subunit. The subunits α_D-HlH and β-HlH comprise a signal sequence of 19 amino acids plus a polypeptide of 3409 and 3414 amino acids, respectively. We could determine 3031 residues of the α_N-HLH subunit. Sequence comparison with other molluscan hemocyanins shows that α_D-HlH is more related to Aplysia californicum hemocyanin than to each of its own isopolypeptides. The structural subunits comprise 8 different functional units (FUs: a, b, c, d, e, f, g, h) and each functional unit possesses a highly conserved copper-A and copper-B site for reversible oxygen binding. Potential N-glycosylation sites are present in all three structural subunits. We confirmed that all three different isoforms are effectively produced and secreted in the hemolymph of H. lucorum by analyzing a tryptic digest of the purified native hemocyanin by MALDI-TOF and LC-FTICR mass spectrometry.     

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.     

Biochemical and molecular characterisation of hemocyanin from the amphipod <Emphasis Type="Italic">Gammarus roeseli</Emphasis>: complex pattern of hemocyanin subunit evolution in Crustacea

Hemocyanin is a copper-containing respiratory protein that is widespread within the arthropod phylum. Among the Crustacea, hemocyanins are apparently restricted to the Malacostraca. While well-studied in Decapoda, no hemocyanin sequence has been known from the ’lower’ Malacostraca. The hemocyanin of the amphipod Gammarus roeseli is a hexamer that consists of at least five distinct subunits. The complete cDNA sequence of one subunit and a tentative partial sequence of another subunit have been determined. The complete G. roeseli hemocyanin subunit comprises 2,150 bp, which translates in a protein of 672 amino acids with a molecular mass of 76.3 kDa. Phylogenetic analyses show that, in contrast to previous assumptions, the amphipod hemocyanins do not belong to the α-type of crustacean hemocyanin subunits. Rather, amphipod hemocyanins split from the clade leading to α and γ-subunits most likely at the time of separation of peracarid and eucarid Crustacea about 300 million years ago. Molecular clock analyses further suggest that the divergence of β-type subunits and other crustacean hemocyanins occurred around 315 million years ago (MYA) in the malacostracan stemline, while α- and γ-type subunits separated 258 MYA, and pseudohemocyanins and γ-subunits 210 million years ago.     

SDS-induced phenoloxidase activity of hemocyanins from Limulus polyphemus, Eurypelma californicum, and Cancer magister

Phenoloxidase, widely distributed among animals, plants, and fungi, is involved in many biologically essential functions including sclerotization and host defense. In chelicerates, the oxygen carrier hemocyanin seems to function as the phenoloxidase. Here, we show that hemocyanins from two ancient chelicerates, the horseshoe crab Limulus polyphemus and the tarantula Eurypelma californicum, exhibit O-diphenoloxidase activity induced by submicellar concentrations of SDS, a reagent frequently used to identify phenoloxidase activity. The enzymatic activity seems to be restricted to only a few of the heterogeneous subunits. These active subunit types share similar topological positions in the quaternary structures as linkers of the two tightly connected 2 x 6-mers. Because no other phenoloxidase activity was found in the hemolymph of these animals, their hemocyanins may act as a phenoloxidase and thus be involved in the primary immune response and sclerotization of the cuticle. In contrast, hemolymph of a more recent arthropod, the crab Cancer magister, contains both hemocyanin with weak phenoloxidase activity and another hemolymph protein with relatively strong phenoloxidase activity. The chelicerate hemocyanin subunits showing phenoloxidase activity may have evolved into a separate phenoloxidase in crustaceans.     

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.