Binding of oxygen and carbon monoxide to arthropod hemocyanin: an allosteric analysis

The binding of oxygen and carbon monoxide to hemocyanin from the mangrove crab Scylla serrata and the lobster Homarus americanus has been studied by thin-layer optical absorption and front face fluorescence techniques. Three types of experiments were performed on subunit and oligomeric preparations of each hemocyanin: oxygen binding, carbon monoxide binding, and oxygen-carbon monoxide competition studies. The results obtained from the subunit preparations of dissociated oligomers from both hemocyanins show that the binding site can be ligated by either one oxygen or one carbon monoxide. The binding results obtained with the oligomeric samples of hemocyanin from both species cannot be described by the two-state MWC model [Monod, J., Wyman, J., & Changeux, J. P. (1965) J. Mol. Biol. 12, 88-118] since the data from the three types of binding experiments cannot be fit with a single set of binding constants. The MWC model has been extended by including a third allosteric form, and an analysis based on the three-state model is able to fit the data from the three types of experiments with the same set of binding constants. The comparison of the oxygen to carbon monoxide affinity ratios (kO2/kCO) indicates that the structure around the binding site of subunits in the T form oligomer is similar to that of the free subunits. The oligomeric forms of both these hemocyanins bind carbon monoxide with a weak but definite positive cooperativity. An analysis of the affinity ratios for the T, S, and R forms suggests that the high affinity of the R form results from a specific interaction between oxygen and binding site.     

The oxygen-binding modulation of hemocyanin from the Southern spiny lobster <Emphasis Type="Italic">Palinurus gilchristi</Emphasis>

Arthropod hemocyanins transport and store oxygen and are composed of six subunits, or multiples thereof depending on the species. Palinurus gilchristi hemocyanin is found only as 1 × 6-mers, as normally occurs in spiny lobsters. An alkaline pH and removal of calcium ions induce a wholly reversible dissociation into monomers. The oxygen-binding properties of 1 × 6-meric hemocyanin from P. gilchristi were investigated with respect to pH and modulating effect exerted by calcium, lactate and urate. The oxygen affinity was highly affected by pH in the presence of calcium ions, while in its absence the Bohr coefficient became 60% lower. The protein is insensitive to lactate, but affected by urate which markedly increased hemocyanin–oxygen affinity, acting as the physiological major positive effector. Calcium ions decrease oxygen affinity at low concentration range (0–1 mM), while as concentration becomes higher than 100 mM, the oxygen affinity increases, indicating the presence of two independent types of calcium-binding sites with high and low affinity, respectively. The previous hypothesis, that the presence of high-affinity binding sites in addition to low affinity ones could be a characteristic feature of Palinuran hemocyanins, has been tested by analyzing, with respect to calcium–hemocyanin interaction, three other species belonging to Palinura.     

Tryptophan quenching as linear sensor for oxygen binding of arthropod hemocyanins

Oxygen binding of hemocyanins results in an absorption band around 340nm and a strong quenching of the intrinsic tryptophan fluorescence. Our study analyses in detail the fluorescence quenching within two hemocyanins, a hexamer (Panulirus interruptus) and a 4 x 6-mer (Eurypelma californicum). Based on the comparison of calculated and measured transfer efficiencies we could show that: (1) For both hemocyanins FRET (fluorescence resonance energy transfer) is exclusively responsible for quenching of the tryptophan fluorescence upon oxygen binding. (2) Tryptophan quenching by FRET is independent of the oxy- or deoxy conformation of the protein. (3) The quenching takes place at the subunit level only and the oligomerization of both hemocyanins has no influence on the amount of quenching. Therefore, tryptophan fluorescence is a linear sensor for bound oxygen. It can be used as a model-free signal to investigate oxygen binding of hemocyanins at all aggregation levels. Furthermore it may provide a new way to analyse oxygen binding of phenoloxidases.     

Functional unit of the Rapana thomasiana (grosse) (marine snail, gastropod) hemocyanin

The amino terminal functional unit (domain a) of the Rapana hemocyanin “heavy” structural subunit, designated as Rta, was obtained after limited trypsinolysis of the whole polypeptide chain. Mass spectrometric analysis showed a molecular mass of 49,698 daltons for the electrophoretically homogeneous fragment. Twenty-five amino acid residues were sequenced directly from the N-terminus of Rta, which allowed the location of the domain in the polypeptide chain of the subunit. Physicochemical parameters were determined by absorption and fluorescence spectroscopy and circular dichroism. Comparison with the respective parameters of the whole Rapana hemocyanin showed that the polypeptide backbone folding, binuclear active site and capability of oxygen binding of the isolated functional unit are identical to those of the native hemocyanin. Comparison of N-terminal sequences of functional units from different molluskan hemocyanins and located at different positions revealed some evolutionary relationships.     

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.     

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.     

Quantum mechanical analysis of oxygenated and deoxygenated states of hemocyanin: theoretical clues for a plausible allosteric model of oxygen binding.

Abstract: In this work with ab initio computations, we describe relevant interactions between protein active sites and ligands, using as a test case arthropod hemocyanins. A computational analysis of models corresponding to the oxygenated and deoxygenated forms of the hemocyanin active site is performed using the Density Functional Theory approach. We characterize the electron density distribution of the binding site with and without bound oxygen in relation to the geometry, which stems out of the crystals of three hemocyanin proteins, namely the oxygenated form from the horseshoe crab Limulus polyphemus, and the deoxygenated forms, respectively, from the same source and from another arthropod, the spiny lobster Panulirus interruptus. Comparison of the three available crystals indicate structural differences at the oxygen binding site, which cannot be explained only by the presence and absence of the oxygen ligand, since the geometry of the ligand site of the deoxygenated Panulirus hemocyanin is rather similar to that of the oxygenated Limulus protein. This finding was interpreted in the frame of a mechanism of allosteric regulation for oxygen binding. However, the cooperative mechanism, which is experimentally well documented, is only partially supported by crystallographic data, since no oxygenated crystal of Panulirus hemocyanin is presently available. We address the following question: is the local ligand geometry responsible for the difference of the dicopper distance observed in the two deoxygenated forms of hemocyanin or is it necessary to advocate the allosteric regulation of the active site conformations in order to reconcile the different crystal forms? We find that the difference of the dicopper distance between the two deoxygenated hemocyanins is not due to the small differences of ligand geometry found in the crystals and conclude that it must be therefore stabilized by the whole protein tertiary structure.     

Differential regulation of hexameric and dodecameric hemocyanin from A. leptodactylus

The oxygen binding properties of hemocyanins are regulated on a short time scale by effectors such as l-lactate, urate and protons, and on longer time scales by expression of the different types of subunits. For Astacus leptodactylus it was shown previously that acclimation to higher temperatures leads to increased levels of a 6-meric hemocyanin species, whereas at lower temperatures the 12-meric form prevails. Here we show that the temperature dependence of the two forms supports the idea, that the maintenance of high affinity towards oxygen is the driving force for the differential expression of these hemocyanins. Furthermore, the two different types of hemocyanin differ not only in the affinity to oxygen, but also with respect to their interaction with l-lactate: while the 12-meric form displays a normal shift in oxygen affinity upon the addition of l-lactate this allosteric regulation is absent in the 6-meric form. Exclusive binding of l-lactate to the 12-meric form was supported by isothermal titration calorimetry. These results indicate that l-lactate binds either at the interface between the two hexamers or at subunit α′ which is responsible for the formation of the 12-mers and is not present in the 6-meric form. Urate has a comparable effect on the oxygen affinity of 6-meric and 12-meric forms and also binds to a similar extent to the oxygenated state as determined by isothermal titration calorimetry. Thus, urate and l-lactate do not seem to share the same binding sites. Interestingly, urate binding sites with no allosteric effect seem to exist, which is unusual. This article is part of a Special Issue entitled: Oxygen Binding and Sensing Proteins.     

Putative phenoloxidases in the tunicate<Emphasis Type="Italic"> Ciona intestinalis</Emphasis> and the origin of the arthropod hemocyanin superfamily

In addition to the respiratory copper-containing proteins for which it is named, the arthropod hemocyanin superfamily also includes phenoloxidases and various copperless storage proteins (pseudo-hemocyanins, hexamerins and hexamerin receptors). It had long been assumed that these proteins are restricted to the arthropod phylum. However, in their analysis of the predicted genes in the Ciona intestinalis (Urochordata:Tunicata) genome, Dehal et al. (Science 298:2157–2167) proposed that the sea squirt lacks hemoglobin but uses hemocyanin for oxygen transport. While there are, nevertheless, four hemoglobin genes present in Ciona, we have identified and cloned two cDNA sequences from Ciona that in fact belong to the arthropod hemocyanin superfamily. They encode for proteins of 794 and 775 amino acids, respectively. The amino acids required for oxygen binding and other structural important residues are conserved in these hemocyanin-like proteins. However, phylogenetic analyses and mRNA expression data suggest that the Ciona hemocyanin-like proteins rather act as phenoloxidases, possibly involved in humoral immune response. Nevertheless, the putative Ciona phenoloxidases demonstrate that the hemocyanin superfamily emerged before the Protostomia and Deuterostomia diverged and allow for the first time the unequivocal rooting of the arthropod hemocyanins and related proteins. Phylogenetic analyses using neighbor-joining and Bayesian methods show that the phenoloxidases form the most ancient branch of the arthropod proteins, supporting the idea that respiratory hemocyanins evolved from ancestors with an enzymatic function. The hemocyanins evolved in agreement with the expected phylogeny of the Arthropoda, with the Onychophora diverged first, followed by the Chelicerata and Pancrustacea. The position of the myriapod hemocyanins is not resolved.Abbreviations EST expressed sequence tags Communicated by G. Heldmaier     

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.     

Variable Subunit Contact and Cooperativity of Hemoglobins

Tertiary structures of proteins are conserved better than their primary structures during evolution. Quaternary structures or subunit organizations, however, are not always conserved. A typical case is found in hemoglobin family. Although human, Scapharca, and Urechis have tetrameric hemoglobins, their subunit contacts are completely different from each other. We report here that only one or two amino acid replacements are enough to create a new contact between subunits. Such a small number of chance replacements is expected during the evolution of hemoglobins. This result explains why different modes of subunit interaction evolved in animal hemoglobins. In contrast, certain interactions between subunits are necessary for cooperative oxygen binding. Cooperative oxygen binding is observed often in dimeric and tetrameric hemoglobins. Conformational change of a subunit induced by the first oxygen binding to the heme group is transmitted through the subunit contacts and increases the affinity of the second oxygen. The tetrameric hemoglobins from humans and Scapharca have cooperativity in spite of their different modes of subunit contact, but the one from Urechis does not. The relationship between cooperativity and the mode of subunit contacts is not clear. We compared the atomic interactions at the subunit contact surface of cooperative and non-cooperative tetrameric hemoglobins. We show that heme-contact modules M3–M6 play a key role in the subunit contacts responsible for cooperativity. A module was defined as a contiguous peptide segment having compact conformation and its average length is about 15 amino acid residues. We show that the cooperative hemoglobins have interactins involving at least two pairs of modules among the four heme-contact modules at subunit contact. Received: 12 January 2001 / Accepted: 3 April 2001     

Neurospora tyrosinase: structural,spectroscopic and catalytic properties

Summary Tyrosinase is a copper containing monooxygenase catalyzing the formation of melanin pigments and other polyphenolic compounds from various phenols. This review deals with the recent progress on the molecular structure of the enzyme from Neurospora crassa and the unique features of the binuclear active site copper complex involved in the activation of molecular oxygen and the binding of substrates. The results of the spectroscopic properties of Neurospora tyrosinase will also be discussed in the light of the structural similarity of the copper complex in the oxygen binding hemocyanins.     

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.     

Nautilus pompilius hemocyanin: 9 A cryo-EM structure and molecular model reveal the subunit pathway and the interfaces between the 70 functional units

Hemocyanins are giant extracellular oxygen carriers in the hemolymph of many molluscs. Nautilus pompilius (Cephalopoda) hemocyanin is a cylindrical decamer of a 350 kDa polypeptide subunit that in turn is a “pearl-chain” of seven different functional units (FU-a to FU-g). Each globular FU has a binuclear copper centre that reversibly binds one O₂ molecule, and the 70-FU decamer is a highly allosteric protein. Its primary structure and an 11 Å cryo-electron microscopy (cryo-EM) structure have recently been determined, and the crystal structures of two related FU types are available in the databanks. However, in molluscan hemocyanin, the precise subunit pathway within the decamer, the inter-FU interfaces, and the allosteric unit are still obscure, but this knowledge is crucial to understand assembly and allosterism of these proteins. Here we present the cryo-EM structure of Nautilus hemocyanin at 9.1 Å resolution (FSC_1/2-bit criterion), and its molecular model obtained by rigid-body fitting of the individual FUs. In this model we identified the subunit dimer, the subunit pathway, and 15 types of inter-FU interface. Four interface types correspond to the association mode of the two protomers in the published Octopus FU-g crystal. Other interfaces explain previously described morphological structures such as the fenestrated wall (which shows D5 symmetry), the three horizontal wall tiers, the major and minor grooves, the anchor structure and the internal collar (which unexpectedly has C5 symmetry). Moreover, the potential calcium/magnesium and N-glycan binding sites have emerged. Many interfaces have amino acid constellations that might transfer allosteric interaction between FUs. From their topologies we propose that the prime allosteric unit is the oblique segment between major and minor groove, consisting of seven FUs from two different subunits. Thus, the 9 Å structure of Nautilus hemocyanin provides fundamentally new insight into the architecture and function of molluscan hemocyanins.     

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.     

Built-in co-operativity of oxygen binding by arthropod hemocyanins

Oxygen binding by arthropod hemocyanin from the scorpion Leirus quinquestriatus and the crabs Telphusa fluviatilis and Ocypoda cursor was studied in Ca²⁺, Mg²⁺-free solutions. The binding was found to be co-operative in all three cases. Our results and a re-examination of the literature lead us to conclude that co-operative oxygen binding is a built-in feature common to arthropod hemocyanins, distinguishing them from mollusc hemocyanins where co-operativity is conditional upon the presence of Ca²⁺ or Mg²⁺.     

Oxygen affinities of maternal and fetal hemoglobins of the viviparous seaperch,Embiotoca lateralis

Summary The striped seaperch,Embiotoca lateralis, is a viviparous teleost. The hemoglobins of adult and fetal seaperch are both tetrameric proteins which in their native state appear to be indistinguishable from one another by electrophoresis. However, differences in the subunit structure of maternal versus fetal seaperch hemoglobins can be detected by electrophoresis in urea with a reducing agent, amino acid analyses and peptide maps of the respective proteins. Furthermore, stripped adult and fetal hemoglobins have different oxygen binding affinities at all pH's tested between pH 6.8 and 8.0. Mid-gestation fetal hemoglobin has a higher oxygen affinity than late-gestation fetal hemoglobin which in turn has a higher affinity than that of the adult hemoglobin. All three stripped hemoglobins show a similar Bohr effect (=–0.9). These data suggest that a difference in oxygen affinities exists in vivo between the adult and fetal blood of the seaperchEmbiotoca lateralis and that it can be explained in part by the presence of a structurally unique fetal hemoglobin. This report is the first to provide evidence for a mechanism of maternal-fetal oxygen transfer in a teleost fish.Abbreviations A adult - LF late-gestation fetal - MF mid-gestation fetal (hemoglobins)     

Structure of hemocyanin subunit CaeSS2 of the crustacean Mediterranean crab Carcinus aestuarii

Arthropodan hemocyanins are giant respiratory proteins responsible for oxygen transport. They exhibit unusual assemblies of up to 48 structural subunits. Hemocyanin from Carcinus aestuarii contains three major and two minor structural subunits. Here, we reveal the primary structure of the gamma-type 75 kDa subunit of Carcinus aestuarii hemocyanin, CaeSS2, and combine structure-based sequence alignments, tryptophan fluorescence, and glycosylation analyses to provide insights into the structural and functional organisation of CaeSS2. We identify three functional domains and three conserved histidine residues that most likely participate in the formation of the copper active site in domain 2. Oxygen-binding ability of Carcinus aestuarii Hc and its structural subunit 2 was studied using CD and fluorescence spectroscopy. Removing the copper dioxygen system from the active site led to a decrease of the melting temperature, which can be explained by a stabilizing effect of the binding metal ion. To study the quenching effect of the active site copper ions in hemocyanins, the copper complex Cu(II)(PuPhPy)2+ was used, which appears as a very strong quencher of the tryptophan emission. Furthermore, the structural localization was clarified and found to explain the observed fluorescence behavior of the protein. Sugar analysis reveals that CaeSS2 is glycosylated, and oligosaccharide chains connected to three O-glycosylated and one N-glycosylated sites were found.     

Reaction of carbon monoxide with hemocyanin: Stereochemical effects of a non-bridging ligand

The carbon monoxide binding equilibria and kinetics of a number of molluscan and arthropodal hemocyanins have been investigated employing the visible luminescence of the carbon monoxide-copper complex.Proteins from both phyla, in oligomeric and monomeric form, bind carbon monoxide non-co-operatively; the reaction is largely enthalpy driven is associated with a small unfavourable entropy change.Molluscan hemocyanins display a carbon monoxide affinity (p₅₀ = 1 to 10mm Hg) higher than that of arthropodal hemocyanins (p₅₀ = 100 to 700mm Hg), and only Panulirus interruptus hemocyanin, among those studied here, exhibits a small Bohr effect. The observed differences in equilibrium constant are kinetically reflected in differences in the carbon monoxide dissociation rate constant, which ranges from 20 to 70 s^?1 for molluscan hemocyanins and from 200 to 9000 s^?1 for arthropodal hemocyanins; on the other hand the differences in the combination rate constants between the two phyla are considerably smaller. A comparison of the equilibrium and kinetic results shows some discrepancies between the two sets of data, suggesting that carbon monoxide binding may be governed by a complex mechanism.The correlation between the ligand binding properties and the stereochemistry of the active site is discussed in the light of the knowledge that, while oxygen is bound to both copper atoms in a site, carbon monoxide is a “non-bridging” ligand, being bound to only one of the metals.     

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)