Cytosolic carbonic anhydrase in the Gulf toadfish is important for tolerance to hypersalinity.

Carbonic anhydrase (CA) is a ubiquitous enzyme involved in acid-base regulation and osmoregulation. Many studies have demonstrated a role for this enzyme in fish osmoregulation in seawater as well as freshwater. However, to date CA responses of marine fish exposed to salinities exceeding seawater (approximately 35 ppt) have not been examined. Consequently, the aim of the present study was to examine CA expression and activity in osmoregulatory tissues of the Gulf Toadfish, Opsanus beta, following transfer to 60 ppt. A gene coding, for CAc of 1827 bp with an open reading frame of 260 amino acids was cloned and showed high expression in all intestinal segments and gills. CAc showed higher expression in posterior intestine and rectum than in anterior and mid intestine and in gills of fish exposed to 60 ppt for up to 4 days. The enzymatic activity, in contrast, was higher in all examined tissues two weeks following transfer to 60 ppt. Comparing early expression and later activity levels of acclimated fish reveals a very different response to hypersalinity among tissues. Results highlight a key role of CAc in osmoregulation especially in distal regions of the intestine; moreover, CAc play a role in the gill in hypersaline environments possibly supporting elevated branchial acid extrusion seen under such conditions.

Unusual oxygen binding behavior of a 24-meric crustacean hemocyanin.

Hemocyanins from Crustacea usually are found as 1x6 or 2x6-meric assemblies. An exception is the hemocyanin isolated from thalassinidean shrimps where the main component is a 24-meric structure. Our analysis of oxygen binding data of the thalassinidean shrimp Upogebia pusilla based on a three-state MWC-model revealed that despite the 24-meric structure the functional properties can be described very well based on the hexamer as allosteric unit. In contrast to the hemocyanins from other thalassinidean shrimps the oxygen affinity of hemocyanin from U. pusilla is increased upon addition of l-lactate. A particular feature of this hemocyanin seems to be that l-lactate already enhances oxygen affinity under resting conditions which possibly compensates the rather low intrinsic affinity observed in absence of l-lactate. The fast rate of oxygen dissociation might indicate that in this hemocyanin a higher cooperativity is less important than a fast response of saturation level to changes in oxygen concentration.

Role of the tertiary structure in the diphenol oxidase activity of Octopus vulgaris hemocyanin.

The functional differences between the oxygen transport protein Hemocyanin and the enzymes Tyrosinase and Catechol oxidase are believed to be governed, at least in part, by the tertiary structure, which differs in these molecules and controls the accessibility of their copper containing active site for substrate(s). Accordingly, Octopus vulgaris Hemocyanin catalyses the o-diphenol oxidation to o-quinone at a very low rate. The crystallographic structure of one of the functional units (called Odg) of O. dofleini Hemocyanin shows two domains, a mainly alpha-helical domain that directly binds the copper ions of the reaction center and a beta-strand domain that precludes access to the active site to ligands bigger than molecular oxygen. In this work, we have first cleaved the whole protein and then purified different oxygen binding functional units from O. vulgaris Hemocyanin. These functional units were used in activity assays with l-DOPA, the paradigmatic substrate for Catechol oxidase. All functional units show a negligible enzymatic activity. The procedure to generate the functional units induces in only one of them a proteolytic cleavage. Amino terminal sequencing and mass spectroscopy of the fragments allow to place the cleavage site between the alpha and beta domains of the functional unit homologous to Odd, in the O. dofleini sequence. An increase, up to three orders of magnitude, of Tyrosinase-like activity was observed when the cleaved Odd-like was incubated with the substrate in the presence of trifluoroethanol or hexafluoroisopropanol.

The molecular heterogeneity of hemocyanin: its role in the adaptive plasticity of Crustacea.

Crustacean hemocyanin (Hc) represents a unique case of molecular heterogeneity among oxygen-carrying proteins. The existence of different genes, encoding single polypeptide chains, constitutes the genetic basis for the inter- and intra-specific polymorphism. In addition, the large number of Hc subunits within crustacean species, together with their flexible expression, provides an efficient intrinsic mechanism of modulation of oxygen transport. This review presents a description and classification of the various aspects of crustacean Hc heterogeneity and defines its role in a perspective of crustacean adaptive physiology.

The molecular heterogeneity of hemocyanin: Structural and functional properties of the 4x6-meric protein of Upogebia pusilla (Crustacea).

The structural properties of the hemocyanin isolated from the Mediterranean mud shrimp, Upogebia pusilla (Decapoda: Thalassinidea), were investigated. Our intent was to make use of the U. pusilla case to perform a structural comparison between crustacean and chelicerate 4x6-meric hemocyanins. The thalassinidean hemocyanin appears similar in size but different in structural organization compared to the chelicerate 4x6-mer. Ultracentrifuge analyses on the purified protein revealed a sedimentation coefficient of 39S, typical of 4x6 hemocyanins. Electron micrographs are in agreement with a model in which four 2x6-meric building blocks are arranged in a tetrahedron-like quaternary structure and not in the quasi-square-planar orientation characteristic of the chelicerate protein. Size-exclusion chromatography-fast protein chromatography analysis showed elevated instability of the protein in absence of divalent ions or at pH values higher than 8.0. This analysis also shows that the dissociation of the U. pusilla 4x6-meric hemocyanin into hexamers occurs without any intermediate 2x6-meric state, in contrast with the dissociation profile of the chelicerate protein exhibiting several dissociation intermediates. The oxygen-binding properties of U. pusilla hemocyanin were studied to disclose possible effects by the typical allosteric effectors that modulate the functional properties of crustacean hemocyanin. A marked Bohr and lactate effect, but no significant influence of urate, on the oxygen affinity of U. pusilla hemocyanin were found.

Copper and zinc dismetabolism in the mouse brain upon chronic cuprizone treatment.

Recent reports describe successful treatment using copper chelation therapy in neurodegenerative animal models. However, the success claimed for chelation therapy in neurodegenerative diseases is still rather controversial. To acquire new information on copper metabolism/homeostasis, we utilized cuprizone, a very sensitive and selective copper-chelating agent with well-known neurotoxic properties, as a relevant chemical model in mice. Upon cuprizone treatment, mice developed a pronounced astrocytosis, with brain oedema and spongiosis characterised by vacuolisations of the neuropil predominantly in the white matter. In addition, cuprizone treatment severely altered copper and zinc homeostasis in the central nervous system (CNS) as well as in all other tissues examined, with increasing metal ion concentrations particularly in the CNS. Concomitant with this increase in the Cu and Zn concentration in the brain, metallothionein-I and -II were also highly immunoreactive in astrocyte, consistent with the astrocytosis and demyelination observed in our and other laboratories.

Contribution of the copper ions in the dinuclear active site to the stability of Carcinus aestuarii hemocyanin.

We have investigated the effect of copper binding on the structural properties of hemocyanin (Hc). To this aim, we have studied the holo- and apo-form of the protein, both in the hexameric and in the monomeric state (CaeSS2 subunit), with experimental approaches that report on the protein aggregation and conformational stability. The results of gel-filtration chromatography and small angle X-ray scattering (SAXS) provide evidence that the hydrodynamic and gyration radius (R(g)) of Hc in the hexameric form only slightly increase upon copper removal, whereas a remarkable enhancement in the R(g) value is observed for the CaeSS2 monomer. CD measurements in the far- and near-UV region indicate that removal of copper only marginally affects the conformation of the hexameric Hc. Instead, copper depletion in the CaeSS2 strongly alters the tertiary structure of the monomer (near-UV CD), even though it is almost inconsequential on the secondary structure content (far-UV CD). These findings are fully consistent with the results of limited proteolysis experiments showing that the hexameric Hc is similarly resistant to proteolysis by trypsin both in the holo- and apo-form. Conversely, the apo-form of CaeSS2 monomer is much more susceptible to proteolytic attack by trypsin than the holo-form. Based on SAXS measurements, the concentration-dependent oligomerization process for apo-CaeSS2 has been analyzed on the basis of a thermodynamic model involving a concentration-dependent equilibrium between a monomer in a native-like and an hexameric aggregate of monomers.

Structural role of the copper ions in the dinuclear active site of Carcinus aestuarii hemocyanin.

In this work we show, by a combination of biochemical and biophysical approaches, that the copper ions bound in the binuclear active site of Carcinus aestuarii hemocyanin play a stabilizing role on the tertiary structure of the protein. Upon removal of copper, the monomeric hemocyanin, but not the hexameric oligomer, undergoes changes at the level of tertiary structure while the secondary structure is almost unaffected. By Small-Angle X-Ray Scattering, supported by gel chromatography measurements, it can be concluded that the apo-monomer, but not the holo form or the hexameric form, undergoes a slow time-dependent oligomerization process.

Comparative analysis of structural properties of Portunid Crab Hemocyanin.

In order to explore the hemocyanin adaptative potential and evolutive dynamics, we have analyzed the structural properties of this oxygen-carrier protein, in some species of portunid Crabs, (Brachyura, Portunida). We have compared the intra- and interspecific subunits patterns, in native and denaturant conditions, to estimate the phenetic relationships and the different stabilities of the protein.

Structural properties, conformational stability and oxygen binding properties of Penaeus monodon hemocyanin.

Hemocyanin sequences allineament shows the presence of highly invariant regions especially in the active site and in the tight intersubunits interaction sites. Comparing the aminoacids in contact regions between monomers is possible to interpret the stability of hexamers.

Resistance to stress and Hc functional modulation in Liocarcinus sp.

This study is included in a project aimed to study the alterations on the structure of the Northern Adriatic Sea ecosystem produced by fishing activity. The indirect or secondary effects of fishery such as the changes of the structure and trophic relationships of the ecosystem are under investigation and we have particularly considered the effects on species such as Liocarcinus depurator that are captured and then rejected because devoid of commercial value. The objective of this study is the Liocarcinus sp. adaptative resistance to stress and the effects of biochemical parameters (allosteric effectors) on Hc functional modulation.

Carbohydrate moieties of molluscan Rapana venosa hemocyanin.

Using Zn2+ ions as new method, several FUs have been isolated from molluscan Hc Rapana venosa without formation of non-functional proteolytic side products. N-terminal sequences of these fragments in comparison with FUS from other gastropodan Hcs show a very high degree of structural identity. Four Fus, purified from enzyme-treated structural subunits RvH1 and RvH2 (RvH1-a, RvH1-f, RvH2-a and RvH2-e) show identical N-terminal sequences compared to fragments isolated after treatment with Zn2+ ions. However, in some cases trypsin cleaves RvH chains at different positions if compared to the Zn2+ treatment. To analyze the oligosaccharide composition of two FUS from the first structural subunit of Rapana Hc, RvH1-a and RvH1-f, several techniques were applied: capillary electrophoresis, MALDI-MS, ESI-MS in combination with glycosidase digestions. On basis of these results and the determined amino acid sequence two N-linkage sites were identified in the FU RvH1-a, but only one in the FU RvH1-f.

Comparison of the X-ray absorption properties of the binuclear active site of molluscan and arthropodan hemocyanins.

The structural characteristics of oxy- and deoxy-hemocyanins have been investigated using X-ray absorption spectroscopy both in the near-edge (XANES) and for the first shell contribution in the EXAFS region. Several arthropodan and molluscan hemocyanins have been studied in order to trace the inter- and intra-phyla differences. The XANES spectra of oxy-hemocyanins of the different species are remarkably similar, consistent with a very strongly conserved co-ordination geometry of the copper active site. In contrast, small but significant differences are observed between the deoxy-forms of arthropodan and molluscan proteins. In particular, the XANES spectra of deoxy-arthropodan hemocyanins (with the exception of L. polyphemus Hc) show a more intense edge feature at approximately 8983 eV. This difference is tentatively assigned to a more planar geometry of the copper-ligands system in the arthropodan rather than in the molluscan proteins. The first shell analysis of the EXAFS modulation is consistent with the presence of n=3Nepsilon(2) imidazole nitrogens at an average distance of 1.92 +/- 0.03 A from copper in all the deoxy-hemocyanins investigated. Binding of dioxygen results for all hemocyanins in the increase of the number of first shell back-scattering atoms to n=5 with average distances of 1.93 A. Alternatively, by separating the contribution of Nepsilon(2) imidazole nitrogens and of peroxide O-atoms, n=3 ligands at 1.98 +/- 0.03 A and n=2 ligands at 1.87 +/- 0.03 A are found.

Carbohydrate composition of Carcinus aestuarii hemocyanin.

The hemocyanin of the crab Carcinus aestuarii contains a carbohydrate moiety that represents 1.6% of protein mass. This carbohydrate content is higher than that exhibited by other arthropod hemocyanins so far investigated. By combination of FPLC ion exchange chromatography and reverse-phase HPLC, the native oligomeric protein can be resolved into three major and one minor electrophoretically pure fractions that are found to be homogeneous by N-terminal sequencing and correspond to the subunit polypeptide chains. Sugar analysis on the different subunits reveals that the subunit referred to as Ca2 is glycosylated, with a carbohydrate content of 6.3%. By Ca2 trypsin digestion, separation of glycopeptides, and amino acid sequencing, three consensus sequences for O-glycosylation and one for N-glycosylation were found. MALDI-MS was applied for the determination of the molecular masses of the various glycopeptides and peptides after removal of carbohydrates by neuraminidase and alpha-N-acetylgalactosaminidase.

Biochemical responses in a Candida famata strain adapted to high copper concentrations.

A strain of Candida famata adapted to high copper concentration (1.26 mM) and a number of biochemical parameters have been tested, in order to get information on the mechanisms of metal toxicity and detoxification as well as on the metabolic responses to the treatment. The cytoplasmic levels of superoxide dismutase, peroxidase and glutathione were found significantly increased with respect to control cells, in contrast to catalase which is not affected. The activities of enolase and of triosephosphate isomerase are found to decrease as a consequence of the exposure to copper. Statistically significant differences in the content of some aminoacids are found between copper-treated and control cells.

Molecular heterogeneity of the hemocyanin isolated from the king crab Paralithodes camtschaticae.

Native Paralithodes camtschaticae hemocyanin is found as a mixture of dodecamers (24S; 80%) and hexamers (16S; 20%). Removal of Ca2+ ions by dialysis against EDTA-containing buffer solution at neutral pH induces complete dissociation of the 24S form into the 16S form. Under these conditions, a further increase in pH to 9.2 produces complete dissociation of the hexamers into monomers (5S). In both cases, the dissociation process is reversible. The dodecamer (24S) is composed of two different hexamers which can be discriminated only by ion-exchange chromatography in the presence of Ca2+ ions. At alkaline pH and in the presence of EDTA, two major monomeric fractions can be separated by ion-exchange chromatography: ParcI (60%) and ParcII (40%). The reassociation properties of the two fractions were studied separately to define their ability to form hexamers and dodecamers. The oxygen-binding properties of the different aggregation states were investigated. Native hemocyanin binds O2 co-operatively (nH = 3) and with low affinity (p50 approximately 103 Torr). The two monomeric fractions, ParcI and ParcII, are not co-operative and the affinity is twice that of the native protein (p50 approximately 65 and 52 Torr). Oxygen-binding measurements of native hemocyanin carried out at different pH values indicate a strong positive Bohr effect within the pH range 6.5-8.0 and an increase in oxygen affinity at pH below 6.5.

Interaction of lactoferrin with ceruloplasmin.

When added to human blood serum, the iron-binding protein lactoferrin (LF) purified from breast milk interacts with ceruloplasmin (CP), a copper-containing oxidase. Selective binding of LF to CP is evidenced by the results of polyacrylamide gel electrophoresis, immunodiffusion, gel filtration, and affinity chromatography. The molar stoichiometry of CP:LF in the complex is 1:2. Near-uv circular dichroism spectra of the complex showed that neither of the two proteins undergoes major structural perturbations when interacting with its counterpart. K(d) for the CP/LF complex was estimated from Scatchard plot as 1.8 x 10(-6) M. The CP/LF complex is found in various fluids of the human body. Upon injection into rat of human LF, the latter is soon revealed within the CP/LF complex of the blood plasma, from where the human protein is substantially cleared within 5 h.

Low-resolution structure of the proteolytic fragments of the Rapana venosa hemocyanin in solution.

Rapana venosa hemocyanin (Hc) is a giant oxygen-binding protein consisting of different subunits assembled in a hollow cylinder. The polypeptide chain of each subunit is believed to be folded in several oxygen-binding functional units of molecular mass 50 kDa, each containing a binuclear copper active site. Limited proteolysis with alpha-chymotrypsin of native R. venosa hemocyanin allows the separation of three functional proteolytic fragments with molecular masses of approximately 150, 100, and 50 kDa. The functional fragments, purified by combining gel filtration chromatography and ion-exchange FPLC, were analyzed by means of small-angle X-ray scattering (SAXS). The gyration radius of the 50-kDa Rapana Hc fraction (2.4 nm) agrees well with that calculated on the basis of the dimensions determined by X-ray crystallography for one functional unit of Octopus Hc (2.1 nm). Independent shape determination of the 50- and 100-kDa proteolytic fragments yields consistent low-resolution models. Simultaneous fitting of the SAXS data from these fragments provides a higher-resolution model of the 100-kDa species made of two functional units tilted with respect to each other. The model of the 150-kDa proteolytic fragment consistent with the SAXS data displays a linear chain-like aggregation of the 50-kDa functional units. These observations provide valuable information for the reconstruction of the three-dimensional structure of the minimal functional subunit of gastropod hemocyanin in solution. Furthermore, the spatial relationships among the different functional units within the subunit will help in elucidation of the overall quaternary structure of the oligomeric native protein.

Hemocyanin subunit organization of the gastropod Rapana thomasiana.

RtH1 and RtH2, the two hemocyanin isoforms of the prosobranch gastropod Rapana thomasiana, have been purified by anion-exchange chromatography and studied by SDS-PAGE and immunoelectrophoresis. Both subunit types are built up of eight functional units (FUs). Under reducing conditions subunit RtH2 splits into two fragments, RtH2-a-f and RtH2-gh, suggesting the presence of a disulfide bridge between FU2-f and FU2-g. By proteolytic cleavage of the subunits into three-, two-, and single-FU fragments, purification of fragments by HPLC, N-terminal sequencing of the peptides, and crossed-line immunoelectrophoresis, FUs-a-h of RtH2 and FU-a, FU-d, FU-e, and FU-f of RtH1 were identified and correlated to the eight-FUs pattern of immunoelectrophoresis. FU-a, FU-e, and FU-f of RtH1 and RtH2 are very closely related immunologically. RtH1 and RtH2 both correspond immunologically to KLH2, one of the two hemocyanin isoforms of the prosobranch gastropod Megathura crenulata.

Subunits composition and allosteric control in Carcinus aestuarii hemocyanin.

Carcinus aestuarii hemocyanin (Hc) exists in two aggregation forms at pH 7.5 and 20 mM Ca2+: 24S accounting for 90% of total hemocyanin and 16S accounting for 10%. Removal of metal cations by EDTA at neutral pH causes the complete dissociation of 24S hemocyanin into two different 16S. At pH 9.2, 24S hemocyanin dissociates into a pH stable 16S and a 5S component. The 5S component consists of three monomeric fractions named CaeSS1 (10%), CaeSS2 (50%) and CaeSS3 (40%); the latter fraction consisting of two isoforms. The fractions CaeSS1, CaeSS2 and CaeSS3 have been studied as far as their reassociation properties to form hexamers are concerned. We investigated the oxygen-binding properties of the native form (24S), the mixture of the two 16S forms, the pH-stable 16S alone and of purified subunit fractions to define the role of each species on the expression of the allosteric behaviour of the 24S aggregate. The analysis of O2-binding data reveals that 24S-Hc can be well described by the modified Monod Wyman and Changeaux-model (nested MWC-model), while the half-molecules (16S) bind oxygen according to the simple MWC-model. The two hexameric 16S within the dodecameric 24S hemocyanin can be regarded as nested allosteric units. They behave as being functionally coupled in the T-states (tT and rT). In the R-states (tR and rR) the two half-molecules seem to be functionally uncoupled since they have the same values of oxygen binding constants as deduced for isolated 16S hexamers.