Paolo Di Muro

Structural properties of Rapana thomasiana grosse hemocyanin: Isolation, characterization and N-terminal amino acid sequence of two different dissociation products

1. The native Rapana thomasiana grosse hemocyanin is dissociated under mild conditions and fractionated into two dissociation products, RHSS1 and RHSS2, with an apparent molecular mass of approximately 250 and approximately 450 kDa, respectively. The two species are present in approximately equivalent amounts. SDS-PAGE analysis reveals that the latter component is a dimer of approximately 250 kDa polypeptide chains. 2. The amino acid compositions, as well as some spectroscopic properties of RHSS1, are very similar to those of RHSS2. After dissociation under mild conditions of the native hemocyanin both species preserve their capability of binding reversibly molecular oxygen. 3. RHSS1 and RHSS2 are sequenced directly from the amino-terminus for 15 and 20 steps, respectively. These parts of the two polypeptide chains are highly homologous but with microheterogeneity associated with some positions. They also exhibit high homology with the N-terminal region of subunits or functional domains of other gastropod Hcs.

A key structural role for active site type 3 copper ions in human ceruloplasmin.

Human ceruloplasmin is a copper containing serum glycoprotein with multiple functions. The crystal structure shows that its six domains are arranged in three pairs with a pseudo-ternary axis. Both the holo and apo forms of human ceruloplasmin were studied by size exclusion chromatography and small angle x-ray scattering in solution. The experimental curve of the holo form displays conspicuous differences with the scattering pattern calculated from the crystal structure. Once the carbohydrate chains and flexible loops not visible in the crystal are accounted for, remaining discrepancies suggest that the central pair of domains may move as a whole with respect to the rest of the molecule. The quasisymmetrical crystal structure therefore appears to be stabilized by crystal packing forces. Upon copper removal, the scattering pattern of human ceruloplasmin exhibits very large differences with that of the holoprotein, which are interpreted in terms of essentially preserved domains freely moving in solution around flexible linkers and exploring an ensemble of open conformations. This model, which is supported by the analysis of domain interfaces, provides a structural explanation for the differences in copper reincorporation into the apoprotein and activity recovery between human ceruloplasmin and two other multicopper oxidases, ascorbate oxidase and laccase. Our results demonstrate that, beyond catalytic activity, the three-copper cluster at the N-terminal-C-terminal interface plays a crucial role in the structural stability of human ceruloplasmin.

Quaternary structure and functional properties of Penaeus monodon hemocyanin

The hemocyanin of the tiger shrimp, Penaeus monodon, was investigated with respect to stability and oxygen binding. While hexamers occur as a major component, dodecamers and traces of higher aggregates are also found. Both the hexamers and dodecamers were found to be extremely stable against dissociation at high pH, independently of the presence of calcium ions, in contrast to the known crustacean hemocyanins. This could be caused by only a few additional noncovalent interactions between amino acids located at the subunit–subunit interfaces. Based on X‐ray structures and sequence alignments of related hemocyanins, the particular amino acids are identified. At all pH values, the p50 and Bohr coefficients of the hexamers are twice as high as those of dodecamers. While the oxygen binding of hexamers from crustaceans can normally be described by a simple two‐state model, an additional conformational state is needed to describe the oxygen‐binding behaviour of Penaeus monodon hemocyanin within the pH range of 7.0 to 8.5. The dodecamers bind oxygen according to the nested Monod–Whyman–Changeaux (MWC) model, as observed for the same aggregation states of other hemocyanins. The oxygen‐binding properties of both the hexameric and dodecameric hemocyanins guarantee an efficient supply of the animal with oxygen, with respect to the ratio between their concentrations. It seems that under normoxic conditions, hexamers play the major role. Under hypoxic conditions, the hexamers are expected not to be completely loaded with oxygen. Here, the dodecamers are supposed to be responsible for the oxygen supply.

Respiration rate and oxy-regulatory capacity in cold stenothermal chironomids.

The effects of temperature and oxygen saturation on the respiration rate of two cold stenothermal chironomids, Diamesa insignipes and Pseudodiamesa branickii were investigated. Fourth instar larvae were collected in winter in a glacio-rhithral stream (1300 m a.s.l., Alps, NE-Italy) and their respiration rate was measured with a Clarks electrode in the range 0-14 degrees C. The respiration rate was significantly higher in D. insignipes than in P. branickii at low temperatures (<or=4 degrees C), higher in P. branickii between 8 and 12 degrees C and comparable at 14 degrees C. Higher values of R (regulation value), R(25%) (respiration rate at 25% oxygen saturation) and b(1)/b(2) (slope ratio in piecewise linear regression), and lower values of P(c) (critical pressure) and I (initial decrease) were recorded in P. branickii than in D. insignipes. These values are compatible with oxy-regulatory behaviour in P. branickii, whereas D. insignipes appeared to be almost an oxy-conformer. On the basis of this autoecological information, new implications regarding survival of species from cold, high altitude habitats under changing climatic conditions are made.

Guanidinium chloride induced unfolding of a hemocyanin subunit from Carcinus aestuarii

The effects of guanidinium hydrochloride (GuHCl) on the functional and structural properties of a 75-kDa, functionally active hemocyanin (Hc) subunit isolated from the crab Carcinus aestuarii (holo-CaeSS2) were investigated. The holo form of the protein contains two copper ions in the active site and is capable of reversibly binding dioxygen. The present results are compared with those previously described for the corresponding functionally inactive subunit (apo-CaeSS2), devoid of the two active site copper ions (accompanying paper [R. Favilla, M. Goldoni, A. Mazzini, M. Beltramini, P. Di Muro, B. Salvato, paper published in this issue]). As with apo-CaeSS2, both equilibrium and kinetic unfolding measurements were carried out using light scattering (LS), circular dichroism, intrinsic and extrinsic fluorescence (IF and EF, respectively). In addition here, absorbance spectroscopy was exploited to evaluate oxygen binding by holo-CaeSS2. These data were combined with those relative to the protein copper content to obtain information on the stability of the active site as a function of denaturant concentration. The different techniques used revealed several unfolding transitions. At GuHCl<1 M, an appreciable increase of LS intensity was observed, about an order of magnitude lower than with apo-CaeSS2, suggesting some reversible protein aggregation. A first cooperative transition as a function of GuHCl was detected as an increase of intensity of the protein IF (C(1/2)=1 M), followed by a second transition, characterised by a small intensity decrease and a red shift of the emission maximum (C(1/2)=1.4 M). Cooperative transitions with C(1/2) values near 1.4 M GuHCl were also detected by following the decrement of: (a) EF intensity of anilino-1-naphtalenesulphonate (ANS) bound to the protein; (b) absorbance at 340 nm, typical of oxy holo-CaeSS2; (c) copper-to-protein stoichiometry. A transition at higher GuHCl (C(1/2)=1.8 M) was also observed by far UV circular dichroism (far UV CD) and related to global unfolding. Unfolding kinetics was also studied using the fluorescence stopped-flow technique. All traces were best fitted by a sum of three or four exponential terms, depending on GuHCl concentration. A comprehensive unfolding model is proposed, which accounts for most of the complex behaviour of this protein subunit, including oxy and deoxy native and aggregation-prone intermediates, a highly fluorescent intermediate, molten globule-like apo and unfolded species.

Molecular Basis of the Bohr Effect in Arthropod Hemocyanin

Flash photolysis and K-edge x-ray absorption spectroscopy (XAS) were used to investigate the functional and structural effects of pH on the oxygen affinity of three homologous arthropod hemocyanins (Hcs). Flash photolysis measurements showed that the well-characterized pH dependence of oxygen affinity (Bohr effect) is attributable to changes in the oxygen binding rate constant, kon, rather than changes in koff. In parallel, coordination geometry of copper in Hc was evaluated as a function of pH by XAS. It was found that the geometry of copper in the oxygenated protein is unchanged at all pH values investigated, while significant changes were observed for the deoxygenated protein as a function of pH. The interpretation of these changes was based on previously described correlations between spectral lineshape and coordination geometry obtained for model compounds of known structure ( Blackburn, N. J., Strange, R. W., Reedijk, J., Volbeda, A., Farooq, A., Karlin, K. D., and Zubieta, J. (1989) Inorg. Chem., 28, 1349-1357 ). A pH-dependent change in the geometry of cuprous copper in the active site of deoxyHc, from pseudotetrahedral toward trigonal was assigned from the observed intensity dependence of the 1s → 4pz transition in x-ray absorption near edge structure (XANES) spectra. The structural alteration correlated well with increase in oxygen affinity at alkaline pH determined in flash photolysis experiments. These results suggest that the oxygen binding rate in deoxyHc depends on the coordination geometry of Cu(I) and suggest a structural origin for the Bohr effect in arthropod Hcs.

Solution structures of 2 6-meric and 4 6-meric hemocyanins of crustaceans Carcinus aestuarii, Squilla mantis and Upogebia pusilla

Arthropod hemocyanins (Hcs) are a family of large, high molecular mass, extracellular oxygen transport proteins. They form oligomeric quaternary structures based on different arrangements of a basic 6×75 kDa hexameric unit. Their complex quaternary structures present binding sites for allosteric effectors and regulate the oxygen binding process in a cooperative manner. In order to describe the functional regulation of arthropod Hcs, a detailed description of their quaternary structure is necessary. We have utilized small angle X-ray scattering to characterize the structure of three arthropod Hcs in unperturbed conditions. Two different levels of complexity are evaluated: for the 2×6-meric case, we analyzed the Hcs of the portunid crab Carcinus aestuarii and stomatopod Squilla mantis, while in the case of 4×6-meric structures, we studied the Hc of the thalassinid shrimp Upogebia pusilla. While C. aestuarii Hc presented a structure comparable to other 2×6-meric crustacean Hcs, S. mantis Hc shows a peculiar and quite unique arrangement of its building blocks, resembling a substructure of giant Hcs found among cheliceratans. For U. pusilla, the arrangement of its subunits is described as tetrahedral, in contrast to the more common square planar 4×6-meric structure found in other arthropod Hcs.

The reaction of Octopus vulgaris hemocyanin with exogenous ligands: proposal of an allosteric model for the binding of cyanide and thiourea to the 11 S subunit

Octopus vulgaris hemocyanin in 11 S aggregation state binds oxygen following a noncooperative oxygen saturation curve with Hill coefficient n = 1. Under the same conditions the equilibrium and kinetics of the reaction with cyanide and other ligands are indicative of an anticooperative behavior displaying different characteristics for the different ligands. The data are consistent with an induced-fit type allosteric model which assumes for the 11 S subunit of O. vulgaris hemocyanin an annular structure made up by five identical domains each containing one binding site whose reactivity is near-neighbor regulated.

Synchrotron SAXS studies on the structural stability of Carcinus aestuarii hemocyanin in solution.

The effect of GuHCl and of NaCl on the structural properties of the hemocyanin (Hc) from Carcinus aestuarii has been studied by small angle x-ray scattering (SAXS) using synchrotron radiation. SAXS data collected as a function of perturbant concentration have been used to analyze conformational states of hexameric holo and apoHc as well as the holo and apoforms of the monomeric subunit CaeSS2. In the case of the holoprotein in GuHCl, two concentration domains were identified: at lower concentration, the perturbant induces aggregation of Hc molecules, whereas at higher concentration the aggregates dissociate with concomitant denaturation of the protein. In contrast, with apoHc the denaturation occurs at rather low GuHCl, pointing to an important effect of the active site bound copper for the stabilization of Hc tertiary structure. The effects of NaCl are similar to those of GuHCl as far as CaeSS2 is concerned, namely oligomerization precedes denaturation, whereas in the case of the hexameric form no aggregation occurs. To improve data analysis, on the basis of the current models for Hc monomers and oligomers, the fraction of each aggregation state and/or unfolded protein has been determined by fitting experimental SAXS curves with form factors calculated from Monte Carlo methods. In addition, a global analysis has been carried out on the basis of a thermodynamic model involving an equilibrium between a monomer in a nativelike and denatured form as well as a class of equilibria among the monomer and other aggregates.

Structural Basis of the Lactate-dependent Allosteric Regulation of Oxygen Binding in Arthropod Hemocyanin

Hemocyanin (Hc) is an oxygen carrier protein in which oxygen binding is regulated by allosteric effectors such as H+ and l-lactate. Isothermal titration calorimetric measurements showed that l-lactate binds to dodecameric and heterohexameric Hc and to the CaeSS3 homohexamer but not to the CaeSS2 monomer. The binding of lactate caused no change in the optical absorption and x-ray absorption spectra of either oxy- or deoxy-Hc, suggesting that no structural rearrangement of the active site occurred. At pH 6.5, the oxygen binding rate constant kobs obtained by flash photolysis showed a significant increase upon addition of l-lactate, whereas l-lactate addition had little effect at pH 8.3. Lactate binding caused a concentration-dependent shift in the interhexameric distances at pH 6.5 based on small angle x-ray scattering measurements. These results show that l-lactate affects oxygen affinity at pH 6.5 by modulating the global structure of Hc without affecting its binuclear copper center (the active site). In contrast to this, the active site structure of deoxy-Hc is affected by changes in pH (Hirota, S., Kawahara, T., Beltramini, M., Di Muro, P., Magliozzo, R. S., Peisach, J., Powers, L. S., Tanaka, N., Nagao, S., and Bubacco, L. (2008) J. Biol. Chem. 283, 31941–31948). Upon addiction of lactate, the kinetic behavior of oxygen rebinding for Hc was heterogeneous under low oxygen concentrations at pH 6.5 due to changes in the T and R state populations, and the equilibrium was found to shift from the T toward the R state with addition of lactate.