SAXS investigation on the temperature dependence of the conformation of Carcinus aestuarii 5S hemocyanin subunit

Structure-based modelling of hemocyanin allergenicity in squid and its response to high hydrostatic pressure

The secondary, tertiary, and quaternary structures of squid hemocyanin (Hc) were characterised, and the relationship between Hc structure and allergenicity responses to high hydrostatic pressure (HHP) was modelled. The Hc allergenicity varied with its protein structure. Electrophoresis analysis revealed that HHP treatment significantly decreased the band intensity of Hc when increasing pressure from 200 and 400 MPa to 600 MPa. The protein structure analysis of squid Hc showed that while HHP treatment decreased the α-helix content, free sulfhydryl content, and R_g, it increased the random coil content, surface hydrophobicity index (Ho), Guinier aggregation number (〈N_agg〉_G) and average aggregation number (〈N_agg〉_Q). The α-helix and random coil contents of the 600 MPa treated samples were 23.67% and 37.54%, respectively, compared to 32.37% and 32.02% in the control, respectively. HHP treatment decreased the IgE and IgG-binding capacities, indicating a significant decrease in the allergenicity (P< 0.05) of squid Hc. This study provided meaningful information of applying HHP to reduce allergenicity, and explained the responses of Hc protein structure to HHP for lowering the allergenicity of squid.

Seasonal and gender-related differences in morphometric features and cellular and biochemical parameters of Carcinus aestuarii from the Lagoon of Venice

In this study, the seasonal variations in the morphometric features and in the cellular and biochemical parameters of the haemolymph were investigated in both male and female crabs (Carcinus aestuarii). Crabs were seasonally (November 2010-August 2011) collected from the Lagoon of Venice, and the moult stage, weight, width and length of the carapace, and width and length of the bigger chela were evaluated. In addition, the total haemocyte count (THC), haemocyte diameter and volume, haemolymph glucose and total protein levels, and haemolymph phenoloxidase (PO) and N-acetyl-β-glucosaminidase (NAG) activities were measured. The results demonstrated that the collected crabs were all in the intermoult stage and that the males were bigger than the females. A two-way ANOVA revealed a significant effect of season on the THC and the haemocyte volume and a significant influence of gender on the haemocyte diameter. Season and gender significantly affected the haemolymph glucose concentration, whereas haemolymph protein levels were dependent only on the season. In addition, both season and gender significantly influenced the PO and NAG activities in the haemolymph. Overall, the results demonstrated that crab morphometric features as well as haemolymph cellular and biochemical parameters varied markedly as a function of both season and gender.

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.

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.

Guanidinium chloride induced unfolding of a hemocyanin subunit from Carcinus aestuarii. I. Apo form

The effects of guanidinium chloride (GuHCl) on the stability of the apo form of the 5S non-reassociating subunit of hemocyanin from the crab Carcinus aestuarii (apo-CaeSS2) were investigated, using a variety of optical spectroscopy techniques (light scattering (LS), fluorescence (IF and EF) and circular dichroism (CD)). The fluorescence of 8-anilino-1-naphtalene sulphonate (ANS) was strongly enhanced in the presence of apo-CaeSS2, in contrast to holo-CaeSS2, suggesting the formation of a molten globule (MG)-like state, consequent to the removal of the two copper ions from the holo subunit. Other evidences, favouring the presence of this state in apo-CaeSS2, derive from an enhanced quenching of intrinsic fluorescence (IF) by acrylamide, a higher sensibility towards aggregation and a higher IF with respect to deoxy holo-CaeSS2. Aggregation of apo-CaeSS2 below 1.2 M GuHCl was detected by LS, suggesting the formation of an aggregation-prone intermediate, called I1. Due to this effect, fluorescence and CD data could only be collected above that denaturant concentration. Both IF (protein) and EF (ANS) fluorescence data were best fitted by a two-state cooperative transition, occurring between the intermediate I1 and the unfolded state U, with C(1/2) 1.6-1.7 M. A similar two-state transition, with a slightly higher C(1/2) value (1.9 M), was also inferred from far-UV CD data, suggesting the possible formation of another intermediate. Partial refolding of apo-CaeSS2 by dilution was found to occur above 1.2 M GuHCl, i.e. up to the level of I1, since at lower denaturant concentration protein aggregation took place, as also observed in unfolding. All thermodynamic parameters, derived from data above 1.2 M GuHCl, are therefore referred to transitions between intermediate and unfolded states only. Unfolding kinetics, followed by fluorescence stopped-flow, was biphasic in the whole GuHCl range investigated (3-5 M), suggesting the formation of a transient intermediate, possibly related to that observed under equilibrium conditions.

Guanidinium chloride induced unfolding of a hemocyanin subunit from Carcinus aestuarii. II. Holo form

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.

Low-resolution molecular structures of isolated functional units from arthropodan and molluscan hemocyanin

Synchrotron x-ray scattering measurements were performed on dilute solutions of the purified hemocyanin subunit (Bsin1) from scorpion (Buthus sindicus) and the N-terminal functional unit (Rta) from a marine snail (Rapana thomasiana). The model-independent approach based on spherical harmonics was applied to calculate the molecular envelopes directly from the scattering profiles. Their molecular shapes in solution could be restored at 2-nm resolution. We show that these units represent stable, globular building blocks of the two hemocyanin families and emphasize their conformational differences on a subunit level. Because no crystallographic or electron microscopy data are available for isolated functional units, this study provides for the first time structural information for isolated, monomeric functional subunits from both hemocyanin families. This has been made possible through the use of low protein concentrations (< or = 1 mg/ml). The observed structural differences may offer advantages in building very different overall molecular architectures of hemocyanin by the two phyla.