C-terminal functional unit of Rapana thomasiana (marine snail, gastropod) hemocyanin isoform RtH1: isolation and characterization

Rapana thomasiana hemocyanin (RtH) is a mixture of two hemocyanin (Hc) isoforms termed RtH1 and RtH2. Both subunit types are built up of eight functional units (FUs). The C-terminal functional unit (RtH1-h) of the Rapana Hc subunit 1 has been isolated by limited trypsinolysis of the subunit polypeptide chain. The oxy- and apo-forms of the unit are characterized by fluorescence spectroscopy. Upon excitation of RtH1-h at 295 or 280 nm, tryptophyl residues buried in the hydrophobic interior of the protein globule determine the fluorescence emission. This is confirmed by quenching experiments with acrylamide, cesium chloride and potassium iodide. The copper-dioxygen system at the binuclear active site quenches the indole emission of the oxy-RtH1-h. The removal of this system increases the fluorescence quantum yield and causes structural rearrangement of the microenvironment of the emitting tryptophyl residues in the apo-RtH1-h. The thermal stability of the apo-RtH1-h is characterized fluorimetrically by the "melting" temperature T(m) (65 degrees C) and by the transition temperature T(m) (83 degrees C) obtained by differential scanning calorimetry for oxy-RtH1-h. The results confirm the role of the copper-dioxygen complex for the stabilization of the Hc structure in solution.     

Isolation and spectroscopic characterization of the structural subunits of keyhole limpet hemocyanin

Keyhole limpet hemocyanin is a respiratory glycoprotein of high molecular weight from the gastropod mollusc Megathura crenulata. Two subunits, KLH1 and KLH2, were isolated using ion exchange chromatography and their physical properties are compared with the parent molecule. The various proteins are characterized by fluorescence spectroscopy, combined with fluorescence quenching studies, using acrylamide, cesium chloride and potassium iodide as tryptophan quenchers. The conformational stability of the native aggregate and its isolated structural subunits are also studied by circular dichroism and fluorescence spectroscopy as a function of temperature, as well as in the presence of guanidinium hydrochloride and urea. The associated subunits in the hemocyanin aggregates increase considerably the melting temperature to 67 degrees C and the free energy of stabilization in water, DeltaG(H(2)O)(D), towards guanidinium hydrochloride is higher for the decamer as compared to the isolated subunits; this difference can be accounted for by the stabilizing effects of intra-subunit interactions exerted within the oligomer. The copper-dioxygen complex at the active site additionally stabilizes the molecule, and removing of the copper ions increases the tryptophan emission and the quantum yield of the fluorescence.     

Anomalous fluorescence of yeast 3-phosphoglucerate kinase.

The 3-phosphoglycerate kinase (EC 2.7.2.3) of yeast which contains two tryptophyl and eight tyrosyl residues per molecule, displayed an unusualy fluorescence emission spectrum with a maximum at 308 nm when excited at 280 nm. The emission peak shifted to 329 nm when excited at 295 nm. We could confirm that it was due to the efficient quenching of tryptophyl fluorescence as well as to the incomplete energy transfer from tyrosyl to tryptophyl residues. The average fluorescence quantum yield of this protein was 0.076 (excitation at 280 nm) and that of tryptophyl residues was 0.046 (excitation at 295 nm). As the pH of the solution was lowered, the fluorescence intensity of phosphoglycerate kinase at 329 nm dramatically increased between pH 5 and 4, while the position of the peak remained unchanged. When denatured in 4 M guanidine hydrochloride, the protein showed two emission peaks, one at 343 nm and the other at 303 nm.     

Fluorimetric and spectrophotometric studies of DPN-linked isocitrate dehydrogenase from bovine heart. Properties of tyrosyl and tryptophyl residues.

The emission maximum of DPN-linked isocitrate dehydrogenase in pH 7.07 buffer is shifted from 317 to 324 nm and fluorescence intensity is decreased when the excitation wave-length is varied from 270 to 290 nm; in 0.2 M KOH, where the fluorescence of tyrosyl residues is almost completely quenched, a further substantial decline in quantum yield of protein fluorescence and a red shift of the emission peak to 339 nm occur. The latter should be due mainly to tryptophyl residues. The enzyme contains 9.4 tyrosyl residues per subunit of molecular weight 42,000 determined spectrophotometrically (295 nm) at pH 13, in good agreement with a tyrosine content of 9.7 by amino acid analysis. No more than 1.1 tyrosyl residues per subunit can be detected up to pH 10.6 at 7 degrees upon prolonged incubation. The increase in absorption at 295 nm with increasing pH is related to loss of enzyme activity and results in a red shift of the emission maximum, and decreased fluorescence intensity. Treatment of the enzyme in a Li+-containing buffer at pH 7.5 with an excess of N-acetylimidazole results in (a) modification of 1.1 tyrosyl residues per subunit, (b) a 30% decrease in enzyme activity, (c) a 6-nm red shift in emission maximum, and (d) a decrease in fluorescence intensity. Manganous DL-isocitrate (1.06 mM) prevents the acetylation of the enzyme. Deacetylation of the O-acetylated enzyme by hydroxylamine completely restores the enzyme activity and reverses the spectral changes. The acetylation studies indicate that the reactive tyrosyl residue does not participate directly in catalysis but may be involved in maintaining the proper conformation of the active enzyme center. A net of 1 of the 2 tryptophyl residues per subunit is perturbed immediately by a number of solvents. This perturbation is not affected by manganous isocitrate, whereas exposure of tyrosyl residues occurs only with time and is prevented by the substrate. The perturbation of the tryptophyl residue is accompanied by a red shift of the fluorescence emission maximum. The more exposed tryptophyl residue may contribute to the energy transfer from protein to nucleotides since the quenching of protein fluorescence upon binding of DPN+, DPNH, or ADP by enzyme results in a blue shift of the emission maximum. Manganous DL-isocitrate (1.06 mM) quenches protein fluorescence by 16% without a shift in emission peak and does not affect the relative extent of fluorescence quenching induced by the nucleotides.     

The role of copper and quaternary structure on the conformational properties of Octopus vulgaris hemocyanin

Some structural properties of Octopus vulgaris hemocyanin have been investigated by fluorescence spectroscopy. The three-dimensional structure of Octopus hemocyanin is remarkably tight, resulting in a deep burial of almost all the tryptophyl residues of the protein. The hemocyanin conformation has been studied in the two main aggregation states (11 S, 50 S) of the protein, and with respect to the presence or absence of copper in the active site. Upon changing the pH of the solution, Octopus hemocyanin in the 50 S aggregation state can assume at least three different conformations. During the transition between each conformation the fluorescence quantum yield changes, but the environment of tryptophans does not change. Dissociation of the protein from 50 S to 11 S strongly enhances its susceptibility toward denaturating agents such as pH or temperature, and modifies the effects of fluorescence quenchers such as acrylamide. Moreover, these effects are more pronounced when copper is removed from the active site. A comparative analysis of the results shows that the subunit-subunit interactions exerted within the 50 S species are more important in the maintenance of the conformational stability than the copper ions present in the active sites. This behavior can be accounted for by the large amount of Ca(II) ions linked to 50 S hemocyanin.     

Structure-based calculation of multi-donor multi-acceptor fluorescence resonance energy transfer in the 4×6-mer tarantula hemocyanin

Hemocyanins are oxygen carriers of arthropods and molluscs. The oxygen is bound between two copper ions, forming a Cu(II)-O₂ ^2–-Cu(II) complex. The oxygenated active sites create two spectroscopic signals indicating the oxygen load of the hemocyanins: first, an absorption band at 340 nm which is due to a ligand-to-metal charge transfer complex, and second, a strong quenching of the intrinsic tryptophan fluorescence, the cause of which has not been definitively identified. We showed for the 4×6-mer hemocyanin of the tarantula Eurypelma californicum that the fluorescence quenching of oxygenated hemocyanin is caused exclusively by fluorescence resonance energy transfer (FRET). The tarantula hemocyanin consists of 24 subunits containing 148 tryptophans acting as donors and 24 active sites as acceptors. The donor–acceptor distances are determined on the basis of a closely related crystal structure of the horseshoe crab Limulus polyphemus hemocyanin subunit II (68–79% homology). Calculation of the expected fluorescence quenching and the measured transfer efficiency coincided extraordinary well, so that the fluorescence quenching of oxygenated tarantula hemocyanin can be completely explained by Förster transfer. This results explain for the first time, on a molecular basis, why fluorescence quantum yield can be used as an intrinsic signal for oxygen load of at least one arthropod hemocyanin, in particular that from the tarantula.     

A spectroscopic analysis of thermal stability of the Chromobacterium viscosum lipase

The thermal stability of the lipase from Chromobacterium viscosum was assessed by deactivation (loss of activity), fluorescence, circular dichroism (CD) and static light scattering (SLS) measurements. Lipase fluorescence emission is dominated by the tryptophyl contribution. An increase in the tyrosyl contribution from 2 to 16% was only observed upon prolonged incubation at 60 degrees C. The effect of temperature on the tryptophyl quantum yield was studied and two activation energies were calculated. Tryptophan residues in the native structure have an activation energy of 1.9 kcal mol(-1) for temperature-dependent non-radiative deactivation of the excited state. A structural change occurs at approximately 66.7 degrees C and the activation energy increases to 10.2 kcal mol(-1). This structural change is not characterized by tryptophan exposure on the surface of the protein. The deactivation and the evolution of structural changes with time after lipase incubation at 60 degrees C were assessed by fluorescence, CD and SLS measurements. CD spectra show that both secondary and tertiary structures remain native-like after incubation at 60 degrees C in spite of the fluorescence changes observed (red-shift from 330 to 336 nm on the trytophyl emission). SLS measurements together with the CD data show that deactivation may be due to protein association between native molecules. Deactivation and the decrease on the fraction of non-associated native lipase evaluated by changes in fluorescence intensity with time, show apparent first order kinetics. According to the rate constants, fluorescence changes precede deactivation pointing to an underestimation of the deactivation. Reactivation upon dilution during the activity assay and substrate-induced reactivation due to lipase interfacial adsorption are possible causes for this underestimation.     

State and reactivity of tryptophyl residues in two bacterial proteases from Sorangium sp.

The state and reactivity of tryptophyl residues in two proteolytic enzymes from Sorangium sp. were investigated by means of the following methods: spectrophotometric oxidation of tryptophans with N-bromosuccinimide, 2-hydroxy-5-nitrobenzyl bromide, and H2O2 in dioxane, optical rotatory dispersion, ultraviolet difference spectrophotometry, solvent perturbation and viscosity measurements. Out of two tryptophyl residues/molecule of alpha-lytic protease, one appears to be completely buried, while the other seems to be exposed. None of these two residues seem to be responsible for the activity of the enzyme. The beta-lytic protease undergoes an irreversible conformational transition between pH 5.0 and 3.5. Out of total four tryptophyl residues/molecule, only one is fully exposed at neutral pH. The other three are gradually exposed in the pH transition region. The degree of exposure and the dimensions of "cavities" shielding tryptophyl residues were estimated. The tryptophyl residues of of beta-lytic protease do not seem to participate in substrate binding or the active site; they are rather one of the determinants of the conformational state of the enzyme.     

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.     

Partial characterization of suberitine,the neurotoxic protein purified from Suberites domuncula

• 1.1. The protein (mol. wt 28.000) consists of four subunits, which are not equivalent as regards the chemical composition, although all of them lack free terminal amino groups.
• 2.2. The single subunits also possess different conformations since both photosensitized oxidation studies and acrylamide-quenching experiments of the protein fluorescence emission show that the three tryptophyl residues have a different accessibility to the aqueous solvent.
• 3.3. Circular dichroism and fluorescence polarization studies suggest that suberitine has a remarkable tight three-dimensional organization: e.g., exposure of suberitine to 6 M urea for several hours is necessary to obtain a general unfolding of the protein molecule.

     

Study of the time-resolved tryptophan fluorescence of crystalline alpha-chymotrypsin

The tryptophan environments in crystalline alpha-chymotrypsin were investigated by fluorescence. The heterogeneous emission from this multitryptophan enzyme was resolved by time-correlated fluorescence spectroscopy. The fluorescence decays at 296-nm laser excitation and various emission wavelengths could be characterized by a triple-exponential function with decay times tau 1 = 150 +/- 50 ps, tau 2 = 1.45 +/- 0.25 ns, and tau 3 = 4.2 +/- 0.4 ns. The corresponding decay-associated emission spectra of the three components had maxima at about 325, 332, and 343 nm. The three decay components in this enzyme can be correlated with X-ray crystallographic data [Birktoft, J.J., & Blow, D.M. (1972) J. Mol. Biol. 68, 187-240]. Inter- and intramolecular tryptophan-tryptophan energy-transfer efficiencies in crystalline alpha-chymotrypsin were computed from the accurately known positions and orientations of all tryptophan residues. These calculations indicate that the three fluorescence decay components in crystalline alpha-chymotrypsin can be assigned to three distinct classes of tryptophyl residues. Because of the different proximity of tryptophan residues to neighboring internal quenching groups, the decay times of the three classes are different. Decay tau 1 can be assigned to Trp-172 and Trp-215 and tau 2 to Trp-51 and Trp-237, while the tryptophyl residues 27, 29, 141, and 207 all have decay time tau 3.     

Time resolved spectroscgpy of tryptopkyl fluorescence of yeast 3-phosphoglycerate kinase

The tryptophyl fluorescence emission of yeast 3-phosphoglycerate kinase decreases from pH 3.9 to pH 7.2 following a normal titration curve with an apparent pK of 4.7. The fluorescence decays have been determined at both extreme pH by photocounting pulse fluorimetry and have been found to vary with the emission wavelength. A quantitative analysis of these results according to a previously described method allows to determine the emission characteristics of the two tryptophan residues present in the protein molecule. At pH 3.9, one of the tryptophan residues is responsible for only 13% of the total fluorescence emission. This first residue has a lifetime τ₁= 0.6 ns and a maximum fluorescence wavelength λ_2max = 332 nm. The second tryptophan residue exhibits two lifetimes τ₂₁= 3.1 ns and τ₂₂= 7.0 ns (λ_2max= 338 nm). In agreement with the attribution of τ₂₁and τ₃₂ to the same tryptophan residue, the ratio β = C₂₁/C₂₂ of the normalized amplitudes is constant along the fluorescence emission spectrum. At pH 7.2, the two tryptophan residues contribute almost equally tc the protein fluorescence. The decay time of tryptophan 1 is 0.4 ns. The other emission parameters are the same as those determined at pH 3.9. We conclude that the fluorescence quenching in the range pH 3.9 to pH 8.0 comes essentially from the formation of a non emitting internal ground state complex between the tryptophan having the longest decay times and a neighbouring protein chemical group. The intrinsic pK of this group and the equilibrium constant of the irternal complex can be estimated. The quenching group is thought to be a carboxylate anion. Excitation transfers between the two tryptophyl residues of the protein molecule appear to have a small efficiency.     

Isolation and partial characterization of the N-terminal functional unit of subunit RtH1 from Rapana thomasiana grosse hemocyanin

Two different structural subunits were identified in Rapana thomasiana hemocyanin: RtH1 and RtH2. RtH1-a is the N-terminal functional unit in the subunit RtH1 and its stability toward temperature and chemical denaturation by guanidinium hydrochloride (Gdn.HCl) are studied and compared with the structural subunit RtH1 and the whole Rapana hemocyanin molecule. The conformational changes, induced by the various treatments, were monitored by CD and fluorescence spectroscopy. The critical temperatures (T(c)) for RtH1-a, the structural subunits and the native Hc, determined by fluorescence spectroscopy, coincide closely with the melting temperatures (T(m)), determined by CD spectroscopy. The free energy of stabilization in water, DeltaG(D)(H(2)O), determined from (Gdn. HCl) denaturation studies, is about two times higher for the structural subunit RtH1 and the whole hemocyanin molecule as compared to the functional unit RtH1-a. The oligomerization between the structural subunits or the eight functional units, assembled in subunit RtH1, has a stabilizing effect on the whole molecule as well as the structural subunits.     

An oxygenation-sensitive dye binding to Carcinus maenas hemocyanin

The interaction of 4',6-diamidino-2-phenylindole (DAPI) with Carcinus maenas hemocyanin has been investigated by steady state fluorescence, dynamic fluorescence and circular dichroism measurements. The dye binds to apohemocyanin (without copper) as well as to oxygenated hemocyanin and to deoxygenated hemocyanin with very similar affinities (kd approximately equal to 1 microM ) and number of binding sites (one per subunit). In contrast, the fluorescence quantum yield enhancement of DAPI bound to oxygenated hemocyanin is nearly 60% lower than that observed for deoxygenated and apo forms. The decrease of fluorescence of the dye bound to deoxygenated hemocyanin is a sigmoidal function of the oxygen partial pressure, specular to that observed by following the absorbance of the copper-oxygen charge transfer band at 340 nm. This result provides preliminary evidence that DAPI may be used as a functional probe to monitor the cooperative binding of oxygen to the protein. The higher fluorescence quantum yield of DAPI bound to either apohemocyanin or deoxygenated protein is characterized by a single fluorescence decay with lifetime of about 3 ns, while with the oxygenated protein two components of about 1 ns and 3.0 ns are observed. This result is interpreted assuming the existence of two rotamers of DAPI in solution (Szabo et al. Photochem. Photobiol. 44 (1986) 143-150) both able to interact with oxygenated hemocyanin but only one to deoxygenated and apo forms. We conclude that the different fluorescence behaviour of the dye induced by the presence of oxygen bound to the protein is probably due to a structural change of hemocyanin in cooperative interaction with oxygen. Furthermore, the interaction is confirmed by the induced negative ellipticity of DAPI bound to apohemocyanin and deoxy-hemocyanin and by the increase of fluorescence anisotropy of DAPI bound to all forms of protein investigated.     

豇豆初生叶多胺氧化酶的分子特性（英文）

从6 d苗龄的豇豆幼苗初生叶中提纯得到的多胺氧化酶是一种糖蛋白,其碳水化合物含量为8.17%.全酶分子量约为146 kD,由分子量为70kD的两个相同亚基组成,每个亚基含1个Cu2+.该酶的等电点为6.2,吸收光谱分别在波长278 nm和500 nm处有1吸收峰.8种蛋白质修饰剂修饰试验并配合底物保护证实酪氨酸、赖氨酸和色氨酸残基及-SH都不是该酶活性中心的必需基团,而组氨酸残基则是活性中心的必需基团.进一步分析部分失活的修饰酶动力学参数的变化得知,组氨酸残基可能处于酶分子的催化部位而非底物的结合部位.     

Thermal unfolding of myosin rod and light meromyosin: circular dichroism and tryptophan fluorescence studies

Rabbit skeletal myosin rod, which is the coiled-coil alpha-helical portion of myosin, contains two tryptophan residues located in the light meromyosin (LMM) portion whose fluorescence contributes 27% to the fluorescence of the entire myosin molecule. The temperature dependence of several fluorescence parameters (quantum yield, spectral position, polarization) of the rod and its LMM portion was compared to the thermal unfolding of the helix measured with circular dichroism. Rod unfolds with three major helix unfolding transitions: at 43, 47, and 53 degrees C, with the 43 and 53 degrees C transitions mainly located in the LMM region and the 47 degrees C transition mainly located in the subfragment 2 region. The fluorescence study showed that the 43 degrees C transition does not involve the tryptophan-containing region and that the 47 degrees C transition produces an intermediate with different fluorescence properties from both the completely helical and fully unfolded states. That is, although the fluorescence of the 47 degrees C intermediate is markedly quenched, the tryptophyl residues do not become appreciably exposed to solvent until the 53 degrees C transition. It is suggested that although the intermediate that is formed in the 47 degrees C transition contains an extensive region which is devoid of alpha-helix, the unfolded region is not appreciably solvated or flexible. It appears to have the properties of a collapsed nonhelical state rather than a classical random coil.     

Interaction of alpha-chymotrypsin with the fluorescent probe 1-anilinonaphthalene-8-sulfonate in solution.

The binding of the fluorescence probe 1-anilinonaphthalene-8-sulfonate (Ans) to alpha-chymotrypsin (alpha-CHT) at pH 3.6 is accompanied by a dramatic enhancement of Ans fluorescence and a shift of the emission maximum to shorter wavelengths. Our study reveals that one Ans molecule binds to alpha-CHT at a site different from either the active site of alpha-CHT or the 2-p-toluidinylnapthalene-6-sulfonate binding site. the binding constant of Ans is about the same (10(4) M-1) at pH 3.6 and 6.4. Nanosecond fluorescence depolarization data indicate that Ans is rigidly bound to alpha-CHT. The fluorescence enhancement due to binding of Ans to alpha-CHT at low pH could be due to binding either to a hydrophobic site or to a site where local dipoles do not relax during the excited-state lifetime of Ans. As the pH is increased, fluorescence intensity of the Ans-alpha-CHT complex decreases appreciably; and the emission maximum shifts to longer wavelengths. The fluorescence decay curves exhibit a corresponding sensitivity to pH. The pH effect on the fluorescence of Ans-alpha-CHT can be interpreted in terms of a pH-dependent equilibrium between alpha-CHT conformers differing in the degree of mobility of polar residues and water molecules at the Ans binding site or structural changes in the Ans binding site.     

The binding of 1-anilino-8-naphthalene sulfonate to the hemocyanin of Octopus vulgaris.

The binding of 1-anilino-8-naphthalene sulfonate (ansyl) to native and copper-free hemocyanin of Octopus vulgaris has been studied in different conditions by measuring the fluorescence properties of the probe in the presence of hemocyanin. Native hemocyanin, either in the oxygenated or in the deoxygenated state, does not bind ansyl. The binding of ansyl with apohemocyanin induces a strong increase (from 0.004 to 0.6 -- 0.7) of the quantum yield and a blue shift from 520 nm to 460 nm of the emission maximum indicating the presence of ansyl binding sites in the protein. Experimental evidence is reported that the binding occurs at the copper-binding site of the protein. The dissociation constants of the ansyl-hemocyanin complexes are equal to about 10(-4) M, i.e. they are of the same order of those obtained with other proteins. The number of binding sites (n) of apohemocyanin for ansyl depends on the conformational state of the protein and ranges from 0.15 -- 0.80 mol/mol protein (Mr 50,000), depending on pH, ionic strength, and urea concentration. A negative interaction between the ansyl binding sites has been suggested.     

3-磷酸甘油醛脱氢酶的胍变性——全位与半位修饰酶的比较

酵母3-磷酸甘油醛脱氢酶在盐酸胍溶液中内源荧光及NAD荧光衍生物的410nm特征荧光发射光谱的变化结果提示,全位及半位修饰羧甲基酶活性部位与NAD共价连接的荧光衍生物的形成,明显受到盐酸胍的干扰,并且前者比后者更为显著.全位及半位修饰光照酶的特征荧光在低胍浓度下较内源荧光降低更为显著,同时伴有最大发射峰先红移后兰移的现象.NAD荧光衍生物的特征荧光在胍溶液中减弱的动力学过程分为快相和慢相,快相一级动力学常数比慢相的大两个数量级,全位及半位修饰酶的特征荧光的减弱快慢相速度常数分别属于同一个数量级.以上结果提示:酶活性部位的构象较整个分子来说更易被变性剂扰乱,柔性强于整个分子;NAD荧光衍生物的形成需要活性部位具有正确的空间几何结构.     

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.