Hemocyanin from the Australian freshwater crayfish Cherax destructor. Electron microscopy of native and reassembled molecules.

Examination and measurement of electron micrographs of negatively stained hemocyanin molecules from Cherax destructor show that the predominant aggregated forms, the 16S and 24S components, are typical structures for arthropod hexamers and dodecamers, respectively. In Cherax hemocyanin the hexamers are formed from the monomeric (Mr congruent to 75,000) subunits, M1 and M2, while the dodecamers contain in addition a dimeric (Mr congruent to 150,000) subunit, M3'. Studies of the composition of solutions of the subunits M1 and m2 to which calcium ions have been added at pH 7.8 show that, under these conditions, reassembly occurs to particles indistinguishable from native hexamers. It is noteworthy that dodecamers are not seen since this confirms the previous suggestion that incorporation of the dimeric subunit in the assembly process is necessary for their formation. The results obtained from Cherax hemocyanin are related to those of previous structural studies of arthropod hemocyanins. In particular, the possible controlling role of certain specific subunits in arthropod hemocyanin oligomers containing more than one kind of subunit is illustrated with a model for the Cherax dodecamer, in which the dimeric subunit is shared between the two halves of the molecule.     

Structural and functional properties of hemocyanin from Cyanagraea praedator, a deep-sea hydrothermal vent crab.

Cyanagraea praedator (Crustacea: Decapoda: Brachyura) is an endemic species of the East Pacific Rise hydrothermal vents, living in the upper part of black smoker chimneys. Because we were seeking species that have made respiratory adaptations to the hydrothermal environment, we looked at Cyanograea hemocyanin (Hc) and determined its quaternary structure and the oxygen-binding properties in relation to temperature, pH, and lactate. C. praedator Hc is composed of dodecamers and hexamers, with dodecamers formed by the perpendicular association of two hexamers. The composition of these polymers was determined by electrophoresis and, for the first time, by electrospray mass spectrometry. Dodecamers and hexamers are composed of six subunits common to the two forms, with molecular mass ranging from 75,008 Da to 75,534 Da. In addition, we found two dodecamer-specific subunits, at 75,419 Da and 75,629 Da. The native hemocyanin possesses a high oxygen affinity (P(50) varies between 4 and 10 Torr at pH 7.5, 15 degrees C) and a large Bohr coefficient (Delta log P(50)/DeltapH approximately -1.8). Oxygen affinity is not affected by lactate or, surprisingly, temperature between 5 degrees C and 35 degrees C (DeltaH = 1.16 kJ/mol(1) 5-35 degrees C). Dialysis of native hemolymph elicited a significant increase in Hc-O(2) affinity (DeltaP(50) = 2.5 Torr at pH 7.5), an effect opposite the usual trend observed for crustacean hemocyanins. In this article these functional properties are interpreted in relation to characteristics of the environment.     

Structural study of Carcinus maenas hemocyanin by native ESI‐MS: Interaction with L‐lactate and divalent cations

The interaction of L ‐lactate and divalent cations with Carcinus maenas hemocyanin has been probed by electrospray ionization mass spectrometry under conditions preserving noncovalent interactions (native ESI‐MS). C. maenas native hemocyanin in the hemolymph occurs mainly as dodecamers and to a lesser extent as hexamers. A progressive acidification with formic acid after alkaline dissociation resulted in the preferential recruitment of the two lightest subunits into light dodecamers, a molecular complex absent from native hemolymph, in addition to regular dodecamers and hexamers. Addition of L ‐lactic acid also induced the recruitment of these subunits, even at alkaline pH. A dodecamer‐specific subunit is needed to enable aggregation over the hexameric state. Experiments with EDTA suggested the existence of different binding sites and association constants for divalent cations within hexameric structures and at the interface between two hexamers. L ‐lactic acid specific interaction with the lightest subunits was not inhibited by removal of the divalent cations. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

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.     

Subunits of Panulirus japonicus hemocyanin. 2. Cooperativity of the homogeneous hexamers

Hexameric hemocyanin from a spiny lobster, Panulirus japonicus, comprises three major subunits (Ib, II and III) and one minor subunit (Ia), as reported in the preceding paper in this journal. It has previously been shown that the O2 equilibria of Panulirus hemocyanin can be described by a concerted model extended to three affinity states [Makino, N. (1986) Eur. J. Biochem. 154, 49-55]. In this study the equilibrium binding of O2 to the reassociated subunits (Ib, II and III) was examined at various pH in the presence or absence of Ca2+ in order to test the applicability of the three-state model to the homogeneous hexamers. The hexameric structure of the reassembled subunits was less stable than that of the native protein under the conditions examined. The model could be fitted to the O2-binding isotherms of the homohexamers composed of the subunits II or III, if the molecular dissociation of the protein was taken into account. It was postulated that the monomeric hemocyanin has the same ligand affinity as that of the hexamer in the intermediate-affinity state (S). The fitting of the model to the O2 binding of the subunit I was unsuccessful mainly because of the low cooperativity of the assembled subunits.     

Structure and function of the hemocyanin from a semi-terrestrial crab,Ocypode quadrata

Summary Structural and functional studies of the hemocyanin of the semi-terrestrial ghost crab,Ocypode quadrata, demonstrate a variety of differences in comparison to the hemocyanin of aquatic crabs. These differences may be related to the terrestrial habit of this crab. Unlike aquatic crabs, the major (56%) blood component is the hexamer; the remaining 44% is dodecamer. The hexamers and dodecamers are not in rapid equilibrium. Electrophoretic analysis of the subunit composition indicates three major components referred to as 1, 3, and 4, and one minor component referred to as component 2. These components, although electrophoretically distinct, are alike immunologically. Components 1 and 2 are essentially absent from purified hexamers, whereas they compose 1/3 of the subunits in dodecamers. These results suggest that they are involved in linking hexamers to form dodecamers, and that two, rather than one, subunits are involved in the bridge. Oxygen-binding measurements show a higher degree of cooperativity, and a much reduced allosteric effect ofl-lactate on the dialyzed hemocyanin as compared to the hemocyanin of aquatic crabs. Exercise rapidly, induces a large drop in hemolymph pH (0.5 units) and a corresponding increase in lactate concentrations (to 10 mM).     

Stabilizing influence of calcium and magnesium ions on the decameric structure of chiton hemocyanins

The stabilizing effects of Ca2+ and Mg2+ ions on the decameric structure of hemocyanins from two representative chitons, Stenoplax conspicua and Mopalia muscosa were investigated by light-scattering molecular weight measurements, ultracentrifugation, absorbance, and circular dichroism methods. The dissociation profiles at any given pH resulting from the decrease in divalent ion concentration, investigated at a fixed protein concentration of 0.1 g.liter-1, could be fitted by a decamer-to-dimer-to monomer scheme of subunit dissociation. The initial decline in the light-scattering molecular weight curves required one or two apparent binding sites per hemocyanin dimer formed as intermediate dissociation product, with apparent dissociation constants (kD,2) for Ca2+ ions of 0.7 to 7 X 10(-4) M, not very different from the value of 2.5 X 10(-4) M obtained by Makino by equilibrium dialysis for the hemocyanin of the opistobranch, Dolabella auricularia. The binding of Mg2+ ion to S. conspicua and M. muscosa hemocyanins appears to be both weaker than the binding of Ca2+ and more pH dependent, with kD,2 values ranging from the 3 X 10(-4) to 4 X 10(-2) M at pH 8.5 to 9.5. The dissociation the decameric hemocyanin species (sedimentation coefficient ca. 60 S) is also observed in the ultracentrifugation with the initial appearance of 18-20 S dimers, followed by a shift in equilibrium to monomeric species of lower sedimentation rates of 11-12 S as the divalent ion concentration is reduced below 1 X 10(-4) M Ca2+ and Mg2+. The dissociation of dimers to monomers in the second step of the reaction is characterized by one or two binding sites per subunit and a somewhat stronger affinity for divalent ions, indicated by apparent dissociation constants (kD,1) of 0.7 X 10(-4) to 3 X 10(-3) M. Circular dichroism and absorbance measurements at 222 and 346 nm suggest no significant changes in the conformation of the hemocyanin subunits produced by the different stages of subunit dissociation.     

The subunit composition of Portunus trituberculatus hemocyanin polymers

The subunit composition of isolated polymeric forms of Portunus trituberculatus hemocyanin were analysed by immunological techniques. The dodecamers contain four monomeric subunits corresponding to subunits I, II, III and IV, whereas the hexamers are devoid of subunit IV. These results suggest that subunit IV is required as a joining piece for the assembly of dodecamers.     

Allosteric control in Limulus polyphemus hemocyanin: functional relevance of interactions between hexamers

Hemocyanin of the horseshoe crab Limulus polyphemus is composed of 48 oxygen-binding subunits, which are arranged in eight hexameric building blocks. Allosteric interactions in this oligomeric protein have been examined by measurement of high-precision oxygen-equilibrium curves, using an automated Imai cell. Several models were compared in numerical analysis of the data. A number of conclusions can be drawn with confidence. (1) Oxygen binding by Limulus hemocyanin cannot satisfactorily be described by the two-state MWC model [Monod, J., Wyman, J., & Changeux, J.P. (1965) J. Mol. Biol. 12, 88-118] for allosteric transitions with either the hexamer or dodecamer as the allosteric unit. (2) Of the models tested, the data sets can be best described by an extended MWC model that allows for an equilibrium, within the 48-subunit ensemble, between cooperative hexamers and cooperative dodecamers. The model invokes T and R states for both hexamers (T6 and R6) and dodecamers (T12 and R12). Allosteric effectors modulate oxygen affinity and cooperativity by affecting the R to T equilibria within hexamers and dodecamers and by shifting the equilibria between hexamers and dodecamers. (3) The fitted model parameters show that under most conditions the intersubunit contacts within T-state hexamers are more constrained than those within T-state dodecamers. (4) The oxygen affinities of the hexameric and dodecameric R states are the same, but under all conditions examined the conformation of the fully oxygenated molecule is that of the dodecameric R state. (5) Between pH 7.4 and pH 8.5 the dodecameric T state has a higher affinity for oxygen than the hexameric T state, allowing for "T-state cooperativity".(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

The hemocyanin of the shamefaced crab Calappa granulata: structural-functional characterization

Arthropod hemocyanins (Hcs) transport and store oxygen and are composed of six subunits, or multiples thereof depending on the species. Calappa granulata Hc is found as a mixture of dodecamers (95%) and hexamers (5%). Removal of calcium ions and alkaline pH induce an incomplete partially reversible dissociation of dodecameric Hc. Two-dimensional electrophoretic pattern of dissociated Hc indicated a large heterogeneity in Hc subunit: most differences are likely to be explained by post-translational modifications. Dodecameric Hc showed a large Bohr effect (Deltalog P50/DeltapH = -0.95) and a normal cooperativity (h50 values = 2.7 +/- 0.2) in the presence of 10 mM CaCl2. The hexameric molecule displayed lower Bohr effect and cooperativity than the dodecamer. Lactate effect on the oxygen affinity (Deltalog P50 = 0.55) and the increase of lactate concentrations in animals kept in emersion were related to the increased oxygen requirements that occur during hypoxia in vivo. Calcium affects oxygen affinity only at high concentrations: this Hc appeared to lack the calcium high-affinity binding sites found in other species. The effect of temperature on both oxygen affinity and cooperativity was measured in the absence and presence of 10 mM lactate, allowing calculation of the exothermic contribution of lactate binding (DeltaH = -25 kJ mol(-1)).     

Fluorescence spectroscopy of the tryptophan microenvironment in Carcinus aestuarii hemocyanin

The steady-state and time-resolved fluorescence properties of the multitryptophan minimal subunit CaeSS2 from Carcinus aestuarii hemocyanin have been studied with the aim of probing the environment of the fluorophores within the protein matrix. Subunit a of Panulirus interruptus hemocyanin, whose X-ray structure is known, has been also studied. The results are compared with those collected with other two monomeric fractions (CaeSS1, CaeSS3) produced by dissociation of the native, oligomeric protein as well as with those of the hexameric aggregate. Three classes of tryptophan residues can be singled out by a combination of fluorescence quenching and lifetime measurements on the holo-Hc (the copper containing, oxygen binding form) and the apo-Hc (the copper-free derivative). One class of tryptophans is exposed to the protein surface. Some of these residues are proposed to be involved in the intersubunit interactions in CaeSS1 and CaeSS3 fractions whereas in CaeSS2 the protein matrix masks them. This suggests the occurrence of conformational rearrangements after detachment of the subunit from the native aggregate, which could explain the inability of CaeSS2 to reassociate. A second class of tryptophan has been correlatively assigned, by comparison with the results obtained with Panulirus interruptus hemocyanin, to residues in close proximity to the active site. The third class includes buried, active site-distant, residues.     

Hemocyanin of the chiton, Stenoplax conspicua (Dall)

1. The hemocyanin of the chiton, Stenoplax conspicua, has a molecular weight determined by light-scattering of 4.2 X 10(6) daltons, (dt) and a sedimentation coefficient of 60 S. 2. The fully dissociated subunits in 6.0 and 8.0 M urea, and at pH 8.9-10 in the absence of divalent ions, have molecular weights of 4.15-4.30 x 10(5) and 4.17-4.75 x 10(5) dt, which is close to one-tenth of the molecular weight of the parent hemocyanin assembly. 3. The pH dependence of the molecular weights from pH 4.5 to 11 exhibit bell-shaped transition profiles, best accounted for by a three-species, decamer to dimer to monomer scheme of subunit dissociation, with one acidic and one basic ionizing group per dimer and 5-8 acidic and basic groups per monomer. 4. In the absence of stabilizing divalent ions S. conspicua hemocyanin is relatively unstable. At pH 7.4 in the presence of 0.01 M EDTA, it is predominantly in the dimeric state, characterized by a sedimentation constant of 18 S. It is also more readily dissociated to monomers at high pHs (8-9 and above) than are the C. stelleri and A. granulata hemocyanins. 5. Urea and GdmCl are effective dissociating agents of S. conspicua hemocyanin. The urea dissociation profile obtained at pH 8.5, 0.01 M Mg2+, 0.01 M Ca2+, and analyzed by means of the decamer-dimer-monomer scheme of subunit dissociation gave estimates of about 30 amino acid groups (Napp) at the dimer contacts within the hemocyanin decamers and about 120 groups per monomer within each dimer, suggesting hydrophobic stabilization of hemocyanin assembly.     

Assembly and calcium-induced cooperativity of Limulus IV hemocyanin: a model system for analysis of structure-function relationships in the absence of subunit heterogeneity

Hemocyanins, the high molecular weight copper proteins which serve as oxygen carriers in many arthropods and molluscs, are representative of multisubunit complexes which are capable of reversible dissociation and assembly. Although reversible, in many hemocyanins these processes are not in true thermodynamic equilibria, and it has been suggested that there is "microheterogeneity" among the molecules in solution. An alternative explanation is that their complex behavior is due to the existence of quaternary interactions between structurally distinct types of subunits within the native molecule which have varying pH and ionic strength sensitivity. Limulus IV hemocyanin was used as a model system to examine structure-function relationships in the absence of subunit heterogeneity. Purified subunit IV of Limulus polyphemus hemocyanin is homogeneous by a number of electrophoretic and immunological criteria and is capable of undergoing pH-dependent self-assembly into hexamers. The monomer-hexamer transition was found to be an equilibrium whose rate is dependent on the presence or absence of calcium ions. The observation that the assembly of this homopolymer behaves as a true equilibrium suggests that the nonequilibrium dissociation profiles observed for native Limulus hemocyanin are related to the extensive subunit heterogeneity of the native protein. In calcium-containing buffers, the monomer-hexamer transitions of Limulus IV hemocyanin can be described by a cooperative mechanism with approximately six protons per hexamer lost on assembly from acid pH and three protons gained on assembly from alkaline pH. Increased ionic strength or increased temperature favors dissociation. Like the native molecule, Limulus IV hemocyanin behaves as an allosteric protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

The subunit characterization of Callinectes sapidus hemocyanin.

Hemocyanin from the blue crab, Callinectes sapidus, sediments at 25.7 S and has a native molecular weight of 940 000 +/- 20 000. Under solution conditions of increased pH (approximately 10) or ionic strength, the native molecule dissociates to a 17 S species. Reversal of this dissociation was unsuccessful. At pH 10 and with the removal of Mg2+, the 17 S species reversibly dissociates to form a subunit species which sediments at 6 S. A comparison of the circular dichroic spectra of the 25.7 S and 6 S hemocyanins suggests that little happens to the structural integrity of the polypeptide backbone upon the two dissociations. Molecular weight estimations under reducing and denaturing conditions indicate that the 6 S hemocyanin species represents the constituent polypeptide chain of the protein molecule. Chemical analysis suggests the presence of a small amount, less than 3%, of carbohydrate bound to the polypeptide chain. Electrophoresis of the hemocyanin in the presence of sodium dodecyl sulfate or urea reveals two major electrophoretic species of either slightly different chemical composition or slightly different polypeptide chain length.     

Physical studies of the hemocyanin of the marine gastropod, Kelletia kelleti (Forbes).

1. The hemocyanin of the Californian whelk, Kelletia kelleti, investigated at pH and ionic conditions close to physiological, has a molecular weight close to 9.0 x 10(6) and a sedimentation constant of 114S, characteristic of the di-decameric structure of molluscan hemocyanins. Light-scattering measurements at pH 8.0, 0.05 M Mg2+, 0.01 M Ca2+ gave a molecular weight of 9.0 +/- 0.6 x 10(6), and scanning transmission electron microscopy produced nearly the same particle mass of 9.22 +/- 0.50 x 10(6) daltons (Da). 2. Light-scattering measurements on the fully dissociated monomers in the presence of 8.0 M urea and at pHs 10.6 and 11.0 gave molecular weights of 4.50 x 10(5)-4.91 x 10(5), that are close to one-twentieth of the mass of the parent di-decameric hemocyanin assembly. 3. Changes in pH produced a bell-shaped molecular weight profile, with molecular weights close to 9.0 x 10(6) in the pH region of about 5.5-8.0, and progressive dissociation to 4.5 x 10(5) Da monomers in the region below pH 4.0 and above pH 9.0 or 10, depending on the absence or presence of stabilizing Mg2+ ions (0.01 M). 4. In the absence of divalent ions some aggregation of hemocyanin was found at pHs close to 5.0, with observed molecular weights above 10 x 10(6) (investigated at a hemocyanin concentration of 0.10 g/l). The early studies of Condie and Langer (Science 144, 1138-1140, 1964) had shown that Kelletia kelleti hemocynanin aggregates at acidic pHs close to the isoelectric point, forming linear polymers of the hemocyanin di-decamers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Subunit dissociation and denaturation of Fasciolaria tulipa hemocyanin

1. The hemocyanin from the marine snail, Fasciolaria tulipa has a molecular weight of 8.6 +/- 0.6 x 10(6) determined by light-scattering and a sedimentation constant of (105.9 +/- 1.1)S. 2. The dissociated subunits at pH 11 and in 8.0 M urea (pH 7.4) had molecular weights of 4.4 x 10(5) and 4.7 x 10(5), close to one-twentieth of the parent didecameric assembly. 3. The pH dependence of the molecular weight profile exhibited bell-shaped transitions in both the presence and absence of Ca2+ and Mg2+ ions. In the physiological pH range of about 7.5-8.2 in divalent ion-containing buffers neither the molecular weight behavior nor the sedimentation patterns suggest any significant dissociation. 4. Both the urea and the Hofmeister salt series were found to dissociate the didecameric hemocyanin assembly. The ureas exhibit increasing effectiveness as dissociating agents with the higher alkyl substituted members of the series, suggesting hydrophobic stabilization of the subunit assembly. 5. Denaturation of the hemocyanin subunits by the urea series follows the same trend in effectiveness as the dissociation reaction; the reagent concentrations required to cause unfolding of the globular domains of the hemocyanin chains were, however, much higher than those needed for dissociation.     

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.     

Purification and characterization of an extracellular beta-1,4-mannanase from a marine bacterium, Vibrio sp. strain MA-138.

A beta-mannanase (EC 3.2.1.78) from Vibrio sp. strain MA-138 was purified by ammonium sulfate precipitation and several chromatographic procedures including gel filtration, adsorption, and ion-exchange chromatographies. The final ion-exchange chromatography Mono Q yielded one major active fraction and three minor active fractions. The major active fraction was purified to homogeneity on the basis of native polyacrylamide gel electrophoresis (PAGE). This purified enzyme was identified as a glycoprotein by periodic acid-Schiff staining and a monomeric protein with a molecular mass of 49 kDa by sodium dodecyl sulfate-PAGE. The pI of the enzyme was 3.8. The purified enzyme exhibited maximal activity at pH 6.5 and 40 degrees C and hydrolyzed at random the internal beta-1,4-mannosidic linkages in beta-mannan to give various sizes of oligosaccharides. The first 20 N-terminal amino acid sequence of the purified enzyme showed high homology with the N-terminal region of beta-mannanase from Streptomyces lividans 66.     

The metal sites on sarcoplasmic reticulum membranes that bind lanthanide ions with the highest affinity are not the ATPase Ca2+ transport sites.

We attempted to establish whether lanthanide ions, when added to sarcoplasmic reticulum (SR) membranes in the absence of nucleotide, compete with Ca2+ for binding to the transport sites of the Ca(2+)-ATPase in these membranes, or whether they bind to different sites. Equilibrium measurements of the effect of lanthanide ions on the intrinsic fluorescence of SR ATPase and on 45Ca2+ binding to it were performed either at neutral pH (pH 6.8), i.e. when endogenous or contaminating Ca2+ was sufficient to nearly saturate the ATPase transport sites, or at acid pH (pH 5.5), which greatly reduced the affinity of calcium for its sites on the ATPase. These measurements did reveal apparent competition between Ca2+ and the lanthanide ions La3+, Gd3+, Pr3+, and Tb3+, which all behaved similarly, but this competition displayed unexpected features: lanthanide ions displaced Ca2+ with a moderate affinity and in a noncooperative way, and the pH dependence of this displacement was smaller than that of the Ca2+ binding to its own sites. Simultaneously, we directly measured the amount of Tb3+ bound to the ATPase relative to the amount of Ca2+ and found that Tb3+ ions only reduced significantly the amount of Ca2+ bound after a considerable number of Tb3+ ions had bound. Furthermore, when we tested the effect of Ca2+ on the amount of Tb3+ bound to the SR membranes, we found that the Tb3+ ions which bound at low Tb3+ concentrations were not displaced when Ca2+ was added at concentrations which saturated the Ca2+ transport sites. We conclude that the sites on SR ATPase to which lanthanide ions bind with the highest affinity are not the high affinity Ca2+ binding and transport sites. At higher concentrations, lanthanide ions did not appear to be able to replace Ca2+ ions and preserve the native structure of their binding pocket, as evaluated in rapid filtration measurements from the effect of moderate concentrations of lanthanide ions on the kinetics of Ca2+ dissociation. Thus, the presence of lanthanide ions slowed down the dissociation from its binding site of the first, superficially bound 45Ca2+ ion, instead of specifically preventing the dissociation of the deeply bound 45Ca2+ ion. These results highlight the need for caution when interpreting, in terms of calcium sites, experimental data collected using lanthanide ions as spectroscopic probes on SR membrane ATPase.