The penta-EF-hand domain of ALG-2 interacts with amino-terminal domains of both annexin VII and annexin XI in a Ca2+-dependent manner

The apoptosis-linked protein ALG-2 is a Ca(2+)-binding protein that belongs to the penta-EF-hand (PEF) protein family. ALG-2 forms a homodimer, a heterodimer with another PEF protein, peflin, and a complex with its interacting protein, named Alix or AIP1. We previously identified annexin XI as a novel ALG-2-binding partner. Both the N-terminal regulatory domain of annexin XI (Anx11N) and the ALG-2-binding domain of Alix/AIP1 are rich in Pro, Gly, Ala, Tyr and Gln. This PGAYQ-biased amino acid composition is also found in the N-terminal extension of annexin VII (Anx7N). Using recombinant ALG-2 proteins and the glutathione S-transferase (GST) fusion proteins of Anx7N and Anx11N, the direct Ca(2+)-dependent interaction was analyzed by a biotin-tagged ALG-2 overlay assay and by a real-time interaction analysis with a surface plasmon resonance (SPR) biosensor. Both GST-Anx7N and GST-Anx11N showed similar binding kinetics against ALG-2 as well as ALG-2-DeltaN23, which lacked the hydrophobic N-terminal region. Two binding sites were predicted in both Anx7N and Anx11N, and the dissociation constants (K(d)) were estimated to be approximately 40-60 nM for the high-affinity site and 500-700 nM for the low-affinity site.     

Ca(2+) and membrane binding to annexin 3 modulate the structure and dynamics of its N terminus and domain III

Annexin 3 (ANX A3) represents approximately 1% of the total protein of human neutrophils and promotes tight contact between membranes of isolated specific granules in vitro leading to their aggregation. Like for other annexins, the primary molecular events of the action of this protein is likely its binding to negatively charged phospholipid membranes in a Ca(2+)-dependent manner, via Ca(2+)-binding sites located on the convex side of the highly conserved core of the molecule. The conformation and dynamics of domain III can be affected by this process, as it was shown for other members of the family. The 20 amino-acid, N-terminal segment of the protein also could be affected and also might play a role in the modulation of its binding to the membranes. The structure and dynamics of these two regions were investigated by fluorescence of the two tryptophan residues of the protein (respectively, W190 in domain III and W5 in the N-terminal segment) in the wild type and in single-tryptophan mutants. By contrast to ANX A5, which shows a closed conformation and a buried W187 residue in the absence of Ca(2+), domain III of ANX A3 exhibits an open conformation and a widely solvent-accessible W190 residue in the same conditions. This is in agreement with the three-dimensional structure of the ANX A3-E231A mutant lacking the bidentate Ca(2+) ligand in domain III. Ca(2+) in the millimolar concentration range provokes nevertheless a large mobility increase of the W190 residue, while interaction with the membranes reduces it slightly. In the N-terminal region, the W5 residue, inserted in the central pore of the protein, is weakly accessible to the solvent and less mobile than W190. Its amplitude of rotation increases upon binding of Ca(2+) and returns to its original value when interacting with membranes. Ca(2+) concentration for half binding of the W5A mutant to negatively charged membranes is approximately 0.5 mM while it increases to approximately 1 mM for the ANX A3 wild type and to approximately 3 mM for the W190 ANX A3 mutant. In addition to the expected perturbation of the W190 environment at the contact surface between the protein and the membrane bilayer, binding of the protein to Ca(2+) and to membranes modulates the flexibility of the ANX A3 hinge region at the opposite of this interface and might affect its membrane permeabilizing properties.     

Cholesterol regulates membrane binding and aggregation by annexin 2 at submicromolar Ca(2+) concentration

Annexin 2 is a member of the annexin family which has been implicated in calcium-regulated exocytosis. This contention is largely based on Ca(2+)-dependent binding of the protein to anionic phospholipids. However, annexin 2 was shown to be associated with chromaffin granules in the presence of EGTA. A fraction of this bound annexin 2 was released by methyl-beta-cyclodextrin, a reagent which depletes cholesterol from membranes. Restoration of the cholesterol content of chromaffin granule membranes with cholesterol/methyl-beta-cyclodextrin complexes restored the Ca(2+)-independent binding of annexin 2. The binding of both, monomeric and tetrameric forms of annexin 2 was also tested on liposomes of different composition. In the absence of Ca(2+), annexin 2, especially in its tetrameric form, bound to liposomes containing phosphatidylserine, and the addition of cholesterol to these liposomes increased the binding. Consistent with this observation, liposomes containing phosphatidylserine and cholesterol were aggregated by the tetrameric form of annexin 2 at submicromolar Ca(2+) concentrations. These results indicate that the lipid composition of membranes, and especially their cholesterol content, is important in the control of the subcellular localization of annexin 2 in resting cells, at low Ca(2+) concentration. Annexin 2 might be associated with membrane domains enriched in phosphatidylserine and cholesterol.     

N-Terminal domain of annexin 2 regulates Ca(2+)-dependent membrane aggregation by the core domain: a site directed mutagenesis study

Annexin 2 binds and aggregates biological membranes in a Ca(2+)-dependent manner. This protein exists as a monomer (p36) or as a heterotetramer (p90) in which two p36 chains are associated with a dimer of p11, a member of the S100 protein family. Protein kinase C phosphorylates the protein at the level of the N-terminal tail on serines 11 and 25, thereby modifying its oligomeric structure and its properties of membrane aggregation. To analyze these effects, the properties of a series of mutants in which serines 11 and 25 were replaced by alanine and/or glutamic acid were investigated. The affinity for p11 light chain was decreased in the S11E mutants. Glutamic acid residues in positions 11 or 25 did not change membrane binding, either in the tetrameric or in the monomeric form. On the other hand, these mutations affected the aggregation properties of the two forms. For the tetramer, the aggregation efficiency was decreased but not the Ca(2+) sensitivity, whereas the latter was affected in the case of the monomer. The effects were stronger in the S11E mutants, and they were cumulative in the double mutant. They suggest a different conformation of the N-terminal domain in the mutants (and in the phosphorylated protein), a hypothesis which is supported by proteolysis experiments. This conformational change would affect aggregation by the monomer through a dimerization step.     

Ca(2+)-dependent annexin self-association on membrane surfaces

Annexin self-association was studied with 90 degrees light scattering and resonance energy transfer between fluorescein (donor) and eosin (acceptor) labeled proteins. Synexin (annexin VII), p32 (annexin IV), and p67 (annexin VI) self-associated in a Ca(2+)-dependent manner in solution. However, this activity was quite labile and, especially for p32 and p67, was not consistently observed. When bound to chromaffin granule membranes, the three proteins consistently self-associated and did so at Ca2+ levels (pCa 5.0-4.5) approximately 10-fold lower than required when in solution. Phospholipid vesicles containing phosphatidylserine and phosphatidylethanolamine (1:1 or 1:3) were less effective at supporting annexin polymerization than were those containing phosphatidylserine and phosphatidylcholine (1:0, 1:1, or 1:3). The annexins bound chromaffin granule membranes in a positively cooperative manner under conditions where annexin self-association was observed, and both phenomena were inhibited by trifluoperazine. Ca(2+)-dependent chromaffin granule membrane aggregation, induced by p32 or synexin, was associated with intermembrane annexin polymerization at Ca2+ levels less than pCa 4, but not at higher Ca2+ concentrations, suggesting that annexin self-association may be necessary for membrane contact at low Ca2+ levels but not at higher Ca2+ levels where the protein may bind two membranes as a monomer.     

Identification of a novel protein complex containing annexin VI, Fyn, Pyk2, and the p120(GAP) C2 domain

p120(GAP) (RasGAP) has been proposed to function as both an inhibitor and effector of Ras. Previously we have shown that RasGAP contains a C2 domain which mediates both Ca(2+)-dependent membrane association and protein-protein interactions. Specifically, three proteins have been isolated in a complex with the C2 domain of RasGAP; these are the Ca(2+)-dependent lipid binding protein annexin VI (p70) and two previously unidentified proteins, p55 and p120. Here we provide evidence that p55 is the Src family kinase Fyn and p120 is the focal adhesion kinase family member Pyk2. In addition, in vitro binding assays indicate that Fyn, but not Pyk2 binds directly to annexin VI. Finally, co-immunoprecipitation studies in Rat-1 fibroblasts confirm that Fyn, Pyk2, annexin VI and RasGAP can form a protein complex in mammalian cells.     

Insight into the location and dynamics of the annexin A2 N-terminal domain during Ca(2+)-induced membrane bridging

Annexin A2 (AnxA2) is a Ca(2+)- and phospholipid-binding protein involved in many cellular regulatory processes. Like other annexins, it is constituted by two domains: a conserved core, containing the Ca(2+) binding sites, and a variable N-terminal segment, containing sites for interactions with other protein partners like S100A10 (p11). A wealth of data exists on the structure and dynamics of the core, but little is known about the N-terminal domain especially in the Ca(2+)-induced membrane-bridging process. To investigate this protein region in the monomeric AnxA2 and in the heterotetramer (AnxA2-p11)(2), the reactive Cys8 residue was specifically labelled with the fluorescent probe acrylodan and the interactions with membranes were studied by steady-state and time-resolved fluorescence. In membrane junctions formed by the (AnxA2-p11)(2) heterotetramer, the flexibility of the N-terminal domain increased as compared to the protein in solution. In "homotypic" membrane junctions formed by monomeric AnxA2, acrylodan moved to a more hydrophobic environment than in the protein in solution and the flexibility of the N-terminal domain also increased. In these junctions, this domain is probably not in close contact with the membrane surface, as suggested by the weak quenching of acrylodan observed with doxyl-PCs, but pairs of N-termini likely interact, as revealed by the excimer-forming probe pyrene-maleimide bound to Cys8. We present a model of monomeric AnxA2 N-terminal domain organization in "homotypic" bridged membranes in the presence of Ca(2+).     

Annexin A4 reduces water and proton permeability of model membranes but does not alter aquaporin 2-mediated water transport in isolated endosomes

Annexin A4 (Anx4) belongs to a ubiquitous family of Ca2+-dependent membrane-binding proteins thought to be involved in membrane trafficking and membrane organization within cells. Anx4 localizes to the apical region in epithelia; however, its physiological role is unclear. We show that Anx4 exhibited binding to liposomes (phosphatidylcholine:phosphatidylserine, 1:1) in the presence of Ca2+ and binding was reversible with EDTA. Anx4 binding resulted in liposome aggregation and a reduction in membrane water permeability of 29% (P < 0.001) at 25 degrees C. These effects were not seen in the presence of Ca2+ or Anx4 alone and were reversible with EDTA. Measurements of membrane fluidity made by monitoring fluorescence anisotropy of 2-(12-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino)dodecanoyl-1-hexadecanoyl-sn-glycero-3-phosphocholine (NBD-HPC) demonstrated that Anx4 binding rigidified the outer leaflet of the bilayer (P < 0.001), thus providing a molecular explanation for the inhibition of water flux. To determine whether Anx4 would produce similar effects on physiological membranes we constructed liposomes which recapitulated the lipid composition of the inner leaflet of the MDCK apical membrane. These membranes exhibited reductions to water permeability upon Anx4 binding (19.5% at 25 degrees C, 31% at 37 degrees C; P < 0.01 and P < 0.001, respectively) and to proton permeability (15% at 25 degrees C, 19.5% at 37 degrees C; P < 0.05). Since our in vitro experiments indicated an effect on membrane permeability, we examined localization of Anx4 in the kidney collecting duct, a region of the nephron responsible for concentrating urine through water reabsorbtion. Anx4 was shown to colocalize apically with aquaporin 2 (AQP2) in collecting duct epithelia. To test for the existence of a functional interaction between Anx4 and AQP2 we isolated AQP2-containing endosomes and exposed them to Anx4/Ca2+. Water flux rates were unchanged, indicating Anx4 does not directly regulate AQP2. We conclude that Anx4 can alter the physical properties of membranes by associating with them and regulate passive membrane permeability to water and protons. These properties represent important new functions for Anx4.     

Novel organization and properties of annexin 2-membrane complexes

Annexin 2 belongs to the annexin family of proteins that bind to phospholipid membranes in a Ca(2+)-dependent manner. Here we show that, under mild acidic conditions, annexin 2 binds to and aggregates membranes containing anionic phospholipids, a fact that questions the mechanism of its interaction with membranes via Ca(2+) bridges only. The H(+) sensitivity of annexin 2-mediated aggregation is modulated by lipid composition (i.e. cholesterol content). Cryo-electron microscopy of aggregated liposomes revealed that both the monomeric and the tetrameric forms of the protein form bridges between the liposomes at acidic pH. Monomeric annexin 2 induced two different organizations of the membrane junctions. The first resembled that obtained at pH 7 in the presence of Ca(2+). For the tetramer, the arrangement was different. These bridges seemed more flexible than the Ca(2+)-mediated junctions allowing the invagination of membranes. Time-resolved fluorescence analysis at mild acidic pH and the measurement of Stokes radius revealed that the protein undergoes conformational changes similar to those induced by Ca(2+). Labeling with the lipophilic probe 3-(trifluoromethyl)-3-(m-[(125)I]iodophenyl)diazirine indicated that the protein has access to the hydrophobic part of the membrane at both acidic pH in the absence of Ca(2+) and at neutral pH in the presence of Ca(2+). Models for the membrane interactions of annexin 2 at neutral pH in the presence of Ca(2+) and at acidic pH are discussed.     

Characterization of a Ca(2+)-binding site in human annexin II by site-directed mutagenesis.

Annexin II, a major cytoplasmic substrate of the src tyrosine kinase, is a member of the annexin family of Ca2+/phospholipid-binding proteins. It is composed of a short N-terminal tail (30 residues) followed by four so-called annexin repeats (each 70-80 residues in length) which share sequence homologies and are thought to form (a) new type(s) of Ca(2+)-binding site(s). We have produced wild-type and site specifically mutated annexin II molecules to compare their structure and biochemistry. The recombinant wild-type annexin II displays biochemical and spectroscopical properties resembling those of the authentic protein purified from mammalian cells. In particular, it shows the Ca(2+)-induced blue shift in fluorescence emission which is typical for this annexin. Replacement of the single tryptophan in annexin II (Trp-212) by a phenylalanine abolishes the fluorescence signal and allows the unambiguous assignment of the Ca(2+)-sensitive spectroscopic properties to Trp-212. This residue is located in the third annexin repeat in a highly conserved stretch of 17 amino acids which are also found in the other repeats and known as the endonexin fold. To study the precise architecture of the Ca2+ site which must reside in close proximity to Trp-212, we changed several residues of the endonexin fold in repeat 3 by site-directed mutagenesis. An analysis of these mutants by fluorescence spectroscopy and Ca(2+)-dependent phospholipid binding reveals that Gly-206 and Thr-207 seem indispensible for a correct folding of this Ca(2+)-binding site.     

Modes of annexin-membrane interactions analyzed by employing chimeric annexin proteins

Annexin II is a member of the annexin family of Ca(2+)- and phospholipid-binding proteins which is particularly enriched on early endosomal membranes and has been implicated in participating in endocytic events. In contrast to other endosomal annexins the association of annexin II with its target membrane can occur in the absence of Ca(2+) in a manner depending on the unique N-terminal domain of the protein. However, endosome binding of annexin II does not require formation of a protein complex with the intracellular ligand S100A10 (p11) as an annexin II mutant protein (PM AnxII) incapable of interacting with p11 is still present on endosomal membranes. Fusion of the N-terminal sequence of this PM AnxII (residues 1-27) to the conserved protein core of annexin I transfers the capability of Ca(2+)-independent membrane binding to the otherwise Ca(2+)-sensitive annexin I. These results underscore the importance of the N-terminal sequence of annexin II for the Ca(2+)-independent endosome association and argue for a direct interaction of this sequence with an endosomal membrane receptor.     

Biochemical Characterization of Annexins I and II Isolated from Pig Nervous Tissue

Five proteins having molecular masses of 90, 67, 37, 36, and 32 kDa (p90, p67, p37, p36, and p32, respectively) were identified in the particulate fractions of pig brain cortex and pig spinal cord prepared in the presence of 0.2 mM Ca2+ and further purified using a protocol previously described for the purification of calpactins. Proteins p90, p37, and p36 are related to annexins I and II. Annexin II, represented by p90, is found as an heterotetramer, composed of two heavy chains of 36 kDa and two light chains of 11 kDa, and as a monomer of 36 kDa. Protein p37, which differs immunologically from p36, is a monomer and could be related to annexin I. All three proteins are Ca(2+)-dependent phospholipid- and F-actin-binding proteins; they are phosphorylated on a serine and on a tyrosine residue by protein kinases associated with synaptic plasma membranes. Purified p36 monomer and p36 heterotetramer proteins bind to actin at millimolar Ca2+ concentrations. The stoichiometry of p36 binding to F-actin at saturation is 1:2, corresponding to one tetramer or monomer of calpactin for two actin monomers (KD, 3 x 10(-6) M). Synaptic plasma membranes supplemented with the monomeric or tetrameric forms of p36 phosphorylate the proteins on a serine residue. The monomer is phosphorylated on a serine residue by a Ca(2+)-independent protein kinase, whereas the heterotetramer is phosphorylated on a serine residue and a tyrosine residue by Ca(2+)-dependent protein kinases. Antibodies to brain p37 and p36 together with antibodies to lymphocytes lipocortins 1 and 2 were used to follow the distribution of these proteins in nervous tissues. Polypeptides of 37, 34, and 36 kDa cross-react with these antibodies. Anti-p37 and antilipocortin 1 cross-react on the same 37- and 34-kDa polypeptides; anti-p36 and antilipocortin 2 cross-react only on the 36-kDa polypeptides.     

Modulation of troponin T molecular conformation and flexibility by metal ion binding to the NH2-terminal variable region

Troponin T (TnT) plays an allosteric signal transduction role in the actin thin-filament-based Ca(2+)-regulation of striated muscle contraction. Developmentally regulated alternative RNA splicing produces TnT isoforms differing in their NH(2)-terminal structure. Physical property variations of the NH(2)-terminal hypervariable region of TnT may have a role in tuning the Ca(2+)-sensitivity and overall cooperativity of the muscle. We have previously demonstrated that metal ion or monoclonal antibody binding to the NH(2)-terminal region can modulate the epitopic conformation and troponin I and tropomyosin binding affinity of TnT. To further establish the molecular basis of this conformational and functional modulation, we have characterized the NH(2)-terminal variable region-originated secondary conformational effect in TnT using fluorescence spectral analysis. The chicken fast skeletal muscle TnT isoform, TnT8e16, containing a cluster of transition-metal ion binding sites (Tx) in the NH(2)-terminal variable region was used in this study. TnT8e16 was titrated for Cu(II) binding-induced changes in fluorescence intensity and anisotropy of the COOH-domain Trp residues (W234, W236, and W285), which demonstrated considerable environmental sensitivity in TnT denaturation studies. Nonlinear Stern-Volmer plots of Trp quenching indicated a metal ion binding-induced conformational change in TnT. Fluorescence anisotropy changes upon metal ion binding indicated a decrease in the mobility of the Trp residues and an increase in the flexibility of fluorescein-labeled Cys263 in the COOH domain. These data support a model that the alternatively spliced NH(2)-terminal variable region of TnT modulates conformation and flexibility of other domains of the protein.     

Surface topography of the p3 and p6 annexin V crystal forms determined by atomic force microscopy

Annexin V is a member of a family of structurally homologous proteins sharing the ability to bind to negatively charged phospholipid membranes in a Ca(2+)-dependent manner. The structure of the soluble form of annexin V has been solved by X-ray crystallography, while electron crystallography of two-dimensional (2D) crystals has been used to reveal the structure of its membrane-bound form. Two 2D crystal forms of annexin V have been reported to date, with either p6 or p3 symmetry. Atomic force microscopy has previously been used to investigate the growth and the topography of the p6 crystal form on supported phospholipid bilayers (Reviakine et al., 1998). The surface structure of the second crystal form, p3, is presented in this study, along with an improved topographic map of the p6 crystal form. The observed topography is correlated with the structure determined by X-ray crystallography.     

The effects of Ca2+ binding on the dynamic properties of a designed Ca2+-binding protein

The effects of Ca(2+) binding on the dynamic properties of Ca(2+)-binding proteins are important in Ca(2+) signaling. To understand the role of Ca(2+) binding, we have successfully designed a Ca(2+)-binding site in the domain 1 of rat CD2 (denoted as Ca.CD2) with the desired structure and retained function. In this study, the backbone dynamic properties of Ca.CD2 have been investigated using (15)N spin relaxation NMR spectroscopy to reveal the effect of Ca(2+) binding on the global and local dynamic properties without the complications of multiple interactive Ca(2+) binding and global conformational change. Like rat CD2 (rCD2) and human CD2 (hCD2), residues involved in the recognition of the target molecule CD48 exhibit high flexibility. Mutations N15D and N17D that introduce the Ca(2+) ligands increase the flexibility of the neighboring residues. Ca(2+)-induced local dynamic changes occur mainly at the residues proximate to the Ca(2+)-binding pocket or the residues in loop regions. The beta-strand B of Ca.CD2 that provides two Asp for the Ca(2+) undergoes an S(2) decrease upon the Ca(2+) binding, while the DE-loop that provides one Asn and one Asp undergoes an S(2) increase. Our study suggests that Ca(2+) binding has a differential effect on the rigidity of the residues depending on their flexibility and location within the secondary structure.     

The W105G and W99G sorcin mutants demonstrate the role of the D helix in the Ca(2+)-dependent interaction with annexin VII and the cardiac ryanodine receptor

Sorcin, a 21.6 kDa two-domain penta-EF-hand (PEF) protein, when activated by Ca(2+) binding, interacts with target proteins in a largely uncharacterized process. The two physiological EF-hands EF3 and EF2 do not belong to a structural pair but are connected by the D helix. To establish whether this helix is instrumental in sorcin activation, two D helix residues were mutated: W105, located near EF3 and involved in a network of interactions, and W99, located near EF2 and facing solvent, were substituted with glycine. Neither mutation alters calcium affinity. The interaction of the W105G and W99G mutants with annexin VII and the cardiac ryanodine receptor (RyR2), requiring the sorcin N-terminal and C-terminal domain, respectively, was studied. Surface plasmon resonance experiments show that binding of annexin VII to W99G occurs at the same Ca(2+) concentration as that of the wild type, whereas W105G requires a significantly higher Ca(2+) concentration. Ca(2+) spark activity of isolated heart cells monitors the sorcin-RyR2 interaction and is unaltered by W105G but is reduced equally by W99G and the wild type. Thus, substitution of W105, via disruption of the network of D helix interactions, affects the capacity of sorcin to recognize and interact with either target at physiological Ca(2+) concentrations, while mutation of solvent-facing W99 has little effect. The D helix appears to amplify the localized structural changes that occur at EF3 upon Ca(2+) binding and thereby trigger a structural rearrangement that enables interaction of sorcin with its molecular targets. The same activation process may apply to other PEF proteins in view of the D helix conservation.     

Cation charge and size selectivity of the C2 domain of cytosolic phospholipase A(2).

C2 domains regulate numerous eukaryotic signaling proteins by docking to target membranes upon binding Ca(2+). Effective activation of the C2 domain by intracellular Ca(2+) signals requires high Ca(2+) selectivity to exclude the prevalent physiological metal ions K(+), Na(+), and Mg(2+). The cooperative binding of two Ca(2+) ions to the C2 domain of cytosolic phospholipase A(2) (cPLA(2)-alpha) induces docking to phosphatidylcholine (PC) membranes. The ionic charge and size selectivities of this C2 domain were probed with representative mono-, di-, and trivalent spherical metal cations. Physiological concentrations of monovalent cations and Mg(2+) failed to bind to the domain and to induce docking to PC membranes. Superphysiological concentrations of Mg(2+) did bind but still failed to induce membrane docking. In contrast, Ca(2+), Sr(2+), and Ba(2+) bound to the domain in the low micromolar range, induced electrophoretic mobility shifts in native polyacrylamide gels, stabilized the domain against thermal denaturation, and induced docking to PC membranes. In the absence of membranes, the degree of apparent positive cooperativity in binding of Ca(2+), Sr(2+), and Ba(2+) decreased with increasing cation size, suggesting that the C2 domain binds two Ca(2+) or Sr(2+) ions, but only one Ba(2+) ion. These stoichiometries were correlated with the abilities of the ions to drive membrane docking, such that micromolar concentrations of Ca(2+) and Sr(2+) triggered docking while even millimolar concentrations of Ba(2+) yielded poor docking efficiency. The simplest explanation is that two bound divalent cations are required for stable membrane association. The physiological Ca(2+) ion triggered membrane docking at 20-fold lower concentrations than Sr(2+), due to both the higher Ca(2+) affinity of the free domain and the higher affinity of the Ca(2+)-loaded domain for membranes. Kinetic studies indicated that Ca(2+) ions bound to the free domain are retained at least 5-fold longer than Sr(2+) ions. Moreover, the Ca(2+)-loaded domain remained bound to membranes 2-fold longer than the Sr(2+)-loaded domain. For both Ca(2+) and Sr(2+), the two bound metal ions dissociate from the protein-membrane complex in two kinetically resolvable steps. Finally, representative trivalent lanthanide ions bound to the domain with high affinity and positive cooperativity, and induced docking to PC membranes. Overall, the results demonstrate that both cation charge and size constraints contribute to the high Ca(2+) selectivity of the C2 domain and suggest that formation of a cPLA(2)-alpha C2 domain-membrane complex requires two bound multivalent metal ions. These features are proposed to stem from the unique structural features of the metal ion-binding site in the C2 domain.     

Effect of annexin I on insulin secretion through surface binding sites in rat pancreatic islets

This study investigates the effect of extracellular annexin I (Anx I) on regulating insulin secretion in isolated rat pancreatic islets. Results show that Anx I stimulates insulin release in pancreatic islets regardless of the presence or absence of extracellular Ca2+. In particular, confocal microscopy shows that Anx I binds to the surface of islet cells in the absence of extracellular Ca2+. However, insulin secretion through Anx I significantly decreases in trypsin-treated islets. Likewise, there is minimal binding of Anx I to the surface of trypsin-treated islets. Anti-Anx I polyclonal antibody also inhibits the stimulating effect of Anx I on insulin secretion. These results indicate that Anx I is capable of binding to the cell surface receptor, in order to regulate the stimulation of insulin release in rat pancreatic islets.     

The crystal structure of annexin Gh1 from Gossypium hirsutum reveals an unusual S3 cluster.

The three-dimensional crystal structure of recombinant annexin Gh1 from Gossypium hirsutum (cotton fibre) has been determined and refined to the final R-factor of 0.219 at the resolution of 2.1 A. This plant annexin consists of the typical 'annexin fold' and is similar to the previously solved bell pepper annexin Anx24(Ca32), but significant differences are seen when compared to the structure of nonplant annexins. A comparison with the structure of the mammalian annexin AnxA5 indicates that canonical calcium binding is geometrically possible within the membrane loops in domains I and II of Anx(Gh1) in their present conformation. All plant annexins possess a conserved tryptophan residue in the AB loop of the first domain; this residue was found to adopt both a loop-in and a loop-out conformation in the bell pepper annexin Anx24(Ca32). In Anx(Gh1), the conserved tryptophan residue is in a surface-exposed position, half way between both conformations observed in Anx24(Ca32). The present structure reveals an unusual sulfur cluster formed by two cysteines and a methionine in domains II and III, respectively. While both cysteines adopt the reduced thiolate forms and are separated by a distance of about 5.5 A, the sulfur atom of the methionine residue is in their close vicinity and apparently interacts with both cysteine sulfur atoms. While the cysteine residues are conserved in at least five plant annexins and in several mammalian members of the annexin family of proteins, the methionine residue is conserved only in three plant proteins. Several of these annexins carrying the conserved residues have been implicated in oxidative stress response. We therefore hypothesize that the cysteine motif found in the present structure, or possibly even the entire sulfur cluster, forms the molecular basis for annexin function in oxidative stress response.     

The EF-hand Ca2+-binding protein p22 plays a role in microtubule and endoplasmic reticulum organization and dynamics with distinct Ca2+-binding requirements

We have reported that p22, an N-myristoylated EF-hand Ca(2+)-binding protein, associates with microtubules and plays a role in membrane trafficking. Here, we show that p22 also associates with membranes of the early secretory pathway membranes, in particular endoplasmic reticulum (ER). On binding of Ca(2+), p22's ability to associate with membranes increases in an N-myristoylation-dependent manner, which is suggestive of a nonclassical Ca(2+)-myristoyl switch mechanism. To address the intracellular functions of p22, a digitonin-based "bulk microinjection" assay was developed to load cells with anti-p22, wild-type, or mutant p22 proteins. Antibodies against a p22 peptide induce microtubule depolymerization and ER fragmentation; this antibody-mediated effect is overcome by preincubation with the respective p22 peptide. In contrast, N-myristoylated p22 induces the formation of microtubule bundles, the accumulation of ER structures along the bundles as well as an increase in ER network formation. An N-myristoylated Ca(2+)-binding p22 mutant, which is unable to undergo Ca(2+)-mediated conformational changes, induces microtubule bundling and accumulation of ER structures along the bundles but does not increase ER network formation. Together, these data strongly suggest that p22 modulates the organization and dynamics of microtubule cytoskeleton in a Ca(2+)-independent manner and affects ER network assembly in a Ca(2+)-dependent manner.