Different molecular arrangements of the tetrameric annexin 2 modulate the size and dynamics of membrane aggregation

Annexin 2, a member of the annexin family of Ca²⁺-dependent membrane binding proteins is found in monomeric and heterotetrameric forms and has been involved in different membrane related functions. The heterotetrameric annexin 2 is composed of a dimer of S100A10, a member of the S100 family of Ca²⁺ binding proteins and two annexin 2 molecules ((Anx2-S100A10)₂). Different molecular models including tetramers and octamers in which S100A10 is localized in the centre of the complex with the annexin 2 molecules positioned around S100A10 had been proposed. Herein, the organization of the (Anx2-S100A10)₂ complex in conditions in which membranes are able to bridge was studied. We performed Cryo-electron microscopy observations of the tetrameric annexin 2 on the membrane surface, and study the S100A10 accessibility to antibodies by flow “cytometry”. We also studied the kinetics and size evolution of vesicle aggregates by dynamic light scattering. The results show that the protein is able to organize in three different arrangements depending on the presence of Ca²⁺ and pH and that the aggregation is faster in the presence of Ca²⁺ compared with the aggregation in its absence. In one arrangement the S100A10 molecule is exposed to the solvent allowing its interaction with other proteins. The presented results will serve as a molecular basis to explain some of the functions of the tetrameric annexin 2.     

Identification of a novel interaction between the Ca(2+)-binding protein S100A11 and the Ca(2+)- and phospholipid-binding protein annexin A6

S100A11 is a member of the S100 family of EF-hand Ca²⁺-binding proteins, which is expressed in smooth muscle and other tissues. Ca²⁺ binding to S100A11 induces a conformational change that exposes a hydrophobic surface for interaction with target proteins. Affinity chromatography with immobilized S100A11 was used to isolate a 70-kDa protein from smooth muscle that bound to S100A11 in a Ca²⁺-dependent manner and was identified by mass spectrometry as annexin A6. Direct Ca²⁺-dependent interaction between S100A11 and annexin A6 was confirmed by affinity chromatography of the purified bacterially expressed proteins, by gel overlay of annexin A6 with purified S100A11, by chemical cross-linking, and by coprecipitation of S100A11 with annexin A6 bound to liposomes. The expression of S100A11 and annexin A6 in the same cell type was verified by RT-PCR and immunocytochemistry of isolated vascular smooth muscle cells. The site of binding of S100A11 on annexin A6 was investigated by partial tryptic digestion and deletion mutagenesis. The unique NH₂ terminal head region of annexin A6 was not required for S100A11 binding, but binding sites were identified in both NH₂- and COOH-terminal halves of the molecule. We hypothesize that an agonist-induced increase in cytosolic free [Ca²⁺] leads to formation of a complex of S100A11 and annexin A6, which forms a physical connection between the plasma membrane and the cytoskeleton, or plays a role in the formation of signaling complexes at the level of the sarcolemma. smooth muscle; protein-protein interaction     

Molecular cloning of rabbit CAP-50, a calcyclin-associated annexin protein.

CAP-50 is a member of annexin family proteins which binds specifically to calcyclin in a Ca2+ dependent manner (Tokumitsu. H., Mizutani. A., Minami. H., Kobayashi. R., and Hidaka. H. (1992) J. Biol. Chem. 267,8919-8924). The cDNA representing the rabbit form of this protein has been cloned from rabbit lung cDNA library. Sequence analysis of two overlapping clones revealed a 81-nucleotides 5'-nontranslated region, 1512-nucleotides of open reading frame, a 672-nucleotides 3'-nontranslated region, and a poly(A) tail. Authenticity of the clones was confirmed by comparison of portions of the deduced amino acid sequence with eight sequences of proteolytic peptides obtained from rabbit lung protein. CAP-50 cDNA encodes a 503 residue protein with a calculated M(r) of 54,043 and shows that the protein is composed of four imperfect repeats and hydrophobic N-terminal region. C-terminal region including four imperfect repeats shows 58.1% identity with human synexin (annexin VII), 48.0% identity with annexin I, 47.4% identity with annexin II, 60.1% identity with annexin IV, 54.5% identity with annexin V. Hydrophobic N-terminal region composed of 202 amino acid residues is not homologous with other annexin proteins suggesting that CAP-50 is a novel member of annexin family proteins.     

Chromosomal mapping of the human annexin IV (ANX4) gene.

Annexin IV (placental anticoagulant protein II) is a member of the annexin or lipocortin family of calcium-dependent phospholipid-binding proteins. A cDNA for human annexin IV was isolated from a placental library that is 675 bases longer in the 3' untranslated region than previously reported, indicating the existence of alternative mRNA processing for this gene. Genomic Southern blotting with a cDNA probe indicated a gene size of 18-56 kb. Primers developed for polymerase chain reaction (PCR) allowed amplification of a 1.6-kb portion of the ANX4 gene. DNA sequence analysis showed that this PCR product contained a single intron with exon-intron boundaries in exactly the same position as in the mouse annexin I and annexin II genes. PCR analysis of a somatic cell hybrid panel mapped the ANX4 gene to chromosome 2, and in situ hybridization with a cDNA probe showed a unique locus for ANX4 at 2p13. This study provides further evidence that genes for the annexins are dispersed throughout the genome but are similar in size and exon-intron organization.     

Specific association of annexin 1 with plasma membrane-resident and internalized EGF receptors mediated through the protein core domain

Phosphorylation of the Ca2+ and membrane-binding protein annexin 1 by epidermal growth factor (EGF) receptor tyrosine kinase has been thought to be involved in regulation of the EGF receptor trafficking. To elucidate the interaction of annexin 1 during EGF receptor internalization, we followed the distribution of annexin 1-GFP fusion proteins at sites of internalizing EGF receptors. The observed association of annexin 1 with EGF receptors was confirmed by immunoprecipitation. We found that this interaction was independent of a functional phosphorylation site in the annexin 1 N-terminal domain but mediated through the Ca2+ binding core domain.     

The relationship between the binding of ATP and calcium to annexin IV. Effect of nucleotide on the calcium-dependent interaction of annexin with phosphatidylserine

With the use of ATP analogues, we have found that porcine liver annexin (Anx) IV can be covalently labelled with 8-azido[γ-³²P]-ATP In the presence of Ca²⁺ (K_d 4.2 μM) and that the labelling is prevented by asolectin/cholesterol liposomes or chelation of calcium ions. On the other hand, non-covalent binding of 2 -(or 3)-0-(2,4,6-trinitrophenyl)adenoslne 5-triphosphate (TNP-ATP) to AnxlV occurs optimally in the presence of liposomes and Ca²⁺ (K_d 7 μM). These observations were further confirmed by the results of intrinsic fluorescence quenching of AnxlV with various nucleotides, suggesting the existence of a relationship between Ca²⁺, phospholipid- and ATP-binding sites within the annexin molecule. The Interaction of AnxIV with nucleotides does not significantly affect its In vitro properties concerning the binding to phosphatidylserine (PS) monolayers.     

Membrane-induced folding and structure of membrane-bound annexin A1 N-terminal peptides: implications for annexin-induced membrane aggregation

Annexins constitute a family of calcium-dependent membrane-binding proteins and can be classified into two groups, depending on the length of the N-terminal domain unique for each individual annexin. The N-terminal domain of annexin A1 can adopt an α-helical conformation and has been implicated in mediating the membrane aggregation behavior of this protein. Although the calcium-independent interaction of the annexin A1 N-terminal domain has been known for some time, there was no structural information about the membrane interaction of this secondary membrane-binding site of annexin A1. This study used circular dichroism spectroscopy to show that a rat annexin A1 N-terminal peptide possesses random coil structure in aqueous buffer but an α-helical structure in the presence of small unilamellar vesicles. The binding of peptides to membranes was confirmed by surface pressure (Langmuir film balance) measurements using phosphatidylcholine/phosphatidylserine monolayers, which show a significant increase after injection of rat annexin A1 N-terminal peptides. Lamellar neutron diffraction with human and rat annexin A1 N-terminal peptides reveals an intercalation of the helical peptides with the phospholipid bilayer, with the helix axis lying parallel to the surface of membrane. Our findings confirm that phospholipid membranes assist the folding of the N-terminal peptides into α-helical structures and that this conformation enables favorable direct interactions with the membrane. The results are consistent with the hypothesis that the N-terminal domain of annexin A1 can serve as a secondary membrane binding site in the process of membrane aggregation by providing a peripheral membrane anchor.     

Identification of a domain that mediates vesicle aggregation reveals functional diversity of annexin repeats.

Annexins are structurally related proteins that bind phospholipids in a Ca2(+)-dependent manner and possess at least four conserved 70-amino acid repeat domains. The ability of certain annexins to promote contact between vesicle membranes in vitro has prompted the suggestion that these proteins regulate membrane traffic in exocytosis. We have previously found that annexins I and II promote contact between vesicles whereas annexin V does not. In order to understand the mechanism of annexin I-mediated vesicle-vesicle contact, we prepared a monoclonal antibody that specifically inhibits annexin I-mediated vesicle aggregation. We identified the domain of annexin I recognized by this monoclonal antibody by using it to screen an expression library containing random fragments of annexin I cDNA. The antibody identified a fragment encoding amino acids 41-118 (the first repeat plus 8 residues of the amino-terminal tail). We constructed a chimeric protein containing these amino acids of annexin I fused to the second, third, and fourth repeats of annexin V. Transfer of this domain conferred the ability to promote vesicle aggregation, confirming that this domain participates directly in mediating contact between vesicle membranes.     

Detection of annexin IV in bovine retinal rods

The fraction of proteins capable of binding to photoreceptor membranes in a Ca²⁺-dependent manner was isolated from bovine rod outer segments. One of these proteins with apparent molecular mass of 32 kD (p32) was purified to homogeneity and identified as annexin IV (endonexin) by MALDI-TOF mass-spectrometry. In immunoblot, annexin IV purified from bovine rod outer segments cross-reacted with antibodies against annexin IV from bovine liver. This is the first detection of annexin IV in vertebrate retina.     

High-resolution structures of annexin A5 in a two-dimensional array

Annexins are soluble cytosolic proteins that bind to cell membranes. Annexin A5 self-assembles into a two-dimensional (2D) array and prevents cell rupture by attaching to damaged membranes. However, this process is not fully understood at the molecular level. In this study, we determined the crystal structures of annexin A5 with and without calcium (Ca²⁺) and confirmed the Ca²⁺-dependent outward motion of a tryptophan residue. Strikingly, the two structures exhibited the same crystal packing and 2D arrangement into a p3 lattice, which agrees well with the results of low-resolution structural imaging. High-resolution structures indicated that a three-fold interaction near the tryptophan residue is important for mediating the formation of the p3 lattice. A hypothesis on the promotion of p3 lattice formation by phosphatidyl serine (PS) is also suggested. This study provides molecular insight into how annexins modulate the physical properties of cell membranes as a function of Ca²⁺ concentration and the phospholipid composition of the membrane.     

Identification of three annexin IX isoforms generated by alternative splicing of the carboxyl-terminal exon in silkworm, Bombyx mori.

Annexins (ANXs) are a family of structurally related proteins with Ca(2+)-dependent phospholipid-binding properties. Here we report the cloning of three cDNAs each encoding annexin IX (ANX IX) isoforms from unfertilized eggs of the silkworm, Bombyx mori. The analysis of exon/intron structures showed that the three mRNAs, named ANX IX-A (2300bp), ANX IX-B (1884bp) and ANX IX-C (1409bp), respectively, were generated from a single gene by alternative usage of a 3'-splice site of the last exon. Thus the three isoforms have an identical sequence from amino acid residues 1 to 307 and this region shows approximately 77% identity to Drosophila melanogaster ANX IX. Only amino acid residues 308-324 (A) or 308-323 (B and C), which correspond to the C-terminal tail, are different in the three proteins. A RT-PCR analysis indicated that the three isoforms of silkworm ANX IX were specifically expressed in various larval tissues and development stages. Interestingly, the C-terminal tail in ANXs I, II and V were previously confirmed as a binding region for protein kinase C. Thus generation of the three ANX IX isoforms in the silkworm, that are different from other ANXs, may have a functional significance other than binding to Ca(2+).     

Molecular evolution of SPARC: absence of the acidic module and expression in the endoderm of the starlet sea anemone, Nematostella vectensis

The matricellular glycoprotein SPARC is composed of three functional domains that are evolutionarily conserved in organisms ranging from nematodes to mammals: a Ca²⁺-binding glutamic acid-rich acidic domain at the N-terminus (domain I), a follistatin-like module (domain II), and an extracellular Ca²⁺-binding (EC) module that contains two EF-hands and two collagen-binding epitopes (domain III). We report that four SPARC orthologs (designated nvSPARC1-4) are expressed by the genome of the starlet anemone Nematostella vectensis, a diploblastic basal cnidarian composed of an ectoderm and endoderm separated by collagen-based mesoglea. We also report that domain I is absent from all N. vectensis SPARC orthologs. In situ hybridization data indicate that N. vectensis SPARC mRNAs are restricted to the endoderm during post-gastrula development. The absence of the Ca²⁺-binding N-terminal domain in cnidarians and conservation of collagen-binding epitopes suggests that SPARC first evolved as a collagen-binding matricellular glycoprotein, an interaction likely to be dependent on the binding of Ca²⁺-ions to the two EF-hands in the EC domain. We propose that further Ca²⁺-dependent activities emerged with the acquisition of an acidic N-terminal module in triplobastic organisms.     

Insights into S100 target specificity examined by a new interaction between S100A11 and annexin A2

S100 proteins are a group of EF-hand calcium-signaling proteins, many of which interact with members of the calcium- and phospholipid-binding annexin family of proteins. This calcium-sensitive interaction enables two neighboring membrane surfaces, complexed to different annexin proteins, to be brought into close proximity for membrane reorganization, using the S100 protein as a bridging molecule. S100A11 and S100A10 are two members of the S100 family found to interact with the N-termini of annexins A1 and A2, respectively. Despite the high degree of structural similarity between these two complexes and the sequences of the peptides, earlier studies have shown that there is little or no cross-reactivity between these two S100s and the annexin peptides. In the current work the specificity and the affinity of the interaction of the N-terminal sequences of annexins A1 and A2 with Ca2+-S100A11 were investigated. Through the use of alanine-scanning peptide array experiments and NMR spectroscopy, an approximate 5-fold tighter interaction was identified between Ca2+-S100A11 and annexin A2 (approximately 3 microM) compared to annexin A1 (approximately 15 microM). Chemical shift mapping revealed that the binding site for annexin A2 on S100A11 was similar to that observed for the annexin A1 but with distinct differences involving the C-terminus of the annexin A2 peptide. In addition, kinetic measurements based on NMR titration data showed that annexin A2 binding to Ca2+-S100A11 occurs at a comparable rate (approximately 120 s(-1)) to that observed for membrane fusion processes such as endo- and exocytosis.     

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.     

Phosphorylation of annexin I by TRPM7 channel-kinase

TRPM7 is an unusual bifunctional molecule consisting of a TRP ion channel fused to a protein kinase domain. It has been shown that TRPM7 plays a key role in the regulation of intracellular magnesium homeostasis as well as in anoxic neuronal death. TRPM7 channel has been characterized using electrophysiological techniques; however, the function of the kinase domain is not known and endogenous substrates for the kinase have not been reported previously. Here we have identified annexin 1 as a substrate for TRPM7 kinase. Phosphorylation of annexin 1 by TRPM7 kinase is stimulated by Ca2+ and is dramatically increased in extracts from cells overexpressing TRPM7. Phosphorylation of annexin 1 by TRPM7 kinase occurs at a conserved serine residue (Ser5) located within the N-terminal amphipathic alpha-helix of annexin 1. The N-terminal region plays a crucial role in interaction of annexin 1 with other proteins and membranes, and therefore, phosphorylation of annexin 1 at Ser5 by TRPM7 kinase may modulate function of annexin 1.     

X-ray structure of full-length annexin 1 and implications for membrane aggregation

Annexins comprise a multigene family of Ca2+ and phospholipid- binding proteins. They consist of a conserved C-terminal or core domain that confers Ca2+-dependent phospholipid binding and an N-terminal domain that is variable in sequence and length and responsible for the specific properties of each annexin. Crystal structures of various annexin core domains have revealed a high degree of similarity. From these and other studies it is evident that the core domain harbors the calcium-binding sites that interact with the phospholipid headgroups. However, no structure has been reported of an annexin with a complete N-terminal domain. We have now solved the crystal structure of such a full-length annexin, annexin 1. Annexin 1 is active in membrane aggregation and its refined 1.8 A structure shows an alpha-helical N-terminal domain connected to the core domain by a flexible linker. It is surprising that the two alpha-helices present in the N-terminal domain of 41 residues interact intimately with the core domain, with the amphipathic helix 2-12 of the N-terminal domain replacing helix D of repeat III of the core. In turn, helix D is unwound into a flap now partially covering the N-terminal helix. Implications for membrane aggregation will be discussed and a model of aggregation based on the structure will be presented.     

Cholesterol regulates membrane binding and aggregation by annexin 2 at submicromolar Ca2+ concentration

Annexin 2 is a member of the annexin family which has been implicated in calcium-regulated exocytosis. This contention is largely based on Ca²⁺-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-β-cyclodextrin, a reagent which depletes cholesterol from membranes. Restoration of the cholesterol content of chromaffin granule membranes with cholesterol/methyl-β-cyclodextrin complexes restored the Ca²⁺-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 Ca²⁺, 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 Ca²⁺ 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 Ca²⁺ concentration. Annexin 2 might be associated with membrane domains enriched in phosphatidylserine and cholesterol.     

Structural elucidation of the protein- and membrane-binding properties of the N-terminal tail domain of human annexin II

The conformational preferences and the solution structure of AnxII(N31), a peptide corresponding to the full-length sequence (residues 1-31) of the human annexin II N-terminal tail domain, were investigated by circular dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopy. CD results showed that AnxII(N31) adopts a mainly alpha-helical conformation in hydrophobic or membrane-mimetic environments, while a predominantly random structure is adopted in aqueous buffer. In contrast to previous results of the annexin I N-terminal domain peptide [Yoon et al. (2000) FEBS Lett. 484, 241-245], calcium ions showed no effect on the structure of AnxII(N31). The NMR-derived structure of AnxII(N31) in 50% TFE/water mixture showed a horseshoe-like fold comprising the N-terminal amphipathic alpha-helix, the following loop, and the C-terminal helical region. Together, the results establish the first detailed structural data on the N-terminal tail domain of annexin II, and suggest the possibility of the domain to undergo Ca(2+)-independent membrane-binding.     

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

Annexin A2 (AnxA2) is a Ca²⁺- and phospholipid-binding protein involved in many cellular regulatory processes. Like other annexins, it is constituted by two domains: a conserved core, containing the Ca²⁺ 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 Ca²⁺-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 Ca²⁺.