Two novel annexins from Drosophila melanogaster. Cloning, characterization, and differential expression in development

The annexins are a family of homologous Ca2(+)- and phospholipid-binding proteins that until now have only been found in vertebrates. cDNA clones encoding two novel annexins from Drosophila melanogaster were isolated and characterized. RNA blots indicate that the messages for the two Drosophila proteins are differentially expressed in development, with one message being expressed throughout development, while the other is only found in early embryos and adult flies. In situ hybridizations localize the two Drosophila genes to 93B and 19A-4,7. A similarly high degree of homology relates Drosophila annexins to different vertebrate annexins, indicating that the Drosophila annexins are not the invertebrate homologues of particular mammalian annexins but that they constitute novel members of the annexin gene family. In continuation with a recently established terminology, the Drosophila annexins will be named annexins IX and X. The biochemical properties of Drosophila annexin X were investigated using recombinant protein. Similar to vertebrate annexins, annexin X bound to liver membranes and liposomes containing phosphatidylserine in a calcium-dependent manner but not to liposomes containing phosphatidylcholine. In addition, annexin X partitioned into the detergent phase of Triton X-114 as a function of calcium. The conservation of the annexin family of Ca2(+)-binding proteins in invertebrates suggests that they have a basic function in cells which is not peculiar to vertebrate biology, and the availability of the Drosophila sequences will open avenues for mutational studies of these functions.     

Annexins as intracellular calcium sensors

The annexins are a multigene family of Ca(2+)- and charged phospholipid-binding proteins. Although they have been ascribed with diverse functions, there is no consensus about the role played by this family as a whole. We have mapped the Ca(2+)-induced translocations of four members of the annexin family and of two truncated annexins in live cells, and demonstrated that these proteins interact with the plasma membrane as well as with internal membrane systems in a highly coordinated manner. Annexin 2 was the most Ca(2+) sensitive of the studied proteins, followed by annexins 6, 4 and 1. The calcium sensitivity of annexin 2 increased further following co-expression with S100A10. Upon elevation of [Ca(2+)](i), annexins 2 and 6 translocated to the plasma membrane, whereas annexins 4 and 1 also became associated with intracellular membranes and the nuclear envelope. The NH(2)-terminus had a modulatory effect on plasma membrane binding: its truncation increased the Ca(2+) sensitivity of annexin 1, and decreased that of annexin 2. Given the fact that several annexins are present within any one cell, it is likely that they form a sophisticated [Ca(2+)] sensing system, with a regulatory influence on other signaling pathways.     

Calcium signaling and annexins

The annexins, are a family of calcium ion (Ca2+)-binding proteins whose physiological functions are poorly understood. Although many diverse functions have been proposed for these proteins, such as in vesicle trafficking, this review focuses on their proposed roles as Ca2+ or other ion channels, or as intracellular ion channel regulators. Such ideas are founded mainly on in vitro and structural analyses, but there is increasing evidence that at least some members of this protein family may indeed play a part in intracellular Ca2+ signaling by acting both as atypical ion channels and as modulators of ion channel activity. This review first introduces the annexin family, then discusses intracellular localization, developmental regulation, and modes of membrane association of annexins, which suggest roles in Ca2+ homeostasis. Finally, it examines the structural and electrophysiological data that argue for key roles for annexins in the control of ion fluxes.     

Structural determinants for plant annexin-membrane interactions

The interactions of two plant annexins, annexin 24(Ca32) from Capsicum annuum and annexin Gh1 from Gossypium hirsutum, with phospholipid membranes have been characterized using liposome-based assays and adsorption to monolayers. These two plant annexins show a preference for phosphatidylserine-containing membranes and display a membrane binding behavior with a half-maximum calcium concentration in the sub-millimolar range. Surprisingly, the two plant annexins also display calcium-independent membrane binding at levels of 10-20% at neutral pH. This binding is regulated by three conserved surface-exposed residues on the convex side of the proteins that play a pivotal role in membrane binding. Due to quantitative differences in the membrane binding behavior of N-terminally His-tagged and wild-type annexin 24(Ca32), we conclude that the N-terminal domain of plant annexins plays an important role, reminiscent of the findings in their mammalian counterparts. Experiments elucidating plant annexin-mediated membrane aggregation and fusion, as well as the effect of these proteins on membrane surface hydrophobicity, agree with findings from the membrane binding experiments. Results from electron microscopy reveal elongated rodlike assemblies of plant annexins in the membrane-bound state. It is possible that these structures consist of protein molecules directly interacting with the membrane surface and molecules that are membrane-associated but not in direct contact with the phospholipids. The rodlike structures would also agree with the complex data from intrinsic protein fluorescence. The tubular lipid extensions suggest a role in the membrane cytoskeleton scaffolding or exocytotic processes. Overall, this study demonstrates the importance of subtle changes in an otherwise conserved annexin fold where these two plant annexins possess distinct modalities compared to mammalian and other nonplant annexins.     

Rabbit annexins: comparison of a series of proteins in cell-free homogenates and membranes from various tissues and a method of rapid preliminary identification of individual components after two-dimensional electrophoresis]

The annexin sets in cell-free homogenates and membranes of rabbit skeletal and heart muscles, liver, kidney, lung, and brain, have been compared by one- and two-dimensional electrophoresis. The pIs and M(r)s of the proteins identified have been determined. The data on two-dimensional electrophoresis of annexins from different animals have been systematized. Simple graphs are proposed which allow to identify annexins on electrophoregrams. The technique has definite potentialities in recognition of some unidentified Ca(2+)-dependent membrane-binding proteins and may be used to predict the trend of search for novel members of the annexin family.     

Allosterism in membrane binding: a common motif of the annexins?

Annexins are a family of proteins generally described as Ca(2+)-dependent for phospholipid binding. Yet, annexins have a wide variety of binding behaviors and conformational states, some of which are lipid-dependent and Ca(2+)-independent. We present a model that captures the cation and phospholipid binding behavior of the highly conserved core of the annexins. Experimental data for annexins A4 and A5, which have short N-termini, were globally modeled to gain an understanding of how the lipid-binding affinity of the conserved protein core is modulated. Analysis of the binding behavior was achieved through use of the lanthanide Tb(3+) as a Ca(2+) analogue. Binding isotherms were determined experimentally from the quenching of the intrinsic fluorescence of annexins A4 and A5 by Tb(3+) in the presence or absence of membranes. In the presence of lipid, the affinity of annexin for cation increases, and the binding isotherms change from hyperbolic to weakly sigmoidal. This behavior was modeled by isotherms derived from microscopic binding partition functions. The change from hyperbolic to sigmoidal binding occurs because of an allosteric transition from the annexin solution state to its membrane-associated state. Protein binding to lipid bilayers renders cation binding by annexins cooperative. The two annexin states denote two affinities of the protein for cation, one in the absence and another in the presence of membrane. In the framework of this model, we discuss membrane binding as well as the influence of the N-terminus in modifying the annexin cation-binding affinity by changing the probability of the protein to undergo the postulated two-state transition.     

Membrane-bound annexin V isoforms (CaBP33 and CaBP37) and annexin VI in bovine tissues behave like integral membrane proteins.

The distribution of annexin V isoforms (CaBP33 and CaBP37) and of annexin VI in bovine lung, heart, and brain subfractions was investigated with special reference to the fractions of these proteins which are membrane-bound. In addition to EGTA-extractable pools of the above proteins, membranes from lung, heart, and brain contain EGTA-resistant annexins V and VI which can be solubilized with detergents (Triton X-100 or Triton X-114). A strong base like Na2CO3, which is usually effective in extracting membrane proteins, only partially solubilizes the membrane-bound, EGTA-resistant annexins analyzed here. Also, only 50-60% of the Triton X-114-soluble annexins partition in the aqueous phase, the remaining fractions being recovered in the detergent-rich phase. Altogether, these findings suggest that, by an as yet unknown mechanism, following Ca(2+)-dependent association of annexin V isoforms and annexin VI with membranes, substantial fractions of these proteins remain bound to membranes in a Ca(2+)-independent way and behave like integral membrane proteins. These results further support the possibility that the above annexins might play a role in membrane trafficking and/or in the regulation of the structural organization of membranes.     

Structure of soluble and membrane-bound human annexin V.

Annexins are a family of water-soluble proteins that bind to membranes in a calcium-dependent manner. Some members have been shown to exhibit voltage-dependent calcium channel activity, a property characteristic of integral membrane proteins. The structures of human annexin V in crystals obtained from aqueous solution and in two-dimensional crystals when bound to phospholipid layers have been determined by X-ray and electron crystallography, respectively. They are compared here. Both structures show close correspondence, suggesting that annexins attach to phospholipid membranes without substantial structural change. These observations, together with biochemical data, lead to the conclusion that annexin V interacts with phospholipid membranes with its convex face. We propose that binding is mediated by direct interaction between the phosphoryl headgroups and the calcium bound to polypeptide loops protruding from the convex face. The membrane area covered by annexin may thus become disordered and permeable allowing calcium flux through the membrane and the central channel-like structure found in annexin molecules.     

Characterizing the binding of annexin V to a lipid bilayer using molecular dynamics simulations

Annexins play critical roles in membrane organization, membrane trafficking and vesicle transport. The family members share the ability to bind to membranes with high affinities, but the interactions between annexins and membranes remain unclear. Here, using long‐time molecular dynamics simulations, we provide detailed information for the binding of an annexin V trimer to a POPC/POPS lipid bilayer. Calcium ions function as bridges between several negatively charged residues of annexin V and the oxygen atoms of lipids. The preferred calcium‐bridges are those formed via the carboxyl oxygen atoms of POPS lipids. H‐bonds and hydrophobic interactions formed by several critical residues have also been observed in the annexin‐membrane interface. The annexin‐membrane binding causes small changes of annexin trimer structures, while has significant effects on lipid bilayer structures. The lipid bilayer shows a bent shape and forms a concave region in the annexin‐membrane interaction interface, which provides an atomic‐level evidence to support the view that annexins could disturb the stability of lipids and bend membranes. This study provides insights into the commonly occurring PS‐dependent and calcium‐dependent binding of proteins to membranes. Proteins 2014; 82:312–322. © 2013 Wiley Periodicals, Inc.     

Formation of tightly bound forms of annexins V and VI in rabbit skeletal muscle membranes isolated in the presence of barium ions

After isolation of rabbit skeletal muscle membranes in the presence of Ba2+ or Ca2+, significant portions of annexin V and VI tightly bind to membranes and become inaccessible for chelating agents. Tightly bound annexin VI is virtually completely solubilized only after treatment with a buffer supplemented both with EGTA and detergent. The portion of tightly bound annexin V cannot be removed even by extraction with buffer containing both EGTA and detergent. In some cases, tightly bound annexin V or VI is detected even in the control (not treated with cations) membranes, thus indicating the possible formation of tight annexin--membrane complexes in situ. The addition of exogenous cations seems to promote only the accumulation of tightly bound annexins within the cell. After temperature-induced phase separation, annexin V and VI bound to the membranes isolated in the presence of Ba2+ or Ca2+ remains mainly in the aqueous phase, similarly to annexins isolated from the control membranes. Neither annexin partitions into the detergent-enriched phase. This indicates the absence of hydrophobicity change in comparison with the standard EGTA-soluble annexins.     

S100-annexin complexes--structural insights

Annexins and S100 proteins represent two large, but distinct, calcium-binding protein families. Annexins are made up of a highly alpha-helical core domain that binds calcium ions, allowing them to interact with phospholipid membranes. Furthermore, some annexins, such as annexins A1 and A2, contain an N-terminal region that is expelled from the core domain on calcium binding. These events allow for the interaction of the annexin N-terminus with target proteins, such as S100. In addition, when an S100 protein binds calcium ions, it undergoes a structural reorientation of its helices, exposing a hydrophobic patch capable of interacting with its targets, including the N-terminal sequences of annexins. Structural studies of the complexes between members of these two families have revealed valuable details regarding the mechanisms of the interactions, including the binding surfaces and conformation of the annexin N-terminus. However, other S100-annexin interactions, such as those between S100A11 and annexin A6, or between dicalcin and annexins A1, A2 and A5, appear to be more complicated, involving the annexin core region, perhaps in concert with the N-terminus. The diversity of these interactions indicates that multiple forms of recognition exist between S100 proteins and annexins. S100-annexin interactions have been suggested to play a role in membrane fusion events by the bridging together of two annexin proteins, bound to phospholipid membranes, by an S100 protein. The structures and differential interactions of S100-annexin complexes may indicate that this process has several possible modes of protein-protein recognition.     

Purification of recombinant annexins without the use of phospholipids

Due to their involvement in a variety of physiological and pathological processes, different isoforms of annexins are being utilized as markers of some human diseases and bio-imaging of tissue injury (due to apoptosis), and have been proposed as drug delivery vehicles. These, in addition to extensive biophysical studies on the role of annexins in organizing lipid domains in biological membranes, have necessitated development of an efficient protocol for producing annexins in bulk quantities. In this paper, we report a one-step purification protocol for annexin a5 without using lipid vesicles or involving any column chromatographic step. Depending on the growth and expression condition, a fraction of recombinant annexin a5 (cloned in pET3d vector) was sequestered into inclusion bodies. When these inclusion bodies were dissolved in 6 M urea, subjected to a 10-fold snap dilution in the presence of 5 mM Ca(2+) and stored overnight at 4 degrees C, annexin a5 was precipitated as a homogenous protein as judged by SDS-PAGE. This one-step purification protocol produced about 35 mg of highly purified annexin a5 per liter of bacterial culture. The annexin a5 purified from inclusion bodies exhibited similar properties to that obtained from the soluble fraction using the conventional lipid-partitioning approach. Our purification protocol for annexin a5 elaborated herein is equally effective for purification of annexin A2, and we believe, will serve as general protocol for purifying other annexins in bulk quantities for diagnostic as well as detailed biophysical studies.     

Annexin II tetramer: structure and function

The annexins are a family of proteins that bind acidic phospholipids in the presence of Ca²⁺. The interaction of these proteins with biological membranes has led to the suggestion that these proteins may play a role in membrane trafficking events such as exocytosis, endocytosis and cell-cell adhesion. One member of the annexin family, annexin II, has been shown to exist as a monomer, heterodimer or heterotetramer. The ability of annexin II tetramer to bridge secretory granules to plasma membrane has suggested that this protein may play a role in Ca²⁺-dependent exocytosis. Annexin II tetramer has also been demonstrated on the extracellular face of some metastatic cells where it mediates the binding of certain metastatic cells to normal cells. Annexin II tetramer is a major cellular substrate of protein kinase C and pp60^src. Phosphorylation of annexin II tetramer is a negative modulator of protein function.Supported by a grant from the Medical Research Council of Canada     

The annexinopathies: a new category of diseases

The annexins are a family of highly homologous phospholipid binding proteins, which share a four-domain structure, with one member of the family - annexin VI - having a duplication consisting of eight domains. Thus far, ten annexins have been described in mammals. Although the biological functions of the annexins have not been definitively established, two human diseases involving annexin abnormalities ('annexinopathies') have been identified as of the time of writing. Overexpression of annexin II occurs in the leukocytes of a subset of patients having a hemorrhagic form of acute promyelocytic leukemia. Underexpression of annexin V occurs on placental trophoblasts in the antiphospholipid syndrome and in preeclampsia. Also, an animal model has been described in which annexin VII is underexpressed and is associated with disease, but the relevance of this animal model to human disease is not yet understood. Future research is likely to elucidate additional 'annexinopathies'.     

Annexin B12 is a sensor of membrane curvature and undergoes major curvature-dependent structural changes

The regulation of membrane curvature plays an important role in many membrane trafficking and fusion events. Recent studies have begun to identify some of the proteins involved in controlling and sensing the curvature of cellular membranes. A mechanistic understanding of these processes is limited, however, as structural information for the membrane-bound forms of these proteins is scarce. Here, we employed a combination of biochemical and biophysical approaches to study the interaction of annexin B12 with membranes of different curvatures. We observed selective and Ca(2+)-independent binding of annexin B12 to negatively charged vesicles that were either highly curved or that contained lipids with negative intrinsic curvature. This novel curvature-dependent membrane interaction induced major structural rearrangements in the protein and resulted in a backbone fold that was different from that of the well characterized Ca(2+)-dependent membrane-bound form of annexin B12. Following curvature-dependent membrane interaction, the protein retained a predominantly alpha-helical structure but EPR spectroscopy studies of nitroxide side chains placed at selected sites on annexin B12 showed that the protein underwent inside-out refolding that brought previously buried hydrophobic residues into contact with the membrane. These structural changes were reminiscent of those previously observed following Ca(2+)-independent interaction of annexins with membranes at mildly acidic pH, yet they occurred at neutral pH in the presence of curved membranes. The present data demonstrate that annexin B12 is a sensor of membrane curvature and that membrane curvature can trigger large scale conformational changes. We speculate that membrane curvature could be a physiological signal that induces the previously reported Ca(2+)-independent membrane interaction of annexins in vivo.     

Annexins and disease

The annexins are a family of closely related calcium- and membrane-binding proteins expressed in most eukaryotic cell types. Despite their structural and biochemical similarities annexins have diverse functions, in cellular activities that include vesicle trafficking, cell division, apoptosis, calcium signalling, and growth regulation. To date there is no evidence to suggest that any individual member of the annexin family is a disease-causing gene, i.e., a gene that through loss, mutation, translocation or amplification leads to a known human disease. However, there is good evidence that in certain clinical conditions, changes in annexin expression levels or localisation may contribute to the pathological consequences and sequelae of disease. In this way, annexins are indirectly linked to some of the most serious human disease classes including cardiovascular disease and cancer. In this review we consider the roles played by annexins in disease and examine the molecular basis for anomalous annexin behaviour that may contribute to disease pathophysiology.     

Annexins in the Human Neuroblastoma SH-SY5Y: Demonstration of Relocation of Annexins II and V to Membranes in Response to Elevation of Intracellular Calcium by Membrane Depolarisation and by the Calcium Ionophore A23187

Abstract: The human neuroblastoma SH-SY5Y was found to express annexins I, II, IV, V, and VI by western blot analysis. Calcium-dependent membrane-binding proteins were isolated from SH-SY5Y and analysed by 2-dimensional gel electrophoresis. Proteins with M_r and pl values similar to those of annexins I, II, III, IV, V, and VI were observed. The identity of annexins II and V was confirmed by western blotting. The membrane association of annexins II and V was studied in cells that had been stimulated to release noradrenaline by K⁺ depolarisation or by treatment with the ionophore A23187. Annexins II and V were both found to associate with membranes in a manner that was resistant to elution with EGTA and required Triton X-100 for their solubilisation. Homogenisation of cells in calcium-containing buffers also resulted in the formation of EGTA-resistant membrane-associated annexins II and V. The results demonstrate calcium-dependent relocation of annexins II and V to membranes in intact cells and suggest that these annexins bind in a calcium-dependent manner to non-phospholipid components of SH-SY5Y membranes. Examination of cells by immunofluorescence microscopy demonstrated that annexin II was homogeneously associated with the plasma membrane before treatment with ionophore and relocated to discrete patches of staining after treatment. Annexin V was found by immunofluorescence to be present in the cytoplasm and in the nucleus. Stimulation of the cells produced no change in the cytoplasmic staining pattern but resulted in a partial relocation of nuclear annexin V to the periphery of the nucleus. The results argue for a general role for both annexins in calcium signalling at discrete intracellular locations. The results are not consistent with the specific involvement proposed previously for annexin II in membrane fusion at sites of vesicle exocytosis.     

Calcium-dependent self-association of annexin II: a possible implication in exocytosis.

Alveolar type II cells secrete lung surfactant through exocytosis of lamellar bodies. We previously showed that the annexin II tetramer (Anx IIt) mediates the fusion of lamellar bodies with liposomes. The present study examined the possible involvement of membrane proteins in this process. Pre-treatment of lamellar bodies with trypsin and alpha-chymotrypsin reduced Anx IIt-mediated membrane fusion. With the use of an Anx IIt-conjugated Sepharose column, three Anx IIt-binding proteins with molecular weights of 67,000, 36,000 and 34,000 were isolated froM the Triton X-100 extract of bovine lung tissue membranes. These proteins were identified as annexins VI, II and IV by Western blot. The interaction of Anx IIt with annexins II and IV was confirmed by ligand blot assay. An EGTA-resistant membrane-bound annexin II was present in lung type II cells. Anx IIt preferentially hound to membranous annexin II compared with cytosolic annexin II of type II cells. With the use of immunofluorescence, annexin II was found to translocate from cytoplasm to plasma membranes in type II cells upon stimulation with phorbol 12-myristate 13-acetate. These results suggest that cytosolic annexin II may bind to membranous annexin II and form a protein-protein bridge to bring two membranes together.