Annexin I is stored within gelatinase granules of human neutrophil and mobilized on the cell surface upon adhesion but not phagocytosis

Annexin I, a member of the calcium- and phospholipid-binding annexin superfamily of proteins, is largely present in human neutrophils. To determine its exact intracellular distribution a combination of flow cytometry, confocal microscopy and electron microscopy analyses were performed on resting human neutrophils as well as on cells which had been activated. In resting neutrophils, annexin I was found to be present in small amounts in the nucleus, in the cytoplasm and partially also associated with the plasma membrane. The cytoplasmic pool of annexin I was predominant, and the protein was co-localized with gelatinase (marker of gelatinase granules), but not with human serum albumin or CD35 (markers of secretory vesicles), or with lysosomes. Electron microscopy showed the presence of annexin I inside the gelatinase granules. Neutrophil adhesion to monolayers of endothelial cells, but not phagocytosis of particles of opsonized zymosan, provoked an intense mobilization of annexin I, with a marked externalization on the outer leaflet of the plasma membrane. Remaining intracellular annexin I was also found in proximity of the plasma membrane. These results provide a novel mechanism for annexin I secretion from human neutrophils, which is via a degranulation event involving gelatinase granules.     

A novel ligand of the formyl peptide receptor: annexin I regulates neutrophil extravasation by interacting with the FPR

The glucocorticoid-regulated protein annexin I (lipocortin I) has been shown to mediate antiinflammatory activities of glucocorticoids, but the molecular basis of its action has remained elusive. Here we show that annexin I acts through the formyl peptide receptor (FPR) on human neutrophils. Peptides derived from the unique N-terminal domain of annexin I serve as FPR ligands and trigger different signaling pathways in a dose-dependent manner. Lower peptide concentrations possibly found in inflammatory situations elicit Ca2+ transients without fully activating the MAP kinase pathway. This causes a specific inhibition of the transendothelial migration of neutrophils and a desensitization of neutrophils toward a chemoattractant challenge. These findings identify annexin I peptides as novel, endogenous FPR ligands and establish a mechanistic basis of annexin I-mediated antiinflammatory effects.     

Endogenous cleavage of annexin I generates a truncated protein with a reduced calcium requirement for binding to neutrophil secretory vesicles and plasma membrane

We have earlier shown that an N-terminal truncated annexin I molecule, annexin I(des1-8), is generated in human neutrophils through cleavage by a membrane localized metalloprotease. The truncated protein showed differences in membrane binding among the neutrophil granule populations as compared to full-length annexin I. In this study, we investigated the cleavage capabilities of isolated neutrophil secretory vesicles and plasma membrane, and the binding of full-length annexin I and annexin I(des1-8) to these membrane fractions. Translocations were performed in vitro to secretory vesicles and plasma membrane, respectively, at different Ca(2+) concentrations. We show that the annexin I-cleaving membrane localized metalloprotease is present both in the secretory vesicles and the plasma membrane. The N-terminal truncation of annexin I gives rise to a molecule with a decreased Ca(2+) requirement for binding, both to secretory vesicles and plasma membrane. There was, thus, no difference in binding of either full-length annexin I or annexin I(des1-8) to the secretory vesicles as compared to the plasma membrane.     

Annexin I-mediated vesicular aggregation: mechanism and role in human neutrophils.

Whole cytosol isolated from human neutrophils was found to accelerate the Ca(2+)-dependent fusion of phospholipid vesicles with neutrophil plasma membranes as measured by several fluorescence resonance energy transfer lipid dilution assays or by the fate of an encapsulated aqueous soluble fluorophore. The Ca2+ (threshold of 2-10 microM) and protein concentration dependencies for fusion mediated by purified human neutrophil annexin I (lipocortin I), recombinant annexin I and des(1-9)annexin I showed behavior similar to that of whole cytosol. A monoclonal antibody against the N-terminal region of annexin I strongly inhibited the action of isolated annexins as well as whole cytosol, indicating that annexin I is the major activity of this type in whole neutrophil cytosol and that it functions even in this complex mixture of proteins. Residual Ca(2+)-dependent fusion activity in the absence of cytosol or annexin I was not inhibited by several antibodies against annexin I, implicating an as yet unknown protein. Kinetic analysis of liposomal fusion showed that annexin I, as in the case of synexin, accelerates aggregation of vesicles but not the actual fusion event per se. The disposition of annexin I in liposomal aggregates was studied by monitoring binding of the protein with a pyrene-phospholipid and by simultaneously monitoring vesicular aggregation by turbidity. An antibody to the N-terminus of annexin I inhibited vesicular aggregation but not binding, suggesting that initial binding of annexin I is similar to that of annexin V. A relatively small proportion of the bound annexin was involved in intervesicular linkage, and no exchange of bound annexin to subsequently added vesicles was observed. The lack of extensive contact between lipids of aggregated vesicles was supported by a lack of energy transfer between phospholipid probes on separate aggregating vesicles. Covalent linkage of maleimidyl or photoaffinity phospholipid derivatives with annexin I in vesicular aggregates did not allow complete disaggregation of vesicles by EDTA, suggesting that monomers of annexin I can contact two membranes simultaneously at the point of intervesicular linkage. These data are discussed in terms of possible models for the structure of this site.     

Annexin III translocates to the periphagosomal region when neutrophils ingest opsonized yeast.

After phagocytosis, killing and digestion of ingested microorganisms depend on fusion of phagocytic vesicle membranes with membranes of intracellular vesicles (azurophil and specific granules). There is considerable evidence that phagosome-granule membrane fusion is regulated by transient increases in intracellular ionized Ca2+. In previous studies, we found that a cytosolic Ca2(+)-dependent membrane-binding protein, annexin III, represents over 1% of the total protein of human neutrophils and promotes tight contact between membranes of isolated specific granules in vitro. To determine whether annexin III localizes to the region of phagosome-granule membrane fusion in vivo, we used a monospecific polyclonal antibody to stain fixed, permeabilized neutrophils that had ingested opsonized yeast. We found that annexin III concentrates in the region surrounding the phagosome. Annexin III was concentrated ninefold in the periphagosomal region compared with the cell body, as demonstrated by laser scanning confocal microscopy. Periphagosomal translocation of annexin III occurred whether yeast were opsonized with IgG, complement, or both, and persisted for at least 1 h after phagocytosis. This is not a general phenomenon, inasmuch as calmodulin was as abundant in the cell body as in the periphagosomal region. These findings imply that annexin III plays a specialized role in the metabolic and structural events that accompany phagocytosis.     

Annexin I-induced aggregation of human neutrophil gelatinase granules

The ability of neutrophil cytosol to induce the aggregation of gelatinase granules of human neutrophils was studied. The cytosol was found to induce the Ca(2+)-dependent aggregation of granules. The stimulatory effect of cytosol was considerably reduced in the presence of the monoclonal antibody recognizing annexin I. Annexin I is a mediator of Ca(2+)-dependent aggregation of gelatinase granules and probably participate in granule secretion.     

Selective secretion of annexin 1, a protein without a signal sequence, by the human prostate gland

Annexins are primarily intracellular proteins as would be predicted from their lack of hydrophobic signal sequences. However, we now report that the human prostate gland selectively secretes high concentrations of annexin 1 (also called lipocortin 1 and p35) and a proteolytic cleavage product, des1-29-annexin 1, into seminal plasma. Secreted annexin 1 had a blocked amino terminus and was structurally indistinguishable from intracellular annexin 1. Although annexin 1 and the structurally related protein, annexin 4, co-localized to many of the same cells of the ductal epithelium of the prostate, annexin 4 was not secreted. Thus, the secretion of annexin 1 appears to involve a highly selective mechanism that does not involve targeting to the endoplasmic reticulum by a hydrophobic signal sequence.     

Neutrophil necrosis and annexin 1 degradation associated with airway inflammation in lung transplant recipients with cystic fibrosis

ABSTRACT: BACKGROUND: Neutrophils sequestered in lower respiratory tract secretions in the inflamed lung may undergo apoptosis and/or necrosis and release toxic cellular contents that can injure airways or parenchyma. This study examined the viability of neutrophils retrieved from the proximal airways of lung transplant recipients with bacterial tracheobronchitis. METHODS: Integrity and stability of intracellular proteins in neutrophils from proximal airways and peripheral blood from lung transplant recipients with bacterial tracheobronchitis were analyzed via Western blot analysis and determination of neutrophil viability by morphologic appearance and flow cytometry. RESULTS: Neutrophils in tracheobronchial secretions from lung transplant recipients with cystic fibrosis who had normal chest radiographic imaging but bronchoscopic evidence of purulent tracheobronchitis post-transplant were necrotic and associated with degradation of intracellular protein annexin 1. The neutrophil influx was compartmentalized to large airways and not detected in peripheral bronchoalveolar airspaces sampled via bronchoalveolar lavage. Peripheral blood neutrophils from healthy subjects cultured in vitro demonstrated that annexin 1 degradation, particularly to a 33 kDa annexin 1 breakdown product (A1-BP), was associated with neutrophil necrosis, but not apoptosis. Although annexin 1 degradation was not specific to neutrophil necrosis, it was a sensitive marker of intracellular protein degradation associated with neutrophil necrosis. Annexin 1 degradation to 33 kDa A1-BP was not observed in peripheral blood neutrophils from healthy subjects, but annexin 1 appeared to be degraded in peripheral blood neutrophils of lung transplant recipients despite a normal morphologic appearance of these cells. CONCLUSIONS: Neutrophils were necrotic from the proximal airways of lung transplant recipients with bacterial tracheobronchitis, and this process may begin when neutrophils are still in the systemic circulation prior to sequestration in inflamed airways. Annexin 1 degradation to 33 kDa A1-BP may be useful as a sensitive marker to detect neutrophil necrosis.     

Annexin-mediated membrane fusion of human neutrophil plasma membranes and phospholipid vesicles.

Membrane fusion was studied using human neutrophil plasma membrane preparations and phospholipid vesicles approximately 0.15 microns in diameter and composed of phosphatidylserine and phosphatidylethanolamine in a ratio of 1 to 3. Liposomes were labeled with N-(7-nitrobenzo-2-oxa-1,3-diazol-4-yl (NBD) and lissamine rhodamine B derivatives of phospholipids. Apparent fusion was detected as an increase in fluorescence of the resonance energy transfer donor, NBD, after dilution of the probes into unlabeled membranes. 0.5 mM Ca2+ alone was sufficient to cause substantial fusion of liposomes with a plasma membrane preparation but not with other liposomes. Both annexin I and des(1-9)annexin I caused a substantial increase in the rate of fusion under these conditions while annexin V inhibited fusion. Fusion mediated by des(1-9)annexin I was observed at Ca2+ concentrations as low as approximately 5 microM, suggesting that the truncated form of this protein may be active at physiologically low Ca2+ concentrations. Trypsin treated plasma membranes were incapable of fusion with liposomes, suggesting that plasma membrane proteins may mediate fusion. Liposomes did not fuse with whole cells at any Ca2+ concentration, indicating that the cytoplasmic side of the membrane is involved. These results suggest that annexin I and unidentified plasma membrane proteins may play a role in Ca(2+)-dependent degranulation of human neutrophils.     

DISTRIBUTION OF ANNEXIN I DURING NON-PATHOGEN OR PATHOGEN PHAGOCYTOSIS BY CONFOCAL IMAGING AND IMMUNOGOLD ELECTRON MICROSCOPY

Annexin I is an abundant protein in U937 cells differentiated towards a macrophagic phenotype. These cells become able to killEscherichia coli, however, the intracellular pathogenBrucella suis, known to interfere with phagosome maturation, multiply in these differentiated cells. We have analysed by confocal and electron microscopy the cellular localization of annexin I during phagocytosis of yeast, non-pathogenicE. coliand the intracellular pathogenB. suis. Using immunocytochemical detections annexin I was found mainly as patches in the cytoplasm of uninfected cells. Upon phagocytosis of yeast orE. coliorganisms, annexin I rapidly translocated and concentrated around phagosomes. On the other hand, annexin I was never detected around liveB. suis-containing phagosomes. However, when dead brucellae were used, annexin I did translocate to the periphagosomal region. Our results suggest that annexin I could play a role in the molecular mechanism of phagosome maturation, which is impaired by some intracellular pathogens.     

Regulation of annexin I in rheumatoid synovial cells by glucocorticoids and interleukin-1

The glucocorticoid (GC)-induced antiinflammatory molecule annexin I is expressed in leukocytes and has antiinflammatory effects in animal models of arthritis, but the expression of annexin I in rheumatoid arthritis (RA) fibroblast-like synoviocytes (FLS) is unknown. We report the constitutive and dexamethasone (DEX)-inducible expression of annexin I in RA FLS. DEX increased FLS annexin I protein translocation and mRNA expression. Interleukin (IL)-1beta also induced annexin I translocation and mRNA but also increased intracellular protein. DEX and IL-1 had additive effects on annexin I mRNA, but DEX inhibited the inducing effect of IL-1beta on cell surface annexin I. These results indicate that glucocorticoids and IL-1beta upregulate the synthesis and translocation of annexin I in RA FLS, but interdependent signalling pathways are involved.     

Differential expression of VirB9 and VirB6 during the life cycle of Anaplasma phagocytophilum in human leucocytes is associated with differential binding and avoidance of lysosome pathway

Anaplasma phagocytophilum, an obligate intracellular bacterium, is the aetiologic agent of human granulocytic anaplasmosis (HGA). A. phagocytophilum virB/D operons encoding type IV secretion system are expressed in cell culture and in the blood of HGA patients. In the present study, their expression across the A. phagocytophilum intracellular developmental cycle was investigated. We found that mRNA levels of both virB9 and virB6 were upregulated during infection of human neutrophils in vitro. The antibody against the recombinant VirB9 protein was prepared and immunogold and immunofluorescence labelling were used to determine the VirB9 protein expression by individual organisms. Majority of A. phagocytophilum spontaneously released from the infected host cells poorly expressed VirB9. At 1 h post infection, VirB9 was not detectable on most bacteria associated with neutrophils. However, VirB9 was strongly expressed by A. phagocytophilum during proliferation in neutrophils. In contrast, with HL-60 cells, approximately 80% of A. phagocytophilum organisms associated at 1 h post infection expressed VirB9 protein and were colocalized with lysosome-associated membrane protein-1 (LAMP-1), whereas, VirB9-undetectable bacteria were not colocalized with LAMP-1. These results indicate developmental regulation of expression of components of type IV secretion system during A. phagocytophilum intracellular life cycle and suggest that bacterial developmental stages influence the nature of binding to the hosts and early avoidance of late endosome-lysosome pathway.     

Histidine phosphorylation of annexin I in airway epithelia

Although [Cl(-)](i) regulates many cellular functions including cell secretion, the mechanisms governing these actions are not known. We have previously shown that the apical membrane of airway epithelium contains a 37-kDa phosphoprotein (p37) whose phosphorylation is regulated by chloride concentration. Using metal affinity (chelating Fe(3+)-Sepharose) and anion exchange (POROS HQ 20) chromatography, we have purified p37 from ovine tracheal epithelia to electrophoretic homogeneity. Sequence analysis and immunoprecipitation using monoclonal and specific polyclonal antibodies identified p37 as annexin I, a member of a family of Ca(2+)-dependent phospholipid-binding proteins. Phosphate on [(32)P]annexin I, phosphorylated using both [gamma-(32)P]ATP and [gamma-(32)P]GTP, was labile under acidic but not alkaline conditions. Phosphoamino acid analysis showed the presence of phosphohistidine. The site of phosphorylation was localized to a carboxyl-terminal fragment of annexin I. Our data suggest that cAMP and AMP (but not cGMP) may regulate annexin I histidine phosphorylation. We propose a role for annexin I in an intracellular signaling system involving histidine phosphorylation.     

The surface receptor is involved in annexin I-stimulated insulin secretion in MIN6N8a cells

This study investigated the effect of extracellular annexin I on regulating insulin secretion in MIN6N8a (an insulin secreting cell line) cells. The properties of annexin I receptor in MIN6N8a cells were also determined. Annexin I stimulated insulin release in MIN6N8a cells, regardless of the presence or absence of extracellular Ca(2+). Confocal microscopy revealed that annexin I bound to the surface of MIN6N8a cells. In addition, FACs analysis showed that annexin I bound to the surface of MIN6N8a cells in a dose-dependent manner. However, the annexin I-stimulated insulin secretion and the annexin I binding were abolished in MIN6N8a cells treated with proteases. Annexin I receptors were regenerated time-dependently. Furthermore, annexin I-stimulated insulin secretion was inhibited by cycloheximide but not by actinomycin D. These results showed that annexin I binds to the surface receptor in order to regulate the stimulation of insulin release in MIN6N8a cells.     

Annexin I modulates cell functions by controlling intracellular calcium release.

Annexin I is an intracellular protein in search of a function. Ex vivo it has calcium- and phospholipid-binding properties. To evaluate its role in vivo, MCF-7 cells were stably transfected with annexin I in sense or antisense orientations. In cells overexpressing annexin I, calcium release was abrogated on stimulation of purinergic or bradykinin receptors, whereas non-transfected cells or cells with down-regulated annexin I released calcium within seconds. Basal calcium and calcium stores were not affected. The impaired calcium release was paralleled by a down-regulation of the activities of phospholipase C, group II phospholipase A2, and E-cadherin with altered adhesion and enhanced tumor growth on soft agar. Significantly smaller tumors, with the histologically most differentiated cells, were observed in nude mice inoculated with cells transfected with the antisense rather than with the sense plasmid. These observations indicate that annexin I modulates cell functions by controlling intracellular calcium release. Frey, B. M., Reber, B. F. X., Vishwanath, B. S., Escher, G., Frey, F. J. Annexin I modulates cell functions by controlling intracellular calcium release.     

Dissecting the cellular functions of annexin XI using recombinant human annexin XI-specific autoantibodies cloned by phage display

Functional studies of cellular proteins are often complicated by the lack of well-defined monoclonal antibodies, the production of which is hampered by the highly conserved nature of these cellular proteins across species. Annexin XI, a member of the Ca2+-dependent, phospholipid-binding protein family, is an example of such a protein and was used in studies to devise a strategy using human autoimmune phage display libraries to generate reagents for biological studies of conserved cellular proteins. An IgG phage display library was generated from bone marrow of an autoimmune patient with high serum antibody titer against annexin XI, which was identified recently as an autoantigen targeted by autoantibodies in several systemic autoimmune diseases. From this phage library, a panel of human monoclonal annexin XI-specific Fabs were isolated and applied to studies of the cellular functions of annexin XI. Confocal microscopy showed a cell cycle-specific redistribution of annexin XI from the cytoplasm to the mitotic spindle. In metaphase, annexin XI was up-regulated and costained with alpha-tubulin. The subcellular distribution of annexin XI in COS-7 cells was shown to be Ca2+-dependent, and exhibited a predominantly nuclear pattern at low concentrations and a cytoplasmic pattern at high Ca2+ concentrations. Calcyclin, found previously to bind annexin XI in vitro, in vivo coated the nuclear membrane of cultured cell lines and did not colocalize with annexin XI. Ultrastructural analysis by immunoelectron microscopy revealed that annexin XI associated with specific granules in both neutrophils and eosinophils, suggesting a role in the exocytotic pathway. Our results illuminate the multifunctional nature of human annexin XI, provide the first evidence that annexin XI associates with the mitotic spindles and might play a role in cell division, and clearly illustrate the potential of phage display-derived human autoantibodies in broader analyses of the function of highly conserved cellular proteins.     

Binding of annexins to lung lamellar bodies and the PMA-stimulated secretion of annexin V from alveolar type II cells

To identify lung lamellar body (LB)-binding proteins, the fractions binding to LB-Sepharose 4B in a Ca(2+)-dependent manner from the lung soluble fractions were analyzed with Mono Q column. Four annexins (annexins III, IV, V, and VIII) were identified by partial amino acid sequence analyses as the LB-binding proteins in the lung soluble fractions. A control experiment using phospholipid (phosphatidylserine/phosphatidylglycerol/phosphtidylcholine) liposome-Sepharose 4B revealed that annexins III, IV and V were the Ca(2+)-dependent proteins binding to the column in the lung soluble fractions, while annexin VIII was not detected. Thus, annexin VIII might preferentially bind to LB. On the other hand, the only Ca(2+)-dependent LB-binding protein identified in the bronchoalveolar lavage fluids was annexin V. It was further demonstrated that annexin V was secreted by isolated alveolar type II cells from rats and that the secretion was stimulated by the addition of phorbol ester (PMA), a potent stimulator of surfactant secretion. The PMA-dependent stimulation of annexin V was attenuated by preincubation with surfactant protein-A (SP-A), a potent inhibitor of surfactant secretion. As LB is thought to be an intracellular store of pulmonary surfactant, which is secreted by alveolar type II cells, annexin V is likely to be secreted together with the lamellar body.     

Human neutrophils contain subpopulations of specific granules exhibiting different sensitivities to changes in cytosolic free calcium

We examined the role of mobilization of intracellular calcium in the ability of human neutrophils to discharge specific granule constituents upon stimulation with the synthetic chemotactic factor, N-formyl-met-leu-phe. Extracellular calcium was not required for optimal secretion of the specific granule markers lactoferrin and vitamin B12-binding protein. Depletion and chelation of intracellular calcium, as well as reconstitution experiments, however, revealed different calcium requirements for stimulated secretion of these markers. N-formyl-met-leu-phe-induced secretion of vitamin B12-binding protein required half-maximal change in intracellular calcium of greater than 20 nM, while lactoferrin requirements were approximately 140 nM. Thus, it appears that cytosolic free calcium modulates fusion of subpopulations of specific granules which with the neutrophil plasma membrane.