Annexin A5 (or annexin V) is a cellular protein in the annexin group. In flow cytometry, annexin V is commonly used to detect apoptotic cells by its ability to bind to phosphatidylserine, a marker of apoptosis when it is on the outer leaflet of the plasma membrane. The function of the protein is unknown; however, annexin A5 has been proposed to play a role in the inhibition of blood coagulation by competing for phosphatidylserine binding sites with prothrombin and also to inhibit the activity of phospholipase A1. These properties have been found by in vitro experiments.
Pathology
Antibodies directed against annexin A5 are found in patients with a disease called the antiphospholipid syndrome (APS), a thrombophilic disease associated with autoantibodies against phospholipid compounds.
Annexin A5 forms a shield around negatively charged phospholipid molecules. The formation of an annexin A5 shield blocks the entry of phospholipids into coagulation (clotting) reactions. In the antiphospholipid antibody syndrome, the formation of the shield is disrupted by antibodies. Without the shield, there is an increased quantity of phospholipid molecules on cell membranes, speeding up coagulation reactions and causing the blood-clotting characteristic of the antiphospholipid antibody syndrome.
Annexin A5 showed upregulation in papillary thyroid carcinoma.[5]
Laboratory use
Annexin A5 is used as a non-quantitative probe to detect cells that have expressed phosphatidylserine (PS) on the cell surface, an event found in apoptosis as well as other forms of cell death.[6][7][8]Platelets also expose PS and PE on their surface when activated, which serves as binding site for various coagulation factors.
The annexin A5 affinity assay typically uses a conjugate of annexin V and a fluorescent or enzymatic label, biotin or other tags, or a radioelement, in a suitable buffer (annexin V binding to aminophospholipids is Ca2+ dependent). The assay combines annexin V staining of PS and PE membrane events with the staining of DNA in the cell nucleus with propidium iodide (PI) or 7-Aminoactinomycin D (AAD-7), distinguishing viable cells from apoptotic cells and necrotic cells.[9] Detection occurs by flow cytometry or a fluorescence microscope.
^Meers P and Mealy T (1994). "Phospholipid determinants for annexin V binding sites and the role of tryptophan". Biochemistry. 33 (19): 5829–37. doi:10.1021/bi00185a022. PMID8180211.
^Koopman G, Reutelingsperger CP, Kuijten GA, Keehnen RM, Pals ST, van Oers MH (Sep 1994). "Annexin V for flow cytometric detection of phosphatidylserine expression on B cells undergoing apoptosis". Blood. 84 (5): 1415–20. doi:10.1182/blood.V84.5.1415.1415. PMID8068938.
Schlaepfer DD, Jones J, Haigler HT (Feb 1992). "Inhibition of protein kinase C by annexin V". Biochemistry. 31 (6): 1886–91. doi:10.1021/bi00121a043. PMID1310621.
Huber R, Berendes R, Burger A, Schneider M, Karshikov A, Luecke H, Römisch J, Paques E (Feb 1992). "Crystal and molecular structure of human annexin V after refinement. Implications for structure, membrane binding and ion channel formation of the annexin family of proteins". Journal of Molecular Biology. 223 (3): 683–704. doi:10.1016/0022-2836(92)90984-R. PMID1311770.
Dawson SJ, White LA (May 1992). "Treatment of Haemophilus aphrophilus endocarditis with ciprofloxacin". The Journal of Infection. 24 (3): 317–20. doi:10.1016/S0163-4453(05)80037-4. PMID1602151.
Tait JF, Frankenberry DA, Shiang R, Murray JC, Adler DA, Disteche CM (1992). "Chromosomal localization of the human gene for annexin V (placental anticoagulant protein I) to 4q26----q28". Cytogenetics and Cell Genetics. 57 (4): 187–92. doi:10.1159/000133143. PMID1683830.
Funakoshi T, Heimark RL, Hendrickson LE, McMullen BA, Fujikawa K (Aug 1987). "Human placental anticoagulant protein: isolation and characterization". Biochemistry. 26 (17): 5572–8. doi:10.1021/bi00391a053. PMID2960376.
Iwasaki A, Suda M, Nakao H, Nagoya T, Saino Y, Arai K, Mizoguchi T, Sato F, Yoshizaki H, Hirata M (Nov 1987). "Structure and expression of cDNA for an inhibitor of blood coagulation isolated from human placenta: a new lipocortin-like protein". Journal of Biochemistry. 102 (5): 1261–73. doi:10.1093/oxfordjournals.jbchem.a122165. PMID2963810.
Funakoshi T, Hendrickson LE, McMullen BA, Fujikawa K (Dec 1987). "Primary structure of human placental anticoagulant protein". Biochemistry. 26 (25): 8087–92. doi:10.1021/bi00399a011. PMID2964863.
Demange P, Voges D, Benz J, Liemann S, Göttig P, Berendes R, Burger A, Huber R (Jul 1994). "Annexin V: the key to understanding ion selectivity and voltage regulation?". Trends in Biochemical Sciences. 19 (7): 272–6. doi:10.1016/0968-0004(94)90002-7. PMID7519374.
Fernández MP, Morgan RO, Fernández MR, Carcedo MT (Nov 1994). "The gene encoding human annexin V has a TATA-less promoter with a high G+C content". Gene. 149 (2): 253–60. doi:10.1016/0378-1119(94)90157-0. PMID7958998.
1a8a: RAT ANNEXIN V COMPLEXED WITH GLYCEROPHOSPHOSERINE
1a8b: RAT ANNEXIN V COMPLEXED WITH GLYCEROPHOSPHOETHANOLAMINE
1anw: THE EFFECT OF METAL BINDING ON THE STRUCTURE OF ANNEXIN V AND IMPLICATIONS FOR MEMBRANE BINDING
1anx: THE CRYSTAL STRUCTURE OF A NEW HIGH-CALCIUM FORM OF ANNEXIN V
1avh: CRYSTAL AND MOLECULAR STRUCTURE OF HUMAN ANNEXIN V AFTER REFINEMENT. IMPLICATIONS FOR STRUCTURE, MEMBRANE BINDING AND ION CHANNEL FORMATION OF THE ANNEXIN FAMILY OF PROTEINS
1avr: CRYSTAL AND MOLECULAR STRUCTURE OF HUMAN ANNEXIN V AFTER REFINEMENT. IMPLICATIONS FOR STRUCTURE, MEMBRANE BINDING AND ION CHANNEL FORMATION OF THE ANNEXIN FAMILY OF PROTEINS
1bc3: RECOMBINANT RAT ANNEXIN V, TRIPLE MUTANT (T72K, S144K, S228K)
1bcw: RECOMBINANT RAT ANNEXIN V, T72A MUTANT
1bcy: RECOMBINANT RAT ANNEXIN V, T72K MUTANT
1bcz: RECOMBINANT RAT ANNEXIN V, T72S MUTANT
1g5n: ANNEXIN V COMPLEX WITH HEPARIN OLIGOSACCHARIDES
1hak: CRYSTAL STRUCTURE OF RECOMBINANT HUMAN PLACENTAL ANNEXIN V COMPLEXED WITH K-201 AS A CALCIUM CHANNEL ACTIVITY INHIBITOR
1hvd: STRUCTURAL AND ELECTROPHYSIOLOGICAL ANALYSIS OF ANNEXIN V MUTANTS. MUTAGENESIS OF HUMAN ANNEXIN V, AN IN VITRO VOLTAGE-GATED CALCIUM CHANNEL, PROVIDES INFORMATION ABOUT THE STRUCTURAL FEATURES OF THE ION PATHWAY, THE VOLTAGE SENSOR AND THE ION SELECTIVITY FILTER
1hve: STRUCTURAL AND ELECTROPHYSIOLOGICAL ANALYSIS OF ANNEXIN V MUTANTS. MUTAGENESIS OF HUMAN ANNEXIN V, AN IN VITRO VOLTAGE-GATED CALCIUM CHANNEL, PROVIDES INFORMATION ABOUT THE STRUCTURAL FEATURES OF THE ION PATHWAY, THE VOLTAGE SENSOR AND THE ION SELECTIVITY FILTER
1hvf: STRUCTURAL AND ELECTROPHYSIOLOGICAL ANALYSIS OF ANNEXIN V MUTANTS. MUTAGENESIS OF HUMAN ANNEXIN V, AN IN VITRO VOLTAGE-GATED CALCIUM CHANNEL, PROVIDES INFORMATION ABOUT THE STRUCTURAL FEATURES OF THE ION PATHWAY, THE VOLTAGE SENSOR AND THE ION SELECTIVITY FILTER
1hvg: STRUCTURAL AND ELECTROPHYSIOLOGICAL ANALYSIS OF ANNEXIN V MUTANTS. MUTAGENESIS OF HUMAN ANNEXIN V, AN IN VITRO VOLTAGE-GATED CALCIUM CHANNEL, PROVIDES INFORMATION ABOUT THE STRUCTURAL FEATURES OF THE ION PATHWAY, THE VOLTAGE SENSOR AND THE ION SELECTIVITY FILTER
1n41: Crystal Structure of Annexin V K27E Mutant
1n42: Crystal Structure of Annexin V R149E Mutant
1n44: Crystal Structure of Annexin V R23E Mutant
1sav: HUMAN ANNEXIN V WITH PROLINE SUBSTITUTION BY THIOPROLINE
2ie6: Annexin V under 2.0 MPa pressure of xenon
2ie7: Annexin V under 2.0 MPa pressure of nitrous oxide
2ran: RAT ANNEXIN V CRYSTAL STRUCTURE: CA2+-INDUCED CONFORMATIONAL CHANGES
