CC chemokine receptor 10 cell surface presentation in melanocytes is regulated by the novel interaction partner S100A10.

The superfamily of G-protein-coupled receptors (GPCR) conveys signals in response to various endogenous and exogenous stimuli. Consequently, GPCRs are the most important drug targets. CCR10, the receptor for the chemokines CCL27/CTACK and CCL28/MEC, belongs to the chemokine receptor subfamily of GPCRs and is thought to function in immune responses and tumour progression. However, there is only limited information on the intracellular regulation of CCR10. We find that S100A10, a member of the S100 family of Ca(2+) binding proteins, binds directly to the C-terminal cytoplasmic tail of CCR10 and that this interaction regulates the CCR10 cell surface presentation. This identifies S100A10 as a novel interaction partner and regulator of CCR10 that might serve as a target for therapeutic intervention.

Reduced allele specific annexin A5 mRNA levels in placentas carrying the M2/ANXA5 allele.

We aimed to trace the allele specific expression of ANXA5 mRNA in placentas carrying the M2 haplotype, conferring higher recurrent pregnancy loss risk, in order to verify directly the role of M2 in the relevant organ. The M2 allele in heterozygous placentas results in an average of 42% reduced ANXA5 mRNA levels as compared to the normal allele. Protein levels in these samples show considerable variations, impossible for statistical interpretation. The M2 allele of ANXA5 can be linked to reduced mRNA levels in heterozygous placentas and could result in more confined protein levels (lowered expression dynamics) of annexin A5.

Combined homology modelling and evolutionary significance evaluation of missense mutations in blood clotting factor VIII to highlight aspects of structure and function.

Most small lesions in the factor VIII (FVIII) gene that cause haemophilia A (HA) are single nucleotide substitutions resulting in amino acid replacing (missense) mutations and leading to various phenotypes, ranging from mild to severe. We took a combined approach of homology modelling and quantitative evaluation of evolutionary significance of amino acid replacing alterations using the Grantham Matrix Score (GMS) to assess their structural effects and significance of pathological expression. Comparative homology models of all amino acid substitutions summarized in the FVIII mutations database plus these identified and reported lately by us or by our collaborators were evaluated. Altogether 640 amino acid replacing mutations were scored for potential distant or local conformation changes, influence on the molecular stability and predicted contact residues, using available FVIII domain models. The average propensity to substitute amino acid residues by mutation was found comparable to the overall probability of de novo mutations. Missense changes reported with various HA phenotypes were all confirmed significant using GMS. The fraction of these, comprising residues apparently involved in intermolecular interactions, exceeds the average proportion of such residues for FVIII. Predicted contact residues changed through mutation were visualized on the surface of FVIII domains and their possible functional implications were verified from the literature and are discussed considering available structural information. Our predictive modelling adds on the current view of domain interface molecular contacts. This structural insight could aid in part to the design of engineered FVIII constructs for therapy, to possibly enhance their stability and prolong circulating lifetime.

Knockdown of annexin 2 decreases migration of human glioma cells in vitro.

Diffuse invasion of brain tissue is a major reason for the poor prognosis of patients with glioblastoma. Annexin 2, a member of the large annexin family of Ca2+ and membrane-binding proteins, is expressed at high protein levels in human gliomas and has been proposed as a marker of glioma malignancy, while its functional role in these tumours is unknown so far. The ability of annexin 2 to interact with the actin cytoskeleton, as well as its potential to bind invasion-associated proteases, suggests that it could participate in invasion-associated processes in human gliomas. Therefore, we analysed here functional consequences of RNA interference-mediated silencing of annexin 2 in U87MG and U373MG human glioma cell lines. While no impact of annexin 2 downregulation on proliferation and adhesion was observed, our analyses revealed that migration of U87MG and U373MG cells was significantly inhibited following annexin 2 depletion. This effect was not related to a compensatory increase of the related annexins 1 or 6. Our findings identify annexin 2 as a potential candidate involved in glioma invasion and support the potential of RNA interference as powerful tool in the decryption of glioma invasion mechanisms.

Agonist-induced trafficking of the low-affinity formyl peptide receptor FPRL1.

The formyl peptide-like receptor FPRL1 is a member of the chemoattractant subfamily of G protein- coupled receptors involved in regulating leukocyte migration in inflammation. To elucidate mechanisms underlying the internalization of ligand-bound FPRL1 and possible receptor recycling, we characterized the endocytic itinerary of FPRL1. We show that agonist-triggered internalization from the plasma membrane into intracellular compartments is prevented by perturbation of clathrin-mediated endocytosis, such as expression of the dominant-negative clathrin Hub mutant, siRNA-mediated depletion of cellular clathrin and expression of a dominant-negative mutant of the large GTPase dynamin. Internalized FPRL1 co-localized with endocytosed transferrin and the small GTPases Rab4 and Rab11 in vesicular structures most resembling recycling endosomes. Recycling of FPRL1 was significantly reduced by pretreatment with PI3-kinase inhibitors. Thus, ligand-bound FPRL1 undergoes primarily clathrin-mediated and dynamin-dependent endocytosis and the receptor recycles via a rapid PI3-kinase-sensitive route as well as pathways involving perinuclear recycling endosomes.

Agonists of proteinase-activated receptor-2 modulate human neutrophil cytokine secretion, expression of cell adhesion molecules, and migration within 3-D collagen lattices.

Proteinase-activated receptor-2 (PAR2) belongs to a novel subfamily of G-protein-coupled receptors with seven-transmembrane domains. PAR2 can be activated by serine proteases such as trypsin, mast cell tryptase, and allergic or bacterial proteases. This receptor is expressed by various cells and seems to be crucially involved during inflammation and the immune response. As previously reported, human neutrophils express functional PAR2. However, the precise physiological role of PAR2 on human neutrophils and its implication in human diseases remain unclear. We demonstrate that PAR2 agonist-stimulated human neutrophils show significantly enhanced migration in 3-D collagen lattices. PAR2 agonist stimulation also induced down-regulation of L-selectin display and up-regulation of membrane-activated complex-1 very late antigen-4 integrin expression on the neutrophil cell surface. Moreover, PAR2 stimulation results in an increased secretion of the cytokines interleukin (IL)-1beta, IL-8, and IL-6 by human neutrophils. These data indicate that PAR2 plays an important role in human neutrophil activation and may affect key neutrophil functions by regulating cell motility in the extracellular matrix, selectin shedding, and up-regulation of integrin expression and by stimulating the secretion of inflammatory mediators. Thus, PAR2 may represent a potential therapeutic target for the treatment of diseases involving activated neutrophils.

The expression levels of three raft-associated molecules in cultivated vascular cells are dependent on culture conditions.

Relaying a signal across the plasma membrane requires functional connections between the partner molecules. Membrane microdomains or lipid rafts provide an environment in which such specific interactions can take place. The integrity of these sites is often taken for granted when signalling pathways are investigated in cell culture. However, it is well known that smooth muscle and endothelial cells undergo cytoskeletal rearrangements during monolayer culturing. Likewise affected--and with potentially important consequences for signalling events--is the organization of the plasma membrane. The expression levels of three raft markers were massively upregulated, and raft-associated 5'-nucleotidase activity increased in conventional monolayer cultures as compared with a spheroidal coculture model, shown to promote the differentiation of endothelial cells. Our data point to a shift of raft components in monolayer cultures and demonstrate potential advantages of the spheroid coculture system for investigation of raft-mediated signalling events in endothelial cells.

Association of annexin 2 with recycling endosomes requires either calcium- or cholesterol-stabilized membrane domains.

Annexin 2 is a Ca2+- and phospholipid-binding protein previously identified on endosomal membranes and the plasma membrane. Inferred from this location and its stimulatory effect on membrane transport annexin 2 has been proposed to play a role in the structural organization and dynamics of endosomal membranes. Validation of this view requires a detailed analysis of the distribution of annexin 2 over the endosomal compartment and a characterization of the parameters governing this distribution. Towards this end we have devised an immunoisolation protocol to purify annexin 2-positive membrane vesicles from subcellular fractions of BHK cells containing early endosomes. We show that this approach leads to the isolation of intact endosomal vesicles containing internalized fluid-phase marker and that the immunoisolated membranes are positive for the transferrin receptor and Rab4 but not for the early endosomal antigen EEA1. A distinct and non-uniform distribution of annexin 2 over the early endosomal compartment is also observed in immunoelectron microscopy analyses of whole-mount specimens of BHK cells. Annexin 2 antibodies labeled transferrin receptor-containing tubular early endosomal structures, but not EEAl-positive endosomal vacuoles. We also observed that the Ca2+-independent association of annexin 2 with endosomal membranes was disrupted by the cholesterol-binding glycerid saponin, while Ca2+ could trigger annexin 2 binding to saponin-treated endosomal membranes. Thus, either Ca2+- or cholesterol-stabilized membrane domains are required for the binding of annexin 2 to endosomes suggesting that both factors may regulate this interaction.

Annexin 2 has an essential role in actin-based macropinocytic rocketing.

Annexin 2 is a Ca(2+) binding protein that binds to and aggregates secretory vesicles at physiological Ca(2+) levels [1] and that also associates Ca(2+) independently with early endosomes [2, 3]. These properties suggest roles in both exocytosis and endocytosis, but little is known of the dynamics of Annexin 2 distribution in live cells during these processes. We have used evanescent field microscopy to image Annexin 2-GFP in live, secreting rat basophilic leukemia cells and in cells performing pinocytosis. Although we found no evidence of Annexin 2 involvement in exocytosis, we observed an enrichment of Annexin 2-GFP in actin tails propeling macropinosomes. The association of Annexin 2-GFP with rocketing macropinosomes was specific because Annexin 2-GFP was absent from the actin tails of rocketing Listeria. This finding suggests that the association of Annexin 2 with macropinocytic rockets requires native pinosomal membrane. Annexin 2 is necessary for the formation of macropinocytic rockets since overexpression of a dominant-negative Annexin 2 construct abolished the formation of these structures. The same construct did not prevent the movement of Listeria in infected cells. These results show that recruitment of Annexin 2 to nascent macropinosome membranes 16656is an essential prerequisite for actin polymerization-dependent vesicle locomotion.

Complex formation and submembranous localization of annexin 2 and S100A10 in live HepG2 cells.

The Ca(2+) and membrane binding protein annexin 2 can form a heterotetrameric complex with the S100A10 protein and this complex is thought to serve a bridging or scaffolding function in the membrane underlying cytoskeleton. To elucidate which of the subunits targets the complex to the subplasmalemmal region in live cells we employed YFP/CFP fusion proteins and live cell imaging in HepG2 cells. We show that monomeric annexin 2 is targeted to the plasma membrane whereas non-complexed S100A10 acquires a general cytosolic distribution. Co-expression of S100A10 together with annexin 2 and the resulting complex formation, however, lead to a recruitment of S100A10 to the plasma membrane thus identifying annexin 2 as the membrane targeting subunit.

Endothelial intracellular Ca2+ release following monocyte adhesion is required for the transendothelial migration of monocytes.

Although molecular changes accompanying leukocyte extravasation have been investigated intensively, the particular events following leukocyte adhesion and leading to the actual transendothelial migration process remain largely unknown. To characterize intraendothelial signals elicited by leukocyte adhesion and functionally required for their transmigration, we recorded endothelial free cytosolic intracellular Ca(2+)levels ([Ca(2+)]i) during the course of leukocyte adhesion. We show that monocyte and granulocyte adhesion induced Ca(2+)transients in either untreated or TNF-alpha-stimulated microvascular endothelial cells (HMEC-1). The functional significance of these [Ca(2+)]i rises was demonstrated by treating filter-grown endothelial monolayers with BAPTA/AM. This in traendothelial Ca(2+)chelation left monocyte adhesion basically unaffected, but caused a significant and dose-dependent reduction of the transendothelial migration of monocytes. Granulocyte diapedesis, on the other hand, was hardly modified. Thapsigargin-treatment of endothelial cells almost completely inhibited the transmigration of monocytes suggesting that the necessary Ca(2+)transients depended on a release from intracellular Ca(2+)stores. Our results thus show that the transmigration of monocytes through endothelial monolayers of microvascular origin is favoured by an increase of the intraendothelial [Ca(2+)]i induced by leukocyte adhesion to the endothelial cells.

Homologues to the first gene for autosomal dominant polycystic kidney disease are pseudogenes.

PKD1 is the first gene identified to be causative for the condition of autosomal dominant polycystic kidney disease. There are several genes homologous to PKD1 that are located proximal to the master gene on the same chromosome. Two of these genes have been recently covered in a large sequencing work on chromosome 16, and their structure has been broadly analyzed. However, the major question whether homologous genes (HG) code for functionally active polypeptides has not been resolved so far. The current study identifies and partially characterizes four more homologues of PKD1, different from the previously published sequence, two of which were found by screening of a BAC library and the other two contained in available databases. Analysis of HG transcripts shows that they are not translated in the model cell line T98G. Taken together, these findings suggest that homologues to PKD1 form a family of pseudogenes.

Folding energetics of ligand binding proteins II. Cooperative binding of Ca2+ to annexin I.

The calcium binding properties of annexin I as observed by thermodynamic DSC studies have been compared to the structural information obtained from X-ray investigation. The calorimetric experiment permitted to evaluate both the reaction scheme - including binding of ligand and conformational changes - and the energetics of each reaction step. According to published X-ray data Annexin I has six calcium binding sites, three medium-affinity type II and three low-affinity type III sites. The present study shows that at 37 degrees C annexin I binds in a Hill type fashion simultaneously two calcium ions in a first step with medium affinity at a concentration of 0.6 mM and another three Ca(2+) ions again cooperatively at 30 mM with low affinity. Therefore it can be concluded that only two medium-affinity type II binding sites are available. The third site, that should be accessible in principle appears to be masked presumably due to the presence of the N terminus. In view of the large calcium concentration needed for saturation of the binding sites, annexin I may be expected to be Ca(2+) free in vivo unless other processes such as membrane interaction occur simultaneously. This assumption is consistent with the finding, that the affinity of annexins to calcium is usually markedly increased by the presence of lipids.

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.

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.

S100-annexin complexes: some insights from structural studies.

Several annexins have been shown to bind proteins that belong to the S100 calcium-binding protein family. The two best-characterized complexes are annexin II with p11 and annexin I with S100C, the former of which has been implicated in membrane fusion processes. We have solved the crystal structures of the complexes of p11 with annexin II N-terminus and of S100C with annexin I N-terminus. Using these structural results, as well as electron microscopy observations of liposome junctions formed in the presence of such complexes (Lambert et al., 1997 J Mol Biol 272, 42-55), we propose a computer generated model for the entire annexin II/p11 complex.

Intact Ca(2+)-binding sites are required for targeting of annexin 1 to endosomal membranes in living HeLa cells.

Annexin 1 is a Ca(2+)-regulated membrane binding protein and a major substrate of the epidermal growth factor receptor kinase. Because of its properties and intracellular distribution, the protein has been implicated in endocytic trafficking of the receptor, in particular in receptor sorting occurring in multivesicular endosomes. Up to now, however, the localization of annexin 1 to cellular membranes has been limited to subcellular fractionation and immunocytochemical analyses of fixed cells. To establish its localization in live cells, we followed the intracellular fate of annexin 1 molecules fused to the Green Fluorescent Protein (GFP). We show that annexin 1-GFP associates with distinct, transferrin receptor-positive membrane structures in living HeLa cells. A GFP chimera containing the Ca(2+)/phospholipid-binding protein core of annexin 1 also shows a punctate intracellular distribution, although the structures labeled here do not resemble early but, at least in part, late endosomes. In contrast, the cores of annexins 2 and 4 fused to GFP exhibit a cytoplasmic or a different punctate distribution, respectively, indicating that the highly homologous annexin core domains carry distinct membrane specificities within live cells. By inactivating the three high-affinity Ca(2+) binding sites in annexin 1 we also show that endosomal membrane binding of the protein in live HeLa cells depends on the integrity of these Ca(2+) binding sites. More detailed analysis identifies a single Ca(2+) site in the second annexin repeat that is crucially involved in establishing the membrane association. These results reveal for the first time that intracellular membrane binding of an annexin in living cells requires Ca(2+) and is mediated in part through an annexin core domain that is capable of establishing specific interactions.

Identification of hydrophobic amino acid residues involved in the formation of S100P homodimers in vivo.

S100 proteins are small dimeric members of the EF-hand superfamily of Ca(2+) binding proteins thought to participate in mediating intracellular Ca(2+) signals by binding to and thereby regulating target proteins in a Ca(2+)-dependent manner. As dimer formation is crucial to S100 function, we applied a yeast two-hybrid approach in analyzing in vivo molecular aspects of S100 dimerization. We chose S100P, a member of the S100 family highly expressed in placenta, for detailed analysis and showed that S100P monomers strongly interact with one another but not with other S100 polypeptides, indicating that homodimer formation is obligatory for S100P. Analysis of the interaction of site-specific S100P mutants with the wild-type polypeptide or with other S100P mutant chains identifies conserved hydrophobic amino acid residues involved in mediating dimerization in vivo. Of these residues, F-15 is crucially important as a mutation to alanine abolishes dimerization even when the F15A S100P mutant polypeptide is allowed to interact with a wild-type chain. On the other hand, I-11, I-12, or F-89 need to be replaced by a less hydrophopic residue in both subunits for there to be a similar extent of interfere with dimerization. This proves that hydrophobic residues implicated through structural studies in S100 dimerization are involved in the dimer interaction in vivo and argues for a hierarchy of hydrophobic contacts stabilizing the dimer and thereby regulating S100 function.