The role of annexin II in vesicle traffic

The annexins are a family of proteins that bind acidic phospholipids in the presence of Ca2+. The association of these proteins with the membranes of secretory granules and endosomes indicates these proteins may play a role in membrane trafficking. One member of the family, annexin II, can exist either as a monomer, heterodimer or heterotetramer in conjunction with the S100 protein p11. The ability of annexin II tetramer to bind both membranes and actin in a Ca2+-dependent manner has led to the hypothesis that annexin II may mediate between vesicle and/or plasma membranes and the cortical cytoskeleton. However, despite intensive biochemical characterisation in vitro, the function of this protein in vivo remains a mystery. In this study annexin II function in living cells was analysed in several different ways using green fluorescent protein (GFP) in full length annexin II-GFP chimeras and chimeras consisting of fragments of annexin II fused to GFP. Transfection of different cell lines with these annexin II-GFP constructs and fluorescence assisted cell sorting (FACS) allowed the generation of multiclonal cell populations expressing annexin II-GFP fusion proteins. These cell populations were analysed for effects on physiological functions - such as secretion (in the RBL cell line) or differentiation (of the PC12 cell line). This line of investigation did not yield evidence to support a role for annexin II in either of these processes. Using novel forms of microscopy the localisation of a full length annexin II- GFP chimera (NAII-GFP) was followed in single cells under physiological conditions. Under conditions of stress NAII-GFP was found to become incorporated into novel actin based structures, reminiscent of Listeria rockets, which propelled pinosomes through the cell interior. This form of vesicle locomotion is dependent on actin polymerisation and may represent a hitherto unrecognised form of vesicle transport

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

AbstractAnnexin 2 is a Ca2+ binding protein that binds to and aggregates secretory vesicles at physiological Ca2+ levels [1] and that also associates Ca2+ 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

CALM regulates clathrin-coated vesicle size and maturation by directly sensing and driving membrane curvature.

The size of endocytic clathrin-coated vesicles (CCVs) is remarkably uniform, suggesting that it is optimized to achieve the appropriate levels of cargo and lipid internalization. The three most abundant proteins in mammalian endocytic CCVs are clathrin and the two cargo-selecting, clathrin adaptors, CALM and AP2. Here we demonstrate that depletion of CALM causes a substantial increase in the ratio of "open" clathrin-coated pits (CCPs) to "necked"/"closed" CCVs and a doubling of CCP/CCV diameter, whereas AP2 depletion has opposite effects. Depletion of either adaptor, however, significantly inhibits endocytosis of transferrin and epidermal growth factor. The phenotypic effects of CALM depletion can be rescued by re-expression of wild-type CALM, but not with CALM that lacks a functional N-terminal, membrane-inserting, curvature-sensing/driving amphipathic helix, the existence and properties of which are demonstrated. CALM is thus a major factor in controlling CCV size and maturation and hence in determining the rates of endocytic cargo uptake.S.E.M. and D.J.O. are funded by a Wellcome Trust Fellowship (to D.J.O. no. 090909/Z). N.A.B. is funded by MRC grant MR/M010007/1, and S.H. is funded by a grant from the German Science Foundation (SFB 635, TP A3). D.S. and S.M. acknowledge financial support from the Lundbeck Foundation and the Danish Councils for Independent and Strategic Research. C.J.M. and F.P. were funded by the Fondation pour la Recherche Medicale.This is the final published version. It first appeared at http://www.cell.com/developmental-cell/fulltext/S1534-5807%2815%2900144-6

Membrane fission by dynamin: what we know and what we need to know

Abstract The large GTPase dynamin is the first protein shown to catalyze membrane fission. Dynamin and its related proteins are essential to many cell functions, from endocytosis to organelle division and fusion, and it plays a critical role in many physiological functions such as synaptic transmission and muscle contraction. Research of the past three decades has focused on understanding how dynamin works. In this review, we present the basis for an emerging consensus on how dynamin functions. Three properties of dynamin are strongly supported by experimental data: first, dynamin oligomerizes into a helical polymer; second, dynamin oligomer constricts in the presence of GTP; and third, dynamin catalyzes membrane fission upon GTP hydrolysis. We present the two current models for fission, essentially diverging in how GTP energy is spent. We further discuss how future research might solve the remaining open questions presently under discussion

A Feedback Loop between Dynamin and Actin Recruitment during Clathrin-Mediated Endocytosis

A live-cell imaging study reveals that a positive feedback loop between dynamin and actin contributes to efficient endocytic membrane scission

Dynamics of Endocytic Vesicle Creation

SummaryClathrin-mediated endocytosis is the main path for receptor internalization in metazoans and is essential for controlling cell integrity and signaling. It is driven by a large array of protein and lipid interactions that have been deciphered mainly by biochemical and genetic means. To place these interactions into context, and ultimately build a fully operative model of endocytosis at the molecular level, it is necessary to know the kinetic details of the role of each protein in this process. In this review, we describe the recent efforts made, by using live cell imaging, to define clear steps in the formation of endocytic vesicles and to observe the recruitment of key proteins during membrane invagination, the scission of a newly formed vesicle, and its movement away from the plasma membrane

Clathrin coated pits, plaques and adhesion

Clathrin mediated endocytosis (CME) is the main route of receptor internalization in mammalian cells and this well conserved mechanism has been intensively studied for over 40yrs. In the general or 'canonical' model of CME clathrin coated pits form stochastically at the plasma membrane and coated pit curvature develops as the coated pit grows through clathrin polymerization. However, the canonical model of CME does not explain the diversity of endocytically active clathrin coated structures (CCSs) found at the plasma membrane by both electron and light microscopy. In this review we examine the canonical model of CME, highlight discrepancies with published experimental data and suggest future avenues of exploration while paying particular attention to the relationship between clathrin coated pits, plaques, sites of adhesion and the formation of endocytic 'hotspots'