The Exocyst Complex in Health and Disease

Martín-Urdiroz, Magdalena; Deeks, Michael J.; Horton, Connor G.; Dawe, Helen R.; Jourdain, Isabelle

doi:10.3389/fcell.2016.00024

Cited by 95 publications

(109 citation statements)

References 234 publications

(410 reference statements)

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“…One of the key components regulating cell polarity is the exocyst complex. It is a heterooctameric protein complex (TerBush et al, 1996) that is shared across eukaryotes (Vaškovi cová et al, 2013;Martin-Urdiroz et al, 2016) and that tethers secretory vesicles to the plasma membrane (PM) and regulates their subsequent fusion. In animal and yeast model systems, many molecular interactions involved in exocyst function have already been discovered: EXO70 and SEC3 drive exocyst to the target site by interaction with phosphatidylinositol 4,5-bisphosphate (PIP 2 ) and small GTPases of the Rho family (He et al, 2007;Liu et al, 2007;Wu et al, 2010;Pleskot et al, 2015), both budding yeast (Saccharomyces cerevisiae) Sec15p (France et al, 2006) and Exo70p interact with the cell polarity determinant Bem1p (Liu and Novick, 2014), SEC15 interacts with secretory vesicle-associated Rab GTPases (Wu et al, 2005) and promotes myosin motor release after vesicle fusion with the PM (Donovan and Bretscher, 2015), and budding yeast Sec6p binds SNARE proteins and promotes SNARE complex assembly (Dubuke et al, 2015) and also binds the SNARE interactor Sec1p (Morgera et al, 2012).…”

mentioning

confidence: 99%

Analysis of Exocyst Subunit EXO70 Family Reveals Distinct Membrane Polar Domains in Tobacco Pollen Tubes

Sekereš

Pejchar²,

Šantrůček³

et al. 2017

Plant Physiol.

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mentioning

confidence: 99%

Analysis of Exocyst Subunit EXO70 Family Reveals Distinct Membrane Polar Domains in Tobacco Pollen Tubes

Sekereš

Pejchar²,

Šantrůček³

et al. 2017

Plant Physiol.

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“…A highly important exocytotic processes is associated with vesicular neurotransmitter release at the presynaptic site [373]. These unique membrane-bound vesicles contain not only neurotransmitters but also soluble proteins, lipids and ATP to be secreted into the synaptic cleft [374,375]. Several families of vesicle proteins have been characterized among which synaptophysin, synapsins, synaptobrevins andsynaptotagmins are most common [372].…”

Section: Toxins and Their Target Of Actionmentioning

confidence: 99%

The Molecular Basis of Toxins’ Interactions with Intracellular Signaling via Discrete Portals

Lahiani

Yavin

Lazarovici

2017

Toxins

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An understanding of the molecular mechanisms by which microbial, plant or animal-secreted toxins exert their action provides the most important element for assessment of human health risks and opens new insights into therapies addressing a plethora of pathologies, ranging from neurological disorders to cancer, using toxinomimetic agents. Recently, molecular and cellular biology dissecting tools have provided a wealth of information on the action of these diverse toxins, yet, an integrated framework to explain their selective toxicity is still lacking. In this review, specific examples of different toxins are emphasized to illustrate the fundamental mechanisms of toxicity at different biochemical, molecular and cellular- levels with particular consideration for the nervous system. The target of primary action has been highlighted and operationally classified into 13 sub-categories. Selected examples of toxins were assigned to each target category, denominated as portal, and the modulation of the different portal’s signaling was featured. The first portal encompasses the plasma membrane lipid domains, which give rise to pores when challenged for example with pardaxin, a fish toxin, or is subject to degradation when enzymes of lipid metabolism such as phospholipases A2 (PLA2) or phospholipase C (PLC) act upon it. Several major portals consist of ion channels, pumps, transporters and ligand gated ionotropic receptors which many toxins act on, disturbing the intracellular ion homeostasis. Another group of portals consists of G-protein-coupled and tyrosine kinase receptors that, upon interaction with discrete toxins, alter second messengers towards pathological levels. Lastly, subcellular organelles such as mitochondria, nucleus, protein- and RNA-synthesis machineries, cytoskeletal networks and exocytic vesicles are also portals targeted and deregulated by other diverse group of toxins. A fundamental concept can be drawn from these seemingly different toxins with respect to the site of action and the secondary messengers and signaling cascades they trigger in the host. While the interaction with the initial portal is largely determined by the chemical nature of the toxin, once inside the cell, several ubiquitous second messengers and protein kinases/ phosphatases pathways are impaired, to attain toxicity. Therefore, toxins represent one of the most promising natural molecules for developing novel therapeutics that selectively target the major cellular portals involved in human physiology and diseases.

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“…In both yeast and mammalian cells the exocyst, a complex of eight polypeptides, is involved in docking and tethering exocytic vesicles at sites of fusion (Lipschutz and Mostov, 2002;EauClaire and Guo, 2003;Martin-Urdiroz et al, 2016). The exocyst complex has been implicated in a wide variety of cell functions, including morphogenesis, migration and tumor invasion; its subunits are direct targets of several small GTPases, such as Rabs, Cdc42, TC10 (a Cdc42 homolog), and RalGT-Pases (Wu and Guo, 2015;Zhu et al, 2017) that result in exocyst activation.…”

Section: Mechanisms Of Ppv Docking and Tetheringmentioning

confidence: 99%