Role of the Exocyst Complex Component Sec6/8 in Genomic Stability

Torres, Michael J.; Pandita, Raj K.; Kulak, Ozlem; Kumar, Rakesh; Formstecher, Étienne; Horikoshi, Nobuo; Mujoo, Kalpana; Hunt, Clayton R.; Zhao, Yingming; Lum, Lawrence; Zaman, Aubhishek; Yeaman, Charles; White, Michael A.; Pandita, Tej K.

doi:10.1128/mcb.00768-15

Cited by 14 publications

(14 citation statements)

References 75 publications

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“…Low but significant GFP fluorescence above the autofluorescence background was detectable by confocal microscopy of live cells for each of the 5 single knock-in lines ( Figure 1D). Sec5, Sec6, Sec8 and Exo70 were enriched at intercellular junctions, consistent with data on fixed and immunostained epithelial cells, but the knock-in cells also have substantial diffuse cytoplasmic pools, and no detectable nuclear signal, contrary to some other reports (Torres et al, 2015). Sec3 was anomalous in showing a predominantly cytoplasmic distribution with no significant accumulation at junctions.…”

Section: Generation and Validation Of Functional Endogenously Taggedsupporting

confidence: 88%

Exocyst Dynamics During Vesicle Tethering and Fusion

Ahmed

Nishida-Fukuda

et al. 2018

Preprint

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The exocyst is a conserved octameric complex that tethers exocytic vesicles to the plasma membrane prior to fusion. Exocyst assembly and delivery mechanisms remain unclear, especially in mammalian cells. Here we tagged multiple endogenous exocyst subunits with sfGFP or Halo using Cas9 gene editing, to create single and double knock-in lines of mammary epithelial cells, and interrogated exocyst dynamics by high-speed imaging and correlation spectroscopy. We discovered that mammalian exocyst is comprised of tetrameric subcomplexes that, unexpectedly, can associate independently with vesicles and plasma membrane and are in dynamic equilibrium. Membrane arrival times are similar for subunits and vesicles, but with a small delay (~80msec) between subcomplexes. Departure of Sec3 occurs prior to fusion, whereas other subunits depart just after fusion. Single molecule counting indicates ~9 exocyst complexes associated per vesicle. These data reveal the mammalian exocyst as a remarkably dynamic two-part complex and provide important new insights into assembly/disassembly mechanisms.Key words: vesicles, membrane fusion, dynamics, TIRFM, CRISPR, gene-editing, protein complex.. CC-BY-NC-ND 4.0 International license It is made available under a (which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.The copyright holder for this preprint . http://dx.doi.org/10.1101/354449 doi: bioRxiv preprint first posted online Jun. 22, 2018; 3 Traffic between membrane-bound compartments requires the docking of cargo vesicles at target membranes, and their subsequent fusion through the interactions of SNARE proteins. The capture and fusion of vesicles are both promoted by molecular tethers known as multisubunit tethering complexes 1 . One group of such tethers, sometimes called CATCHR (complexes associate with tethering containing helical rods) comprises multisubunit complexes required for fusion in the secretory pathway, and includes COG, Dsl1p, GARP and the exocyst 2 . The endolysosomal pathway contains two different tethering complexes, CORVET and HOPS, with similar overall structures to the CATCHR group 3 .COG consists of two subcomplexes, each containing four subunits, which function together within the Golgi 4-6 . The exocyst is also octameric, and is necessary for exocytic vesicle fusion to the plasma membrane (PM), but the organization of the complex has been controversial [7][8][9][10] . Several studies in yeast suggest that one (Sec3) or two (Sec3 and Exo70)subunits associate with the PM and recruit a vesicle-bound subcomplex of the other subunits, but other work argues that the exocyst consists of 2 subcomplexes of 4 subunits each that form a stable octamer or, in mammalian cells, that 5 subunits at the PM recruit 3 other subunits on the vesicle [11][12][13][14][15][16][17][18][19][20][21][22] . Rab GTPases promote exocyst binding to the vesicle, and SNARES, Rho family GTPases, the PAR3 polarity protein, and phospho-inositide binding domains are all involved ...

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Section: Generation and Validation Of Functional Endogenously Taggedsupporting

confidence: 88%

Exocyst Dynamics During Vesicle Tethering and Fusion

Ahmed

Nishida-Fukuda

et al. 2018

Preprint

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“…Sec8 has been shown to interact with 33 DDR and chromatin modifying proteins and to modulate the response to DNA damage. Ablation of Sec8 leads to an increase in the frequency of DNA repair but generates chromosomal aberrations (Torres et al, 2015 ). Therefore, paradoxically, the absence of Sec8 induces genomic instability.…”

Section: The Exocyst Complex In Metazoamentioning

confidence: 99%

“…Sec8 may participate in the cellular response to DNA damage by restraining the spacio-temporal recruitment of chromatin remodeling proteins in the absence of appropriate DDR signaling, thus promoting a faithful repair. Depletion of Sec8 also confers radioresistance, which has implications for the treatment by radiotherapy of colorectal cancers, in which Sec8 is deleted (Ashktorab et al, 2010 ; Torres et al, 2015 ). The G 1 /S checkpoint is another mechanism by which propagation of damaged DNA can be prevented.…”

Section: The Exocyst Complex In Metazoamentioning

confidence: 99%

The Exocyst Complex in Health and Disease

Martín-Urdiroz

Deeks

Horton

et al. 2016

Front. Cell Dev. Biol.

103

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Exocytosis involves the fusion of intracellular secretory vesicles with the plasma membrane, thereby delivering integral membrane proteins to the cell surface and releasing material into the extracellular space. Importantly, exocytosis also provides a source of lipid moieties for membrane extension. The tethering of the secretory vesicle before docking and fusion with the plasma membrane is mediated by the exocyst complex, an evolutionary conserved octameric complex of proteins. Recent findings indicate that the exocyst complex also takes part in other intra-cellular processes besides secretion. These various functions seem to converge toward defining a direction of membrane growth in a range of systems from fungi to plants and from neurons to cilia. In this review we summarize the current knowledge of exocyst function in cell polarity, signaling and cell-cell communication and discuss implications for plant and animal health and disease.

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“…Depletion of Sec8 sensitizes U2OS cells to DNA break formation or detection in a manner that also alters the persistence of the DNA damage response or resolution of the breaks themselves. Thus, disruption of Sec8 results in the accumulation of ATF2 and RNF20 and the anomalous accumulation of DDR‐associated chromatin marks and Rad51 repairosomes (Torres et al, ).…”

Section: Osteosarcomamentioning

confidence: 99%

Diverse Functions and Signal Transduction of the Exocyst Complex in Tumor Cells

Tanaka

Goto

Iino

2016

Journal Cellular Physiology

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The exocyst complex is a large conserved hetero-oligomeric complex that consists of Sec3, Sec5, Sec6, Sec8, Sec10, Sec15, Exo70, and Exo84 subunits. It has been implicated in the targeting of vesicles for regulated exocytosis in various cell types, and is also important for targeted exocytosis of post-Golgi transport vesicles to the plasma membrane. The exocyst complex is essential for membrane growth, secretion, and function during exocytosis and endocytosis. Moreover, the individual components of the complex are thought to act on specific biological processes, such as cytokinesis, ciliogenesis, apoptosis, autophagy, and epithelial-mesenchymal transition (EMT). As a result, recent studies suggest that the exocyst complex may be involved in several diseases such as kidney disease, neuropathogenesis, diabetes, and cancer. In this review, we focus on the diverse functions and cellular signaling pathways of the exocyst complex in various tumors. J. Cell. Physiol. 232: 939-957, 2017. © 2016 Wiley Periodicals, Inc.

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Role of the Exocyst Complex Component Sec6/8 in Genomic Stability

Cited by 14 publications

References 75 publications

Exocyst Dynamics During Vesicle Tethering and Fusion

Exocyst Dynamics During Vesicle Tethering and Fusion

The Exocyst Complex in Health and Disease

Diverse Functions and Signal Transduction of the Exocyst Complex in Tumor Cells

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