The process of fusion at the nerve terminal is mediated via a specialized set of proteins in the synaptic vesicles and the presynaptic membrane. Three soluble N-ethylmaleimide-sensitive factor (NSF)-attachment protein receptors (SNAREs) have been implicated in membrane fusion. The structure and arrangement of these SNAREs associated with lipid bilayers were examined using atomic force microscopy. A bilayer electrophysiological setup allowed for measurements of membrane conductance and capacitance. Here we demonstrate that the interaction of these proteins to form a fusion pore is dependent on the presence of t-SNAREs and v-SNARE in opposing bilayers. Addition of purified recombinant v-SNARE to a t-SNARE-reconstituted lipid membrane increased only the size of the globular t-SNARE oligomer without influencing the electrical properties of the membrane. However when t-SNARE vesicles were added to a v-SNARE membrane, SNAREs assembles in a ring pattern and a stepwise increase in capacitance, and increase in conductance were observed. Thus, t- and v-SNAREs are required to reside in opposing bilayers to allow appropriate t-/v-SNARE interactions leading to membrane fusion.
Cholera toxin (CT), an AB5-subunit toxin, enters host cells by binding the ganglioside GM1 at the plasma membrane (PM) and travels retrograde through the trans-Golgi Network into the endoplasmic reticulum (ER). In the ER, a portion of CT, the enzymatic A1-chain, is unfolded by protein disulfide isomerase and retro-translocated to the cytosol by hijacking components of the ER associated degradation pathway for misfolded proteins. After crossing the ER membrane, the A1-chain refolds in the cytosol and escapes rapid degradation by the proteasome to induce disease by ADP-ribosylating the large G-protein Gs and activating adenylyl cyclase. Here, we review the mechanisms of toxin trafficking by GM1 and retro-translocation of the A1-chain to the cytosol.
The process of cancer progression involves the action of multiple proteolytic systems, among which the family of matrix metalloproteinases (MMPs) play a pivotal role. The MMPs evolved to accomplish their proteolytic tasks in multiple cellular and tissue microenvironments including lipid rafts by incorporation and deletions of specific structural domains. The membrane typeMMPs (MT-MMPs) incorporated membrane anchoring domains that display these proteases at the cell surface, and thus they are optimal pericellular proteolytic machines. Two members of the MT-MMP subfamily, MMP-17 (MT4-MMP) and MMP-25 (MT6-MMP), are anchored to the plasma membrane via a glycosyl-phosphatidyl inositol (GPI) anchor, which confers these enzymes a unique set of regulatory and functional mechanisms that separates them from the rest of the MMP family. Discovered almost a decade ago, the body of work on GPI-MT-MMPs today is still surprisingly limited when compared to other MT-MMPs. However, new evidence shows that the GPI-MT-MMPs are highly expressed in human cancer, where they are associated with progression. Accumulating biochemical and functional evidence also highlights their distinct properties. In this review, we summarize the structural, biochemical, and biological properties of GPI-MT-MMPs and present an overview of their expression and role in cancer. We further discuss the potential implications of GPI-anchoring for enzyme function. Finally, we comment on the new scientific challenges that lie ahead to better understand the function and role in cancer of these intriguing but yet unique MMPs.
The swelling of secretory vesicles has been implicated in exocytosis, but the underlying mechanism of vesicle swelling remains largely unknown. Zymogen granules (ZGs), the membrane-bound secretory vesicles in exocrine pancreas, swell in response to GTP mediated by a Gαi3 protein. Evidence is presented here that the water channel aquaporin-1 (AQP1) is present in the ZG membrane and participates in rapid GTP-induced vesicular water gating and swelling. Isolated ZGs exhibit low basal water permeability. However, exposure of granules to GTP results in a marked potentiation of water entry. Treatment of ZGs with the known water channel inhibitor Hg2+ is accompanied by a reversible loss in both the basal and GTP-stimulatable water entry and vesicle swelling. Introduction of AQP1-specific antibody raised against the carboxyl-terminal domain of AQP1 blocks GTP-stimulable swelling of vesicles. Our results demonstrate that AQP1 associated at the ZG membrane is involved in basal as well as GTP-induced rapid gating of water in ZGs of the exocrine pancreas
N-ethylmalemide-sensitive factor attachment protein receptor (SNARE) has been proposed to play a critical role in the membrane fusion process. The SNARE complex was suggested to be the minimal fusion machinery. However, there is mounting evidence for a major role of calcium in membrane fusion. Hence, the role of calcium in SNARE-induced membrane fusion was the focus of this study. It revealed that recombinant v-SNARE and t-SNARE, reconstituted into separate liposomes, interact to bring lipid vesicles into close proximity, enabling calcium to drive fusion of opposing bilayers. Exposure to calcium triggered vesicle fusion at both, high potency and efficacy. The half-time for calcium-induced fusion of SNARE-reconstituted vesicles was determined to be approximately 10 s, which is two orders of magnitude faster than in its absence. Calcium acts downstream of SNAREs, since the presence of SNAREs in bilayers increases the potency of calcium-induced vesicle fusion, without significantly influencing its efficacy. Hence, this study suggests that in the physiological state in cells, both SNAREs and calcium operate as the minimal fusion machinery.
Cholera toxin (CT) causes the massive secretory diarrhea associated with epidemic cholera. To induce disease, CT enters the cytosol of host cells by co-opting a lipid-based sorting pathway from the plasma membrane, through the trans-Golgi network (TGN), and into the endoplasmic reticulum (ER). In the ER, a portion of the toxin is unfolded and retro-translocated to the cytosol. Here, we established zebrafish as a genetic model of intoxication and examined the Derlin and flotillin proteins, which are thought to be usurped by CT for retro-translocation and lipid sorting, respectively. Using antisense morpholino oligomers and siRNA, we found that depletion of Derlin-1, a component of the Hrd-1 retro-translocation complex, was dispensable for CT-induced toxicity. In contrast, the lipid raft-associated proteins flotillin-1 and -2 were required. We found that in mammalian cells, CT intoxication was dependent on the flotillins for trafficking between plasma membrane/endosomes and two pathways into the ER, only one of which appears to intersect the TGN. These results revise current models for CT intoxication and implicate protein scaffolding of lipid rafts in the endosomal sorting of the toxin-GM1 complex. IntroductionCholera toxin (CT) is an AB 5 -subunit toxin responsible for the massive secretory diarrhea seen in epidemic cholera. As for most toxins, CT must gain access to the cytosol of host cells to cause disease. The strategy employed by CT is to bind ganglioside GM1 in the plasma membrane (PM) via the B-subunit (CTB). GM1 carries the toxin retrograde through endosomes, the trans-Golgi network (TGN), and likely all the way into the ER (1, 2). In the ER, a portion of the A-subunit (CTA), the A1-chain, crosses to the cytosol by coopting the machinery that retro-translocates terminally misfolded proteins for degradation by the proteasome (termed ER-associated degradation [ERAD]; refs. 3, 4). The A1-chain refolds in the cytosol and activates adenylate cyclase to increase cAMP. The mechanisms for lipid sorting and ERAD usurped by CT are fundamental to eukaryotic cell biology but remain incompletely understood. To explore how CT exploits these pathways in an unbiased way, we used the zebrafish as a model because it is amenable to genetic screens. Here, we show that CT intoxicates zebrafish embryos by hijacking the same basic mechanisms used in mammalian cells and examine the dependence of CT toxicity on two families of proteins implicated in toxin action: the flotillins and Derlins. These proteins have emerged as important components of lipid-based trafficking and ERAD, respectively.There is evidence that GM1 sorts CT retrograde from PM to ER by association with lipid rafts (2, 5-8). Lipid rafts are cooperative selfassemblies of lipids and proteins that influence various aspects of
Recent studies have linked the ER stress sensor IRE1α with the RIG-I pathway, which triggers an inflammatory response upon detection of viral RNAs. In response to ER dysfunction, IRE1α cleaves mRNA into single-strand fragments that lack markers of self, which activate RIG-I. Certain microbial products from mucosal pathogens activate this pathway by binding IRE1α directly, and the discovery that IRE1 is amplified at mucosal surfaces by gene duplication suggests an important role for IRE1 in mucosal immunity. Here, we review evidence in support of this hypothesis, and propose a model wherein IRE1 surveys the integrity of the ER, acting as a guard receptor and a pattern recognition receptor, capable both of sensing cellular stress caused by microbial infection and of responding to pathogens directly.
Membrane type 1 (MT1) matrix metalloproteinase (MMP-14)is a membrane-tethered MMP considered to be a major mediator of pericellular proteolysis. MT1-MMP is regulated by a complex array of mechanisms, including processing and endocytosis that determine the pool of active proteases on the plasma membrane. Autocatalytic processing of active MT1-MMP generates an inactive membrane-tethered 44-kDa product (44-MT1) lacking the catalytic domain. This form preserves all other enzyme domains and is retained at the cell surface. Paradoxically, accumulation of the 44-kDa form has been associated with increased enzymatic activity. Here we report that expression of a recom- Membrane type 1 matrix metalloproteinase (MT1-MMP, 2 MMP-14) is a type I-transmembrane protease and a major mediator of pericellular proteolysis. MT1-MMP is responsible for the proteolytic cleavage of multiple pericellular and membrane-associated substrates, including collagens and other extracellular matrix proteins, growth factors, growth factor receptors, cell adhesion proteins and their receptors, cytokines, protease inhibitors, and proteases, just to mention a few (1-5). MT1-MMP is also the major physiological activator of pro-MMP-2 (pro-gelatinase A) on the cell surface (6, 7), a process that further contributes to pericellular proteolysis. As a multifunctional protease, MT1-MMP elicits profound effects on cell behavior and has been implicated in the pathogenesis of various human diseases, including cancer (8 -10), diabetes (11, 12), vascular (13, 14), and connective tissue diseases (2).The importance of MT1-MMP for pericellular proteolysis demands a tight control of its catalytic activity at the cell surface. This is partly achieved by the action of endogenous protease inhibitors, the tissue inhibitors of metalloproteinases (TIMPs), which bind to the active site inhibiting catalysis (15). In addition, by virtue of being a membrane-anchored protease, MT1-MMP developed a unique set of regulatory mechanisms that control enzymatic activity independently of TIMPs. These processes include the targeting of active enzyme to specific plasma membrane locations, endocytosis, and autocatalytic processing (1, 16 -19). Together, these distinct processes determine the level of active enzyme on the cell surface. However, how these processes are integrated to control the pool of active MT1-MMP is not understood.The processing of MT1-MMP is a cell surface event in which the active enzyme is usually autocatalytically cleaved in trans to generate a major membrane-anchored product of ϳ44 kDa (also referred to as the 43-or 45-kDa species in some studies) and a soluble ϳ18-kDa inactive fragment of the catalytic domain (6, 20 -25). The 44-kDa product of MT1-MMP is detected in cultured cells expressing natural MT1-MMP (20, 26 -32) and has been found in platelets (33), human tumors extracts (34 -36), and extracts of arthritic synovial tissues (37). MT1-MMP processing is stimulated by a variety of factors known to stimulate MT1-MMP expression, trafficking, and/or endocytosi...
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