Characterization of Proteins Involved in Membrane Fusion- Atlastin and Munc18c

Verma, Avani

16 September 2013

Membranes provide a barrier to cells and organelles, and allow the selective transport of molecules between compartments. Membrane fusion is essential for organelle biogenesis as well as trafficking of molecules between cellular compartments. Membrane fusion is also required for the formation of the branched network of tubules that make up the Endoplasmic Reticulum (ER). One protein implicated in ER fusion is Atlastin, a dynamin like GTPase. Mutations in Atlastin-1, among others, cause Hereditary Spastic Paraplegias (HSP), a group of neurological disorders that cause progressive weakness of lower extremities. We have shown that the C-terminal tail of atlastin is necessary for membrane fusion. The requirement of the C-terminal tail can be partially abrogated in an unstable lipid environment. This implies that the C-terminal tail of Atlastin plays a role in perturbing the lipid bilayer to allow membrane fusion. Understanding the molecular details of how Atlastin drives membrane fusion may help elucidate the pathogenesis of HSP. Intracellular fusion at the plasma membrane is SNARE mediated and regulated by Sec1p/Munc18 (SM) proteins. Increased rate of glucose transport into fat and muscles cells by translocation of glucose transporter GLUT4 in response to insulin is a SNARE regulated fusion process. Recent reports have linked Munc18c and Syntaxin4 with obesity and Type 2 diabetes. We characterized the function of Munc18c, an SM protein, in regulating GLUT-4 containing vesicle fusion with the plasma membrane. We have shown that Munc18c directly inhibits membrane fusion by interacting with its cognate SNARE complexes. Characterization of membrane fusion in a minimal system as the in vitro liposome fusion assay offers a powerful tool with which to finely dissect the mechanistic basis of SM protein function.

Membrane Fusion

Atlastin

Munc18c

Regulation of Exocytosis by Syntaxin 4-Munc18c Complexes

Jewell, Jenna Lee

31 August 2010

Indiana University-Purdue University Indianapolis (IUPUI) / Type 2 diabetes involves defects in glucose-stimulated insulin secretion (GSIS) from the pancreatic beta cells in combination with defects in peripheral (muscle and adipose) tissue glucose uptake. Both GSIS and glucose uptake are regulated by Syntaxin 4 (Syn4)-Munc18c complexes. Importantly, reports link obesity and Type 2 diabetes in humans with changes in protein levels of Munc18c and Syn4; yet the molecular mechanisms underlying this requirement remain unclear. The central hypothesis proposed is that Syn4-Munc18c complexes are modulated by post-translational modifications and novel interactions. Toward this, we found that Syn4-Munc18c complexes are regulated by tyrosine phosphorylation of Munc18c at Y219 in beta cells. Munc18c tyrosine phosphorylation disrupts Syn4-Munc18c complexes, which leads to an increase in Munc18c associating with the double C2 domain protein Doc2β. Disruption of Syn4-Munc18c upon tyrosine phosphorylation results in an increase in Syn4-SNARE complex formation and GSIS from beta cells. Similarly, tyrosine phosphorylation of Munc18c at Y219 and also Y521, disrupts its association with Syn4 in insulin-stimulated 3T3L1 adipocytes and skeletal muscle. In vitro kinase assays further suggested that the insulin receptor tyrosine kinase targeted Y521 of Munc18c. Further investigations using 3T3L1 adipocytes and skeletal muscle extracts indicate that Munc18c interacts with the insulin receptor tyrosine kinase in an insulin-dependent manner, resulting in phosphorylation of Munc18c, coordinate with the timing of its dissociation from Syn4. Finally, we found that stimulus-induced changes occurred also with Syn4, most notably in the islet beta cells. Syn4-mediated insulin release requires F-actin remodeling to mobilize insulin granules to the plasma membrane. Our studies reveal that Syn4 directly associates with F-actin in MIN6 beta cells, and that the disruption of this complex correlates with increases in glucose-stimulated insulin secretion. Future studies will focus upon the potential link between Syn4, F-actin remodeling with Munc18c, to further gain understanding of the requirements for Syn4-Munc18c complexes in insulin secretion. In sum, given the parallels of Munc18c tyrosine phosphorylation in regulating Syn4-Munc18c interaction and exocytosis in beta cells and peripheral tissues, manipulations of this complex may have therapeutic potential as a strategy to treat Type 2 diabetes.

Munc18c, Syntaxin 4, SNARE, diabetes

Exocytosis -- Regulation

Diabetes -- Research

Molecular Interactions of Munc18cand GLUT4-associated SNARE proteins

Latham, Catherine Frances Mary

Unknown Date

The focus of this thesis is to characterise the interactions between GLUT4-related SNARE proteins – syntaxin4, SNAP23 and VAMP2 – and a regulatory protein, Munc18c. GLUT4 is the primary insulin-regulated glucose transporter and is presentin fat and muscle cells. GLUT4 is held in intracellular pools of vesicles until it is transported to the cell surface upon insulin stimulation. Insulin initiates a cellular signalling cascade via the insulin receptor on the cell membrane, which in turn stimulates GLUT4 vesicles to move to the cell surface where they fuse to the plasmamembrane via SNARE proteins. SNAREs are membrane-anchored proteins present on both vesicle and target membranes that form a tight complex which brings themembranes together for fusion. Fusion of vesicles to the target membrane releases the vesicular cargo.SNARE-mediated membrane fusion is a conserved mechanism that controls many other vesicle fusion processes such as neurotransmitter release and yeast vesicular trafficking. However, the regulation of the SNARE mechanism is not fully understood. SNAREs can interact with many other proteins that could act as regulatory factors,and studies have focused primarily on a group of effector proteins called Sec1p/Munc18 (SM) proteins. SM proteins were discovered and characterised because they bind to one type of SNARE protein, syntaxin. The SM protein that interacts with the GLUT4-related SNARE, syntaxin4, is Munc18c.The aim of this thesis was to investigate Munc18c interactions with SNARE proteins, principally syntaxin4, using biochemical techniques with purified recombinant proteins. This work was carried out in several stages including: 1) development of methods to produce and purify GLUT4-related SNARE proteins, SNARE complexes and Munc18c, 2) development of an assay to quantify Munc18c interactions with binding partners using surface plasmon resonance, 3) investigation into interactions between Munc18c and SNARE ternary complex, 4) characterising Munc18c interactions with syntaxin4, and 5) developing a method to produce selenomethionine-containing Munc18c in a baculovirus system to be used in structural studies. The methods and outcomes of these experiments are described inthis thesis. There were two major outcomes from this work. Firstly, Munc18c interacts with SNARE ternary complex, and secondly, Munc18c requires only the N-terminal 29residues of syntaxin4 for an interaction to occur. These results were determined using pulldown assays with purified proteins, as well as other chromatographic methods to show that protein complexes were formed. The steps taken to develop these binding assays are also discussed. Initial crystallisation conditions forMunc18c-HIS and a peptide consisting of syntaxin4 residues 1-20 have been identified using crystallisation screens. The interactions determined for Munc18c binding to Sx4 are in direct contrast to those of neuronal SM protein, Munc18a, and its interaction with neuronal SNARE proteins - Munc18a does not bind to its ternary complex and binds to the entire cytoplasmic domain of Sx1a. Rather, the Munc18c:Sx4 interactions are similar to that for the yeast SM protein, Sly1p, which can interact with both its SNARE ternary complex and with its syntaxin via the Nterminal residues. Another interesting outcome of this research was that syntaxin4 binds to metals (cobalt and nickel). This finding represents the first reported for a syntaxin interacting with metals. Preliminary results indicate that un-tagged syntaxin4 can bind to cobalt resin, and to nickel immobilised on a chip. This interesting and novel property of syntaxin4 binding was serendipitously discovered while investigating conditions for the Munc18c assay. Overall, I have shown that Munc18c, the SM protein involved in GLUT4 trafficking, interacts with SNARE proteins in a different manner to its mammalian counterpart inneurons, Munc18a, and is more like Sly1p, a yeast ER-Golgi SM protein. Munc18c interacts with SNARE complexes and only the N-terminal residues of syntaxin4.These interactions demonstrate that the regulatory mechanism for SNARE-mediated fusion is conserved between yeast and mammals. This finding has several implications for the role of Munc18c in the exocytosis of GLUT4-containing vesicles. Munc18c could act at several stages in the fusion process via syntaxin4 binding.These interactions could involve binding to other proteins (such as synip or tomosyn), conformational switching of syntaxin4 or interaction with metal ions to induce conformational changes in the proteins. Finally, these studies of GLUT4 exocytosis contribute to our understanding of glucose transport disorders such as Type 2 diabetes and could one day pave the way for the design of therapeutic agents.

exocytosis

glucose

GLUT4

SNARE

pulldown

protein-protein interactions

biacore

crystallisation

Munc18c