Proteomic profiling of the prechylomicron transport vesicle involved in the assembly and secretion of apoB‐48‐containing chylomicrons in the intestinal enterocytes

et al. 2012

Journal of Proteomics

The VLDL transport vesicle (VTV) mediates the transport of nascent VLDL particles from the ER to the Golgi and plays a key role in VLDL-secretion from the liver. The functionality of VTV is controlled by specific proteins; however, full characterization and proteomic profiling of VTV remain to be carried out. Here, we report the first proteomic profile of VTVs. VTVs were purified to their homogeneity and characterized biochemically and morphologically. Thin section transmission electron microscopy suggests that the size of VTV ranges between 100 nm to 120 nm and each vesicle contains only one VLDL particle. Immunoblotting data indicate VTV concentrate apoB100, apoB48 and apoAIV but exclude apoAI. Proteomic analysis based on 2D-gel coupled with MALDI-TOF identified a number of vesicle-related proteins, however, many important VTV proteins could only be identified using LC-MS/MS methodology. Our data strongly indicate that VTVs greatly differ in their proteome with their counterparts of intestinal origin, the PCTVs. For example, VTV contains Sec22b, SVIP, ApoC-I, reticulon 3, cideB, LPCAT3 etc. which are not present in PCTV. The VTV proteome reported here will provide a basic tool to study the mechanisms underlying VLDL biogenesis, maturation, intracellular trafficking and secretion from the liver.

Section: Resultssupporting

confidence: 92%

Section: Resultssupporting

confidence: 79%

Proteomic Analysis of the Very Low Density Lipoprotein (VLDL) transport vesicles

Rahim

Nafi-valencia

et al. 2012

Journal of Proteomics

Molecular Membrane Biology

“…Further proteomic analyses of isolated PCTVs might shed light on this apparent contraction and help to identify new candidates to define function and elucidate the mechanism. Such experiments have already revealed cytoskeletal proteins and a large number of enzymes and chaperones to be associated with PCTVs (Wong et al 2009). In addition, clear and definitive morphological data, such as immunogold labelling and electron tomography would resolve the issue of whether PCTVs are encapsulated by COPII.…”

Section: Export Of Lipoproteinsmentioning

confidence: 96%

Cargo loading at the ER

Schmidt

Stephens

2010

Trafficking of newly synthesized cargo through the early secretory pathway defines and maintains the intracellular organization of eukaryotic cells as well as the organization of tissues and organs. The importance of this pathway is underlined by the increasing number of mutations in key components of the ER export machinery that are causative of a diversity of human diseases. Here we discuss the molecular mechanisms that dictate cargo selection during vesicle budding. While, in vitro reconstitution assays, unicellular organisms such as budding yeast, and mammalian cell culture still have much to offer in terms of gaining a full understanding of the molecular basis for secretory cargo export, such assays have to date been limited to analysis of smaller, freely diffusible cargoes. The export of large macromolecular complexes from the ER such as collagens (up to 300 nm) or lipoproteins (~500 nm) presents a clear problem in terms of maintaining both selectivity and efficiency of export. It has also become clear that in order to translate our knowledge of the molecular basis for ER export to a full understanding of the implications for normal development and disease progression, the use of metazoan models is essential. Combined, these approaches are now starting to shed light not only on the mechanisms of macromolecular cargo export from the ER but also reveal the implications of failure of this process to human development and disease.

“…We have shown previously that a unique composition of SNARE complex is required for the fusion of PCTVs (pre-chylomicron transport vesicles) with intestinal cis -Golgi [30,31]. The PCTV is the largest ER-derived vesicle [32,33] that uniquely utilizes VAMP7 (vesicle-associated membrane protein 7) as a v-SNARE [31,34]. Although both VTVs and PCTVs are the large ER-derived vesicles engaged in ER–Golgi transport of TAG-rich lipoproteins, VLDL and chylomicrons respectively, both vesicles appeared to be fundamentally different in their budding and fusion mechanisms.…”

Section: Introductionmentioning

confidence: 99%

The identification of the SNARE complex required for the fusion of VLDL-transport vesicle with hepatic cis-Golgi

Mani

2010

Biochemical Journal

VLDLs (very-low-density lipoproteins) are synthesized in the liver and play an important role in the pathogenesis of atherosclerosis. Following their biogenesis in hepatic ER (endoplasmic reticulum), nascent VLDLs are exported to the Golgi which is a physiologically regulatable event. We have previously shown that a unique ER-derived vesicle, the VTV (VLDL-transport vesicle), mediates the targeted delivery of VLDL to the Golgi lumen. Because VTVs are different from other ER-derived transport vesicles in their morphology and biochemical composition, we speculated that a distinct set of SNARE (soluble N-ethylmaleimide-sensitive factor-attachment protein receptor) proteins would form a SNARE complex which would eventually facilitate the docking/fusion of VTVs with Golgi. Our results show that Sec22b is concentrated in VTVs as compared with the ER. Electron microscopic results show that Sec22b co-localizes with p58 and Sar1 on the VTV surface. Pre-treatment of VTV with antibodies against Sec22b inhibited VTV–Golgi fusion, indicating its role as a v-SNARE (vesicle SNARE). To isolate the SNARE complex, we developed an in vitro docking assay in which VTVs were allowed to dock with the Golgi, but fusion was prevented to stabilize the SNARE complex. After the docking reaction, VTV–Golgi complexes were collected, solubilized in 2% Triton X-100 and the SNARE complex was co-immunoprecipitated using anti-Sec22b or GOS28 antibodies. A ~ 110 kDa complex was identified in non-boiled samples that was dissociated upon boiling. The components of the complex were identified as Sec22b, syntaxin 5, rBet1 and GOS28. Antibodies against each SNARE component significantly inhibited VTV–Golgi fusion. We conclude that the SNARE complex required for VTV–Golgi fusion is composed of Sec22b, syntaxin 5, rBet1 and GOS28.