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Lecture 3 Vesicular Trafficking -Cops and Clathrins -Arfs, Rabs, Sars -Snares. Vesicular Trafficking allows Proteins and Vesicles to Reach their Destinations. The orientation of transmembrane proteins. Proteins IN the ER face the OUTSIDE of the cell. COPII = ER-> Golgi
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Lecture 3 Vesicular Trafficking -Cops and Clathrins -Arfs, Rabs, Sars -Snares
Vesicular Trafficking allows Proteins and Vesicles to Reach their Destinations
The orientation of transmembrane proteins Proteins IN the ER face the OUTSIDE of the cell
COPII = ER-> Golgi COPI = Golgi to Golgi
Vesicular Trafficking allows Proteins and Vesicles to Reach their Destinations
The orientation of transmembrane proteins Proteins IN the ER face the OUTSIDE of the cell
COPII = ER-> Golgi COPI = Golgi to Golgi
Vesicle budding and vesicle fusion are two different processes Both mechanically and mechanistically
Receptor-mediated Endocytosis requires clathrin Triskeleion = 3 large and 3 small polypeptides = 1 clathrin
Adaptin binds clathrin and receptors, acting as a bridge (4 types) Hsp70 chaperone and auxillin uncoat the vesicle. What prevents uncoating at membranes? Vesicles form at many membranes (Golgi, PM) At these membranes COPI and COPII function instead of clathrin Vesicles can be tubular
GTPases function in vesicle formation GAP = GTPase Activating Protein GEF = Guanine Nucleotide Exchange Factor
GTPases are required for vesicle formation (start) and Vesicle fusion (end) ARF is the GTPase for COPI and Sar is the GTPase for COPII GEFs determine when the vesicle is ready to bud GEF activation triggers GTPase activation and hydrophobic tail exposure GAPs triggers GTPase inactivation. It falls off the membrane and triggers coat disassembly
Snares guide vesicular transport Vesicle-surface markers that direct vesicles to the correct place V=vesicle and t=target SNARES
Snares are integral-membrane proteins that pull membranes together. The coiled coil The coiled-coil is a tightly intertwined set of 4 a-helix domains Three are contributed by t-snares, and 1 by the v-snare At least 1 of the t-snares is an integral-membrane protein Snares (20) and Rabs Neuronal snares are the targets of neural toxin proteases (botulism)
Snares also promote Membrane fusion
Rab GTPases ensure the specificity of vesicular docking 30 members -each bind a particular vesicle -On the cytoplasmic face Rabs interact with Snares Variation in Rab C-terminal tails Variation in effectors Rabs are different from coat Assembly GTPases (ARFs)
SMAP2, a Novel ARF GTPase-activating Protein, Interacts with Clathrin and Clathrin Assembly Protein and Functions on the AP-1–positive Early Endosome/Trans-Golgi Network Waka Natsume et al. We recently reported that SMAP1, a GTPase-activating protein (GAP) for Arf6, directly interacts with clathrin and regulates the clathrin-dependent endocytosis of transferrin receptors from the plasma membrane. Here, we identified a SMAP1 homologue that we named SMAP2. Like SMAP1, SMAP2 exhibits GAP activity and interacts with clathrin heavy chain (CHC). Furthermore, we show that SMAP2 interacts with the clathrin assembly protein CALM. Unlike SMAP1, however, SMAP2 appears to be a regulator of Arf1 in vivo. SMAP2 colocalized with the adaptor proteins for clathrin AP-1 and EpsinR on the early endosomes/trans-Golgi-network (TGN). Moreover, overexpression of SMAP2 delayed the accumulation of TGN38/46 molecule on the TGN. This suggests that SMAP2 functions in the retrograde, early endosome-to-TGN pathway in a clathrin- and AP-1–dependent manner. Thus, the SMAP gene family constitutes an important ArfGAP subfamily, with each SMAP member exerting both common and distinct functions in vesicle trafficking.
How are Snares separated? NSF is an ATPase that dissociates Snare pairs
HIV enters through membrane fusion Influenza enters through receptor-mediated endocytosis IM-like Proteins Hydrophobic Tails exposed Snare-like