Heterotetrameric adapter (AP) complexes cooperate with the small GTPase Arf1 or lipids in cargo selection, vesicle formation, and budding at endomembranes in eukaryotic cells. While most AP complexes also require clathrin as the outer vesicle shell, formation of AP-3-coated vesicles involved in Golgi-to-vacuole transport in yeast has been postulated to depend on Vps41, a subunit of the vacuolar HOPS tethering complex. HOPS has also been identified as the tether of AP-3 vesicles on vacuoles. To unravel this conundrum of a dual Vps41 function, we anchored Vps41 stably to the mitochondrial outer membrane. By monitoring AP-3 recruitment, we now show that Vps41 can tether AP-3 vesicles to mitochondria, yet AP-3 vesicles can form in the absence of Vps41 or clathrin. By proximity labeling and mass spectrometry, we identify the Arf1 GTPase-activating protein (GAP) Age2 at the AP-3 coat and show that tethering, but not fusion at the vacuole can occur without complete uncoating. We conclude that AP-3 vesicles retain their coat after budding and that their complete uncoating occurs only after tethering at the vacuole.
Lysosomes are essential for cellular recycling, nutrient signaling, autophagy, and pathogenic bacteria and viruses invasion. Lysosomal fusion is fundamental to cell survival and requires HOPS, a conserved heterohexameric tethering complex. On the membranes to be fused, HOPS binds small membrane-associated GTPases and assembles SNAREs for fusion, but how the complex fulfills its function remained speculative. Here, we used cryo-electron microscopy to reveal the structure of HOPS. Unlike previously reported, significant flexibility of HOPS is confined to its extremities, where GTPase binding occurs. The SNARE-binding module is firmly attached to the core, therefore, ideally positioned between the membranes to catalyze fusion. Our data suggest a model for how HOPS fulfills its dual functionality of tethering and fusion and indicate why it is an essential part of the membrane fusion machinery.
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Lysosomes are of central importance in cellular recycling, nutrient signaling and endocytosis, are tightly connected to autophagy and the invasion of pathogenic bacteria and viruses. Lysosomal fusion events are fundamental to cell survival and require HOPS, a conserved heterohexameric tethering complex. HOPS recognizes and binds small membrane-associated GTPases on lysosomes and organelles, and assembles membrane bound SNAREs for fusion. Through tethering, HOPS brings membranes in close proximity to each other and significantly increases fusion efficacy by catalysing SNARE assembly. Consequently, different HOPS mutations are causative for severe diseases. Despite its fundamental cellular duties, it remained speculative how HOPS fulfils its function as high-resolution structural data were unavailable. Here, we used cryo-electron microscopy to reveal the structure of HOPS. In the complex, two central subunits form the backbone and an assembly hub for the functional domains. Two GTPase binding units extend to opposing ends, while the SNARE binding module points to the side, resulting in a triangular shape of the complex. Unlike previously reported, HOPS is surprisingly rigid and extensive flexibility is confined to its extremities. We show that HOPS complex variants with mutations proximal to the backbone can still tether membranes but fail to efficiently promote fusion indicating, that the observed integrity of HOPS is essential to its function. In our model, the core of HOPS acts as a counter bearing between the flexible GTPase binding domains. This positions the SNARE binding module exactly between the GTPase anchored membranes to promote fusion. Our structural and functional analysis reveals the link between the spectacular architecture of HOPS and its mechanism that couples membrane tethering and SNARE assembly, to catalyse lysosomal fusion.
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