1. Navigation through the Plasma Membrane Molecular Landscape Shapes Random Organelle Movement
- Author
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Dun, Alison R., Lord, Gabriel J., Wilson, Rhodri S., Kavanagh, Deirdre M., Cialowicz, Katarzyna I., Sugita, Shuzo, Park, Seungmee, Yang, Lei, Smyth, Annya M., Papadopulos, Andreas, Rickman, Colin, and Duncan, Rory R.
- Subjects
Organelles ,Agricultural and Biological Sciences(all) ,Biochemistry, Genetics and Molecular Biology(all) ,Secretory Vesicles ,Cell Membrane ,mathematical modeling ,super-resolution ,cytoskeleton ,Biological Transport ,Membrane Fusion ,PC12 Cells ,Exocytosis ,Rats ,Report ,microscopy ,Animals ,SNARE Proteins ,actin ,vesicle - Abstract
Summary Eukaryotic plasma membrane organization theory has long been controversial, in part due to a dearth of suitably high-resolution techniques to probe molecular architecture in situ and integrate information from diverse data streams [1]. Notably, clustered patterning of membrane proteins is a commonly conserved feature across diverse protein families (reviewed in [2]), including the SNAREs [3], SM proteins [4, 5], ion channels [6, 7], and receptors (e.g., [8]). Much effort has gone into analyzing the behavior of secretory organelles [9, 10, 11, 12, 13], and understanding the relationship between the membrane and proximal organelles [4, 5, 12, 14] is an essential goal for cell biology as broad concepts or rules may be established. Here we explore the generally accepted model that vesicles at the plasmalemma are guided by cytoskeletal tracks to specific sites on the membrane that have clustered molecular machinery for secretion [15], organized in part by the local lipid composition [16]. To increase our understanding of these fundamental processes, we integrated nanoscopy and spectroscopy of the secretory machinery with organelle tracking data in a mathematical model, iterating with knockdown cell models. We find that repeated routes followed by successive vesicles, the re-use of similar fusion sites, and the apparently distinct vesicle “pools” are all fashioned by the Brownian behavior of organelles overlaid on navigation between non-reactive secretory protein molecular depots patterned at the plasma membrane., Graphical Abstract, Highlights • Membrane-proximal vesicle movements are random • Secretory molecules at the plasma membrane organize into conformational clusters • Random vesicle movements navigate among these clusters • This model explains vesicle behaviors without a requirement for functional pools, Dun et al. use mathematical modeling, super-resolution imaging, and biological perturbations to shape the membrane molecular landscape, examining the inter-relationship between the plasma membrane and organelle dynamics. They show that secretory vesicles at the cell surface move randomly, navigating among depots of secretory machinery molecules.
- Published
- 2017
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