Vesicle docking in regulated exocytosis

Research output: Contribution to journalReviewResearch

Standard

Vesicle docking in regulated exocytosis. / Verhage, Matthijs; Sørensen, Jakob B.

In: Traffic - International Journal of Intracellular Transport, Vol. 9, No. 9, 2008, p. 1414-24.

Research output: Contribution to journalReviewResearch

Harvard

Verhage, M & Sørensen, JB 2008, 'Vesicle docking in regulated exocytosis', Traffic - International Journal of Intracellular Transport, vol. 9, no. 9, pp. 1414-24. https://doi.org/10.1111/j.1600-0854.2008.00759.x

APA

Verhage, M., & Sørensen, J. B. (2008). Vesicle docking in regulated exocytosis. Traffic - International Journal of Intracellular Transport, 9(9), 1414-24. https://doi.org/10.1111/j.1600-0854.2008.00759.x

Vancouver

Verhage M, Sørensen JB. Vesicle docking in regulated exocytosis. Traffic - International Journal of Intracellular Transport. 2008;9(9):1414-24. https://doi.org/10.1111/j.1600-0854.2008.00759.x

Author

Verhage, Matthijs ; Sørensen, Jakob B. / Vesicle docking in regulated exocytosis. In: Traffic - International Journal of Intracellular Transport. 2008 ; Vol. 9, No. 9. pp. 1414-24.

Bibtex

@article{ac2ec9f0fb7011de825d000ea68e967b,
title = "Vesicle docking in regulated exocytosis",
abstract = "In electron micrographs, many secretory and synaptic vesicles are found 'docked' at the target membrane, but it is unclear why and how. It is generally assumed that docking is a necessary first step in the secretory pathway before vesicles can acquire fusion competence (through 'priming'), but recent studies challenge this. New biophysical methods have become available to detect how vesicles are tethered at the target membrane, and genetic manipulations have implicated many genes in tethering, docking and priming. However, these studies have not yet led to consistent working models for these steps. In this study, we review recent attempts to characterize these early steps and the cellular factors to orchestrate them. We discuss whether assays for docking, tethering and priming report on the same phenomena and whether all vesicles necessarily follow the same linear docking-priming-fusion pathway. We conclude that most evidence to date is consistent with such a linear pathway assuming several refinements that imply that some vesicles can be nonfunctionally docked ('dead-end' docking) or, conversely, that the linear pathway can be greatly accelerated (crash fusion).",
author = "Matthijs Verhage and S{\o}rensen, {Jakob B}",
note = "Keywords: Animals; Exocytosis; Humans; Membrane Fusion; Microscopy, Electron; Secretory Pathway; Secretory Vesicles; Synaptic Membranes; Synaptic Vesicles; Vesicular Transport Proteins",
year = "2008",
doi = "10.1111/j.1600-0854.2008.00759.x",
language = "English",
volume = "9",
pages = "1414--24",
journal = "Traffic",
issn = "1398-9219",
publisher = "Wiley-Blackwell",
number = "9",

}

RIS

TY - JOUR

T1 - Vesicle docking in regulated exocytosis

AU - Verhage, Matthijs

AU - Sørensen, Jakob B

N1 - Keywords: Animals; Exocytosis; Humans; Membrane Fusion; Microscopy, Electron; Secretory Pathway; Secretory Vesicles; Synaptic Membranes; Synaptic Vesicles; Vesicular Transport Proteins

PY - 2008

Y1 - 2008

N2 - In electron micrographs, many secretory and synaptic vesicles are found 'docked' at the target membrane, but it is unclear why and how. It is generally assumed that docking is a necessary first step in the secretory pathway before vesicles can acquire fusion competence (through 'priming'), but recent studies challenge this. New biophysical methods have become available to detect how vesicles are tethered at the target membrane, and genetic manipulations have implicated many genes in tethering, docking and priming. However, these studies have not yet led to consistent working models for these steps. In this study, we review recent attempts to characterize these early steps and the cellular factors to orchestrate them. We discuss whether assays for docking, tethering and priming report on the same phenomena and whether all vesicles necessarily follow the same linear docking-priming-fusion pathway. We conclude that most evidence to date is consistent with such a linear pathway assuming several refinements that imply that some vesicles can be nonfunctionally docked ('dead-end' docking) or, conversely, that the linear pathway can be greatly accelerated (crash fusion).

AB - In electron micrographs, many secretory and synaptic vesicles are found 'docked' at the target membrane, but it is unclear why and how. It is generally assumed that docking is a necessary first step in the secretory pathway before vesicles can acquire fusion competence (through 'priming'), but recent studies challenge this. New biophysical methods have become available to detect how vesicles are tethered at the target membrane, and genetic manipulations have implicated many genes in tethering, docking and priming. However, these studies have not yet led to consistent working models for these steps. In this study, we review recent attempts to characterize these early steps and the cellular factors to orchestrate them. We discuss whether assays for docking, tethering and priming report on the same phenomena and whether all vesicles necessarily follow the same linear docking-priming-fusion pathway. We conclude that most evidence to date is consistent with such a linear pathway assuming several refinements that imply that some vesicles can be nonfunctionally docked ('dead-end' docking) or, conversely, that the linear pathway can be greatly accelerated (crash fusion).

U2 - 10.1111/j.1600-0854.2008.00759.x

DO - 10.1111/j.1600-0854.2008.00759.x

M3 - Review

C2 - 18445120

VL - 9

SP - 1414

EP - 1424

JO - Traffic

JF - Traffic

SN - 1398-9219

IS - 9

ER -

ID: 16835331