Presentation is loading. Please wait.

Presentation is loading. Please wait.

Secretion: Dense-core vesicles can kiss-and-run too

Published byIndra Hengki Kusnadi Modified over 5 years ago

Similar presentations

Presentation on theme: "Secretion: Dense-core vesicles can kiss-and-run too"— Presentation transcript:

1 Secretion: Dense-core vesicles can kiss-and-run too
Cristina R Artalejo, Abdeladim Elhamdani, H.Clive Palfrey  Current Biology  Volume 8, Issue 2, Pages R62-R65 (January 1998) DOI: /S (98)

2 Figure 1 At the top is shown the oxidation reaction which converts catecholamines to quinones and which, in the presence of an electric field, generates electrons that can be measured by amperometry. Below is illustrated the set-up for patch amperometry [6]. The carbon fibre electrode is contained within a patch electrode, allowing the simultaneous recordings shown in the inset: catecholamine release (upper trace), capacitance increase (middle trace) and membrane conductance (lower trace). In the recordings shown, a dense-core vesicle attaches to the membrane via a flickering fusion pore (note noise in record) that allows passage of catecholamine recorded as a discrete foot signal not associated with the subsequent spike (top trace). Note that, at the asterisk, the fusion pore flickers open and closed, also reflected in the capacitance trace. Current Biology 1998 8, R62-R65DOI: ( /S (98) )

3 Figure 2 A comparison of the kiss-and-run and complete fusion models of dense-core vesicle exocytosis. In the complete fusion model (left), the dense-core vesicle membrane becomes continuous with the plasma membrane, and vesicle proteins mix with plasma membrane proteins. Secretion is by ‘degranulation’, in which the entire vesicular content is extruded. Catecholamine molecules are released from the matrix and all components enter the extracellular space. Retrieval is by coated pits, which become vesicles that carry dense-core vesicle membrane proteins to sites of new dense-core vesicle assembly. In the kiss-and-run model (right), dense-core vesicles connect to the membrane via a ‘fusion pore’. One possibility (shown) is that catecholamine release occurs through the fusion pore by ion exchange with incoming Na+ ions (counterions could also enter the vesicle across its own membrane [12]). Rapid endocytosis [11] ensues, pinching off the dense-core vesicle intact from the membrane. Refilling with new transmitter can then take place immediately, rapidly reforming a mature dense-core vesicle. Rings around retracting vesicles in both pathways represent dynamin, known to be involved in the pinch-off reaction. Current Biology 1998 8, R62-R65DOI: ( /S (98) )

Download ppt "Secretion: Dense-core vesicles can kiss-and-run too"

Similar presentations

SNARE complex and Ca 2+ sensor Endocytic invagination 1.Bar-domain containing protein such as amphiphysin which inducing membrane curvature 2.Clathrin,

SNARE complex and Ca 2+ sensor Endocytic invagination 1.Bar-domain containing protein such as amphiphysin which inducing membrane curvature 2.Clathrin,
Cellular Neuroscience (207) Ian Parker Lecture # 18 - Quantal release of neurotransmitter.

Cellular Neuroscience (207) Ian Parker Lecture # 18 - Quantal release of neurotransmitter.
Ch. 4: “Cells & Their Environment”

Ch. 4: “Cells & Their Environment”
01.26.11 Lecture 6 - Intracellular compartments and transport I.

Lecture 6 - Intracellular compartments and transport I.
Cell Membrane lecture II Chapter 4 Mr. Montjoy, guest lecturer.

Cell Membrane lecture II Chapter 4 Mr. Montjoy, guest lecturer.
Active Transport, Diffusion and Osmosis. Passive Transport by Diffusion Diffusion is the movement of molecules from an area of high concentration to an.

Active Transport, Diffusion and Osmosis. Passive Transport by Diffusion Diffusion is the movement of molecules from an area of high concentration to an.
Membrane structure and function

Membrane structure and function
Passive and Active Transport

Passive and Active Transport
Cells and Their Environment

Cells and Their Environment
Announcements Slides used at tutorial posted to webpage.

Announcements Slides used at tutorial posted to webpage.
Cells and Their Environment

Cells and Their Environment
The Plasma Membrane – Gateway to the Cell

The Plasma Membrane – Gateway to the Cell
Types of Cellular Transport  Passive Transport cell doesn’t use energy 1.Diffusion 2.Facilitated Diffusion 3.Osmosis  Active Transport cell does use.

Types of Cellular Transport  Passive Transport cell doesn’t use energy 1.Diffusion 2.Facilitated Diffusion 3.Osmosis  Active Transport cell does use.
Chapter 5: Homeostasis and Transport

Chapter 5: Homeostasis and Transport
Homeostasis and Cell Transport Chapter 5 Table of Contents Section 1 Passive Transport Section 2 Active Transport.

Homeostasis and Cell Transport Chapter 5 Table of Contents Section 1 Passive Transport Section 2 Active Transport.
Homeostasis and Cell Transport Chapter 5 Table of Contents Section 1 Passive Transport Section 2 Active Transport.

Homeostasis and Cell Transport Chapter 5 Table of Contents Section 1 Passive Transport Section 2 Active Transport.
ACTIVE TRANSPORT In many cases, cells must move materials from an area of lower concentration to an area of higher concentration. Higher conc Lower conc.

ACTIVE TRANSPORT In many cases, cells must move materials from an area of lower concentration to an area of higher concentration. Higher conc Lower conc.
Cycling of Matter in Living Systems 2.2 The Role of Cell Membrane in Transport.

Cycling of Matter in Living Systems 2.2 The Role of Cell Membrane in Transport.
A Closer Look at Cell Membranes  Aim: How do large particles enter and exit cells?  Do Now: Name some molecules/materials that enter and exit the cell.

A Closer Look at Cell Membranes  Aim: How do large particles enter and exit cells?  Do Now: Name some molecules/materials that enter and exit the cell.
3.6 How Do Diffusion And Osmosis Affect Transport Across The Plasma Membrane? Simple diffusion through the phospholipid bilayer Fig. 3-7a Simple diffusion.

3.6 How Do Diffusion And Osmosis Affect Transport Across The Plasma Membrane? Simple diffusion through the phospholipid bilayer Fig. 3-7a Simple diffusion.

Similar presentations

Ads by Google