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Mechanisms of Membrane Domain Formation00:59

Mechanisms of Membrane Domain Formation

3.2K
Different physical properties of lipids and proteins allow them to localize and form distinct islands or domains in the membrane. Some membrane domains are formed due to protein-protein interactions, whereas others are formed due to the presence of specific lipids such as sphingolipids and sterols—for example, large proteins, such as bacteriorhodopsin, aggregate and create distinct domains.
Another mechanism for membrane domain formation involves membrane proteins interacting with...
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Lipids as Anchors01:32

Lipids as Anchors

5.9K
In the plasma membrane, the lipids forming the bilayer can also act as an anchor to tether proteins to the membrane. The three main types of lipid anchors found in eukaryotes are – prenyl groups, fatty acyl groups, and glycosylphosphatidylinositol or GPI groups. Prenyl and fatty acyl groups act as anchors on the cytosolic surface of the membrane, whereas GPI anchors proteins on the extracellular side.
The carboxy-terminal of most of the prenylated proteins, such as Ras proteins, contains...
5.9K
SNAREs and Membrane Fusion01:43

SNAREs and Membrane Fusion

10.2K
Once a transport vesicle has recognized its target organelle, the vesicular membrane needs to fuse with the target membrane to unload the cargo. Transmembrane proteins called SNAREs present on organelle membranes and their vesicles, mediate vesicle fusion.
SNAREs exist in pairs that symmetrically interact and catalyze the fusion of the lipid bilayers in vesicle and target organelle. v-SNARE in the vesicle membrane are single polypeptide chains that bind to a complementary t-SNARE, composed of 2...
10.2K
Tail-anchoring of Proteins in the ER Membrane01:45

Tail-anchoring of Proteins in the ER Membrane

2.8K
Tail-anchored, or TA, proteins are estimated to make up to 3-5% of membrane proteins found in the eukaryotic cell. Such proteins have a single transmembrane domain located approximately 30 amino acid residues upstream from the C-terminal end. As a result, the signal recognition particle (SRP) cannot guide a TA protein to the ER membrane for cotranslational insertion. Hence, they are integrated into the ER membrane post-translationally using their C-terminal end as the anchor. TA proteins...
2.8K
Types of Membrane Protrusions01:28

Types of Membrane Protrusions

3.0K
The protrusion of the cell surface is an initial step for several cellular processes, including cell migration, phagocytosis, and neurite outgrowth. These membrane protrusions are a result of cytoskeletal rearrangement. The most  widely observed cell protrusions include lamellipodia, pseudopodia, filopodia, microvilli, invadopodia, and podosomes. These protrusions can be of two types — static or dynamic.
The microvilli, an example of stable protrusions, are finger-like projections...
3.0K
Mechanisms of Membrane-bending01:15

Mechanisms of Membrane-bending

2.6K
The living membranes are flexible due to their fluid mosaic nature; however, their bending into different shapes is an active process regulated by specific lipids and proteins. The membrane bending can be transient as seen in vesicles or stable for a long time as in microvilli. Cells regulate the size, location, and duration of the membrane curvature.
Membrane bending can happen due to intrinsic changes in lipid composition or extrinsic association with different proteins. The proteins involved...
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Related Experiment Video

Updated: Apr 21, 2026

SNARE-mediated Fusion of Single Proteoliposomes with Tethered Supported Bilayers in a Microfluidic Flow Cell Monitored by Polarized TIRF Microscopy
10:58

SNARE-mediated Fusion of Single Proteoliposomes with Tethered Supported Bilayers in a Microfluidic Flow Cell Monitored by Polarized TIRF Microscopy

Published on: August 24, 2016

10.6K

Membrane tethering.

Pei Zhi Cheryl Chia1, Paul A Gleeson2

  • 1National Institute of Dental and Craniofacial Research, National Institutes of Health 30 Convent Drive, Bethesda, MD 20892-4340 USA.

F1000Prime Reports
|October 25, 2014
PubMed
Summary
This summary is machine-generated.

Membrane tethers and small GTPases guide cargo-carrying vesicles to their destinations, ensuring efficient delivery. These tethers coordinate protein complexes for precise membrane fusion and compartment organization.

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Area of Science:

  • Cell Biology
  • Molecular Biology
  • Biochemistry

Background:

  • Membrane trafficking is crucial for cellular function, involving vesicle docking and fusion.
  • Membrane tethers and small GTPases (guanosine triphosphatases) are key regulators of vesicle docking.
  • SNARE proteins mediate the final fusion event between vesicles and target membranes.

Purpose of the Study:

  • To review the properties and functions of membrane tethers in cellular transport.
  • To elucidate the mechanisms by which tethers facilitate vesicle docking.
  • To highlight the role of tethers in SNARE complex coordination and membrane organization.

Main Methods:

  • Literature review of biochemical and structural studies.
  • Analysis of existing data on membrane tether classification and localization.
  • Synthesis of information on the mechanistic roles of tethers in membrane trafficking.

Main Results:

  • Different classes of membrane tethers are well-defined with specific intracellular locations.
  • Tethers play a critical role in mediating the docking of transport vesicles.
  • Tethers are involved in coordinating SNARE complex assembly and regulating membrane compartment organization.

Conclusions:

  • Membrane tethers are essential for efficient and accurate membrane trafficking.
  • Understanding tether function provides insights into the regulation of endomembrane system organization.
  • This review consolidates current knowledge on tethers in both secretory and endocytic pathways.