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Tension Response at Adherens Junctions01:26

Tension Response at Adherens Junctions

2.8K
The adherens junctions that anchor cells together are multi-protein complexes that dynamically adapt to mechanical stimuli such as tensile forces and shear stress. Mechanosensory proteins in these junctions can sense such mechanical stimuli and undergo a shift in their conformation, resulting in an altered function — a process called mechanotransduction.
α-Catenin as a Mechanosensory Protein
The α-catenin of adherens junctions is an allosteric protein with three VH (vinculin...
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Adhesion01:14

Adhesion

41.3K
Adhesion occurs when one type of molecule is attracted to a different molecule. Water exhibits adhesive properties in the presence of polar surfaces, such as glass or cellulose in plants. For instance, when water is poured into a glass, the positively charged hydrogen molecules of water are more attracted to the negatively charged oxygen molecules in the silica than to the oxygen in neighboring water molecules.
Capillary action is a result of water’s adhesive tendencies. When a narrow...
41.3K
Cell-matrix's Response to Mechanical Forces01:13

Cell-matrix's Response to Mechanical Forces

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In animal cells, the extracellular matrix allows cells within tissues to withstand external stresses and transmits signals from the outside of the cell to the inside. The extracellular matrix is extensive, and its composition varies between different types of tissues. For example, the reticular fibers and ground substance make up the ECM in loose connective tissue, while collagen and bone minerals make up the ECM of bone tissue. 
Anchoring junctions mechanically attach a cell to the...
2.7K
Intracellular Signaling Affects Focal Adhesions01:17

Intracellular Signaling Affects Focal Adhesions

2.8K
Integrins act both as extracellular input receivers and as intracellular processing activators. As their name suggests, integrins are entirely integrated into the membrane structure. Their hydrophobic membrane-spanning regions interact with the phospholipid bilayer's hydrophobic region. These membrane receptors provide extracellular attachment sites for effectors like hormones and growth factors. They activate intracellular response cascades when their effectors are bound and active.
Some...
2.8K
Adherens Junctions01:24

Adherens Junctions

5.0K
Strong contact points between adjacent cells anchor them to each other, forming tissues. Such anchoring junctions are of two types –  adherens junctions and desmosomes. Adherens junctions are abundant in tissues such as  epithelium and endothelium, forming a continuous zone of adhesion called the adhesion belt. In other tissues, such as  heart muscle, they appear as clusters, linking the cells to produce coordinated heart muscle contraction.
Adherens Junctions are Dynamic
5.0K
Cell Adhesion Molecules - Types and Functions01:20

Cell Adhesion Molecules - Types and Functions

7.2K
Cell adhesion molecules (CAMs) are pivotal to multicellularity and the coordinated functioning of tissues and organ systems. They enable physical interactions between cells and provide mechanical strength to tissues. They also function as receptors for signal transmission across the plasma membrane. The CAMs are broadly classified into four families - integrins, cadherins, selectins, and immunoglobulin-like CAMs (IgCAMs).
CAM Families
The Integrin family of proteins is primarily  involved...
7.2K

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Related Experiment Video

Updated: Sep 7, 2025

Analyzing Cell Surface Adhesion Remodeling in Response to Mechanical Tension Using Magnetic Beads
07:55

Analyzing Cell Surface Adhesion Remodeling in Response to Mechanical Tension Using Magnetic Beads

Published on: March 8, 2017

8.6K

Sticking Together an Updated Model for Temporary Adhesion.

Philip Bertemes1,2, Alexandra L Grosbusch1,2, Anik Geschwindt1,2

  • 1Institute of Zoology, University of Innsbruck, 6020 Innsbruck, Austria.

Marine Drugs
|June 23, 2022
PubMed
Summary
This summary is machine-generated.

Flatworms use a unique bioadhesive for temporary attachment. Researchers identified two novel proteins, Tmed-krg1 and Tmed-tyr1, crucial for this adhesion system, paving the way for new synthetic glues.

Keywords:
PolycladidaRNA interferenceaquaticduo-gland adhesive systemgluein situ hybridisationnon-permanent adhesion

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Imaging Molecular Adhesion in Cell Rolling by Adhesion Footprint Assay
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Imaging Molecular Adhesion in Cell Rolling by Adhesion Footprint Assay

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Adhesion Frequency Assay for In Situ Kinetics Analysis of Cross-Junctional Molecular Interactions at the Cell-Cell Interface
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Imaging Molecular Adhesion in Cell Rolling by Adhesion Footprint Assay
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Imaging Molecular Adhesion in Cell Rolling by Adhesion Footprint Assay

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Area of Science:

  • Marine Biology
  • Biochemistry
  • Molecular Biology

Background:

  • Non-parasitic flatworms secrete bioadhesives for temporary substrate attachment against water flow.
  • Previous studies on adhesive proteins were limited to two flatworm taxa, revealing a lack of conserved surface-binding proteins.
  • Understanding the molecular basis of flatworm adhesion is crucial for bio-inspired material development.

Purpose of the Study:

  • To investigate the molecular mechanisms of temporary adhesion in the polyclad flatworm Theama mediterranea.
  • To identify novel genes and proteins involved in the flatworm bioadhesive system.
  • To explore the potential of these components for developing advanced synthetic adhesives.

Main Methods:

  • Genome and transcriptome sequencing of Theama mediterranea.
  • Tail-specific positional RNA sequencing.
  • In situ hybridization and RNA interference for gene expression and functional analysis.

Main Results:

  • Identified 15 candidate genes potentially involved in temporary adhesion.
  • Discovered a novel Kringle-domain-containing protein (Tmed-krg1) exclusively expressed in the anchor cell, essential for adhesion.
  • Identified a secreted tyrosinase (Tmed-tyr1) likely involved in crosslinking adhesive proteins.

Conclusions:

  • Two novel components, Tmed-krg1 and Tmed-tyr1, are key to the flatworm temporary adhesion system.
  • These findings expand the understanding of bioadhesive mechanisms in diverse flatworm taxa.
  • The identified proteins offer potential for developing advanced reversible synthetic glues for medical and industrial applications.