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Activation of Integrins01:15

Activation of Integrins

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Integrins bind ligands and transmit information from outside the cell to inside or vice-versa through an "outside-in signaling" or "inside-out signaling."
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Integrins01:10

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Animal and protozoan cells do not have cell walls to help maintain shape and provide structural stability. Instead, these eukaryotic cells secrete a sticky mass of carbohydrates and proteins into the spaces between adjacent cells. This network of proteins and molecules is called an extracellular matrix or ECM.
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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.
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Exon Recombination02:32

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The evolution of new genes is critical for speciation. Exon recombination, also known as exon shuffling or domain shuffling, is an important means of new gene formation. It is observed across vertebrates, invertebrates, and in some plants such as potatoes and sunflowers. During exon recombination, exons from the same or different genes recombine and produce new exon-intron combinations, which might evolve into new genes. 
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Immunoglobulin-like Cell Adhesion Molecules01:31

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Immunoglobulin-like cell adhesion molecules or Ig-CAMs are a versatile group of cell surface glycoproteins belonging to the immunoglobulin protein superfamily. Ig-CAMs possess the characteristic immunoglobulin protein domains and other domains such as the fibronectin type III domain. The Ig domains are glycosylated to varying degrees in different Ig-CAMs.
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Selectins01:25

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Cell adhesion is  an essential aspect of multicellularity. While stable cell interactions usually occur between cells of the same type, transient cell interactions occur between cells of different tissue types, such as between neutrophils and endothelial cells. Selectins are one class of cell adhesion molecules (CAMs) that bind carbohydrate ligands to form transient cell adhesion. They are rod-like proteins with a long extracellular part of variable length ending with the lectin domain,...
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Related Experiment Video

Updated: Jan 18, 2026

Transmembrane Domain Oligomerization Propensity determined by ToxR Assay
06:45

Transmembrane Domain Oligomerization Propensity determined by ToxR Assay

Published on: May 26, 2011

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Molecular exaptation by the integrin αI domain.

Jeremy A Hollis1,2, Matthew C Chan1, Harmit S Malik1,3

  • 1Division of Basic Sciences, Fred Hutchinson Cancer Center, Seattle, WA 98109, USA.

Science Advances
|September 10, 2025
PubMed
Summary
This summary is machine-generated.

The I domain in integrins evolved from a collagen-binding domain, enabling ligand binding and preserving function despite blocking the ancestral pocket. This molecular exaptation expanded cellular communication in vertebrates.

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Area of Science:

  • Biochemistry
  • Evolutionary Biology
  • Structural Biology

Background:

  • Integrins are cell surface receptors crucial for cell adhesion and signaling.
  • Ligand binding induces conformational changes in integrins for signal transmission.
  • The evolution of the integrin alpha (α) subunit's inserted (I) domain presented a challenge to conventional activation mechanisms.

Purpose of the Study:

  • To elucidate how the I domain in integrins preserves function despite obstructing the ancestral ligand-binding pocket.
  • To investigate the evolutionary origin and mechanism of I domain-mediated integrin activation.
  • To understand the role of the I domain in expanding cellular communication in vertebrates.

Main Methods:

  • Comparative analysis of cryo-electron microscopy structures of αEβ7 and α4β7 integrins.
  • Determination of apo and ligand-bound states for both integrin types.
  • Tracing the evolutionary history of the I domain.

Main Results:

  • The I domain intrinsically mimics an extrinsic ligand to maintain integrin activation.
  • The I domain's origin was traced to an ancestral collagen-collagen interaction domain.
  • This ancient molecular exaptation allowed for immediate integrin activation upon I domain insertion.

Conclusions:

  • The evolution of the I domain represents a key adaptation in integrin function.
  • Molecular exaptation of a collagen-binding domain facilitated integrin activation and expanded signaling.
  • These findings provide insight into the evolutionary and biochemical basis of vertebrate cellular communication.