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Intracellular Signaling Cascades01:24

Intracellular Signaling Cascades

Once a ligand binds to a receptor, the signal is transmitted through the membrane and into the cytoplasm. The continuation of a signal in this manner is called signal transduction. Signal transduction only occurs with cell-surface receptors, which cannot interact with most components of the cell, such as DNA. Only internal receptors can interact directly with DNA in the nucleus to initiate protein synthesis. When a ligand binds to its receptor, conformational changes occur that affect the...
Intracellular Signaling Cascades01:24

Intracellular Signaling Cascades

Once a ligand binds to a receptor, the signal is transmitted through the membrane and into the cytoplasm. The continuation of a signal in this manner is called signal transduction. Signal transduction only occurs with cell-surface receptors, which cannot interact with most components of the cell, such as DNA. Only internal receptors can interact directly with DNA in the nucleus to initiate protein synthesis. When a ligand binds to its receptor, conformational changes occur that affect the...
Overview of Cell Signaling01:23

Overview of Cell Signaling

Despite the protective membrane that separates a cell from the environment, cells need the ability to detect and respond to environmental changes. Additionally, cells often need to communicate with one another. Unicellular and multicellular organisms use a variety of cell signaling mechanisms to communicate with the environment.
Cells respond to many types of information, often through receptor proteins positioned on the membrane. For example, skin cells respond to and transmit touch...
Overview of Cell Signaling01:23

Overview of Cell Signaling

Despite the protective membrane that separates a cell from the environment, cells need the ability to detect and respond to environmental changes. Additionally, cells often need to communicate with one another. Unicellular and multicellular organisms use a variety of cell signaling mechanisms to communicate with the environment.
Cells respond to many types of information, often through receptor proteins positioned on the membrane. For example, skin cells respond to and transmit touch...
Amplifying Signals via Enzymatic Cascade01:22

Amplifying Signals via Enzymatic Cascade

When a ligand binds to a cell-surface receptor, the receptor's intracellular domain changes shape, which may either activate its enzyme function or allow its binding to other molecules. The initial signal is amplified by most signal transduction pathways. This means that a single ligand molecule can activate multiple molecules of a downstream target. Proteins that relay a signal are most commonly phosphorylated at one or more sites, activating or inactivating the protein. Kinases catalyze the...
Amplifying Signals via Second Messengers01:15

Amplifying Signals via Second Messengers

Many receptor binding ligands are hydrophilic; they do not cross the cell membrane but bind to cell-surface receptors. Thus, their message must be relayed by second messengers present in the cell cytoplasm. There are several second messenger pathways, each with its own way of relaying information. For example, the G protein-coupled receptors can activate both phosphoinositol and cyclic AMP (cAMP) second messenger pathways. The phosphoinositol pathway is active when the receptor induces...

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Related Experiment Video

Updated: Jun 24, 2026

Applications of Spatio-temporal Mapping and Particle Analysis Techniques to Quantify Intracellular Ca2+ Signaling In Situ
09:34

Applications of Spatio-temporal Mapping and Particle Analysis Techniques to Quantify Intracellular Ca2+ Signaling In Situ

Published on: January 7, 2019

Positional information generated by spatially distributed signaling cascades.

Javier Muñoz-García1, Zoltan Neufeld, Boris N Kholodenko

  • 1School of Mathematical Sciences and Complex Adaptive Systems Laboratory, University College Dublin, Dublin, Ireland.

Plos Computational Biology
|March 21, 2009
PubMed
Summary
This summary is machine-generated.

This study reveals how spatial enzyme separation controls protein signal propagation. Robust signals create activity gradients, with enzyme activity ratios key for controlling propagation in cellular signaling cascades.

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Area of Science:

  • Cellular signaling
  • Biophysics
  • Systems biology

Background:

  • Temporal dynamics of protein modification cascades are well-understood.
  • Spatial aspects of signal propagation remain largely unexplored.
  • Previous work demonstrated spatial enzyme separation creates signaling gradients.

Purpose of the Study:

  • Investigate conditions for signal stalling versus robust propagation in spatial cascades.
  • Analyze factors influencing signal amplitude and propagation length.
  • Understand how spatial distribution differs from temporal control.

Main Methods:

  • Derivation of an approximate analytical solution for signal propagation.
  • Analysis of protein diffusivity, cascade level, and enzyme activity ratios.
  • Modeling of spatially distributed signaling cascades.

Main Results:

  • Identified conditions under which signals stall or propagate robustly.
  • Robust propagation yields activity gradients with plateaus and abrupt decays.
  • Analytical solution links signal amplitude/length to cascade parameters.
  • Enzyme activity ratio is critical for propagation when enzymes are not saturated.

Conclusions:

  • Spatial enzyme separation is a key regulator of signal propagation dynamics.
  • Signaling gradients serve as a pattern formation mechanism.
  • These gradients provide spatial guidance and convey cell size information.