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Calmodulin-dependent Signaling01:16

Calmodulin-dependent Signaling

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Calmodulin (CaM) is a calcium-binding protein in eukaryotes that controls various calcium-regulated cellular processes. It has four calcium-binding sites that bind calcium to form the calcium-calmodulin ( Ca2+-CaM) complex. GPCR stimulation increases the calcium levels in the cells that bind to CaM and induces a conformational change.
The Ca2+-CaM complex does not have enzymatic activity by itself. Instead, the complex binds downstream target proteins, including membrane proteins or enzymes,...
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Feedback Regulation of Calcium Concentration01:27

Feedback Regulation of Calcium Concentration

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Calcium is an essential signaling molecule required for various cellular functions. Calcium pumps and ion channels on cell and organellar membranes, such as those on the endoplasmic reticulum (ER), regulate calcium concentrations inside the cell. They remain closed, keeping the cytosolic calcium levels low at a resting state.
Various transmembrane receptors, such as G protein-coupled receptors (GPCRs), elicit a response to extracellular signals by increasing cytosolic calcium. Activated GPCRs...
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IP3/DAG Signaling Pathway01:11

IP3/DAG Signaling Pathway

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Membrane lipids such as phosphatidylinositol (PI) are precursors for several membrane-bound and soluble second messengers. Specific kinases phosphorylate PI and produce phosphorylated inositol phospholipids. One such inositol phospholipids are the  phosphatidylinositol-4,5 bisphosphate [PI(4,5)P2], present in the inner half of the lipid bilayer. Upon ligand binding, GPCR stimulates Gq proteins to turn on phospholipase Cꞵ. Activated phospholipase Cꞵ cleaves PI(4,5)P2 and...
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Amplifying Signals via Second Messengers01:15

Amplifying Signals via Second Messengers

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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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Paracrine Signaling01:21

Paracrine Signaling

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Paracrine signaling allows cells to communicate with their immediate neighbors via secretion of signaling molecules. Such a signal can only trigger a response in nearby target cells because the signal molecules degrade quickly or are inactivated if not taken up. Prominent examples of paracrine signaling include nitric oxide signaling in blood vessels, synaptic signaling of neurons, the blood clotting system, tissue repair/wound healing, and local allergic skin reactions. Nitric oxide as a...
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Intracellular Signaling Affects Focal Adhesions01:17

Intracellular Signaling Affects Focal Adhesions

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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.
Some...
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Related Experiment Video

Updated: Apr 28, 2026

Culture of Brain Capillary Pericytes for Cytosolic Calcium Measurements and Calcium Imaging Studies
09:33

Culture of Brain Capillary Pericytes for Cytosolic Calcium Measurements and Calcium Imaging Studies

Published on: May 27, 2020

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Calcium signalling in pericytes.

Theodor Burdyga1, Lyudmyla Borysova

  • 1Department of Cellular and Molecular Physiology, Institute of Translational Medicine, University of Liverpool, Liverpool, UK.

Journal of Vascular Research
|June 7, 2014
PubMed
Summary
This summary is machine-generated.

Pericytes and myocytes, crucial microvessel cells, exhibit distinct contractile responses and calcium (Ca2+) signaling. This review explores pericyte contractility and Ca2+ dynamics in regulating local blood flow.

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Area of Science:

  • Physiology
  • Cell Biology
  • Vascular Biology

Background:

  • Microvessels comprise arterioles and venules, with capillaries connecting them.
  • Arterioles have myocytes, while capillaries and venules are surrounded by diverse pericytes.
  • Pericytes and myocytes differ in their responses to vasoactive molecules, suggesting distinct roles in blood flow regulation.

Purpose of the Study:

  • To review pericyte contractility and calcium (Ca2+) signaling.
  • To explore the functional roles of pericytes in microvessel physiology and pathophysiology.
  • To summarize findings on Ca2+ sources, release, and entry mechanisms in pericytes.

Main Methods:

  • Review of existing literature on pericyte and myocyte physiology.
  • Analysis of Ca2+ signaling mechanisms in pericytes.
  • Examination of contractile activities in vascular cells.

Main Results:

  • Pericytes and myocytes display different physiological responses to vasoactive substances.
  • Contractile activity in both cell types is regulated by cytosolic free Ca2+ concentration.
  • Specific mechanisms of Ca2+ handling (sources, release, entry) influence Ca2+ signal characteristics in pericytes.

Conclusions:

  • Pericytes play a significant role in microvessel function and blood flow regulation.
  • Understanding pericyte Ca2+ signaling is key to comprehending microvascular dynamics.
  • Further research into pericyte contractility and Ca2+ dynamics can illuminate microvascular pathophysiology.