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IP3/DAG Signaling Pathway01:11

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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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Small GTPases - Ras and Rho01:24

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Ras and Rho are small monomeric GTPases that act downstream of receptor tyrosine kinase (RTK) and regulate various cellular processes. These GTPases switch between active and inactive states by binding to guanine nucleotides.
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Amplifying Signals via Enzymatic Cascade01:22

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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...
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Allosteric Regulation01:08

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Allosteric regulation of enzymes occurs when the binding of an effector molecule to a site that is different from the active site causes a change in the enzymatic activity. This alternate site is called an allosteric site, and an enzyme can contain more than one of these sites. Allosteric regulation can either be positive or negative, resulting in an increase or decrease in enzyme activity. Most enzymes that display allosteric regulation are metabolic enzymes involved in the degradation or...
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Amplifying Signals via Second Messengers01:15

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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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Calmodulin-dependent Signaling01:16

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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.
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Related Experiment Video

Updated: Jun 6, 2025

Fluorescence-Based Measurements of Phosphatidylserine/Phosphatidylinositol 4-Phosphate Exchange Between Membranes
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Fluorescence-Based Measurements of Phosphatidylserine/Phosphatidylinositol 4-Phosphate Exchange Between Membranes

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RhoA Allosterically Activates Phospholipase Cε via its EF Hands.

Vaani Ohri, Kadidia Samassekou, Kaushik Muralidharan

    Biorxiv : the Preprint Server for Biology
    |November 28, 2024
    PubMed
    Summary

    RhoA GTPase activates Phospholipase Cε (PLCε), a key enzyme in cardioprotection, by binding to a unique site. This interaction enhances PLCε activity and promotes cardiomyocyte survival.

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    PIP-on-a-chip: A Label-free Study of Protein-phosphoinositide Interactions
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    PIP-on-a-chip: A Label-free Study of Protein-phosphoinositide Interactions

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    Area of Science:

    • Biochemistry
    • Molecular Biology
    • Cardiovascular Research

    Background:

    • Phospholipase Cε (PLCε) is activated by small GTPases, playing a role in cellular signaling.
    • The RhoA GTPase regulates PLCε in the cardiovascular system, initiating a cardioprotective pathway.
    • The precise molecular mechanism of RhoA-mediated PLCε activation remains unclear.

    Purpose of the Study:

    • To elucidate the molecular mechanism by which RhoA GTPase activates PLCε.
    • To determine the structural basis of RhoA-PLCε interaction.
    • To investigate the role of a specific PLCε insertion in RhoA-dependent activation.

    Main Methods:

    • Cryo-electron microscopy (cryo-EM) to reconstruct the structure of RhoA bound to PLCε.
    • Site-directed mutagenesis to assess the function of the PLCε insertion.
    • Biochemical assays to measure PLCε activation.

    Main Results:

    • The cryo-EM reconstruction revealed that RhoA binds to a unique insertion within the EF hands of PLCε.
    • Deletion or mutation of this PLCε insertion significantly reduced RhoA-dependent activation.
    • This specific interaction did not affect PLCε regulation by other G proteins.

    Conclusions:

    • RhoA binding to PLCε allosterically activates the enzyme.
    • RhoA interaction increases PLCε's membrane association, leading to maximal lipase activity.
    • This mechanism is crucial for RhoA-mediated cardioprotection and cardiomyocyte survival.