Toll-like receptor

Examples of Toll-like receptor in the following topics:

• Toll-Like Receptors

  • Toll-like receptors (TLRs) are a class of proteins that play a key role in the innate immune system as well as the digestive system.
  • Toll-like receptors (TLRs) are a class of proteins that play a key role in the innate immune system as well as the digestive system .
  • TLRs together with the Interleukin-1 receptors form a receptor superfamily, known as the "Interleukin-1 Receptor/Toll-Like Receptor Superfamily"; all members of this family have in common a so-called TIR (Toll-IL-1 receptor) domain.
  • Signaling pathway of Toll-like receptors.
  • The curved leucine-rich repeat region of Toll-like receptors, represented here by TLR3

• Types of WBCs

  • Granulocytes contain toll-like receptors that allow them to recognize pathogen-associated molecular patterns (PAMPS).
  • All categories except neutrophils contain IgE receptors that implicate them in allergic responses.
  • B and T lymphocytes contain MHC antigen receptors and their activity is antigen-specific.
  • Monocytes and their progeny contain toll-like receptors and granules.

• Cell-Mediated Autoimmune Reactions

  • In coeliac disease it seems likely that B cells that recognize transglutamine tissue are helped by T cells that recognize gliadin.
  • A receptor, Peanut agglutinin receptor(PNAR)).
  • These ligands include B cell receptor (for antigen), IgG Fc receptors, CD21 (which binds complement C3d), Toll-like receptors 9 and 7 (which can bind DNA and nucleoproteins) and PNAR.
  • HLA-DQ (DQ) is a cell surface receptor type protein found on antigen presenting cells.
  • HLA-DQ (DQ) is a cell surface receptor type protein found on antigen presenting cells (APC).

• Clonal Selection and B-Cell Differentiation

  • B cells mature in the bone marrow, where they undergo VDJ recombination to produce unique receptors that do not react to self-antigens.
  • B cell activation refers to the differentiation and clonal expansion of B cells.When the B cell receptor on the cell surface matches its cognate antigen in the body, the B cell proliferates and secretes a free form of those receptors (antibodies) in the body, with binding sites identical to those on the original cell surface.
  • T cell independent activation occurs when antigens directly bind to B cell themselves, usually through cross-linking the antigen to the B cell receptor or receiving the antigen with a toll-like receptor.
  • Clonal selection is a theory stating that B cells express antigen-specific receptors before antigens are ever encountered in the body.

• Antigen-Presenting Cells

  • The T cell receptor is restricted to recognizing antigenic peptides only when bound to appropriate molecules of the major histocompatibility complex (MHC), also known in humans as Human leukocyte antigen (HLA).
  • These professional APCs are equipped with special immunostimulatory receptors that allow for enhanced activation of T cells.
  • This maturation process is dependent on signaling from other pathogen-associated molecular pattern (PAMP) molecules through pattern recognition receptors, such as the members of the Toll-like receptor family.

• Phagocytes

  • A receptor on the phagocyte's cell membrane binds to a foreign particle, such as a pathogenic microbe or a toxin.
  • The Fc receptor is typically the receptor of use, which binds to antibodies that have opsonized (marked) a pathogen or toxin.
  • For instance, other receptors may be used to engulf pathogens, and other non-oxidative methods (such as lysozyme) exist to kill the phagocytized pathogen.
  • Other cells, such as epithelial cells and fibroblasts, may also engage in phagocytosis, but lack receptors to detect opsonized pathogens and are not primarily immune system cells.
  • Mast cells are PMN granulocytes with toll-like receptors that tend to trigger inflammatory responses.

• Blocking of Hormone Receptors

  • A receptor antagonist does not provoke a biological response upon receptor binding, but limits or dampens agonist-mediated responses.
  • A receptor antagonist is a type of receptor ligand or drug that does not provoke a biological response itself upon binding to a receptor, but blocks or dampens agonist-mediated responses.
  • Binding to the active site on the receptor regulates receptor activation directly.
  • The current accepted definition of receptor antagonist is based on the receptor occupancy model.
  • Many antagonists are reversible antagonists that, like most agonists, will bind and unbind a receptor at rates determined by receptor-ligand kinetics.

• Binding Initiates a Signaling Pathway

  • Ligand binding to cell-surface receptors activates the receptor's intracellular components setting off a signaling pathway or cascade.
  • Cell-surface receptors, also known as transmembrane receptors, are membrane-anchored (integral) proteins that bind to external ligand molecules.
  • There are three general categories of cell-surface receptors: ion channel-linked receptors, G-protein-linked receptors, and enzyme-linked receptors.
  • Enzyme-linked receptors are cell-surface receptors with intracellular domains that are associated with an enzyme.
  • The events in the cascade occur in a series, much like a current flows in a river.

• T Cell Receptors

  • The T Cell Receptor (TCR) found on the surface of T cells is responsible for recognizing antigens.
  • The receptor that recognizes these peptide-MHC complexes is called the T Cell Receptor (TCR).
  • T cells also express other membrane receptors that do not recognize antigens but participate in responses to antigens; these are collectively called 'accessory molecules'.
  • T cell receptor consists of alpha and beta chains, a transmembrane domain, and a cytoplasmic region.
  • The presence of vacuoles, i.e. microscopic "holes" in the gray matter, gives the brain of BSE-affected cows a sponge-like appearance when tissue sections are examined in the lab.

• Neurotransmitters

  • Neurotransmitters match up with receptors like a key in a lock.
  • The cholinergic system has two types of receptors: the nicotinic receptor and the acetylcholine receptor, which is known as the muscarinic receptor.
  • The depolarizing (more likely to reach an action potential) or hyperpolarizing (less likely to reach an action potential) effect is also dependent on the receptor.
  • Glycine and GABA are considered inhibitory amino acids, again because their receptors cause hyperpolarization, making the receiving cell less likely to reach an action potential.
  • On the other hand, when an excess of the neurotransmitter dopamine blocks glutamate receptors, disorders like schizophrenia can occur.