Receptors transmembrane signaling

The hormonal stimulation of adenylyl cyclase is effected by a transmembrane signaling pathway consisting of three components, all membrane-associated. Binding of hormone to the external surface of a hormone receptor causes a conformational change in this transmembrane protein, which in turn stimulates a GTP-binding protein (abbreviated G protein). G proteins are heterotrimeric proteins consisting of a- (45-47 kD), /3- (35 kD), and y- (7-9 kD) subunits. The a-subunit binds GDP or GTP and has an intrinsic, slow... 

Transmembrane Signalling Nuclear Receptors Gluco-mineralocorticoid Receptors... 

Transmembrane Signaling Drag-receptor Interaction G-protein-coupled Receptors Histaminergic System Adenosine Receptois... 

Transmembrane Signaling Nicotinic Receptors Purinergic System... 

Drug Interactions Drug-Receptor Interaction G-protein-coupled Receptors Tolerance and Desensitization Transmembrane Signaling... 

Transmembrane Signaling. Figure 2 Membrane topology of receptors that are associated with effector proteins. Upon binding to their cognate ligands (cyan), receptor proteins without intramolecularly linked effector domain couple via transducer proteins (yellow) to or directly recruit and activate effector proteins (red). Notch receptors release their transducer domains upon proteolytic cleavage, a, p and y stand for G-protein a-, p- and y-subunits, respectively. 

Luttrell LM (2006) Transmembrane signaling by G protein-coupled receptors. Methods Mol Biol 332 3—49... 

Buckley, N. J. (1990). Molecular pharmacology of cloned muscarinic receptors. In Transmembrane Signalling, Intracellular Messengers and Implications for Drug Development, ed. S. R. Nahorski, pp. 11-30. Chichester John Wiley 8r Sons. 

The family of heterotrimeric G proteins is involved in transmembrane signaling in the nervous system, with certain exceptions. The exceptions are instances of synaptic transmission mediated via receptors that contain intrinsic enzymatic activity, such as tyrosine kinase or guanylyl cyclase, or via receptors that form ion channels (see Ch. 10). Heterotrimeric G proteins were first identified, named and characterized by Alfred Gilman, Martin Rodbell and others close to 20 years ago. They consist of three distinct subunits, a, (3 and y. These proteins couple the activation of diverse types of plasmalemma receptor to a variety of intracellular processes. In fact, most types of neurotransmitter and peptide hormone receptor, as well as many cytokine and chemokine receptors, fall into a superfamily of structurally related molecules, termed G-protein-coupled receptors. These receptors are named for the role of G proteins in mediating the varied biological effects of the receptors (see Ch. 10). Consequently, numerous effector proteins are influenced by these heterotrimeric G proteins ion channels adenylyl cyclase phosphodiesterase (PDE) phosphoinositide-specific phospholipase C (PI-PLC), which catalyzes the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2) and phospholipase A2 (PLA2), which catalyzes the hydrolysis of membrane phospholipids to yield arachidonic acid. In addition, these G proteins have been implicated in... 

This transmembrane signaling system involves a complex consisting of several functional proteins (Figure 7) stimulatory (e.g. P-adrenergic, dopamine Dp serotonin, vasopressin) [124] and inhibitory (e.g. a2-adrenergic, dopamine D2, opiod, and muscarinic) [125] receptors, stimulatory (Gs) and inhibitory (G ) G-proteins, and the catalytic protein, adenylate cyclase. On stimulation of a receptor, an associated G-protein binds GTP and the resulting receptor/G-protein/GTP complex then activates, or inhibits, adenylate cyclase in the catalysis of the synthesis... 

Locher, K. P., Rees, B., Koebnik, R., Mitschler, A., Moulinier, L., Rosenbusch, J. P. and Moras, D. (1998). Transmembrane signaling across the ligand-gated FhuA receptor crystal structures of free and ferrichrome-bound states reveal allosteric changes, Cell, 95, 771-778. 

Activation of neutrophils with PAF occurs through a G-protein-linked receptor, and the subsequent transmembrane signalling involves the stimulation of inositol phosphate metabolism. Within 30 s of addition of PAF (0.01-100 nM), intracellular Ca2+ levels increase and Ca2+ transport from the external medium is enhanced. It seems that phospholipase C-dependent and -independent activation pathways are involved in Ca2+ mobilisation. This indirectly suggests that two receptors may be involved in PAF activation. The first of these is pertussis-toxin-insensitive and may be linked to a... 

Gudermann, T., Nurnberg, B., and Schultz, G. Receptors and G proteins as primary components of transmembrane signal transduction. Part 1. G-protein-coupled receptors structure and function./. Mol. Med. 1995, 73, 51-63. 

Odorants are thought to bind to integral membrane receptors on the cilia of the olfactory sensory neurons. The receptors are thought to he specific different olfactory neuron types recognize different odorants that share certain characteristics (Buck, 1993). The odorant receptors transduce signals via interactions with G-proteins (so-called because guanosine trisphosphate is involved in their activation). These G-protein-coupled exhibit seven hydrophobic domains (Fig. 5.6). Variation in the amino acid sequence of the transmembrane domain may account for specificity and selectivity of odor reception. 

The mechanism of action of U ions remains to be fully elucidated. Oiemi-cally, lithium is the lightest of the alkaU metals, which include such biologically important elements as sodium and potassium. Apart from interference with transmembrane cation fluxes (via ion channels and pumps), a lithium effect of major significance appears to be membrane depletion of phosphatidylinositol bisphosphates, the principal lipid substrate used by various receptors in transmembrane signalling (p. 66). 

Figure 1. Schematic representations of significant biological functions displayed by host-guest complexation in homogeneous solutions or at membrane surfaces, (a) Separation (e.g., antibody-antigen complex formation), (b) Transformation (e.g., enzymatic reaction), (c) Translocation (e.g., carrier- or channel-mediated transport), (d) Transduction (e.g., receptor-mediated transmembrane signaling).

Fig. 5.5. General functions of transmembrane receptors. Extracellular signals convert the transmembrane receptor from the inactive form R to the active form R. The activated receptor transmits the signal to effector proteins next in the reaction sequence. Important effector reactions are the activation of heterotrimeric G-proteins, of protein tyrosine kinases and of protein tyrosine phosphatases. The tyrosine kinases and tyrosine phosphatases may be an intrinsic part of the receptor or they may be associated with the receptor. The activated receptor may also include adaptor proteins in the signaling pathway or it may induce opening of ion channels.

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