Membrane-bound proteins hormone receptors

Inositol triphosphate (IP3)-gated channels are also associated with membrane-bound receptors for hormones and neurotransmitters. In this case, binding of a given substance to its receptor causes activation of another membrane-bound protein, phospholipase C. This enzyme promotes hydrolysis of phosphatidylinositol 4,5-diphosphate (PIP2) to IP3. The IP3 then diffuses to the sarcoplasmic reticulum and opens its calcium channels to release Ca++ ions from this intracellular storage site. 

Figure 1.21 depicts an aitomativc pathway. Following the events of Figure 1,19, the polypeptide is inserted into the membrane, pacicaged into a secretory vesicle, and inserted into the plasma membrane via fusion of the vesicle with the PM, Membrane-bound proteins include nutrient transport proteins, hormone receptors, ion pumps, and proteins that transmit impulses along the length of a nerve or muscle fiber. 

Calcium ions constitute only one of several participants in the pathway of "calcium signaling." The role of cytosolic Ca ions, in this pathway, is to rise suddenly in concentration over a course of a few seconds or minutes, and then to fall back to basal levels. The following commentary concerns events that occur before, during, and after the burst of calcium ions. An extracellular stimulant, such as a hormone, binds to a receptor in the cell membrane. The event of binding provokes the activation of a membrane-bound protein, phospholipase C,... 

FIGURE 24.12 The PIP2 second-messenger scheme. When a hormone binds to a receptor, it activates phospholipase C, in a process mediated by a G protein. Phospholipase C hydrolyzes PIPj to IP3 and DAG. IP3 stimulates the release of Ca from intracellular reservoirs in the ER. A complex formed between Ca and the calcium-binding protein calmodulin activates a cytosolic protein kinase for phosphorylation of a target enzyme. DAG remains bound to the plasma membrane, where it activates the membrane-bound protein kinase C (PKC). PKC is involved in the phosphorylation-channel proteins that control the flow of Ca + in and out of the cell. Ca from extracellular sources can produce sustained responses even when the supply of Ca + in intracellular reservoirs is exhausted. 

Lipid bilayer membranes serve not only as matrices for receptors and other membrane-bound proteins, but interact with many neuropeptides and peptide hormones in a manner that allows multiple correlations with the biological activity of the peptides. 

FIGURE 15.21 Hormone (H) binding to its receptor (R) creates a hormone receptor complex (H R) that catalyzes GDP-GTP exchange on the o -subunit of the heterotrimer G protein (G ), replacing GDP with GTP. The G -subunit with GTP bound dissociates from the /37-subunits and binds to adenylyl cyclase (AC). AC becomes active upon association with G GTP and catalyzes the formation of cAMP from ATP. With time, the intrinsic GTPase activity of the G -subunit hydrolyzes the bound GTP, forming GDP this leads to dissociation of G GDP from AC, reassociation of G with the /Sy subunits, and cessation of AC activity. AC and the hormone receptor H are integral plasma membrane proteins G and G are membrane-anchored proteins. 

Adrenaline (epinephrine) is a catecholamine, which is released as a neurotransmitter from neurons in the central nervous system and as a hormone from chromaffin cells of the adrenal gland. Adrenaline is required for increased metabolic and cardiovascular demand during stress. Its cellular actions are mediated via plasma membrane bound G-protein-coupled receptors. 

Protein/peptide hormones are derived from amino acids. These hormones are preformed and stored for future use in membrane-bound secretory granules. When needed, they are released by exocytosis. Protein/peptide hormones are water soluble, circulate in the blood predominantly in an unbound form, and thus tend to have short half-lives. Because these hormones are unable to cross the cell membranes of their target tissues, they bind to receptors... 

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