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Cell membranes peripheral proteins

It is easy to see that nonpolar, lipophilic molecules will easily cross membranes. But we know that polar metabolites and ions must also gain entrance to as well as exit from cells and organelles. This is accomplished through another type of membrane component - membrane proteins. These proteins may lie on the surface of the membrane (peripheral proteins) or be located either entirely within the nonpolar interior, or be partially exterior and interior, or completely span the bilayer (integral proteins). See Figure 2c. These proteins function as channels, carriers, receptors, or signal transmission devices. [Pg.19]

A cell membrane is a fluid mosaic of lipids and proteins. Phosphoglycerides are the major membrane lipids that form a bilayer with their hydrophilic head groups interacting with water on both the extracellular and intracellular surfaces, and their hydrophobic fatty acyl chains in the central and hydrophobic regions of the membrane. Peripheral proteins are embedded at the periphery, while integral proteins span from one side to the other. Biomembranes separate the contents of the cell from the external environment. [Pg.526]

Fig. 10.6. Proteins in the red blood cell membrane. The proteins named Band 3 (the bicarbonate-chloride exchange transporter) and glycophorin contain nonpolar a-helical segments spanning the lipid bilayer. These proteins contain a large number of polar and charged hydrophilic amino acids in the intracellular and extracellular domains. On the inside of the cell, they are attached to peripheral proteins constituting the inner membrane skeleton. Band 3 is connected to spectrin filaments via the protein ankyrin. Glycophorin is connected to short actin filaments and spectrin via protein 4.1. Fig. 10.6. Proteins in the red blood cell membrane. The proteins named Band 3 (the bicarbonate-chloride exchange transporter) and glycophorin contain nonpolar a-helical segments spanning the lipid bilayer. These proteins contain a large number of polar and charged hydrophilic amino acids in the intracellular and extracellular domains. On the inside of the cell, they are attached to peripheral proteins constituting the inner membrane skeleton. Band 3 is connected to spectrin filaments via the protein ankyrin. Glycophorin is connected to short actin filaments and spectrin via protein 4.1.
Potassium is the second most abundant cation in the body and is found primarily in the intracellular fluid. Potassium has many important physiologic functions, including regulation of cell membrane electrical action potential (especially in the myocardium), muscular function, cellular metabolism, and glycogen and protein synthesis. Potassium in PN can be provided as chloride, acetate, and phosphate salts. One millimole of potassium phosphate provides 1.47 mEq of elemental potassium. Generally, the concentration of potassium in peripheral PN (PPN) admixtures should not exceed 80 mEq/L (80 mmol/L). While it is safer to also stick to the 80 mEq/L (80 mmol/L) limit for administration through a central vein, the maximum recommended potassium concentration for infusion via a central vein is 150 mEq/L (150 mmol/L).14 Patients with abnormal potassium losses (e.g., loop or thiazide diuretic therapy) may have higher requirements, and patients with renal failure may require potassium restriction. [Pg.1497]

Fig. 7 Diagrammatic representation of the fluid mosaic model of the cell membrane. The basic structure of the membrane is that of a lipid bilayer in which the lipid portion (long tails) points inward and the polar portion (round head ) points outward. The membrane is penenetrated by transmembrane (or integral) proteins. Attached to the surface of the membrane are peripheral proteins (inner surface) and carbohydrates that bind to lipid and protein molecules (outer surface). (Modified from Ref. 14.)... Fig. 7 Diagrammatic representation of the fluid mosaic model of the cell membrane. The basic structure of the membrane is that of a lipid bilayer in which the lipid portion (long tails) points inward and the polar portion (round head ) points outward. The membrane is penenetrated by transmembrane (or integral) proteins. Attached to the surface of the membrane are peripheral proteins (inner surface) and carbohydrates that bind to lipid and protein molecules (outer surface). (Modified from Ref. 14.)...
Mechanism of Action An antiarrhythmic that directly affects myocardial cell membranes. Therapeutic Effect Contributes to suppression of ventricular tachycardia. Pharmacokinetics Absorption is not expected to be present in peripheral blood at recommended doses. Protein binding l%-6%. Not metabolized. Excreted unchanged in urine. Removed by hemodialysis. Half-life 6-13.5 hr. [Pg.150]

In a series of studies, Dubovsky et al. ( 34) measured intracellular calcium ion concentrations in bipolar manic and depressed patients. They found decreases in mean concentrations in four bipolar, manic, and five bipolar, depressed, patients, in comparison with seven normothymic subjects without personal or first-degree relative histories of psychiatric disorders. Their findings were consistent with a diffuse abnormality in the mechanisms modulating intracellular calcium homeostasis. Further, this phenomenon s presence in both platelets and lymphocytes lends credence to a disruption in the cell membrane, the G-protein, or other mechanisms involved in the homeostasis of intracellular calcium ion concentrations. This may also support an extension of their findings from peripheral to neuronal tissue. [Pg.190]

Thus, the fat globules are surrounded, at least initially, by a membrane typical of eukaryotic cells. Membranes are a conspicuous feature of all cells and may represent 80% of the dry weight of some cells. They serve as barriers separating aqueous compartments with different solute composition and as the structural base on which many enzymes and transport systems are located. Although there is considerable variation, the typical composition of membranes is about 40% lipid and 60% protein. The lipids are mostly polar (nearly all the polar lipids in cells are located in the membranes), principally phospholipids and cholesterol in varying proportions. Membranes contain several proteins, perhaps up to 100 in complex membranes. Some of the proteins, referred to as extrinsic or peripheral, are loosely attached to the membrane surface and are easily removed by mild extraction procedures. The intrinsic or integral proteins, about 70% of the total protein, are tightly bound to the lipid portion and are removed only by severe treatment, e.g. by SDS or urea. [Pg.114]

Figure 3.2 The molecular arrangement of the cell membrane (A) integral proteins (B) glycoprotein (C) pore formed from integral protein (D) various phospholipids with saturated fatty acid chains (E) phospholipids with unsaturated fatty acid chains (F) network proteins (G) cholesterol (H) glycolipid (I) peripheral protein. There are four different phospholipids phosphatidyl serine phosphatidyl choline phosphatidyl ethanolamine and sphingomyelin represented as , o. The stippled area of the protein represents the hydrophobic portion. Source From Ref. 1. Figure 3.2 The molecular arrangement of the cell membrane (A) integral proteins (B) glycoprotein (C) pore formed from integral protein (D) various phospholipids with saturated fatty acid chains (E) phospholipids with unsaturated fatty acid chains (F) network proteins (G) cholesterol (H) glycolipid (I) peripheral protein. There are four different phospholipids phosphatidyl serine phosphatidyl choline phosphatidyl ethanolamine and sphingomyelin represented as , o. The stippled area of the protein represents the hydrophobic portion. Source From Ref. 1.
The fluid-mosaic model for biological membranes as envisioned by Singer and Nicolson. Integral membrane proteins are embedded in the lipid bilayer peripheral proteins are attached more loosely to protruding regions of the integral proteins. The proteins are free to diffuse laterally or to rotate about an axis perpendicular to the plane of the membrane. For further information, see S. J. Singer and G. L. Nicolson, The fluid mosaic model of the structure of cell membranes, Science 175 720, 1972. [Pg.392]

The cytoskeletons of other eukaryotic cells typically include both microtubules and microfilaments, which consist of long, chainlike oligomers of the proteins tubulin and actin, respectively. Bundles of microfilaments often lie just underneath the plasma membrane (fig. 17.22). They participate in processes that require changes in the shape of the cell, such as locomotion and phagocytosis. In some cells, cytoskeletal microfilaments appear to be linked indirectly through the plasma membrane to peripheral proteins on the outer surface of the cell (fig. 17.23). Among the cell surface proteins connected to this network is fibronectin, a glycoprotein believed to play a role in cell-cell interactions. The lateral diffusion of fibronectin is at least 5,000 times slower than that of freely diffusible membrane proteins. [Pg.396]

The structure of spectrin and the location of spectrin in the cytoskeleton. (a) An a/3 dimer of spectrin. Both a and f3 subunits are extended structures consisting of end-to-end domains of 106 amino-acyl residues folded into three a helices the subunits twist about one another loosely as shown. (b) The erythrocyte membrane skeleton. Spectrin tetramers ((X2P2), shown in yellow, are linked to the cytoplasmic domain of the anion channel (blue) by the protein ankyrin (red), and to glycophorin and actin filaments by protein 4.1. This structure lends stability to the red cell membrane while maintaining sufficient flexibility to allow erythrocytes to withstand substantial shear forces in the peripheral circulation. [Pg.397]

The apoproteins of HDL are secreted by the liver and intestine. Much of the lipid comes from the surface monolayers of chylomicrons and VLDL during lipolysis. HDL also acquire cholesterol from peripheral tissues in a pathway that protects the cholesterol homeostasis of cells. In this process, free cholesterol is transported from the cell membrane by a transporter protein, ABCA1, acquired by a small particle termed prebeta-1 HDL, and then esterified by lecithin cholesterol acyltransferase (LCAT), leading to the formation of larger HDL species. The cholesteryl esters are transferred to VLDL, IDL, LDL, and chylomicron remnants with the aid of cholesteryl ester transfer protein (CETP). Much of the cholesteryl ester thus transferred is ultimately delivered to the liver by endocytosis of the acceptor lipoproteins. HDL can also deliver cholesteryl esters directly to the liver via a docking receptor (scavenger receptor, SR-BI) that does not endocytose the lipoproteins. [Pg.789]

The main precursors of plasma HDL are most likely disk-shaped bilayers composed of PL and protein and secreted by the liver and intestine. HDL are also derived from the surplus surface material removed from TG-rich lipoproteins during lipolysis. HDL are involved in the net transfer of cholesterol from peripheral tissues to the liver, where it can be eliminated or recirculated. This process is initiated by the uptake of FC from cell membranes into the HDL. The nature of this uptake is not known but may involve binding of HDL to the membrane. [Pg.117]

Cytochrome c (Cyt c), the peripheral protein loosely associated with the inner membrane of mitochondria, is one of the most well-known factors involved in apoptosis (Green 2005). In healthy cells, Cyt c functions as an electron shuttle in the respiratory chain and its activity is necessary for life. Cyt c is released by the mitochondria as the consequence of elevated permeability of the outer membrane in responses to proapoptotic stimuli (Li et al. 1997). In the cytosol, Cyt c binds to the apoptosis-protease activating factor 1 (Apaf-1), which then recruits caspase-9 to form the apoptosome (Li et al. 1997). Caspase-9 in turn cleaves and activates executioner caspase-3, resulting in apoptotic cell death as described above. The whole process requires energy and relatively intact cell machinery. [Pg.271]

Cell membrane Lipid bilayer, containing surface proteins (peripheral proteins), proteins totally embedded in the membrane (intregal proteins), and glycoproteins partially embedded in the membrane Maintains ionic and chemical concentration gradients, cell-specific markers, intercellular communication, regulates cell growth and proliferation... [Pg.10]

Figure 1.3. Diagram of cell membrane. The plasma membrane is a lipid bilayer containing peripheral proteins, including HLA antigens, proteoglycans, and integral proteins, such as pore-forming proteins that transverse the cell membrane. Figure 1.3. Diagram of cell membrane. The plasma membrane is a lipid bilayer containing peripheral proteins, including HLA antigens, proteoglycans, and integral proteins, such as pore-forming proteins that transverse the cell membrane.
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