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Surface-membrane proteins

Figure 12.2 (a) Schematic drawing of membrane proteins in a typical membrane and their solubilization by detergents. The hydrophilic surfaces of the membrane proteins are indicated by red. (b) A membrane protein crystallized with detergents bound to its hydrophobic protein surface. The hydrophilic surfaces of the proteins and the symbols for detergents are as in (a). (Adapted from H. Michel, Trends Biochem. Sci. 8 56-59, 1983.)... [Pg.225]

Structure of Membrane Protein.s Membrane and Cell-Surface... [Pg.259]

A receptor is a surface membrane component, usually a protein, which regulates some biological event in response to reversible binding of a relatively small molecule40 . The precise three-dimensional structures of the binding sites of receptors still remain unknown today. Thus, this section mainly describes the correlation of shape similarity between the molecules which would bind to a given receptor with their biological activity. [Pg.106]

It is necessary to note that the initial conditions of the samples in solution were absolutely different. RC was extracted from the membranes by detergent (lauryldimethy-lamineoxide—LDAO) the solution contains the individual protein molecules surrounded by a detergent belt shielding the hydrophobic areas of the protein surface. In the case of BR the situation is different. BR is the main part of purple membranes (about 80%) and is already close packed in it. It is difficult to extract BR in the form of individual molecules, for they are very unstable (Okamura et al. 1974). Thus, the initial solution of BR was in reality the solution of sonicated membrane fragments. [Pg.153]

While the fluid mosaic model of membrane stmcture has stood up well to detailed scrutiny, additional features of membrane structure and function are constantly emerging. Two structures of particular current interest, located in surface membranes, are tipid rafts and caveolae. The former are dynamic areas of the exo-plasmic leaflet of the lipid bilayer enriched in cholesterol and sphingolipids they are involved in signal transduction and possibly other processes. Caveolae may derive from lipid rafts. Many if not all of them contain the protein caveolin-1, which may be involved in their formation from rafts. Caveolae are observable by electron microscopy as flask-shaped indentations of the cell membrane. Proteins detected in caveolae include various components of the signal-transduction system (eg, the insutin receptor and some G proteins), the folate receptor, and endothetial nitric oxide synthase (eNOS). Caveolae and lipid rafts are active areas of research, and ideas concerning them and their possible roles in various diseases are rapidly evolving. [Pg.422]

Any living cell continuously receives information about its surroundings. Its surface membrane has numerous protein receptors, which interact with practically all vitally important molecules. [Pg.649]

Herr, F.H., Matarese, V., Bernlohr, D.A. and Storch, J. (1995) Surface lysine residues modulate the collisional transfer of fatty acid from adipocyte fatty acid binding protein to membranes. Biochemistry 34, 11840-11845. [Pg.334]

Indeed, hydrophilic N- or C-terminal ends and loop domains of these membrane proteins exposed to aqueous phases are able to undergo rapid or intermediate motional fluctuations, respectively, as shown in the 3D pictures of transmembrane (TM) moieties of bacteriorhodopsin (bR) as a typical membrane protein in the purple membrane (PM) of Halobacterium salinarum.176 178 Structural information about protein surfaces, including the interhelical loops and N- and C-terminal ends, is completely missing from X-ray data. It is also conceivable that such pictures should be further modified, when membrane proteins in biologically active states are not always present as oligomers such as dimer or trimer as in 2D or 3D crystals but as monomers in lipid bilayers. [Pg.45]

Ca2+ influx initiates protein and membrane associations by several different mechanisms. Allosteric regulation of the hydrophobicity of protein-binding surfaces frequently occurs. One of the best studied examples is the Ca2+-dependent binding of calmodulin to other proteins (Ch. 22). Annexins are a family of proteins that exhibit Ca2+-dependent associations with cell membranes through direct interaction with phospholipids, and conversely, interactions with phospholipids increase their affinities for Ca2+ [7]. [Pg.25]

Most transport vesicles bud off as coated vesicles, with a unique set of proteins decorating their cytosolic surface 141 GTP-binding proteins, such as the small monomeric GTPases and heterotrimeric GTPases (G proteins) facilitate membrane transport 142 SNARE proteins and Rabs control recognition of specific target membranes 143... [Pg.139]

The fluorescence energy transfer process has been widely used to determine the distance between fluorophores, the surface density of fluorophores in the lipid bilayer, and the orientation of membrane protein or protein segments, often with reference to the membrane surface and protein-protein interactions. Membranes are intrinsically dynamic in nature, so that so far the major applications have been the determination of fixed distances between molecules of interest in the membrane. [Pg.249]

Morphological studies show that SFV particles bound to BHK-21 cells are preferentially associated with the microvillar projections of the cell surface membranes (Helenius et al., 1980). Many of the virions which are not bound to microvilli (5% of all the cell surface viruses) are located in coated pits. The coated pits are invaginations of the plasma membrane, with a characteristic electron-dense coat composed of clathrin and other proteins on the cytoplasmic face (Pearse and Bretscher, 1981). Many of the coated pits are localized close to the base of microvilli. [Pg.99]

The problem we have not yet touched upon is how components can specifically move from one cellular component to another. Both the entry and the exit of SFV spike proteins are dependent on a number of such cellular processes. The newly synthesized spike proteins move from the ER to the Golgi complex and then to the cell surface. The cell surface membrane is continuously retrieved by endocytosis into endosomes. From here the endocytosed membrane components probably recycle back to the cell surface, but some components may also be channeled into lysosomes for degradation. Especially in cells with secretory activity, the recycling pathway from the cell surface also includes the Golgi complex (see Farquhar and Palade, 1981). [Pg.122]

The stain/fixation method is usually used for surface markers that can withstand fixation and is followed by the application of a DNA-binding fluoro-chrome. The fixation/stain method is used not only for surface markers that can withstand fixation, but also for intracellular constituents, such as cytoplasmic proteins, nuclear membrane, and nuclear proteins. This is accomplished by using a crosslinking fixative (e.g., paraformaldehyde [PFA] or formalin) followed by a permeabilizing agent (e.g., Triton X-100, Tween-20, saponin, or lysolecithin). Some of the precipitating agents (e.g., ethanol, methanol, or acetone) can also be used for permeabilization after the initial fixation with PFA or formalin, or they can be used alone for both fixation and permeabilization (see Chapter 8). [Pg.266]


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