Cell membrane binding process

Glycodendrimers are mainly considered in various biomedical fields [39b] because of their high biocompatibility in combination with multivalency and specific interactions that are important, for example, for protein and cell membrane binding and recognition processes. The use of glycopolymers as viral and bacterial antiadhesion drugs and for inhibition of infections is very prominent (see also Sections 6.2 and 6.3). 

Materials may be absorbed by a variety of mechanisms. Depending on the nature of the material and the site of absorption, there may be passive diffusion, filtration processes, faciHtated diffusion, active transport and the formation of microvesicles for the cell membrane (pinocytosis) (61). EoUowing absorption, materials are transported in the circulation either free or bound to constituents such as plasma proteins or blood cells. The degree of binding of the absorbed material may influence the availabiHty of the material to tissue, or limit its elimination from the body (excretion). After passing from plasma to tissues, materials may have a variety of effects and fates, including no effect on the tissue, production of injury, biochemical conversion (metaboli2ed or biotransformed), or excretion (eg, from liver and kidney). 

Noncarcinogenic elTects include all toxicological responses except tumors. Toxicological responses and iiicchanisins vary widely, and e.xamples of these include interference with normal cell processes by displacing elements out of the cell and binding with a cell to reduce membrane penneability. However,... 

One of the early events of the apoptotic process involves the translocation of phosphatidylserine on the surface of cell membranes annexin V binding and propidium iodide uptake reveals various cellular states. After treatment with organotin(IV) compounds the cells could be categorized into populations vital cells (annexin V /P ), early apoptotic cells (annexin V /P ), late apoptotic cells (annexin V /P ), and necrotic cells (annexin V /P" ). Cells are observed with a fluorescence microscope and it is possible to observe translocation of phosphatidylserine (PS) from the inner side of the plasma membrane to the outer one and to see a green stain for annexin V FLUOS bound to PS, and a red stain for propidium iodide. 

Birch and coworkers studied the time-intensity interrelationships for the sweetness of sucrose and thaumatin, and proposed three thematically different processes (see Fig. 47). In mechanism (1), the sweet stimuli approach the ion-channel, triggering site on the taste-cell membrane, where they bind, open the ion-channel (ionophore), and cause a flow of sodium and potassium ions into, or out of, the cell. Such a mechanism would correspond to a single molecular event, and would thus account for both time and intensity of response, the intensity of response being dependent on the ion flux achieved while the stimulus molecule binds to the ionophore. 

Recent evidence indicates that the 5-HT transporter is subject to post-translational regulatory changes in much the same way as neurotransmitter receptors (Blakeley et al. 1998). Protein kinase A and protein kinase C (PKC), at least, are known to be involved in this process. Phosphorylation of the transporter by PKC reduces the Fmax for 5-HT uptake and leads to sequestration of the transporter into the cell, suggesting that this enzyme has a key role in its intracellular trafficking. Since this phosphorylation is reduced when substrates that are themselves transported across the membrane bind to the transporter (e.g. 5-HT and fi -amphetamine), it seems that the transport of 5-HT is itself linked with the phosphorylation process. Possibly, this process serves as a homeostatic mechanism which ensures that the supply of functional transporters matches the demand for transmitter uptake. By contrast, ligands that are not transported (e.g. cocaine and the selective serotonin reuptake inhibitors (SSRIs)) prevent the inhibition of phosphorylation by transported ligands. Thus, such inhibitors would reduce 5-HT uptake both by their direct inhibition of the transporter and by disinhibition of its phosphorylation (Ramamoorthy and Blakely 1999). 

Adsorption the process of solute accumulation at a cell membrane surface. For cations, this usually involves electrostatic binding to anionic groups on the cell membrane. 

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