Inhibition membrane transport systems

Adenosine is produced by many tissues, mainly as a byproduct of ATP breakdown. It is released from neurons, glia and other cells, possibly through the operation of the membrane transport system. Its rate of production varies with the functional state of the tissue and it may play a role as an autocrine or paracrine mediator (e.g. controlling blood flow). The uptake of adenosine is blocked by dipyridamole, which has vasodilatory effects. The effects of adenosine are mediated by a group of G protein-coupled receptors (the Gi/o-coupled Ai- and A3 receptors, and the Gs-coupled A2a-/A2B receptors). Ai receptors can mediate vasoconstriction, block of cardiac atrioventricular conduction and reduction of force of contraction, bronchoconstriction, and inhibition of neurotransmitter release. A2 receptors mediate vasodilatation and are involved in the stimulation of nociceptive afferent neurons. A3 receptors mediate the release of mediators from mast cells. Methylxanthines (e.g. caffeine) function as antagonists of Ai and A2 receptors. Adenosine itself is used to terminate supraventricular tachycardia by intravenous bolus injection. 

Mercury can influence ion, water, and nonelectrolyte transport in different cells [ 14, 77]. The cell membrane is believed to be the first point of attack by heavy metals however, intracellular enzymes and metabolic processes may also be inhibited [70, 78, 79]. The attachment of heavy metals to ligands in or on the plasma membrane may result in changes in passive permeability or selective blockage of specific transport processes. Many membrane transport systems are known to be sensitive to sulphydryl-group modification [ 14, 80, 81]. 

Carrier-mediated passage of a molecular entity across a membrane (or other barrier). Facilitated transport follows saturation kinetics ie, the rate of transport at elevated concentrations of the transportable substrate reaches a maximum that reflects the concentration of carriers/transporters. In this respect, the kinetics resemble the Michaelis-Menten behavior of enzyme-catalyzed reactions. Facilitated diffusion systems are often stereo-specific, and they are subject to competitive inhibition. Facilitated transport systems are also distinguished from active transport systems which work against a concentration barrier and require a source of free energy. Simple diffusion often occurs in parallel to facilitated diffusion, and one must correct facilitated transport for the basal rate. This is usually evident when a plot of transport rate versus substrate concentration reaches a limiting nonzero rate at saturating substrate While the term passive transport has been used synonymously with facilitated transport, others have suggested that this term may be confused with or mistaken for simple diffusion. See Membrane Transport Kinetics... 

If the (3-lyase enzyme, or the renal basolateral membrane transport system, or y-glutamyltransferase, or cysteinylglycinase is inhibited, the nephrotoxicity of DCVC can be reduced, indicating that each of these processes is involved. 

Several processes in the immune response are affected by lithium in vivo and in vitro 139). The proliferative responses of hamster lymphoid cells to concanavalin A or phytohemagglutinin, which stimulate mitosis in T cells, were enhanced by lithium in a serum-free culture system. Proliferative stimulation also was obtained with lithium using the B cell mitogen lipopolysaccharide, but the B cell mitogens dextran sulfate and trypsin had no effect 140-143). Lithium increased the effects of suboptimal concentrations of stimulants, but had smaller effects on stimulation by optimal concentrations. With concanavalin A, the response to optimal stimulatory concentrations was inhibited 140). Paradoxical results such as these may be due to inhibitory effects of lithium on adenylate cyclase, or to effects on membrane transport systems 141). Most of these experiments used very high concentrations of lithium, considerably in excess of normal therapeutic doses (maximal inhibitory concentrations were 10 mM with hamster cells and 5 mM with human lymphocytes). At therapeutic levels of lithium, increased incorporation of [ H]thymidine was seen in human peripheral blood mononuclear cells. 

Effects on passive and active membrane transport systems, e.g., increase of passive efflux and flux of ions such as protons, cations Mg and Ca or small molecules, stimulation of the leakage of protons and potassium, changes in the uptake of compounds (e.g., solvents) and excretion (e.g., metabolic products), inhibition of active transport systems (e.g., ATP depletion). 

Enhanced selectivity and sensitivity has been achieved in two ways (1) induction of the desired metabolic or membrane transport systems, or (2) the inhibition or suppression of undesired systems. The former method has been successfully used for phenolics (Trichosporon cutaneum), tyrosine... 

Animal studies and studies using brush border membrane vesicles from human kidney cortex indicate that biotin is reclaimed from the glomerular filtrate against a concentration gradient by a saturable, Na -depen-dent, structurally specific system, but biocytin does not inhibit tubular reabsorption of biotin. Subsequent egress of biotin from the tubular cells occurs via a basolateral membrane transport system that is not dependent on Na. Studies of patients with biotinidase deficiency surest that there may be a role for biotinidase in the renal handling of biotin. 

Effects of Allelochemlcals on ATPases. Several flavonoid compounds inhibit ATPase activity that is associated with mineral absorption. Phloretin and quercetin (100 pM) inhibited the plasma membrane ATPase Isolated from oat roots (33). The naphthoquinone juglone was inhibitory also. However, neither ferulic acid nor salicylic acid inhibited the ATPase. Additional research has shown that even at 10 mM salicylic acid inhibits ATPase activity only 10-15% (49). This lack of activity by salicylic acid was substantiated with the plasma membrane ATPase Isolated from Neurospora crassa (50) however, the flavonols fisetln, morin, myricetin, quercetin, and rutin were inhibitory to the Neurospora ATPase. Flavonoids inhibited the transport ATPases of several animal systems also (51-53). Thus, it appears that flavonoids but not phenolic acids might affect mineral transport by inhibiting ATPase enzymes. 

Transport systems. Partitioning of various types of molecules such as allelochemlcals into the lipid bilayer of the mitochondrial inner membrane can perturb the membrane and alter the conformation, properties, and function of components of the membranes. Unfortunately, it is not always possible to demonstrate directly the existence of carrier systems, but indirect evidence can be obtained. Alterations induced to the membrane are sometimes reflected in the osmotic behavior of mitochondria. The inner membrane is relatively impermeable to many cations, including K and H, and many solutes (31). Hence, the organelles are osmotic-ally stable under certain conditions. Indications were obtained that the allelochemlcals inhibited the action of carrier-mediated transport processes associated with the mitochondrial inner membrane (as reflected in the osmotic behavior). Responses obtained with quercetin are shown in Figure 3. Mitochondria are osmotically... 

Much progress has been made in understanding the different mechanisms that can cause mitochondrial dysfunction, such as (i) uncoupling of electron transport from ATP synthesis by undermining integrity of inner membrane (ii) direct inhibition of electron transport system components (iii) opening of the mitochondrial permeability transition pore leading to irreversible collapse of the transmembrane potential and release of pro-apoptotic factors (iv) inhibition of the... 

It is important to make a clear distinction between neuronal and vesicular transport. Neuronal transport occurs from the junctional extracellular fluid (biophase) across the cell membrane of the neuron and into the neuronal cytosol. Vesicular transport is from the neuronal cytosol across the membrane of the vesicle and into the vesicle. Although these two systems readily transport both norepinephrine and epinephrine, certain drugs will selectively inhibit one or the other transport system. 

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