Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

ATP pump

Barboiu, M., Cerneaux, S., Vaughan, G. and van der Lee, A. (2004) Ion-driven ATP-pump by self-organized hybrid membrane materials. Journal of the American Chemical Society, 126, 3545-3550. [Pg.335]

Transport ATPases transport cations—they are ion pumps. ATPases of the F type—e. g., mitochondrial ATP synthase (see p. 142)—use transport for ATP synthesis. Enzymes of the V type, using up ATP, pump protons into lyso-somes and other acidic cell compartments (see p. 234). P type transport ATPases are particularly numerous. These are ATP-driven cation transporters that undergo covalent phosphorylation during the transport cycle. [Pg.220]

Figure 15.2. Location of xenobiotic transporters in selected barrier and excretory tissues. For simplicity, the tissues are arranged along a structure representing the vascular space. Arrows indicated direction of transport under normal conditions. This figure is not meant to be comprehensive not all transporters expressed in a tissue are shown. Transporters driven by ATP pump substrates out of cells (efflux). Other transporters are capable of supporting substrate uptake or efflux. Which of these processes predominates depends on available driving forces—for example, substrate concentration gradient and the capability to couple transport to sources of potential energy. Figure 15.2. Location of xenobiotic transporters in selected barrier and excretory tissues. For simplicity, the tissues are arranged along a structure representing the vascular space. Arrows indicated direction of transport under normal conditions. This figure is not meant to be comprehensive not all transporters expressed in a tissue are shown. Transporters driven by ATP pump substrates out of cells (efflux). Other transporters are capable of supporting substrate uptake or efflux. Which of these processes predominates depends on available driving forces—for example, substrate concentration gradient and the capability to couple transport to sources of potential energy.
Figure C3.2.17. Diagram of a liposome-based artificial photosynthetic membrane showing the photocycle that pumps protons into the interior of the liposome and the CFqF j-ATP synthase enzyme. From [55],... Figure C3.2.17. Diagram of a liposome-based artificial photosynthetic membrane showing the photocycle that pumps protons into the interior of the liposome and the CFqF j-ATP synthase enzyme. From [55],...
Active Transport. Maintenance of the appropriate concentrations of K" and Na" in the intra- and extracellular fluids involves active transport, ie, a process requiring energy (53). Sodium ion in the extracellular fluid (0.136—0.145 AfNa" ) diffuses passively and continuously into the intracellular fluid (<0.01 M Na" ) and must be removed. This sodium ion is pumped from the intracellular to the extracellular fluid, while K" is pumped from the extracellular (ca 0.004 M K" ) to the intracellular fluid (ca 0.14 M K" ) (53—55). The energy for these processes is provided by hydrolysis of adenosine triphosphate (ATP) and requires the enzyme Na" -K" ATPase, a membrane-bound enzyme which is widely distributed in the body. In some cells, eg, brain and kidney, 60—70 wt % of the ATP is used to maintain the required Na" -K" distribution. [Pg.380]

Depletion of ATP in the cells prevents maintenance of the membrane potential, inhibits the functioning of ion pumps, and attenuates cellular signal transduction (e.g., formation of second messengers such as inositol phos phates or cyclic AMP). A marked ATP depletion ultimately impairs the activ-itv of the cell and leads to ceil death. [Pg.283]

FIGURE 10.8 A schematic diagram of the Na, K -ATPase in mammalian plasma membrane. ATP hydrolysis occurs on the cytoplasmic side of the membrane, Na ions are transported out of the cell, and ions are transported in. The transport stoichiometry is 3 Na out and 2 in per ATP hydrolyzed. The specific inhibitor ouabain (Figure 7.12) and other cardiac glycosides inhibit Na, K -ATPase by binding on the extracellular surface of the pump protein. [Pg.302]

ATP hydrolysis occurs on the cytoplasmic side of the membrane (Figure 10.8), and the net movement of one positive charge outward per cycle makes the sodium pump electrogenic in nature. [Pg.302]

Featherstone, C., 1990. An ATP-driven pump for secretion of yeast mating factor. Trends in Biochemical Sciences 15 169—170. [Pg.325]

FIGURE 19.3 Just as a water pump must be primed with water to get more water out, the glycolytic pathway is primed with ATP iu steps 1 and 3 iu order to achieve net production of ATP iu the second phase of the pathway. [Pg.613]

When Mitchell first described his chemiosmotic hypothesis in 1961, little evidence existed to support it, and it was met with considerable skepticism by the scientific community. Eventually, however, considerable evidence accumulated to support this model. It is now clear that the electron transport chain generates a proton gradient, and careful measurements have shown that ATP is synthesized when a pH gradient is applied to mitochondria that cannot carry out electron transport. Even more relevant is a simple but crucial experiment reported in 1974 by Efraim Racker and Walther Stoeckenius, which provided specific confirmation of the Mitchell hypothesis. In this experiment, the bovine mitochondrial ATP synthasereconstituted in simple lipid vesicles with bac-teriorhodopsin, a light-driven proton pump from Halobaeterium halobium. As shown in Eigure 21.28, upon illumination, bacteriorhodopsin pumped protons... [Pg.697]

Photosynthetic electron transport, which pumps into the thylakoid lumen, can occur in two modes, both of which lead to the establishment of a transmembrane proton-motive force. Thus, both modes are coupled to ATP synthesis and are considered alternative mechanisms of photophosphorylation even though they are distinguished by differences in their electron transfer pathways. The two modes are cyclic and noncyclic photophosphorylation. [Pg.729]

Fig. 5. Tentative mixed potential model for the sodium-potassium pump in biological membranes the vertical lines symbolyze the surface of the ATP-ase and at the same time the ordinate of the virtual current-voltage curves on either side resulting in different Evans-diagrams. The scale of the absolute potential difference between the ATP-ase and the solution phase is indicated in the upper left comer of the figure. On each side of the enzyme a mixed potential (= circle) between Na+, K+ and also other ions (i.e. Ca2+ ) is established, resulting in a transmembrane potential of around — 60 mV. This number is not essential it is also possible that this value is established by a passive diffusion of mainly K+-ions out of the cell at a different location. This would mean that the electric field across the cell-membranes is not uniformly distributed. Fig. 5. Tentative mixed potential model for the sodium-potassium pump in biological membranes the vertical lines symbolyze the surface of the ATP-ase and at the same time the ordinate of the virtual current-voltage curves on either side resulting in different Evans-diagrams. The scale of the absolute potential difference between the ATP-ase and the solution phase is indicated in the upper left comer of the figure. On each side of the enzyme a mixed potential (= circle) between Na+, K+ and also other ions (i.e. Ca2+ ) is established, resulting in a transmembrane potential of around — 60 mV. This number is not essential it is also possible that this value is established by a passive diffusion of mainly K+-ions out of the cell at a different location. This would mean that the electric field across the cell-membranes is not uniformly distributed.
Currently, five different molecular classes of mdr efflux pumps are known [5], While pumps of the the ATP-binding cassette (ABC) transporter superfamily are driven by ATP hydrolysis, the other four superfamilies called resistance-nodulation-division (RND), major facilitator superfamily (MFS), multidrug and toxic compound extrusion (MATE), and small multidrag resistance transporter (SMR) are driven by the proton-motive force across the cytoplasmic membrane. Usually a single pump protein is located within the cytoplasmic membrane. However, the RND-type pumps which are restricted to Gram-negative bacteria consist of two additional components, a periplasmic membrane fusion protein (MFP) which connects the efflux pump to an outer... [Pg.105]

See other pages where ATP pump is mentioned: [Pg.49]    [Pg.44]    [Pg.3852]    [Pg.427]    [Pg.428]    [Pg.130]    [Pg.247]    [Pg.3851]    [Pg.419]    [Pg.2081]    [Pg.1360]    [Pg.627]    [Pg.49]    [Pg.44]    [Pg.3852]    [Pg.427]    [Pg.428]    [Pg.130]    [Pg.247]    [Pg.3851]    [Pg.419]    [Pg.2081]    [Pg.1360]    [Pg.627]    [Pg.90]    [Pg.124]    [Pg.98]    [Pg.40]    [Pg.153]    [Pg.536]    [Pg.127]    [Pg.227]    [Pg.232]    [Pg.272]    [Pg.302]    [Pg.304]    [Pg.304]    [Pg.307]    [Pg.309]    [Pg.613]    [Pg.693]    [Pg.718]    [Pg.171]    [Pg.171]    [Pg.230]   
See also in sourсe #XX -- [ Pg.2081 ]



SEARCH



ATP-dependent export pump

ATP-powered Pump

Proton pumps ATP-driven

© 2024 chempedia.info