Membrane luminal

The uptake of mercury in the proximal tubule can occur by two mechanisms, with one being from the luminal membrane and another from the basolateral membrane. Luminal uptake involves the activity of y-glutamyltransferase and cysteinylglycinase... 

Water moving from the blood into the brain through an intact BBB has to cross three membranes luminal and abluminal endothelial cell membranes, and the membrane of the astrocyte foot processes (Kimelberg, 2004 Tait et al., 2008). High density of AQP4 is present in the vascular-facing astrocytic membranes. Although... 

The renal tubular epithelium consists of three aqueous compartments separated by two lipid membranes (luminal and peritubular). Across these two boundaries ionic potassium, but not chloride, is distributed in accordance with the Donnan relationship of electrochemical equilibrium. 

Table II gives a summary of the late proximal tubule activity ratios, electrical PDs and calculated equilibrium potentials. These parameters are presented under three headings (1) across the tubular epithelium (transepithelial), (2) across the luminal cell membrane (luminal), and (3) across the peritubular cell membrane (peritubular). Whereas the transepithelial treatment is essentially one that deals with a two-compartment system, analysis across the luminal and peritubular boundaries involves a three-compartment system.

Mineralocorticoids foUow a mechanistic route similar to that of glucocorticoids, though differing in the proteins expressed. The activated MR-DNA complex promotes the expression of aldosterone-induced proteins (AIPs), which then act to increase conductance of the luminal membrane and concurrently increase pump activity of the basolateral membrane. These actions result from a number of AlP-influenced cellular characteristics,... 

In some luminous organisms, luciferases and photoproteins exist in particulate forms that are insoluble in water or common buffer solutions, resembling membrane proteins. The protein is probably highly aggregated or bound to an insoluble material thus, the protein... 

Specific proteases located on the luminal side of the endoplasmic reticulum. They cleave the amino-terminal peptides from the precursor forms of membrane and secretory proteins. 

Cell membrane spanning proteins contain a luminal/ extracellular domain, a transmembrane region and a cytosolic domain. In a type I transmembrane protein the N-terminus is the extracellular/luminal part of the protein, whereas the C-terminus comprises the cytosolic region of the membrane protein. 

Vitamin K carboxylase is a transmembraneous protein in the lipid bilayer of the endoplasmatic reticulum (ER). It is highly glycosilated and its C-terminal is on the luminal side of the membrane. Besides its function as carboxylase it takes part as an epoxidase in the vitamin K cycle (Fig. 1). For the binding of the y-carboxylase the vitamin K-dependent proteins have highly conserved special recognition sites. Most vitamin K-dependent proteins are carboxy-lated in the liver and in osteoblasts, but also other tissues might be involved, e.g., muscles. 

Figure 41-14. The transcellular movement of glucose in an intestinal cell. Glucose follows Na+ across the luminal epithelial membrane. The Na+ gradient that drives this symport is established by Na+ -K+ exchange, which occurs at the basal membrane facing the extra-ceiiuiarfiuid compartment. Glucose at high concentration within the ceii moves "downhill" into the extracel-iuiarfiuid by fadiitated diffusion (a uniport mechanism).

Ribosomes remain attached to the ER during synthesis of signal peptide-containing proteins but are released and dissociated into their two types of subunits when the process is completed. The signal peptide is hydrolyzed by signal peptidase, located on the luminal side of the ER membrane (Figure 46-4), and then is apparently rapidly degraded by proteases. 

The cytoplasmic domains reconstructed from negatively stained [90] and from frozen-hydrated samples [91,177] have similar shapes. Both include the protruding lobe and the bridge region that links the Ca " -ATPase molecules into dimers. The intramembranous peptide domains of the two ATPase molecules which make up a dimer spread apart as they pass through the bilayer toward the luminal side of the membrane, establishing contacts with the Ca -ATPase molecules in the neighboring dimer chains. The lateral association of dimer chains into extended crystal lattice is... 

The A20 antibody did not bind significantly to native SR vesicles, but solubilization of the membrane with C Eg or permeabilization of the vesicles by EGTA exposed its epitope and increased the binding more than 20-fold [139], By contrast, the A52 antibody reacted freely with the native sarcoplasmic reticulum, while the A25 antibody did not react either in the native or in the C Eg solubilized or permeabilized preparations, and required denaturation of Ca " -ATPase for reaction, Clarke et al, [139] concluded that the epitope for A52 is freely exposed on the cytoplasmic surface, while the epitope for A20 was assigned to the luminal surface, where it became accessible to cytoplasmic antibodies only after solubilization or permeabilization of the membrane. The epitope for A25 is assumed to be on the cytoplasmic surface in a folded structure and becomes accessible only after denaturation. 

The slow and fast isoenzymes of Ca -ATPase contain 42 and 50 arginine residues, respectively. The C-terminal sequence of the neonatal fast-twitch isoenzyme is Arg-Arg-Lys. There are only four arginine residues in the putative transmembrane helices, which are probably located near the cytoplasmic or luminal surface of the membrane. The remaining arginine residues are distributed in the cytoplasmic domains. 

The physiological role of the ICOR is not clear and may be heterogeneous in the various tissues. In the thick ascending limb of the loop of Henle this channel appears to serve as the exit for CP at the basal cell pole [16,65,66], This conductive mechanism, therefore, is required for the reabsorption of Na and CP by this segment of the nephron [16]. In the rectal gland of Squalus acanthias a very similar channel is utilized for Na" and CP secretion. In these latter cells the CP-channel is present in the luminal membrane and is controlled by cytosolic cAMP [15,56,71]. It has been claimed that this kind of channel is also responsible for the secretion of CP in the colonic crypt cell, in colonic carcinoma cells and in respiratory epithelial cells [17,19,20,22]. Recent data have cast some doubt on this concept ... 

The third mucosal layer is that lining the entire length of the small intestine and which represents a continuous sheet of epithelial cells. These epithelial cells (or enterocytes) are columnar in shape, and the luminal cell membrane, upon which the microvilli reside, is called the apical cell membrane. Opposite this membrane is the basal (or basolateral) plasma membrane, which is separated from the lamina propria by a basement membrane. A sketch of this cell is shown in Fig. 5. The primary function of the villi is absorption. 

Figure 2 Comparison of intestinal epithelial cells in culture and in situ. (A) Human colon Caco-2 cells grown in culture for 16 days on a semiporous filter. (B) Epithelial layer of rat jejunum. AP, apical or luminal membrane B, basal or abluminal membrane BM, basement membrane G, goblet cell LS, lateral space mv, microvilli Nu, nucleus TJ, tight junction. Bars equal 10 pm. 

An essential requirement for diffusion of Na+ ions is the creation of a concentration gradient for sodium between the filtrate and intracellular fluid of the epithelial cells. This is accomplished by the active transport ofNa+ ions through the basolateral membrane of the epithelial cells (see Figure 19.4). Sodium is moved across this basolateral membrane and into the interstitial fluid surrounding the tubule by the Na+, K+-ATPase pump. As a result, the concentration of Na+ ions within the epithelial cells is reduced, facilitating the diffusion of Na+ ions into the cells across the luminal membrane. Potassium ions transported into the epithelial cells as a result of this pump diffuse back into the interstitial fluid (proximal tubule and Loop of Henle) or into the tubular lumen for excretion in the urine (distal tubule and collecting duct). 

Formation of Na+ channels in the luminal membrane of the tubular epithelial cells (facilitates passive diffusion of Na+ ions into the cell)... 

Formation of Na+, K+-ATPase carrier molecules in the basolateral membrane of the tubular epithelial cells (promotes extrusion of Na+ ions from the cells and their movement into plasma by way of peritubular capillaries enhances the concentration gradient for passive diffusion through Na+ channels in the luminal membrane)... 

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