Big Chemical Encyclopedia

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

Articles Figures Tables About

Intestinal membrane-bound

Four major enzyme groups are secreted lipolytic, proteolytic, amylolytic, and nucleic acid splitting enzymes. These pancreatic enzymes, some of which are secreted in multipile forms, possess specificities complementary to die intestinal membrane-bound enzymes (Tabic 1). Fresh, uncontsnkinated pancreatic juice is without proteolytic activity because these enzymes am in the form of inactive zymogens. An important fraction of the calcium in pancreatic juice accompanies the enzymes, especially ct-amylase. Human pancreatic juice is moat dose to that of the pig, with high proportions of lipase and a-amylase in comparison with other mammals [1]. Therefore, pig pancreas extract, pancreatin, has up to now been die oreferred enzvme source for therapeutic tuncreas substitution. [Pg.187]

Enzymatic Conversion of Cholesterol. A decrease of cholesterol in meat products in the future may be possible through the conversion of cholesterol [57-88-5] to coprosterol [560-68-9] which is not absorbed readily in the intestine. Cholesterol reductase can be isolated from alfalfa leaves and cucumber leaves (53). Treatment of meat animals might involve an injection of this ensyme immediately prior to slaughter, allowing for the conversion of a portion of the membrane-bound cholesterol into coprostanol. [Pg.35]

Diabetic patients have reduced antioxidant defences and suffer from an increased risk of free radical-mediated diseases such as coronary heart disease. EC has a pronounced insulin-like effect on erythrocyte membrane-bound acetylcholinesterase in type II diabetic patients (Rizvi and Zaid, 2001). Tea polyphenols were shown to possess anti-diabetic activity and to be effective both in the prevention and treatment of diabetes (Choi et al, 1998 Yang et al, 1999). The main mechanism by which tea polyphenols appear to lower serum glucose levels is via the inhibition of the activity of the starch digesting enzyme, amylase. Tea inhibits both salivary and intestinal amylase, so that starch is broken down more slowly and the rise in serum glucose is thus reduced. In addition, tea may affect the intestinal absorption of glucose. [Pg.138]

The coupling of solute transport in the GI lumen with solute lumenal metabolism (homogeneous reaction) and membrane metabolism (heterogeneous reaction) has been discussed by Sinko et al. [54] and is more generally treated in Cussler s text [55], At the cellular level, solute metabolism can occur at the mucosal membrane, in the enterocyte cytosol, and in the endoplasmic reticulum (or microsomal compartment). For peptide drugs, the extent of hydrolysis by lumenal and membrane-bound peptidases reduces drug availability for intestinal absorption [56], Preferential hydrolysis (metabolic specificity) has been targeted for reconversion... [Pg.191]

Figure 8.3 A model of iron transport across the intestine. Reduction of ferric complexes to the ferrous form is achieved by the action of the brush border ferric reductase. The ferrous form is transported across the brush border membrane by the proton-coupled divalent cation transporter (DCT1) where it enters an unknown compartment in the cytosol. Ferrous iron is then transported across the basolateral membrane by IREG1, where the membrane-bound copper oxidase hephaestin (Hp) promotes release and binding of Fe3+ to circulating apotransferrin. Except for hephaestin the number of transmembrane domains for each protein is not shown in full. Reprinted from McKie et al., 2000. Copyright (2000), with permission from Elsevier Science. Figure 8.3 A model of iron transport across the intestine. Reduction of ferric complexes to the ferrous form is achieved by the action of the brush border ferric reductase. The ferrous form is transported across the brush border membrane by the proton-coupled divalent cation transporter (DCT1) where it enters an unknown compartment in the cytosol. Ferrous iron is then transported across the basolateral membrane by IREG1, where the membrane-bound copper oxidase hephaestin (Hp) promotes release and binding of Fe3+ to circulating apotransferrin. Except for hephaestin the number of transmembrane domains for each protein is not shown in full. Reprinted from McKie et al., 2000. Copyright (2000), with permission from Elsevier Science.
Choudhury BR, Poddar MK. (1985) Andrographolide and Kalmegh (Andrographis paniculata) extract Effect on intestinal brush-border membrane bound hydrolases. Methods Find Exp Clin Pharmacol 7 617-621. [Pg.363]

These zinc-dependent endopeptidases (meprin A [EC 3.4.24.18] and meprin B [EC 3.4.24.63] ) are members of the peptidase family M12A. They catalyze the hydrolysis of peptide bonds in proteins and peptide substrates. Meprin A, a membrane-bound enzyme that has been isolated from mouse and rat kidney and intestinal brush borders as well as salivary ducts, acts preferentially on carboxyl side of hydrophobic amino acyl residues. Meprin A and B are insensitive to inhibition by phosphora-midon and thiorphan. [Pg.452]

Role of PI in membrane protein anchoring Specific proteins can be covalently attached via a carbohydrate bridge to membrane-bound PI (Figure 17.9). [Note Examples of such proteins include alkaline phosphatase (a digestive enzyme found on the surface of the small intestine that attacks organic phosphates), and acetylcholine esterase (an enzyme of the postsynaptic membrane that... [Pg.203]

About one third of the zinc in venous plasma is bound to a2-macroglobulin, and the remainder to albumin, with the exception of trace amounts bound to histidine and cysteine.1145 However, transferrin has been implicated in the uptake of zinc from the intestinal membrane, while albumin is involved in the removal of zinc from intestinal mucosal cells and its transport to the liver. Other ligands proposed for various transport processes for zinc are citric acid and picolinic acid.1146... [Pg.672]

Mucoadhesive polymers exhibiting strong complexing properties are capable of inhibiting intestinal brush border membrane-bound proteases through a far distance inhibitory effect [65]. In vivo, the mucoadhesive polymer is separated from the brush border membrane by a mucus layer [30]. Although there is no direct contact between polymer- and membrane-bound enzymes, it could be shown that inhibition takes place. The exploitation of this far distance effect seems to be a very promising alternative to small molecular mass inhibitors, which are currently used as inhibitors of brush border membrane-bound proteases. [Pg.93]

Bernkop-Schniirch, A., G. Walker, and H. Zarti. 2001. Thiolation of polycarbophil enhances its inhibition of intestinal brush border membrane bound aminopeptidase N. J Pharm Sci 90 1907. [Pg.103]

Bernkop-Schnurch A, Marschtitz MK (1997) Development and in vivo evaluation of systems to protect peptide drugs from aminopeptidase N. Pharm Res 14 181-185 Bernkop-Schnurch A, Paikl C, Valenta C (1997) Novel bioadhesive chitosan-EDTA conjugate protects leucine enkephalin from degradation by aminopeptidase N. Pharm Res 14 917-922 Bernkop-Schnurch A, Thaler S (2000) Polycarbophil-cysteine conjugates as platforms for oral (poly)peptide delivery systems. J Pharm Sci 89 901-909 Bernkop-Schnurch A, Walker G, Zarti H (2001) Thiolation of polycarbophil enhances its inhibition of intestinal brush border membrane bound aminopeptidase N. J Pharm Sci 90 1907-1914... [Pg.81]

See other pages where Intestinal membrane-bound is mentioned: [Pg.94]    [Pg.158]    [Pg.827]    [Pg.818]    [Pg.4530]    [Pg.94]    [Pg.158]    [Pg.827]    [Pg.818]    [Pg.4530]    [Pg.113]    [Pg.3]    [Pg.199]    [Pg.39]    [Pg.3]    [Pg.192]    [Pg.193]    [Pg.29]    [Pg.38]    [Pg.266]    [Pg.256]    [Pg.184]    [Pg.49]    [Pg.328]    [Pg.548]    [Pg.267]    [Pg.286]    [Pg.245]    [Pg.86]    [Pg.92]    [Pg.93]    [Pg.94]    [Pg.97]    [Pg.159]    [Pg.40]    [Pg.309]    [Pg.365]    [Pg.8]   


SEARCH



Intestinal membrane

Intestinal membrane-bound enzymes

Membrane bound

© 2024 chempedia.info