Taurocholate

Mammalian bile contains sodium salts of conjugated bile acids, e.g. glycocholic acid and taurocholic acid, in which cholic acid is combined (amide linkage) with glycine and taurine respectively. 

Sodium taurocholate [145-42-6] M 555.7. Purified by recrystn and gel chromatography using Sephadex LH-20. 

The structure of cholic acid helps us understand how bile salts such as sodium taurocholate promote the transport of lipids through a water-rich environment. The bottom face of the molecule bear s all of the polar groups, and the top face is exclusively hydrocarbon-like. Bile salts emulsify fats by forming micelles in which the fats are on the inside and the bile salts are on the outside. The hydrophobic face of the bile salt associates with the fat that is inside the micelle the hydrophilic face is in contact with water on the outside. 

FIGURE 25.41 Cholic acid, a bile salt, is synthesized from cholesterol via 7o -hydroxy-cholesterol. Conjugation with taurine or glycine produces taurocholic acid and glycocholic acid, respectively. Taurocholate and glycocholate are freely water-soluble and are highly effective detergents. 

Taupunkt, m. dew point thaw point. Taurochol-salz, n. taurocholate. -saure, / taurocholic acid. 

L-Cysteine is a precursor of the thioethanolamine portion of coenzyme A and of the taurine that conjugates with bile acids such as taurocholic acid (Chapter 26). 

The thioethanolamine of coenTyme A and the taurine of taurocholic acid arise from cysteine. 

In culture, the human colon carcinoma cell hne Caco-2 spontaneously differentiates at confluency into polarized cells with enterocyte-like characteristics. The principle of this approach consists of following the passage of the compound of interest from the apical or lumen-like sides to the basolateral or lymph-hke sides of Caco-2 cells, thus following the absorption of the compound per se. One obhgate step for fat-soluble nutrients such as carotenoids to cross the intestinal barrier is their incorporation into CMs assembled in the enterocytes. Under normal cell culture conditions, Caco-2 cells are unable to form CMs. When supplemented with taurocholate and oleic acid, Caco-2 cells were reported to assemble and secrete CMs. ... 

In contrast to previous in vivo models, this in vitro model provides the possibility of dissociating experimentally two important processes of intestinal absorption cellular uptake and secretion. Under conditions mimicking the postprandial state (taurocholate/oleic acid supplementation), differentiated Caco-2 cells were able to (1) take up carotenoids at the apical sides and incorporate them into CMs and (2) secrete them at the basolateral sides associated with CM fractions. Using this approach, the extent of absorption of P-carotene through Caco-2 cell monolayers after 16 hr of incubation was 11.2%, a value falling within the in vivo range (9 to 22%). ° - Of the total amount of P-carotene secreted, 78% was associated with the two CM fractions and 10% with the VLDL fraction. ... 

Bile acids The organic acids in bile contains sodium glycocholate and sodium taurocholate, cholesterol, biliverdin and bilirubin, mucus, fat, lecithin, and cells and cellular debris. 

When diabetic rabbits (24) were treated with 50 IU of bovine insulin imbibed at 50 mg/g poly (acrylic acid) (Figure 14) no reduction in serum glucose over that achieved by the dry blend control could be detected. Pretreatment of the animals with oral doses of either a penetration enhancer, sodium taurocholate, or a protease inhibitor, aproteinin, failed to improve the insulin activity. One possible explanation for this unexpected lack of activity might be that the diseased animals exhibit impaired ileal absorption of fluids (25). 

Figure 14. Effect of oral delivery of an insulin/polyacid matrix to diabetic rabbits on serum glucose, with and without adjuvants (sodium taurocholate, aprotinin).

Figure 7.13 shows some of the structures of common bile acids. In low ionic strength solutions, sodium taurocholate forms tetrameric aggregates, with critical... 

Yamashita et al. [82] added up to 10 mM taurocholic acid, cholic acid (cmc 2.5 mM), or sodium laurel sulfate (SLS low ionic strength cmc 8.2 mM) to the donating solutions in Caco-2 assays. The two bile acids did not interfere in the transport of dexamethasone. However, SLS caused the Caco-2 cell junctions to become leakier, even at the sub-CMC 1 mM level. Also, the permeability of dexamethasone decreased at 10 mM SLS. 

These general observations have been confirmed in PAMPA measurements in our laboratory, using the 2% DOPC-dodecane lipid. With very lipophilic molecules, glycocholic acid added to the donor solution slightly reduced permeabilities, taurocholic acid increased permeabilities, but SLS arrested membrane transport altogether in several cases (especially cationic, surface-active drugs such as CPZ). 

FGJ Poelma, R Breas, JJ Tukker. Intestinal absorption of drugs. IV. The influence of taurocholate and L-cysteine on the barrier function of mucus. Int J Pharm 64 161-169, 1990. 

Morimoto et al. [33] demonstrated that the ocular absorption of hydrophilic compounds over a wide range of molecular weights could be increased by 2 and 10 mM sodium taurocholate and sodium taurodeoxycholate in a dose-dependent manner. The compounds were glutathione (307 Da), 6-carboxyfluorescein (376 Da), FTTC-dextran (4 kDa), and insulin (5.7 kDa). Of the two bile salts, sodium taurodeoxycholate was more effective. At 10 mM, this bile salt increased the permeability of 6-carboxyfluorescein from 0.02% to 11%, glutathione from 0.08% to 6%, FITC-dextran from 0% to 0.07%, and insulin from 0.06% to 3.8%. Sodium taurocholate, on the other hand, increased the permeability to 0.13%, 0.38%, 0.0011%, and 0.14%, respectively. Taurodeoxycholate was more effective than taurocholate in the nasal epithelium as well [202], This difference in activities can possibly be attributed to their micelle-forming capability, which is higher for taurodeoxycholate, a dihydroxy bile salt [190],... 

Conjunctival insulin absorption in rabbits estimated as plasma insulin levels after punctal occlusion was also shown to be increased by bile salts (sodium deoxycholate, glycocholate, and taurocholate) and a surfactant (polyoxyethylene-9-lauryl ether) [200], Their rank order of effectiveness at 1% was sodium deoxycholate > polyoxyethylene-9-lauryl ether > sodium glycocholate = sodium taurocholate. There was an 18-, 29-, 3-, and 3-fold increase, respectively, in conjunctival absorption. Sodium deoxycholate, a dihydroxy bile salt, was more effec-... 

The literature survey in this section suggests that the ideal in vitro permeability assay would have pH 6.0 and 7.4 in the donor wells, with pH 7.4 in the acceptor wells. (Such a two-pH combination could differentiate acids from bases and non-ionizables by the differences between the two Pe values.) Furthermore, the acceptor side would have 3% wt/vol BSA to maintain a sink condition (or some sinkforming equivalent). The donor side may benefit from having a bile acid (i.e., taurocholic or glycocholic, 5-15 mM), to solubilize the most lipophilic sample molecules. The ideal lipid barrier would have a composition similar to those in Table 3.1, with the membrane possessing a substantial negative charge (mainly from PI). Excessive DMSO/other co-solvents would be best avoided, due to their unpredictable effects. 

Woodcock, S., Williamson, I., Hassan, I., MacKay, M., Isolation and characterization of clones from the Caco-2 cell line displaying increased taurocholic add transport, J. Cell Sd. 1991, 98, 323-332. 

NTCP Sodium-dependent taurocholate cotransporting polypeptide... 

Zimmerli, B., J. Vaiantinas, and P. J. Meier. Multispecificity of Na+-dependent taurocholate uptake in basolateral (sinusoidal) rat liver plasma membrane vesicles. J. Pharmacol. Exp. Ther. 1989, 250, 301-318. 

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