| Taurocholic acid, known also as cholaic acid, cholyltaurine, or acidum cholatauricum, is a deliquescent yellowish crystalline bile acid involved in the emulsification of fats. It occurs as a sodium salt in the bile of mammals. It is a conjugate of cholic acid with taurine. In medical use, it is administered as a cholagogue and choleretic.
Hydrolysis of taurocholic acid yields taurine.
For commercial use, taurocholic acid is manufactured from cattle bile, a byproduct of the meat-processing industry.
This acid is also one of the many molecules in the body that has cholesterol as its precursor. |
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Read full article at Wikipedia
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InChI=1S/C26H45NO7S/c1- 15(4-7-23(31)27-10-11-35(32,33)34)18-5-6-19-24-20(14-22(30)26(18,19)3)25(2)9-8-17(28)12-16(25)13-21(24)29/h15-22,24,28-30H,4-14H2,1-3H3,(H,27,31)(H,32,33,34)/t15-,16+,17-,18-,19+,20+,21-,22+,24+,25+,26-/m1/s1 |
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| [H][C@@]12C[C@H](O)CC[C@]1(C)[C@@]1([H])C[C@H](O)[C@]3(C)[C@]([H])(CC[C@@]3([H])[C@]1([H])[C@H](O)C2)[C@H](C)CCC(=O)NCCS(O)(=O)=O |
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Bronsted base
A molecular entity capable of accepting a hydron from a donor (Bronsted acid).
(via organic amino compound )
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human metabolite
Any mammalian metabolite produced during a metabolic reaction in humans (Homo sapiens).
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View more via ChEBI Ontology
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2-[(3α,7α,12α-trihydroxy-24-oxo-5β-cholan-24-yl)amino]ethanesulfonic acid
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3α,7α,12α-trihydroxy-5β-cholanic acid 24-taurine
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ChemIDplus
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cholic acid taurine conjugate
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ChemIDplus
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Choloyl-taurine
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KEGG COMPOUND
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Cholyltaurine
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KEGG COMPOUND
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N-choloyltaurine
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ChemIDplus
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Taurocholate
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KEGG COMPOUND
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Taurocholic acid
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KEGG COMPOUND
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2956951
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Reaxys Registry Number
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Reaxys
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81-24-3
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CAS Registry Number
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KEGG COMPOUND
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81-24-3
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CAS Registry Number
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ChemIDplus
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Li Y, Gao YN, Zhu YB, Lu WF, Yu JY, Dong YY, Xu MY, Peng B, Wu JZ, Su Q, Bai J, Shi XL, Kang YM, Li HB, Xu ML (2024)
Taurocholic acid ameliorates hypertension through the activation of TGR5 in the hypothalamic paraventricular nucleus.
Food & function 15, 5088-5102 [PubMed:38666497]
[show Abstract]
Diets rich in taurine can increase the production of taurine-conjugated bile acids, which are known to exert antihypertensive effects. Despite their benefits to the heart, kidney and arteries, their role in the central nervous system during the antihypertensive process remains unclear. Since hypothalamic paraventricular nucleus (PVN) plays a key role in blood pressure regulation, we aimed to investigate the function of bile acids in the PVN. The concentration of bile acids in the PVN of spontaneously hypertensive rats (SHRs) and normotensive Wistar-Kyoto rats (WKY) fed with normal chow was measured using LC-MS/MS, which identified taurocholic acid (TCA) as the most down-regulated bile acid. To fully understand the mechanism of TCA's functions in the PVN, bi-lateral PVN micro-infusion of TCA was carried out. TCA treatment in the PVN led to a significant reduction in the blood pressure of SHRs, with decreased plasma levels of norepinephrine and improved morphology of cardiomyocytes. It also decreased the number of c-fos+ neurons, reduced the inflammatory response, and suppressed oxidative stress in the PVN of the SHRs. Most importantly, the TGR5 receptors in neurons and microglia were activated. PVN infusion of SBI-115, a TGR5 specific antagonist, was able to counteract with TCA in the blood pressure regulation of SHRs. In conclusion, TCA supplementation in the PVN of SHRs can activate TGR5 in neurons and microglia, reduce the inflammatory response and oxidative stress, suppress activated neurons, and attenuate hypertension. | He S, Li L, Lei S, Su J, Zhang Y, Zeng H (2024)
Effect of lotus seed resistant starch on the bioconversion pathway of taurocholic acid by regulating the intestinal microbiota.
International journal of biological macromolecules 266, 131174 [PubMed:38552699]
[show Abstract]
Taurocholic acid (TCA) is abundant in the rat intestine and has multiple health benefits. In the gut, intestinal microbiota can transform TCA into different bile acid (BA) derivatives, with the composition of microbiota playing a crucial role in the transformation process. This study aims to investigate how lotus seed resistant starch (LRS) can regulate microbiota to influence BA transformation. A fecal fermentation study was conducted in vitro, using either LRS, high-amylose maize starch (HAMS), or glucose (GLU) to analyze microbiota composition, BA content, and metabolic enzyme activities over different fermentation times. Bioinformatics analysis found that LRS increased the relative abundance of Enterococcus, Bacillus, and Lactobacillus, and decreased Escherichia-Shigella, compared with HAMS and GLU. LRS also reduced total BA content and accelerated the conversion of TCA to cholic acid, deoxycholic acid, and other derivatives. These results reveal that LRS and GLU tend to mediate the dehydroxy pathway, whereas HAMS tends to secrete metabolic enzymes in the epimerization pathway. Therefore, the evidence that LRS may regulate TCA bioconversion may benefit human colon health research and provide an important theoretical basis, as well as offer new concepts for the development of functional foods. | Buchinger TJ, Li K, Bussy U, Huerta B, Tamrakar S, Johnson NS, Li W (2024)
Male lake char release taurocholic acid as part of a mating pheromone.
The Journal of experimental biology 227, jeb246801 [PubMed:38270203]
[show Abstract]
The evolutionary origins of sexual preferences for chemical signals remain poorly understood, due, in part, to scant information on the molecules involved. In the current study, we identified a male pheromone in lake char (Salvelinus namaycush) to evaluate the hypothesis that it exploits a non-sexual preference for juvenile odour. In anadromous char species, the odour of stream-resident juveniles guides migratory adults into spawning streams. Lake char are also attracted to juvenile odour but have lost the anadromous phenotype and spawn on nearshore reefs, where juvenile odour does not persist long enough to act as a cue for spawning site selection by adults. Previous behavioural data raised the possibility that males release a pheromone that includes components of juvenile odour. Using metabolomics, we found that the most abundant molecule released by males was also released by juveniles but not females. Tandem mass spectrometry and nuclear magnetic resonance were used to identify the molecule as taurocholic acid (TCA), which was previously implicated as a component of juvenile odour. Additional chemical analyses revealed that males release TCA at high rates via their urine during the spawning season. Finally, picomolar concentrations of TCA attracted pre-spawning and spawning females but not males. Taken together, our results indicate that male lake char release TCA as a mating pheromone and support the hypothesis that the pheromone is a partial match of juvenile odour. | Xu J, Xie S, Chi S, Zhang S, Cao J, Tan B (2022)
Protective effects of taurocholic acid on excessive hepatic lipid accumulation via regulation of bile acid metabolism in grouper.
Food & function 13, 3050-3062 [PubMed:35199809]
[show Abstract]
Dietary bile acid (BA) supplementation can notably ameliorate fatty liver disease caused by high dietary lipids, but the mechanism behind this is poorly understood. The present study was aimed at gaining insight into how TCA (taurocholic acid sodium) reduced hepatic lipid accumulation via the regulation of bile acid metabolism. We explored BA metabolism in juvenile hybrid grouper (Epinephelus fuscoguttatus♀ × E. lanceolatus♂). Three trials were: (1) fed the control, high lipid (HD) or gradient TCA diet; (2) fed a BA diet with or without antibiotics; and (3) injected with an agonist or antagonist of TGR5 (G protein-coupled bile acid receptor 1) and FXR (farnesoid X receptor). The results showed that the TCA diet (about 900 mg kg-1) significantly reduced lipid accumulation in the liver, thus improving liver health. The HD suppressed the abundance of bile-salt hydrolase (BSH) microbes, thus decreasing the concentration of unconjugated primary BAs. TCA administration altered the gut microbial composition and weakened the effects of the HD, thus increasing the level of unconjugated BAs. TCA treatment increased the transport and reabsorption of BAs by activating the TGR5 and FXR signaling pathways, and increased the BA pool size. Furthermore, the presence of microbiota in the intestine increased BA reabsorption and the BA pool size. Our study revealed that exogenous TCA alters the structure of intestinal microbiota and BA composition, then activated the FXR expression, thus regulating the BA metabolism via enhanced BA reabsorption. This, in turn, reduced lipid accumulation and improved the health of the liver in grouper. | Khatun Z, Nurunnabi, Cho KJ, Byun Y, Bae YH, Lee YK (2014)
Oral absorption mechanism and anti-angiogenesis effect of taurocholic acid-linked heparin-docetaxel conjugates.
Journal of controlled release : official journal of the Controlled Release Society 177, 64-73 [PubMed:24412572]
[show Abstract]
Oral delivery is the preferred route to deliver therapeutics via nanoparticles due to ease of administration and patient acceptance. Here, we report on the findings of the absorption pathway of taurocholic acid (TCA)-linked heparin and docetaxel (DTX) conjugate, which we refer to as HDTA. We studied the oral absorption of HDTA using a Caco-2 cell transport system and an animal model. We have also used other absorption enhancers, such as ethylene glycol tetraacetic acid (EGTA), or inhibitors, such as sodium azide, to compare the relative permeability of HDTA conjugates. In vivo comparative studies were conducted using free TCA as a pre-administration and exhibited the maximum absorption site of the organ after oral administration of HDTA conjugates. HDTA was found to be absorbed mainly in the ileum and Caco-2 cell monolayer through passive diffusion and bile acid transporters. High fluorescence intensity of HDTA in mice came from the ileum, and it was eliminated from the body through colon. This novel formulation could be further investigated by clinical trials to find the prospect of oral anti-cancer drug delivery through anti-angiogenic treatment strategies. | Sato S, Yamamoto H, Mukaisho K, Saito S, Hattori T, Yamamoto G, Sugihara H (2014)
Continuous taurocholic acid exposure promotes esophageal squamous cell carcinoma progression due to reduced cell loss resulting from enhanced vascular development.
PloS one 9, e88831 [PubMed:24551170]
[show Abstract]
BackgroundRefluxogenic effects of smoking and alcohol abuse may be related to the risk of esophageal squamous cell carcinoma (ESCC). The present study attempts to clarify the effects of continuous taurocholic acid (TCA) exposure, which is neither mutagenic nor genotoxic, on ESCC progression.MethodsA squamous carcinoma cell line (ESCC-DR) was established from a tumor induced in a rat model of gastroduodenal reflux. ESCC-DR cells were incubated with 2 mM TCA for ≥2 months. The effects of continuous TCA exposure were evaluated in vitro on cell morphology, growth, and invasion and in vivo on xenograft tumor growth in nude mice. Moreover, the mean level of secreted transforming growth factor (TGF)-β1 and vascular endothelial growth factor (VEGF) proteins in cell culture supernatants and mRNA synthesis of TGF-β1 and VEGF-A of ESCC cells were measured. The angiogenic potential was further examined by a migration assay using human umbilical vein endothelial cells (HUVECs).ResultsContinuous TCA exposure induced marked formation of filopodia in vitro. Expression levels of angiogenic factors were significantly higher in the cells treated with TCA than in control cells. Tumor xenografts derived from cells pre-exposed to TCA were larger and more vascularized than those derived from control cells. In addition, TCA exposure increased HUVEC migration.ConclusionContinuous TCA exposure enhanced ESCC progression due to reduced cell loss in vivo. Cell loss was inhibited by TCA-induced vascular endothelial cell migration, which was mediated by TGF-β1 and VEGF-A released from ESCC cells. | Perwaiz S, Tuchweber B, Mignault D, Gilat T, Yousef IM (2001)
Determination of bile acids in biological fluids by liquid chromatography-electrospray tandem mass spectrometry.
Journal of lipid research 42, 114-119 [PubMed:11160372]
[show Abstract]
A simple, sensitive, and specific liquid chromatography-electrospray tandem mass spectrometry (LC-MS/MS) method for the determination of bile acids in human bile has been developed. The bile acids were extracted with a C(18) (octadecyl) reversed-phase column and identified and quantified by simultaneous monitoring of their parent and daughter ions, using the multiple reaction monitoring mode. Identification and quantification of conjugated bile acids in bile was achieved in 5 min. The detection limit was 1 ng, and the determination was linear for concentrations up to 100 ng. The percent recovery of standards made of single conjugated (glycine and taurine) bile acid or of mixture of glycine- or taurine-conjugated cholic acid, chenodeoxycholic acid, deoxycholic acid, ursodeoxycholic acid, and lithocholic acid averaged 71.73% to 95.92%. The percent recovery of the same standard bile acids was also determined by gas chromatography-mass spectrometry (GC-MS), using the selected ion monitoring mode, and averaged 66% to 96%. A biliary bile acid profile of human gallbladder bile was obtained by LC-MS/MS and GC-MS. The results showed a good correlation between the two techniques and no significant differences between the two methods were observed. The LC-MS/MS method was also used for the analysis of serum, urine, and fecal bile acids. In conclusion, LC-MS/MS is a simple, sensitive, and rapid technique for the analysis of conjugated bile acids in bile and other biological samples. - Perwaiz, S., B. Tuchweber, D. Mignault, T. Gilat, and I. M. Yousef. Determination of bile acids in biological fluids by liquid chromatography-electrospray tandem mass spectrometry. J. Lipid Res. 2001. 42: 114;-119. |
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