Department of Gastroenterology and Hepatology, University Medical Center Groningen, University of Groningen, Groningen, The Netherlands.
Hepatology. 2010 Dec;52(6):2167-76. doi: 10.1002/hep.23954. Epub 2010 Nov 3.
Bile acid-CoA:amino acid N-acyltransferase (BAAT) conjugates bile salts to glycine or taurine, which is the final step in bile salt biosynthesis. In addition, BAAT is required for reconjugation of bile salts in the enterohepatic circulation. Recently, we showed that BAAT is a peroxisomal protein, implying shuttling of bile salts through peroxisomes for reconjugation. However, the subcellular location of BAAT remains a topic of debate. The aim of this study was to obtain direct proof for reconjugation of bile salts in peroxisomes. Primary rat hepatocytes were incubated with deuterium-labeled cholic acid (D(4)CA). Over time, media and cells were collected and the levels of D(4)CA, D(4)-tauro-CA (D(4)TCA), and D(4)-glyco-CA (D(4)GCA) were quantified by liquid chromatography-tandem mass spectrometry (LC/MS/MS). Subcellular accumulation of D(4)-labeled bile salts was analyzed by digitonin permeabilization assays and subcellular fractionation experiments. Within 24 hours, cultured rat hepatocytes efficiently (>90%) converted and secreted 100 μM D(4)CA to D(4)TCA and D(4)GCA. The relative amounts of D(4)TCA and D(4)GCA produced were dependent on the presence of glycine or taurine in the medium. Treatment of D(4)CA-exposed hepatocytes with 30-150 μg/mL digitonin led to the complete release of D(4)CA, D(4)GCA, and glyceraldehyde 3-phosphate dehydrogenase (GAPDH) (cytosolic marker). Full release of D(4)TCA, catalase, and BAAT was only observed at 500 μg/mL digitonin, indicating the presence of D(4)TCA in membrane-enclosed organelles. D(4)TCA was detected in fractions of purified peroxisomes, which did not contain D(4)CA and D(4)GCA.
We established a novel assay to study conjugation and intra- and transcellular transport of bile salts. Using this assay, we show that cholic acid shuttles through peroxisomes for taurine-conjugation.
胆汁酸-CoA:氨基酸 N-酰基转移酶(BAAT)将胆汁盐与甘氨酸或牛磺酸结合,这是胆汁盐生物合成的最后一步。此外,BAAT 是肠肝循环中胆汁盐再结合所必需的。最近,我们表明 BAAT 是一种过氧化物酶体蛋白,这意味着胆汁盐通过过氧化物酶体穿梭进行再结合。然而,BAAT 的亚细胞定位仍然是一个争论的话题。本研究的目的是为过氧化物体中胆汁盐的再结合提供直接证据。原代大鼠肝细胞与氘标记的胆酸(D(4)CA)孵育。随着时间的推移,收集培养基和细胞,并通过液相色谱-串联质谱法(LC/MS/MS)定量测定 D(4)CA、D(4)-牛磺酸-CA(D(4)TCA)和 D(4)-甘氨酸-CA(D(4)GCA)的水平。通过去氢胆酸钠渗透测定和亚细胞分级实验分析 D(4)-标记的胆汁盐的亚细胞积累。在 24 小时内,培养的大鼠肝细胞有效地(>90%)将 100 μM D(4)CA 转化并分泌为 D(4)TCA 和 D(4)GCA。产生的 D(4)TCA 和 D(4)GCA 的相对量取决于培养基中甘氨酸或牛磺酸的存在。用 30-150μg/ml 去氢胆酸钠处理暴露于 D(4)CA 的肝细胞,导致 D(4)CA、D(4)GCA 和甘油醛 3-磷酸脱氢酶(GAPDH)(胞质标记物)完全释放。仅在用 500μg/ml 去氢胆酸钠处理时才观察到 D(4)TCA、过氧化氢酶和 BAAT 的完全释放,表明 D(4)TCA 存在于膜封闭的细胞器中。D(4)TCA 存在于纯化的过氧化物体级分中,该级分中不含有 D(4)CA 和 D(4)GCA。
我们建立了一种新的测定方法来研究胆汁盐的结合和细胞内及细胞间转运。使用该测定法,我们表明胆酸通过过氧化物体穿梭进行牛磺酸结合。
