Marks D L, LaRusso N F, McNiven M A
Center for Basic Research in Digestive Diseases, Mayo Clinic, Rochester, Minnesota.
Gastroenterology. 1995 Mar;108(3):824-33. doi: 10.1016/0016-5085(95)90457-3.
BACKGROUND/AIMS: Vesicular transport is supported by microtubule-based, force-transducing adenosine triphosphatases (ATPases), such as kinesin, a ubiquitous motor enzyme that has been well studied in neuronal tissues. Although vesicular transport is important for hepatocellular secretory and clearance activities, the role of kinesin in liver function is poorly understood. Furthermore, the effects of bile acids on kinesin are unknown.
Kinesin was purified from rat liver cytosol by conventional chromatography and microtubule affinity binding and was characterized by immunoblotting with domain-specific kinesin antibodies and amino acid sequencing of tryptic fragments. Kinesin activity was measured with and without bile acids using an in vitro motility assay and ATPase assays.
Immunoblot analysis and partial amino acid sequencing of purified kinesin showed that the sequence at the heavy chain of hepatic kinesin is nearly identical to that of brain kinesin. Purified kinesin transported microtubules in vitro with a velocity of approximately 0.5 microns/s; this activity was significantly inhibited by 0.5-1 mmol/L taurochenodeoxycholate but not by tauroursodeoxycholate. At a dose of 1 mmol/L, chenodeoxycholate conjugates, but not ursodeoxycholate or cholate conjugates, directly inhibited the ATPase activities of kinesin and another microtubule motor, cytoplasmic dynein.
Cholestatic concentrations of chenodeoxycholate conjugates directly inhibit the activity of microtubule motors, suggesting a possible mechanism for impairment of vesicular transport in cholestasis.
背景/目的:囊泡运输由基于微管的、能传递力的三磷酸腺苷酶(ATP酶)支持,如驱动蛋白,这是一种在神经组织中已得到充分研究的普遍存在的运动酶。尽管囊泡运输对肝细胞的分泌和清除活动很重要,但驱动蛋白在肝功能中的作用却知之甚少。此外,胆汁酸对驱动蛋白的影响尚不清楚。
通过常规色谱法和微管亲和结合从大鼠肝脏胞质溶胶中纯化驱动蛋白,并用结构域特异性驱动蛋白抗体进行免疫印迹和胰蛋白酶片段的氨基酸测序对其进行表征。使用体外运动分析和ATP酶分析测量有无胆汁酸时的驱动蛋白活性。
纯化的驱动蛋白的免疫印迹分析和部分氨基酸测序表明,肝脏驱动蛋白重链的序列与脑驱动蛋白的序列几乎相同。纯化的驱动蛋白在体外以约0.5微米/秒的速度运输微管;这种活性被0.5 - 1毫摩尔/升的牛磺鹅去氧胆酸盐显著抑制,但不被牛磺熊去氧胆酸盐抑制。在1毫摩尔/升的剂量下,鹅去氧胆酸盐共轭物而非熊去氧胆酸盐或胆酸盐共轭物直接抑制驱动蛋白和另一种微管运动蛋白胞质动力蛋白的ATP酶活性。
鹅去氧胆酸盐共轭物的胆汁淤积浓度直接抑制微管运动蛋白的活性,提示胆汁淤积中囊泡运输受损的一种可能机制。
