血脑屏障中的内皮小泡:它们与通透性有关吗?
Endothelial vesicles in the blood-brain barrier: are they related to permeability?
作者信息
Stewart P A
机构信息
Department of Surgery, University of Toronto, Ontario, Canada.
出版信息
Cell Mol Neurobiol. 2000 Apr;20(2):149-63. doi: 10.1023/a:1007026504843.
Abstract
- Macromolecules cross capillary walls via large vascular pores that are thought to be formed by plasmalemmal vesicles. Early hypotheses suggested that vesicles transferred plasma constituents across the endothelial wall either by a "shuttle" mechanism or by fusing to form transient patent channels for diffusion. Recent evidence shows that the transcytotic pathway involves both movement of vesicles within the cell and a series of fusions and fissions of the vesicular and cellular membranes. 2. The transfer of macromolecules across the capillary wall is highly specific and is mediated by receptors incorporated into specific membrane domains. Therefore, despite their morphological similarity, endothelial vesicles from heterogeneous populations in which the predominant receptor proteins incorporated in their membranes define the functions of individual vesicles. 3. Blood-brain barrier capillaries have very low permeabilities to most hydrophilic molecules. Their low permeability to macromolecules has been presumed to be due to an inhibition of the transcytotic mechanism, resulting in a low density of endothelial vesicles. 4. A comparison of vesicular densities and protein permeabilities in a number of vascular beds shows only a very weak correlation, therefore vesicle numbers alone cannot be used to predict permeability to macromolecules. 5. Blood-brain barrier capillaries are fully capable of transcytosing specific proteins, for example, insulin and transferrin, although the details are still somewhat controversial. 6. It has recently been shown that the albumin binding protein gp60 (also known as albondin), which facilitates the transcytosis of native albumin in other vascular beds, is virtually absent in brain capillaries. 7. It seems likely that the low blood-brain barrier permeability to macromolecules may be due to a low level of expression of specific receptors, rather than to an inhibition of the transcytosis mechanism.
摘要
- 大分子通过被认为由质膜小泡形成的大血管孔穿过毛细血管壁。早期假说是,小泡通过“穿梭”机制或融合形成瞬时开放通道进行扩散,从而在内皮壁上转运血浆成分。最近的证据表明,转胞吞途径既涉及小泡在细胞内的移动,也涉及小泡膜和细胞膜的一系列融合与裂变。2. 大分子穿过毛细血管壁的转运具有高度特异性,且由整合到特定膜结构域的受体介导。因此,尽管不同群体的内皮小泡形态相似,但膜中主要受体蛋白决定了单个小泡的功能。3. 血脑屏障毛细血管对大多数亲水分子的通透性非常低。其对大分子的低通透性被认为是由于转胞吞机制受到抑制,导致内皮小泡密度较低。4. 对多个血管床中小泡密度和蛋白质通透性的比较显示,两者之间的相关性非常弱,因此仅小泡数量不能用于预测对大分子的通透性。5. 血脑屏障毛细血管完全有能力转胞吞特定蛋白质,例如胰岛素和转铁蛋白,尽管具体细节仍存在一定争议。6. 最近发现,促进天然白蛋白在其他血管床中转胞吞的白蛋白结合蛋白gp60(也称为albondin)在脑毛细血管中几乎不存在。7. 血脑屏障对大分子的低通透性似乎可能是由于特定受体的低表达水平,而非转胞吞机制受到抑制。
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