蛙视网膜光感受器细胞中视紫红质在高尔基体后膜上的极化分选。
Polarized sorting of rhodopsin on post-Golgi membranes in frog retinal photoreceptor cells.
作者信息
Deretic D, Papermaster D S
机构信息
Department of Pathology, University of Texas Health Science Center, San Antonio 78284-7750.
出版信息
J Cell Biol. 1991 Jun;113(6):1281-93. doi: 10.1083/jcb.113.6.1281.
Abstract
We have isolated a subcellular fraction of small vesicles (mean diameter, 300 nm) from frog photoreceptors, that accumulate newly synthesized rhodopsin with kinetics paralleling its appearance in post-Golgi membranes in vivo. This fraction is separated from other subcellular organelles including Golgi and plasma membranes and synaptic vesicles that are sorted to the opposite end of the photoreceptor cell. The vesicles have very low buoyant density in sucrose gradients (rho = 1.09 g/ml), a relatively simple protein content and an orientation of rhodopsin expected of transport membranes. Reversible inhibition of transport by brefeldin A provides evidence that these vesicles are exocytic carriers. Specific immunoadsorption bound vesicles whose protein composition was indistinguishable from the membranes sedimented from the subcellular fraction. Some of these proteins may be cotransported with rhodopsin to the rod outer segment; others may be involved in vectorial transport.
摘要
我们从青蛙光感受器中分离出了一种小囊泡的亚细胞组分(平均直径300纳米),这些小囊泡能积累新合成的视紫红质,其动力学过程与视紫红质在体内高尔基体后膜中的出现情况相似。该组分与其他亚细胞细胞器分离,包括高尔基体、质膜和被分选到光感受器细胞另一端的突触小泡。这些囊泡在蔗糖梯度中的浮力密度非常低(ρ = 1.09克/毫升),蛋白质含量相对简单,并且视紫红质的取向符合转运膜的预期。布雷菲德菌素A对转运的可逆抑制提供了证据,表明这些囊泡是胞吐载体。特异性免疫吸附结合的囊泡,其蛋白质组成与从亚细胞组分中沉淀的膜无法区分。其中一些蛋白质可能与视紫红质共同转运到视杆外段;其他蛋白质可能参与向量运输。
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