豇豆花叶病毒移动蛋白中的不同功能结构域。
Distinct functional domains in the cowpea mosaic virus movement protein.
作者信息
Lekkerkerker A, Wellink J, Yuan P, van Lent J, Goldbach R, van Kammen A B
机构信息
Department of Molecular Biology, Agricultural University, The Netherlands.
出版信息
J Virol. 1996 Aug;70(8):5658-61. doi: 10.1128/JVI.70.8.5658-5661.1996.
Abstract
Cell-to-cell movement of cowpea mosaic virus particles in plants takes place with the help of tubules that penetrate presumably modified plasmodesmata. These tubules, which are built up by the virus-encoded 48-kDa movement protein (MP), are also formed on single protoplast cells. To determine whether the MP contains different functional domains, the effect of mutations in its coding region was studied. Mutations between amino acids 1 and 313 led to complete abolishment of the tubule-forming capacity, while a deletion in the C-terminal region resulted in tubules that could not take up virus particles. From these observations, it is concluded that the MP contains at least two distinct domains, one that is involved in tubule formation and that spans amino acids 1 and 313 and a second that is probably involved in the incorporation of virus particles in the tubule and that is located in the C terminus between amino acids 314 and 331.
摘要
豇豆花叶病毒粒子在植物中的细胞间移动是借助穿透可能经过修饰的胞间连丝的小管来实现的。这些由病毒编码的48 kDa运动蛋白(MP)构建而成的小管,也会在单个原生质体细胞上形成。为了确定MP是否包含不同的功能结构域,研究了其编码区突变的影响。氨基酸1至313之间的突变导致小管形成能力完全丧失,而C端区域的缺失则导致形成的小管无法摄取病毒粒子。从这些观察结果可以得出结论,MP至少包含两个不同的结构域,一个参与小管形成,跨度为氨基酸1至313,另一个可能参与病毒粒子在小管中的掺入,位于氨基酸314至331之间的C端。
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