Ohashi Makoto, Horie Kazutaka, Hoshikawa Yoshiko, Nagata Keiko, Osaki Mistuhiko, Ito Hisao, Sairenji Takeshi
Division of Biosignaling, Department of Biomedical Science, School of Life Science, Faculty of Medicine, Tottori University, 86 Nishi-cho, Yonago 683-8503, Japan.
Microbes Infect. 2007 Feb;9(2):150-9. doi: 10.1016/j.micinf.2006.11.001. Epub 2006 Nov 29.
As a new model to elucidate molecular mechanisms in Epstein-Barr virus (EBV) activation, we tested the tetracycline-inducible (Tet-On)/BZLF1-oriP plasmid system in Raji cells. Cells transfected with this Tet-On plasmid did not activate EBV by doxycycline and surprisingly EBV latency was disrupted with large amounts of BMRF1 protein (EA-D) being accumulated in the cells. Brilliant EA-D fluorescence was markedly condensed in small sized cells, intra-cellular vesicles, and extra-cellular particles. Scanning electron microscopy demonstrated the extra-cellular particles to be covered with a membrane. EA-D molecules of 58, 50, 48, and 44kDa were expressed in the cells. The high (58 and 50kDa) and low (48 and 44kDa) EA-D molecules appeared in the early and late stages, respectively. Low EA-D molecules were detected mostly in EA-D positive cells separated into the heaviest density layer of a discontinuous Percoll gradient. Such molecules could be created from high EA-D molecules by protein phosphatase treatment. The EA-D molecules that appeared similar were detected in EBV-activated P3HR-1 and Akata cells. Several hypotheses concerning the accumulation of EA-D molecules of various polymorphic forms and their phosphorylation/dephosphorylation in this model system are presented, with possible biological and clinical relevance.
作为阐明爱泼斯坦-巴尔病毒(EBV)激活分子机制的一种新模型,我们在Raji细胞中测试了四环素诱导型(Tet-On)/BZLF1-oriP质粒系统。用这种Tet-On质粒转染的细胞不会因强力霉素而激活EBV,令人惊讶的是,EBV潜伏期被破坏,大量BMRF1蛋白(EA-D)在细胞中积累。明亮的EA-D荧光明显聚集在小尺寸细胞、细胞内囊泡和细胞外颗粒中。扫描电子显微镜显示细胞外颗粒被膜覆盖。细胞中表达了58、50、48和44kDa的EA-D分子。高(58和50kDa)和低(48和44kDa)EA-D分子分别出现在早期和晚期。低EA-D分子大多在分离到不连续Percoll梯度最重密度层的EA-D阳性细胞中检测到。通过蛋白磷酸酶处理,这些分子可以由高EA-D分子产生。在EBV激活的P3HR-1和Akata细胞中检测到了相似的EA-D分子。本文提出了关于该模型系统中各种多态形式的EA-D分子积累及其磷酸化/去磷酸化的几种假设,并探讨了其可能的生物学和临床意义。
