Storlie Johnathan, Jackson Wallen, Hutchinson Jennifer, Grose Charles
University Hospital/2501 JCP, 200 Hawkins Dr., Iowa City, IA 52242, USA.
J Virol. 2006 Oct;80(19):9544-56. doi: 10.1128/JVI.00668-06.
In the course of examining the trafficking pathways of varicella-zoster virus (VZV) glycoproteins gE, gI, gH, and gB, we discovered that all four are synthesized within 4 to 6 h postinfection (hpi) in cultured cells. Thereafter, they travel via the trans-Golgi network to the outer cell membrane. When we carried out a similar analysis on VZV gC, we observed little gC biosynthesis in the first 72 hpi. Further examination disclosed that gC was present in the inocula of infected cells, but no new gC biosynthesis occurred during the first 24 to 48 h thereafter, during which time new synthesis of gE, gH, and major capsid protein was easily detectable. Similarly, delayed gC biosynthesis was confirmed with three different VZV strains and two different cell lines. Bioinformatics analyses disclosed the presence of PBX/HOX consensus binding domains in the promoter/enhancer regions of the genes for VZV gC and ORF4 protein (whose orthologs transactivate gC in other herpesviruses). Bioinformatics analysis also identified two HOXA9 activation regions on ORF4 protein. Treatment of infected cultures with chemicals known to induce the production of PBX/HOX transcription proteins, namely, hexamethylene bisacetamide (HMBA) and retinoic acid, led to more rapid gC biosynthesis. Immunoblotting demonstrated a fivefold increase in the HOXA9 protein after HMBA treatment. In summary, these results documented that gC was not produced during early VZV replication cycles, presumably related to a deficiency in the PBX/HOX transcription factors. Furthermore, these results explain the apparent spontaneous loss of VZV gC in some passaged viruses, as well as other anomalous gC results.
在研究水痘带状疱疹病毒(VZV)糖蛋白gE、gI、gH和gB的运输途径过程中,我们发现这四种糖蛋白在感染后4至6小时(hpi)内在培养细胞中合成。此后,它们通过反式高尔基体网络运输到细胞外膜。当我们对VZV gC进行类似分析时,我们观察到在感染后最初72小时内gC生物合成很少。进一步检查发现gC存在于感染细胞的接种物中,但在随后的24至48小时内没有新的gC生物合成,在此期间gE、gH和主要衣壳蛋白的新合成很容易检测到。同样,用三种不同的VZV毒株和两种不同的细胞系证实了gC生物合成延迟。生物信息学分析揭示了VZV gC和ORF4蛋白(其直系同源物在其他疱疹病毒中反式激活gC)基因的启动子/增强子区域存在PBX/HOX共有结合域。生物信息学分析还在ORF4蛋白上鉴定出两个HOXA9激活区域。用已知可诱导PBX/HOX转录蛋白产生的化学物质,即六亚甲基双乙酰胺(HMBA)和视黄酸处理感染培养物,导致gC生物合成更快。免疫印迹显示HMBA处理后HOXA9蛋白增加了五倍。总之,这些结果证明在VZV早期复制周期中不产生gC,推测与PBX/HOX转录因子的缺乏有关。此外,这些结果解释了一些传代病毒中VZV gC明显的自发丢失以及其他异常的gC结果。