A novel cellular protein, VPEF, facilitates vaccinia virus penetration into HeLa cells through fluid phase endocytosis.

Vaccinia virus is a large DNA virus that infects many cell cultures in vitro and animal species in vivo. Although it has been used widely as a vaccine, its cell entry pathway remains unclear. In this study, we showed that vaccinia virus intracellular mature virions bound to the filopodia of HeLa cells and moved toward the cell body and entered the cell through an endocytic route that required a dynamin-mediated pathway but not a clathrin- or caveola-mediated pathway. Moreover, virus penetration required a novel cellular protein, vaccinia virus penetration factor (VPEF). VPEF was detected on cell surface lipid rafts and on vesicle-like structures in the cytoplasm. Both vaccinia virus and dextran transiently colocalized with VPEF, and, importantly, knockdown of VPEF expression blocked vaccinia virus penetration as well as intracellular transport of dextran, suggesting that VPEF mediates vaccinia virus entry through a fluid uptake endocytosis process in HeLa cells. Intracellular VPEF-containing vesicles did not colocalize with Rab5a or caveolin but partially colocalized with Rab11, supporting the idea that VPEF plays a role in vesicle trafficking and recycling in HeLa cells. In summary, this study characterized the mechanism by which vaccinia virus enters HeLa cells and identified a cellular factor, VPEF, that is exploited by vaccinia virus for cell entry through fluid phase endocytosis.

Genetic characterization of fas-associated phosphatase-1 as a putative tumor suppressor gene on chromosome 4q21.3 in hepatocellular carcinoma.

PURPOSE: Allelic loss at chromosome 4q21-23 occurs frequently in human hepatocellular carcinoma, and the putative tumor suppressor gene (TSG) has not yet been identified. We studied the Fas-associated phosphatase-1 (FAP-1) gene as a potential candidate TSG in this region. EXPERIMENTAL DESIGN: The expression level of FAP-1 RNA in hepatocellular carcinomas was evaluated by RNase protection and quantitative PCR. Sodium bisulfite modification and subsequent single-strand conformational polymorphism and sequence analyses were used to assay the methylation of CpGs at FAP-1 promoter. Direct sequencing of the FAP-1 coding region was conducted for detecting the genetic mutations. Two common single nucleotide polymorphisms of FAP-1 were selected for evaluating their association with the hepatocellular carcinoma trait in sporadic and familial hepatocellular carcinomas. Moreover, the functional effect of FAP-1 on cellular proliferation has been evaluated by small interfering RNA approach. RESULTS: Around 50% of hepatocellular carcinomas showed significantly decreased expression of FAP-1 compared with the corresponding nontumorous liver tissues. In most cases, the RNA level was well correlated with the methylation status of promoter CpGs, suggesting that the promoter methylation may contribute to the down-regulation. Several genetic mutations of FAP-1 have been identified in hepatocellular carcinomas. The G/G genotype of FAP-1 cSNP6304 was significantly associated with the increased risk of multiplex familial hepatocellular carcinomas (odds ratio, 2.44; 95% confidence interval, 1.19-5.01). Finally, knockdown expression of FAP-1 was shown to enhance the cellular proliferation in PLC5 cells. CONCLUSIONS: FAP-1 could be inactivated during hepatocarcinogenesis, mainly attributed by allelic loss and promoter methylation. The genetic mutations and polymorphisms may also confront with the higher hepatocellular carcinoma risk. These results first suggested FAP-1 as a putative TSG in hepatocarcinogenesis.