ABSTRACT
ABSTRACT Hepatitis C Virus belongs to the Flaviviridae family. One proposed mechanism of HCV persistence in the ability to infect hematopoietic cells, including Dendritic cells (DCs). HCV infection of DCs could impair their functions that represent one of the mechanisms, thus hampering viral clearance by the host immune system. Among HCV-encoded proteins, the highly conserved Core protein has been suggested to be responsible for the immunomodulatory properties of this Hepacivirus. Recombinant viral vectors expressing the HCV Core protein and allowing its transduction and therefore the expression of the protein into DCs could be useful tools for the analysis of the properties of the Core protein. Vaccinia Virus and retrovirus have been used to transduce human DCs. Likewise, gene transfer into DCs using Semliki Forest Virus has been reported. This study aimed to express the HCV Core protein in human monocyte-derived DCs using an SFV vector, in which the subgenomic RNA encoding the structural proteins was replaced by the HCV Core sequence and then analyze the effects of its expression on DCs functions.
RESUMEN El virus de la Hepatitis C (VHC) pertenece a la familia Flaviviridae. Uno de los mecanismos propuestos de la persistencia del VHC es la capacidad de infectar células hematopoyéticas, incluidas las células dendríticas (DCs). La infección por VHC de DCs podría alterar sus funciones y corresponde a uno de los mecanismos que impiden el aclaramiento de la infección por VHC por el sistema inmunitario del hospedero. Entre las proteínas codificadas por el VHC, se ha sugerido que la proteína Core, altamente conservada, es responsable de las propiedades inmunomoduladoras de este Hepacivirus. Los vectores virales recombinantes que expresan la proteína Core y permiten su transducción a DCs podrían ser herramientas útiles para el análisis de las propiedades de esta proteína. El virus Vaccinia y el retrovirus se han utilizado para la transducción de DCs humanas. Del mismo modo, la transducción de DCs usando el virus del bosque de Semliki ha sido reportada. El objetivo de este estudio fue expresar la proteína Core de VHC en DCs derivadas de monocitos humanos utilizando un vector de SFV, en el que el ARN subgenómico que codifica las proteínas estructurales fue reemplazado por la secuencia Core del VHC y evaluar los efectos de su expresión en las funciones de DCs.
ABSTRACT
The number of biopharmaceuticals for medical and veterinarian use produced in mammalian cells is increasing year after year. All of them are obtained by stable recombinant cell lines. However, it is recognized that transient gene expression produces high level expression in a short time. In that sense, viral vectors have been extensively used for producing recombinant proteins on lab-scale. Among them, Semliki Forest virus is commonly employed for this purpose. This review discusses the main aspects related to the use of Semliki Forest virus technology as well as its advantages and drawbacks which limit currently its utilization in biopharmaceutical industry on large-scale.
ABSTRACT
The ORF5 gene encodes a major envelope glycoprotein (GP5), which is one of the three major proteins of porcine reproductive and respiratory syndrome virus (PRRSV). The GP5 protein has been known to be a 24.5-26kDa N-glycosylated envelope protein. The GP5 is involved in inducing neutralizing antibodies. For this reason, the GP5 is primary candidate for the PRRSV subunit vaccine. To produce the native form of GP5 in mammalian cells, we have cloned the ORF5 gene from PRRSV CNV-1 into the Semliki Forest virus (SFV)-based expression vector, resulting in recombinant pSFV-ORF5. By the infection with recombinant pSFV-ORF5 to BHK-21 cells, the GP5 expression was confirmed by immunocytochemistry and immunoblotting assay. The recombinant virus particle harboring ORF5 gene was infectious to BHK-21 and MARC-145. The RNA synthesis and expression of GP5 in the infected cell was also confirmed by RT-PCR.