Hepatitis E virus derived from different sources exhibits different behaviour in virus inactivation and/or removal studies with plasma derivatives.

Hepatitis E virus (HEV) causes viral hepatitis, and is considered a risk factor for blood products. Although some HEV inactivation/removal studies have been reported, detailed investigations of different manufacturing steps as heat treatment, partitioning during cold ethanol fractionation, low pH treatment, and virus filtration have yet to be reported for plasma-derived medicinal products. In this study, human serum- and swine faeces-derived HEVs, with and without detergent treatment, were used. The kinetic patterns of inactivation, log reduction value, or partitioning during the process were evaluated. In addition, the mouse encephalomyocarditis virus (EMCV) and canine and porcine parvoviruses (CPV/PPV) were also evaluated as model viruses for HEV. Small pore size (19 or 15 nm) virus filtration demonstrated effective removal of HEV. Middle pore size (35 nm) virus filtration and 60 °C liquid heating demonstrated moderate inactivation/removal. Ethanol fractionation steps demonstrated limited removal of HEV. Unpurified HEV exhibited different properties than the detergent-treated HEV, and both forms displayed differences when compared with EMCV, CPV, and PPV. Limited or no inactivation of HEV was observed during low pH treatment. Untreated plasma-derived HEV from humans showed different properties compared to that of HEV treated with detergent or derived from swine faeces. Therefore, HEV spike preparation requires more attention.

RNA interfering approach for clarifying the PPARgamma pathway using lentiviral vector expressing short hairpin RNA.

Peroxisome proliferator-activated receptor gamma (PPARgamma) plays a central role in adipocyte differentiation and insulin sensitivity. Although PPARgamma also appears to regulate diverse cellular processes in other cell types such as lymphocytes, the detailed mechanisms remain unclear. In this study, we established a lentivirus-mediated short hairpin RNA expression system and identified a potent short hairpin RNA which suppresses PPARgamma expression, resulting in marked inhibition of preadipocyte-to-adipocyte differentiation in 3T3-L1 cells. Our PPARgamma-knockdown method will serve to clarify the PPARgamma pathway in various cell types in vivo and in vitro, and will facilitate the development of therapeutic applications for a variety of diseases.

Enhanced in vivo gene transfer into the placenta using RGD fiber-mutant adenovirus vector.

Among viral vectors, the fiber-mutant adenovirus vector carrying the Arg-Gly-Asp (RGD) peptide sequence (Ad-RGD) seems to have potential for both clinical gene therapy and basic research. As a part of a thorough evaluation of Ad-RGD in preclinical studies, we designed an experiment to investigate in detail the distribution of Ad-RGD compared with conventional adenovirus vector (WT-Ad) in pregnant mice. Surprisingly, Ad-RGD had substantial placental tropism, at 10-100 times that of WT-Ad. Transgene expression was sustained for at least 7 days, and Ad-RGD expressing firefly luciferase or red fluorescent protein has so far caused no placental dysfunction leading to fetal death. Ad-RGD showed high levels of transduction efficiency in in vitro-differentiated trophoblast stem cells, in which higher expression of αvß3 integrin than in undifferentiated cells was observed. Our results suggest that the use of Ad-RGD or another RGD-mediated targeting strategy holds promise for drug delivery to the placenta.