Eight members of the HSP/HSC70 family were identified in Spodoptera frugiperda Sf9 cells infected with Autographa californica multiple nucleopolyhedrovirus (AcMNPV) by 2D electrophoresis followed by mass spectrometry (MALDI/TOF) and a Mascot search. The family includes five HSP70s induced by AcMNPV-infection and three constitutive cognate HSC70s that remained abundant in infected cells. Confocal microscopy revealed dynamic changes in subcellular localization of HSP/HSC70s in the course of infection. At the early stages (4 to 10 hpi), a fraction of HSPs is localized in distinct speckles in cytoplasm. The speckles contained ubiquitinylated proteins suggesting that they may be aggresomes where proteins targeted by ubiquitin are sequestered or processed for proteolysis. S. frugiperda HSP90 was identified in the 2D gels by Western blotting. Its amount was unchanged during infection. A selective inhibitor of HSP90, 17-AAG, decreased the rate of viral DNA synthesis in infected cells suggesting a supportive role of HSP90 in virus replication.
The hepatitis C virus (HCV) envelope proteins E1 and E2, being virion
components, are involved in the formation of infectious particles in infected
cells. The detailed structure of the infectious particle of HCV remains poorly
understood. Moreover, the virion assembly and release of virions by the cell
are the least understood processes. It is believed that virion properties
depend on glycosylation of the virus envelope proteins in a cell, while
glycansat several glycosylation sites of these proteins play a pivotal role in
protein functioning and the HCV life cycle. N-glycans of glycoproteins can
influence viral particle formation, virus binding to cell surface, and HCV
pathogenesis. We studied the effect of glycans on the folding ofthe E2
glycoprotein, formation of functional glycoprotein complexes and virus
particles in insect and mammalian cells. In order to investigate these
processes, point mutations of the N-glycosylation sites of HCV protein E2
(genotype 1b strain 274933RU) were generated and the mutant proteins were
further analyzed in the baculovirus expression system. Elimination of the
single glycosylation sites of the E2 glycoprotein, except for the N6 site, did
not affect its synthesis efficiency in Sf9 insect cells, while the
electrophoretic mobility of mutant proteins increased in proportion to the
decrease in the number of glycosylation sites. The level of synthesis of HCV
glycoprotein E2 in human HEK293T cells depended on the presence of glycans at
the N1 and N8 glycosylation sites in contrast to Sf9 cells. At the same time,
elimination of glycans at the N1, N2, and N10 sites led to the accumulation of
unproductive E1E2 dimers as aggregates and productive assembly suppression of
virus-like particles both in insect and mammalian cells. In addition,
elimination of single glycosylation sites of HCV E2 had no impact on the RNA
synthesis of structural proteins and formation of virus-like particles in
insect and mammalian cells.
Baculovirus AcMNPV causes proteotoxicity in Sf9 cells as revealed by accumulation of ubiquitinated proteins and aggresomes in the course of infection. Inhibition of proteasomes by lactacystin increased markedly the stock of ubiquitinated proteins indicating a primary role of proteasomes in detoxication. The proteasomes were present in Sf9 cells as 26S and 20S complexes whose protease activity did not change during infection. Proteasome inhibition caused a delay in the initiation of viral DNA replication suggesting an important role of proteasomes at early stages in infection. However, lactacystin did not affect ongoing replication indicating that active proteasomes are not required for genome amplification. At late stages in infection (24-48 hpi), aggresomes containing the ubiquitinated proteins and HSP/HSC70s showed gradual fusion with the vacuole-like structures identified as lysosomes by antibody to cathepsin D. This result suggests that lysosomes may assist in protection against proteotoxicity caused by baculoviruses absorbing the ubiquitinated proteins.
Hepatitis C virus (HCV) is characterized by considerable genetic variability and, as a consequence, it has 6 genotypes and multitude of subtypes. HCV envelope glycoproteins are involved in the virion formation; the correct folding of these proteins plays the key role in virus infectivity. Glycosylation at certain sites of different genotypes HCV glycoproteins shows substantial differences in functions of the individual glycans (Goffard et al., 2005; Helle et al., 2010) [1], [2]. In this study, differential glycosylation sites of HCV genotype 1b envelope proteins in insect and mammalian cells was demonstrated. We showed that part of glycosylation sites was important for folding of the proteins involved in the formation of viral particles. Point mutations were introduced in the protein N-glycosylation sites of HCV (genotype 1b) and the mutant proteins were analyzed using baculovirus expression system in mammalian and insect cells. Our data showed that, in contrast to HCV 1a and 2a, the folding of HCV 1b envelope proteins E2 (sites N1, N2, N10) and E1 (sites N1, N5) was disrupted, however that did not prevent the formation of virus-like particles (VLP) with misfolded glycoproteins having densities typical for HCV particles containing RNA fragments. Experimental data are supported by mathematical modeling of the structure of E1 mutant variants.
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