Hepatitis B virus (HBV) enters the host and survives by using several mechanisms. One of the ways that HBV survives and replicates in the host cells is by inducing autophagy. Previous reports have shown that microRNA (miRNA)-30a inhibits autophagosome formation in cancer cells. Hence, we hypothesized that overexpression of miRNA-30a could inhibit HBVinduced autophagosome formation in hepatic cells. To study this, both HepG2 cells and HepG2.2.1.5 cells (HBV-expressing stable cell line) were transfected with miRNA-30a, and the cells were collected either for RNA isolation or protein isolation after 72 h of transfection. Beclin-1 expression was significantly higher in untransfected HepG2.2.1.5 cells than in HepG2 cells. Western blots showed that miRNA-30a overexpression resulted in a significant decrease in beclin-1 expression (eight-fold and four-fold in HepG2 and HepG2.2.1.5 cells, respectively) and c-myc expression, whereas the numbers of terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling (TUNEL)-positive cells were increased. In contrast, overexpression of HBV X protein (HBx) in HepG2 cells resulted in the enhancement of beclin-1 (six-fold increase as compared with the empty vector-transfected cells) and c-myc expression, whereas the numbers of TUNEL-positive cells were reduced. To confirm these findings, HBx and miRNA-30a were coexpressed in HepG2 cells, and the results showed significant inhibition of autophagosome formation and beclin-1 and c-myc expression, whereas apoptosis increased. These data demonstrate that HBx induces autophagosome formation via beclin-1 expression, whereas miRNA-30a overexpression could successfully inhibit the beclin-1 expression induced by HBx, thereby modulating autophagosome formation in hepatic cells.
RNAi is an evolutionarily fluid mechanism with dramatically different activities across animal phyla. One major group where there has been little investigation is annelid worms. Here, the small RNAs of the polychaete developmental model Capitella teleta are profiled across development. As is seen with nearly all animals, nearly 200 microRNAs were found with 58 high-confidence novel species. Greater miRNA diversity was associated with later stages consistent with differentiation of tissues. Outside miRNA, a distinct composition of other small RNA pathways was found. Unlike many invertebrates, an endogenous siRNA pathway was not observed, indicating pathway loss relative to basal planarians. No processively generated siRNA-class RNAs could be found arising from dsRNA precursors. This has a significant impact on RNAi technology development for this group of animals. Unlike the apparent absence of siRNAs, a significant population of piRNAs was observed. For many piRNAs, phasing and ping-pong biogenesis pathways were identified. Interestingly, piRNAs were found to be highly expressed during early development, suggesting a potential role in regulation in metamorphosis. Critically, the configuration of RNAi factors in C. teleta is found in other annelids and mollusks, suggesting that similar biology is likely to be present in the wider clade. This study is the first in providing comprehensive analysis of small RNAs in annelids.
RNAi is an evolutionarily fluid mechanism with dramatically different activities across animal phyla. One major group where there has been little investigation is annelid worms. Here the small RNAs of the polychaete developmental model, Capitella teleta, are profiled across development. As is seen with nearly all animals, nearly 200 hundred microRNAs were found with 58 high confidence novel species. Greater miRNA diversity was associated with later stages consistent with differentiation of tissues. Outside miRNA, a distinct composition of other small RNA pathways was found. Unlike many invertebrates, an endogenous siRNA pathway was not observed, indicating pathway loss relative to basal planarians. No processively generated siRNA‐class RNAs could be found arising from dsRNA precursors. This has significant impact on RNAi technology development for this group of animals. Unlike the apparent absence of siRNAs, a significant population of piRNAs were observed. For many piRNAs phasing and ping pong biogenesis pathways were identified. Interestingly, piRNAs were found to be highly expressed during early development, suggesting a potential role in regulation in metamorphosis. Critically, the configuration of RNAi factors in C. teletais found in other annelids and mollusks, suggesting that similar biology is likely present in the wider clade. This study is the first providing comprehensive analysis of small RNAs in annelids.
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