Background: The incidence of non-B non-C hepatocellular carcinoma (NBNC-HCC), which is negative for hepatitis B surface antigen and hepatitis C virus antibodies, is on the rise. Relatively high numbers of NBNC-HCC patients are hepatitis B core antibody (HBcAb) positive, suggesting that previous HBV infection may play a role in NBNC-HCC development, though the exact mechanisms are unclear. This study aimed to investigate whether HBV genomes are integrated into the host genome of HBcAb-positive NBNC-HCC cases and how these integrations may contribute to cancer development and progression. Methods: HBV detection PCR using HBV-specific primers on DNA extracted from HBcAb-positive NBNC-HCC tissue samples was performed. Positive samples were further examined for HBV integration sites using viral DNA-capture sequencing. Additionally, hepatitis B core-related antigen (HBcrAg) serum levels were measured to assess whether they could be predictive for HBV detection PCR results. Results: Among 90 HBcAb-positive NBNC-HCC samples, HBV genome amplification was detected in 18 samples, and elevated HBcrAg levels were associated with the HBV detection PCR results. Seventeen of these samples exhibited HBV integration. The HBV genome was integrated near the TERT gene in 7 samples, resulting in significantly increased TERT mRNA levels; in the KMT2B gene (2 samples); and downstream of LOC441666 (2 samples). Conclusion: The integration sites we identified in our samples have been previously reported in HBV-related HCC, suggesting that HBV integration may also contribute to hepatocarcinogenesis in HBcAb-positive NBNC-HCC. Furthermore, HBcrAg could serve as a potential, noninvasive marker for detecting HBV integration in these cases.
RNA silencing is a prominent antiviral defense mechanism in plants. When infected with a virus, RNA silencing-deficient plants tend to show exacerbated symptoms along with increased virus accumulation. However, how symptoms are exacerbated is little understood. Here, we investigated the role of the copper chaperon for superoxide dismutase (CCS) 1, in systemic necrosis observed in Argonaute (AGO)2-silenced tomato plants infected with potato virus X (PVX). While infection with the UK3 strain of PVX induced mosaic symptoms in tomato plants, systemic necrosis occurred when AGO2 was silenced. The CCS1 mRNA level was reduced and micro RNA398 (miR398), which potentially target CCS1, was increased in AGO2-knockdown tomato plants infected with PVX-UK3. Ectopic expression of CCS1 using recombinant PVX attenuated necrosis, suggesting that CCS1 alleviates systemic necrosis by activating superoxide dismutases to scavenge reactive oxygen species. Previous reports have indicated a decrease in the levels of CCS1 and superoxide dismutases along with an increased level of miR398 in plants infected with other viruses and viroids, and thus might represent shared regulatory mechanisms that exacerbate symptoms in these plants.
Rapid characterization of the causative agent(s) during a disease outbreak can aid in the implementation of effective control measures. However, isolation of the agent(s) from crude clinical samples can be challenging and time-consuming, hindering the establishment of countermeasures. In the present study, we used saliva specimens collected for the diagnosis of SARS-CoV-2-a good example of a practical target-and attempted to characterize the virus within the specimens without virus isolation. Thirty-four saliva samples from coronavirus disease 2019 patients were used to extract RNA and synthesize DNA amplicons by PCR. New primer sets were designed to generate DNA amplicons of the full-length spike (S) gene for subsequent use in a circular polymerase extension reaction (CPER), a simple method for deriving recombinant viral genomes. According to the S sequence, four clinical specimens were classified as BA. 1, BA.2, BA.5, and XBB.1 and were used for the
Abstract Severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) is the largest single‐stranded RNA virus known to date. Its genome contains multiple accessory protein genes that act against host immune responses but are not required for progeny virus production. The functions of the accessory proteins in the viral life cycle have been examined, but their involvement in viral pathogenicity remains unclear. Here, we investigated the roles of the accessory proteins in viral immunopathogenicity. To this end, recombinant SARS‐CoV‐2 possessing nonsense mutations in the seven accessory protein open reading frames (ORFs) (ORF3a, ORF3b, ORF6, ORF7a, ORF8, ORF9b, and ORF10) was de novo generated using an early pandemic SARS‐CoV‐2 strain as a backbone. We confirmed that the resultant virus (termed ORF3–10 KO) did not express accessory proteins in infected cells and retained the desired mutations in the viral genome. In cell culture, the ORF3–10 KO virus exhibited similar virus growth kinetics as the parental virus. In hamsters, ORF3–10 KO virus infection resulted in mild weight loss and reduced viral replication in the oral cavity and lung tissue. ORF3–10 KO virus infection led to mild inflammation, indicating that an inability to evade innate immune sensing because of a lack of accessory proteins impairs virus growth in vivo and results in quick elimination from the body. Overall, we showed that SARS‐CoV‐2 accessory proteins are involved in immunopathogenicity.
