The clustered regularly interspaced short palindromic repeats (CRISPR)/associated nuclease (Cas) system is an efficient gene editing tool. In this study, it is found that both single guide RNA (gRNA) and Cas9 protein could be exported from the CRISPR/Cas9‐expressing cells by endogenous exosomes independently. Further experiments demonstrate that these naturally produced endogenous exosomes could be used as a vehicle to deliver the functional Cas9 and hepatitis B virus (HBV)‐specific gRNA to cut HBV DNA transfected in HuH7 cells or human papilloma virus (HPV)‐specific gRNA to cut the integrated HPV DNA in HeLa cells, respectively. In conclusion, this study indicates the potential of endogenous exosomes as a safe and effective delivery vehicle of the functional gRNA and Cas9 protein. Meanwhile, the endogenous exosomes‐mediated delivery of gene editing activity to adjacent and distant cells or tissues may further complicate the off‐target and safety concerns about the CRISPR/Cas9 system.
Integration of human papillomavirus (HPV) viral DNA into the human genome has been postulated as an important etiological event during cervical carcinogenesis. Several recent reports suggested a possible role for such integration‐targeted cellular genes (ITGs) in cervical carcinogenesis. Therefore, a comprehensive analysis of HPV integration events was undertaken using data collected from 14 publications, with 499 integration loci on human chromosomes included. It revealed that HPV DNA preferred to integrate into intragenic regions and gene‐dense regions of human chromosomes. Intriguingly, the host cellular genes nearby the integration sites were found to be more transcriptionally active compared with control. Furthermore, analysis of the integration sites in the human genome revealed that there were several integration hotspots although all chromosomes were represented. The ITGs identified were found to be enriched in tumor‐related terms and pathways using gene ontology and KEGG analysis. In line with this, three of six ITGs tested were found aberrantly expressed in cervical cancer tissues. Among them, it was demonstrated for the first time that MPPED2 could induce HeLa cell and SiHa cell G1/S transition block and cell proliferation retardation. Moreover, “knocking out” the integrated HPV fragment in HeLa cell line decreased expression of MYC located ∼500 kb downstream of the integration site, which provided the first experimental evidence supporting the hypothesis that integrated HPV fragment influence MYC expression via long distance chromatin interaction. Overall, the results of this comprehensive analysis implicated that dysregulation of ITGs caused by viral integration as possibly having an etiological involvement in cervical carcinogenesis.
Human papillomavirus (HPV) infection is the most important risk factor for cervical cancer development. In HeLa cell line, the HPV viral genome is integrated at 8q24 in one allele of chromosome 8. It has been reported that the HPV fragment integrated in HeLa genome can cis‐activate the expression of proto‐oncogene MYC, which is located at 500 kb downstream of the integrated site. However, the underlying molecular mechanism of this regulation is unknown. A recent study reported that MYC was highly expressed exclusively from the HPV‐integrated haplotype, and a long‐range chromatin interaction between the integrated HPV fragment and MYC gene has been hypothesized. In this study, we provided the experimental evidences supporting this long‐range chromatin interaction in HeLa cells by using Chromosome Conformation Capture (3C) method. We found that the integrated HPV fragment, MYC and 8q24.22 was close to each other and might form a trimer in spatial location. When knocking out the integrated HPV fragment or 8q24.22 region from chromosome 8 by CRISPR/Cas9 system, the expression of MYC reduced dramatically in HeLa cells. Interestingly, decreased expression was only observed in three from eight cell clones, when only one 8q24.22 allele was knocked out. Functionally, HPV knockout caused senescence‐associated acidic β‐gal activity in HeLa cells. These data indicate a long‐distance interaction of the integrated HPV fragment with MYC gene and 8q24.22 region, providing an alternative mechanism relevant to the carcinogenicity of HPV integration.
The p53 mutation and altered Pten expression are two most common genetic events in Hepatitis B virus (HBV) infection related hepatocellular carcinoma (HCC). To confirm the causative role of p53 and Pten somatic mutation in HCC development, we established CRISPR/Cas9-mediated somatic gene disruption via hydrodynamic tail vein injection, allowing for in vivo targeting p53 and Pten simultaneously in adult HBV transgenic mice. Here we demonstrated that the utility of this approach resulted in macroscopic liver tumors as early as 4 months’ post injection and most tumors harbored both p53 and Pten loss-of-function alterations. Immunohistochemical (IHC) and histopathology analysis demonstrated that the tumors were positive for Glutamine synthetase (GS), a marker of HCC and accompanied with prominent lipid accumulation. The study here indicated that CRISPR/Cas9-mediated p53 and Pten somatic mutation accelerated hepatocarcinogenesis in adult HBV transgenic mice. This method also provides a fast and convenient system for generating mouse model of HCC with HBV infection characteristics.
Purpose Vaccination reduces the incidence of severe COVID-19 and death and effectively limits viral spread. Concerns have been raised about COVID-19 vaccine responses in the large population of HIV-infected patients. This study aims to explore the safety and immunogenicity of the inactivated COVID-19 vaccine in people living with HIV (PLWH). Patients and Methods All participants in this study already had their second dose of an inactivated COVID-19 vaccine at least 14 days earlier, without a history of SARS-CoV-2 infection. The primary safety outcomes were the incidence of adverse reactions and changes in CD4 + T-cell counts. SARS-CoV-2 IgG and neutralizing antibody responses to the D614G variant and delta variant were measured for immune response assessment. Results Forty-seven HIV-infected patients and 18 healthy donors (HDs) were enrolled in this study. Adverse reactions were mild or self-limiting and were reported in 19.1% of HIV-infected patients. Most PLWH developed antibody responses against the inactivated COVID-19 vaccine. The longitudinal analysis of antibody responses in PLWH (median interval between detection and complete vaccination, 59 days) showed that antibodies were maintained for at least three months, though their titers were reduced. However, the antibody-positive rates in PLWH were significantly lower than those in HDs. Additionally, compared to HDs (Geomean titers (GMT) of 165 for D614G and GMT of 72 for delta), the neutralizing antibody titers against the two variants in PLWH (GMT of 43 for D614G and GMT 13 for delta) were decreased significantly (p = 0.018 and p < 0.001, respectively). HIV-infected patients with CD4 + T-cell counts ≤350 cells/μL appeared to exhibit a poor antibody response to inactivated vaccination. Conclusion Inactivated COVID-19 vaccines appear to be efficacious in PLWH. However, antibody responses in HIV-infected patients are inferior to those in healthy individuals, especially PLWH with lower CD4 + T-cell counts.
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