DNA Replication ; Epigenesis, Genetic ; Hepatitis B virus ; genetics ; physiology ; Virus Replication

Norovirus ; chemistry ; genetics ; physiology ; ultrastructure ; Open Reading Frames ; Virus Replication

OBJECTIVETo investigate the effect of HS3ST3B1 on hepatitis B virus (HBV) replication.

METHODSHepG2 cells were classified into 7 groups according to the plasmids transfected: (1) Blank group, no plasmid transfected; 2. Positive control, transfected with pCH9-HBV which permits HBV replication; (3) Negative control, transfected with pCH9-HBV + pcDNA3.1 + pTZU6+1; (4) Treatment A, transfected with pCH9-HBV + pCDNA3.1-HS3ST3B1 + pTZU6+1; (5) Interference A, transfected with pCH9-HBV + pCDNA3.1-HS3ST3B1 + psh1126 (a plasmid to interfere HS3ST3B1 expression); (6) Treatment B, transfected with pCH9-HBV + pTZU6+1; (7) Interference B, transfected with pCH9-HBV + psh1126. The levels of HBV DNA were detected in the above groups by Southern blotting. HBV total RNA of Negative control, Treatment A and Interference A were quantified by Real-time PCR to determine the influence of HS3ST3B1 over-expression on the HBV RNA transcription. The activity of the four HBV promoters [core promoter (cp), x promoter(xp), surface antigen promoter1(sp1), surface antigen promoter2 (sp2)] were assayed by Dual-Luciferase Reporter Assay System. The data was analyzed using one way ANOVA, with P < 0.05 indicating statistically meaningful difference.

RESULTSouthern blot data revealed the level of HBV DNA in Treatment A and Interference A accounted for 10% +/- 2% and 31% +/- 4% of that in control. Compared with control, a statistical difference existed between Treatment A and Control, with F value equalling to 20.8 and P value equalling to 0.034 respectively. A statistical difference also existed between Interfere A and Treatment A, with F value equalling to 24.9 and P value equalling to 0.021 respectively. The level of HBV DNA in Experiment B was raised by 130% +/- 11% as compared to that in Interference B, and the levels of HBV DNA showed a dose-dependent decrease when H7 cells were transfected with 0.5, 1.0, 1.5 microg pCDNA3.1-HS3ST3B1 respectively. Statistical differences existed between control and H7 transfected with different dose of pCDNA3.1-HS3ST3B1, with F values equalling to 22.7, 20.3, 26.5 and P values equalling to 0.029, 0.041 and 0.015 respectively. Real-time PCR revealed that the HBV total RNA in Treatment A accounted for 17.0% +/- 2.7% of that in control and there was a statistical difference between Treatment A and control, with F value equalling to 25.6 and P value equalling to 0.018. In addition, HBV DNA in Interference A was restored to 74.0% +/- 3.9% of that in control, and there was also a statistical difference between Treatment A and Interference A, with F value equalling to 21.3 and P value equalling to 0.032. However, the down regulation of HBV total RNA had nothing to do with HBV promoters activity.

CONCLUSIONHS3ST3B1 can inhibit HBV replication and reduce the level of HBV total RNA, but the downregulation of HBV total RNA may not be the result of direct interaction of HS3ST3B1 and HBV promoters.

DNA Replication ; DNA, Viral ; biosynthesis ; Hep G2 Cells ; Hepatitis B virus ; genetics ; physiology ; Humans ; Plasmids ; Sulfotransferases ; genetics ; Transfection ; Virus Replication

OBJECTIVETo investigate the change of viral titers under different conditions in cultured cells persistently-infected with different strains of Japanese encephalitis virus (JEV) and find out the factors that influence viral multiplication.

METHODSJEV JaGAr-01 and Nakayama wild strains were used to infect human hepatoma cell line KN73 respectively, and the persistent infection model was established. Viral titers were examined by plaque methods using BHK cells. Human nerve fibroblastoma cell line IMR-32 was infected with the strains of the virus that can cause persistent infection, and the thermal sensitivity of the viral strains was measured at 30 degrees C and 37 degrees C. KN73 cells persistently infected with JEV were infected with two JEV strains respectively, and viral superinfection was studied. To explore the replication of the persistently-infected viruses, KN73 and IMR-32 cells were infected with the viral strains.

RESULTSTwo persistently infected viral strains did not show any thermal difference. The results of superinfection were that the viral titers of JaGAr-01 strains were 1.3 and 8.8 percent of the control, respectively, and the viral titers of Nakayama strain were 80 and 1.7 percent of the control, respectively. JaGAr-01 wild strains, Nakayama wild strains and their persistently-infected strains infected KN73 and IMR-32 respectively. The replication of the persistently-infected strains was obviously lower than the wild strains in KN73 cells, however, in IMR-32 cells their replication was similar.

CONCLUSIONSThe two strains of JEV were not found to be temperature-mutant. It is possible that mutant viruses containing DI particles exist in JEV persistently-infected strains. In different cells there may be different host factors hindering the replication of the persistently-infected strains.

Animals ; Cell Line ; Encephalitis Virus, Japanese ; genetics ; physiology ; Encephalitis, Japanese ; virology ; Humans ; Virus Cultivation ; Virus Replication

MicroRNA (miRNA) are small non-coding molecules of ribonucleic acid. They are about 22 nucleotides in length, single-stranded, and mediate post-translational regulation by the repression or degradation of messenger RNA(mRNA). miRNA play a key part in the proliferation, differentiation and death of cells. Viral infection is one of the most common causes of human disease. Some studies have found that miRNA has a very close relationship with viral infection, which has an effect on viral replication, the immune response and antiviral immunity. Use of miRNA may become the cornerstone of new methods for the diagnosis and treatment of viral infection. This article summarizes the progress of research into miRNA and viral infection.
Animals ; Humans ; MicroRNAs ; genetics ; metabolism ; Virus Diseases ; genetics ; metabolism ; virology ; Virus Physiological Phenomena ; Virus Replication ; Viruses ; genetics

Critical Illness ; Hepatitis B virus ; genetics ; physiology ; Hepatitis B, Chronic ; virology ; Humans ; Transcription, Genetic ; Virus Replication

Replication of duck plague virus(DPV) in artificially infected ducks were detected by in situ hybridization (ISH) which employed a 37bp oligonucleotide as probe designed according to DPV DNA sequence in GenBank. The results indicated that DPV DNA was detected in liver, intestine and bursa Fabricius at 4 h, in spleen and esophagus at 6h, in thymus at 12h post infection; DPV DNA in lung and kidney was detected only in dead ducks and no positive signal was detected in muscle, heart, cerebrum and pancreas. DPV DNA was distributed in cell nucleus and cytoplasm. Hepatocytes, sinus endodermal cells and Kuffer's cells were the mainly infected cell types in liver. DPV DNA was mainly detected in epithelium of villi, in lamina propria of intestinal villi of duodenum, in stratum spinosum of esophagus, and in epithelium, cortex, medulla of bursa Fabricius. The positive signals were mainly detected in medulla of thymus, lymphocytes and macrophages of spleen. The research suggests that ISH is a direct and specific method in detecting DPV DNA in paraffin sections and it's also a good method for virus diagnosis and DNA location of DPV.
Animals ; DNA, Viral ; analysis ; Ducks ; virology ; In Situ Hybridization ; Influenza A virus ; genetics ; isolation & purification ; physiology ; Virus Replication

Porcine epidemic diarrhea virus (PEDV) is a highly pathogenic virus that can cause acute intestinal infectious diseases in both piglets and fattening pigs. The virus encodes at least 16 non-structural proteins, including nsp9, which has been shown to bind to single-stranded RNA. However, its function and mechanism remain unclear. In this study, we aimed to identify potential host proteins that interact with PEDV nsp9 using immunoprecipitation combined with mass spectrometry. The interactions were then confirmed by co-immunoprecipitation (Co-IP) and confocal laser scanning fluorescence techniques. The results showed that nsp9 interacts with HSPA8, Tollip, HSPA9 and TOMM70. Among them, overexpression of HSPA8 resulted in caused first upregulated and then down-regulated expression of nsp9, and promoted the proliferation of PEDV. Overexpression of Tollip significantly upregulated the expression of nsp9 and inhibited the proliferation of PEDV. Overexpression of TOMM70 significantly reduced the expression of nsp9, but did not show significant effect on the proliferation of PEDV. Overexpression of HSPA9 did not show significant effect on the expression of nsp9 and the proliferation of PEDV. These findings may facilitate further investigating the role of nsp9-interacting proteins in PEDV infection.
Animals ; Swine ; Porcine epidemic diarrhea virus/genetics* ; Virus Replication ; Proteins ; Swine Diseases

COPI is a protein complex that transports vesicles from the Golgi complex back to endoplasmic reticulum. Many viruses such as RNA viruses, DNA viruses and retroviruses, hijack or adapt COPI related proteins including coatomer, ARF1 and GBF1 for their own benefits. Here, we summarize the current progress of the roles of COPI related proteins in virus replication.
Animals ; Coat Protein Complex I ; genetics ; metabolism ; Humans ; Virus Diseases ; genetics ; metabolism ; virology ; Virus Physiological Phenomena ; Virus Replication

Animals ; Cloning, Molecular ; DNA Replication ; DNA, Viral ; genetics ; Gene Expression Regulation, Viral ; Hepatitis B virus ; genetics ; metabolism ; physiology ; Humans ; Trans-Activators ; genetics ; Virus Replication