A duck hepatitis B virus strain with a knockout mutation in the putative X ORF shows similar infectivity and in vivo growth characteristics to wild-type virus.

Hepadnaviruses including human hepatitis B virus (HBV) and duck hepatitis B virus (DHBV) express X proteins, HBx and DHBx, respectively. Both HBx and DHBx are transcriptional activators and modulate cellular signaling in in vitro assays. To test whether the DHBx protein plays a role in virus infection, we compared the in vivo infectivity and growth characteristics of a DHBV3 strain with a stop codon in the X-like ORF (DHBV3-X-K.O.) to those of the wild-type DHBV3 strain. Here we report that the two strains showed no significant difference in (i). their ability to induce infection that resulted in stable viraemia measured by serum surface antigen (DHBsAg) and DHBV DNA, and detection of viral proteins and replicative DNA intermediates in the liver; (ii). the rate of spread of infection in liver and extrahepatic sites after low-dose virus inoculation; and (iii). the ability to produce transient or persistent infection under balanced age/dose conditions designed to detect small differences between the strains. Thus, none of the infection parameters assayed were detectably affected by the X-ORF knockout mutation, raising the question whether DHBx expression plays a physiological role during in vivo infection with wild-type DHBV.

Structural and functional homology between duck and chicken interferon-gamma.

The Duck interferon gamma (DuIFN-gamma) cDNA was cloned from a phytohaemaglutinin-stimulated duck spleen cDNA library screened using a chicken IFN-gamma (ChIFN-gamma) cDNA probe. The DuIFN-gamma cDNA is 1392 nt long and shows 99% and 80% sequence identity with another cloned DuIFN-gamma cDNA, and with ChIFN-gamma cDNA, respectively. The cDNA contains a 495 bp ORF that encodes a putative 164 amino acid (AA) protein that shares 67% identity with ChIFN-gamma, but only 30-35% identity with mammalian IFN-gamma. The predicted three-dimensional (3D) structures of DuIFN-gamma and ChIFN-gamma are similar when analysed by comparative protein modelling. Culture supernatant collected from COS cells transfected with DuIFN-gamma cDNA was able to activate nitrite secretion from a chicken macrophage cell line (HD11) in a dose-dependent fashion. This activity could not be neutralised by an anti-ChIFN-gamma monoclonal antibody (Mab 85) that was able to neutralise the activity of ChIFN-gamma. Recombinant DuIFN-gamma (rDuIFN-gamma) protein was expressed in E. coli as an N-terminally His-tagged protein and was purified on a nickel affinity column. The eluted protein, which was detected as a approximately 18 kDa band with a purity of >90%, was also detected by Western blot using the anti-ChIFN-gamma monoclonal antibody (Mab 9.1). The rDuIFN-gamma was shown to activate nitrite secretion by HD11 cells in a dose-dependent fashion with a specific activity that was approximately 16-fold lower than a rChIFN-gamma control. Two rabbit antisera raised against rDuIFN-gamma were able to neutralise COS cell-expressed DuIFN-gamma activity; one of these also neutralised ChIFN-gamma activity. These findings indicate that DuIFN-gamma shares structural and functional identity with ChIFN-gamma, which is consistent with our previous results which demonstrated cross reactivity with other lymphokines from the two species.

Kinetics of early molecular events in duck hepatitis B virus replication in primary duck hepatocytes.

This paper describes the use of one-step growth conditions to study the kinetics of duck hepatitis B virus (DHBV) replication in primary duck hepatocytes. Synchronized infection was achieved using partially purified DHBV virions at an m.o.i. of 640 DHBV DNA-containing virions per cell, and these conditions were shown to produce a single cycle of infection. In this model, input purified DHBV DNA was rapidly internalized by cells at > or = 0.5 h, and localized to the nucleus by 4 h, but both covalently closed circular (CCC) DNA and single-stranded DNA were not detected until 48 h postinoculation (p.i.), suggesting that there was a > or = 40 h delay between DHBV localization to the nucleus and formation of CCC DNA. In contrast, CCC DNA can be first detected in hepatocytes at 6 h p.i. in in vivo infection of ducks with the same DHBV strain. In an analysis of the nuclear transport of the DHBV genome, release of nuclear viral DNA from a particulate form to a soluble nucleoplasmic form was only 50% complete by 48 h p.i. However, this process occurred simultaneously with genome uncoating since all soluble nucleoplasmic DHBV DNA was free of nucleocapsid material; this suggests that nucleocapsid disassembly and genome uncoating may occur at the nuclear membrane and not within the nucleus. Quantitative analysis demonstrated inefficiency in a number of steps including virus uptake and internalization, translocation of nucleocapsid across the nuclear membrane and antigen expression from intranuclear viral DNA.

Kinetics of duck hepatitis B virus infection following low dose virus inoculation: one virus DNA genome is infectious in neonatal ducks.

Using pooled serum from congenitally duck hepatitis B virus (DHBV)-infected ducks as inoculum, we examined the effect of virus dose on the incubation period of infection and on the patterns of spread of virus infection in the liver. The pooled serum inoculum contained 9.5 x 10(9) DHBV genomes per milliliter and had an infectivity titre (ID50) in newly hatched ducks of 1.5 x 10(10) per milliliter with a 95% confidence interval of 3.0 x 10(9) to 6.3 x 10(10) ID50/ml, indicating the equivalence between one DHBV genome and one infectious unit within the limits of the assays. The incubation period of infection was inversely related to the dose of inoculum and the onset of viraemia ranged from Day 6 with the highest dose to Day 14 or 29 with the lowest dose inoculum. To study the spread of virus infection from a low percentage of initially infected cells we inoculated newly hatched ducks intravenously with sufficient DHBV (1.5 x 10(3) ID50) to infect only approximately 0.0001% of total liver cells. DHBV infection first reached detectable levels on Day 4 postinoculation (p.i.) and was detected in approximately 0.035% of hepatocytes, most of which occurred as single cells or pairs of cells, indicating that a number of rounds of infection had occurred with the spread of virus both to adjoining cells, i.e., by cell-to-cell spread, and to cells located in other parts of the liver lobule. Despite some bird-to-bird variation in timing, the percentage of infected hepatocytes increased exponentially with a mean doubling time of 16 hr from Day 4 to Day 14 p.i., by which time replication was seen in > 95% of hepatocytes. This rapid dissemination from a small number of infected hepatocytes suggests that, in neonatal ducks, there are no major delays in virus replication within the liver, that any innate and adaptive defence mechanisms operating during the first 10 to 14 days of infection are insufficient to contain virus spread, and that even a small number of infected hepatocytes produce enough progeny to rapidly infect the remaining hepatocytes.