Although intramuscular (i.m.) injection of DNA encoding glycoprotein D (gD) of bovine herpesvirus-1 (BHV-1) induces immune responses in cattle, this route of delivery is inefficient. Here we assessed three parameters that may enhance the efficacy of a gD DNA vaccine in cattle. First, the immune response generated by i.m. injected plasmid expressing a secreted form of gD (tgD) was determined and found to be very similar in magnitude to the response induced by gD-expressing plasmid. Secondly, gD- and tgD-expressing plasmids were administered by intradermal (i.d.) immunization, which resulted in a superior immune response to the secreted form, but no improvement in the response to the membrane-associated form. However, the form of gD used for immunization did not influence the immunoglobulin subtype, the ratio of antigen-specific IgG1 to IgG2 being approximately 4:1. Finally, the effect of promoter strength was assessed by replacing the Rous sarcoma virus (RSV) promoter, which was used in the original experiments, with the human cytomegalovirus immediate early promoter and first intron A (HCMV/IA). Although upon transfection in vitro the HCMV/IA promoter appeared to be stronger than the RSV promoter, there was only a 2-fold higher antibody response in vivo upon i.d. injection of cattle. Protection against virus challenge was obtained in the calves immunized i.d. with tgD-encoding plasmid, as shown by a significant reduction in weight loss, virus excretion, temperature response and clinical disease. No significant protection was observed in the animals vaccinated i.d. with the gD-expressing plasmid, which correlates with the lower level of immunity pre-challenge.
Bovine herpesvirus type 1 (BHV-1) is an alphaherpesvirus which is an important pathogen of cattle, causing a variety of clinical manifestations in its natural host (46). BHV-1 virions have a typical herpesvirus structure characterized by the presence of a double-stranded DNA genome enclosed in an icosahedral capsid, the tegument surrounding the capsid, and the outer host-derived lipid envelope bearing virus-encoded glycoproteins. While the major constituents of the viral envelope have been extensively studied (reviewed in reference 17), the proteins present in the tegument and nucleocapsid of BHV-1 have been poorly characterized. Compositionally, the tegument is the most complex compartment of the virion, containing more than 15 viral gene products (32). In addition to their structural role, various regulatory functions, including modulation of transcription (34, 47), kinase activity (39), RNase activity (41), and DNA packaging (43), have been assigned to some tegument proteins, suggesting that these virion constituents function at several stages during virus infection, establishing conditions for efficient viral replication and promoting virus assembly and egress.Although the U L 47 gene product, tegument protein VP8, is the most abundant component of mature BHV-1 virions (5), its function is unknown. Like its herpes simplex virus type 1 (HSV-1) homologue (31), VP8 is posttranslationally modified by phosphorylation (5,23) and by the addition of O-linked carbohydrates (49). Both HSV-1 and BHV-1 U L 47 homologues possess nuclear localization and nuclear export signatures (7,51,53,56), enabling them to shuttle between the nucleus and cytoplasm when expressed in transiently transfected cells (51,56) or during viral infection (52, 53). Furthermore, both proteins exhibit a steady-state nuclear localization at early stages of infection and during transient expression (6,35,49,51,52,56), suggesting a functional role for these homologues in the nucleus. Nucleocytoplasmic shuttling of VP8 is sensitive to treatment with a RNA polymerase II inhibitor, actinomycin D (52). This observation coupled with recently demonstrated RNA binding activity of the HSV-1 and BHV-1
The major tegument protein of bovine herpesvirus 1 (BoHV-1), VP8, is essential for virus replication in cattle. VP8 is phosphorylated in vitro by casein kinase 2 (CK2) and BoHV-1 unique short protein 3 (U S 3). In this study, VP8 was found to be phosphorylated in both transfected and infected cells but was detected as a nonphosphorylated form in mature virions. This suggests that phosphorylation of VP8 is strictly controlled during different stages of the viral life cycle. The regulation and function of VP8 phosphorylation by U S 3 and CK2 were further analyzed. An in vitro kinase assay, site-directed mutagenesis, and liquid chromatography-mass spectrometry were used to identify the active sites for U S 3 and CK2. The two kinases phosphorylate VP8 at different sites, resulting in distinct phosphopeptide patterns. S 16 is a primary phosphoreceptor for U S 3, and it subsequently triggers phosphorylation at S 32 . CK2 has multiple active sites, among which T 107 appears to be the preferred residue. Additionally, CK2 consensus motifs in the N terminus of VP8 are essential for phosphorylation. Based on these results, a nonphosphorylated VP8 mutant was constructed and used for further studies. In transfected cells phosphorylation was not required for nuclear localization of VP8. Phosphorylated VP8 appeared to recruit promyelocytic leukemia (PML) protein and to remodel the distribution of PML in the nucleus; however, PML protein did not show an association with nonphosphorylated VP8. This suggests that VP8 plays a role in resisting PML-related host antiviral defenses by redistributing PML protein and that this function depends on the phosphorylation of VP8. IMPORTANCEThe progression of VP8 phosphorylation over time and its function in BoHV-1 replication have not been characterized. This study demonstrates that activation of S 16 initiates further phosphorylation at S 32 by U S 3. Additionally, VP8 is phosphorylated by CK2 at several residues, with T 107 having the highest level of phosphorylation. Evidence for a difference in the phosphorylation status of VP8 in host cells and mature virus is presented for the first time. Phosphorylation was found to be a critical modification, which enables VP8 to attract and to redistribute PML protein in the nucleus. This might promote viral replication through interference with a PML-mediated antiviral defense. This study provides new insights into the regulation of VP8 phosphorylation and suggests a novel, phosphorylation-dependent function for VP8 in the life cycle of BoHV-1, which is important in view of the fact that VP8 is essential for virus replication in vivo. Bovine herpesvirus 1 (BoHV-1) is a herpesvirus belonging to the subfamily Alphaherpesvirinae and one of the most common pathogens in cattle. The major clinical symptoms caused by BoHV-1 are infectious bovine rhinotracheitis, conjunctivitis, vulvovaginitis, and balanoposthitis. The virus particle is composed of a capsid containing the double-stranded DNA genome, which is surrounded by a tegument layer and an en...
Infectious diseases are responsible for a significant number of deaths during the first weeks of life. Some of the salient pathogens include HSV, HIV, hepatitis B virus, group B streptococcus, Haemophilus sp., and Chlamydia sp. The vertical transmission of many of these pathogens significantly increases the risk of neonatal infection. We recently reported that oral DNA immunization in utero induced high serum Ab titers and cell-mediated immunity in fetal lambs. In this study, we demonstrate immune memory and mucosal immunity in newborn lambs following oral DNA immunization of the fetus. A single oral exposure in utero to plasmid DNA encoding a truncated form of glycoprotein D of bovine herpesvirus-1 induced detectable immune responses in 80% (12 of 15) of newborn lambs. There was no evidence for the induction of immune tolerance in nonresponding lambs. Responding lambs displayed both systemic and mucosal immune responses and reduced virus shedding following intranasal challenge. Furthermore, strong anamnestic responses were evident for at least 3 mo after birth. The efficacy of in utero oral DNA immunization was further demonstrated with the hepatitis B surface Ag, and protective serum Ab titers occurred in 75% of immunized lambs. Thus, the present investigation confirms that oral DNA immunization in utero can induce both mucosal and systemic immune responses in the neonate and that this immunity has the potential to prevent vertical disease transmission.
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