Mapping the sites of latency and reactivation by bovine herpesvirus 5 (BoHV-5) and a thymidine kinase-deleted BoHV-5 in lambs / Mapeamento dos sítios de latência e reativação pelo herpesvírus bovino tipo 5 (BoHV-5) e por mutante deletado no gene da timidina quinase em ovinos

A thymidine kinase (tk)-deleted bovine herpesvirus 5 (BoHV-5tkΔ) was previously shown to establish latent infection and reactivate - even poorly - in a sheep model (Cadore et al. 2013). As TK-negative alphaherpesviruses are unlike to reactivate in neural tissue, this study investigated the sites of latency and reactivation by this recombinant in lambs. For this, groups of lambs were inoculated intranasally with the parental BoHV-5 strain (SV-507/99) or with the recombinant BoHV-5tkΔ. During latent infection (40 days post-inoculation, pi), the distribution of recombinant virus DNA in neural and non-neural tissues was similar to that of the parental virus. Parental and recombinant virus DNA was consistently detected by PCR in trigeminal ganglia (TGs); frequently in palatine and pharyngeal tonsils and, less frequently in the retropharyngeal lymph nodes. In addition, latent DNA of both viruses was detected in several areas of the brain. After dexamethasone (Dx) administration (day 40pi), the recombinant virus was barely detected in nasal secretions contrasting with marked shedding of the parental virus. In tissues of lambs euthanized at day 3 post-Dx treatment (pDx), reverse-transcription-PCR (RT-PCR) for a late viral mRNA (glycoprotein D gene) demonstrated reactivation of parental virus in neural (TGs) and lymphoid tissues (tonsils, lymph node). In contrast, recombinant virus mRNA was detected only in lymphoid tissues. These results demonstrate that BoHV-5 and the recombinant BoHV-5tkΔ do establish latent infection in neural and non-neural sites. Reactivation of the recombinant BoHV-5tkΔ, however, appeared to occur only in non-neural sites. In anyway, the ability of a tk-deleted strain to reactivate latent infection deserves attention in the context of vaccine safety.

Um recombinante do herpesvírus bovino tipo 5 com deleção no gene da timidina quinase (BoHV-5tkΔ) foi capaz de estabelecer latência e reativar - embora ineficientemente - em modelo experimental em ovinos (Cadore et al. 2013). Como a reativação de alfaherpesvírus defectivos na TK em tecido neural é improvável, o presente estudo investigou os sítios de latência e reativação por esse recombinante em ovinos. Para isso, grupos de ovinos foram inoculados com a cepa de BoHV-5 parental (SV-507/99) ou com o recombinante BoHV-5tkΔ. Durante a infecção latente (dia 40 pós-infecção, pi) a distribuição do DNA do vírus recombinante no encéfalo de ovinos infectados experimentalmente foi similar ao do vírus parental (SV-507/99). O DNA de ambos os vírus foi detectado consistentemente por PCR nos gânglios trigêmeos (TGs), frequentemente nas tonsilas faríngeas e palatinas e, com menos frequência, nos linfonodos retrofaríngeos. Após administração de dexametasona (Dx), o vírus recombinante foi raramente detectado nas secreções nasais, contrastando com excreção abundante do vírus parental. RT-PCR para mRNA de um gene tardio (glicoproteína D) realizado em tecidos de animais eutanasiados 3 dias pós-Dx demonstrou reativação do vírus parental em tecido neural (TGs) e não-neural (tonsilas, linfonodo). Em contraste, a reativação do vírus recombinante ficou restrita ao tecido linfoide. Esses resultados demonstram que tanto o BoHV-5 parental quanto o recombinante estabelecem latência em sítios neurais e não-neurais. No entanto, o recombinante BoHV-5tkΔ parece reativar apenas nos tecidos não-neurais (linfoide). De qualquer forma, a capacidade do recombinante reativar a infecção latente deve ser considerada no contexto de segurança vacinal.

Mapping the sites of latency and reactivation by bovine herpesvirus 5 (BoHV-5) and a thymidine kinase-deleted BoHV-5 in lambs / Mapeamento dos sítios de latência e reativação pelo herpesvírus bovino tipo 5 (BoHV-5) e por mutante deletado no gene da timidina quinase em ovinos

A thymidine kinase (tk)-deleted bovine herpesvirus 5 (BoHV-5tkΔ) was previously shown to establish latent infection and reactivate - even poorly - in a sheep model (Cadore et al. 2013). As TK-negative alphaherpesviruses are unlike to reactivate in neural tissue, this study investigated the sites of latency and reactivation by this recombinant in lambs. For this, groups of lambs were inoculated intranasally with the parental BoHV-5 strain (SV-507/99) or with the recombinant BoHV-5tkΔ. During latent infection (40 days post-inoculation, pi), the distribution of recombinant virus DNA in neural and non-neural tissues was similar to that of the parental virus. Parental and recombinant virus DNA was consistently detected by PCR in trigeminal ganglia (TGs); frequently in palatine and pharyngeal tonsils and, less frequently in the retropharyngeal lymph nodes. In addition, latent DNA of both viruses was detected in several areas of the brain. After dexamethasone (Dx) administration (day 40pi), the recombinant virus was barely detected in nasal secretions contrasting with marked shedding of the parental virus. In tissues of lambs euthanized at day 3 post-Dx treatment (pDx), reverse-transcription-PCR (RT-PCR) for a late viral mRNA (glycoprotein D gene) demonstrated reactivation of parental virus in neural (TGs) and lymphoid tissues (tonsils, lymph node). In contrast, recombinant virus mRNA was detected only in lymphoid tissues. These results demonstrate that BoHV-5 and the recombinant BoHV-5tkΔ do establish latent infection in neural and non-neural sites. Reactivation of the recombinant BoHV-5tkΔ, however, appeared to occur only in non-neural sites. In anyway, the ability of a tk-deleted strain to reactivate latent infection deserves attention in the context of vaccine safety.

Um recombinante do herpesvírus bovino tipo 5 com deleção no gene da timidina quinase (BoHV-5tkΔ) foi capaz de estabelecer latência e reativar - embora ineficientemente - em modelo experimental em ovinos (Cadore et al. 2013). Como a reativação de alfaherpesvírus defectivos na TK em tecido neural é improvável, o presente estudo investigou os sítios de latência e reativação por esse recombinante em ovinos. Para isso, grupos de ovinos foram inoculados com a cepa de BoHV-5 parental (SV-507/99) ou com o recombinante BoHV-5tkΔ. Durante a infecção latente (dia 40 pós-infecção, pi) a distribuição do DNA do vírus recombinante no encéfalo de ovinos infectados experimentalmente foi similar ao do vírus parental (SV-507/99). O DNA de ambos os vírus foi detectado consistentemente por PCR nos gânglios trigêmeos (TGs), frequentemente nas tonsilas faríngeas e palatinas e, com menos frequência, nos linfonodos retrofaríngeos. Após administração de dexametasona (Dx), o vírus recombinante foi raramente detectado nas secreções nasais, contrastando com excreção abundante do vírus parental. RT-PCR para mRNA de um gene tardio (glicoproteína D) realizado em tecidos de animais eutanasiados 3 dias pós-Dx demonstrou reativação do vírus parental em tecido neural (TGs) e não-neural (tonsilas, linfonodo). Em contraste, a reativação do vírus recombinante ficou restrita ao tecido linfoide. Esses resultados demonstram que tanto o BoHV-5 parental quanto o recombinante estabelecem latência em sítios neurais e não-neurais. No entanto, o recombinante BoHV-5tkΔ parece reativar apenas nos tecidos não-neurais (linfoide). De qualquer forma, a capacidade do recombinante reativar a infecção latente deve ser considerada no contexto de segurança vacinal.

Selection and characterization of brivudin resistant bovine herpesvirus type 5

Bovine herpesvirus type 5 (BoHV-5) is the agent of meningoencephalitis, an important disease of cattle in South America. The neuropathogenesis of BoHV-5 infection is poorly understood and most previous research focused on the role of envelope glicoproteins in neurovirulence. Thymidine kinase (TK) is a viral enzyme necessary for virus replication in neurons and, therefore, represents a potential target for virus attenuation. The selection and characterization of BoHV-5 variants resistant to the nucleoside analog brivudin (BVDU), which selects TK-defective viruses is here described. Several BVDU-resistant clones were obtained after multiple passages in tissue culture in the presence of BVDU and one clone (BoHV-5/R-27) was further characterized. The selected clone replicated to similar titers and produced plaques with similar size and morphology to those of wild-type virus (SV507/99). The genetic stability of the resistant virus was demonstrated after ten passages in cell culture in the absence of the drug. Moreover, the drug-resistant virus showed reduced virulence in a rabbit model: virus inoculation in four rabbits did not result in disease, in contrast with 75 percent morbidity (3/4) and 50 percent mortality (2/2) among rabbits inoculated with the parental virus. These results demonstrate that BoHV-5 is sensitive to BVDU and that drug-resistant mutants can be readily selected upon BVDU treatment. BVDU-resistant mutants, likely defective in TK, retained their ability to replicate in tissue culture yet were attenuated for rabbits. This strategy to obtain TK-defective BoHV-5 may be useful to study the role of TK in BoHV-5 neuropathogenesis and for vaccine development.