jump to content

Fachbereich Veterinärmedizin

Service-Navigation

Feedback | Homepage
Department of Veterinary Medicine at the Freie Universität Berlin/

Veterinary Library

Mikronavigation

    Publication Database

    Impact of viral telomeric repeat sequences on herpesvirus vector vaccine integration and persistence (2024)

    Art
    Zeitschriftenartikel / wissenschaftlicher Beitrag
    Autoren
    Denesvre, Caroline
    You, Yu
    Rémy, Sylvie
    Vychodil, Tereza (WE 5)
    Courvoisier, Katia
    Penzes, Zoltán
    Bertzbach, Luca D.
    Kheimar, Ahmed
    Kaufer, Benedikt B. (WE 5)
    Quelle
    PLoS pathogens
    Bandzählung: 20
    Heftzählung: 5
    Seiten: e1012261
    ISSN: 1553-7374
    Sprache
    Englisch
    Verweise
    URL (Volltext): https://dx.plos.org/10.1371/journal.ppat.1012261
    DOI: 10.1371/journal.ppat.1012261
    Pubmed: 38805555
    Kontakt
    Institut für Virologie

    Robert-von-Ostertag-Str. 7-13
    14163 Berlin
    +49 30 838 51833
    virologie@vetmed.fu-berlin.de

    Abstract / Zusammenfassung

    Marek’s disease virus (MDV) vaccines were the first vaccines that protected against cancer. The avirulent turkey herpesvirus (HVT) was widely employed and protected billions of chickens from a deadly MDV infection. It is also among the most common vaccine vectors providing protection against a plethora of pathogens. HVT establishes latency in T-cells, allowing the vaccine virus to persist in the host for life. Intriguingly, the HVT genome contains telomeric repeat arrays (TMRs) at both ends; however, their role in the HVT life cycle remains elusive. We have previously shown that similar TMRs in the MDV genome facilitate its integration into host telomeres, which ensures efficient maintenance of the virus genome during latency and tumorigenesis. In this study, we investigated the role of the TMRs in HVT genome integration, latency, and reactivation in vitro and in vivo. Additionally, we examined HVT infection of feather follicles. We generated an HVT mutant lacking both TMRs (vΔTMR) that efficiently replicated in cell culture. We could demonstrate that wild type HVT integrates at the ends of chromosomes containing the telomeres in T-cells, while integration was severely impaired in the absence of the TMRs. To assess the role of TMRs in vivo, we infected one-day-old chickens with HVT or vΔTMR. vΔTMR loads were significantly reduced in the blood and hardly any virus was transported to the feather follicle epithelium where the virus is commonly shed. Strikingly, latency in the spleen and reactivation of the virus were severely impaired in the absence of the TMRs, indicating that the TMRs are crucial for the establishment of latency and reactivation of HVT. Our findings revealed that the TMRs facilitate integration of the HVT genome into host chromosomes, which ensures efficient persistence in the host, reactivation, and transport of the virus to the skin.