Tunneling nanotubes induced by pseudorabies virus facilitate viral transmission in neuronal cells to evade the immune system
摘要
Pseudorabies virus (PRV), an alphaherpesvirus endemic in swine, has recently emerged as a causative agent of fatal human encephalitis, yet its neuropathogenic mechanisms remain largely unexplored. Tunneling nanotubes (TNTs) are actin-rich intercellular membrane extensions that have been found to mediate intercellular communication and facilitate the cell-to-cell transmisssion of viruses.
MethodsImmunofluorescence analysis, confocal imaging, time-lapse photography, in situ sectioning transmission electron microscopy, and scanning electron microscopy were employed to characterize the structure and function of PRV-induced TNTs in SK-N-SH cells widely utilized in neuroscience research. A cell compartment co-culture model was further constructed in this study, and the morphological differences in TNTs, as well as the corresponding viral transmission efficiency under immune pressure, were statistically analyzed and compared between different PRV strains. Additionally, we investigated the role of viral US3 in TNTs formation via proteins overexpression, gene-deleted virus construction and kinase-inactivated US3 protein expression.
ResultsWe demonstrate that PRV infection induces the extensive formation of TNTs in SK-N-SH cells. These structures act as protected conduits that facilitate efficient cell-to-cell viral transmission, enabling the virus to evade neutralizing antibodies. Critically, a human-isolate variant strain (hSD-1/2019) induced the formation of significantly more, longer and thicker TNTs than a classical PRV strain (Ea). In addition, hSD-1/2019 also exhibited more efficient viral transmission under immune pressure, providing a novel mechanism to explain the enhanced virulence of hSD-1/2019. Further investigation identified that the viral protein US3 and its kinase activity are essential for TNTs formation. However, TNTs induced by viral infection were morphologically distinct from those induced by US3 overexpression alone, suggesting that additional viral factors are required to regulate TNTs maturation and morphology.
ConclusionsOur findings provide novel insights into PRV neuropathogenesis from the perspective of viral transport dynamics, and identify virus-induced intercellular conduits as a potential therapeutic target against infections of PRV and similar neuroinvasive viruses.