Nucleus softens during herpesvirus infection

  1. Aapo Tervonen
  2. Visa Ruokolainen
  3. Simon Leclerc
  4. Katie Tieu
  5. Sébastien Lyonnais
  6. Henri Niskanen
  7. Jian-Hua Chen
  8. Alka Gupta
  9. Minna U Kaikkonen
  10. Carolyn A Larabell
  11. Delphine Muriaux
  12. Salla Mattola
  13. Daniel E Conway
  14. Teemu O Ihalainen
  15. Vesa Aho
  16. Maija Vihinen-Ranta
1 evaluations Published on
Read the full article Related papers
This article on Sciety

Abstract

Nuclear mechanics is remodeled not only by extracellular forces but also by internal modifications, such as those induced by viral infections. During herpes simplex virus type 1 infection, the nuclear structures undergo drastic reorganization, but little is known about how nuclear mechanobiology changes as a result. We show that the nucleus softens dramatically during the infection. To understand the phenomenon, we used advanced microscopy and computational modeling. We discovered that the enlarged viral replication compartment had a low biomolecular density, partially explaining the observed nuclear softening. The mobility of the nuclear lamina decreased, which suggests increased rigidity and an inability to induce softening. However, computational modeling supported by experimental data showed that reduced outward forces, such as cytoskeletal pull and intranuclear osmotic pressure acting both on and within the nucleus, can explain the decreased nuclear stiffness. Our findings reveal that during infection, the nucleus is subject to changes in multiple mechanical forces, leading to decreased nuclear stiffness.

Author Summary:

DNA viruses take over the host cell nucleus, inducing dramatic structural modifications. There is currently very little knowledge of how the progression of viral infection modifies the mechanical properties of the nucleus, which are essential for various cellular processes, including gene expression and cell migration. Here, we show that the nucleus softens when herpesvirus infection progresses. We discovered that the viral replication compartment established in the central parts of the nucleus had a low biomolecular density, which may contribute to the nuclear softening. The shape and motion of the nuclear lamina suggested that it became more rigid, indicating that another mechanism was involved in the decreased elasticity. Our mechanical simulations and experiments showed that a reduction in outward forces, such as actin cytoskeleton pull or osmotic pressure, is the most likely factor in the nuclear softening. Our study provides new insights into the effects of DNA viruses on the mechanics of host cell nuclei, significantly expanding the knowledge of viral infection mechanobiology.

Related articles

Related articles are currently not available for this article.