Viruses deliver their genomes to the host cell's nucleus where they can replicate. Like most viruses, the adenovirus 2 (Ad2) particle is far too large to squeeze through nuclear pores and the virus has had to find a clever way to 'squirt' its genome inside the nucleus. A study published in the latest issue of Nature Cell Biology reveals that Ad2 enlists the help of an unexpected cellular partner—histone H1—to achieve its goal.

Urs Greber and colleagues at the University of Zürich show that Ad2 docks to the nuclear pore via the nuclear-pore complex (NPC) receptor CAN/Nup214—the first receptor of the nuclear membrane identified to bind any virus. What happens then is remarkable. The virus disassembles slowly and transfers its genetic material through the nuclear pore while remaining attached to the NPC. But the CAN/Nup214 receptor is not the only cellular protein required for virus disassembly; the virus also gets help from an unlikely ally—the linker histone H1 protein.

H1 is a generic chromatin-binding protein implicated in transcriptional repression and higher-order chromatin structure. H1 does not stably bind chromatin but rather bounces back and forth between chromatin and nucleoplasm, allowing a small, unbound fraction of H1 to escape from the nucleus. Under normal circumstances, the fugitive H1 is retrieved by the cell's import system and brought back into the nucleus; in Ad2-infected cells, it assists in Ad2 disassembly.

The photographs show two human lung carcinoma cells, one of which was injected with anti-histone H1 antibodies. The injected cell can be seen in the photograph on the left, stained with an injection marker present in the antibody solution (purple). The photograph on the right shows the two cells stained with antibodies to the NPC (green) and Ad2 DNA (red). In the uninjected cell, Ad2 DNA can be seen bound to NPC on the nuclear membrane but also inside the nucleus; in the cell injected with anti-H1 antibodies all Ad2 DNA remains bound to the NPC.

There is another twist to the story. H1 does not promote Ad2 disassembly by interacting with viral DNA, but rather with the hexon protein that is part of the viral capsid. Specifically, H1 most likely binds a surface-exposed acidic cluster on hexon, possibly destabilizing its interactions with other capsid components and triggering the viral disassembly process. In uninfected cells, H1 is efficiently retrieved from the cytoplasm by the H1 import factors importin β and importin 7. As the disassembly of Ad2 also requires the same two importins, the authors speculate that hexon-bound H1 is recognized by the normal import system of the cell, and the complex is brought into the nucleus thereby destabilizing the viral capsid. The process triggers a gradual disassembly of the virus particle while it is held in place at the NPC, allowing the DNA that spills out of the virus to enter the nucleus.