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Abstract

Human Immunodeficiency virus type 1 (HIV-1) is a lentivirus that infects non-dividing cells of the immune system. In non-dividing cells, nuclear import of the viral genome occurs through the nuclear pore complex (NPC), a large macromolecular assembly that forms a channel of ~40 nm across the nuclear envelope. This process requires interactions between NPC components known as nucleoporins and CA (capsid) proteins of HIV-1 post-fusion complexes. In mature HIV-1 virions, multiple copies of CA assemble into a lattice of hexamers and pentamers, forming a cone-shaped capsid core of ~60 nm in width and ~110 nm in length encasing the viral genome. Because of its large size, it was generally believed that the capsid core entirely or partially disassembled prior to its translocation through the NPC. However, nuclear entry and uncoating are rare events and challenging to characterize and therefore subject to a long-standing debate.

Here, cryo-electron tomography (cryo-ET) on cryo-focused ion beam (FIB) milled T-cells was combined with subtomogram averaging (SA) to study the ultrastructure of HIV-1 capsids in the process of nuclear entry. Using a HIV-1 variant arrested at the nuclear pore due to a defect in binding of the CA lattice to the host cell protein CPSF6, snapshots of HIV-1 nuclear entry at multiple stages were captured. Reverse transcription-competent HIV-1 complexes were identified in the cytosol, docking to and within the NPC, and in the nucleoplasm of T cells. Surprisingly, in the cytosol and at the NPC, the viral complexes retained cone-shaped capsids highly resembling in size and geometry the mature capsid cores within intact virions. The density at their interior suggested that they were associated with the viral genome. The cone-shape capsids deeply enter into the NPC central channel with their narrow ends. The hexameric lattices of these capsids were intact or nearly intact. These findings argued against the current models of uncoating in the cytosol or at the NPC and rather supported translocation of intact HIV-1 capsids through the NPC. Instead, HIV-1 capsids uncoat in the nucleus of T cells. Inside the nucleus, tube-shape fragments still containing few lattice elements were observed. The lack of density at their inside suggested that the viral genome was released from these complexes. Uncoating may thus occur through the partial opening and remodeling of the hexameric lattices of HIV-1 capsids, rather than a step-wise disassembly. To address how an intact HIV-1 capsid can enter the central channel of NPC, the human NPC from T cells was structurally analyzed in cellulo by SA. The NPC overall structure was not altered upon infection but rather dilated in comparison to the structure previously obtained from purified envelopes. The diameter of the central channel of NPC in T cells corresponded to ~64 nm, suggesting that the translocation of intact HIV-1 capsid through the NPC is geometrically possible. The dilated conformation of NPCs in T cells is independent of HIV-1 infection, but represents a physiological condition of actively transporting NPCs.