Human T-cell lymphotropic virus type 1 (HTLV-1) is a deltaretrovirus and the most oncogenic pathogen. Many of the ~20 million HTLV-1 infected people will develop severe leukaemia or an ALS-like motor disease, unless a therapy becomes available. A key step in the establishment of infection is the integration of viral genetic material into the host genome, catalysed by the retroviral integrase (IN) enzyme. Here, we use X-ray crystallography and single-particle cryo-electron microscopy to determine the structure of the functional deltaretroviral IN assembled on viral DNA ends and bound to the B56γ subunit of its human host factor, protein phosphatase 2 A. The structure reveals a tetrameric IN assembly bound to two molecules of the phosphatase via a conserved short linear motif. Insight into the deltaretroviral intasome and its interaction with the host will be crucial for understanding the pattern of integration events in infected individuals and therefore bears important clinical implications.
UBR5 is a nuclear E3 ligase that ubiquitinates a vast range of substrates for proteasomal degradation. This HECT E3 ligase has recently been identified as an important regulator of oncogenes, e.g., MYC, but little is known about its structure or mechanisms of substrate engagement and ubiquitination. Here, we present the cryo-EM structure of the human UBR5, revealing a building block of an antiparallel dimer which can further assemble into larger oligomers. The large helical scaffold of the dimer is decorated with numerous protein-interacting motifs for substrate engagement. Using cryo-EM processing tools, we observe the dynamic nature of the domain movements of UBR5, which allows the catalytic HECT domain to reach engaged substrates. We characterise the proteasomal nuclear import factor AKIRIN2 as an interacting protein and propose UBR5 as an efficient ubiquitin chain elongator. This preference for ubiquitinated substrates permits UBR5 to function in several different signalling pathways and cancers. Together, our data expand on the limited knowledge of the structure and function of HECT E3s.
UBR5 is a nuclear E3 ligase that ubiquitinates a vast range of substrates for proteasomal degradation. This HECT domain‐containing ubiquitin ligase has recently been identified as an important regulator of oncogenes, e.g., MYC, but little is known about its structure or mechanisms of substrate engagement and ubiquitination. Here, we present the cryo‐EM structure of human UBR5, revealing an α‐solenoid scaffold with numerous protein–protein interacting motifs, assembled into an antiparallel dimer that adopts further oligomeric states. Using cryo‐EM processing tools, we observe the dynamic nature of the UBR5 catalytic domain, which we postulate is important for its enzymatic activity. We characterise the proteasomal nuclear import factor AKIRIN2 as an interacting protein and propose UBR5 as an efficient ubiquitin chain elongator. This preference for ubiquitinated substrates and several distinct domains for protein–protein interactions may explain how UBR5 is linked to several different signalling pathways and cancers. Together, our data expand on the limited knowledge of the structure and function of HECT E3 ligases.
2The Retroviridae delta-retrovirus genus includes the most oncogenic pathogen -human T-cell lymphotropic virus type 1 (HTLV-1)(1). Many of the ~20 million people infected with HTLV-1 will develop severe leukaemia (2) or an ALS-like motor disease (3) unless a therapy becomes available. A key step in the establishment of infection is the integration of viral genetic material into the host genome, catalysed by the viral integrase (IN) enzyme. Here we used X-ray crystallography and single-particle cryo-electron microscopy to determine the structure of functional delta-retroviral IN assembled on viral DNA ends and bound the B56g subunit of its human host factor, the protein phosphatase 2A (4). The structure reveals a tetrameric IN assembly bound to the phosphatase via a conserved short linear motif found within the extended linker connecting the catalytic core (CCD) and C-terminal (CTD) IN domains. Unexpectedly, all four IN subunits are involved in B56g binding, taking advantage of the flexibility of the CCD-CTD linkers. Our results fill the current gap in the structural understanding of the delta-retroviral integration machinery. Insight into the interactions between the delta-retroviral intasome and the host will be crucial for understanding the pattern of integration events in infected individuals and therefore bears important clinical implications.
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