Analysis of the intrinsic chromatin binding property of HIV-1 integrase and its regulation by LEDGF/p75 using human chromosomes spreads

ABSTRACTRetroviral integration requires the stable insertion of the viral genome into the host chromosomes. During this process, the functional integration complex must associate with cellular chromatin via the interaction between retroviral integrase and nucleosomes. The final association between the HIV-1 integration complex and the nucleosomal target DNA remains unclear and may involve the chromatin-binding properties of both the retroviral integrase and its cellular cofactor LEDGF/p75. To date, there is no experimental system allowing the direct monitoring of this protein association with chromatin to depict the molecular mechanism of this process fully. To investigate this and understand the LEDGF/p75-mediated chromatin tethering of HIV-1 integrase further, we used both biochemical approaches and an unedited chromosome-binding assays. Our study revealed that retroviral IN has an intrinsic ability to bind and recognize specific chromatin regions even in the absence of its cofactor. We also showed that this integrase chromatin-binding property was modulated by the interaction with its cofactor LEDGF/p75, which redirected the enzyme to alternative chromatin regions. Using these approaches, we also better determined the chronology of efficient LEDGF/p75-mediated targeting of HIV-1 integrase to chromatin. In addition to supporting a chromatin-binding function of the integrase protein acting in concert with LEDGF/p75 for the optimal association with the nucleosomal substrate, our work precisely elucidates the mechanism of action of LEDGF/p75 in this crucial integration step.

Cryo-EM structure of the deltaretroviral intasome in complex with the PP2A regulatory subunit B56γ

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.

Targeting Integrase Enzyme: A Therapeutic Approach to Combat HIV Resistance

Global Human Immunodeficiency Virus (HIV) statistics by the World Health Organization (WHO) for the year 2017 was estimated to be 36.9 (31.1-43.9) million. Antiviral drug resistance poses a serious threat to public health and requires immediate action. Retroviral Integrase (IN), a component enzyme in the retroviral pre-integration complex (PIC) enables a retrovirus to incorporate its genetic material into the host DNA. Development of resistance by the current integrases invites immediate attention of the drug discovery community for the development of new second-generation Integrase Strand Transfer Inhibitors (INSTIs). It will exhibit greater efficacy against Elvitegravir (EVG) and Raltegravir (RAL) resistant strains of HIV. This review focuses on the mechanism, importance of integrase structure, function and current research on small molecule inhibitors of integrase to overcome drug resistance. The molecular mechanism of retroviral integrase inhibition and the evolution of resistance are also explored.

Two-long terminal repeat (LTR) DNA circles are a substrate for HIV-1 integrase

Integration of the HIV-1 DNA into the host genome is essential for viral replication and is catalyzed by the retroviral integrase. To date, the only substrate described to be involved in this critical reaction is the linear viral DNA produced in reverse transcription. However, during HIV-1 infection, two-long terminal repeat DNA circles (2-LTRcs) are also generated through the ligation of the viral DNA ends by the host cell's nonhomologous DNA end-joining pathway. These DNAs contain all the genetic information required for viral replication, but their role in HIV-1's life cycle remains unknown. We previously showed that both linear and circular DNA fragments containing the 2-LTR palindrome junction can be efficiently cleaved in vitro by recombinant integrases, leading to the formation of linear 3′-processed–like DNA. In this report, using in vitro experiments with purified proteins and DNAs along with DNA endonuclease and in vivo integration assays, we show that this circularized genome can also be efficiently used as a substrate in HIV-1 integrase-mediated integration both in vitro and in eukaryotic cells. Notably, we demonstrate that the palindrome cleavage occurs via a two-step mechanism leading to a blunt-ended DNA product, followed by a classical 3′-processing reaction; this cleavage leads to integrase-dependent integration, highlighted by a 5-bp duplication of the host genome. Our results suggest that 2-LTRc may constitute a reserve supply of HIV-1 genomes for proviral integration.

A supramolecular assembly mediates lentiviral DNA integration

Retroviral integrase (IN) functions within the intasome nucleoprotein complex to catalyze insertion of viral DNA into cellular chromatin. Using cryo–electron microscopy, we now visualize the functional maedi-visna lentivirus intasome at 4.9 angstrom resolution. The intasome comprises a homo-hexadecamer of IN with a tetramer-of-tetramers architecture featuring eight structurally distinct types of IN protomers supporting two catalytically competent subunits. The conserved intasomal core, previously observed in simpler retroviral systems, is formed between two IN tetramers, with a pair of C-terminal domains from flanking tetramers completing the synaptic interface. Our results explain how HIV-1 IN, which self-associates into higher-order multimers, can form a functional intasome, reconcile the bulk of early HIV-1 IN biochemical and structural data, and provide a lentiviral platform for design of HIV-1 IN inhibitors.