Lentiviruses such as HIV-1 traverse nuclear pore complexes (NPC) and infect terminally differentiated non-dividing cells, but how they do this is unclear. The cytoplasmic NPC protein Nup358/RanBP2 was identified as an HIV-1 co-factor in previous studies. Here we report that HIV-1 capsid (CA) binds directly to the cyclophilin domain of Nup358/RanBP2. Fusion of the Nup358/RanBP2 cyclophilin (Cyp) domain to the tripartite motif of TRIM5 created a novel inhibitor of HIV-1 replication, consistent with an interaction in vivo. In contrast to CypA binding to HIV-1 CA, Nup358 binding is insensitive to inhibition with cyclosporine, allowing contributions from CypA and Nup358 to be distinguished. Inhibition of CypA reduced dependence on Nup358 and the nuclear basket protein Nup153, suggesting that CypA regulates the choice of the nuclear import machinery that is engaged by the virus. HIV-1 cyclophilin-binding mutants CA G89V and P90A favored integration in genomic regions with a higher density of transcription units and associated features than wild type virus. Integration preference of wild type virus in the presence of cyclosporine was similarly altered to regions of higher transcription density. In contrast, HIV-1 CA alterations in another patch on the capsid surface that render the virus less sensitive to Nup358 or TRN-SR2 depletion (CA N74D, N57A) resulted in integration in genomic regions sparse in transcription units. Both groups of CA mutants are impaired in replication in HeLa cells and human monocyte derived macrophages. Our findings link HIV-1 engagement of cyclophilins with both integration targeting and replication efficiency and provide insight into the conservation of viral cyclophilin recruitment.
HIV-1 is able to replicate in primary human macrophages without stimulating innate immunity despite reverse transcription of genomic RNA into double stranded DNA, an activity that might be expected to trigger innate pattern recognition receptors (PRRs). We hypothesized that, if correctly orchestrated HIV-1 uncoating and nuclear entry is important for evasion of innate sensors, then manipulation of specific interactions between HIV-1 capsid (CA) and host factors that putatively regulate these processes should trigger PRRs and stimulate type 1 interferon secretion. Here we show that HIV-1 CA mutants N74D and P90A, which are impaired for interaction with cofactors Cleavage and Polyadenylation Specificity Factor subunit 6 (CPSF6) and cyclophilins (Nup358 and CypA) respectively(1-2), cannot replicate in primary human monocyte derived macrophages (MDM) because they trigger innate sensors leading to nuclear translocation of NFκB and IRF3, the production of soluble type-1 interferon (IFN) and induction of an antiviral state. Depletion of CPSF6 with shRNA expression allows wild type virus to trigger innate sensors and interferon production. In each case, suppressed replication is rescued by IFN-receptor blockade demonstrating a role for IFN in restriction. IFN production is dependent on viral reverse transcription but not integration suggesting that a viral reverse transcription product comprises the HIV-1 pathogen associated molecular pattern (PAMP). Finally, we show that we can pharmacologically induce wild type HIV-1 infection to stimulate IFN secretion and an antiviral state using a non-immunosuppressive cyclosporine analogue. We conclude that HIV-1 has evolved to utilize CPSF6 and cyclophilins to cloak its replication allowing evasion of innate immune sensors and induction of a cell autonomous innate immune response in primary human macrophages (Extended Data Fig 1).
Antibodies provide effective antiviral immunity despite the fact that viruses escape into cells when they infect. Here we show that antibodies remain attached to viruses after cell infection and mediate an intracellular immune response that disables virions in the cytosol. We have discovered that cells possess a cytosolic IgG receptor, tripartite motif-containing 21 (TRIM21), which binds to antibodies with a higher affinity than any other IgG receptor in the human body. TRIM21 rapidly recruits to incoming antibodybound virus and targets it to the proteasome via its E3 ubiquitin ligase activity. Proteasomal targeting leads to rapid degradation of virions in the cytosol before translation of virally encoded genes. Infection experiments demonstrate that at physiological antibody concentrations TRIM21 neutralizes viral infection. These results reveal an intracellular arm of adaptive immunity in which the protection mediated by antibodies does not end at the cell membrane but continues inside the cell to provide a last line of defense against infection. V iruses and their hosts have been coevolving for millions of years, and this has given rise to a complex system of immunity traditionally divided into innate and adaptive responses. Innate immunity comprises germ-line encoded receptors and effector mechanisms that recognize pathogen-associated molecular patterns (PAMPs) (1). The advantage of innate immunity is that it is fast and generic; however, viruses are adept at avoiding recognition by inhibiting innate immunity or by changing their molecular patterns. In contrast, adaptive immunity can clear a host of infection and provide protection against future infection. Unlike the PAMP receptors of innate immunity, adaptive immunity uses proteins such as antibodies to target pathogens. Antibodies are unique in the human body in that they evolve during the lifetime of an individual and can continue to target evolving pathogens (2). The weakness of adaptive immunity is that it can take 1 to 2 wk to reach full effectiveness. Moreover, the dogma of antibody immunity for the last 100 y has been that antibodies only provide extracellular protection (3). It is thought that once a virus has entered the cytosol of a cell, antibodies are helpless to prevent its infection.Recently we described an intracellular cytosolic protein called tripartite motif-containing 21 (TRIM21) that is capable of binding to an invariant region of antibody molecules via its PRYSPRY domain (4). We found this activity to be structurally, thermodynamically, and kinetically conserved across mammals (5). However, antibodies are extracellular proteins, as are all known mammalian IgG receptors (with the exception of FcRn, which is intracellular but not cytosolic). It therefore seemed incongruous to us that TRIM21 should be a universally conserved intracellular protein and yet be a high-affinity, highly specific IgG receptor. We hypothesized that there might be an antibody effector mechanism inside cells, mediated by TRIM21. Here we demonstrate the existence of...
Many mammalian species express restriction factors that confer host resistance to retroviral infection. Here we show that HIV-1 sensitivity to restriction factors is modulated by cyclophilin A (CypA), a host cell protein that binds the HIV-1 capsid protein (CA). In certain nonhuman primate cells, the CA-CypA interaction is essential for restriction: HIV-1 infectivity is increased >100-fold by cyclosporin A (CsA), a competitive inhibitor of the interaction, or by an HIV-1 CA mutation that disrupts CypA binding. Conversely, disruption of CA-CypA interaction in human cells reveals that CypA protects HIV-1 from the Ref-1 restriction factor. These findings suggest that HIV-1 has co-opted a host cell protein to counteract restriction factors expressed by human cells and that this adaptation can confer sensitivity to restriction in unnatural hosts. Manipulation of HIV-1 CA recognition by restriction factors promises to advance animal models and new therapeutic strategies for HIV-1 and AIDS.
The HIV-1 genome enters cells inside a shell comprised of capsid (CA) protein. Variation in CA sequence alters HIV-1 infectivity and escape from host restriction factors. However, apart from the Cyclophilin A-binding loop, CA has no known interfaces with which to interact with cellular cofactors. Here we describe a novel protein-protein interface in the N-terminal domain of HIV-1 CA, determined by X-ray crystallography, which mediates both viral restriction and host cofactor dependence. The interface is highly conserved across lentiviruses and is accessible in the context of a hexameric lattice. Mutation of the interface prevents binding to and restriction by CPSF6-358, a truncated cytosolic form of the RNA processing factor, cleavage and polyadenylation specific factor 6 (CPSF6). Furthermore, mutations that prevent CPSF6 binding also relieve dependence on nuclear entry cofactors TNPO3 and RanBP2. These results suggest that the HIV-1 capsid mediates direct host cofactor interactions to facilitate viral infection.
We also demonstrate that the activity of the murine restriction factor Fv1 depends on TRIM5␣ expression when Fv1 is expressed in human cells. Furthermore, a drug that modifies the behavior of the related promyelocytic leukemia protein PML specifically rescues infection by viruses restricted by human TRIM5␣. Alignment of the TRIM5␣ proteins from rhesus macaque and AGM indicates an 18-aa insertion. We speculate that this insertion may contribute to the broader specificity of the AGM TRIM5␣ restriction as compared with the human and rhesus macaque proteins.
Vertebrate evolution has taken place against a background of constant retrovirus infection, and much of the mammalian genome consists of endogenous retrovirus-like elements. Several host genes have evolved to control retrovirus replication, including Friend-virus-susceptibility-1, Fv1, on mouse chromosome 4 (refs 3, 4). The Fv1 gene acts on murine leukaemia virus at a stage after entry into the target cell but before integration and formation of the provirus. Although restriction is not absolute, Fv1 prevents or delays spontaneous or experimentally induced viral tumours. In vitro, Fv1 restriction leads to an apparent 50-1,000 fold reduction in viral titre. Genetic evidence implicates a direct interaction between the Fv1 gene product and a component of the viral preintegration complex, the capsid protein CA (refs 7-9). We have now cloned Fv1: the gene appears to be derived from the gag region of an endogenous retrovirus unrelated to murine leukaemia virus, implying that the Fv1 protein and its target may share functional similarities despite the absence of nucleotide-sequence homology.
We speculate that these activities have been selected for by retroviral epidemics in the distant past.
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