Host Cofactors and Pharmacologic Ligands Share an Essential Interface in HIV-1 Capsid That Is Lost upon Disassembly

Price, Amanda J.; Jacques, D.A.; McEwan, William A.; Fletcher, Adam J.; Essig, Sebastian; Chin, Jason W.; Halambage, Upul D.; Aiken, Christopher; James, Leo C.

doi:10.1371/journal.ppat.1004459

Cited by 262 publications

(556 citation statements)

References 45 publications

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“…Paradoxically, PF74 promotes the assembly of recombinant CA in vitro (29), yet the compound destabilizes the viral capsid in native HIV-1 cores (32) and in target cells (32,33). PF74 does not appear to significantly perturb the structure of the CA hexamer, yet the compound binds to the hexamer with higher affinity than to dissociated CA subunits, consistent with the drug target being the assembled capsid (30,31). Partial resistance to PF74 was conferred by 5 mutations in the CA NTD, three of which were in the PF74 binding pocket, and reduced the binding of the compound (29,32).…”

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confidence: 70%

“…However, loss of binding was not strictly correlated with the degree of resistance, suggesting that coli, as described previously (34,36). The affinities of PF74 for purified CA hexamers were determined by equilibrium dialysis and isothermal titration calorimetry (ITC), as reported previously (30,34). The affinity of Nup153 and CPSF6 peptides for CA hexamers was determined by ITC (30,37).…”

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confidence: 70%

“…Of these, PF74 has received considerable attention. PF74 binds to a pocket formed at the interface between the CA amino-terminal (N-terminal) domain (NTD) and the C-terminal domain (CTD) between adjacent subunits in the CA hexamer (29)(30)(31). Paradoxically, PF74 promotes the assembly of recombinant CA in vitro (29), yet the compound destabilizes the viral capsid in native HIV-1 cores (32) and in target cells (32,33).…”

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confidence: 99%

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HIV-1 Resistance to the Capsid-Targeting Inhibitor PF74 Results in Altered Dependence on Host Factors Required for Virus Nuclear Entry

Zhou

Price

Halambage

et al. 2015

J Virol

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During HIV-1 infection of cells, the viral capsid plays critical roles in reverse transcription and nuclear entry of the virus. The capsid-targeting small molecule PF74 inhibits HIV-1 at early stages of infection. HIV-1 resistance to PF74 is complex, requiring multiple amino acid substitutions in the viral CA protein. Here we report the identification and analysis of a novel PF74-resistant mutant encoding amino acid changes in both domains of CA, three of which are near the pocket where PF74 binds. Interestingly, the mutant virus retained partial PF74 binding, and its replication was stimulated by the compound. The mutant capsid structure was not significantly perturbed by binding of PF74; rather, the mutations inhibited capsid interactions with CPSF6 and Nup153 and altered HIV-1 dependence on these host factors and on TNPO3. Moreover, the replication of the mutant virus was markedly impaired in activated primary CD4 ؉ T cells and macrophages. Our results suggest that HIV-1 escapes a capsid-targeting small molecule inhibitor by altering the virus's dependence on host factors normally required for entry into the nucleus. They further imply that clinical resistance to inhibitors targeting the PF74 binding pocket is likely to be strongly limited by functional constraints on HIV-1 evolution. IMPORTANCE The HIV-1 capsid plays critical roles in early steps of infection and is an attractive target for therapy. Here we show that selection for resistance to a capsid-targeting small molecule inhibitor can result in viral dependence on the compound. The mutant virus was debilitated in primary T cells and macrophages-cellular targets of infection in vivo.The mutations also altered the virus's dependence on cellular factors that are normally required for HIV-1 entry into the nucleus. This work provides new information regarding mechanisms of HIV-1 resistance that should be useful in efforts to develop clinically useful drugs targeting the HIV-1 capsid.T he HIV-1 capsid plays multiple roles during the early stages of infection, all of which are critical for optimal infectivity. The conical viral capsid, composed of the CA protein, consists of a lattice of hexamers interspersed with 12 pentamers, which provide curvature and closure of the ends of the cone (reviewed in reference 1). Studies of the viral capsid have received much attention of late, with the identification of inhibitory host proteins that directly target the viral capsid (2-8) and elucidation of high-resolution structures of the CA hexamer and pentamer and tubular assemblies of CA resulting in working structural models of the entire viral capsid (9-11). Several positive-acting host factors have been reported to bind the viral capsid, including cyclophilin A, CPSF6, TNPO3, Nup153, and RanBP2 (12-21); in general, these appear to facilitate infection by coordinating entry of the viral preintegration complex into the nucleus, where they may also play a role in chromatin targeting during integration. Moreover, the host factors CPSF6 and cyclophilin A contribut...

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HIV-1 Resistance to the Capsid-Targeting Inhibitor PF74 Results in Altered Dependence on Host Factors Required for Virus Nuclear Entry

Zhou

Price

Halambage

et al. 2015

J Virol

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“…Full-length CPSF6 is found only in the nucleus of NIH3T3 cells, while the CPSF6 C-terminal truncated protein (CPSF6-358) is localized to the cytosol, suggesting that the RS-like domain is required for its nuclear transport . Price et al (2014) suggested that CPSF6 binds to the N-terminal region of monomeric HIV-1 CA and accommodates NUP153 only when CA exists in its assembled hexameric form, resulting in both being transported into the nucleus by TNPO3 (Price et al 2014). Thus, CPSF6 interacts with intact cores, which are larger than the nuclear pore channel, and impedes nuclear entry.…”

Section: Cleavage and Polyadenylation Specific Factor 6 (Cpsf6)mentioning

confidence: 99%

“…Thus, CPSF6 interacts with intact cores, which are larger than the nuclear pore channel, and impedes nuclear entry. However, CA N74D is insensitive to CPSF6-358 restriction by preventing interaction of CA with CPSF6-358 because N74D requires ligand-specific contact and binds to CPSF6 but not NUP153 (Price et al 2012(Price et al , 2014. The protein interface is conserved both structurally and functionally across diverse lentiviruses, including HIV-2, SIVmac, and FIV.…”

Section: Cleavage and Polyadenylation Specific Factor 6 (Cpsf6)mentioning

confidence: 99%

Cellular and viral determinants of retroviral nuclear entry

2016

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Retroviruses must integrate their cDNA into the host genome to generate proviruses. Viral DNA-protein complexes interact with cellular proteins and produce pre-integration complexes, which carry the viral genome and cross the nuclear pore channel to enter the nucleus and integrate viral DNA into host chromosomal DNA. If the reverse transcripts fail to integrate, linear or circular DNA species such as 1-and 2-long terminal repeats are generated. Such complexes encounter numerous cellular proteins in the cytoplasm, which restrict viral infection and protect the nucleus. To overcome host cell defenses, the pathogens have evolved several evasion strategies. Viral proteins often contain nuclear localization signals, allowing entry into the nucleus. Among more than 1000 proteins identified as required for HIV infection by RNA interference screening, karyopherins, cleavage and polyadenylation specific factor 6, and nucleoporins have been predominantly studied. This review discusses current opinions about the synergistic relationship between the viral and cellular factors involved in nuclear import, with focus on the unveiled mysteries of the host-pathogen interaction, and highlights novel approaches to pinpoint therapeutic targets.

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Labeling of virus components for advanced, quantitative imaging analyses

et al. 2016

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In recent years, investigation of virus-cell interactions has moved from ensemble measurements to imaging analyses at the single-particle level. Advanced fluorescence microscopy techniques provide single-molecule sensitivity and subdiffraction spatial resolution, allowing observation of subviral details and individual replication events to obtain detailed quantitative information. To exploit the full potential of these techniques, virologists need to employ novel labeling strategies, taking into account specific constraints imposed by viruses, as well as unique requirements of microscopic methods. Here, we compare strengths and limitations of various labeling methods, exemplify virological questions that were successfully addressed, and discuss challenges and future potential of novel approaches in virus imaging.

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Host Cofactors and Pharmacologic Ligands Share an Essential Interface in HIV-1 Capsid That Is Lost upon Disassembly

Cited by 262 publications

References 45 publications

HIV-1 Resistance to the Capsid-Targeting Inhibitor PF74 Results in Altered Dependence on Host Factors Required for Virus Nuclear Entry

HIV-1 Resistance to the Capsid-Targeting Inhibitor PF74 Results in Altered Dependence on Host Factors Required for Virus Nuclear Entry

Cellular and viral determinants of retroviral nuclear entry

Labeling of virus components for advanced, quantitative imaging analyses

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