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Abstract
HIV-1 often acquires drug-resistant mutations in spite of the benefits of antiretroviral therapy (ART). HIV-1 integrase (IN) is essential for the concerted integration of HIV-1 DNA into the host genome. IN further contributes to HIV-1 RNA binding, which is required for HIV-1 maturation. Non-catalytic-site integrase inhibitors (NCINIs) have been developed as allosteric IN inhibitors, which perform anti-HIV-1 activity by a multimodal mode of action such as inhibition of the IN-lens epithelium-derived growth factor (LEDGF)/p75 interaction in the early stage and disruption of functional IN multimerization in the late stage of HIV-1 replication. Here, we show that IN undergoes an adaptable conformational change to escape from NCINIs. We observed that NCINI-resistant HIV-1 variants have accumulated 4 amino acid mutations by passage 26 (P26) in the IN-encoding region. We employed high-performance liquid chromatography (HPLC), thermal stability assays, and X-ray crystallographic analysis to show that some amino acid mutations affect the stability and/or dimerization interface of the IN catalytic core domains (CCDs), potentially resulting in the severely decreased multimerization of full-length IN proteins (IN undermultimerization). This undermultimerized IN via NCINI-related mutations was stabilized by HIV-1 RNA and restored to the same level as that of wild-type HIV-1 in viral particles. Recombinant HIV-1 clones with IN undermultimerization propagated similarly to wild-type HIV-1. Our study revealed that HIV-1 can eventually counteract NCINI-induced IN overmultimerization by IN undermultimerization as one of the escape mechanisms. Our findings provide information on the understanding of IN multimerization with or without HIV-1 RNA and may influence the development of anti-HIV-1 strategies.IMPORTANCE Understanding the mechanism of HIV-1 resistance to anti-HIV-1 drugs could lead to the development of novel drugs with increased efficiency, resulting in more effective ART. ART composed of more potent and long-acting anti-HIV-1 drugs can greatly improve drug adherence and also provide HIV-1 prevention such as preexposure prophylaxis. NCINIs with a multimodal mode of action exert potent anti-HIV-1 effects through IN overmultimerization during HIV-1 maturation. However, HIV-1 can acquire some mutations that cause IN undermultimerization to alleviate NCINI-induced IN overmultimerization. This undermultimerized IN was efficiently stabilized by HIV-1 RNA and restored to the same level as that of wild-type HIV-1. Our findings revealed that HIV-1 eventually acquires such a conformational escape reaction to overcome the unique NCINI actions. The investigation into drug-resistant mutations associated with HIV-1 protein multimerization may facilitate the elucidation of its molecular mechanism and functional multimerization, allowing us to develop more potent anti-HIV-1 drugs and unique treatment strategies.
Highlights
Human immunodeficiency virus type 1 (HIV-1) infection has been a chronic infectious disease
Characteristics of recombinant HIV-1NL4-3 clones carrying NCINI-related resistance mutations Several potent NCINIs induce IN over-multimerization, leading to the production of immature viruses, but are not related to Gag and Gag-Pol proteolytic processing (Jurado et al, 2013; Sharma et al, 2014) (Figure 3—figure supplement 3A). In order to investigate characteristics of HIV-1 carrying the NCINI-3 resistance mutations with IN under-multimerization, we examined the process of viral production including Gag and Gag-Pol proteolytic processing, and viral maturation of the recombinant HIV-1 INK173Q, -INP15, -INP20, and -INP26 clones
Binding affinity (KD value) of NCINI-3 to CCDWT was 0.95 μM, while that of CCDA128T and CCDK173Q decreased by 2.10 μM (2.2-folds) and 1.41 μM (1.5-folds), respectively (Figure 4D, E). Further, CCDP15 carrying the double mutations (A128T/K173Q) did not interact under 10 μM NCINI-3 (Figure 4D, E). These results indicate that such conformational alterations of CCDA128T, CCDK173Q, and CCDP15 proteins may affect NCINI binding indirectly
Summary
Human immunodeficiency virus type 1 (HIV-1) infection has been a chronic infectious disease. Four FDA-approved integrase strand transfer inhibitors (INSTIs), raltegravir (RAL), elvitegravir (ELG), dolutegravir (DTG), and bictegravir (BTG) which target the active site of IN are more potent and well tolerated than other classes of anti-HIV-1 drugs due to the lack of homologous human proteins, allowing these INSTIs to have been widely used for clinical HIV-1 treatment. A single tablet containing only two anti-HIV-1 drugs (DTG and rilpivirine (RPV) - second-generation non-nucleoside reverse transcriptase inhibitor (NNRTIs)) was approved by the FDA in 2018 as the first maintenance therapy for HIV-1 infection (Dowers et al, 2018). The study of drug-resistant mutations with respect to such allosteric inhibitors may help to elucidate how HIV-1 proteins undergo functional multimerization, which may aid in the development of novel anti-HIV-1 drugs and unique treatment strategies
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