The HIV-1 integration reaction proceeds in two steps, both of which are carried out by integrase (IN). In the first step (3' processing or 3'P), IN removes a small number of nucleotides (usually 2) from the 3' ends of the linear viral DNA. In the second step, IN inserts the newly trimmed 3' ends of the viral DNA into host DNA; this reaction is called strand transfer, or ST. IN has only one active site that carries out both the 3'P and ST reactions. There are crystal structures of prototype foamy virus IN that show similarities and differences in the way that IN interacts with the viral DNA substrate in the 3'P and ST reactions. Because integration is an essential step in the virus life cycle, IN is an important target for antiretroviral drugs. The three approved anti-IN drugs (raltegravir, elvitegratir, and dolutegravir) all target the ST reaction, and, are, for this reason, sometimes called INSTIs. Despite their relatively recent development, INSTIs are potent drugs with few side effects and are becoming increasingly important in antiretroviral therapy (ART). Cabotegravir has been formulated with rilpivirine and this combination has shown promise in long-term treatment strategies. However, as is the case with all anti-HIV drugs, INSTIs select for resistant strains of HIV. We are focusing on developing new anti-IN compounds that show little or no toxicity, and are broadly effective against the known drug-resistant mutants. We have made excellent progress in developing IN inhibitors that have low nanomolar potency in a one-round assay, retain potency against a broad panel of resistant mutants, and show little or no toxicity in cultured cells. Although we continue to make and test IN inhibitors, we have made sufficient progress that we have, with help from the NCI, begun to do pharmacokinetic testing on the best compounds. We also showed that either a suboptimal dose of IN inhibitors, or drug resistance mutations in IN, can cause aberrant integrations that can involve a deletion in the end of the viral DNA, can lead to deletions, duplications, or inversions of the host DNA, and can occasionally cause insertions of sequences from other chromosomes. _____The development of new, broadly effective anti-HIV drugs that have little or no toxicity is a high-priority NIH goal for AIDS research. _____There are millions of retroviral integration sites in the host cell genome, but for many retroviruses, integration is far from random; we have been studying how HIV selects its integration sites. In the last few years, we have become increasingly interested in understanding what governs the distribution of HIV integration sites, both in cultured cells and in samples from patients. In the work that was done in cultured cells, we were part of a collaboration that investigated the ability of the host protein HRP2 to replace LEDGF in directing HIV integration to the bodies of highly expressed genes, and we showed that the host factor CPSF6 plays a key role in guiding the preintegration complex to regions of the genome that are gene rich and contain numerous highly expressed genes. LEDGF is a bipartite protein, in which the C-terminus binds IN and the N-terminus binds chromatin. We and others have used integration site analysis to show that there is extensive clonal expansion of HIV-infected cells in patients on ART, and that, in some cases, the integration sites can contribute to this expansion. We also showed that highly expanded clones can carry infectious proviruses, and release virions into the blood. Thus, clonal expansion of infected cells can contribute to the reservoir that has made it impossible to cure HIV infections with the currently available drugs. Although it has been proposed that viral replication plays an essential role in persistence and in the maintenance of the reservoir, even in fully compliant patients on successful ART, we think that the weight of the evidence supports the idea that there are patients in which ART completely blocks viral replication. Thus, it is important to understand the processes that allow infectious proviruses to persist even if viral replication is completely blocked. ____Our data provide a better understanding of the generation, maintenance, and persistence of the reservoir that has made it impossible to cure patients with the available anti-HIV drugs. However, there are limitations to the samples that can be obtained from HIV-infected patients. For that reason, we developed a simian immunodeficiency virus (SIV)/rhesus macaque model in collaboration with Dr. Jeffrey Lifson (Leidos Biomedical Research, Inc.) and showed that SIV-infected cells can clonally expand in infected macaques. _____ We and others have made chimeric proteins in which the IN-binding portion of LEDGF is fused to any one of a variety of chromatin-binding proteins. This approach makes it possible to use the fusion protein to redirect HIV integration (in cells that lack LEDGF) and, by determining the distribution of the HIV integration sites, we also determine the distribution of the chromatin-binding factor used to create the fusion. We have used this strategy, HIV integration targeting sequencing (HIT-Seq), to determine the distribution, on chromatin, of both wild-type (WT) and mutant forms of some key chromatin-binding proteins. _____The technology that we use to isolate large numbers of HIV integration sites was developed as part of the project in which we use redirected HIV integration to map the binding sites of host proteins, both WT and mutant, on chromatin. Although this HIT-Seq technology works well and has allowed us to answer some key questions about where and how important host factors bind to chromatin, we have redirected the personnel and resources that were dedicated to the HIT-Seq project to projects in which we are mapping HIV integration sites in patients and SIV integration sites in macaques. ______PATENTS LINKED TO THIS PROJECT: (1) Zhao XZ, Smith S, Metifiot M, Johnson B, Marchand C, Hughes SH, Pommier Y, Burke TR Jr: Compounds for Inhibiting Drug-Resistant Strains of HIV-1 Integrase. U.S. Patent #9,676,771 issued June 13, 2017. (2) Zhao XZ, Smith S, Metifiot M, Johnson B, Marchand C, Hughes SH, Pommier Y, Burke TR Jr: Compounds for Inhibiting Drug-Resistant Strains of HIV-1 Integrase. U.S. Patent Application No. 15/589,590 filed May 8, 2017 (Divisional of U.S. Application No. 14/891,309) [NIH ref. E-093-2013/2-US-10]. (3) Zhao XZ, Smith S, Metifiot M, Johnson B, Marchand C, Hughes SH, Pommier Y, Burke TR Jr: Compounds for Inhibiting Drug-Resistant Strains of HIV-1 Integrase. U.S. Provisional Patent Application No. 61/824,306 filed May 16, 2013 [NIH ref. E-093-2013/0-US-01]. (4) Zhao XZ, Hughes S, Vu B-HC, Smith S, Johnson B, Pommier Y, Burke TR Jr. HIV Integrase Inhibitory Oxoisoindoline Sulfonamides. U.S. Provisional Patent Application No. 61/511,916 filed July 26, 2011 (PCT Patent Application No. PCT/US2012/048169 filed July 25, 2012; International Publication Number WO2013016441 A1 published January 31, 2013). _____Corresponds to Hughes Project 2 in the July 2016 site visit report of the HIV Dynamics and Replication Program]

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Investigator-Initiated Intramural Research Projects (ZIA)
Project #
1ZIABC011426-06
Application #
9556568
Study Section
Project Start
Project End
Budget Start
Budget End
Support Year
6
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Basic Sciences
Department
Type
DUNS #
City
State
Country
Zip Code
Smith, Steven J; Zhao, Xue Zhi; Burke Jr, Terrence R et al. (2018) Efficacies of Cabotegravir and Bictegravir against drug-resistant HIV-1 integrase mutants. Retrovirology 15:37
Roth, Theodore L; Puig-Saus, Cristina; Yu, Ruby et al. (2018) Reprogramming human T cell function and specificity with non-viral genome targeting. Nature 559:405-409
Smith, Steven J; Zhao, Xue Zhi; Burke Jr, Terrence R et al. (2018) HIV-1 Integrase Inhibitors That Are Broadly Effective against Drug-Resistant Mutants. Antimicrob Agents Chemother 62:
Zhao, Xue Zhi; Smith, Steven J; Maskell, Daniel P et al. (2017) Structure-Guided Optimization of HIV Integrase Strand Transfer Inhibitors. J Med Chem 60:7315-7332
Bui, John K; Sobolewski, Michele D; Keele, Brandon F et al. (2017) Proviruses with identical sequences comprise a large fraction of the replication-competent HIV reservoir. PLoS Pathog 13:e1006283
Varadarajan, Janani; McWilliams, Mary Jane; Mott, Bryan T et al. (2016) Drug resistant integrase mutants cause aberrant HIV integrations. Retrovirology 13:71
Boritz, Eli A; Darko, Samuel; Swaszek, Luke et al. (2016) Multiple Origins of Virus Persistence during Natural Control of HIV Infection. Cell 166:1004-1015
Hughes, Stephen H; Coffin, John M (2016) What Integration Sites Tell Us about HIV Persistence. Cell Host Microbe 19:588-98
Shao, Wei; Shan, Jigui; Kearney, Mary F et al. (2016) Retrovirus Integration Database (RID): a public database for retroviral insertion sites into host genomes. Retrovirology 13:47
Métifiot, Mathieu; Johnson, Barry C; Kiselev, Evgeny et al. (2016) Selectivity for strand-transfer over 3'-processing and susceptibility to clinical resistance of HIV-1 integrase inhibitors are driven by key enzyme-DNA interactions in the active site. Nucleic Acids Res 44:6896-906

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