Single atom changes in newly synthesized HIV protease inhibitors reveal structural basis for extreme affinity, high genetic barrier, and adaptation to the HIV protease plasticity

HIV-1 protease inhibitors (PIs), such as darunavir (DRV), are the key component of antiretroviral therapy. However, HIV-1 often acquires resistance to PIs. Here, seven novel PIs were synthesized, by introducing single atom changes such as an exchange of a sulfur to an oxygen, scission of a single bo...

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Veröffentlicht in:	Scientific reports 2020-06, Vol.10 (1), p.10664-10664, Article 10664
Hauptverfasser:	Bulut, Haydar, Hattori, Shin-ichiro, Aoki-Ogata, Hiromi, Hayashi, Hironori, Das, Debananda, Aoki, Manabu, Davis, David A., Rao, Kalapala Venkateswara, Nyalapatla, Prasanth R., Ghosh, Arun K., Mitsuya, Hiroaki
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Schlagworte:	631/154 631/535 631/92 Adaptation Amino acids Antiretroviral agents Antiretroviral drugs Antiretroviral therapy Antiviral agents Benzene Cell Line Cell permeability Darunavir - pharmacology Drug Resistance, Viral - drug effects Fluorine HIV HIV Infections - drug therapy HIV Protease - metabolism HIV Protease Inhibitors - pharmacology HIV-1 - drug effects Human immunodeficiency virus Humanities and Social Sciences Humans multidisciplinary Plasticity Proteinase inhibitors Science Science (multidisciplinary) Sulfur Virus Replication - drug effects
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creator	Bulut, Haydar Hattori, Shin-ichiro Aoki-Ogata, Hiromi Hayashi, Hironori Das, Debananda Aoki, Manabu Davis, David A. Rao, Kalapala Venkateswara Nyalapatla, Prasanth R. Ghosh, Arun K. Mitsuya, Hiroaki
description	HIV-1 protease inhibitors (PIs), such as darunavir (DRV), are the key component of antiretroviral therapy. However, HIV-1 often acquires resistance to PIs. Here, seven novel PIs were synthesized, by introducing single atom changes such as an exchange of a sulfur to an oxygen, scission of a single bond in P2′-cyclopropylaminobenzothiazole (or -oxazole), and/or P1-benzene ring with fluorine scan of mono- or bis-fluorine atoms around DRV’s scaffold. X-ray structural analyses of the PIs complexed with wild-type Protease (PR WT ) and highly-multi-PI-resistance-associated PR DRV R P51 revealed that the PIs better adapt to structural plasticity in PR with resistance-associated amino acid substitutions by formation of optimal sulfur bond and adaptation of cyclopropyl ring in the S2′-subsite. Furthermore, these PIs displayed increased cell permeability and extreme anti-HIV-1 potency compared to DRV. Our work provides the basis for developing novel PIs with high potency against PI-resistant HIV-1 variants with a high genetic barrier.
doi_str_mv	10.1038/s41598-020-65993-z
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Our work provides the basis for developing novel PIs with high potency against PI-resistant HIV-1 variants with a high genetic barrier.</description><subject>631/154</subject><subject>631/535</subject><subject>631/92</subject><subject>Adaptation</subject><subject>Amino acids</subject><subject>Antiretroviral agents</subject><subject>Antiretroviral drugs</subject><subject>Antiretroviral therapy</subject><subject>Antiviral agents</subject><subject>Benzene</subject><subject>Cell Line</subject><subject>Cell permeability</subject><subject>Darunavir - pharmacology</subject><subject>Drug Resistance, Viral - drug effects</subject><subject>Fluorine</subject><subject>HIV</subject><subject>HIV Infections - drug therapy</subject><subject>HIV Protease - metabolism</subject><subject>HIV Protease Inhibitors - pharmacology</subject><subject>HIV-1 - drug effects</subject><subject>Human immunodeficiency virus</subject><subject>Humanities and Social Sciences</subject><subject>Humans</subject><subject>multidisciplinary</subject><subject>Plasticity</subject><subject>Proteinase inhibitors</subject><subject>Science</subject><subject>Science (multidisciplinary)</subject><subject>Sulfur</subject><subject>Virus Replication - 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However, HIV-1 often acquires resistance to PIs. Here, seven novel PIs were synthesized, by introducing single atom changes such as an exchange of a sulfur to an oxygen, scission of a single bond in P2′-cyclopropylaminobenzothiazole (or -oxazole), and/or P1-benzene ring with fluorine scan of mono- or bis-fluorine atoms around DRV’s scaffold. X-ray structural analyses of the PIs complexed with wild-type Protease (PR WT ) and highly-multi-PI-resistance-associated PR DRV R P51 revealed that the PIs better adapt to structural plasticity in PR with resistance-associated amino acid substitutions by formation of optimal sulfur bond and adaptation of cyclopropyl ring in the S2′-subsite. Furthermore, these PIs displayed increased cell permeability and extreme anti-HIV-1 potency compared to DRV. Our work provides the basis for developing novel PIs with high potency against PI-resistant HIV-1 variants with a high genetic barrier.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>32606378</pmid><doi>10.1038/s41598-020-65993-z</doi><tpages>1</tpages><oa>free_for_read</oa></addata></record>
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subjects	631/154 631/535 631/92 Adaptation Amino acids Antiretroviral agents Antiretroviral drugs Antiretroviral therapy Antiviral agents Benzene Cell Line Cell permeability Darunavir - pharmacology Drug Resistance, Viral - drug effects Fluorine HIV HIV Infections - drug therapy HIV Protease - metabolism HIV Protease Inhibitors - pharmacology HIV-1 - drug effects Human immunodeficiency virus Humanities and Social Sciences Humans multidisciplinary Plasticity Proteinase inhibitors Science Science (multidisciplinary) Sulfur Virus Replication - drug effects
title	Single atom changes in newly synthesized HIV protease inhibitors reveal structural basis for extreme affinity, high genetic barrier, and adaptation to the HIV protease plasticity
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