The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops

HIV-1 protease (PR) is a 99 amino acid protein responsible for proteolytic processing of the viral polyprotein – an essential step in the HIV-1 life cycle. Drug resistance mutations in PR that are selected during antiretroviral therapy lead to reduced efficacy of protease inhibitors (PI) including d...

Descripción completa

Detalles Bibliográficos
Autores principales: Kuiper, Benjamin D., Keusch, Bradley J., Dewdney, Tamaria G., Chordia, Poorvi, Ross, Kyla, Brunzelle, Joseph S., Kovari, Iulia A., MacArthur, Rodger, Salimnia, Hossein, Kovari, Ladislau C.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Elsevier 2015
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5668655/
https://www.ncbi.nlm.nih.gov/pubmed/29124158
http://dx.doi.org/10.1016/j.bbrep.2015.06.003
_version_ 1783275706539573248
author Kuiper, Benjamin D.
Keusch, Bradley J.
Dewdney, Tamaria G.
Chordia, Poorvi
Ross, Kyla
Brunzelle, Joseph S.
Kovari, Iulia A.
MacArthur, Rodger
Salimnia, Hossein
Kovari, Ladislau C.
author_facet Kuiper, Benjamin D.
Keusch, Bradley J.
Dewdney, Tamaria G.
Chordia, Poorvi
Ross, Kyla
Brunzelle, Joseph S.
Kovari, Iulia A.
MacArthur, Rodger
Salimnia, Hossein
Kovari, Ladislau C.
author_sort Kuiper, Benjamin D.
collection PubMed
description HIV-1 protease (PR) is a 99 amino acid protein responsible for proteolytic processing of the viral polyprotein – an essential step in the HIV-1 life cycle. Drug resistance mutations in PR that are selected during antiretroviral therapy lead to reduced efficacy of protease inhibitors (PI) including darunavir (DRV). To identify the structural mechanisms associated with the DRV resistance mutation L33F, we performed X-ray crystallographic studies with a multi-drug resistant HIV-1 protease isolate that contains the L33F mutation (MDR769 L33F). In contrast to other PR L33F DRV complexes, the structure of MDR769 L33F complexed with DRV reported here displays the protease flaps in an open conformation. The L33F mutation increases noncovalent interactions in the hydrophobic pocket of the PR compared to the wild-type (WT) structure. As a result, L33F appears to act as a molecular anchor, reducing the flexibility of the 30s loop (residues 29–35) and the 80s loop (residues 79–84). Molecular anchoring of the 30s and 80s loops leaves an open S1/S1′ subsite and distorts the conserved hydrogen-bonding network of DRV. These findings are consistent with previous reports despite structural differences with regards to flap conformation.
format Online
Article
Text
id pubmed-5668655
institution National Center for Biotechnology Information
language English
publishDate 2015
publisher Elsevier
record_format MEDLINE/PubMed
spelling pubmed-56686552017-11-09 The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops Kuiper, Benjamin D. Keusch, Bradley J. Dewdney, Tamaria G. Chordia, Poorvi Ross, Kyla Brunzelle, Joseph S. Kovari, Iulia A. MacArthur, Rodger Salimnia, Hossein Kovari, Ladislau C. Biochem Biophys Rep Research Article HIV-1 protease (PR) is a 99 amino acid protein responsible for proteolytic processing of the viral polyprotein – an essential step in the HIV-1 life cycle. Drug resistance mutations in PR that are selected during antiretroviral therapy lead to reduced efficacy of protease inhibitors (PI) including darunavir (DRV). To identify the structural mechanisms associated with the DRV resistance mutation L33F, we performed X-ray crystallographic studies with a multi-drug resistant HIV-1 protease isolate that contains the L33F mutation (MDR769 L33F). In contrast to other PR L33F DRV complexes, the structure of MDR769 L33F complexed with DRV reported here displays the protease flaps in an open conformation. The L33F mutation increases noncovalent interactions in the hydrophobic pocket of the PR compared to the wild-type (WT) structure. As a result, L33F appears to act as a molecular anchor, reducing the flexibility of the 30s loop (residues 29–35) and the 80s loop (residues 79–84). Molecular anchoring of the 30s and 80s loops leaves an open S1/S1′ subsite and distorts the conserved hydrogen-bonding network of DRV. These findings are consistent with previous reports despite structural differences with regards to flap conformation. Elsevier 2015-06-12 /pmc/articles/PMC5668655/ /pubmed/29124158 http://dx.doi.org/10.1016/j.bbrep.2015.06.003 Text en © 2015 Published by Elsevier B.V. http://creativecommons.org/licenses/by-nc-nd/4.0/ This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
spellingShingle Research Article
Kuiper, Benjamin D.
Keusch, Bradley J.
Dewdney, Tamaria G.
Chordia, Poorvi
Ross, Kyla
Brunzelle, Joseph S.
Kovari, Iulia A.
MacArthur, Rodger
Salimnia, Hossein
Kovari, Ladislau C.
The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops
title The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops
title_full The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops
title_fullStr The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops
title_full_unstemmed The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops
title_short The L33F darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the HIV-1 protease 30s and 80s loops
title_sort l33f darunavir resistance mutation acts as a molecular anchor reducing the flexibility of the hiv-1 protease 30s and 80s loops
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5668655/
https://www.ncbi.nlm.nih.gov/pubmed/29124158
http://dx.doi.org/10.1016/j.bbrep.2015.06.003
work_keys_str_mv AT kuiperbenjamind thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT keuschbradleyj thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT dewdneytamariag thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT chordiapoorvi thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT rosskyla thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT brunzellejosephs thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT kovariiuliaa thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT macarthurrodger thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT salimniahossein thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT kovariladislauc thel33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT kuiperbenjamind l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT keuschbradleyj l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT dewdneytamariag l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT chordiapoorvi l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT rosskyla l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT brunzellejosephs l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT kovariiuliaa l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT macarthurrodger l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT salimniahossein l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops
AT kovariladislauc l33fdarunavirresistancemutationactsasamolecularanchorreducingtheflexibilityofthehiv1protease30sand80sloops

Ejemplares similares