Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening

Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening

Abstract Background Macrophages, besides resting latently infected CD4+ T cells, constitute the predominant stable, major non-T cell HIV reservoirs. Therefore, it is essential to eliminate both latently infected CD4+ T cells and tissue macrophages to completely eradicate HIV in patients. Until now,...

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Main Authors: Simon X. M. Dong, Frederick S. Vizeacoumar, Kalpana K. Bhanumathy, Nezeka Alli, Cristina Gonzalez-Lopez, Niranjala Gajanayaka, Ramon Caballero, Hamza Ali, Andrew Freywald, Edana Cassol, Jonathan B. Angel, Franco J. Vizeacoumar, Ashok Kumar
Format: Article
Language:English
Published: BMC 2021-07-01
Series:BMC Infectious Diseases
Subjects:
AIDS
Apoptosis
HIV reservoir
Genome-wide screening
Selective killing
Macrophages
Online Access:https://doi.org/10.1186/s12879-021-06346-7
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language English
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author Simon X. M. Dong
Frederick S. Vizeacoumar
Kalpana K. Bhanumathy
Nezeka Alli
Cristina Gonzalez-Lopez
Niranjala Gajanayaka
Ramon Caballero
Hamza Ali
Andrew Freywald
Edana Cassol
Jonathan B. Angel
Franco J. Vizeacoumar
Ashok Kumar
spellingShingle Simon X. M. Dong
Frederick S. Vizeacoumar
Kalpana K. Bhanumathy
Nezeka Alli
Cristina Gonzalez-Lopez
Niranjala Gajanayaka
Ramon Caballero
Hamza Ali
Andrew Freywald
Edana Cassol
Jonathan B. Angel
Franco J. Vizeacoumar
Ashok Kumar
Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening
BMC Infectious Diseases
AIDS
Apoptosis
HIV reservoir
Genome-wide screening
Selective killing
Macrophages
author_facet Simon X. M. Dong
Frederick S. Vizeacoumar
Kalpana K. Bhanumathy
Nezeka Alli
Cristina Gonzalez-Lopez
Niranjala Gajanayaka
Ramon Caballero
Hamza Ali
Andrew Freywald
Edana Cassol
Jonathan B. Angel
Franco J. Vizeacoumar
Ashok Kumar
author_sort Simon X. M. Dong
title Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening
title_short Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening
title_full Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening
title_fullStr Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening
title_full_unstemmed Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screening
title_sort identification of novel genes involved in apoptosis of hiv-infected macrophages using unbiased genome-wide screening
publisher BMC
series BMC Infectious Diseases
issn 1471-2334
publishDate 2021-07-01
description Abstract Background Macrophages, besides resting latently infected CD4+ T cells, constitute the predominant stable, major non-T cell HIV reservoirs. Therefore, it is essential to eliminate both latently infected CD4+ T cells and tissue macrophages to completely eradicate HIV in patients. Until now, most of the research focus is directed towards eliminating latently infected CD4+ T cells. However, few approaches have been directed at killing of HIV-infected macrophages either in vitro or in vivo. HIV infection dysregulates the expression of many host genes essential for the survival of infected cells. We postulated that exploiting this alteration may yield novel targets for the selective killing of infected macrophages. Methods We applied a pooled shRNA-based genome-wide approach by employing a lentivirus-based library of shRNAs to screen novel gene targets whose inhibition should selectively induce apoptosis in HIV-infected macrophages. Primary human MDMs were infected with HIV-eGFP and HIV-HSA viruses. Infected MDMs were transfected with siRNAs specific for the promising genes followed by analysis of apoptosis by flow cytometry using labelled Annexin-V in HIV-infected, HIV-exposed but uninfected bystander MDMs and uninfected MDMs. The results were analyzed using student’s t-test from at least four independent experiments. Results We validated 28 top hits in two independent HIV infection models. This culminated in the identification of four target genes, Cox7a2, Znf484, Cstf2t, and Cdk2, whose loss-of-function induced apoptosis preferentially in HIV-infected macrophages. Silencing these single genes killed significantly higher number of HIV-HSA-infected MDMs compared to the HIV-HSA-exposed, uninfected bystander macrophages, indicating the specificity in the killing of HIV-infected macrophages. The mechanism governing Cox7a2-mediated apoptosis of HIV-infected macrophages revealed that targeting respiratory chain complex II and IV genes also selectively induced apoptosis of HIV-infected macrophages possibly through enhanced ROS production. Conclusions We have identified above-mentioned novel genes and specifically the respiratory chain complex II and IV genes whose silencing may cause selective elimination of HIV-infected macrophages and eventually the HIV-macrophage reservoirs. The results highlight the potential of the identified genes as targets for eliminating HIV-infected macrophages in physiological environment as part of an HIV cure strategy.
topic AIDS
Apoptosis
HIV reservoir
Genome-wide screening
Selective killing
Macrophages
url https://doi.org/10.1186/s12879-021-06346-7
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spelling doaj-ebee62ccabb146e1b7cef32300ef31132021-07-11T11:51:51ZengBMCBMC Infectious Diseases1471-23342021-07-0121111910.1186/s12879-021-06346-7Identification of novel genes involved in apoptosis of HIV-infected macrophages using unbiased genome-wide screeningSimon X. M. Dong0Frederick S. Vizeacoumar1Kalpana K. Bhanumathy2Nezeka Alli3Cristina Gonzalez-Lopez4Niranjala Gajanayaka5Ramon Caballero6Hamza Ali7Andrew Freywald8Edana Cassol9Jonathan B. Angel10Franco J. Vizeacoumar11Ashok Kumar12Apoptosis Research Center, Children’s Hospital of Eastern Ontario, Faculty of Medicine, University of OttawaDepartment of Pathology, College of Medicine, University of SaskatchewanDepartment of Pathology, College of Medicine, University of SaskatchewanDepartment of Pathology, College of Medicine, University of SaskatchewanCancer Research, Saskatchewan Cancer AgencyApoptosis Research Center, Children’s Hospital of Eastern Ontario, Faculty of Medicine, University of OttawaApoptosis Research Center, Children’s Hospital of Eastern Ontario, Faculty of Medicine, University of OttawaApoptosis Research Center, Children’s Hospital of Eastern Ontario, Faculty of Medicine, University of OttawaDepartment of Pathology, College of Medicine, University of SaskatchewanDepartment of Health Sciences, Carleton UniversityDepartment of Medicine, the Ottawa Health Research Institute, Faculty of Medicine, University of OttawaDepartment of Pathology, College of Medicine, University of SaskatchewanApoptosis Research Center, Children’s Hospital of Eastern Ontario, Faculty of Medicine, University of OttawaAbstract Background Macrophages, besides resting latently infected CD4+ T cells, constitute the predominant stable, major non-T cell HIV reservoirs. Therefore, it is essential to eliminate both latently infected CD4+ T cells and tissue macrophages to completely eradicate HIV in patients. Until now, most of the research focus is directed towards eliminating latently infected CD4+ T cells. However, few approaches have been directed at killing of HIV-infected macrophages either in vitro or in vivo. HIV infection dysregulates the expression of many host genes essential for the survival of infected cells. We postulated that exploiting this alteration may yield novel targets for the selective killing of infected macrophages. Methods We applied a pooled shRNA-based genome-wide approach by employing a lentivirus-based library of shRNAs to screen novel gene targets whose inhibition should selectively induce apoptosis in HIV-infected macrophages. Primary human MDMs were infected with HIV-eGFP and HIV-HSA viruses. Infected MDMs were transfected with siRNAs specific for the promising genes followed by analysis of apoptosis by flow cytometry using labelled Annexin-V in HIV-infected, HIV-exposed but uninfected bystander MDMs and uninfected MDMs. The results were analyzed using student’s t-test from at least four independent experiments. Results We validated 28 top hits in two independent HIV infection models. This culminated in the identification of four target genes, Cox7a2, Znf484, Cstf2t, and Cdk2, whose loss-of-function induced apoptosis preferentially in HIV-infected macrophages. Silencing these single genes killed significantly higher number of HIV-HSA-infected MDMs compared to the HIV-HSA-exposed, uninfected bystander macrophages, indicating the specificity in the killing of HIV-infected macrophages. The mechanism governing Cox7a2-mediated apoptosis of HIV-infected macrophages revealed that targeting respiratory chain complex II and IV genes also selectively induced apoptosis of HIV-infected macrophages possibly through enhanced ROS production. Conclusions We have identified above-mentioned novel genes and specifically the respiratory chain complex II and IV genes whose silencing may cause selective elimination of HIV-infected macrophages and eventually the HIV-macrophage reservoirs. The results highlight the potential of the identified genes as targets for eliminating HIV-infected macrophages in physiological environment as part of an HIV cure strategy.https://doi.org/10.1186/s12879-021-06346-7AIDSApoptosisHIV reservoirGenome-wide screeningSelective killingMacrophages

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