The use of Nanotrap particles technology in capturing HIV-1 virions and viral proteins from infected cells.

Elizabeth Jaworski,Sergey Iordanskiy,Emanuel Petricoin,Rachel Van Duyne,Nazly Shafagati,Mohammed Saifuddin,Benjamin Lepene,Mary Young,Kylene Kehn-Hall,Lance Liotta,Gavin Sampey,Fatah Kashanchi,Steven Jacobson

doi:10.1371/journal.pone.0096778

Elizabeth Jaworski, Sergey Iordanskiy + Show 11 more

Open Access

https://doi.org/10.1371/journal.pone.0096778

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Abstract

HIV-1 infection results in a chronic but incurable illness since long-term HAART can keep the virus to an undetectable level. However, discontinuation of therapy rapidly increases viral burden. Moreover, patients under HAART frequently develop various metabolic disorders and HIV-associated neuronal disease. Today, the main challenge of HIV-1 research is the elimination of the residual virus in infected individuals. The current HIV-1 diagnostics are largely comprised of serological and nucleic acid based technologies. Our goal is to integrate the nanotrap technology into a standard research tool that will allow sensitive detection of HIV-1 infection. This study demonstrates that majority of HIV-1 virions in culture supernatants and Tat/Nef proteins spiked in culture medium can be captured by nanotrap particles. To determine the binding affinities of different baits, we incubated target molecules with nanotrap particles at room temperature. After short sequestration, materials were either eluted or remained attached to nanotrap particles prior to analysis. The unique affinity baits of nanotrap particles preferentially bound HIV-1 materials while excluded albumin. A high level capture of Tat or Tat peptide by NT082 and NT084 particles was measured by western blot (WB). Intracellular Nef protein was captured by NT080, while membrane-associated Nef was captured by NT086 and also detected by WB. Selective capture of HIV-1 particles by NT073 and NT086 was measured by reverse transcriptase assay, while capture of infectious HIV-1 by these nanoparticles was demonstrated by functional transactivation in TZM-bl cells. We also demonstrated specific capture of HIV-1 particles and exosomes-containing TAR-RNA in patients' serum by NT086 and NT082 particles, respectively, using specific qRT-PCR. Collectively, our data indicate that certain types of nanotrap particles selectively capture specific HIV-1 molecules, and we propose to use this technology as a platform to enhance HIV-1 detection by concentrating viral proteins and infectious virions from infected samples.

Highlights

Human immunodeficiency virus type 1 (HIV-1) virions possess 9.7 kb dimeric positive-sense single-stranded RNA genome, which contains a total of nine genes, structural, regulatory and accessory [1]
Ethics Statement All research involving human participants have been approved by The Georgetown University (GTU) Institutional Review Board (IRB) for The Women’s Interagency HIV Study (WIHS) which covers viral and immunologic studies related to HIV-1 infection and its co-morbidities
One nanotrap particle (NT084) did not contain the outer shell, and three of the particles (NT073, NT085 and NT086) contained vinyl sulfonic acid (VSA) incorporated into the shell

Summary

Introduction

Human immunodeficiency virus type 1 (HIV-1) virions possess 9.7 kb dimeric positive-sense single-stranded RNA genome, which contains a total of nine genes, structural (env, gag, pol), regulatory (tat, rev) and accessory (nef, vif, vpr, vpu) [1]. Since its discovery in 1981, HIV-1 caused more deaths than any other single infectious disease [7,8]. A substantial number of newly infected individuals are not aware of their HIV-1 positive status [8,10,11]. Patients under HAART frequently develop various metabolic disorders and HIV-associated neuronal disease [14,15,16,17,18]. The main challenge of HIV-1 research is the elimination of the residual virus in infected individuals [12,13,19]

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