Abstract
HIV encodes an aspartyl protease that is activated during, or shortly after, budding of viral particles from the surface of infected cells. Protease-mediated cleavage of viral polyproteins is essential to generating infectious viruses, a process known as ‘maturation’ that is the target of FDA-approved antiretroviral drugs. Most assays to monitor protease activity rely on bulk analysis of millions of viruses and obscure potential heterogeneity of protease activation within individual particles. In this study we used nanoscale flow cytometry in conjunction with an engineered FRET reporter called VIral ProteasE Reporter (VIPER) to investigate heterogeneity of protease activation in individual, patient-derived viruses. We demonstrate previously unappreciated interpatient variation in HIV protease processing efficiency that impacts viral infectivity. Additionally, monitoring of protease activity in individual virions distinguishes between drug sensitivity or resistance to protease inhibitors in patient-derived samples. These findings demonstrate the feasibility of monitoring enzymatic processes using nanoscale flow cytometry and highlight the potential of this technology for translational clinical discovery, not only for viruses but also other submicron particles including exosomes, microvesicles, and bacteria.
Highlights
HIV-1 encodes an aspartyl protease (PR) that is encoded as a monomer within the viral Gag-Pol polyprotein but functions as a mature dimer
The PR cleavage sequence SQNYPIVQ, which separates the matrix (MA) and capsid (CA) subunits of the HIV Gag structural proteins, was inserted between mUKG and mKOκ. This reporter was linked to the viral accessory protein Vpr that makes noncovalent interaction with the Gag p6 protein[22], which we anticipated would result in specific incorporation of the reporter into viral particles (Fig. 1A)
The band intensity of the processed p24 CA by western blot correlated extremely well with viruses in the processed mUKG gate (R2 = 0.96, p < 0.0001, Fig. 2F). These results indicate that VIral ProteasE Reporter (VIPER) is a sensitive and reproducible indicator of HIV PR activity that correlates well with processing of the Gag structural proteins
Summary
HIV-1 encodes an aspartyl protease (PR) that is encoded as a monomer within the viral Gag-Pol polyprotein but functions as a mature dimer. During or shortly after virus budding, PR dimerizes, undergoes autocatalytic processing from the polyprotein, and subsequently cleaves the viral Gag and Gag-Pol polyproteins into individual subunits in a highly ordered process called maturation. This PR-dependent maturation is characterized by the rearrangement of the Gag capsid proteins into an elongated conical shell and condensation of the Gag nucleocapsid proteins that stabilize the dimeric viral RNA genome. A variety of techniques to monitor HIV PR function are available including cell-free assays with recombinant PR, western blot analysis of Gag and Gag-Pol polyprotein processing, and electron microscopy. We demonstrate that NFC can distinguish between PR inhibitor-sensitive and -resistant patient-derived viruses, accurately predicting sensitivity of all 20 (100%) antiretroviral naïve or sensitive viruses and 13 of 16 (81%) of PI and challenging multi-PI resistant viruses
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