Disruption of innate defense responses by endoglycosidase HPSE promotes cell survival
Alex Agelidis, Benjamin A. Turturice, Rahul K. Suryawanshi, Tejabhiram Yadavalli, Dinesh Jaishankar, Joshua Ames, James Hopkins, Lulia Koujah, Chandrashekhar D. Patil, Satvik R. Hadigal, Evan J. Kyzar, Anaamika Campeau, Jacob M. Wozniak, David J. Gonzalez, Israel Vlodavsky, Jin-ping Li, David L. Perkins, Patricia W. Finn, Deepak Shukla
Alex Agelidis, Benjamin A. Turturice, Rahul K. Suryawanshi, Tejabhiram Yadavalli, Dinesh Jaishankar, Joshua Ames, James Hopkins, Lulia Koujah, Chandrashekhar D. Patil, Satvik R. Hadigal, Evan J. Kyzar, Anaamika Campeau, Jacob M. Wozniak, David J. Gonzalez, Israel Vlodavsky, Jin-ping Li, David L. Perkins, Patricia W. Finn, Deepak Shukla
View: Text | PDF
Research Article Cell biology Microbiology

Disruption of innate defense responses by endoglycosidase HPSE promotes cell survival

Abstract

The drive to withstand environmental stresses and defend against invasion is a universal trait extant in all forms of life. While numerous canonical signaling cascades have been characterized in detail, it remains unclear how these pathways interface to generate coordinated responses to diverse stimuli. To dissect these connections, we followed heparanase (HPSE), a protein best known for its endoglycosidic activity at the extracellular matrix but recently recognized to drive various forms of late-stage disease through unknown mechanisms. Using herpes simplex virus-1 (HSV-1) infection as a model cellular perturbation, we demonstrate that HPSE acts beyond its established enzymatic role to restrict multiple forms of cell-intrinsic defense and facilitate host cell reprogramming by the invading pathogen. We reveal that cells devoid of HPSE are innately resistant to infection and counteract viral takeover through multiple amplified defense mechanisms. With a unique grasp of the fundamental processes of transcriptional regulation and cell death, HPSE represents a potent cellular intersection with broad therapeutic potential.

Authors

Alex Agelidis, Benjamin A. Turturice, Rahul K. Suryawanshi, Tejabhiram Yadavalli, Dinesh Jaishankar, Joshua Ames, James Hopkins, Lulia Koujah, Chandrashekhar D. Patil, Satvik R. Hadigal, Evan J. Kyzar, Anaamika Campeau, Jacob M. Wozniak, David J. Gonzalez, Israel Vlodavsky, Jin-ping Li, David L. Perkins, Patricia W. Finn, Deepak Shukla

×

Figure 5

Attenuation of IFN response and necroptotic cell death restores infection in the absence of HPSE.

Options: View larger image (or click on image) Download as PowerPoint
Attenuation of IFN response and necroptotic cell death restores infectio...
(A) Measurement of cell death by flow cytometry detection of propidium iodide (PI) cellular uptake after 24-hour HSV-1 or mock infection. (B) Immunofluorescence microscopy of cells infected with GFP–HSV-1; images captured at 24 hpi. Despite profound abrogation of virus production in the absence of HPSE, multiple clusters of rounded and detached cells resembling plaques are observed after infection. Scale bar: 50 μm. (C) Western blot analysis of key proteins involved in induction of necroptosis at indicated times after infection. (D) Representative flow cytometry quantification and micrographs of Hpse+/+ and Hpse-/- cells after infection with GFP–HSV-1 for 48 hours, incubated with inhibitors of apoptosis (ZVAD) or necroptosis (Nec-1) as indicated. Scale bar: 100 μm. (E) Restoration of virus production in Hpse-/- cells with blocking of IFN-α receptor (α-IFNAR) and necroptosis (Nec-1) showing a synergistic effect (n = 5). (F) Inverse relationship between viral infected cell protein (ICP0) and ISG15 expression demonstrated by Western blot, with near complete rescue of virus production observed upon α-IFNAR and Nec-1 treatment in Hpse-/- cells. Data represent mean ± SEM. Significance determined by 2-way ANOVA with Dunnett’s correction for multiple comparisons against control (DMSO). ***P < 0.001, ****P < 0.0001.