Inducible nitric oxide synthase deficiency promotes murine-ß-coronavirus induced demyelination.

BACKGROUND: Multiple sclerosis (MS) is characterized by neuroinflammation and demyelination orchestrated by activated neuroglial cells, CNS infiltrating leukocytes, and their reciprocal interactions through inflammatory signals. An inflammatory stimulus triggers inducible nitric oxide synthase (NOS2), a pro-inflammatory marker of microglia/macrophages (MG/Mφ) to catalyze sustained nitric oxide production. NOS2 during neuroinflammation, has been associated with MS disease pathology; however, studies dissecting its role in demyelination are limited. We studied the role of NOS2 in a recombinant ß-coronavirus-MHV-RSA59 induced neuroinflammation, an experimental animal model mimicking the pathological hallmarks of MS: neuroinflammatory demyelination and axonal degeneration. OBJECTIVE: Understanding the role of NOS2 in murine-ß-coronavirus-MHV-RSA59 demyelination. METHODS: Brain and spinal cords from mock and RSA59 infected 4-5-week-old MHV-free C57BL/6 mice (WT) and NOS2-/- mice were harvested at different disease phases post infection (p.i.) (day 5/6-acute, day 9/10-acute-adaptive and day 30-chronic phase) and compared for pathological outcomes. RESULTS: NOS2 was upregulated at the acute phase of RSA59-induced disease in WT mice and its deficiency resulted in severe disease and reduced survival at the acute-adaptive transition phase. Low survival in NOS2-/- mice was attributed to (i) high neuroinflammation resulting from increased accumulation of macrophages and neutrophils and (ii) Iba1 + phagocytic MG/Mφ mediated-early demyelination as observed at this phase. The phagocytic phenotype of CNS MG/Mφ was confirmed by significantly higher mRNA transcripts of phagocyte markers-CD206, TREM2, and Arg1 and double immunolabelling of Iba1 with MBP and PLP. Further, NOS2 deficiency led to exacerbated demyelination at the chronic phase as well. CONCLUSION: Taken together the results imply that the immune system failed to control the disease progression in the absence of NOS2. Thus, our observations highlight a protective role of NOS2 in murine-ß-coronavirus induced demyelination.

C-Terminal Lipidation of SARS-CoV-2 Fusion Peptide Reinstates Superior Membrane Fusion Catalytic Ability.

The Spike (S) protein of severe acute respiratory syndrome-associated coronavirus-2 (SARS-CoV-2) mediates a critical stage in infection, the fusion between viral and host membranes. The protein is categorized as a class I viral fusion protein and has two distinct cleavage sites that can be activated by proteases. The activation deploys the fusion peptide (FP) for insertion into the target cell membranes. Recent studies including our experiments showed that the FP was unable to modulate the kinetics of fusion at a low peptide-to-lipid ratio akin to the spike density at the viral surface. Therefore, we have modified the C-terminus of FP and attached a myristoyl chain (C-myr-FP) to restrict the C-terminus near to interface, bridge both membranes, and increase the effective local concentration. The lipidated FP (C-myr-FP) of SARS-CoV-2 greatly accelerates membrane fusion at a low peptide-to-lipid ratio as compared to the FP with no lipidation. Biophysical experiments suggest that C-myr-FP adopts a helical structure, perturbs the membrane interface, and increases water penetration to catalyze fusion. Scrambled peptide (C-myr-sFP) and truncated peptide (C-myr-8FP) couldn't significantly catalyze the fusion suggesting the important role of myristoylation and the N-terminus. C-myr-FP enhances the murine coronavirus infection by promoting syncytia formation in L2 cells. The C-terminal lipidation of the FP may be a useful strategy to induce artificial fusion in biomedical applications.

DJ-1-Nrf2 axis is activated upon murine ß-coronavirus infection in the CNS.

Coronaviruses have emerged as alarming pathogens owing to their inherent ability of genetic variation and cross-species transmission. Coronavirus infection burdens the endoplasmic reticulum (ER.), causes reactive oxygen species production and induces host stress responses, including unfolded protein response (UPR) and antioxidant system. In this study, we have employed a neurotropic murine ß-coronavirus (M-CoV) infection in the Central Nervous System (CNS) of experimental mice model to study the role of host stress responses mediated by interplay of DJ-1 and XBP1. DJ-1 is an antioxidant molecule with established functions in neurodegeneration. However, its regulation in virus-induced cellular stress response is less explored. Our study showed that M-CoV infection activated the glial cells and induced antioxidant and UPR genes during the acute stage when the viral titer peaks. As the virus particles decreased and acute neuroinflammation diminished at day ten p.i., a significant up-regulation in UPR responsive XBP1, antioxidant DJ-1, and downstream signaling molecules, including Nrf2, was recorded in the brain tissues. Additionally, preliminary in silico analysis of the binding between the DJ-1 promoter and a positively charged groove of XBP1 is also investigated, thus hinting at a mechanism behind the upregulation of DJ-1 during MHV-infection. The current study thus attempts to elucidate a novel interplay between the antioxidant system and UPR in the outcome of coronavirus infection.