Activation of an Aquareovirus,Chum Salmon Reovirus (CSV), by the Ciliates Tetrahymena thermophila and T. canadensis

For the first time, ciliates have been found to activate rather than inactivate a virus, chum salmon reovirus (CSV). Activation was seen as an increase in viral titre upon incubation of CSV at 22 °C with Tetrahymena canadenesis and two strains of T. thermophila: wild type (B1975) and a temperature conditional mutant for phagocytosis (NP1). The titre increase was not likely due to replication because CSV had no visible effects on the ciliates and no vertebrate virus has ever been shown unequivocally to replicate in ciliates. When incubated with B1975 and NP1 at 30 °C, CSV was activated only by B1975. Therefore, activation required CSV internalization because at 30 °C only B1975 exhibited phagocytosis. CSV replicated in fish cells at 18 to 26 °C but not at 30 °C. Collectively, these observations point to CSV activation being distinct from replication. Activation is attributed to the CSV capsid being modified in the ciliate phagosomal‐lysosomal system and released in a more infectious form. When allowed to swim in CSV‐infected fish cell cultures, collected, washed, and transferred to uninfected cultures, T. canadensis caused a CSV infection. Overall the results suggest that ciliates could have roles in the environmental dissemination of some fish viral diseases.     

Inflammatory-dependent Sting activation induces antiviral autophagy to limit zika virus in the Drosophila brain

Incidences of congenital syndrome associated with maternal zika virus (ZIKV) infection during pregnancy are well documented; however, the cellular and molecular mechanisms by which ZIKV infection causes these devastating fetal pathologies are still under active investigation. ZIKV is a member of the flavivirus family and is mainly transmitted to human hosts through Aedes mosquito vectors. However, in vivo models for the neurological tropism of the virus and the arthropod vector have been lacking. A recent study published in Cell Host & Microbe from Dr. Sara Cherry’s lab investigates both of these key aspects of the ZIKV infectious life cycle. Liu et al. demonstrate how inflammatory activated Sting/dSTING-dependent antiviral macroautophagy/autophagy is sufficient to restrict ZIKV infection in the Drosophila melanogaster brain. Additionally, this study provides further evidence for the ancestral function of autophagy in protecting host cells from viral invaders.

Abbreviations: AGO2: Argonaute 2; ATG: autophagy-related; Dcr-2: Dicer-2; DptA/Dipt: Diptericin A; Drs: Drosomycin; DCV: Drosophila C virus; IMD: immune-deficiency; qRT-PCR: quantitative real-time PCR; Rel/NF-κB: Relish; RNAi: RNA interference; ZIKV: zika virus     

Peroxisomal protein PEX13 functions in selective autophagy

PEX13 is an integral membrane protein on the peroxisome that regulates peroxisomal matrix protein import during peroxisome biogenesis. Mutations in PEX13 and other peroxin proteins are associated with Zellweger syndrome spectrum (ZSS) disorders, a subtype of peroxisome biogenesis disorder characterized by prominent neurological, hepatic, and renal abnormalities leading to neonatal death. The lack of functional peroxisomes in ZSS patients is widely accepted as the underlying cause of disease; however, our understanding of disease pathogenesis is still incomplete. Here, we demonstrate that PEX13 is required for selective autophagy of Sindbis virus (virophagy) and of damaged mitochondria (mitophagy) and that disease‐associated PEX13 mutants I326T and W313G are defective in mitophagy. The mitophagy function of PEX13 is shared with another peroxin family member PEX3, but not with two other peroxins, PEX14 and PEX19, which are required for general autophagy. Together, our results demonstrate that PEX13 is required for selective autophagy, and suggest that dysregulation of PEX13‐mediated mitophagy may contribute to ZSS pathogenesis.     

The role of autophagy in controlling SARS-CoV-2 infection: An overview on virophagy-mediated molecular drug targets

Autophagy-dependent cell death is a prominent mechanism that majorly contributes to homeostasis by maintaining the turnover of organelles under stressful conditions. Several viruses, including coronaviruses (CoVs), take advantage of cellular autophagy to facilitate their own replication. Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is a beta-coronavirus (β-CoVs) that mediates its replication through a dependent or independent ATG5 pathway using specific double-membrane vesicles that can be considered as similar to autophagosomes. With due attention to several mutations in NSP6, a nonstructural protein with a positive regulatory effect on autophagosome formation, a potential correlation between SARS-CoV-2 pathogenesis mechanisms and autophagy can be expected. Certain medications, albeit limited in number, have been indicated to negatively regulate autophagy flux, potentially in a way similar to the inhibitory effect of β-CoVs on the process of autophagy. However, there is no conclusive evidence to support their direct antagonizing effect on CoVs. Off-target accumulation of a major fraction of FDA-approved autophagy modulating drugs may result in adverse effects. Therefore, medications that have modulatory effects on autophagy could be considered as potential lead compounds for the development of new treatments against this virus. This review discusses the role of autophagy/virophagy in controlling SARS-CoV-2, focusing on the potential therapeutic implications.