Project description:With the near eradication of poliovirus due to global vaccination campaigns, attention has shifted to other enteroviruses that can cause polio-like paralysis syndrome (now termed acute flaccid myelitis (AFM)). In particular, enterovirus D68 (EV-D68) is believed to be the main driver of epidemic outbreaks of AFM in recent years, yet not much is known about EV-D68 host interactions. EV-D68 is a respiratory virus but, in rare cases, can spread to the central nervous system to cause severe neuropathogenesis. We use genome-scale CRISPR screens to identify genes important for EV-D68 infection. A549 and U87-MG cells were stably transduced with lentiCas9-Blast (Addgene, #52962) and subsequently selected using Blasticidin. Then, 300 million cells that constitutively express Cas9 were transduced with lentiGuide-Puro from the Brunello library (MOI 0.3). Cells were then selected with puromycin, expanded to 3 billion cells, and then pooled together and cryofrozen in aliquots. One hundred million cells were thawed constituting over 1000× genome coverage worth of mutagenized library,expanded, and seeded for the screens. Each screen had over 500x genome coverage. The cells were infected with EV-D68 IL (BEI USA/2014/18952) (MOI 0.1). Virus-resistant colonies were harvested. The uninfected reference used was the unselected starting population. The unselected and selected cells were both processed with QIAamp DNA columns to purify the gDNA. A first round of PCR was used to amplify the guide RNA sequences encoded in the gDNA, followed by a second round of PCR to add the barcodes/adapters for amplicon sequencing. 2% agarose gels and a QIAquick gel extraction kit were used to purify the amplicons. The amplicons were then subjected to next-generation sequencing on a HiSeq instrument lane (Illumina) via Novogene.

Project description:Mechanisms used by positive-stranded RNA viruses to control the translation-replication switch remain largely unexplored. Using metabolic labeling coupled with quantitative proteomics analyses, we unraveled the protein composition of temporal ribonucleoprotein complexes (RNPs) isolated during early and late enterovirus A71 (EV-A71) infection. Comparing the RNP components at the eclipse and maturation phase, representing early and late infection, revealed RNP remodeling over time by exchanging nuclear with cytoplasmic proteins. Among the nuclear proteins, EV-A71 infection induced the phosphorylation and cytoplasmic re-localization of nuclear SR proteins. During early infection, phosphorylated SR proteins cofractionated with the translation machinery rather than the replication organelles. During late infection, this co-localization, as well as the EV-A71-induced phosphorylated SR proteins, was no longer detected. Inhibition of SR protein phosphorylation by the kinase inhibitors SRPKIN-1 and TG003 significantly reduced the replication of several enteroviruses. Our results demonstrate the importance of phosphoregulation of SR proteins during enterovirus replication and reveal a potential target for broad-spectrum antivirals.

Project description:Enteroviruses (EVs) are one of the most prevalent viruses worldwide. They are characterised by a high genetic and phenotypic diversity, being able to cause a plethora of symptoms. EV-D68, a respiratory EV, and EV-D94, an enteric EV, represent an interesting paradigm of EV tropism heterogeneity. These are closely related viruses, belonging to the same species, but with distinct phenotypic features. Here, we used these two viruses as well as relevant tissue culture models mimicking the respiratory and intestinal epithelia, to highlight key distinctive features of enteric and respiratory EVs. We emphasize the critical role of temperature in restricting the tissue tropism of EV-D68 and the limited replication of EV-D94 in small airway tissues. In parallel, using transcriptomic analysis, we uncover fundamental differences between intestinal and respiratory tissues, in their steady-state as well as in response to infection. Intestinal tissues are more immunotolerant than respiratory tissues both in absence and presence of infection and they present higher turnover. Finally, we highlight the different strategies applied by EV-D94 and EV-D68 towards the host antiviral response in intestinal and respiratory tissues. In summary, our study provides an insightful characterization of the differential pathogenesis of EV-D68 and EV-D94 and the interplay with their main target tissues.

Project description:To elucidate alterations in immune cells during enterovirus 71 (EV-A71) infection and explore potential interaction mechanisms.Single-cell sequencing technology was used to sequence peripheral blood monocytes (PBMCs) obtained from a severe hand, foot and mouth disease (HFMD) patient due to EV-A71 and a healthy control.

Project description:Enteroviruses, particularly the group B Coxsackieviruses have been associated with the development of type 1 diabetes. Several CVB serotypes can establish chronic infection in human cells in vivo and in vitro. However, the mechanisms of leading to enterovirus persistency and, possibly, bell-cell autoimmunity are not fully understood. We established a carrier-state persistent infection model in human pancreatic ductal-like cell line PANC-1 using two distinct CVB1 strains and profiled infection-induced changes in cellular transcriptome. In the current study we observed clear changes in the gene expression of factors associated with the pancreatic microenvironment, the secretory pathway and lysosomal biogenesis during persistent CVB1 infections. Moreover, we gained deeper insights into immune-related genes which differed clearly between the two persistent infections. Overall our study reveals extensive transcriptional responses in persistently CVB1 infected pancreatic cell line with strong opposite but also common changes between the two strains.

Project description:RNA interference (RNAi) is an antiviral immunity conserved in diverse eukaryotes including mammals, while viruses encodes viral suppressors of RNAi (VSRs) as countermeasures. However, the physiological impact of RNAi on viral infection in mammals has not been fully assessed, and it also remains unknown whether antiviral RNAi can be therapeutically exploited. Here, we show that peptides designed to target enterovirus A71 (EV-A71)-encoded protein 3A, a well-characterized VSR, triggered an effective antiviral response. These VSR-targeting peptides, particularly ER-DRI, abrogated the VSR function of 3A, which enabled EV-A71-derived siRNA production and unlocked RNAi response that potently inhibited EV-A71 infection in mammals. ER-DRI treatment elicited a strong in vivo antiviral RNAi response that protected mice against lethal EV-A71 challenge. It also potently inhibited another enterovirus, Coxsackievirus-A16, dependently of RNAi. Our findings demonstrate that antiviral RNAi does have a physiologically important impact in mammals and targeting VSRs is a promising strategy for antiviral therapies.

Project description:Toxoplasma gondii (T. gondii), a prolific protozoan parasite, forms cysts within neurons of the central nervous system that maintain infection for the lifetime of the host. Astrocytes are fundamental to neuronal health by providing nutrients and structural support and help regulate neurotransmitters by continuous communication with neurons. It is not yet known how infection and the presence of intracellular cysts, disrupts the crucial relationship between these cells. Extracellular vesicles (EVs) function in intracellular communication and can contain proteins, lipids, DNA, miRNA, and other RNA subtypes. EVs are produced by all cells and play an important role in neuronal-astrocyte interactions, including the regulation of glutamate receptors on astrocytes. Previous work has demonstrated that Toxoplasma infection reduces astrocytic expression of the primary glutamate transporter, GLT-1. Here we tested if cyst infection of neurons alters the production and content of EVs. EVs were isolated from uninfected and infected primary murine cortical neurons and their size, concentration, and characterization were confirmed with nanoparticle tracking analysis (NTA), transmission electron microscopy (TEM), ELISA, western blot, liquid chromatography (LC)-mass spectrometry (MS)/MS, and microRNA sequencing. Analysis reveals that infection of neurons reduced neuronal production of EVs and altered their protein and miRNA content. In addition to changes in host protein content, EVs from infected neurons contained the Toxoplasma proteins GRA1, GRA2, GRA7, MAG1 and MAG2. Following incubation of neuronal EVs with primary astrocytes, GRA7 protein could be observed within intracellular EVs and the nuclei of GRA7+EV-containing cells. EVs from infected neurons altered gene expression of astrocytes resulting in an increase in pro-inflammatory transcriptional signatures, along with a downregulation of GLT-1 protein expression with similar transcriptional changes found in astrocytes in vivo. These results demonstrate the ability of a parasitic infection in the brain to alter EV production and the fundamental communication between neurons and astrocytes.

Project description:Toxoplasma gondii (T. gondii), a prolific protozoan parasite, forms cysts within neurons of the central nervous system that maintain infection for the lifetime of the host. Astrocytes are fundamental to neuronal health by providing nutrients and structural support and help regulate neurotransmitters by continuous communication with neurons. It is not yet known how infection and the presence of intracellular cysts, disrupts the crucial relationship between these cells. Extracellular vesicles (EVs) function in intracellular communication and can contain proteins, lipids, DNA, miRNA, and other RNA subtypes. EVs are produced by all cells and play an important role in neuronal-astrocyte interactions, including the regulation of glutamate receptors on astrocytes. Previous work has demonstrated that Toxoplasma infection reduces astrocytic expression of the primary glutamate transporter, GLT-1. Here we tested if cyst infection of neurons alters the production and content of EVs. EVs were isolated from uninfected and infected primary murine cortical neurons and their size, concentration, and characterization were confirmed with nanoparticle tracking analysis (NTA), transmission electron microscopy (TEM), ELISA, western blot, liquid chromatography (LC)-mass spectrometry (MS)/MS, and microRNA sequencing. Analysis reveals that infection of neurons reduced neuronal production of EVs and altered their protein and miRNA content. In addition to changes in host protein content, EVs from infected neurons contained the Toxoplasma proteins GRA1, GRA2, GRA7, MAG1 and MAG2. Following incubation of neuronal EVs with primary astrocytes, GRA7 protein could be observed within intracellular EVs and the nuclei of GRA7+EV-containing cells. EVs from infected neurons altered gene expression of astrocytes resulting in an increase in pro-inflammatory transcriptional signatures, along with a downregulation of GLT-1 protein expression with similar transcriptional changes found in astrocytes in vivo. These results demonstrate the ability of a parasitic infection in the brain to alter EV production and the fundamental communication between neurons and astrocytes.

Project description:Here, we derive human brain organoids with innately developing microglia to investigate the cellular responses to SARS-CoV-2 infection on a single cell level. We find evidence of limited tropism to SARS-CoV-2 for all major cell types and observe extensive neuronal cell death that also include non-infected cells. Single cell transcriptome profiling reveals distinct responses in microglia and astrocytes that share features with cellular states observed in neurodegenerative diseases

Project description:Hand, foot, and mouth disease (HFMD) is caused by more than 20 pathogenic enteroviruses belonging to the Picornaviridae family and Enterovirus genus. Since the introduction of the EV71 vaccine in 2016, the number of HFMD cases caused by EV71 has decreased. However, cases of infections caused by other enteroviruses, such as coxsackievirus A6 (CA6) and CA10, have been increasing accordingly. In this study, we used a clinical isolate of CA6 to establish an intragastric infection mouse model using 7-day-old mice to mimic the natural transmission route, by which we investigated the differential gene expression profiles associated with virus infection and pathogenicity. After intragastric infection, mice exhibited hind limb paralysis symptoms and weight loss, similar to those reported for EV71 infection in mice. The skeletal muscle was identified as the main site of virus replication, with a peak viral load reaching 2.31 × 107 copies/mg at 5 dpi and increased infiltration of inflammatory cells. RNA sequencing analysis identified differentially expressed genes (DEGs) after CA6 infection. DEGs in the blood, muscle, brain, spleen, and thymus were predominantly enriched in immune system responses, including pathways such as Toll-like receptor signalling and PI3K-Akt signalling. Our study has unveiled the genes involved in the host immune response during CA6 infection, thereby enhancing our comprehension of the pathological mechanism of HFMD.