Project description:TRIM5 integrates hypoglycemic stress and influenza infection

Project description:Hypoglycemia, a common complication in diabetic patients receiving insulin or hypoglycemic agents, as well as in individuals undergoing prolonged fasting, can cause brain damage; however, the molecular mechanisms underlying this effect remain poorly understood. To shed light on this issue, we investigated the molecular basis of hypoglycemia-induced neurodegeneration using both in vitro and in vivo hypoglycemic models. Starvation-induced hypoglycemia triggers neurodegenerative features in human neurons and glial cells, mirroring those observed in the brains of hypoglycemic mice. Notably, neurons activated a survival mechanism via serum response factor (SRF) and myocardin-related transcription factor A (MRTF-A)-mediated metabolic reprogramming, utilizing extracellular matrix (ECM) components as alternative energy sources. This adaptation led to excessive production of urea cycle by-products, which in turn induced neurodegeneration, astrocyte reactivity, and microglial activation. Importantly, glucose refeeding reversed these neurodegenerative features by deactivating SRF/MRTF-A signaling. Together, our results uncover a neuron-intrinsic mechanism linking glucose deprivation to reversible neurodegeneration via SRF/MRTF-A, offering potential targets for preventing hypoglycemia-associated brain damage.

Project description:Introduction: Asthma, a chronic airway disease, is marked by allergic inflammation, hyperresponsiveness, and tissue remodeling. Influenza infections in asthma patients can cause severe exacerbations, though the underlying mechanisms remain unclear. This study investigated how pre-existing allergic inflammation affects immune responses to influenza infection in mice exposed to house dust mite (HDM). Methods: Mice were repeatedly exposed to HDM, followed by infection with influenza A virus, and were sacrificed three days post-infection. Plasma was analyzed for HDM-specific immunoglobulins, while lung tissue was used for immune cell flow cytometry and RNA sequencing analysis. Results: HDM exposure induced allergic inflammation, evidenced by more HDM-specific IgE, IgG1, IgG2, eosinophils, neutrophils, Th1, and Th17 cells compared to controls. Upon influenza infection, the effects of HDM and influenza co-infection interacted, showing fewer Th1 cells and regulatory T cells and more Th2 cells compared to mice exposed to influenza virus alone. Interestingly, RNA-seq analysis revealed less upregulation of Th1-related genes and antiviral pathways in co-exposed mice, suggesting impaired Th1 immunity and antiviral responses. Conclusion: Pre-existing allergic inflammation significantly altered immune responses in mice coinfected with influenza, revealing underdeveloped antiviral responses as early as three days post-infection. These findings may explain the increased susceptibility of patients with asthma to severe viral diseases.

Project description:Repeated exposures to insulin-induced hypoglycemia in diabetic patients progressively impair the counter-regulatory response (CRR) that restores normoglycemia. This defect is characterized by reduced secretion of glucagon and other counter-regulatory hormones. Evidence indicates that glucose responsive neurons located in the hypothalamus, orchestrate the CRR. Here, we aimed at identifying the changes in hypothalamic gene and protein expression that underlie impaired CRR. High fat diet fed and low dose streptozocin-treated C57BL6N mice were exposed to one (acute hypoglycemia, AH) or multiple (recurrent hypoglycemia, RH) insulin-induced hypoglycemic episodes. Single nuclei RNA sequencing (snRNAseq) data were obtained from the hypothalamus and cortex of AH and RH mice. Proteomic data were also obtained from hypothalamic synaptosomal fractions. The present study shows that repeated moderate hypoglycemia in diabetic mice lead, in the hypothalamus, to multiple cellular physiology changes, affecting all cell types and their interactions, which show striking features of neurodegenerative diseases. It also shows that repeated hypoglycemic episodes affect very differently the hypothalamus and the cortex.

Project description:Host cell lipids play a pivotal role in the pathogenesis of respiratory virus infection. However, a direct comparison of the lipidomic profile of influenza virus and rhinovirus infections is lacking. In this study, we first compared the lipid profile of influenza virus and rhinovirus infection in a bronchial epithelial cell line. Most lipid features were downregulated for both influenza virus and rhinovirus, especially for the sphingomyelin features. Pathway analysis showed that sphingolipid metabolism was the most perturbed pathway. Functional study showed that bacterial sphingomyelinase suppressed influenza virus and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) replication, but promoted rhinovirus replication. These findings suggest that sphingomyelin pathway can be a potential target for antiviral therapy, but should be carefully evaluated as it has opposite effects on different respiratory viruses. Furthermore, the differential effect of sphingomyelinase on rhinovirus and influenza virus may explain the interference between rhinovirus and influenza virus infection.

Project description:Induction of vast transcriptional programs is a central event of innate host responses to viral infections. Here we report a unique transcriptional program with potent antiviral activity, driven by E74-like ETS transcription factor 1 (ELF1). Using high-content microscopy to quantify viral infection over time, we found that ELF1 inhibits eight diverse RNA and DNA viruses uniquely at multi-cycle replication. Elf1 deficiency results in enhanced susceptibility to influenza A virus infections in mice. ELF1 does not feed-forward to induce interferons, and ELF1’s antiviral effect is not abolished by the absence of STAT1 or by inhibition of JAK phosphorylation. Accordingly, comparative expression analyses by RNAseq revealed that the ELF1 transcriptional program is distinct from interferon signatures. Thus, ELF1 provides an additional layer of the innate host response, independent from the action of type I interferons.

Project description:Human rhinovirus and influenza virus infections of the upper airway lead to colds and the flu and can trigger exacerbations of lower airway diseases including asthma and chronic obstructive pulmonary disease. Despite modest advances in the diagnosis and treatment of infections by these viruses, novel diagnostic and therapeutic targets are still needed to differentiate between the cold and the flu, since the clinical course of influenza can be severe while that of rhinovirus is usually more mild. In our investigation of influenza and rhinovirus infection of human respiratory epithelial cells, we used a systems approach to identify the temporally changing patterns of host gene expression from these viruses. After infection of human bronchial epithelial cells (BEAS-2B) with rhinovirus, influenza virus or co-infection with both viruses, we studied the time-course of host gene expression changes over three days. From these data, we constructed a transcriptional regulatory network model that revealed shared and unique host responses to these viral infections such that after a lag of 4-8 hours, most cell host responses were similar for both viruses, while divergent host cell responses appeared after 24-48 hours. The similarities and differences in gene expression after epithelial infection of rhinovirus, influenza virus, or both viruses together revealed qualitative and quantitative differences in innate immune activation and regulation. These differences help explain the generally mild outcome of rhinovirus infections compared to influenza infections which can be much more severe. Human bronchial epithelial cells (BEAS-2B) were infected with rhinovirus, influenza virus or both viruses and RNAs were then profiled at 10 time points (2, 4, 6, 8, 12, 24, 26, 48, 60 and 72hrs)

Project description:The protein TRIM5 alpha has multiple roles in anti-retroviral defense, but the mechanisms underlying TRIM5 alpha action are unclear. Here, we used an APEX2-based proteomics approach to identify TRIM5 alpha-interacting proteins. Analysis of the TRIM5 alpha interactome found proteins participating in a wide variety of cellular functions including regulating antiviral signaling pathways. We used this data set to uncover a novel role for TRIM5 alpha in mitophagy, an autophagy-based mode of mitochondrial quality control that is compromised in multiple human diseases. Mitochondrial damage triggered the relocalization of TRIM5 alpha to ER-mitochondria contact sites where TRIM5 alpha colocalized with markers of autophagy initiation and autophagosome biogenesis. Furthermore, we found that TRIM5 alpha knockout attenuated both Parkin-dependent and Parkin-independent mitophagy by preventing the recruitment of autophagy regulators FIP200 and ATG13 to unhealthy mitochondria. Finally, TRIM5 alpha knockout cells showed reduced mitochondrial function under basal conditions and were more susceptible to uncontrolled immune activation and cell death in response to mitochondrial damage than were wild type cells. Taken together, our studies have identified a homeostatic role for a protein previously recognized exclusively for its antiviral actions.

Project description:Dynamic nuclear SUMO modifications play essential roles in orchestrating cellular responses to proteotoxic stress, DNA damageand DNA virus infections. Here, we describe the host SUMOylation response to the nuclear-replicating RNA pathogen, influenz A virus. Using quantitative proteomics to compare SUMOylation responses to various stresses (including heat-shock), we reveal that influenza A virus infection causes unique re-targeting of SUMO1 and SUMO2 to a diverse range of host proteins involved in transcription, mRNA processing, RNA quality control and DNA damage repair. This global characterization of influenza virus-triggered SUMO remodeling provides a proteomic resource to understand host nuclear SUMOylation responses to infection.

Project description:Influenza virus infections remain a major public health burden. The intrinsic ever-evolving nature of this virus, the suboptimal efficacy of recent influenza inactivated vaccines, as well as the emergence of resistance against a limited antiviral arsenal, highlight the urgent need for novel therapeutic approaches to treat influenza infections. Here, we exploited in vivo transcriptomic signatures of infection, directly obtained from a patient’s cohort to identify in silico a list of marketed drugs with signatures that counteracted that of the infection state.