MAVS integrates glucose metabolism and RIG-I-like receptor signaling

Cepharanthine mitigates NIBV-induced pyroptosis via the MDA5/NF-κB/NLRP3 signaling pathway

This study elucidates the mechanism through which cepharanthine (CEP) mitigates NIBV-induced pyrodeath in renal tubular epithelial cells by modulating the MDA5/NF-κB/NLRP3 signaling pathway. Primary renal tubular epithelial cells (RTECs) were isolated from one-day-old Hy-Line Brown chicks and subsequently assigned to four groups. The C+CEP and N + CEP groups received 0.5 μM CEP, while the NIBV and N + CEP groups were exposed to 1 MOI of the SX9 strain of NIBV. The study shows that CEP significantly reduces NIBV load (P < 0.05) and decreases the mRNA and protein levels of MDA5/NF-κB/NLRP3 signaling components, such as MDA5, ISP-1, TRAF6, TAK1, NF-κB, IKKα, IKKβ, NLRP3, caspase-1, IL-1β, and IL-18, upon NIBV infection (P < 0.05 or P < 0.01). Moreover, CEP markedly reduced cellular pyroptosis (P < 0.001) and lactate dehydrogenase (LDH) activity (P < 0.01). Flow cytometry and fluorescence-based assays corroborated these findings, revealing a substantial diminution in pyroptosis post-NIBV infection in CEP-treated cells (P < 0.01). Laser confocal microscopy revealed a clear decrease in NLRP3-associated red fluorescence foci after CEP treatment. These results highlight that CEP could mitigate NIBV-induced pyroptosis in RTECs by modulating the MDA5/NF-κB/NLRP3 signaling pathway.

Exploring the role of mitochondrial dysfunction and aging in COVID-19-Related neurological complications

The COVID-19 pandemic, caused by SARS-CoV-2, posed a tremendous challenge to healthcare systems globally. Severe COVID-19 infection was reported to be associated with altered immunometabolism and cytokine storms, contributing to poor clinical outcomes and in many cases resulting in mortality. Despite promising preclinical results, many drugs have failed to show efficacy in clinical trials, highlighting the need for novel approaches to combat the virus and its severe manifestations. Mitochondria, crucial for aerobic respiration, play a pivotal role in modulating immunometabolism and neuronal function, making their compromised capability as central pathological mechanism contributing to the development of neurological complications in COVID-19. Dysregulated mitochondrial dynamics can lead to uncontrolled immune responses, underscoring the importance of mitochondrial regulation in shaping clinical outcomes. Aging further accelerates mitochondrial dysfunction, compounding immune dysregulation and neurodegeneration, making older adults particularly vulnerable to severe COVID-19 and its neurological sequelae. COVID-19 infection impairs mitochondrial oxidative phosphorylation, contributing to the long-term neurological complications associated with the disease. Additionally, recent reports also suggest that up to 30% of COVID-19 patients experience lingering neurological issues, thereby highlighting the critical need for further research into mitochondrial pathways to mitigate long-tern neurological consequences of Covid-19. This review examines the role of mitochondrial dysfunction in COVID-19-induced neurological complications, its connection to aging, and potential biomarkers for clinical diagnostics. It also discusses therapeutic strategies aimed at maintaining mitochondrial integrity to improve COVID-19 outcomes.

From powerhouse to modulator: regulating immune system responses through intracellular mitochondrial transfer

Mitochondria are traditionally known as the cells' powerhouses; however, their roles go far beyond energy suppliers. They are involved in intracellular signaling and thus play a crucial role in shaping cells' destiny and functionality, including immune cells. Mitochondria can be actively exchanged between immune and non-immune cells via mechanisms such as nanotubes and extracellular vesicles. The mitochondria transfer from immune cells to different cells is associated with physiological and pathological processes, including inflammatory disorders, cardiovascular diseases, diabetes, and cancer. On the other hand, mitochondrial transfer from mesenchymal stem cells, bone marrow-derived stem cells, and adipocytes to immune cells significantly affects their functions. Mitochondrial transfer can prevent exhaustion/senescence in immune cells through intracellular signaling pathways and metabolic reprogramming. Thus, it is emerging as a promising therapeutic strategy for immune system diseases, especially those involving inflammation and autoimmune components. Transferring healthy mitochondria into damaged or dysfunctional cells can restore mitochondrial function, which is crucial for cellular energy production, immune regulation, and inflammation control. Also, mitochondrial transfer may enhance the potential of current therapeutic immune cell-based therapies such as CAR-T cell therapy.

The ELF3-TRIM22-MAVS signaling axis regulates type I interferon and antiviral responses

Activation of the innate immune response is essential for host cells to restrict the dissemination of invading viruses and other pathogens. Proteins belonging to the tripartite motif (TRIM) family are key effectors in antiviral innate immunity. Among these, TRIM22, a RING-type E3 ubiquitin ligase, has been recognized as a significant regulator in the pathogenesis of various diseases. In the present study, we identified TRIM22 as a critical modulator of mitochondrial antiviral signaling protein (MAVS) activation. Loss of TRIM22 function led to reduced production of type I interferons (IFNs) in response to viral infection such as influenza A virus (IAV) or vesicular stomatitis virus (VSV), thereby facilitating viral replication. Mechanistically, TRIM22 was found to enhance retinoic acid-inducible gene I (RIG-I)-mediated signaling through the catalysis of Lys63-linked polyubiquitination of MAVS, which, in turn, activated the TANK-binding kinase 1 (TBK1)/interferon regulatory factor 3 (IRF3) pathway, driving IFN-β production. Additionally, TRIM22 was shown to inhibit the assembly of the MAVS-NLRX1 inhibitory complex, further amplifying innate immune responses. Our findings also demonstrated that RNA virus infection upregulated TRIM22 expression via the nuclear translocation of ELF3, a transcription factor that activates TRIM22 gene expression. This regulatory loop underscores the role of TRIM22 in modulating the type I IFN pathway, providing critical insights into the host's antiviral defense mechanisms. Our research highlights the potential of targeting the ELF3-TRIM22-MAVS axis as a therapeutic strategy for enhancing antiviral immunity and preventing RNA virus infections.IMPORTANCEInterferon (IFN)-mediated antiviral responses are crucial for the host's defense against foreign pathogens and are regulated by various signaling pathways. The tripartite motif (TRIM) family, recognized for its multifaceted roles in immune regulation and antiviral defense, plays a significant part in this process. In our study, we explored the important role of TRIM22, a protein that helped regulate the host's immune response to viral infections. We found that TRIM22 enhances the Lys63-linked polyubiquitination of mitochondrial antiviral signaling protein (MAVS), which was essential for producing type I interferons. Interestingly, we discovered that the expression of TRIM22 increases after an RNA virus infection, due to a transcription factor ELF3, which moved into the nucleus of cells to activate TRIM22 transcription. This created a feedback loop that strengthens the role of TRIM22 in modulating the type I IFN pathway. By uncovering these mechanisms, we aimed to enhance our understanding of how the immune system works and provide insights that could lead to innovative antiviral therapies.

Berberine Suppresses Influenza A Virus-Triggered Pyroptosis in Macrophages via Intervening in the mtROS-MAVS-NLRP3 Inflammasome Pathway

Infection with influenza A virus (IAV) may trigger excessive inflammatory responses, leading to severe viral pneumonia and accelerating disease progression. Therefore, controlling these excessive inflammatory responses is crucial for the prevention and treatment of pneumonia caused by IAV. Berberine (BBR), an isoquinoline alkaloid extracted from traditional Chinese medicine, possesses extensive pharmacological activities. However, its immunoregulatory effects and molecular mechanisms in the context of IAV infection require further investigation. This study explored the impact of BBR on macrophage pyroptosis and inflammatory responses induced by IAV infection. Our findings revealed that BBR effectively inhibits the release of IL-1β and TNF-α induced by IAV infection and suppresses gasdermin D (GSDMD)-mediated pyroptosis in a dose-dependent manner. Further research indicates that BBR alleviates macrophage pyroptosis and inflammatory responses in IAV-infected cells by reducing the release of mitochondrial reactive oxygen species (mtROS), inhibiting mitochondrial antiviral signaling protein (MAVS) expression and blocking the activation of the NOD-like receptor family pyrin domain containing 3 (NLRP3) inflammasome. Experiments using siRNA to knockdown MAVS further confirmed the pivotal role of MAVS in BBR's inhibition of IAV-induced macrophage pyroptosis. This study provides a scientific basis for the application of BBR as an anti-inflammatory drug in the treatment of inflammatory diseases caused by IAV infection and directs future research endeavors.

Lactate activates trained immunity by fueling the tricarboxylic acid cycle and regulating histone lactylation

Trained immunity refers to the long-term memory of the innate immune cells. However, little is known about how environmental nutrient availability influences trained immunity. This study finds that physiologic carbon sources impact glucose contribution to the tricarboxylic acid (TCA) cycle and enhance cytokine production of trained monocytes. Our experiments demonstrate that trained monocytes preferentially employe lactate over glucose as a TCA cycle substrate, and lactate metabolism is required for trained immune cell responses to bacterial and fungal infection. Except for the contribution to the TCA cycle, endogenous lactate or exogenous lactate also supports trained immunity by regulating histone lactylation. Further transcriptome analysis, ATAC-seq, and CUT&Tag-seq demonstrate that lactate enhance chromatin accessibility in a manner dependent histone lactylation. Inhibiting lactate-dependent metabolism by silencing lactate dehydrogenase A (LDHA) impairs both lactate fueled the TCA cycle and histone lactylation. These findings suggest that lactate is the hub of immunometabolic and epigenetic programs in trained immunity.

Circular RNAs modulate cancer drug resistance: advances and challenges

Acquired drug resistance is a main factor contributing to cancer therapy failure and high cancer mortality, highlighting the necessity to develop novel intervention targets. Circular RNAs (circRNAs), an abundant class of RNA molecules with a closed loop structure, possess characteristics including high stability, which provide unique advantages in clinical application. Growing evidence indicates that aberrantly expressed circRNAs are associated with resistance against various cancer treatments, including targeted therapy, chemotherapy, radiotherapy, and immunotherapy. Therefore, targeting these aberrant circRNAs may offer a strategy to improve the efficiency of cancer therapy. Herein, we present a summary of the most recently studied circRNAs and their regulatory roles on cancer drug resistance. With the advances in artificial intelligence (AI)-based bioinformatics algorithms, circRNAs could emerge as promising biomarkers and intervention targets in cancer therapy.

Exploring the role of mitochondrial antiviral signaling protein in cardiac diseases

Mitochondrial antiviral signaling (MAVS) was first discovered as an activator of NF-κB and IRF3 in response to viral infection in 2005. As a key innate immune adapter that acts as an 'on/off' switch in immune signaling against most RNA viruses. Upon interaction with RIG-I, MAVS aggregates to activate downstream signaling pathway. The MAVS gene, located on chromosome 20p13, encodes a 540-amino acid protein that located in the outer membrane of mitochondria. MAVS protein was ubiquitously expressed with higher levels in heart, skeletal muscle, liver, placenta and peripheral blood leukocytes. Recent studies have reported MAVS to be associated with various conditions including cancers, systemic lupus erythematosus, kidney disease, and cardiovascular disease. This article provides a comprehensive summary and description of MAVS research in cardiac disease, encompassing structure, expression, protein-protein interactions, modifications, as well as the role of MAVS in heart disease. It is aimed to establish a scientific foundation for the identification of potential therapeutic target.

Feline Calicivirus Infection Manipulates Central Carbon Metabolism

Viruses can manipulate the host metabolism to achieve optimal replication conditions, and central carbon metabolism (CCM) pathways are often crucial in determining viral infections. Feline calicivirus (FCV), a diminutive RNA viral agent, induces upper respiratory tract infections in feline hosts, with highly pathogenic strains capable of precipitating systemic infections and subsequent host cell necrosis, thereby presenting a formidable challenge to feline survival and protection. However, the relationship between FCV and host cell central carbon metabolism (CCM) remains unclear, and the precise pathogenic mechanisms of FCV are yet to be elucidated. Upon FCV infection of Crandell-Rees Feline Kidney (CRFK) cells, an enhanced cellular uptake of glucose and glutamine was observed. Metabolomics analyses disclosed pronounced alterations in the central carbon metabolism of the infected cells. FCV infection was found to augment glycolytic activity while sustaining the tricarboxylic acid (TCA) cycle flux, with cellular ATP levels remaining invariant. Concurrently, both glutamine metabolism and the flux of the pentose phosphate pathway (PPP) were noted to be intensified. The application of various inhibitory agents targeting glycolysis, glutamine metabolism, and the PPP resulted in a significant suppression of FCV proliferation. Experiments involving glucose and glutamine deprivation demonstrated that the absence of either nutrient markedly curtailed FCV replication. Collectively, these findings suggest a critical interplay between central carbon metabolism and FCV proliferation. FCV infection stimulates CRFK cells to augment glucose and glutamine uptake, thereby supplying the necessary metabolic substrates and energy for viral replication. During the infection, glutamine emerges as the primary energy substrate, ensuring ATP production and energy homeostasis, while glucose is predominantly channeled into the pentose phosphate pathway to facilitate nucleotide synthesis.

Peroxisomes are underappreciated organelles hijacked by viruses

Peroxisomes are cellular organelles that are crucial for metabolism, stress responses, and healthy aging. They have recently come to be considered as important mediators of the immune response during viral infections. Consequently, various viruses target peroxisomes for the purpose of hijacking either their biogenesis or their functions, as a means of replicating efficiently, making this a compelling research area. Despite their known connections with mitochondria, which have been the object of considerable research on account of their role in the innate immune response, less is known about peroxisomes in this context. In this review, we explore the evolving understanding of the role of peroxisomes, highlighting recent findings on how they are exploited by viruses to modulate their replication cycle.

The impact of COVID-19 on accelerating of immunosenescence and brain aging

The COVID-19 pandemic, caused by the novel coronavirus SARS-CoV-2, has profoundly impacted global health, affecting not only the immediate morbidity and mortality rates but also long-term health outcomes across various populations. Although the acute effects of COVID-19 on the respiratory system have initially been the primary focus, it is increasingly evident that the virus can have significant impacts on multiple physiological systems, including the nervous and immune systems. The pandemic has highlighted the complex interplay between viral infection, immune aging, and brain health, that can potentially accelerate neuroimmune aging and contribute to the persistence of long COVID conditions. By inducing chronic inflammation, immunosenescence, and neuroinflammation, COVID-19 may exacerbate the processes of neuroimmune aging, leading to increased risks of cognitive decline, neurodegenerative diseases, and impaired immune function. Key factors include chronic immune dysregulation, oxidative stress, neuroinflammation, and the disruption of cellular processes. These overlapping mechanisms between aging and COVID-19 illustrate how the virus can induce and accelerate aging-related processes, leading to an increased risk of neurodegenerative diseases and other age-related conditions. This mini-review examines key features and possible mechanisms of COVID-19-induced neuroimmune aging that may contribute to the persistence and severity of long COVID. Understanding these interactions is crucial for developing effective interventions. Anti-inflammatory therapies, neuroprotective agents, immunomodulatory treatments, and lifestyle interventions all hold potential for mitigating the long-term effects of the virus. By addressing these challenges, we can improve health outcomes and quality of life for millions affected by the pandemic.

UBXN9 governs GLUT4-mediated spatial confinement of RIG-I-like receptors and signaling

The cytoplasmic RIG-I-like receptors (RLRs) recognize viral RNA and initiate innate antiviral immunity. RLR signaling also triggers glycolytic reprogramming through glucose transporters (GLUTs), whose role in antiviral immunity is elusive. Here, we unveil that insulin-responsive GLUT4 inhibits RLR signaling independently of glucose uptake in adipose and muscle tissues. At steady state, GLUT4 is trapped at the Golgi matrix by ubiquitin regulatory X domain 9 (UBXN9, TUG). Following RNA virus infection, GLUT4 is released and translocated to the cell surface where it spatially segregates a significant pool of cytosolic RLRs, preventing them from activating IFN-β responses. UBXN9 deletion prompts constitutive GLUT4 translocation, sequestration of RLRs and attenuation of antiviral immunity, whereas GLUT4 deletion heightens RLR signaling. Notably, reduced GLUT4 expression is uniquely associated with human inflammatory myopathies characterized by hyperactive interferon responses. Overall, our results demonstrate a noncanonical UBXN9-GLUT4 axis that controls antiviral immunity via plasma membrane tethering of cytosolic RLRs.

The E3 ligase ASB3 downregulates antiviral innate immunity by targeting MAVS for ubiquitin-proteasomal degradation

E3 ubiquitin ligases are very important for regulating antiviral immunity during viral infection. Here, we discovered that Ankyrin repeat and SOCS box-containing protein 3 (ASB3), an E3 ligase, are upregulated in the presence of RNA viruses, particularly influenza A virus (IAV). Notably, overexpression of ASB3 inhibits type I IFN (IFN-I) responses induced by Sendai virus (SeV) and IAV, and ablation of ASB3 restores SeV and H9N2 infection-mediated transcription of IFN-β and its downstream interferon-stimulated genes (ISGs). Interestingly, animals lacking ASB3 presented decreased susceptibility to H9N2 and H1N1 infections. Mechanistically, ASB3 interacts with MAVS and directly mediates K48-linked polyubiquitination and degradation of MAVS at K297, thereby inhibiting the phosphorylation of TBK1 and IRF3 and downregulating downstream antiviral signaling. These findings establish ASB3 as a critical negative regulator that controls the activation of antiviral signaling and describe a novel function of ASB3 that has not been previously reported.

Charting and probing the activity of ADARs in human development and cell-fate specification

Adenosine deaminases acting on RNA (ADARs) impact diverse cellular processes and pathological conditions, but their functions in early cell-fate specification remain less understood. To gain insights here, we began by charting time-course RNA editing profiles in human organs from fetal to adult stages. Next, we utilized hPSC differentiation to experimentally probe ADARs, harnessing brain organoids as neural specific, and teratomas as pan-tissue developmental models. We show that time-series teratomas faithfully recapitulate fetal developmental trends, and motivated by this, conducted pan-tissue, single-cell CRISPR-KO screens of ADARs in teratomas. Knocking out ADAR leads to a global decrease in RNA editing across all germ-layers. Intriguingly, knocking out ADAR leads to an enrichment of adipogenic cells, revealing a role for ADAR in human adipogenesis. Collectively, we present a multi-pronged framework charting time-resolved RNA editing profiles and coupled ADAR perturbations in developmental models, thereby shedding light on the role of ADARs in cell-fate specification.

RIG012 assists in the treatment of pneumonia by inhibiting the RIG-I-like receptor signaling pathway

Objective

Pneumonia is a common clinical condition primarily treated with antibiotics and organ support. Exploring the pathogenesis to identify therapeutic targets may aid in the adjunct treatment of pneumonia and improve survival rates.

Methods

Transcriptomic data from peripheral blood of 183 pneumonia patients were analyzed using Gene Set Variation Analysis (GSVA) and univariate Cox regression analysis to identify signaling pathways associated with pneumonia mortality. A pneumonia mouse model was established via airway injection of Klebsiella pneumoniae, and pathway-specific blockers were administered via tail vein infusion to assess whether the identified signaling pathways impact the mortality in pneumonia.

Results

The combination of GSVA and Cox analysis revealed 17 signaling pathways significantly associated with 28-day mortality in pneumonia patients (P < 0.05). Notably, the RIG-I-like receptor signaling pathway exhibited the highest hazard ratio of 2.501 with a 95% confidence interval of [1.223-5.114]. Infusion of RIG012 via the tail vein effectively inhibited the RIG-I-like receptor signaling pathway, significantly ameliorated lung injury in pneumonia mice, reduced pulmonary inflammatory responses, and showed a trend toward improved survival rates.

Conclusion

RIG012 may represent a novel adjunctive therapeutic agent for pneumonia.

USP8 suppresses porcine reproductive and respiratory syndrome virus replication by positively regulating MAVS mediated Ⅰ-IFN signaling

Porcine reproductive and respiratory syndrome virus (PRRSV) is an important RNA virus that has caused huge economic losses to swine industry in the whole world. Ubiquitin specific protease 8 (USP8), a pivotal regulator of protein degradation, intricately contributes to orchestrating the delicate balance of various biological processes through its deubiquitinating activity. However, the role of USP8 in antiviral immune response to PRRSV remains elusive. In the study, by means of overexpressing USP8, we identified that USP8 suppressed the replication of PRRSV, while reducing USP8 expression using siRNA significantly led to the promotion of PRRSV replication. And USP8 facilitates the production of IFN-β and some IFN-stimulated genes (ISGs) during PRRSV infection. Mechanistically, USP8 promoted mitochondrial antiviral signaling protein (MAVS)-mediated IFN-β signaling. Moreover, USP8 interacted with MAVS and exerted anti-PRRSV effects in a MAVS-dependent manner. This study highlights the importance of USP8 in regulating PRRSV replication, which may enhance our comprehension of its role in innate immunity and its impact on viral replication.

System-level integrative omics analysis to identify the virus-host immunometabolic footprint during infection

The emergence and re-emergence of infectious diseases present significant global health threats. Understanding their pathogenesis is crucial for developing diagnostics, therapeutics, and preventive strategies. System-level integrative omics analysis offers a comprehensive approach to deciphering virus-host immunometabolic interactions during infections. Multi-omics approaches, integrating genomics, transcriptomics, proteomics, and metabolomics, provide holistic insights into disease mechanisms, host-pathogen interactions, and immune responses. The interplay between the immune system and metabolic processes, termed immunometabolism, has gained attention, particularly in infectious diseases. Immunometabolic studies reveal how metabolic processes regulate immune cell function, shaping immune responses and influencing infection outcomes. Metabolic reprogramming is crucial for immune cell activation, differentiation, and function. Using systems biological algorithms to understand the immunometabolic alterations can provide a holistic view of immune and metabolic pathway interactions, identifying regulatory nodes and predicting responses to perturbations. Understanding these pathways enhances the knowledge of immune regulation and offers avenues for therapeutic interventions. This review highlights the contributions of multi-omics systems biology studies in understanding infectious disease pathogenesis, focusing on RNA viruses. The integrative approach enables personalized medicine strategies, considering individual metabolic and immune variations. Leveraging these interdisciplinary approaches promises advancements in combating RNA virus infections and improving health outcomes, highlighting the transformative impact of multi-omics technologies in infectious disease research.

Long COVID as a disease of accelerated biological aging: An opportunity to translate geroscience interventions

It has been four years since long COVID-the protracted consequences that survivors of COVID-19 face-was first described. Yet, this entity continues to devastate the quality of life of an increasing number of COVID-19 survivors without any approved therapy and a paucity of clinical trials addressing its biological root causes. Notably, many of the symptoms of long COVID are typically seen with advancing age. Leveraging this similarity, we posit that Geroscience-which aims to target the biological drivers of aging to prevent age-associated conditions as a group-could offer promising therapeutic avenues for long COVID. Bearing this in mind, this review presents a translational framework for studying long COVID as a state of effectively accelerated biological aging, identifying research gaps and offering recommendations for future preclinical and clinical studies.

Role of the Innate Immune Response in Glomerular Disease Pathogenesis: Focus on Podocytes

Accumulating evidence indicates that inflammatory and immunologic processes play a significant role in the development and progression of glomerular diseases. Podocytes, the terminally differentiated epithelial cells, are crucial for maintaining the integrity of the glomerular filtration barrier. Once injured, podocytes cannot regenerate, leading to progressive proteinuric glomerular diseases. However, emerging evidence suggests that podocytes not only maintain the glomerular filtration barrier and are important targets of immune responses but also exhibit many features of immune-like cells, where they are involved in the modulation of the activity of innate and adaptive immunity. This dual role of podocytes may lead to the discovery and development of new therapeutic targets for treating glomerular diseases. This review aims to provide an overview of the innate immunity mechanisms involved in podocyte injury and the progression of proteinuric glomerular diseases.

mRNA and miRNA expression profiles reveal the potential roles of RLRs signaling pathway and mitophagy in duck hepatitis A virus type 1 infection

Duck hepatitis A virus 1 (DHAV-1) is the primary cause of duck viral hepatitis, leading to sudden mortality in ducklings and significant economic losses in the duck industry. However, little is known about how DHAV-1 affects duckling liver at the molecular level. We conducted an analysis comparing the expression patterns of mRNAs and miRNAs in DHAV-1-infected duckling livers to understand the underlying mechanisms and dynamic changes. We identified 6,818 differentially expressed mRNAs (DEGs) and 144 differentially expressed microRNAs (DEMs) during DHAV-1 infection. Functional enrichment analysis of DEGs and miRNA target genes using gene ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) revealed their potential involvement in innate antiviral immunity, mitophagy, and pyroptosis. We constructed coexpression networks of mRNA-miRNA interactions and confirmed key DEMs (novel-mir333, novel-mir288, novel-mir197, and novel-mir71) using RT-qPCR. Further investigation demonstrated that DHAV-1 activates the RLRs signaling pathway, disrupts mitophagy, and induces pyroptosis. In conclusion, DHAV-1-induced antiviral immunity is closely linked to mitophagy, suggesting it could be a promising therapeutic target.

UBXN9 governs GLUT4-mediated spatial confinement of RIG-I-like receptors and signaling

The cytoplasmic RIG-I-like receptors (RLRs) recognize viral RNA and initiate innate antiviral immunity. RLR signaling also triggers glycolytic reprogramming through glucose transporters (GLUTs), whose role in antiviral immunity is elusive. Here, we unveil that insulin-responsive GLUT4 inhibits RLR signaling independently of glucose uptake in adipose and muscle tissues. At steady state, GLUT4 is docked at the Golgi matrix by ubiquitin regulatory X domain 9 (UBXN9, TUG). Following RNA virus infection, GLUT4 is released and translocated to the cell surface where it spatially segregates a significant pool of cytosolic RLRs, preventing them from activating IFN-β responses. UBXN9 deletion prompts constitutive GLUT4 trafficking, sequestration of RLRs, and attenuation of antiviral immunity, whereas GLUT4 deletion heightens RLR signaling. Notably, reduced GLUT4 expression is uniquely associated with human inflammatory myopathies characterized by hyperactive interferon responses. Overall, our results demonstrate a noncanonical UBXN9-GLUT4 axis that controls antiviral immunity via plasma membrane tethering of cytosolic RLRs.

Pattern-Recognition Receptors and Immunometabolic Reprogramming: What We Know and What to Explore

BACKGROUND

Evolutionarily, immune response is a complex mechanism that protects the host from internal and external threats. Pattern-recognition receptors (PRRs) recognize MAMPs, PAMPs, and DAMPs to initiate a protective pro-inflammatory immune response. PRRs are expressed on the cell membranes by TLR1, 2, 4, and 6 and in the cytosolic organelles by TLR3, 7, 8, and 9, NLRs, ALRs, and cGLRs. We know their downstream signaling pathways controlling immunoregulatory and pro-inflammatory immune response. However, the impact of PRRs on metabolic control of immune cells to control their pro- and anti-inflammatory activity has not been discussed extensively.

SUMMARY

Immune cell metabolism or immunometabolism critically determines immune cells' pro-inflammatory phenotype and function. The current article discusses immunometabolic reprogramming (IR) upon activation of different PRRs, such as TLRs, NLRs, cGLRs, and RLRs. The duration and type of PRR activated, species studied, and location of immune cells to specific organ are critical factors to determine the IR-induced immune response.

KEY MESSAGE

The work herein describes IR upon TLR, NLR, cGLR, and RLR activation. Understanding IR upon activating different PRRs is critical for designing better immune cell-specific immunotherapeutics and immunomodulators targeting inflammation and inflammatory diseases.

Hepatocyte Intrinsic Innate Antiviral Immunity against Hepatitis Delta Virus Infection: The Voices of Bona Fide Human Hepatocytes

The pathogenesis of viral infection is attributed to two folds: intrinsic cell death pathway activation due to the viral cytopathic effect, and immune-mediated extrinsic cellular injuries. The immune system, encompassing both innate and adaptive immunity, therefore acts as a double-edged sword in viral infection. Insufficient potency permits pathogens to establish lifelong persistent infection and its consequences, while excessive activation leads to organ damage beyond its mission to control viral pathogens. The innate immune response serves as the front line of defense against viral infection, which is triggered through the recognition of viral products, referred to as pathogen-associated molecular patterns (PAMPs), by host cell pattern recognition receptors (PRRs). The PRRs-PAMPs interaction results in the induction of interferon-stimulated genes (ISGs) in infected cells, as well as the secretion of interferons (IFNs), to establish a tissue-wide antiviral state in an autocrine and paracrine manner. Cumulative evidence suggests significant variability in the expression patterns of PRRs, the induction potency of ISGs and IFNs, and the IFN response across different cell types and species. Hence, in our understanding of viral hepatitis pathogenesis, insights gained through hepatoma cell lines or murine-based experimental systems are uncertain in precisely recapitulating the innate antiviral response of genuine human hepatocytes. Accordingly, this review article aims to extract and summarize evidence made possible with bona fide human hepatocytes-based study tools, along with their clinical relevance and implications, as well as to identify the remaining gaps in knowledge for future investigations.

Metabolic regulation of type I interferon production

Over the past decade, there has been a surge in discoveries of how metabolic pathways regulate immune cell function in health and disease, establishing the field of immunometabolism. Specifically, pathways such as glycolysis, the tricarboxylic acid (TCA) cycle, and those involving lipid metabolism have been implicated in regulating immune cell function. Viral infections cause immunometabolic changes which lead to antiviral immunity, but little is known about how metabolic changes regulate interferon responses. Interferons are critical cytokines in host defense, rapidly induced upon pathogen recognition, but are also involved in autoimmune diseases. This review summarizes how metabolic change impacts interferon production. We describe how glycolysis, lipid metabolism (specifically involving eicosanoids and cholesterol), and the TCA cycle-linked intermediates itaconate and fumarate impact type I interferons. Targeting these metabolic changes presents new therapeutic possibilities to modulate type I interferons during host defense or autoimmune disorders.

Metabolic Enzymes in Viral Infection and Host Innate Immunity

Metabolic enzymes are central players for cell metabolism and cell proliferation. These enzymes perform distinct functions in various cellular processes, such as cell metabolism and immune defense. Because viral infections inevitably trigger host immune activation, viruses have evolved diverse strategies to blunt or exploit the host immune response to enable viral replication. Meanwhile, viruses hijack key cellular metabolic enzymes to reprogram metabolism, which generates the necessary biomolecules for viral replication. An emerging theme arising from the metabolic studies of viral infection is that metabolic enzymes are key players of immune response and, conversely, immune components regulate cellular metabolism, revealing unexpected communication between these two fundamental processes that are otherwise disjointed. This review aims to summarize our present comprehension of the involvement of metabolic enzymes in viral infections and host immunity and to provide insights for potential antiviral therapy targeting metabolic enzymes.