Bi-directional signaling between the intestinal epithelium and type-3 innate lymphoid cells regulates secretory dynamics and interleukin-22

Oral exposure to nanoplastics and food allergy in mice fed a normal or high-fat diet

The global prevalence of food allergies, particularly IgE-mediated responses, is increasing at an alarming rate. This trend is likely driven by environmental factors such as nanoplastics (NPs) ingestion and the westernization of dietary and lifestyle habits. This study examines the impact of polystyrene nanoplastics (PS-NPs) on ovalbumin (OVA)-induced food allergies in mice subjected to either a normal diet (ND) or a high-fat diet (HFD). BALB/c mice were stratified into eight groups based on dietary regimen, NP exposure, and OVA sensitization. Food allergy was induced via OVA administration, and multiple physiological and immunological parameters were evaluated, including body weight, intestinal permeability, cytokine profiles, gut microbiota composition, and small intestinal gene expression. Mice in the HFD + OVA + NP group exhibited significant increases in intestinal permeability, diarrhea severity, and serum OVA-specific IgE levels compared to other groups. Flow cytometric analysis revealed an expansion of innate lymphoid cells (ILC2 and ILC1) within the lamina propria of the small intestine. Shotgun metagenomic sequencing demonstrated gut microbiota dysbiosis, characterized by a reduction in beneficial bacterial populations in the HFD + OVA + NP cohort. Weighted Gene Co-Expression Network Analysis (WGCNA) identified a negative correlation between NPs exposure or OVA sensitization and the expression of Slc1a1, Slc5a8, and Mep1a, while a positive correlation was observed with Aa467197 expression. These findings indicate that oral exposure to PS-NPs exacerbates OVA-induced food allergies, particularly in the context of an HFD, through mechanisms involving increased intestinal permeability, gut microbial dysbiosis, and gene expression modulation. This study highlights the potential health hazards posed by environmental microplastic contamination and its possible contribution to the escalating incidence of food allergies.

The gut-organ axis: Clinical aspects and immune mechanisms

The gut-brain axis exemplifies the bidirectional connection between the intestines and the brain, as evidenced by the impact of severe stress on gastrointestinal symptoms including abdominal pain and diarrhea, and conversely, the influence of abdominal discomfort on mood. Clinical observations support the notion of the gut-brain connection, including an increased prevalence of inflammatory bowel disease (IBD) in patients with depression and anxiety, as well as the association of changes in the gut microbiota with neurological disorders such as multiple sclerosis, Parkinson's disease, stroke and Alzheimer's disease. The gut and brain communicate via complex mechanisms involving inflammatory cytokines, immune cells, autonomic nerves, and gut microbiota, which contribute to the pathogenesis in certain gut and brain diseases. Two primary pathways mediate the bidirectional information exchange between the intestinal tract and the brain: signal transduction through bloodstream factors, such as bacterial metabolites and inflammatory cytokines, and neural pathways, such as neurotransmitters and inflammatory cytokines within the autonomic nervous system through the interaction between the nerve cells and beyond. In recent years, the basic mechanisms of the pathophysiology of the gut-brain axis have been gradually elucidated. Beyond the gut-brain interaction, emerging evidence suggests the influence of the gut extends to other organs, such as the liver and lungs, through intricate inter-organ communication pathways. An increasing number of reports on this clinical and basic cross-organ interactions underscore the potential for better understanding and novel therapeutic strategies targeting inter-organs networks. Further clarification of interactions between multiorgans premises transformative insights into cross-organ therapeutic strategies.

Immune Regulation of Goblet Cell and Mucus Functions in Health and Disease

The mucosal surfaces of the body are the most vulnerable points for infection because they are lined by single or multiple layers of very active epithelial cells. The main protector of these cells is the mucus system generated by the specialized goblet cell secreting its main components, the gel-forming mucins. The organization of the mucus varies from an attached mucus that is impenetrable to bacteria in the large intestine to a nonattached, more penetrable mucus in the small intestine. The respiratory tract mucus system clears particles and microorganisms from healthy lungs but causes disease if reorganized to an attached mucus that cannot be efficiently transported. Similarly, transformation of large intestine mucus from impenetrable to penetrable causes chronic inflammation directed toward the intestinal microbiota. Mucus-producing goblet cells are regulated by and responsive to signals from immune cells, and at the same time signal back to the immune system. In this review we focus on the relationship of immune cells with intestinal goblet cells and mucus, making parallels to the respiratory tract.

Enteric GABAergic neuron-derived γ-aminobutyric acid initiates expression of Igfbp7 to sustain ILC3 homeostasis

Neuronal signals have emerged as critical factors that regulate group 3 innate lymphoid cell (ILC3) response and tissue homeostasis, but the molecular mechanisms underlying this regulation remain largely elusive. Here, we identified that the enteric GABAergic neuron-derived neurotransmitter γ-aminobutyric acid (GABA) inhibited proliferation and IL-17A production in ILC3s in a manner dependent on the GABA receptors Gabbr1 and Gabbr2. Conditional deletion of Gabbr1 or ablation of GABAergic neurons caused increased IL-17A production and aggravated colitis. Mechanistically, GABA suppressed the expression of the LIP isoform of the transcription factor C/EBP-β in ILC3s, which repressed the transcription of Igfbp7, which encodes the secreted factor Igfbp7. Autocrine Igfbp7 signaling through the receptor Igf1R inhibited ILC3 proliferation and IL-17A production. Suppression of signaling through the GABA-C/EBP-β-IGFBP7 pathway highly correlated with severity of intestinal inflammation in patients with inflammatory bowel disease (IBD). Collectively, our findings describe an important molecular mechanism underlying the maintenance of gut immune homeostasis.

Epithelial-neuronal-immune cell interactions: Implications for immunity, inflammation, and tissue homeostasis at mucosal sites

The epithelial lining of the respiratory tract and intestine provides a critical physical barrier to protect host tissues against environmental insults, including dietary antigens, allergens, chemicals, and microorganisms. In addition, specialized epithelial cells communicate directly with hematopoietic and neuronal cells. These epithelial-immune and epithelial-neuronal interactions control host immune responses and have important implications for inflammatory conditions associated with defects in the epithelial barrier, including asthma, allergy, and inflammatory bowel diseases. In this review, we discuss emerging research that identifies the mechanisms and impact of epithelial-immune and epithelial-neuronal cross talk in regulating immunity, inflammation, and tissue homeostasis at mucosal barrier surfaces. Understanding the regulation and impact of these pathways could provide new therapeutic targets for inflammatory diseases at mucosal sites.