Mechanistic studies on the allergy protective effect of Acinetobacter lwoffii in the mouse

BACKGROUND: Early childhood or even prenatal exposures to farm bacteria such as Acinetobacter lwoffii have been demonstrated an association with a decreased incidence of allergy and asthma later in life. Studies in mouse models demonstrated that intranasal application of A. lwoffii stimulates local and systemic innate immunity as reflected by increased levels of the pro-inflammatory cytokines, especially interleukin-6 (IL-6) levels in lungs and serum. AIMS AND HYPOTHESIS: The key concept of this study was to understand different mechanistic pathways of the A. lwoffii protective effect against asthma. We hypothesized that interleukin-6 (IL-6) might contributes to the protective effect of A. lwoffii against asthma/allergy development. We further supposed that treatment with A. lwoffii stimulates the innate immune system in which it can skew the function of the adaptive immune system towards mechanisms know to favor lower asthma and/or allergy susceptibility. Furthermore, we expand our hypothesis to highlight the role of the cecum microbiota changes in mediating the protective effects of the A. lwoffii against asthma in the WT and IL-6 KO mice. METHOD AND RESULTS: We first investigate the innate immune response upon contact with A. lwoffii, the mouse was chronically treated with A. lwoffii and then the blood and bronchial lavage were collected for pro-inflammatory cytokines measurement, TNFa and IL-1b developed tolerance after the 5th application but the IL-6 exhibit unusual response with no tolerance during the repeated treatment. Further assessments in Wild-type and IL-6 knockout mice pre-exposed to A. lwoffii and subjected to the OVA model of airway inflammation demonstrate a pivotal role of IL-6 in mediating the protective effects of A. lwoffii. This data was supported with the in vitro data where the mouse primary macrophages (PM), plasmacytoid dendritic cells (pDCs), and myeloid dendritic cells (mDCs) exposed to A. lwoffii secreted huge amounts of IL-6, as measured in the culture supernatants. Culturing of naïve murine T cells with supernatant from A. lwoffii-exposed macrophages or recombinant IL-6 induce the secretion of high levels of IL-10 and less extend of IL-17. The subsequent animal experiment revealed that IL-10 but not IL-17 deficient mice pretreated with A. lwoffii failed to develop protection against airway inflammation, suggesting that IL-10 but not IL-17 plays an important role in mediating the effects of A. lwoffii downstream of IL-6. On top of that, the microbial DNA from the cecum content of the IL-6 KO and WT littermate mice were isolated and sequenced to investigate the changes in the relative abundance of taxa in the cecum microbiome. The genotype effect, the A. lwoffii effect, the OVA sensitization effect, and the A. lwoffii effect in OVA-sensitized mice were studied in IL-6 KO and WT littermate animal. The data demonstrated an important role of the Ruminococcaceae family which is indicating their susceptibility to immune control which is maybe underlying the immunological/anti-allergic phenotypes in the IL-6 KO mice, the A. lwoffii is having its immunological effects through the inhibition of the Ruminococcaceae family. CONCLUSION: Protective effects of A. lwoffii against asthma development seem to be at least partly mediated by IL-6. Thus IL-6 might be an important modulator of the adaptive immune system towards the non-/anti-allergic direction. The in vitro macrophages exposed to A. lwoffii secrete huge amounts of IL-6, which in turn stimulates the synthesis of IL-10 and IL-17 by T cells after culturing the naïve T cells with supernatant from A. lwoffii-exposed macrophages. A subsequent experiment in mouse model demonstrates that IL-10 but not IL-17 play an important role in downstream the protective effects of A. lwoffii on adaptive immunity. Furthermore, the microbiome analysis in the IL-6 KO and WT littermate indicates a possible immune regulation via the Ruminococcaceae family which is maybe underlying the immunological/anti-allergic phenotypes in the IL-6 KO mice, the A. lwoffii is having its immunological effects through the inhibition of the Ruminococcaceae family. Further investigations in germ-free mice are required to address the role Ruminococcaceae, and additional in-depth investigations, including those on the possible interaction with IL-10, are ongoing

Dental Biofilm and Saliva Microbiome and Its Interplay with Pediatric Allergies

Little is known about the interplay and contribution of oral microorganisms to allergic diseases, especially in children. The aim of the clinical study was to associate saliva and dental biofilm microbiome with allergic disease, in particular with allergic asthma. In a single-center study, allergic/asthmatic children (n = 15; AA-Chd; age 10.7 ± 2.9), atopic/allergic children (n = 16; AT/AL-Chd; 11.3 ± 2.9), and healthy controls (n = 15; CON-Chd; age 9.9 ± 2.2) were recruited. After removing adhering biofilms from teeth and collecting saliva, microbiome was analyzed by using a 16s-rRNA gene-based next-generation sequencing in these two mediums. Microbiome structure differed significantly between saliva and dental biofilms (β-diversity). Within the groups, the dental biofilm microbiome of AA-Chd and AT/AL-Chd showed a similar microbial fingerprint characterized by only a small number of taxa that were enriched or depleted (4) compared to the CON-Chd, while both diseased groups showed a stronger microbial shift compared to CON-Chd, revealing 14 taxa in AA-Chd and 15 taxa in AT/AL-Chd that were different. This could be the first note to the contribution of dental biofilm and its metabolic activity to allergic health or disease

An update on the epigenetics of asthma

PURPOSE OF REVIEW: Asthma is a common disease worldwide, however, its pathogenesis has not been fully elucidated. Emerging evidence suggests that epigenetic modifications may play a role in the development and natural history of asthma. The aim of this review is to highlight recent progress in research on epigenetic mechanisms in asthma. RECENT FINDINGS: Over the past years, epigenetic studies, in particular DNA methylation studies, have added to the growing body of evidence supporting a link between epigenetic regulation of gene expression and asthma. Recent studies demonstrate that epigenetic mechanisms also play a role in asthma remission. Although most existing studies in this field have been conducted on blood cells, recent evidence suggests that epigenetic signatures are also crucial for the regulation of airway epithelial cells. Studies conducted on nasal epithelium revealed highly replicable epigenetic patterns that could be used for diagnostic purposes. SUMMARY: Further research is needed to explore the diagnostic and therapeutic potential of epigenetic modifications in asthma. Multiomics studies on asthma will become increasingly important for a better understanding of etiology, heterogeneity, and severity of asthma, as well as establishing molecular biomarkers that could be combined with clinical information to improve the management of asthma patients

Decreased Histone Acetylation Levels at Th1 and Regulatory Loci after Induction of Food Allergy

Immunoglobulin E (IgE)-mediated allergy against cow’s milk protein fractions such as whey is one of the most common food-related allergic disorders of early childhood. Histone acetylation is an important epigenetic mechanism, shown to be involved in the pathogenesis of allergies. However, its role in food allergy remains unknown. IgE-mediated cow’s milk allergy was successfully induced in a mouse model, as demonstrated by acute allergic symptoms, whey-specific IgE in serum, and the activation of mast cells upon a challenge with whey protein. The elicited allergic response coincided with reduced percentages of regulatory T (Treg) and T helper 17 (Th17) cells, matching decreased levels of H3 and/or H4 histone acetylation at pivotal Treg and Th17 loci, an epigenetic status favoring lower gene expression. In addition, histone acetylation levels at the crucial T helper 1 (Th1) loci were decreased, most probably preceding the expected reduction in Th1 cells after inducing an allergic response. No changes were observed for T helper 2 cells. However, increased histone acetylation levels, promoting gene expression, were observed at the signal transducer and activator of transcription 6 (Stat6) gene, a proallergic B cell locus, which was in line with the presence of whey-specific IgE. In conclusion, the observed histone acetylation changes are pathobiologically in line with the successful induction of cow’s milk allergy, to which they might have also contributed mechanistically

Secreted Ligands of the NK Cell Receptor NKp30: B7-H6 Is in Contrast to BAG6 Only Marginally Released via Extracellular Vesicles

NKp30 (Natural Cytotoxicity Receptor 1, NCR1) is a powerful cytotoxicity receptor expressed on natural killer (NK) cells which is involved in tumor cell killing and the regulation of antitumor immune responses. Ligands for NKp30, including BAG6 and B7-H6, are upregulated in virus-infected and tumor cells but rarely detectable on healthy cells. These ligands are released by tumor cells as part of the cellular secretome and interfere with NK cell activity. BAG6 is secreted via the exosomal pathway, and BAG6-positive extracellular vesicles (EV-BAG6) trigger NK cell cytotoxicity and cytokine release, whereas the soluble protein diminishes NK cell activity. However, the extracellular format and activity of B7-H6 remain elusive. Here, we used HEK293 as a model cell line to produce recombinant ligands and to study their impact on NK cell activity. Using this system, we demonstrate that soluble B7-H6 (sB7-H6), like soluble BAG6 (sBAG6), inhibits NK cell-mediated target cell killing. This was associated with a diminished cell surface expression of NKG2D and NCRs (NKp30, NKp40, and NKp46). Strikingly, a reduced NKp30 mRNA expression was observed exclusively in response to sBAG6. Of note, B7-H6 was marginally released in association with EVs, and EVs collected from B7-H6 expressing cells did not stimulate NK cell-mediated killing. The molecular analysis of EVs on a single EV level using nano flow cytometry (NanoFCM) revealed a similar distribution of vesicle-associated tetraspanins within EVs purified from wildtype, BAG6, or B7-H6 overexpressing cells. NKp30 is a promising therapeutic target to overcome NK cell immune evasion in cancer patients, and it is important to unravel how extracellular NKp30 ligands inhibit NK cell functions

Short-Chain Fatty Acids Augment Differentiation and Function of Human Induced Regulatory T Cells

Regulatory T cells (Tregs) control immune system activity and inhibit inflammation. While, in mice, short-chain fatty acids (SCFAs) are known to be essential regulators of naturally occurring and in vitro induced Tregs (iTregs), data on their contribution to the development of human iTregs are sparse, with no reports of the successful SCFAs-augmented in vitro generation of fully functional human iTregs. Likewise, markers undoubtedly defining human iTregs are missing. Here, we aimed to generate fully functional human iTregs in vitro using protocols involving SCFAs and to characterize the underlying mechanism. Our target was to identify the potential phenotypic markers best characterizing human iTregs. Naïve non-Treg CD4+ cells were isolated from the peripheral blood of 13 healthy adults and cord blood of 12 healthy term newborns. Cells were subjected to differentiation toward iTregs using a transforming growth factor β (TGF-β)-based protocol, with or without SCFAs (acetate, butyrate, or propionate). Thereafter, they were subjected to flow cytometric phenotyping or a suppression assay. During differentiation, cells were collected for chromatin-immunoprecipitation (ChIP)-based analysis of histone acetylation. The enrichment of the TGF-β-based protocol with butyrate or propionate potentiated the in vitro differentiation of human naïve CD4+ non-Tregs towards iTregs and augmented the suppressive capacity of the latter. These seemed to be at least partly underlain by the effects of SCFAs on the histone acetylation levels in differentiating cells. GITR, ICOS, CD39, PD-1, and PD-L1 were proven to be potential markers of human iTregs. Our results might boost the further development of Treg-based therapies against autoimmune, allergic and other chronic inflammatory disorders

Epigenetic Modifications in Placenta are Associated with the Child’s Sensitization to Allergens

Prenatal environmental exposures are considered to contribute to the development of allergic sensitization by epigenetic mechanisms. The role of histone acetylation in the placenta has not been examined yet. We hypothesized that placental histone acetylation at the promoter regions of allergy-related immune regulatory genes is associated with the development of sensitization to allergens in the child. Histones H3 and H4 acetylation at the promoter regions of 6 selected allergy-related immune regulatory genes was assessed by a chromatin immunoprecipitation assay in 173 term placentas collected in the prospective birth-cohort ALADDIN. The development of IgE sensitization to allergens in the children was followed from 6 months up to 5 years of age. We discovered significant associations of histone acetylation levels with decreased risk of allergic sensitization in 3 genes. Decreased risk of sensitization to food allergens was associated with higher H3 acetylation levels in placentas at the IFNG and SH2B3 genes, and for H4 acetylation in HDAC4. Higher HDAC4 H4 acetylation levels were also associated with a decreased risk of sensitization to aeroallergens. In conclusion, our results suggest that acetylation of histones in placenta has a potential to predict the development of sensitization to allergens in children

Differential Regulation of Interferon Signaling Pathways in CD4+ T Cells of the Low Type-2 Obesity-Associated Asthma Phenotype

In the era of personalized medicine, insights into the molecular mechanisms that differentially contribute to disease phenotypes, such as asthma phenotypes including obesity-associated asthma, are urgently needed. Peripheral blood was drawn from 10 obese, non-atopic asthmatic adults with a high body mass index (BMI; 36.67 ± 6.90); 10 non-obese, non-atopic asthmatic adults with normal BMI (23.88 ± 2.73); and 10 healthy controls with normal BMI (23.62 ± 3.74). All asthmatic patients were considered to represent a low type-2 asthma phenotype according to selective clinical parameters. RNA sequencing (RNA-Seq) was conducted on peripheral blood CD4+ T cells. Thousands of differentially expressed genes were identified in both asthma groups compared with heathy controls. The expression of interferon (IFN)-stimulated genes associated with IFN-related signaling pathways was specifically affected in obese asthmatics, while the gap junction and G protein-coupled receptor (GPCR) ligand binding pathways were enriched in both asthma groups. Furthermore, obesity gene markers were also upregulated in CD4+ T cells from obese asthmatics compared with the two other groups. Additionally, the enriched genes of the three abovementioned pathways showed a unique correlation pattern with various laboratory and clinical parameters. The specific activation of IFN-related signaling and viral infection pathways might provide a novel view of the molecular mechanisms associated with the development of the low type-2 obesity-associated asthma phenotype, which is a step ahead in the development of new stratified therapeutic approaches