BackgroundMultiple sclerosis (MS) is an inflammatory and demyelinating disease of the CNS. The etiology of MS is complex, and results from the interaction of multiple environmental and genetic factors. Although human leukocyte antigen-HLA alleles such as HLA-DR2 and –DR3 are considered the strongest genetic factors, the environmental factors responsible for disease predisposition are not well understood. Recently, diet and gut microbiota have emerged as an important environmental factors linked to the increased incidence of MS. Especially, western diets rich in protein and fat have been linked to the increased incidence of obesity. Numerous clinical data indicate a role of obesity and gut microbiota in MS; however, the mechanistic link between gut microbiota and obesity in the pathobiology of MS remains unclear. The present study determines the mechanisms driving MS severity in the context of obesity utilizing a high-fat diet (HFD) induced obese HLA-DR3 class-II transgenic mouse model of MS.MethodsHLA-DR3 transgenic mice were kept on a standard HFD diet or Normal Chow (NC) for eight weeks. Gut microbiota composition and functional analysis were performed from the fecal DNA of mice. Experimental autoimmune encephalomyelitis-EAE (an animal model of MS) was induced by immunization with the proteolipid protein-PLP91-110 peptide in complete Freud’s Adjuvant (CFA) and pertussis toxin.ResultsWe observed that HFD-induced obesity caused gut dysbiosis and severe disease compared to mice on NC. Amelioration of disease severity in mice depleted of gut microbiota suggested an important role of gut bacteria in severe EAE in obese mice. Fecal microbiota analysis in HFD mice shows gut microbiota alterations with an increase in the abundance of Proteobacteria and Desulfovibrionaceae bacteria and modulation of various bacterial metabolic pathways including bacterial hydrogen sulfide biosynthetic pathways. Finally, mice on HFD showed increased gut permeability and systemic inflammation suggesting a role gut barrier modulation in obesity induced disease severity.ConclusionsThis study provides evidence for the involvement of the gut microbiome and associated metabolic pathways plus gut permeability in obesity-induced modulation of EAE disease severity. A better understanding of the same will be helpful to identify novel therapeutic targets to reduce disease severity in obese MS patients.
A disrupted equilibrium between IL-17A-producing CD4 T-cells (Th17) and CD4+CD25+FoxP3+ regulatory T cells (Tregs) play an important role in the pathobiology of Multiple sclerosis (MS). Gut bacteria help in maintaining immune homeostasis by regulating the balance between anti-inflammatory Tregs and pro-inflammatory Th17 cells. Although, both gut bacteria and Tregs can regulate Th17 cells, the impact of IL-17A on gut microbiota and Tregs is unclear. Utilizing HLA-DR3 transgenic mouse model of MS, we show that IL-17A deficiency (HLA-DR3.IL17A-/- mice) expands Treg-inducing gut bacteria such as Prevotella, Parabacteroides, and Bacteroides and consequently Tregs, resulting in a milder disease in an animal model of MS. Notably, IL-17A sufficient DR3 mice develop milder disease on cohousing with IL-17A-deficient mice, highlighting a dominant role for gut microbiota in inducing Treg and reducing disease severity. Further, we observed an enrichment of bacterial-specific Treg promoting short-chain-fatty-acid metabolic pathways and induction of tolerogenic dendritic cells in HLA-DR3.IL17A-/- mice. Thus, our study shows a novel role of IL-17A in immune homeostasis and inflammation through regulation of the gut microbiota-Treg axis which can be used for the development of gut bacteria as therapeutics for MS.Significance of our workIL-17A a pro-inflammatory cytokine, is linked with pathobiology of multiple inflammatory diseases including multiple sclerosis (MS) and regulated by both gut microbiota and regulatory CD4 T cells (Tregs). However, the importance of IL-17A in the regulation of gut microbiota and Treg is unknown. Here we show that IL-17A can regulate Treg and disease phenotype by modulating gut microbiota and provide a novel mechanism by which immune-mediators such as IL-17A impact the gut microbiota to alter immune cell function and ultimately disease outcomes. Transfer of milder disease phenotype from IL-17A deficient mice to IL-17A sufficient mice on cohousing indicate a dominant role of gut microbiota in disease suppression. Thus, our study lays the foundation for future studies to unravel the interplay between immunological responses and the gut microbiota which will result in the development of microbiota-based therapeutics to treat autoimmune diseases.
Multiple sclerosis (MS) is an inflammatory, demyelinating disease of the central nervous system with unknown etiology. The interaction of both genetic and environmental factors plays an important role in MS pathogenesis. Recently, gut microbiota has emerged as a potential environmental factor in MS pathology due to its ability to modulate host immune response. Yet, it is unknown whether genetic factors, such as HLA class II gene(s), can influence gut microbiota which then can modulate MS through regulation of the host immune response. In the present study, we investigated the involvement of gut microbiota in HLA class II genes mediated susceptibility and resistance to MS/experimental autoimmune encephalomyelitis-EAE (an animal model of MS). Previously, we showed that HLA-DR3 transgenic mice lacking endogenous mouse class II genes (AE-KO) were susceptible to proteolipid protein-PLP91–110 induced EAE, whereas AE-KO.HLA-DQ8 transgenic mice were resistant to PLP91–110. Surprisingly, HLA-DR3.DQ8 double transgenic mice showed increased EAE severity compared with HLA-DR3 mice. Distinct microbiota in HLA-DR3, HLA-DQ8, and HLA-DR3.DQ8 transgenic mice compared to AE-KO mice suggested an important role of HLA class-II gene in shaping the gut microbiota composition. We also observed that gut microbiota of HLA-DQ8 mice was more similar to HLA-DR3.DQ8 than HLA-DR3. As the presence of HLA-DQ8 on an HLA-DR3 background increases disease severity, our data suggest that HLA-DQ8 restricted microbiota may contribute to disease severity in HLA-DR3.DQ8 mice. Altogether, our study provides evidence that the HLA-DR and -DQ genes linked to specific gut microbiota may contribute to EAE susceptibility or resistance in a transgenic animal model of MS. The authors acknowledge funding from the National Multiple Sclerosis Society (RG 5138A1/1T), NIAID/NIH (1R01AI137075-01), a Carver Trust Medical Research Initiative Grant, and the University of Iowa Environmental Health Sciences Research Center, NIEHS/NIH (P30 ES005605). SA was supported by the Emory Warner Fellowship, which provides medical students at the Carver College of Medicine the opportunity to take a full year out of their medical school curriculum to work in a laboratory in the University of Iowa Department of Pathology.
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