A commensal symbiotic factor derived from Bacteroides fragilis promotes human CD39(+)Foxp3(+) T cells and Treg function.

Polysaccharide A (PSA) derived from the human commensal Bacteroides fragilis is a symbiosis factor that stimulates immunologic development within mammalian hosts. PSA rebalances skewed systemic T helper responses and promotes T regulatory cells (Tregs). However, PSA-mediated induction of Foxp3 in humans has not been reported. In mice, PSA-generated Foxp3(+) Tregs dampen Th17 activity thereby facilitating bacterial intestinal colonization while the increased presence and function of these regulatory cells may guard against pathological organ-specific inflammation in hosts. We herein demonstrate that PSA induces expression of Foxp3 along with CD39 among naïve CD4 T cells in vitro while promoting IL-10 secretion. PSA-activated dendritic cells are essential for the mediation of this regulatory response. When cultured with isolated Foxp3(+) Tregs, PSA enriched Foxp3 expression, enhanced the frequency of CD39(+)HLA-DR(+) cells, and increased suppressive function as measured by decreased TNFα expression by LPS-stimulated monocytes. Our findings are the first to demonstrate in vitro induction of human CD4(+)Foxp3(+) T cells and enhanced suppressive function of circulating Foxp3(+) Tregs by a human commensal bacterial symbiotic factor. Use of PSA for the treatment of human autoimmune diseases, in particular multiple sclerosis and inflammatory bowel disease, may represent a new paradigm in the approach to treating autoimmune disease.

A commensal bacterial product elicits and modulates migratory capacity of CD39(+) CD4 T regulatory subsets in the suppression of neuroinflammation.

Tolerance established by host-commensal interactions regulates host immunity at both local mucosal and systemic levels. The intestinal commensal strain Bacteroides fragilis elicits immune tolerance, at least in part, via the expression capsular polysaccharide A (PSA). How such niche-specific commensal microbial elements regulate extra-intestinal immune responses, as in the brain, remains largely unknown. We have recently shown that oral treatment with PSA suppresses neuro-inflammation elicited during experimental autoimmune encephalomyelitis (EAE), an animal model for multiple sclerosis. This protection is dependent upon the expansion of immune-regulatory CD4 T cells (Treg) expressing CD39, an ectonucleotidase. Here, we further show that CD39 modulation of purinergic signals enhances migratory phenotypes of both total CD4 T cells and Foxp3(+) CD4 Tregs at central nervous system (CNS) lymphoid-draining sites in EAE in vivo and promotes their migration in vitro. These changes are noted during PSA treatment, which leads to heightened accumulation of CD39(+) CD4 Tregs in the CNS. Deficiency of CD39 abrogates accumulation of Treg during EAE, and is accompanied by elevated Th1/Th17 signals in the CNS and in gut-associated lymphoid tissues. Our results demonstrate that immune-modulatory commensal bacterial products impact the migratory patterns of CD4 Treg during CNS autoimmunity via the regulation of CD39. These observations provide clues as to how intestinal commensal microbiome is able to modulate Treg functions and impact host immunity in the distal site.

An intestinal commensal symbiosis factor controls neuroinflammation via TLR2-mediated CD39 signalling.

The mammalian immune system constitutively senses vast quantities of commensal bacteria and their products through pattern recognition receptors, yet excessive immune reactivity is prevented under homeostasis. The intestinal microbiome can influence host susceptibility to extra-intestinal autoimmune disorders. Here we report that polysaccharide A (PSA), a symbiosis factor for the human intestinal commensal Bacteroides fragilis, protects against central nervous system demyelination and inflammation during experimental autoimmune encephalomyelitis (EAE), an animal model for multiple sclerosis, through Toll-like receptor 2 (TLR2). TLR2 mediates tissue-specific expansion of a critical regulatory CD39(+) CD4 T-cell subset by PSA. Ablation of CD39 signalling abrogates PSA control of EAE manifestations and inflammatory cytokine responses. Further, CD39 confers immune-regulatory phenotypes to total CD4 T cells and Foxp3(+) CD4 Tregs. Importantly, CD39-deficient CD4 T cells show an enhanced capability to drive EAE progression. Our results demonstrate the therapeutic potential and underlying mechanism by which an intestinal symbiont product modulates CNS-targeted demyelination.

Glatiramer acetate biases dendritic cells towards an anti-inflammatory phenotype by modulating OPN, IL-17, and RORγt responses and by increasing IL-10 production in experimental allergic encephalomyelitis.

Paralleling our previous mechanistic studies of glatiramer acetate (GA; Copaxone) activity, we show that GA curbs the expression of Toll-like receptor (TLR) 9 and the universal adapter protein Myd88 in mice with EAE, the animal model for multiple sclerosis. Concurrent with enhanced dendritic cell (DC) production of IL-10, GA interferes with OPN, IL-17, and ROR gamma expression in DCs of mice with EAE, and suppresses brain expression of the EAE-induced chemokines, MIP1α and ß, IP-10 and RANTES. Thus GA not only biases dendritic cells towards an anti-inflammatory phenotype, but also suppresses the expression of factors that affect the blood-brain barrier penetration during neuroinflammation.

Augmentation of regulatory B cell activity in experimental allergic encephalomyelitis by glatiramer acetate.

We recently showed that B cells reduce CNS inflammation in mice with experimental allergic encephalomyelitis (EAE). Here, we demonstrate that adoptively transferred CD5/CD19+ B cells protect against EAE severity. Furthermore, we show that glatiramer acetate (GA), a therapeutic for relapsing multiple sclerosis treatment, amplifies this effect. Transfer of GA-conditioned B cells leads to increased production of immunoregulatory cytokines and reduced CNS inflammation, as well as decreased expression of the chemokine receptor, CXCR5, and elevated BDNF expression in the CNS. Thus B cells can protect against EAE, and GA augments this effect in maintaining immune homeostasis and controlling EAE disease progression.

Increased expression of B cell-associated regulatory cytokines by glatiramer acetate in mice with experimental autoimmune encephalomyelitis.

B cells are of increasing importance as a target for multiple sclerosis treatment. Here we show that GA treatment of mice with experimental autoimmune encephalomyelitis (EAE) biases cytokine production by B cells towards cytokines associated with regulation in MS including interleukin (IL)-4, -10 and -13 and reduces pro-inflammatory IL-6, IL-12, and TNF alpha levels. GA also down-regulates expression of B cell-activating factor (BAFF) of the TNF family and a proliferation-inducing ligand (APRIL), as well as the BAFF receptor in mice with EAE. Thus, GA impacts both B cell survival and B cell cytokine production during CNS inflammatory disease in an EAE model.