Vitamin D deficiency induces Th2 skewing and eosinophilia in neonatal allergic airways disease.

BACKGROUND: Associations between vitamin D status and childhood asthma are increasingly reported, but direct causation and mechanisms underlying an effect remain unknown. We investigated the effect of early-life vitamin D deficiency on the development of murine neonatal allergic airways disease (AAD). METHODS: In utero and early-life vitamin D deficiency was achieved using a vitamin D-deficient diet for female mice during the third trimester of pregnancy and lactation. Offspring were weaned onto a vitamin D-deficient or vitamin D-replete diet, and exposure to intranasal house dust mite (HDM) or saline was commenced from day 3 of life for up to 6 weeks, when airway hyper-responsiveness (AHR), airway inflammation and remodelling were assessed. RESULTS: Neonatal mice that had in utero and early-life vitamin D deficiency had significantly increased pulmonary CD3(+) CD4(+) T1ST2(+) cells and reduced CD4(+) IL-10(+) cells. This effect was enhanced following HDM exposure. AHR in HDM-exposed mice was unaffected by vitamin D status. Introduction of vitamin D into the diet at weaning resulted in a significant reduction in serum IgE levels, reduced pulmonary eosinophilia and peri-bronchiolar collagen deposition. CONCLUSION: Peri-natal vitamin D deficiency alone has immunomodulatory effects including Th2 skewing and reduced IL-10-secreting T regulatory cells, exaggerated with additional allergen exposure. Vitamin D deficiency in early life does not affect AHR, but contributes to disease severity with worse eosinophilic inflammation and airway remodelling. Importantly, supplementation with vitamin D improves both of these pathological abnormalities.

T regulatory cells and the control of allergic disease.

Allergic diseases are caused by the induction of T helper (Th)2 cells and IgE responses specific for common environmental antigens (allergens) in susceptible individuals. There is increasing interest in the role of both naturally occurring and induced regulatory T cell (Treg) populations in preventing these inappropriate immune responses and the underlying sensitisation to allergens. Current evidence suggests that Tregs may actively prevent Th2 responses to allergens occurring in healthy non-atopic individuals and that their function may be impaired in allergic patients. Evidence that existing therapies may act by modulating Treg function is reviewed. Future research aims to understand the mechanisms involved in the generation and function of allergen-specific Tregs. A primary aim is to promote the development of optimised therapeutic regimens with the capacity to provide long-lasting, allergen-specific, inhibitory mechanisms at the time and site of allergen challenge.

Self major histocompatibility complex class-II-specific regulatory CD4 T cells prevent both Th1- and Th2-mediated autoimmune diseases in the rat.

It is clear that functional heterogeneity of T cells may be explained by differential cytokine production. The aim of this paper was to review evidence for regulatory cells, generated after HgCl(2)-exposure. They differ from classical Th1 and Th2 cells, produce transforming growth factor-beta and interleukin-10 and exert their regulatory functions in a Th1/Th2-unrestricted fashion.

The balance between CD45RChigh and CD45RClow CD4 T cells in rats is intrinsic to bone marrow-derived cells and is genetically controlled.

The level of CD45RC expression differentiates rat CD4 T cells in two subpopulations, CD45RC(high) and CD45RC(low), that have different cytokine profiles and functions. Interestingly, Lewis (LEW) and Brown Norway (BN) rats, two strains that differ in their ability to mount type 1 and type 2 immune responses and in their susceptibility to autoimmune diseases, exhibit distinct CD45RC(high)/CD45RC(low) CD4 T cell ratios. The CD45RC(high) subpopulation predominates in LEW rats, and the CD45RC(low) subpopulation in BN rats. In this study, we found that the antiinflammatory cytokines, IL-4, IL-10, and IL-13, are exclusively produced by the CD45RC(low) CD4 T cells. Using bone marrow chimeras, we showed that the difference in the CD45RC(high)/CD45RC(low) CD4 T cell ratio between naive LEW and BN rats is intrinsic to hemopoietic cells. Furthermore, a genome-wide search for loci controlling the balance between T cell subpopulations was conducted in a (LEW x BN) F(2) intercross. Genome scanning identified one quantitative trait locus on chromosome 9 (approximately 17 centiMorgan (cM); log of the odds ratio (LOD) score 3.9). In addition, two regions on chromosomes 10 (approximately 28 cM; LOD score 3.1) and 20 (approximately 40 cM; LOD ratio score 3) that contain, respectively, a cytokine gene cluster and the MHC region were suggestive for linkage. Interestingly, overlapping regions on these chromosomes have been implicated in the susceptibility to various immune-mediated disorders. The identification and functional characterization of genes in these regions controlling the CD45RC(high)/CD45RC(low) Th cell subpopulations may shed light on key regulatory mechanisms of pathogenic immune responses.

Cellular and genetic factors involved in the difference between Brown Norway and Lewis rats to develop respectively type-2 and type-1 immune-mediated diseases.

The understanding of the mechanisms of immune tolerance and the unravelling of the pathophysiology of autoimmune diseases rely on animal models. In this respect, BN and LEW rats represent models of choice to study immune-mediated diseases from the cellular and genetic points of view. Indeed, BN and LEW rats are extremes with respect to their polarisation of the immune response as well as their susceptibility to autoimmune diseases. LEW rats are susceptible to Th1-mediated autoimmune diseases while BN rats are highly susceptible to Th2-mediated autoimmune disease. Comparison of the T cell compartment between LEW and BN rats revealed several important differences. 1) A MHC-dependent quantitative difference that is due to a defect in the CD8 T cell compartment in BN rats. 2) A qualitative MHC-independent difference that is related to a high frequency of CD45RClow CD4 and CD8 T cell subsets, producing IL-4, IL-13, IL-10 and TGF-beta in BN rats as compared to LEW rats. 3) Interestingly, the genetic studies showed that susceptibility to Th1-mediated experimental autoimmune encephalomyelitis, and to Th2-mediated disorders triggered by gold salts as well as the difference in the CD4SRChigh/CD45RClow ratio between LEW and BN rats are genetically determined by regions on chromosomes 9, 10 and 20.