Dietary non-starch polysaccharides impair immunity to enteric nematode infection.

BACKGROUND: The influence of diet on immune function and resistance to enteric infection and disease is becoming ever more established. Highly processed, refined diets can lead to inflammation and gut microbiome dysbiosis, whilst health-promoting dietary components such as phytonutrients and fermentable fibres are thought to promote a healthy microbiome and balanced mucosal immunity. Chicory (Cichorium intybus) is a leafy green vegetable rich in fibres and bioactive compounds that may promote gut health. RESULTS: Unexpectedly, we here show that incorporation of chicory into semisynthetic AIN93G diets renders mice susceptible to infection with enteric helminths. Mice fed a high level of chicory leaves (10% dry matter) had a more diverse gut microbiota, but a diminished type-2 immune response to infection with the intestinal roundworm Heligmosomoides polygyrus. Furthermore, the chicory-supplemented diet significantly increased burdens of the caecum-dwelling whipworm Trichuris muris, concomitant with a highly skewed type-1 immune environment in caecal tissue. The chicory-supplemented diet was rich in non-starch polysaccharides, particularly uronic acids (the monomeric constituents of pectin). In accordance, mice fed pectin-supplemented AIN93G diets had higher T. muris burdens and reduced IgE production and expression of genes involved in type-2 immunity. Importantly, treatment of pectin-fed mice with exogenous IL-25 restored type-2 responses and was sufficient to allow T. muris expulsion. CONCLUSIONS: Collectively, our data suggest that increasing levels of fermentable, non-starch polysaccharides in refined diets compromises immunity to helminth infection in mice. This diet-infection interaction may inform new strategies for manipulating the gut environment to promote resistance to enteric parasites.

Gluten-free diet reduces autoimmune diabetes mellitus in mice across multiple generations in a microbiota-independent manner.

Experimental and clinical data suggest that a gluten-free diet attenuates the development of type 1 diabetes. A gluten-free diet changes the gut microbiota composition, and such microbial changes are expected to reduce the autoimmune responses. However, in experiments with laboratory mice, a gluten-free diet changes the gut microbiota differently under varying experimental settings, questioning the specific role of the gut microbes. Here we show that a maternal gluten-free diet until weaning of their pups, delayed type 1 diabetes in both dams (parent generation) and offspring (F1 generation) of untreated non-obese diabetic (NOD) mice and in mice treated with a full cocktail of antibiotics that eradicates most of the existing microbiota. Breeding a second (F2) generation of NOD mice, never exposed to the gluten-free diet or the associated microbial changes, also demonstrated a preventative effect on type 1 diabetes even though their parents (the F1 generation) had only been on a gluten-free diet very early in life. Collectively, the experimental data, thus, points towards microbiota-independent dietary protection. Furthermore, both the perinatal gluten-free diet and antibiotic treatment reduced inflammation in the salivary glands and improved glucose challenged beta cell function in the F1 offspring. However, in contrast to the autoimmune response in the pancreas, those changes appeared to be microbiota dependent, as they were missing in the antibiotic treated mice, and do, therefore, not seem to be related to the preventative effect on type 1 diabetes. Interestingly, adoptive transfer of splenocytes from gluten-free fed mice protected NOD.SCID mice from developing diabetes, demonstrating that the anti-diabetic effect of a gluten-free diet was based on early life changes in the evolving immune system. In particular, genes involved in regulation of lymphocyte activation, proliferation, and cell adhesion were highly expressed in the spleen in gluten-free fed mice at weaning compared to control fed mice of the F1 generation, which suggested that gluten promotes autoimmunity by inhibiting immune regulation, though the involvement of the specific genes needs further investigation. In conclusion, gluten-free diet reduces autoimmune inflammation in salivary glands and pancreas in NOD mice in a microbiota-dependent and -independent manner respectively, and has preventative effect on type 1 diabetes by modulating the systemic immune system.

Wet-lab tested microRNA assays for qPCR studies with SYBR® Green and DNA primers in pig tissues.

MicroRNAs are key post-transcriptional regulators of gene expression that are involved in several biological processes including those that mediate disease pathophysiology. Hence, quantifying microRNA expression levels can provide important and novel insights into disease biology. In recent years, the pig has emerged as an excellent large animal model for studying human diseases and conditions (e.g. obesity) due to similarities in organ size, gastro-intestinal tract, metabolism, immune response, genetics and the availability of relevant tissues that are not normally easily available in humans. We have previously developed two useful tools in the field of microRNA quantitative real time PCR (qPCR): 1) a very specific, sensitive and simple qPCR method based on DNA primers, MiR-specific qPCR; and 2) the free primer-design software miRprimer. The present study integrates in a publicly accessible database all available information on validated porcine microRNA qPCR assays that have utilized these tools. Due to the high phylogenetic conservation in microRNA sequence between pig, humans and other domestic species this database is a very valuable resource for the broader scientist community who are working on microRNAs and want to use readily tested qPCR assays in a simple and cost-effective manner.