Riitta Veijola scite author profile

Recent studies have suggested a bacterial role in the development of autoimmune disorders including type 1 diabetes (T1D). Over 30 billion nucleotide bases of Illumina shotgun metagenomic data were analyzed from stool samples collected from four pairs of matched T1D case-control subjects collected at the time of the development of T1D associated autoimmunity (i.e., autoantibodies). From these, approximately one million open reading frames were predicted and compared to the SEED protein database. Of the 3,849 functions identified in these samples, 144 and 797 were statistically more prevalent in cases and controls, respectively. Genes involved in carbohydrate metabolism, adhesions, motility, phages, prophages, sulfur metabolism, and stress responses were more abundant in cases while genes with roles in DNA and protein metabolism, aerobic respiration, and amino acid synthesis were more common in controls. These data suggest that increased adhesion and flagella synthesis in autoimmune subjects may be involved in triggering a T1D associated autoimmune response. Extensive differences in metabolic potential indicate that autoimmune subjects have a functionally aberrant microbiome. Mining 16S rRNA data from these datasets showed a higher proportion of butyrate-producing and mucin-degrading bacteria in controls compared to cases, while those bacteria that produce short chain fatty acids other than butyrate were higher in cases. Thus, a key rate-limiting step in butyrate synthesis is more abundant in controls. These data suggest that a consortium of lactate- and butyrate-producing bacteria in a healthy gut induce a sufficient amount of mucin synthesis to maintain gut integrity. In contrast, non-butyrate-producing lactate-utilizing bacteria prevent optimal mucin synthesis, as identified in autoimmune subjects.

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Toward defining the autoimmune microbiome for type 1 diabetes

Giongo

et al. 2010

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Several studies have shown that gut bacteria have a role in diabetes in murine models. Specific bacteria have been correlated with the onset of diabetes in a rat model. However, it is unknown whether human intestinal microbes have a role in the development of autoimmunity that often leads to type 1 diabetes (T1D), an autoimmune disorder in which insulin-secreting pancreatic islet cells are destroyed. High-throughput, culture-independent approaches identified bacteria that correlate with the development of T1D-associated autoimmunity in young children who are at high genetic risk for this disorder. The level of bacterial diversity diminishes overtime in these autoimmune subjects relative to that of age-matched, genotype-matched, nonautoimmune individuals. A single species, Bacteroides ovatus, comprised nearly 24% of the total increase in the phylum Bacteroidetes in cases compared with controls. Conversely, another species in controls, represented by the human firmicute strain CO19, represented nearly 20% of the increase in Firmicutes compared with cases overtime. Three lines of evidence are presented that support the notion that, as healthy infants approach the toddler stage, their microbiomes become healthier and more stable, whereas, children who are destined for autoimmunity develop a microbiome that is less diverse and stable. Hence, the autoimmune microbiome for T1D may be distinctly different from that found in healthy children. These data also suggest bacterial markers for the early diagnosis of T1D. In addition, bacteria that negatively correlated with the autoimmune state may prove to be useful in the prevention of autoimmunity development in high-risk children.

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Interleukin-2 gene variation impairs regulatory T cell function and causes autoimmunity

et al. 2007

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Autoimmune diseases are thought to result from imbalances in normal immune physiology and regulation. Here, we show that autoimmune disease susceptibility and resistance alleles on mouse chromosome 3 (Idd3) correlate with differential expression of the key immunoregulatory cytokine interleukin-2 (IL-2). In order to test directly that an approximately two-fold reduction in IL-2 underpins the Idd3-linked destabilization of immune homeostasis, we demonstrate that engineered haplodeficiency of IL-2 gene expression not only reduces T cell IL-2 production by two-fold but also mimics the autoimmune dysregulatory effects of the naturally-occurring susceptibility alleles of IL-2. Reduced IL-2 production achieved by both genetic mechanisms correlates with fewer and less functional CD4+CD25+ regulatory T cells, which are critical for maintaining immune homeostasis.Multifactorial diseases with high population prevalence develop as a result of interactions between multiple genetic and environmental factors. Since the early 1990s, several loci have been mapped by genetic linkage and association analyses in humans and in rodent models of autoimmune disease, including type 1 diabetes (T1D). T1D is caused by the destruction of the insulin-producing pancreatic beta cells by various immune cell types, including CD8+ cytotoxic T-cells. In human T1D, four loci, in addition to the HLA region, have been identified: the genes encoding insulin, the negative immunoregulatory molecules CTLA-4 and LYP, and, most recently, the alpha chain of the interleukin-2 receptor (CD25) 1 . All of these common variants or haplotypes support the concept that autoimmunity is a part of normal physiology, and that the balance between immune responses to foreign antigens and

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Riitta Veijola

Seroconversion to Multiple Islet Autoantibodies and Risk of Progression to Diabetes in Children

Gut Microbiome Metagenomics Analysis Suggests a Functional Model for the Development of Autoimmunity for Type 1 Diabetes

Toward defining the autoimmune microbiome for type 1 diabetes

Interleukin-2 gene variation impairs regulatory T cell function and causes autoimmunity

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