1. Rasgrp1 mutation increases naïve T-cell CD44 expression and drives mTOR-dependent accumulation of Helios+ T cells and autoantibodies
- Author
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Craig N. Jenne, Yunli Shao, Kristen M Coakley, Noelle K Polakos, Lisa A. Miosge, Katrina L. Randall, Stephen R. Daley, Darienne R. Myers, T. Daniel Andrews, Daniel Y. Hu, Carla M. Roots, Belinda Whittle, Geoff Sjollema, Edward M. Bertram, Bhavani Balakishnan, Jeroen P. Roose, S. Whitney Barnes, John R. Walker, Jason G. Cyster, Andre Limnander, Anselm Enders, Matthew A. Field, and Christopher C. Goodnow
- Subjects
Mouse ,T-Lymphocytes ,T lymphocte ,medicine.disease_cause ,Biochemistry ,T lymphoctes ,Autoimmunity ,Mice ,0302 clinical medicine ,Guanine Nucleotide Exchange Factors ,Missense mutation ,Biology (General) ,0303 health sciences ,education.field_of_study ,biology ,TOR Serine-Threonine Kinases ,General Neuroscience ,autoimmunity ,RasGRP1 ,General Medicine ,3. Good health ,Hyaluronan Receptors ,medicine.anatomical_structure ,mTOR ,Medicine ,Guanine nucleotide exchange factor ,signaling ,Research Article ,Naive T cell ,QH301-705.5 ,Science ,T cell ,Immunology ,Population ,General Biochemistry, Genetics and Molecular Biology ,03 medical and health sciences ,medicine ,Animals ,EF Hand Motifs ,education ,PI3K/AKT/mTOR pathway ,Autoantibodies ,030304 developmental biology ,General Immunology and Microbiology ,CD44 ,ENU mutant ,Molecular biology ,Mutation ,biology.protein ,030215 immunology - Abstract
Missense variants are a major source of human genetic variation. Here we analyze a new mouse missense variant, Rasgrp1Anaef, with an ENU-mutated EF hand in the Rasgrp1 Ras guanine nucleotide exchange factor. Rasgrp1Anaef mice exhibit anti-nuclear autoantibodies and gradually accumulate a CD44hi Helios+ PD-1+ CD4+ T cell population that is dependent on B cells. Despite reduced Rasgrp1-Ras-ERK activation in vitro, thymocyte selection in Rasgrp1Anaef is mostly normal in vivo, although CD44 is overexpressed on naïve thymocytes and T cells in a T-cell-autonomous manner. We identify CD44 expression as a sensitive reporter of tonic mTOR-S6 kinase signaling through a novel mouse strain, chino, with a reduction-of-function mutation in Mtor. Elevated tonic mTOR-S6 signaling occurs in Rasgrp1Anaef naïve CD4+ T cells. CD44 expression, CD4+ T cell subset ratios and serum autoantibodies all returned to normal in Rasgrp1AnaefMtorchino double-mutant mice, demonstrating that increased mTOR activity is essential for the Rasgrp1Anaef T cell dysregulation. DOI: http://dx.doi.org/10.7554/eLife.01020.001, eLife digest Our DNA contains more than three billion nucleotides. Each of these nucleotides can be an A, C, G or T, and groups of three neighboring nucleotides within our DNA are used to represent the 20 amino acids that are used to make proteins. This means that changing just one nucleotide can cause one amino acid to be replaced by a different amino acid in the protein encoded by that stretch of DNA: AAA and AAG code for the amino acid lysine, for example, but AAC and AAT code for asparagine. Known as missense gene variants, these changes can also increase or decrease the expression of the gene. Every person has thousands of missense gene variants, including about 12,000 inherited from their parents. Sometimes these variants have no consequence, but they can be harmful if replacing the correct amino acid with a different amino acid prevents the protein from performing an important task. In particular, missense gene variants in genes that encode immune system proteins are likely to play a role in diseases of the immune system. For example, variants near a gene called Rasgrp1 have been linked to two autoimmune diseases – type 1 diabetes and Graves’ disease—in which the immune system mistakenly attacks the body’s own cells and tissues. Now Daley et al. have shed new light on the mechanism by which a missense gene variant in Rasgrp1 can cause autoimmune diseases. Mice with this mutation show signs of autoimmune disease, but their T cells—white blood cells that have a central role in the immune system – develop normally despite this mutation. Instead, Daley et al. found that a specific type of T cell, called T helper cells, accumulated in large numbers in the mutant mice and stimulated cells of a third type—immune cells called B cells—to produce autoantibodies. The production of autoantibodies is a common feature of autoimmune diseases. Daley et al. traced the origins of the T helper cells to excessive activity on a signaling pathway that involves a protein called mTOR, and went on to show that treatment with the drug rapamycin counteracted the accumulation of the T helper cells and reduced the level of autoimmune activity. In addition to exemplifying how changing just one amino acid change can have a profound effect, the work of Daley et al. is an attractive model for exploring how missense gene variants in people can contribute to autoimmune diseases. DOI: http://dx.doi.org/10.7554/eLife.01020.002
- Published
- 2013