Browsing by Subject "LAT"
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Item Open Access The Function of LAT in T Cell Activation and Autoimmunity(2010) Chuck, MarianaLAT (linker for activation of T cells) is an important transmembrane adaptor protein in TCR-mediated signaling. Upon TCR engagement, LAT associates with multiple proteins which allows for the activation of downstream signaling pathways. The interaction between LAT with phospholipase C (PLC-gamma1) is especially critical for T cell receptor (TCR)-mediated Ca2+ signaling and MAPK activation. Knock-in mice harboring a mutation at the PLC-gamma1 binding site (Y136) of LAT develop a severe lymphoproliferative syndrome. These mice have defective thymic development and selection and lack natural regulatory T cells, implicating a breakdown of both central and peripheral tolerance. The phenotype observed in LAT-/- mice is even more severe.T cells are absent in the periphery of these mice due to a complete block in thymocyte development at the DN3 stage thereby making it difficult to study the physiological role of LAT in the activation and function of mature T cells. In order to bypass the developmental defects exhibited by LAT-/- and LATY136F mice, we developed conditional knock-in lines in which only a nonfunctional (ERCreLATf/-) or a LATY136F-mutated allele (ERCreLATf/m) of LAT is expressed in mature T cells after deletion of the wildtype LAT allele.
Analysis of ERCreLATf/m T cells after LAT deletion indicated that the interaction between LAT and PLC-gamma1 plays an important role in TCR-mediated signaling, proliferation, and IL-2 production. Furthermore, the deletion of LAT induced the development of the LATY136F lymphoproliferative syndrome in these mice. Although Foxp3+ natural Treg cells were present in these mice after deletion, they were unable to suppress the proliferation of conventional T cells. Our data indicated that the binding of LAT to PLC-gamma1 is essential for the suppressive function of CD4+CD25+ regulatory T cells.
We have also performed studies using ERCreLATf/- T cells to demonstrate that total LAT deficiency reduced the expression of Foxp3, CTLA4, and CD25 in peripheral Treg cells. Interestingly, mice with LAT deleted in peripheral T cells developed a lymphoproliferative syndrome similar to that observed in LATY136F mice although the disease caused by the LATY136F mutation was more severe. These data implicate LAT in both the positive and the negative regulation of mature T cells. Moreover, our findings indicate that LAT is essential in the maintenance of the regulatory T cell profile in the periphery, thereby aiding in the prevention of lymphoproliferative autoimmune disease.
Item Open Access The Gatekeeper of TCR Signaling: LAT in T cell Homeostasis and Autoimmunity(2015) O'Brien, Sarah ALinker for Activation of T cells, LAT, is a transmembrane adaptor protein that is vital for integrating TCR-mediated signals that modulate T cell development, activation, and proliferation. Upon engagement of the T cell receptor, LAT is phosphorylated and associates with Grb2, Gads, and PLCγ1 through its four distal tyrosine residues. Mutation of tyrosine 136 abolishes LAT binding to PLCγ1. This results in impaired TCR-mediated calcium mobilization and Erk activation. LATY136F knock-in mice have a severe but incomplete block in T cell development. Yet, CD4+ αβ T cells undergo uncontrolled expansion in the periphery, resulting in a severe autoimmune syndrome characterized by Th2 skewing and resultant B cell autoreactivity. Here, we further studied the role of LAT-PLCγ1 signaling in T cell lineage commitment, cytokine production, and autoimmunity.
First, we investigated the importance of the LAT-PLCγ1 interaction in γδ T cells by crossing LATY136F mice with TCRβ-deficient mice. Our data showed that the LATY136F mutation had no major effect on the homeostasis of epithelial γδ T cells, which could be found in the skin and small intestine. Interestingly, a population of CD4+ γδ T cells in the spleen and lymph nodes underwent continuous expansion and produced elevated amounts of IL4, resulting in an autoimmune syndrome similar to that caused by αβ T cells in LATY136F mice. Development of these hyperproliferative γδ T cells was not dependent on expression of MHC class II or CD4, and their proliferation could be partially suppressed by regulatory T cells. Our data indicated that a unique subset of CD4+ γδ T cells could hyperproliferate in LATY136F mice and suggested that LAT-PLCγ1 signaling may function differently in various subsets of γδ T cells.
In addition to examining γδ and αβ T cell development, we also were interested in further exploring the role of LAT in cytokine production. While our previous data have demonstrated that T cells in LATY136F mice are Th2 skewed, producing large amounts of IL4, we investigated other cytokines that may be important for autoimmunity and found that these CD4+ αβ T cells could also produce the proinflammatory cytokine IL6. Analysis of whole cell lysates from CD4+ αβ LATY136F T cells demonstrated that NFκB, AKT, and p38 were constitutively phosphorylated, and inhibition of these pathways resulted in reduced IL6 production. By crossing LATY136F mice with IL6 deficient mice, we demonstrated that early T cell survival was diminished in the absence of IL6. We further showed that this reduced CD4+ T cell pool was not due to further blocks in development, or an increase in FoxP3+ regulatory T cells. Finally, we demonstrated that over time, CD4+ T cells do hyperproliferate, yet B cell class switching and autoreactivity remains low. Our data uncovered a novel role for LAT-PLCγ1 signaling in regulating IL6 production by T cells during autoimmunity.
Finally, we wanted to further examine IL4 production and T helper cell differentiation in LATY136F mice. We examined IL4 production using KN2 reporter mice, where huCD2 marks T cells that have recently produced IL4 protein. We demonstrated that only a small proportion of the LATY136F T cells were actively secreting IL4. This subset of T cells were Tfh cells that expressed BCL6 and localized to B cell-rich germinal centers within the spleen. Most studies to date have examined Tfh cells in infection models, and have demonstrated that Tfh cells have very low expression of GATA3. Our results revealed in a spontaneous T cell-mediated autoimmune model system, that Tfh cells express both high levels of BCL6 and GATA3. Additionally, using an inducible deletion system, where normal development occurs, we showed that Tfh cells differentiation is the result of aberrant LAT signaling, rather than autoreactive TCRs with high affinity for self-peptide-MHC. LATY136F Tfh cells did require B cells for their development. Together, these results displayed a novel role for tonic LAT-PLCγ1 signaling in modulating Tfh cell differentiation and BCL6 expression.