(from abstract). The eye contains immune privileged tissues. Immune privilege refers to the attenuated nature of immune responses fund in certain tissues, such as the eye. Immune privilege is thought to enable the eye to respond to antigenic challenges in ways that preserve delicate structures upon which vision depends. Immune privilege of the eye was observed long ago, but is not yet understood. A long standing question concerning mechanisms of ocular immune privilege is the role of sequestration, the passive immune tolerance attributed to localization of antigens behind anatomic barriers. In the eye, these barriers include the retinal vascular endothelium and retinal pigment epithelium, which comprise the """"""""blood/retinal barrier."""""""" Sequestration was postulated to reduce lymphatic perusal of retina and minimize leakage of antigens from this tissue. Absence of interaction between the immune system and antigens can lead to ignorance of those antigens. Most current studies of ocular immune privilege concentrate on elucidating active mechanisms of tolerance, termed immune deviation, calling the significance of sequestration into question. Assessment of the contribution of sequestration to retinal immune privilege in normal animals has been difficult because adequate negative controls were not available, analysis requires comparison of immune responses of animals that express an antigen in sequestered versus non-sequestered sites, especially in the absence of mechanical compromises to the blood-retinal barrier. Using genetic approaches, our two experimental strategies for achieving these conditions have been fruitful. The PI reported that transgenic (Tg) expression of beta-galactosidase (b-gal) in mouse retina created a target for b-gal-mediated EAU by C04 T cells, but the mice were not tolerant to b-gal, appealing ignorant of it unless antigen-specific, activated C04 T cells were raised. His other approach showed UM retroviral transduction of the rat retinal S-Ag (A/K/A arrestin) gene into rat bone marrow-derived cells led to loss of susceptibility to EAU induction by rat S-Ag peptides. The straight-forward conclusion is that sequestration inhibits induction of active tolerance by retinal antigens, and contributes substantially to retinal immune privilege in normal eyes. Important questions remain, and he proposes to continue using the Tg mice. First, our observation of a lack of tolerance could be explained by proposing that adjuvant-driven immunization, or adoptive transfer of activated CD4 T cells, overwhelmed existing, active mechanisms of tolerance. Using T cell receptor Tg mice, we will ask if naive CD4 T cells specific for b-gal become exposed to retinal b-gal in normal or damaged, or inflamed eyes. If so, what is the outcome? The PI will extend these questions to CD8 T cells. Second, since potent active ocular immune deviation mechanisms have been experimentally induced, do they apply to normal eyes? Third since our studies of sequestration to date show it to be important, do active mechanisms provide """"""""back-up' for sequestration in damaged or inflamed eyes?
| Schuld, Nathan J; Hussong, Stacy A; Kapphahn, Rebecca J et al. (2015) Immunoproteasome deficiency protects in the retina after optic nerve crush. PLoS One 10:e0126768 |
| McPherson, Scott W; Heuss, Neal D; Gregerson, Dale S (2012) Regulation of CD8(+) T Cell Responses to Retinal Antigen by Local FoxP3(+) Regulatory T Cells. Front Immunol 3:166 |
| Ferrington, Deborah A; Gregerson, Dale S (2012) Immunoproteasomes: structure, function, and antigen presentation. Prog Mol Biol Transl Sci 109:75-112 |
| Heuss, Neal D; Lehmann, Ute; Norbury, Christopher C et al. (2012) Local activation of dendritic cells alters the pathogenesis of autoimmune disease in the retina. J Immunol 188:1191-200 |
| McPherson, Scott W; Heuss, Neal D; Lehman, Ute et al. (2011) Generation of Regulatory T Cells to Antigen Expressed in the Retina. Curr Immunol Rev 7:344-349 |
| Lehmann, Ute; Heuss, Neal D; McPherson, Scott W et al. (2010) Dendritic cells are early responders to retinal injury. Neurobiol Dis 40:177-84 |
| McPherson, Scott W; Heuss, Neal D; Gregerson, Dale S (2009) Lymphopenia-induced proliferation is a potent activator for CD4+ T cell-mediated autoimmune disease in the retina. J Immunol 182:969-79 |
| Gregerson, Dale S; Heuss, Neal D; Lehmann, Ute et al. (2009) Peripheral induction of tolerance by retinal antigen expression. J Immunol 183:814-22 |
| Gregerson, Dale S; Heuss, Neal D; Lehmann, Ute et al. (2008) Evidence for extrathymic generation of regulatory T cells specific for a retinal antigen. Ophthalmic Res 40:154-9 |
| Ferrington, Deborah A; Hussong, Stacy A; Roehrich, Heidi et al. (2008) Immunoproteasome responds to injury in the retina and brain. J Neurochem 106:158-69 |
Showing the most recent 10 out of 24 publications
