Failure of memory (CD44 high) CD4 T cells to recognize their target antigen in retina

Engrafted Neural Progenitor Cells Express a Tissue-Restricted Reporter Gene Associated with Differentiated Retinal Photoreceptor Cells

Neural progenitor cells (NPCs) have shown ability to repair injured CNS, and might provide precursors to retinal neurons. NPCs were isolated from the brains of 14 day murine embryos of transgenic mice that express β-galactosidase (β-gal) on the arrestin promoter, which specifically directs expression to retinal photoreceptor cells. NPCs were transferred to adult, syngeneic mice via inoculation into the anterior chamber of the eye, the peritoneal cavity, or the brain. At 14 weeks postgrafting, tissues were collected and examined to determine if differentiated NPC progeny were present in retina based on histochemical detection of β-gal. Four of six anterior chamber-inoculated recipients showed Bluo-gal-stained cells in retina, indicating the presence of transferred NPCs or their progeny. Because the progenitor cells do not express β-gal, positive staining indicates differentiation leading to activation of the arrestin promoter. Two recipients inoculated by the intraperitoneal route also exhibited Bluo-gal staining in retina. The NPCs did not express β-gal if inoculated into brain, but survived and dispersed. Most recipients, regardless of inoculation route, were PCR positive for β-gal DNA in extraocular tissues, but no Bluo-gal staining was found outside of the retina. Injury to the retina promoted, but was not required, for progenitor cell engraftment. β-Gal-positive cells were concentrated in the outer layers of the retina. In summary, a reporter gene specifically expressed in differentiated retinal photoreceptor cells due to the activity of the arrestin promoter was expressed in recipient mouse retina following transfer of NPCs prepared from the β-gal transgenic mice. The presence of β-gal DNA, but not Bluo-gal staining, in spleen and other tissues revealed that the cells also migrated elsewhere and took up residence in other organs, but did not undergo differentiation that led to β-gal expression.

Lymphopenia-induced proliferation is a potent activator for CD4+ T cell-mediated autoimmune disease in the retina

To study retinal immunity in a defined system, a CD4+ TCR transgenic mouse line (betagalTCR) specific for beta-galactosidase (betagal) was created and used with transgenic mice that expressed betagal in retinal photoreceptor cells (arrbetagal mice). Adoptive transfer of resting betagalTCR T cells, whether naive or Ag-experienced, into arrbetagal mice did not induce retinal autoimmune disease (experimental autoimmune uveoretinitis, EAU) and gave no evidence of Ag recognition. Generation of betagalTCR T cells in arrbetagal mice by use of bone marrow grafts, or double-transgenic mice, also gave no retinal disease or signs of Ag recognition. Arrbetagal mice were also resistant to EAU induction by adoptive transfer of in vitro-activated betagalTCR T cells, even though the T cells were pathogenic if the betagal was expressed elsewhere. In vitro manipulations to increase T cell pathogenicity before transfer did not result in EAU. The only strategy that induced a high frequency of severe EAU was transfer of naive, CD25-depleted, betagalTCR T cells into lymphopenic arrbetagal recipients, implicating regulatory T cells in the T cell inoculum, as well as in the recipients, in the resistance to EAU. Surprisingly, activation of the CD25-depleted betagalTCR T cells before transfer into the lymphopenic recipients reduced EAU. Taken together, the results suggest that endogenous regulatory mechanisms, as well as peripheral induction of regulatory T cells, play a role in the protection from EAU.

Immunoproteasome responds to injury in the retina and brain

It is well known that immunoproteasome generates peptides for MHC Class I occupancy and recognition by cytotoxic T lymphocytes (CTL). The present study focused on evidence for alternative roles for immunoproteasome. Retina and brain were analyzed for expression of immunoproteasome subunits using immunohistochemistry and western blotting under normal conditions and after injury/stress induced by CTL attack on glia (brain) or neurons (retina). Normal retina expressed substantial levels of immunoproteasome in glia, neurons, and retinal pigment epithelium. The basal level of immunoproteasome in retina was two-fold higher than in brain; CTL-induced retinal injury further up-regulated immunoproteasome expression. Immunoproteasome up-regulation was also observed in injured brain and corresponded with expression in Purkinje cells, microglia, astrocytes, and oligodendrocytes. These results suggest that the normal environment of the retina is sufficiently challenging to require on-going expression of immunoproteasome. Further, immunoproteasome up-regulation with retinal and brain injury implies a role in neuronal protection and/or repair of damage.

Limited peripheral T cell anergy predisposes to retinal autoimmunity

Autoimmune uveoretinitis accounts for at least 10% of worldwide blindness, yet it is unclear why tolerance to retinal Ags is so fragile and, particularly, to what extent this might be due to defects in peripheral tolerance. To address this issue, we generated double-transgenic mice expressing hen egg lysozyme, under the retinal interphotoreceptor retinoid-binding promoter, and a hen egg lysozyme-specific CD4(+) TCR transgene. In this manner, we have tracked autoreactive CD4(+) T cells from their development in the thymus to their involvement in uveoretinitis and compared tolerogenic mechanisms induced in a variety of organs to the same self-Ag. Our findings show that central tolerance to retinal and pancreatic Ags is qualitatively similar and equally dependent on the transcriptional regulator protein AIRE. However, the lack of Ag presentation in the eye-draining lymph nodes results in a failure to induce high levels of T cell anergy. Under these circumstances, despite considerable central deletion, low levels of retinal-specific autoreactive CD4(+) T cells can induce severe autoimmune disease. The relative lack of anergy induction by retinal Ags, in contrast to the same Ag in other organs, helps to explain the unique susceptibility of the eye to spontaneous and experimentally induced autoimmune disease.

Bystander killing of neurons by cytotoxic T cells specific for a glial antigen

To explore pathways to neuron loss in inflammatory diseases, transgenic mice expressing beta-galactosidase (beta-gal) in either astrocytes or photoreceptor cells, or both, were inoculated with activated, beta-gal-specific cytotoxic CD8 T lymphocytes (CTLs). beta-gal-positive astrocytes in brain were rapidly attacked, with particular damage in cerebellum. Substantial loss of cerebellar granule cells was found, even though these neurons did not express beta-gal. The small number of beta-gal-positive retinal astrocytes present in these mice was also rapidly destroyed by transferred CTLs, but without detectable consequences for retinal neurons. However, in mice with photoreceptor cell-specific beta-gal expression, near-total destruction of photoreceptor cells was produced by CTL transfer. Attack on photoreceptor cells displayed minimal inflammation, and onset was a week later than onset of astrocyte-directed disease. CTL transfer into F1 mice expressing beta-gal in both astrocytes and photoreceptor cells confirmed that pathogenesis directed against antigen expressed in glia versus neurons proceeded in two distinct, independent phases. beta-gal-positive retinal astrocytes were severely affected by 5 days post-transfer, followed by rapid resolution. Photoreceptor cells in the same retina were unaffected until 12 days post-transfer. The susceptibility of photoreceptor cells was not enhanced by the prior CTL attack on beta-gal-expressing retinal astrocytes. The results demonstrate that extensive bystander killing of neurons can occur in vivo as a result of direct CTL attack on surrounding astrocytes. Antigen-expressing retinal neurons were also efficiently killed by CTLs, but by a mechanism that was substantially delayed and dissociated from the killing of retinal astrocytes.

Resting CD8 T cells recognize beta-galactosidase expressed in the immune-privileged retina and mediate autoimmune disease when activated

Although the expression of class II major histocompatibility complex (MHC) in retina is extremely low, it is an established fact that activated CD4 T cells, specific for retinal antigens (Ags), mediate experimental autoimmune uveoretinitis (EAU). Conversely, CD8 T cells have not been shown to recognize Ag in the retina. This study investigated whether retinal-specific Ags are detected by class I MHC-restricted CD8 T cells. Using a CD8 T-cell clone (beta3) specific for an immunodominant epitope of beta-galactosidase (beta-gal), local Ag recognition was shown by transfer of activated beta3 cells into beta-gal transgenic (Tg) mice expressing beta-gal in the retina (hi-arr-beta-gal mice), or in the brain and eye (GFAP-beta-gal mice). Beta-gal-positive photoreceptor cells were damaged in the retina of hi-arr-beta-gal mice, and anterior segment disease was found in the eyes of GFAP-beta-gal mice. Ag recognition by resting CD8 T cells was also evaluated. Recovery of 5(6)-carboxyfluorescein diacetate N-succinimidyl ester (CFSE)-labelled beta3 cells from hi-arr-beta-gal mice was slightly decreased compared to recovery from B10.A mice, while recovery from GFAP-beta-gal mice was transiently increased. Conversely, recovery of CFSE- cells increased in hi-arr-beta-gal mice, consistent with an Ag-dependent response. The CFSE content of the CFSE+ population was unchanged relative to beta3 cells recovered from controls. Intracellular cytokine responses of beta3 cells recovered from hi-arr-beta-gal and GFAP-beta-gal mice correlated with the number of cells recovered, regardless of CFSE content. Even though their production of interferon-gamma and tumour necrosis factor-alpha was affected little by transfer into hi-arr-beta-gal recipients, the ability of beta3 cells to mediate delayed-type hypersensitivity was inhibited in hi-arr-beta-gal mice. These results show that resting CD8 T cells are affected by the presence of Ag that originates in retina and, when activated prior to transfer, mediate pathogenic autoimmunity against retinal and other ocular targets.