Biallelic mutations in the ferredoxin reductase gene cause novel mitochondriopathy with optic atrophy.

Iron-sulfur (Fe-S) clusters are ubiquitous cofactors essential to various cellular processes, including mitochondrial respiration, DNA repair, and iron homeostasis. A steadily increasing number of disorders are being associated with disrupted biogenesis of Fe-S clusters. Here, we conducted whole-exome sequencing of patients with optic atrophy and other neurological signs of mitochondriopathy and identified 17 individuals from 13 unrelated families with recessive mutations in FDXR, encoding the mitochondrial membrane-associated flavoprotein ferrodoxin reductase required for electron transport from NADPH to cytochrome P450. In vitro enzymatic assays in patient fibroblast cells showed deficient ferredoxin NADP reductase activity and mitochondrial dysfunction evidenced by low oxygen consumption rates (OCRs), complex activities, ATP production and increased reactive oxygen species (ROS). Such defects were rescued by overexpression of wild-type FDXR. Moreover, we found that mice carrying a spontaneous mutation allelic to the most common mutation found in patients displayed progressive gait abnormalities and vision loss, in addition to biochemical defects consistent with the major clinical features of the disease. Taken together, these data provide the first demonstration that germline, hypomorphic mutations in FDXR cause a novel mitochondriopathy and optic atrophy in humans.

Impact of inflammation on ocular immune privilege.

The immune-privileged status of the anterior chamber of the eye is altered in experimentally induced intraocular inflammation and in the pigment dispersion syndrome of DBA/2J mice. However, the eye has developed multiple mechanisms to maintain ocular immune privilege even in the presence of intraocular inflammation.

Analysis of immune privilege in eyes with Mycobacteria tuberculosa adjuvant-induced uveitis.

PURPOSE: To examine the effects of intravitreal Mycobacteria tuberculosa adjuvant (MTA) on ocular immune privilege. METHODS: MTA was injected into the vitreous cavity of BALB/c mouse eyes to induce anterior uveitis. The inflamed eyes were then examined for their capacity to afford immune privilege to injected allogeneic tumor cells and to promote anterior chamber-associated immune deviation (ACAID). Aqueous humor (AqH) was tested for IL-12 content and for its ability to inhibit T-cell activation. RESULTS: AqH removed from MTA-inflamed eyes at 6 and 12 h contained high levels of IL-12, which then fell almost to baseline at 24 h. This is relevant to the finding that the inflamed eye failed to support ACAID induction at an early time period and then regained the ACAID-induction capability at a later time. Nonetheless, AqH removed from MTA-inflamed eyes retained its capacity to suppress T-cell activation, and MTA-inflamed eyes afforded extended survival to alloantigenic tumor cells implanted into the anterior chamber. CONCLUSION: Intraocular inflammation evoked by MTA causes the local accumulation of IL-12 and simultaneously robs the eye of its capacity to promote systemic immune tolerance to eye-derived antigens. However, MTA-inflamed eyes retain immune privilege, as indicated by their support of the progressive growth of allogeneic tumor cells.

Spontaneous corneal hem- and lymphangiogenesis in mice with destrin-mutation depend on VEGFR3 signaling.

Lymphangiogenesis, the formation of new lymphatic vessels, is important for tumor metastasis and induction of immunity to peripheral antigens including organ transplants. We herein describe a novel mouse model of spontaneous, secondary lymphangiogenesis in the normally avascular cornea. corn1 mice, which suffer from a deletion in the gene encoding the cytoskeletal protein destrin, develop hemangiogenesis as well as spontaneous outgrowth of LYVE-1+++/CD31+ lymphatic vessels into the cornea starting at age 4 weeks. Corneal lymphangiogenesis is delayed in onset, is less intense, and regresses earlier compared with hemangiogenesis. Moreover, the lymphangiogenesis is preceded only by a mild recruitment of CD45+ inflammatory cells into the cornea. In contrast to mice with inflammation-induced hem- and lymphangiogenesis, corn1 mice do not develop breakdown of the blood-aqueous barrier. Finally, in this novel mouse model, a blocking anti-VEGFR3 antibody significantly inhibited not only lymph- but also hemangiogenesis. In summary, destrin deletion has differential effects on spontaneous hem- and lymphangiogenesis in the normally avascular cornea and represents a novel mouse model to study the mechanisms of lymphangiogenesis and to test the antihem- and antilymphangiogenic properties of known or new antiangiogenic agents.

By altering ocular immune privilege, bone marrow-derived cells pathogenically contribute to DBA/2J pigmentary glaucoma.

Pigment dispersion syndrome causes iris pigment release and often progresses to elevated intraocular pressure and pigmentary glaucoma (PG). Because melanin pigment can have adjuvant like properties and because the Gpnmb gene, which contributes to pigment dispersion in DBA/2J (D2) mice, is expressed in dendritic cells, we tested the hypothesis that ocular immune abnormalities participate in PG phenotypes. Strikingly, we show that D2 eyes exhibit defects of the normally immunosuppressive ocular microenvironment including inability of aqueous humor to inhibit T cell activation, failure to support anterior chamber (AC)-associated immune deviation, and loss of ocular immune privilege. Histologic analysis demonstrates infiltration of inflammatory leukocytes into the AC and their accumulation within the iris, whereas clinical indications of inflammation are typically very mild to undetectable. Importantly, some of these abnormalities precede clinical indications of pigment dispersal, suggesting an early role in disease etiology. Using bone marrow chimeras, we show that lymphohematopoietic cell lineages largely dictate the progression of pigment dispersion, the ability of the eye to support induction of AC-associated immune deviation, and the integrity of the blood/ocular barrier. These results suggest previously unsuspected roles for bone marrow-derived cells and ocular immune privilege in the pathogenesis of PG.

Ocular immune privilege and the impact of intraocular inflammation.

Immune privilege, a characteristic of the internal compartments of the eye, is a physiologic mechanism that is designed to provide the eye with protection against pathogens while protecting the delicate visual axis from the sight-destroying potential of immunogenic inflammation. It is assumed that the presence of intraocular inflammation is incompatible with the existence of immune privilege. The validity of this assumption has been tested in four animal models of intraocular inflammation-systemic and local endotoxin-induced uveitis (EIU), mycobacterial adjuvant-induced uveitis (MAIU), and experimental autoimmune uveitis (EAU). Immune privilege was assessed in inflamed eyes by growth of intracamerally injected allogeneic tumor cells, by the capacity to support immune deviation following intracameral injection of antigen (ovalbumin, OVA), by assaying protein, leukocyte, and selected cytokine content of aqueous humor (AqH), and by capacity of inflamed AqH to suppress T cell activation in vitro. The results indicate that, irrespective of the type of inflammation, tumor cells formed progressively growing tumors in inflamed eyes. Moreover, OVA injected into the anterior chamber of eyes inflamed by MAIU and EAU failed to induce immune deviation. AqH from inflamed eyes reflected breakdown of the blood:ocular barrier as well as transient loss of its immunosuppressive properties. Immunosuppressive microenvironments routinely reemerged in inflamed eyes, and the immunosuppressive agent present under these circumstances in AqH was active TGF beta2. It is concluded that immune privilege is surprisingly resistant to abolition by intraocular inflammation, and that maintenance of immune privilege in the face of ongoing inflammation depends upon the emergence of progressive and partially different immunosuppressive mechanisms.

Using tolerance induced via the anterior chamber of the eye to inhibit Th2-dependent pulmonary pathology.

Anterior chamber-associated immune deviation (ACAID), a manifestation of ocular immune privilege, prevents Th1-dependent delayed hypersensitivity from developing in response to eye-derived Ags, thereby preserving vision. Since Th2-type cells have recently been shown to mediate destructive inflammation of the cornea, we wondered whether pre-emptive induction of ACAID could inhibit Th2 responses. Using a murine model of OVA -specific, Th2-dependent pulmonary inflammation, we pretreated susceptible mice by injecting OVA alone into the anterior chamber, or by injecting OVA-pulsed, TGF-beta2-treated peritoneal exudate cells i.v. These mice were then immunized with OVA plus alum strategy that generates Th2-mediated OVA-specific pulmonary pathology. When pretreated mice were challenged intratracheally with OVA, their bronchoalveolar lavage fluids contained far fewer eosinophils and significantly less IL-4, IL-5, and IL-13 compared with that of positive, nonpretreated controls. Similarly, lung-draining lymph node cells of pretreated mice secreted significantly less IL-4, IL-5, and IL-13 when challenged in vitro with OVA. Moreover, sera from pretreated mice contained much lower titers of OVA-specific IgE Abs. We conclude that Ags injected into the anterior chamber of the eye impair both Th1 and Th2 responses. These results reduce the likelihood that ACAID regulates Th1 responses via a Th2-like mechanism. Thus, immune privilege of the eye regulates inflammation secondary to both Th1- and Th2-type immune responses.