Synthetic iE-DAP and iE-Lys (an inactive derivative of iE-DAP) were purchased from Invivogen (San Diego, CA); MDP was purchased from Bachem (Torrance, CA). Peptides were dissolved in sterile saline for injections. All three reagents tested below the lower limit of detection of endotoxin activity by limulus amebocyte lysate assay. Mice were given intravitreal injections (2 μL volume) via a Hamilton syringe with a 30-gauge, half-inch needle. 

Age-matched (8- to 10-week-old) female BALB/c mice or mice deficient in caspase-1 or IL-1R1 and their appropriate strain controls (nonobese diabetic [NOD] and C57BL/6, respectively) were obtained from Jackson Laboratories (Bar Harbor, ME). Mice were housed in a facility approved by the Association of Assessment and Accreditation of Laboratory Animal Care International. Procedures were carried out in accordance with National Institutes of Health and ARVO guidelines and Oregon Health and Science University Institutional Animal Care and Use policies. 

Leukocyte responses within the vasculature and the extravascular tissue of the iris were assessed by intravital microscopy according to a previously established method. ¹⁶ Briefly, at the time of imaging, animals were injected intraperitoneally with 35 mg/kg rhodamine 6G (Sigma, St. Louis, MO) and were anesthetized with 1.7% isoflurane. Digital images of the iris vasculature were captured with a black-and-white video camera (Kappa Scientific, Gleichen, Germany) on an epifluorescence intravital microscope (modified Orthoplan; Leica, Wetzlar, Germany) in three independent regions. Diameter and length of each vessel segment or iris tissue and leukocyte phenotype (rolling, adhering, infiltrating) were quantified off-line with Image J analysis software (developed by Wayne Rasband, National Institutes of Health, Bethesda, MD; available at http://rsb.info.nih.gov/ij/index.html.), as previously described. ¹⁶  

Mouse eyes were prepared for histologic assessment as previously described. ¹⁶ Briefly, whole eyes were dissected, fixed, and embedded in paraffin for sectioning. Seven-micrometer tissue sections were stained with hematoxylin and eosin. An observer masked to treatment groups quantified the number of leukocytes within the anterior chamber of seven sections for each eye (approximately every tenth slide of a whole eye sectioned completely). The mean number of leukocytes per section was then calculated for each mouse eye. For immunohistochemistry, tissue sections were deparaffinized, as discussed, incubated with 2% goat serum in PBS for 1 hour at room temperature, and incubated with 2.5 μg/mL rat anti–mouse Ly6G/GR1 antibody (R&D Systems, Minneapolis, MN) in a humidified atmosphere overnight at 4°C. Sections were washed and incubated in 1:500 dilution of goat anti–rat IgG antibody (eBioscience, San Diego, CA) overnight at 4°C, followed by extensive washing in PBS. Antibody-antigen complexes were visualized with the substrate diaminobenzidine (DAB) according to the manufacturer’s instructions (Invitrogen, Carlsbad, CA) and were counterstained with methyl green (Sigma). Slides were photographed at 400× with a microscope (DM500B; Leica, Wetzlar, Germany) and a digital camera (DC500; Leica). 

Protein was extracted from whole eye tissue in the presence of protease inhibitors, as previously described. ³¹ Protein concentrations were determined using a kit (BCA; Pierce-Endogen, Rockford, IL), and equal amounts of protein for each sample were measured for IL-1β by ELISA (R&D Systems). Expression of NOD1 was assessed by immunoblotting according to a modified protocol ³⁴ with the use of an anti–mouse/human NOD1 goat antibody (Santa Cruz Biotechnology, Santa Cruz, CA), which was detected with near infrared-fluorescence-labeled secondary antibody (IRDye-698; Licor-Odyssey, Lincoln, NE). Images were captured using commercially available software (Licor- Odyssey), and the fluorescence intensity of the bands was measured. Data were analyzed as a ratio of NOD1 expression to β-actin and expressed relative to saline controls. 

Data are represented as mean ± SEM. Mean differences between treatment and genotype were analyzed using two-way and one-way analyses of variance with Bonferroni test or t-test post hoc analyses. Differences were considered statistically significant when P < 0.05. 

NOD1 has been considered primarily expressed within immune cells and lymphoid tissues. Although its mRNA expression has been documented in murine eye tissue, ⁵ its protein expression in mouse eye tissues has yet to be determined. As shown in Figure 1 , NOD1 is constitutively expressed within murine eye tissue. We did not observe any change in protein levels in response to local treatment with the NOD1-specific agonist iE-DAP at a dose and time that induced inflammation. 

Our finding that NOD1 is present in eye tissue prompted us to further hypothesize that it could contribute to uveitis. To explore the functional significance of NOD1, we used chemically synthesized dipeptide, ie-DAP, which is devoid of contamination of other bacterial products. ie-DAP is considered the minimal motif of PGN responsible for the activation of NOD1. ¹⁸ We examined the effects of increasing doses of locally administered ie-DAP on the ocular inflammatory response within the microvasculature of iris tissue by intravital microscopy (Fig. 2) . We observed a dose-dependent effect of iE-DAP treatment with maximal inflammation achieved at a dose of 100 μg. Treatment with iE-Lys, which is an inactive derivative of iE-DAP that does not activate NOD1, did not cause any inflammation, indicating the specificity of iE-DAP. We were unable to test greater doses of iE-DAP because of limitations of the solubility of iE-DAP and the volume we could inject intravitreally in mice. Notably, we did not observe any influence of strain on the ocular inflammatory response to 100 μg iE-DAP when comparing BALB/c and C57BL/6^tyr−/− mice, which lack pigment as a consequence of tyrosinase mutation (data not shown). The albino C57BL/6 mice were used in these studies because pigment interfered with detection of fluorescence by intravital microscopy. 

To determine the duration of the inflammatory response induced by iE-DAP, mice were treated with intravitreal injections of 100 μg iE-DAP or saline, and ocular inflammation was assessed by intravital microscopy as a function of time (Fig. 3) . Inflammation was detectable as early as 5 hours after treatment and was still present at 24 hours, as indicated by the significant increase in the number of rolling, adhering, and infiltrating leukocytes. Interestingly, the inflammation induced by iE-DAP was more sustained than what we have reported for MDP-induced uveitis, wherein the ocular inflammatory response was completely resolved by 24 hours. ¹⁶ We also observed a significant increase in leukocyte presence within the aqueous of the anterior chamber in mice treated with iE-DAP and increased fibrin deposition (Fig. 4B) . At 24 hours after treatment, iE-DAP resulted in a significant increase in the number of leukocytes/tissue section (45 ± 2.9) within the aqueous of the anterior chamber of the eye compared with 3.5 ± 1.2 for saline (P < 0.05). Based on their characteristic nuclear morphology, most leukocytes appeared to be neutrophils. Indeed, immunohistochemistry confirmed the presence of neutrophils in the aqueous (Figs. 4C 4D) . We also observed a minor neutrophil infiltrate within the nerve fiber layer of the retina (Figs. 4E 4F)and to some extent within the choroid (data not shown). We observed limited inflammation within the vitreous humor. Control sections stained with an isotype control antibody showed no positive staining (data not shown). These new data support the role for neutrophils in iE-DAP–induced uveitis, which would be consistent with our previous report of MDP induced uveitis ¹⁶ and endotoxin-induced uveitis. ³⁵  

NOD1 and NOD2 share common structural domains and functions in that they both activate downstream signaling pathways by way of their interactions with RIP2 and their CARD domains. Therefore, we hypothesized that NOD1 and NOD2 might use similar mediators to trigger ocular inflammation. To test this hypothesis, we chose to focus on the roles of IL-1β and caspase-1, which we have defined in NOD2-driven ocular inflammation. ³¹ We demonstrated that NOD2 activation induces IL-1β expression in the eye and that caspase-1 plays an essential role in MDP-induced IL-1β production. ³¹ As such, we tested whether iE-DAP induced IL-1β production in the eye and whether its proteolytic processing was dependent on caspase-1. As shown in Figure 5A , we found that protein levels of IL-1β within iE-DAP–injected eyes were significantly increased at 5 hours after treatment. Moreover, mice deficient in caspase-1 showed a significant reduction in IL-1β production (Fig. 5B) . These data indicate that NOD1 activation results in increased IL-1β and that IL-1β production depends on caspase-1. This finding is consistent with what we have shown for the effect of NOD2 on IL-1β production in the eye. 

We then assessed the functional role of IL-1 processing and signaling events in the ocular inflammatory response elicited by iE-DAP (Fig. 6) . Caspase-1 KO mice and their congenic controls were treated with iE-DAP, and the peak ocular inflammatory response was assessed by intravital microscopy at 5 hours (Figs. 6A 6B 6C) . Caspase-1 deficiency significantly diminished the development of ocular inflammation in response to iE-DAP. The number of rolling leukocytes tended to be decreased, and the numbers of adhering and infiltrating leukocytes were significantly reduced compared with congenic controls. We did not observe any significant difference between genotypes at the 24-hour time period (data not shown). Because caspase-1 is responsible for the proteolytic cleavage of pro–IL-1β to its mature form, in addition to other cytokines such as IL-18, we used IL-1R1 KO mice to assess the specific contribution of IL-1β signaling events. The IL-1R1 KO mice are on a C57BL/6 background with iris pigmentation, which obscures the detection of fluorescent leukocytes through intravital microscopy. Thus, we assessed the number of leukocytes within the anterior chamber by histology (Fig. 6D) . Deficiency in IL-1R1 completely abolished the iE-DAP–induced leukocyte response within the anterior chamber, indicating an essential role for IL-1 in ocular inflammation downstream of NOD1. Surprisingly, this finding is in contrast to that of NOD2, wherein MDP-induced uveitis occurred independently of IL-1β. ³¹ Taken together, these findings indicate that IL-1β signaling events are crucial in NOD1-driven ocular inflammation, thereby distinguishing mechanisms of NOD1 from NOD2-uveitis. 

Elucidation of the role of different pattern recognition receptors in the eye could lead to new perspectives on the ocular inflammatory processes underlying uveitis. The connection between NLR family members, such as NOD2, and autoinflammatory diseases manifesting with uveitis undoubtedly warrants further investigation of NLR family members in ocular inflammatory responses. Here, we demonstrate that another NLR family member, NOD1, is present in murine eye tissue and is functionally active as local treatment with its agonist results in ocular inflammation in a dose- and time-dependent fashion. Like that of NOD2, NOD1 activation resulted in the production of IL-1β in the eye in a caspase-1–dependent mechanism. Yet, to our surprise, NOD1 and NOD2 differed with respect to the role of IL-1 signaling events in the development of ocular inflammation. 

Although NOD1 was originally considered to be expressed predominantly in lymphoid tissue, its expression has more recently been documented in nonlymphoid tissue. ^{36 37 38} We demonstrate here that NOD1 protein is expressed in eye tissue. Our finding is consistent with an earlier report of Nod1 mRNA expression in murine eye tissue ⁵ and in human corneal epithelial cells. ³⁹ Thus, it is plausible that NOD1 could trigger uveitis by acting locally within the eye, especially considering that local injection of its agonist results in ocular inflammation. It is also possible that leukocytes expressing NOD1 and recruited to the eye could contribute to the propagation of the inflammatory response in the setting of the appropriate ligand. Indeed, we found an increased presence of neutrophils, which are known to express NOD1, within the aqueous, vitreous, and the nerve fiber layer of the retina. The location of the ocular inflammation resulting from an intravitreal injection of iE-DAP may be indicative of the location of NOD1 within the eye. Our data suggest a role for NOD1 within the anterior and posterior segments of the eye. Future investigation of the specific cell types within the eye that express NOD1 and their responsiveness to iE-DAP should be informative. We did not observe any variation in NOD1 protein levels in response to stimulation with its ligand at the peak of inflammation (5 hours) or at 2 or 24 hours after treatment. This may indicate that its activity was determined by its homodimerization and interactions with RIP2 rather than by its regulation at the protein expression level. 

The mechanisms by which NOD1 could trigger ocular inflammation have not been explored until now. Our studies here identify IL-1β processing through caspase-1 and IL-1R1 signaling as contributing events. IL-1β mRNA expression is regulated by NF-κB, but its biological activity is further regulated by its proteolytic processing and secretion, which are mediated by caspase-1 in the inflammasome. Unlike TLRs, which activate only the NF-κB pathway and require a second signal for activation of the caspase-1 pathway, NLRs appear to have the capacity to directly regulate caspase-1 activity. ²⁸ Indeed, we have previously demonstrated that NOD2 activation results in IL-1β production in a caspase-1–dependent fashion in the eye. ³¹ We report here the novel finding that NOD1 has a similar capacity in vivo, which places importance on the previously underexplored caspase-1 or inflammasome pathway in ocular inflammatory responses. Although caspase-1 has been identified as a downstream mediator of NOD1 with respect to IL-1β production in vitro, ^{26 27} our findings here are the first demonstration of this capacity in vivo. Because of the described ability of NOD1 to activate NF-κB, we might also speculate that NOD1, like NOD2, is able to initiate signals to NF-κB and to caspase-1 pathways, thereby resulting in the production of IL-1β independently of other TLR signals. Increased NF-κB–regulated expression of cytokines and chemokines, which promote leukocyte-endothelium interactions and infiltration, may also influence the ocular inflammatory response downstream of NOD1. Our data suggest the involvement of IL-1 signaling events in leukocyte adherence and infiltration because these processes were affected the greatest in caspase-1 KO mice. Alternatively, IL-1 could be involved in crucial early events, such that in its absence the development of subsequent inflammatory events is impeded. The inflammatory effects of IL-1R1 activation—including the upregulation of numerous inflammatory mediators transcribed by NF-κB, such as cytokines and chemokines that could contribute to inflammation at later times—have been described. 

Interestingly, our finding that IL-1β processing and signaling events are essential in NOD1-mediated uveitis is in contrast to what we demonstrated for NOD2. In NOD2-mediated uveitis, IL-1β is produced within the eye in response to MDP in a caspase-1–dependent manner, similar to what we found after iE-DAP activation of NOD1. However, caspase-1 and IL-1β were not essential for ocular inflammation mediated by NOD2, though they were involved in systemic inflammatory responses triggered by MDP. ³¹ The difference between NOD1 and NOD2 mechanisms of uveitis was surprising given the homology in protein structure and downstream signaling events involving RIP2, NF-κB, and caspase-1. However, it has been suggested that distinct signaling mediators, such as TRAF6 in NOD2, could be involved rather than TRAF2 and TRAF5 in NOD1 signaling. ⁴⁰ Consistent with our findings, a recent report described differential functional roles for NOD1 and NOD2 in regulating acute joint inflammation in a mouse model of arthritis, ⁴¹ supporting the idea of distinct inflammatory events that distinguish NOD1 and NOD2 and warrant further investigation in other inflammatory diseases. 

Similar to MDP, iE-DAP in itself is not a highly potent inflammatory agent. ¹⁸ In models of inflammation in other organ systems, comparable doses of iE-DAP and MDP were used in vivo. ^{16 42 43 44} NLRs, which are located within the cytoplasm, may require greater doses of ligand for their activation than are needed for the activation of cell-surface receptors. However, the sensitivity of the receptor or the tissue type may also influence responses because comparable amounts of the TLR2 agonist PGN are used to induce local knee inflammation in mice. ⁴⁵ Exactly how the NODs are activated in response to their agonist is not understood, but several theories have been proposed. Active phagocytosis seems reasonable in bacterial infection or in response to PGN, which could subsequently be broken down to peptides activating NOD1 or NOD2 within the cytosol. In addition, direct bacterial infection could occur. The agonist of NOD2, MDP, is directly internalized in cells, ⁴⁶ and an active intracellular muropeptide transport system involving PepT1 has been described in epithelial cells. ⁴⁷ There is yet to be any evidence demonstrating a direct interaction between NOD1 and NOD2 and their agonists, suggesting that they might even require some additional factors in the cytosol or plasma membrane for recognition of their agonists. As such, it is possible that the NODs act as downstream signaling transducers. Nonetheless, we emphasize that despite the dose, iE-DAP did elicit a specific response because the same dose of the inactive form of the peptide did not cause ocular inflammation. 

Even though the inflammatory effects of NOD1 and NOD2 agonists are lower than those of TLR agonists, a synergistic effect between the two systems appears to occur, indicating an additional regulatory function of the NODs. Simultaneous stimulation of macrophages with iE-DAP and LPS results in the synergistic production of cytokines ^{18 48 49} indicating that NOD1 may serve to amplify TLR responsiveness. The synergistic effect of MDP and TLR agonists in vitro and in vivo has been more widely reported. ^{48 49 50 51 52} The cross-talk between the NLR and TLR systems has been proposed as an important regulatory function in immune homeostasis. This could make sense in situations in which TLR responsiveness might be compromised or suppressed, as in the intestine, where TLRs are thought to be tolerant or refractory to activation as a consequence of continual exposure to bacteria in the intestinal tract. Indeed, a recent report indicates that NOD1 and NOD2 are important components in LPS tolerance. ⁵³ The role for NOD1 and NOD2 in promoting inflammatory responses is contradictory to other findings of NOD2 in which NOD2 functions to negatively regulate TLR2-inflammatory responses. Mice deficient in NOD2 are more susceptible to intestinal inflammation ^{54 55} and produce greater amounts of IFN-γ and T-helper 1 T cells, which are considered part of the pathologic mechanisms of Crohn’s disease and colitis. This function may explain, in part, how NOD2 polymorphisms predispose to Crohn’s disease because the common polymorphism (Leu1007fsinsC) results in a truncated form of NOD2 that is unresponsive to MDP. ^{51 56} Such a loss of function may result in unregulated TLR2 responsiveness, thereby rendering the intestine prone to hyperinflammation in the face of continual bacterial exposure. Whether NOD1 performs similar regulatory functions within the intestine has not been explored to the same extent. Bouskra et al. ⁵⁷ published findings on the importance of NOD1 in regulating intestinal homeostasis through the maintenance of lymphoid follicles. Thus, although intracellular Gram-negative infections are relatively rare within the eye, NOD1 is nonetheless likely to be an important mediator of intraocular inflammation directly or perhaps through its regulatory effects on TLR responses. Future studies to investigate the possible interplay of NOD1 activation with TLR responses or even NOD2 responses in vivo should be informative. 

In conclusion, the NLR family plays an important role in immune surveillance and just as likely plays an important role in regulating ocular inflammatory responses. Our findings here are the first steps toward understanding how direct activation of NOD1 triggers ocular inflammatory events that might predispose a person to uveitis. 

 

The authors thank Monica Jann, Julie Ji, and Tessa Diebel for their technical contributions.