Jeffrey Dunmire

Animal Models of Glaucoma

Glaucoma is a heterogeneous group of disorders that progressively lead to blindness due to loss of retinal ganglion cells and damage to the optic nerve. It is a leading cause of blindness and visual impairment worldwide. Although research in the field of glaucoma is substantial, the pathophysiologic mechanisms causing the disease are not completely understood. A wide variety of animal models have been used to study glaucoma. These include monkeys, dogs, cats, rodents, and several other species. Although these models have provided valuable information about the disease, there is still no ideal model for studying glaucoma due to its complexity. In this paper we present a summary of most of the animal models that have been developed and used for the study of the different types of glaucoma, the strengths and limitations associated with each species use, and some potential criteria to develop a suitable model.

MicroRNA in aqueous humor from patients with cataract.

MicroRNAs (miRNAs) are small non-coding RNA molecules with regulatory function and marked tissue specificity that can modulate multiple gene targets. They have been detected in body fluids and are associated with various physiologic and pathologic processes. We analyzed aqueous humor (AH) from human subjects undergoing cataract surgery to establish the presence and relative quantities of known miRNAs. AH was collected from patients without known ocular diseases other than cataract and a normal systemic history. Quantitative real-time PCR in an array platform was used to detect known miRNAs present in the AH. Among the 264 miRNAs tested, 110 were present in the AH. The top 5 abundant miRNAs identified were miR-202, miR-193b, miR-135a, miR-365, and miR-376a. The presence of miRNAs in AH suggests that they may have functional roles in regulating target genes in tissues lining the anterior chamber. Further analysis of the AH miRNA population may identify potential gene targets and provide insights regarding their roles in AH regulation, glaucoma and anterior segment disease processes.

Anti-retinal antibodies in serum of laser-treated rabbits.

PURPOSE Retinal injuries that affect the photoreceptors and/or the retinal pigment epithelium (RPE) may result in the leakage of retinal proteins into the systemic circulation. This study was designed to determine whether an immune response is elicited after an acute retinal injury resulting in circulating anti-retinal antibodies in the serum. METHODS Fifty laser burns of different grades (minimally visible lesion [MVL], grade II [GII], or grade III [GIII] lesions) were created in the retinas of Dutch Belted rabbits. The degree of laser burns was confirmed by fundus imaging and histology. Serum samples were collected from the animals 3 months after the retinal injury. Candidate autoantigens were identified by two-dimensional (2-D) Western blots of rabbit retinal lysate probed with sera from either control or laser-treated animals. Candidate autoantigens were further characterized by immunostaining to confirm their retinal localization. RESULTS Seven and 11 protein spots were selected from the MVL and GII laser-treated samples, respectively, for autoantigen identification. No protein spots were detected in the GIII laser-treated samples. Four candidate autoantigens were common to both MVL and GII lesions: dihydropyrimidinase-related protein 2, fructose-bisphosphate aldolase C, chaperonin-containing T-complex polypeptide 1 subunit zeta, and pyruvate kinase isozyme. CONCLUSIONS Laser-induced retinal injuries resulted in circulating anti-retinal antibodies that were detectable 3 months after the injury. The response appeared to vary with the severity of the laser retinal damage. The identification of the candidate antigens in this study suggest that this approach may permit future development of new diagnostic methods for retinal injuries.

Lymphatic and Blood Vessel Density in Human Conjunctiva After Glaucoma Filtration Surgery.

Purpose:To investigate the lymphatic vascular microvessel density (LVD) and the blood vascular microvessel density (MVD) and their distribution in excised leaking blebs after mitomycin C trabeculectomy and normal conjunctiva specimens. Materials and Methods:LVD and MVD in normal human conjunctiva (n=8) and excised blebs in the hypocellular stroma and peribleb tissue (conjunctiva adjacent to hypocellular bleb tissue) (n=8) were evaluated by immunohistochemistry using antibodies raised against Lymphatic Vessel Endothelial Receptor 1 (D2-40, lymphatic endothelium) and CD34 (vascular endothelium). LVD and MVD counts were performed by light microscopyin 5 fields at ×20 magnification by 3 observers. Differences were determined using Mann-Whitney U test (P<0.05 was considered significant). Results:The leaking blebs showed typical epithelial-stromal domes with areas of acellular stroma covered by attenuated epithelium and surrounded by normal conjunctival epithelium and a dense scar-like matrix replacing the substantia propria. The LVD and MVD were significantly reduced to nil in the hypocellular conjunctival stroma of the excised blebs compared with normal conjunctiva (21.42 vs. 1.16, P<0.002 and 24.28 vs. 1, P<0.008, respectively). The LVD and MVD was also reduced (2- to 2.5-fold) in the peribleb stroma when compared with normal conjunctiva specimens. Conclusions:In this study we show reduced LCD and MVD in the hypocellular and peribleb stroma. These results may suggest a role of these vessels in an altered immune response in leaking blebs leading to an increased risk for blebitis.

Proteomics in the Study of Bacterial Keratitis

Bacterial keratitis is a serious ocular infection that can cause severe visual loss if treatment is not initiated at an early stage. It is most commonly caused by Staphylococcus aureus, Pseudomonas aeruginosa, Streptococcus pneumoniae, or Serratia species. Depending on the invading organism, bacterial keratitis can progress rapidly, leading to corneal destruction and potential blindness. Common risk factors for bacterial keratitis include contact lens wear, ocular trauma, ocular surface disease, ocular surgery, lid deformity, chronic use of topical steroids, contaminated ocular medications or solutions, and systemic immunosuppression. The pathogenesis of bacterial keratitis, which depends on the bacterium-host interaction and the virulence of the invading bacterium, is complicated and not completely understood. This review highlights some of the proteomic technologies that have been used to identify virulence factors and the host response to infections of bacterial keratitis in order to understand the disease process and develop improved methods of diagnosis and treatment. Although work in this field is not abundant, proteomic technologies have provided valuable information toward our current knowledge of bacterial keratitis. More studies using global proteomic approaches are warranted because it is an important tool to identify novel targets for intervention and prevention of corneal damage caused by these virulent microorganisms.

Immunohistochemical evidence of specific iris involvement in Blau syndrome.

Purpose: To evaluate iris involvement in Blau syndrome using histology and immunohistochemistry. Methods: Iridectomy specimen of a patient with treated Blau syndrome and a normal control were evaluated by light microscopy and immunohistochemistry using antibodies against CD4+, CD8+, HLA-DR, CD68+, NF-κB and IL-17. Results: Blau iris tissue demonstrated increased numbers of CD4+ lymphocytes and CD68 negative, HLA-DR positive spindle shaped cells compared to normal iris tissue. Blau iris tissue also demonstrated elevated CD4+/CD8+ ratio and IL-17 and NF-κB immunolabeling. No macrophages, epithelioid cells, or granulomas were noted in the Blau specimen. Conclusions: The persistent immunolocalization of inflammatory markers in an iris specimen from an aggresively treated patient with proven Blau syndrome suggests that further pathologic and immunohistochemical investigation of Blau ocular tissue is necessary to better understand the complexities of NOD2 activating mutations in the eye.

Non-invasive Detection of Unique Molecular Signatures in Laser-Induced Retinal Injuries

Unintentional laser exposure is an increasing concern in many operational environments. Determining whether a laser exposure event caused a retinal injury currently requires medical expertise and specialized equipment that are not always readily available. The purpose of this study is to test the feasibility of using dynamic light scattering (DLS) to non-invasively detect laser retinal injuries through interrogation of the vitreous humor (VH). Three grades of retinal laser lesions were studied: mild (minimally visible lesions), moderate (Grade II), and severe (Grade III). A pre-post-treatment design was used to collect DLS measurements in vivo at various time points, using a customized instrument. VH samples were analyzed by liquid chromatography/tandem mass spectrometry (LC-MS/MS) and relative protein abundances were determined by spectral counting. DLS signal analysis revealed significant changes in particle diameter and intensity in laser-treated groups as compared with control. Differences in protein profile in the VH of the laser-treated eyes were noted when compared with control. These results suggest that laser injury to the retina induces upregulation of proteins that diffuse into the VH from the damaged tissue, which can be detected non-invasively using DLS.