Autofluorescence Imaging to Evaluate Retinal Disease Progression in Rodent.

Fundus autofluorescence (FAF) imaging is a noninvasive retinal imaging methodology that allows mapping of lipofuscin distribution in the retinal pigment epithelium cell (RPE). Excessive accumulation of lipofuscin granules in the lysosomal compartment of RPE cells represents a common downstream pathogenetic pathway in various hereditary and complex retinal diseases, including age-related macular degeneration. The clinical applications of FAF coupled with its ease of use, and the noninvasive nature of characterizing retinal diseases, are increasingly valuable to the field of ophthalmology and in assessing the progression of retinitis pigmentosa (RP). Quantitative AF (qAF) enhances the understanding of retinal disease processes, serves as a diagnostic aid, and allows for the monitoring of the effects of therapeutic interventions. This chapter introduces basic principles of FAF and general protocols of FAF evaluating retinal disease progression in rodents.

CRISPR genome surgery in a novel humanized model for autosomal dominant retinitis pigmentosa.

Mutations in rhodopsin (RHO) are the most common causes of autosomal dominant retinitis pigmentosa (adRP), accounting for 20% to 30% of all cases worldwide. However, the high degree of genetic heterogeneity makes development of effective therapies cumbersome. To provide a universal solution to RHO-related adRP, we devised a CRISPR-based, mutation-independent gene ablation and replacement (AR) compound therapy carried by a dual AAV2/8 system. Moreover, we developed a novel hRHOC110R/hRHOWT humanized mouse model to assess the AR treatment in vivo. Results show that this humanized RHO mouse model exhibits progressive rod-cone degeneration that phenocopies hRHOC110R/hRHOWT patients. In vivo transduction of AR AAV8 dual vectors remarkably ablates endogenous RHO expression and overexpresses exogenous WT hRHO. Furthermore, the administration of AR during adulthood significantly hampers photoreceptor degeneration both histologically and functionally for at least 6 months compared with sole gene replacement or surgical trauma control. This study demonstrates the effectiveness of AR treatment of adRP in the human genomic context while revealing the feasibility of its application for other autosomal dominant disorders.

Long-term vitamin A supplementation in a preclinical mouse model for RhoD190N-associated retinitis pigmentosa.

Retinitis pigmentosa (RP) is caused by one of many possible gene mutations. The National Institutes of Health recommends high daily doses of vitamin A palmitate for RP patients. There is a critical knowledge gap surrounding the therapeutic applicability of vitamin A to patients with the different subtypes of the disease. Here, we present a case report of a patient with RP caused by a p.D190N mutation in Rhodopsin (RHO) associated with abnormally high quantitative autofluorescence values after long-term vitamin A supplementation. We investigated the effects of vitamin A treatment strategy on RP caused by the p.D190N mutation in RHO by exposing Rhodopsin p.D190N (RhoD190N/+) and wild-type (WT) mice to experimental vitamin A-supplemented and standard control diets. The patient's case suggests that the vitamin A treatment strategy should be further studied to determine its effect on RP caused by p.D190N mutation in RHO and other mutations. Our mouse experiments revealed that RhoD190N/+ mice on the vitamin A diet exhibited higher levels of autofluorescence and lipofuscin metabolites compared to WT mice on the same diet and isogenic controls on the standard control diet. Vitamin A supplementation diminished photoreceptor function in RhoD190N/+ mice while preserving cone response in WT mice. Our findings highlight the importance of more investigations into the efficacy of clinical treatments like vitamin A for patients with certain genetic subtypes of disease and of genotyping in the precision care of inherited retinal degenerations.

Impaired cholesterol efflux in retinal pigment epithelium of individuals with juvenile macular degeneration.

Macular degeneration (MD) is characterized by the progressive deterioration of the macula and represents one of the most prevalent causes of blindness worldwide. Abnormal intracellular accumulation of lipid droplets and pericellular deposits of lipid-rich material in the retinal pigment epithelium (RPE) called drusen are clinical hallmarks of different forms of MD including Doyne honeycomb retinal dystrophy (DHRD) and age-related MD (AMD). However, the appropriate molecular therapeutic target underlying these disorder phenotypes remains elusive. Here, we address this knowledge gap by comparing the proteomic profiles of induced pluripotent stem cell (iPSC)-derived RPEs (iRPE) from individuals with DHRD and their isogenic controls. Our analysis and follow-up studies elucidated the mechanism of lipid accumulation in DHRD iRPE cells. Specifically, we detected significant downregulation of carboxylesterase 1 (CES1), an enzyme that converts cholesteryl ester to free cholesterol, an indispensable process in cholesterol export. CES1 knockdown or overexpression of EFEMP1R345W, a variant of EGF-containing fibulin extracellular matrix protein 1 that is associated with DHRD and attenuated cholesterol efflux and led to lipid droplet accumulation. In iRPE cells, we also found that EFEMP1R345W has a hyper-inhibitory effect on epidermal growth factor receptor (EGFR) signaling when compared to EFEMP1WT and may suppress CES1 expression via the downregulation of transcription factor SP1. Taken together, these results highlight the homeostatic role of cholesterol efflux in iRPE cells and identify CES1 as a mediator of cholesterol efflux in MD.

Characterization and functional study of Antrodia camphorata lipopolysaccharide.

Lipopolysaccharide (LPS) is a highly proinflammatory molecule isolated from bacteria. This study demonstrated the existence of LPS in a medicinal fungus, Antrodia camphorata. Because no LPS had been identified in any fungus organism, the purification of LPS from A. camphorata was attempted. LPSs from six strains of A. camphorata (35396, 35398, 35716, B71, B85, and B86) were isolated. Chemical and functional properties were investigated on the fungus LPS. Compositional analysis revealed that sorbitol, fucose, galactose, and glucose were the neutral sugars in LPS of A. camphorata. Galactosamine, glucosamine, galactose, and glucose were the predominant monosaccharide species in E. coli O129 LPS molecules, whereas galactosamine and glucosamine were absent in A. camphorata LPS. Because these properties are different from those of bacterial LPS, the functions between fungus and bacterial LPS are also discussed. The vascular endothelial lining of blood vessels, which controls leucocyte traffic and activation, may be one of the primary targets of LPS action during sepsis. Assays for biological activity were performed on endothelial cells with anti-inflammatory effects associated with sepsis. A. camphorata LPS apparently showed a lesser extent of cytotoxicity than bacterial LPS. In contrary to the proinflammatory property of bacterial LPS, LPS from A. camphorata differentially reversed bacterial LPS-induced intercellular adhersion molecule-1 and monocyte adhesion; both were indicators during inflammatory process. In conclusion, basic chemical properties categorized A. camphorata extracts into lipopolysaccharide. However, the detailed functional structures and bioactivities of A. camphorata LPS were totally different from those of bacterial LPS. The investigation of the existence and anti-inflammatory effect of fungus LPS is at present a truly novel and important finding. These results show that LPS isolated from A. camphorata offers a novel therapeutic target for anti-inflammation against E. coli infection.