RESUMEN
Retinitis pigmentosa (RP) is the most common type of inherited retinal dystrophy. The course of RP is irreversible and leads to progressive loss of vision. It is characterized by hypotrophic degeneration of photoreceptor cells and retinal pigment epithelium. Multiple factors are involved in the development of the disease, including apoptosis, oxidative stress, and inflammatory/immune responses. In the past decades, gene therapy, stem cell therapy and other therapeutic approaches have been extensively investigated. However, due to the heritability and high heterogeneity of the disease and the difficulty in diagnosis and treatment, there is still a lack of standardized and effective therapies. Therefore, there is a need to develop new diagnostic and therapeutic approaches suitable for diseases with pathogenic mutations. With the understanding of the interaction between gene expression regulation and retinal pathology, the value of clinical applications of non-coding RNAs (ncRNAs) in retinal degeneration has gained attention. There is growing evidence that ncRNAs are widely distributed and involved in the regulation of multiple biological processes in the retina as well as processes associated with the development of RP, making them promising biomarkers for the diagnosis, treatment, and prognosis of RP. This paper reviews the crosstalk between ncRNA and RP, systematically discusses the role of ncRNAs in normal retinal cell physiology and RP pathogenesis and explores the potential of ncRNAs as therapeutic agents for clinical applications in RP.
RESUMEN
Diabetic retinopathy (DR) is a severe microvascular complication of diabetes mellitus and a major cause of blindness in young adults. Multiple potential factors influence DR; however, the exact mechanisms are poorly understood. Advanced treatments for DR, including laser therapy, vitrectomy, and intraocular drug injections, slow the disease's progression but fail to cure or reverse visual impairment. Therefore, additional effective methods to prevent and treat DR are required. The biological clock plays a crucial role in maintaining balance in the circadian rhythm of the body. Poor lifestyle habits, such as irregular routines and high-fat diets, may disrupt central and limbic circadian rhythms. Disrupted circadian rhythms can result in altered glucose metabolism and obesity. Misaligned central and peripheral clocks lead to a disorder of the rhythm of glucose metabolism, and chronically high sugar levels lead to the development of DR. We observed a disturbance in clock function in patients with diabetes, and a misaligned clock could accelerate the development of DR. In the current study, we examine the relationship between circadian rhythm disorders, diabetes, and DR. We conclude that: 1) abnormal function of the central clock and peripheral clock leads to abnormal glucose metabolism, further causing DR and 2) diabetes causes abnormal circadian rhythms, further exacerbating DR. Thus, our study presents new insights into the prevention and treatment of DR.
