Dysregulated lipid metabolism, characterized by the accumulation of lipid deposits on Bruch's membrane and in drusen, is considered a key pathogenic event in age-related macular degeneration (AMD). The imbalance of lipid production, usage, and transport in local tissues, particularly in the retinal pigment epithelium (RPE), is increasingly recognized as crucial in AMD development. However, the molecular mechanisms governing lipid metabolism in the RPE remain elusive. LIPIN1, a multifunctional protein acting as both a modulator of transcription factors and a phosphatidate phosphatase (PAP1), is known to play important regulatory roles in lipid metabolism and related biological functions, such as inflammatory responses. While deficits in LIPIN1 have been linked to multiple diseases, its specific roles in the retina and RPE remain unclear. In this study, we investigated LIPIN1 in RPE integrity and function using a tissue-specific knockout animal model. The clinical and histological examinations revealed age-dependent degeneration in the RPE and the retina, along with impaired lipid metabolism. Bulk RNA sequencing indicated a disturbance in lipid metabolic pathways. Moreover, these animals exhibited inflammatory markers reminiscent of human AMD features, including deposition of IgG and C3d on Bruch's membrane. Collectively, our findings indicate that LIPIN1 is a critical component of the complex regulatory network of lipid homeostasis in the RPE. Disruption of LIPIN1-mediated regulation impaired lipid balance and contributed to AMD-related pathogenic changes.
Keywords: Lipin1; age‐related macular degeneration; lipid; metabolism; retinal pigment epithelium.
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