ABSTRACT: Diabetic retinopathy (DR), the leading cause of blindness in working-age adults, is thought to be primarily a microvascular complication of diabetes. Müller cells, the major macroglia of the retina, are important for maintaining a healthy and functional retina and play a critical role in several pathological events during DR disease progression as they are a central element of the retinal neurovascular unit. Here, we aim to improve our understanding of Müller cell-specific signaling pathways that are altered during disease progression in order to develop novel gene therapy strategies targeting Müller cells in DR. To achieve this, we used a multi-omics approach on purified Müller cells from 6-month-old control and diabetic db/db mice, including (i) RNA-seq followed by oPOSSUM-3 transcription factor (TF) binding site cluster analysis, (ii) glial chromatin landscape analysis by ATAC-seq, and (iii) Müller cell proteomics by MS/MS mass spectrometry. This led to the identification of the glucocorticoid receptor (GR, gene ID: Nr3c1) as the most promising candidate. Its transcripts and protein were most highly expressed in Müller cells and significantly reduced in cells from diabetic mice, its target gene cluster was downregulated in Müller cells from diabetic animals, and importantly, it was identified as a potential master regulator not only by oPOSSUM analysis based on differentially expressed mRNA in Müller cells, but also validated by the ATAC-seq approach. Next, we investigated the effect of GR modulation in an in vitro cortisol-stimulated retinal explant model. Cortisol not only increased GR phosphorylation levels, but also induced changes in the expression of known downstream GR target genes. Finally, we evaluated whether AAV-mediated GR overexpression in Müller cells improves retinal functionality and found moderate functional improvements in electroretinogram recordings. Although synthetic and topical glucocorticoids are widely used in ophthalmology with undeniable beneficial effects, our study provides valuable new insights into the role of GR signaling and glial alterations in the diabetic retina and thus supports the therapeutic concept of locally enhancing the GR signaling axis. However, our finding of reduced GR levels in Müller cells of the diabetic retina suggests that therapeutic approaches should aim at increasing the expression of the receptor rather than adding more ligands. This may result in optimized local efficacy with fewer systemic unwarranted side effects.