Conventional glucocorticoid (GC) treatment has a long-term influence on T-cell immunity, resulting in an increased risk of opportunistic infection after drug withdrawal. The underlying mechanisms remain ambiguous. This study demonstrated that long-term GC treatment induced persistent lymphopenia in patients with primary glomerular disease. GCs continuously suppressed the proportion of CD4+ T cells even after the daily dose was tapered down to the physiologic equivalences, leading to a significant decline of the CD4/CD8 ratio. Meanwhile, GCs impaired CD4+ T cell biology, leading to enhanced apoptotic cell death, reduced proliferative capacity, downregulated pro-inflammatory genes, and upregulated immunoregulatory genes. Specifically, GCs altered FOXP3 expression pattern in CD4+ T cells and favored their acquisition of an active T regulatory (Treg) cell phenotype with enhanced IL-10 production upon stimulation. Mechanistically, GCs tampered with the transcriptional regulation of mechanistic target of rapamycin complex 1 (mTORC1) pathway, resulting in an inhibitory impact on the signaling activity. Targeting mTORC1 signaling by siRNAs could sufficiently modify the viability of GC-exposed CD4+ T cells. By high-throughput sequencing of genome-wide DNA methylation and mRNA, we further uncovered a causal relationship between the altered DNA methylation level and transcription activity in a subset of mTORC1 pathway genes in long-term GC exposure. Taken together, this study reveals a novel regulation of mTORC1 signaling, which might dominate the long-term influence of GC on CD4+ T cell biology in a dose-independent manner.
Keywords: DNA methylation; FOXP3; Glucocorticoid; Mechanistic target of rapamycin complex 1; T cell.
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