Abstract
Neuroinflammation is involved in the development of depression and may induce depression-like behaviors by affecting metabolism through interactions with circadian rhythms. As the hub of metabolism, mitochondria are regulated by various types of metabolism and release signals that regulate cellular functions. In this study, we performed transcriptomic analysis of the hippocampus of IL-33-overexpressing mice to provide new ideas to explore the pathogenesis of inflammation-mediated depression at the transcriptional level. Male C57BL/6J mice and IL-33-overexpressing mice were subjected to behavioral tests. The hippocampus was extracted during the light or dark period, and differential gene expression analysis was conducted using RNA sequencing. Differential gene enrichment analysis was performed, as well as multilayered analysis of mitochondrial transcriptional rhythms by integrating the regulatory networks and Mito 3.0 database. The results were further verified using RT-qPCR. IL-33-overexpressing mice exhibited depressive behaviors associated with rhythmic disorders and shortened circadian cycles. Differential KEGG (Kyoto Encyclopedia of Genes and Genomes) enrichment analysis showed that the top 20 pathways with the lowest p-values included mood-related, immune-related, and circadian rhythm-related pathways. Differential gene GO (Gene Ontology) enrichment analysis showed that 20 of the top 30 pathways with the lowest p-values were related to metabolism. Transcriptome data from IL-33-overexpressing mice showed that the mitochondrial-encoded subunit of the oxidative respiratory complex showed predominantly increased expression during the light period. Metabolic disorders and disrupted mitochondrial transcriptional rhythm were also observed. Weighted gene correlation network analysis showed that the circadian cycle is associated with depression-like behavior disorders. Network analysis showed that circadian-related genes were enriched in mitochondrial pathways related to metabolism and oxidative phosphorylation. Multilayer analysis of mitochondrial transcriptional rhythms using the mitochondrial database Mito 3.0 revealed that mitochondrial dynamics and surveillance pathways were the most enriched. The depressive behavior in mice caused by long-term IL-33 stimulation may be related to changes in the transcriptional rhythms of metabolism-related genes and the interaction between mitochondria and clock genes. This suggests that mitochondrial transcriptional rhythms are central to the pathogenesis of microinflammation-induced depression, further supporting the potential of mitochondria as a target for the prevention and treatment of depression.