Abstract
AbstractPost-traumatic stress disorder (PTSD), a consequence of psychological trauma, is associated with increased inflammation and an elevated risk of developing comorbid inflammatory diseases. However, the mechanistic link between this mental health disorder and inflammation remains elusive. Using a pre-clinical model of PTSD known as repeated social defeat stress (RSDS), we previously identified that S100a8 and S100a9 mRNA, genes that encode the protein calprotectin, were significantly upregulated in T-lymphocytes after psychological trauma. Calprotectin expression positively correlated with inflammatory gene expression and the mitochondrial redox environment in T-lymphocytes, therefore, we hypothesized that genetic deletion of calprotectin would attenuate the inflammatory and redox phenotype displayed after RSDS. Using pharmacological and genetic manipulation of S100a9 (which functionally eliminates calprotectin) in mice, we unexpectedly observed worsening of behavioral pathology, inflammation, and the mitochondrial redox environment in mice after RSDS compared to wild-type (WT) animals. Furthermore, loss of calprotectin significantly enhanced the metabolic demand on T-lymphocytes suggesting this protein may play an undescribed role in mitochondrial regulation. This was further supported by single-cell RNA sequencing analysis demonstrating that RSDS and loss of S100a9 primarily altered genes associated with mitochondrial function and oxidative phosphorylation. Taken together, these data demonstrate the loss of calprotectin potentiates the RSDS-induced phenotype, which suggests its observed upregulation after psychological trauma may provide previously unexplored protective functions.
Publisher
Cold Spring Harbor Laboratory