Endocrine Abstracts

Chronic stress is a pervasive concern in the modern society. A long-term hyper activation of the hypothalamic-pituitary-adrenal (HPA) axis leads to elevated amounts of stress hormones [e.g. ACTH and glucocorticoids (GCs)]. This can incur maladaptation that eventually contributes to mental illness, cardiovascular dysfunctions, diabetes, cancer and autoimmune diseases. Emerging key players for stress adaptation of the HPA axis are stem/progenitor cell populations. In this study, we aim to unravel the mechanisms involved in the regulation of stem/progenitor cells of the HPA axis during stress adaptation. To that aim, we incorporated an in vitro system of non-adherent spheroids from primary adrenocortical mouse cells that were stimulated with ACTH. The treatment resulted in the increased growth of the spheroids compared to unstimulated controls indicating a potential role of the hormone in cell proliferation and stem cell behaviour. This result is in line with the enlarged adrenals observed in patients with Cushing’s syndrome. To assess the contribution of stem cells during stress adaptation in the adrenal cortex in vivo, we performed immobilization stress and lineage tracing studies using the tamoxifen inducible Gli1:CreERT2/R26R:eYFP mouse line. By combining these results along with single-cell RNA-seq technology, we aim to shed light into molecular factors involved in the adult adrenal cortex regeneration and remodelling. To follow the effect of GC excesses on the negative feedback loop observed during a normal stress response on the pituitary gland, we stimulated adherent primary anterior pituitary colonies with dexamethasone and corticosterone. GC treatment led to downregulation of Pomc expression, a precursor polypeptide for ACTH and other hormones, in the treated colonies compared to the control. This downregulation caused by GCs could be mediated through different gene targets of the glucocorticoid receptor as well as via paracrine signalling from pituitary stem cells. Altogether, our results will provide us with more profound knowledge of mechanisms underlying interactions between stressors and stem/progenitor cells of the HPA axis along with novel therapeutic targets for stress-associated disorders.