The Impact of Cannabinoid Exposure on Glucocorticoid Receptor Signaling in Neural Stem Cells

Preterm birth-birth before 37 weeks of pregnancy-can cause many short- and long-term complications in newborns, including respiratory distress syndrome (RDS). RDS results from incomplete lung development and a surfactant deficiency, and it is a major factor of pre-term mortality. Synthetic glucocorticoids (sGCs) such as Betamethasone or Dexamethasone (Beta, Dex) are administered prenatally to women at risk of pre-term birth to prevent preterm complications. While sGCs are known to improve outcome, they also cause alterations in brain development and neural stem cell biology that are associated with long-term neurological defects. One common recreational drug used during pregnancy is cannabis. Some of the active components of cannabis include cannabinoids, which interact with the endocannabinoid receptor pathway in cells. Cannabinoids have been shown to induce proliferation and differentiation of embryonic neural stem cells (NSCs). We hypothesized that maternal cannabis use activates cannabinoid signaling pathways and leads to changes in glucocorticoid signaling in the developing brain. The purpose of this study was to determine whether cannabis use leads to a better or worse neurological outcome for children born pre-term and treated with sGCs for RDS. Neural stem cell neurospheres (NSCs) were isolated from the cerebral cortex of mice and treated with Vehicle (ethanol), Dex, cannabinoid receptor agonist WIN-55,212-2 (Win), or a combination WinDex. The transcriptional profile induced by exposure to Vehicle, Dex, and WinDex RNA were analyzed using microarray analyses examining the complete expressed genome. Gene Chip profiles indicated that both glucocorticoids and cannabinoids induce distinct transcriptional responses in E14.5 NSCs. The genes involved in proliferation-including S100a11, Jun, and Bex2-were repressed by Dex whereas WinDex rescued some of these expression profiles. Some genes encoding microRNA that inhibit our top target coding genes implicated in proliferation showed a greater induction by Dex compared to WinDex. Quantitative Polymerase Chain Reaction (qPCR) was performed to validate our genes of interest, including Adm, which has been shown to induce neural stem cell proliferation and differentiation. The biological impact of Winn on Dex-induced changes in NSC function were examined by in-vitro proliferation and differentiation studies using antibodies to Tuj1 (neurons), GFAP (glia), and CNPase (immature oligodendrocytes). The experiments indicate that Dex increased neuronal and oligodendrocyte differentiation, while WinDex appeared to reverse this phenotype in neurons. These studies suggest that cannabis use during pregnancy may limit the biological impact sGCs for preterm birth and lead to distinct cellular responses.