Abstract
Maintenance of acid-base homeostasis in extracellular fluids and in the cytoplasm is essential for the physiological activities of cells and tissues [1]. However, changes in extracellular pH (pHe) occurs in a variety of physiological and pathological conditions, including hypoxia and inflammation associated with trauma and cancer. Concerning bone tissue, if abnormal acidification occurs, mineral deposition and osteoblast differentiation are inhibited, whereas osteoclast formation and activity are enhanced [2]. Indeed, acidification, that usually occurs in the early phases of fracture repair, has been suggested as a driving force for regeneration via release of growth factors that act on the stem cell fraction of repair bone [3]. However, the effect of low pHe on stemness has been insufficiently explored so far. Thus, in this study, we investigated the role of short term exposure to low pHe (6.5–6.8) on MSC stemness.
MSC derived from dental pulps (DPSC) and bone marrow (BM-MSC) were used. To perform the specific assays, culture medium at specific pH (6.5, 6.8, 7.1 and 7.4) was maintained by using different concentrations of sodium bicarbonate according to the Henderson-Hasselbach equation.
Changes in osteoblast-related gene expression (COL1A1 and ALPL), and mineral nodule formation were measured by qRT-PCR and Alizarin red staining, respectively.
The stem phenotype was analysed by measuring changes in stemness-related genes (SOX2, OCT4, KLF4, c-MYC) expression and spheres forming ability. Additionally, cell number, Ki67 index and cell cycle were analysed to monitor cell proliferation and quiescence.
We confirmed that acidic pHe inhibits the osteogenic differentiation of DPSC. Low pHe significantly but transitorily decreased the expression of osteoblast-related genes (COL1A1 and ALPL) and decreased the mineral nodule formation in vitro.
Acidic pHe conditions significantly increased the ability of DPSC and BM-MSC to form floating spheres. At acidic pHe spheres were higher but smaller when compared to spheres formed at alkaline pHe conditions. Moreover, acidic pHe increased significantly the expression of stemness-related genes. Finally, low pHe induced a significant decrease of DPSC cell number. Reduction of cell proliferation correlated with a lower number of cycling cells, as revealed by the Ki67 index that significantly decreased in a pH-dependent manner. Cell cycle analysis revealed an accumulation of cells in the G0 phase, when cultured at low pH.
In this study, we demonstrated a close relationship between acidic pHe and the regulation of MSC stemness. We therefore suggest that pHe modulation of MSC stemness is a major determinant of skeletal homeostasis and regeneration, and this finding should be considered in bone healing strategies based on cell therapy.
