Abstract
Stem cells have indefinite self-renewable capability; however, factors that modulate their pluripotency/function are not fully identified. Here we show that store-dependent Ca2+ entry is essential for modulating the function of bone marrow-derived mesenchymal stem cells (MSCs). Increasing external Ca2+ modulated cell cycle progression that was critical for MSCs survival. Additionally, Ca2+ was critical for stem proliferation, its differentiation, and maintaining stem cell potential. Ca2+ channel characterization, including gene silencing, showed two distinct Ca2+ entry channels (through Orai1/TRPC1 or via Orai3) that differentially regulate the proliferation and viability of MSCs. Importantly, NFκB translocation, but not JNK/ERK into the nucleus, was observed upon store depletion, which was blocked by the addition of Ca2+ channel inhibitors. Radiation lead to a decrease in saliva secretion, decrease in acinar cell number, and enlarged ducts were observed, which were restored by the transplantation of stem cells that were propagated in higher Ca2+. Finally radiation showed a decrese in TRPC1 expression along with a decrese in AQP5, which was again restored upon MSC tranplantation. Together these results suggest that Ca2+ entry is essential for stem cell function that could be critical for regenerative medicine.
Highlights
Stem cells are unique as they possess the indefinite self-renewable capability that can be differentiated into all types of cell lineages, making them unique and ideal candidates for organ development or tissue therapy[1,2]
We found that mesenchymal stem cells (MSCs) showed a differential expression pattern for these stem cell markers
bone marrow cells (BMCs) showed the expression of both stem cells (CD29, CD44) and immune cells (CD11b, CD45) markers (Fig. 1f, g), and no decrease in the expression of immune cell markers was observed in BMCs, when compared with MSCs
Summary
Stem cells are unique as they possess the indefinite self-renewable capability that can be differentiated into all types of cell lineages, making them unique and ideal candidates for organ development or tissue therapy[1,2]. Several types of stem cells have been identified that are either according to their origin (embryonic, germinal, and somatic stem cells), or are classified based on their differentiating potential (totipotent, pluripotent, and multipotent cell types)[3]. Stem cells are located in particular anatomic regions that provide the microenvironment or niche needed for their self‐renewal, differentiation, and maintenance. The mammalian bone marrow is the largest reservoir that contains various stem cells such as: hematopoietic stem cells (HSCs), multipotent adult progenitor stem cells (MAPCs), and mesenchymal stem cells (MSCs)[4,5,6,7]. Demand for tissue reconstruction especially for the regeneration of damaged tissues. Due to disease or aging has been expanding[8]; there is a critical need to understand the factors that could modulate their stemness/proliferation
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