Springer Science and Business Media LLC

The potential of cell therapy in regenerative medicine has greatly expanded thanks to the availability of sources of pluripotent cells. In particular, induced pluripotent stem cells (iPS) have dominated the scenario in the last years for their ability to proliferate and differentiate into specific cell types. Nevertheless, the concerns inherent to the cell reprogramming process, limit iPS use in therapy and pose questions on the long-term behavior of these cells. In particular, despite the development of virus-free methods for their obtainment, a major and persisting drawback, is related to the acquisition of a stable pluripotent state, that is un-physiological and may lead to cell instability. The increased understanding of epigenetic mechanisms has paved the way to the use of “small molecules” and “epigenetic modifiers” that allow the fine tuning of cell genotype and phenotype. In particular, it was demonstrated that an adult mature cell could be directly converted into a different cell type with the use of these chemicals, obtaining a new patient-specific cell, suitable for cell therapy. This approach is simple and direct and may represent a very promising tool for the regenerative medicine of several and diverse degenerative diseases.

Cancer cell lines can be useful to model cancer stem cells. Infection with Mycoplasma species is an insidious problem in mammalian cell culture. While investigating stem-like properties in early passage melanoma cell lines, we noted poorly reproducible results from an aliquot of a cell line that was later found to be infected with Mycoplasma hyorhinis. Deliberate infection of other early passage melanoma cell lines aliquots induced variable and unpredictable effects on expression of putative cancer stem cell markers, clonogenicity, proliferation and global gene expression. Cell lines established in stem cell media (SCM) were equally susceptible. Mycoplasma status is rarely reported in publications using cultured cells to study the cancer stem cell hypothesis. Our work highlights the importance of surveillance for Mycoplasma infection while using any cultured cells to interrogate tumor heterogeneity.

Stem cells have great potential for understanding early development, treating human disease, tissue trauma and early phase drug discovery. The factors that control the regulation of stem cell survival, proliferation, migration and differentiation are still emerging. Some evidence now exists demonstrating the potent effects of various G-protein coupled receptor (GPCR) ligands on the biology of stem cells. This review aims to give an overview of the current knowledge of the regulation of embryonic and somatic stem cell maintenance and differentiation by GPCR ligands.

Data from in vitro and in vivo models suggest that malnutrition and stress trigger adaptive responses, leading to small for gestational age (SGA) blastocysts with fewer cell numbers. These stress responses are initially adaptive, but become maladaptive with increasing stress exposures. The common stress responses of the blastocyst-derived stem cells, pluripotent embryonic and multipotent placental trophoblast stem cells (ESCs and TSCs), are decreased growth and potency, and increased, imbalanced and irreversible differentiation. SGA embryos may fail to produce sufficient antiluteolytic placental hormone to maintain corpus luteum progesterone secretion that provides nutrition at the implantation site. Myriad stress inputs for the stem cells in the embryo can occur in vitro during in vitro fertilization/assisted reproductive technology (IVF/ART) or in vivo. Paradoxically, stresses that diminish stem cell growth lead to a higher level of differentiation simultaneously which further decreases ESC or TSC numbers in an attempt to functionally compensate for fewer cells. In addition, prolonged or strong stress can cause irreversible differentiation. Resultant stem cell depletion is proposed as a cause of miscarriage via a “quiet” death of an ostensibly adaptive response of stem cells instead of a reactive, violent loss of stem cells or their differentiated progenies.