While the epidermis turns over in its entirety once a month, the skeleton is completely replaced by a new one (or, an equivalent mass of tissue) 3–5 times in a lifetime
(between skeletal maturity and death). One would argue that a stem cell could be dispensable Screening Library manufacturer for coping with this specific physiological need. Stated in a less teleological way, one would wonder why a system of stem and progenitor cells would be evolutionarily selected and conserved in the skeleton. Similar considerations, many years later, apply to many other systems seen today as dependent on some kind of stem cell. For example, we consider that a neural stem cell exists in specific
regions of the brain, even if postnatal neurogenesis is very limited in rodents, and its very existence is still open to question in see more humans. Most importantly, we have extended significantly the use of the term “stem cell” beyond its original definition, which was tailored on postnatal self-renewing tissues. Attempts to define a set of functions as defining all kinds of cells we call stem cells have met a limit. Embryonic pluripotent stem cells (ES cells) and postnatal stem cells display majorly different biological properties. No postnatal (stem) cell is pluripotent, unless modified into an Induced Pluripotent Stem (iPS) Cell. As applied to cultured ES cells, furthermore, the term self-renewal has a different meaning compared
to the one it has in postnatal stem cells. Unlike postnatal stem cells, ES cells do not self-renew in vivo for the lifespan of the organism. Pluripotency can however be maintained in ES cells as these are cultured as continuous lines in vitro, under specific conditions. The extended use of the term “stem cell” (and of the terminology describing stem cell properties) for Liothyronine Sodium vastly different biological systems calls, in fact, for a more precise appreciation of the physiological function that is encrypted in each kind of stem cell, and evolutionarily conserved. For embryonic pluripotency, diapause (the ability of some species to arrest embryo development and to resume it depending on environmental and nutritional conditions) can be tentatively conceived as the function conserved across a number of species, but not in primates [40]. For other systems, specific conserved functions remain to be identified, and each is linked to gross properties of the relevant “stem” cell system (growth kinetics, differentiation potential), and to the underpinning regulatory circuits. Identifying the properties and circuits that define the stem cells in bone rests not on the analogy, but on the divergence of the system from the hematopoietic system.
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