Abstract
This study re-examined the dying process in the interdigital tissue during the formation of free digits in the developing limbs. We demonstrated that the interdigital dying process was associated with cell senescence, as deduced by induction of β-gal activity, mitotic arrest, and transcriptional up-regulation of p21 together with many components of the senescence-associated secretory phenotype. We also found overlapping domains of expression of members of the Btg/Tob gene family of antiproliferative factors in the regressing interdigits. Notably, Btg2 was up-regulated during interdigit remodeling in species with free digits but not in the webbed foot of the duck. We also demonstrate that oxidative stress promoted the expression of Btg2, and that FGF2 and IGF1 which are survival signals for embryonic limb mesenchyme inhibited Btg2 expression. Btg2 overexpression in vivo and in vitro induced all the observed changes during interdigit regression, including oxidative stress, arrest of cell cycle progression, transcriptional regulation of senescence markers, and caspase-mediated apoptosis. Consistent with the central role of p21 on cell senescence, the transcriptional effects induced by overexpression of Btg2 are attenuated by silencing p21. Our findings indicate that cell senescence and apoptosis are complementary processes in the regression of embryonic tissues and share common regulatory signals.
Highlights
Normal development requires the coordination of growth and differentiation and the elimination of excess cells in embryonic structures
This study examined whether apoptosis and cell senescence in embryonic systems are redundant regressive changes that are regulated by tumor suppressor genes, similar to adult tissues during ageing and cancer
Several programmed cell death processes in the embryo are accompanied by cell senescence [19,20,21], which is characterized by the irreversible loss of replicating ability
Summary
Normal development requires the coordination of growth and differentiation and the elimination of excess cells in embryonic structures. Digit formation in vertebrate embryonic limbs provides a valuable model of programmed cell death that sculpts interdigital tissue to varying degrees and confers hand/foot (autopod) morphology in accordance with the functional specialization of a species to swim (ducks, and turtles), fly (bats), or walk (chickens, humans, and lizards) [1,2,3,4]. Several recent studies have proposed that some regressive changes in the embryo include cell senescence that is similar to the senescence induced by oncogenes or senescence-inducing stimuli in adult tissues [19,20,21]. The unraveling of the molecular machinery that determines whether a skeletal progenitor undergoes senescence and cell death or proliferates and differentiates to form a digit is of great biological relevance [22]
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