Abstract
The ability of salamanders, such as newts, to regenerate damaged tissues has been studied for centuries. A prominent example of this regenerative power is the ability to re-grow entire amputated limbs. One important step in this regeneration process is skeletal muscle cellularization, in which the muscle fibers break down into dedifferentiated, mononuclear cells that proliferate and form new muscle in the replacement limb. In contrast, mammalian skeletal muscle does not undergo cellularization after injury. A significant proportion of research about tissue regeneration in salamanders aims to characterize regulatory genes that may have mammalian homologs. A less mainstream approach is to develop small molecule compounds that induce regeneration-related mechanisms in mammals. In this commentary, we discuss progress in discovering small molecules that induce cellularization in mammalian muscle. New research findings using these compounds has also shed light on cellular processes that regulate cellularization, such as apoptotic signaling. Although formidable technical hurdles remain, this progress increases our understanding of tissue regeneration and provide opportunities for developing small molecules that may enhance tissue repair in humans.
Highlights
The ability of salamanders, such as newts, to regenerate damaged tissues has been studied for centuries
In the context of limb regeneration, this had led to the development of small molecules that can change the behavior of mammalian muscle tissue in vitro to resemble the injury response observed in salamanders
We summarize recent progress in the characterization of these small molecules and discuss their potential to be developed as therapeutic agents to enhance tissue regeneration in humans
Summary
The ability of salamanders, such as newts, to regenerate damaged tissues has been studied for centuries. In the context of limb regeneration, this had led to the development of small molecules that can change the behavior of mammalian muscle tissue in vitro to resemble the injury response observed in salamanders. Genetic manipulations or exogenous agents that induce myotube fragmentation can be observed using microscopy and provide a simple assay for candidate compounds that produce cellularization in mammalian muscles [21].
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