Abstract
Regeneration allows animals to replace and restore injured tissues. Animal phyla have evolved different regenerative strategies to increase survival advantages. In contrast to the earlier principle that regeneration recapitulates development, recent studies indicate that wound healing in adult mammals is modified by the inflammatory response to injury, and biochemical signaling from immune and other cellular systems may modulate wound reparative responses to achieve successful tissue regeneration. Here we briefly survey different regenerative strategies used by animals across different phyla. We next focus on skin regeneration using the mouse wound-induced hair neogenesis model as an example to show the circumstances required to rebuild a new, morphogenetically competent field in the adult mammalian skin. Parallel investigations in African spiny mice (Acomys sp.) have further shown that skin rigidity can also modulate wound bed properties to facilitate de novo formation of skin appendages. These regenerating, periodically arranged hair primordia emerge using Turing activator/inhibitor principles with activities derived from sources that differ from those used in embryonic development, including the mechanical environment. Thus, a novel combination of biochemical, immunological, and mechanical signaling strategies can work together to achieve successful cutaneous regeneration in adult animals, potentially inspiring novel therapeutic strategies.