ENDOSCOPIC REMOVAL OF A FOREIGN BODY IN A MEXICAN AXOLOTL (AMBYSTOMA MEXICANUM) WITH THE USE OF MS222-INDUCED IMMOBILIZATION.

This communication briefly describes the use of tricaine methanesulfonate (MS222) to induce chemical restraint/general anesthesia of a Mexican axolotl (Ambystoma mexicanum) for the endoscopic retrieval of a gastric foreign body. There is very little published scientific literature concerning the anesthesia of Mexican axolotls. The anesthesia used in this case was an immersion bath of tricaine methanesulfonate where the concentration of tricaine methanesulfonate was gradually increased to 500 mg/L (ppm) over a 15-min period. A loss of righting reflex was observed within 3 min of attaining the final concentration of the anesthetic bath. The first voluntary movements following the transfer to a freshwater bath occurred within 7 min. The recovery was uneventful. Tricaine methanesulfonate in this case proved to be an effective anesthetic agent for a short, minimally invasive procedure.

Systemic cell cycle activation is induced following complex tissue injury in axolotl.

Activation of progenitor cells is crucial to promote tissue repair following injury in adult animals. In the context of successful limb regeneration following amputation, progenitor cells residing within the stump must re-enter the cell cycle to promote regrowth of the missing limb. We demonstrate that in axolotls, amputation is sufficient to induce cell-cycle activation in both the amputated limb and the intact, uninjured contralateral limb. Activated cells were found throughout all major tissue populations of the intact contralateral limb, with internal cellular populations (bone and soft tissue) the most affected. Further, activated cells were additionally found within the heart, liver, and spinal cord, suggesting that amputation induces a common global activation signal throughout the body. Among two other injury models, limb crush and skin excisional wound, only limb crush injuries were capable of inducing cellular responses in contralateral uninjured limbs but did not achieve activation levels seen following limb loss. We found this systemic activation response to injury is independent of formation of a wound epidermis over the amputation plane, suggesting that injury-induced signals alone can promote cellular activation. In mammals, mTOR signaling has been shown to promote activation of quiescent cells following injury, and we confirmed a subset of activated contralateral cells is positive for mTOR signaling within axolotl limbs. These findings suggest that conservation of an early systemic response to injury exists between mammals and axolotls, and propose that a distinguishing feature in species capable of full regeneration is converting this initial activation into sustained and productive growth at the site of regeneration.

MARCKS-like protein is an initiating molecule in axolotl appendage regeneration.

Identifying key molecules that launch regeneration has been a long-sought goal. Multiple regenerative animals show an initial wound-associated proliferative response that transits into sustained proliferation if a considerable portion of the body part has been removed. In the axolotl, appendage amputation initiates a round of wound-associated cell cycle induction followed by continued proliferation that is dependent on nerve-derived signals. A wound-associated molecule that triggers the initial proliferative response to launch regeneration has remained obscure. Here, using an expression cloning strategy followed by in vivo gain- and loss-of-function assays, we identified axolotl MARCKS-like protein (MLP) as an extracellularly released factor that induces the initial cell cycle response during axolotl appendage regeneration. The identification of a regeneration-initiating molecule opens the possibility of understanding how to elicit regeneration in other animals.