Step-by-step protocol for alternative injury models in newt cardiac regeneration.

Although the heart is one of the most important organs for animal survival, its regenerative capacity varies among animal species. Notably, adult mammals cannot regenerate their hearts after damage such as acute myocardial infarction. In contrast, some vertebrate animals can regenerate the heart throughout their lives. Cross-species comparative studies are important to understand the full picture of cardiac regeneration in vertebrates. Among the animal species able to regenerate the heart, some urodele amphibians, such as newts, possess a remarkable capacity for this process. Standardized methods of inducing cardiac regeneration in the newt are needed as a platform for studies comparing newts and other animal models. The procedures presented here describe amputation and cryo-injury techniques for the induction of cardiac regeneration in Pleurodeles waltl, an emerging model newt species. Both procedures consist of simplified steps that require no special equipment. We additionally show some examples of the regenerative process obtained using these procedures. This protocol has been developed for P. waltl. However, these methods are also expected to be applicable to other newt and salamander species, facilitating comparative research with other model animals.

Cryo-injury procedure-induced cardiac regeneration shows unique gene expression profiles in the newt Pleurodeles waltl.

BACKGROUND: Cardiac regeneration in the adult mouse is not substantial. Some vertebrates, such as newts and zebrafish, regenerate the heart throughout their lives. To understand how regenerative abilities differ among animal species, comparative research has been conducted in animals like mouse, zebrafish, and newt. For those purposes, cryo-injury is suitable as an experimental model for the pathological condition of human myocardial infarction. In fact, cryo-injury procedures are common in mouse and zebrafish. RESULTS: In the present study, we induced cryo-damage on the ventricle in Iberian ribbed newts using a liquid nitrogen-chilled probe. We observed that the injured area recovered within 8 weeks, with remodeling of scar tissue and proliferation of cardiomyocytes. We investigated the subsequent recovery of cryo-injured and amputated tissues by comparative analysis of the gene expression profiles following these two procedures. CONCLUSIONS: Notably, we established a cryo-injury procedure for the newt and confirmed that regeneration of the cryo-damaged myocardial tissue is achieved by changes in gene expression that are milder than those observed in the amputation model. Our results suggest that the cryo-injury method is suitable for comparing the process of cardiac regeneration in the newt with that in other animal models.