Abstract
Zebrafish can regenerate their damaged hearts throughout their lifespan. It is, however, unknown, whether regeneration remains effective when challenged with successive cycles of cardiac damage in the same animals. Here, we assessed ventricular restoration after two, three and six cryoinjuries interspaced by recovery periods. Using transgenic cell-lineage tracing analysis, we demonstrated that the second cryoinjury damages the regenerated area from the preceding injury, validating the experimental approach. We identified that after multiple cryoinjuries, all hearts regrow a thickened myocardium, similarly to hearts after one cryoinjury. However, the efficiency of scar resorption decreased with the number of repeated cryoinjuries. After six cryoinjuries, all examined hearts failed to completely resolve the fibrotic tissue, demonstrating reduced myocardial restoration. This phenotype was associated with enhanced recruitment of neutrophils and decreased cardiomyocyte proliferation and dedifferentiation at the early regenerative phase. Furthermore, we found that each repeated cryoinjury increased the accumulation of collagen at the injury site. Our analysis demonstrates that the cardiac regenerative program can be successfully activated many times, despite a persisting scar in the wounded area. This finding provides a new perspective for regenerative therapies, aiming in stimulation of organ regeneration in the presence of fibrotic tissue in mammalian models and humans.
Highlights
Regenerative response after repeated amputation is the maxillary barbel[12]
Given that the heart does not change its orientation in the body cavity and that the cryoprobe is always inserted from the ventral position, we assumed that the same site of the ventricle would be targeted by each cryoinjury
Our laboratory has previously identified that the careg transgenic reporter is induced in regenerating cardiomyocytes of the peri-injury zone, which gives rise to the new myocardium[22]
Summary
Regenerative response after repeated amputation is the maxillary barbel[12]. These studies suggest that antagonistic signals may accumulate after recurrent injuries, decreasing the efficiency of the subsequent regeneration. The zebrafish provides an outstanding model system for heart regeneration. Whether the zebrafish heart can repeatedly deploy this complex regenerative program after multiple injuries remains unknown. We sought to determine if adult zebrafish are able to restore their myocardium after several cryoinjuries. The hearts of each group were analyzed at 60 days after the last cryoinjury, to allow for terminal remodeling of the wound (Fig. 1). We observed impairment of scar resolution, suggesting reduced efficiency in the replacement of fibrotic tissue with a new myocardium
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
