Molecular Characterization of Early Dedifferentiation in Newt Forelimb Regeneration

Abstract

Newts have the incredible ability to regenerate many different organs and tissues as adults, including the limbs. Limb regeneration occurs via the dedifferentiation of stump tissue and the formation of a blastema, which provides the majority of cells for the regenerate. Despite all that we have learned about dedifferentiation and blastema formation, the cellular and molecular mechanisms underlying these processes are still poorly understood. We used representational difference analysis (RDA) to identify genes involved in the early dedifferentiation process in newt forelimb regeneration. Our analysis identified approximately 410 unique genes that were differentially regulated during this process. Microarray analysis was used to determine the expression profile of these genes throughout limb and tail regeneration. We used quantitative PCR (qPCR) to validate the expression of a subset of these genes [β-catenin, wntless, dapper, thymosin-β 4 (Tβ4), and thymosin-β 10/15 (Tβ10/15)] in regenerating limb and tail tissue, as well as in differentiating newt myoblasts. We also verified the expression of these genes in the regenerating newt limb using immunohistochemistry (IHC) and in situ hybridization (ISH). Finally, we performed a functional analysis on β-catenin, wntless, dapper, and Tβ4 by overexpressing these genes in mouse myoblasts to examine their effects on differentiation and potential roles in dedifferentiation. Quantitative PCR verified the expression of β-catenin, wntless, dapper, and Tβ4 during limb regeneration and IHC/ISH localized the β-catenin and Tβ4 proteins to the blastema during regeneration. Tβ10/15 was shown by qPCR to be expressed in the tail during regeneration. Overexpression of newt β-catenin, wntless, dapper, and Tβ4 in mouse myoblasts showed that each of these genes has an inhibitory effect on the differentiation of myoblasts into myotubes and, therefore, may play a role in promoting or maintaining the dedifferentiated state. Our work has identified a large number of genes with potential roles in regulating the dedifferentiation process during newt forelimb regeneration. We have also laid a framework from which much more work can be done by drawing on the genes we have identified and the microarray data, which indicate ideal follow-up candidates. Our analysis of specific genes has also increased our understanding of the molecular events occurring during the dedifferentiation process in the regenerating newt limb.