Project description:Axolotl limb regeneration proceeds through the formation of a blastema, a mound of progenitor cells that accumulate at the end of the amputated stump. These progenitor cells expand and later undergo patterning to regenerate the missing limb, restoring both form and function. A subset of cells within the blastema become senescent, a state of permanent growth arrest. Here, we address the functional relevance of cellular senescence to axolotl limb regeneration, through a combination of gain- and loss-of-function assays. Using transcriptomic analyses on in vitro and in vivo senescent cells, we gain insights into the basis of the senescent phenotype, cell-cycle arrest, and molecular mediators involved in axolotl regeneration at the molecular level.

Project description:Axolotl limb regeneration proceeds through the formation of a blastema, a mound of progenitor cells that accumulate at the end of the amputated stump. These progenitor cells expand and later undergo patterning to regenerate the missing limb, restoring both form and function. A subset of cells within the blastema become senescent, a state of permanent growth arrest. Here, we address the functional relevance of cellular senescence to axolotl limb regeneration, through a combination of gain- and loss-of-function assays. Using transcriptomic analyses on in vitro and in vivo senescent cells, we gain insights into the basis of the senescent phenotype, cell-cycle arrest, and molecular mediators involved in axolotl regeneration at the molecular level.

Project description:Identifying the genetic program that induces limb regeneration in salamanders is an important resource for regenerative medicine, which currently lacks tools to promote regeneration of functional body structures. The genetic network underlying limb regeneration has been elusive due to the complexity of the injury response that occurs concomitant to blastema formation. Here we performed parallel expression profile time courses of non-regenerative lateral wounds versus amputated limbs in axolotl. We show that limb regeneration occurs in three distinguishable phases--early wound healing followed by a transition phase leading to establishment of the limb development program. By focusing on the transition phase, we identified 93 strictly regeneration-associated genes involved in oxidative stress response, chromatin modification, epithelial development and limb development. The specific expression of the genes was confirmed by in situ hybridization. Regeneration-specific expression databases are critical resources for understanding how regeneration-relevant phenotypes can be induced from adult cells Regeneration of the axolotl forelimb lower arm was compared with the healing of a deep lateral injury in a high density timecourse (uncut, 3h, 6h, 9h, 12h, 24h, 36h, 52h, 72h, 120h, 168h, 288h and 528h after injury). Three independent biological replicates were performed using separate cluches of animals. Amputated and lateral wound samples were made as matched contralateral samples of four pooled animals per timepoint.

Project description:Blastema formation is a hallmark of limb regeneration that requires proliferation and migration of progenitors derived from many tissues to the amputation plane. To better understand the genetic programs that initiate limb regeneration, we reasoned that blastemal progenitors would be among early proliferating cells in the stump following amputation. Here we separately profiled dividing and non-dividing stump tissues, as well as the wound epidermis, during early axolotl limb regeneration to examine transcriptional programs of blastemal progenitors. We provide a description of the changes in gene expression specific to early dividing cells at the site of amputation, inclusive of progenitors for the regenerating limb. This work collectively demonstrates differential suppression/activation of core developmental signaling pathways in subsets of the early regenerating limb and further suggests that interleukin-8 (il-8) signaling is important for regeneration.

Project description:Identifying the genetic program that induces limb regeneration in salamanders is an important resource for regenerative medicine, which currently lacks tools to promote regeneration of functional body structures. The genetic network underlying limb regeneration has been elusive due to the complexity of the injury response that occurs concomitant to blastema formation. Here we performed parallel expression profile time courses of non-regenerative lateral wounds versus amputated limbs in axolotl. We show that limb regeneration occurs in three distinguishable phases--early wound healing followed by a transition phase leading to establishment of the limb development program. By focusing on the transition phase, we identified 93 strictly regeneration-associated genes involved in oxidative stress response, chromatin modification, epithelial development and limb development. The specific expression of the genes was confirmed by in situ hybridization. Regeneration-specific expression databases are critical resources for understanding how regeneration-relevant phenotypes can be induced from adult cells

Project description:Regeneration of complex multi-tissue structures, such as limbs, requires the coordinated effort of multiple cell types. In axolotl limb regeneration, the wound epidermis and blastema have been extensively studied via histology, grafting, and bulk-tissue RNA-sequencing. However, studying the contributions of these tissues is hindered due to limited information regarding the molecular identity of the cell types in regenerating limbs. By performing unbiased single-cell RNA-sequencing on over 25,000 cells from axolotl limbs, we identify a plethora of cellular diversity within epidermal, mesenchymal, and hematopoietic lineages in homeostatic and regenerating limbs. We identify regeneration-induced genes, develop putative trajectories for blastema cell differentiation, and propose the molecular identity and origin of fibroblast-derived blastema progenitor cells residing in homeostatic limbs. This work will enable application of molecular techniques to assess the contribution of these populations to limb regeneration. It will also facilitate work aimed at identifying transcripts and cells critical for limb regeneration.

Project description:The salamander has the remarkable ability to regenerate its limb after amputation. Cells at the site of amputation form a blastema and then proliferate and differentiate to regrow the limb. To better understand this process, we have performed deep RNA sequencing of the blastema over a time course. We find genes expressed in three phases with a prominent burst in oncogene expression during the first day, blastemal/limb bud genes peaking at 7 to 14 days, and markers for terminal differentiation upregulated later. We compare these expression patterns to those in a mouse digit amputation model to identify genes specific to the regenerative response. We find that limb patterning genes, SALL genes, and genes involved in the proteasome, adult stem cell, embryonic stem cell, retinoid metabolism, and WNT and NOTCH signaling are regeneration-specific. We establish the “Axolomics” Database, which provides a tool for depositing, retrieving, and searching axolotl-related “omic” information. The experiment includes two time course data sets. One is from mouse digit amputation, another is from Axolotl digit amputation

Project description:Limb regeneration, while observed lifelong in salamanders, is restricted to pre-metamorphic stages in Xenopus laevis frogs. After amputation, post-metamorphic frogs form a blastema that grows only an unsegmented cartilage rod. Whether this loss is due to systemic factors such as the immune system or due to an intrinsic incapability of cells to form competent stem cells has been unclear. Here, we use genetic fate mapping to establish that, as in axolotl, connective tissue (CT) cells form the post-metamorphic frog blastema. Using heterochronic transplantation into the limb bud and single-cell transcriptomic profiling, we show that axolotl CT cells fully dedifferentiate and integrate to form lineages including cartilage in the developing limb. In contrast, frog blastema CT cells do not fully re-express the limb bud progenitor program, even when transplanted into the limb bud. Correspondingly, transplanted cells contribute to extraskeletal CT but not to developing cartilage. Further, using single-cell RNA-seq analysis we find that the embryonic and the adult frog cartilage differentiation programs are molecularly distinct. This work defines intrinsic restrictions in CT dedifferentiation as a limitation in adult regeneration.

Project description:Salamander limb regeneration is dependent upon tissue interactions that are local to the amputation site. Communication among limb epidermis, peripheral nerves, and mesenchyme coordinate cell migration, cell proliferation, and tissue patterning to generate a blastema, a mass of progenitor cells that forms missing limb structures. An outstanding question is how molecular cross-talk between these tissues gives rise to the regeneration blastema. To identify genes associated with epidermis-nerve-mesenchymal interactions during limb regeneration, we examined histological and transcriptional changes during the first week following injury in the wound epidermis and subjacent cells between three injury types; 1) a flank wound on the side of the animal that will not regenerate a limb, 2) a denervated limb that will not regenerate a limb, and 3) an innervated limb that will regenerate a limb. Early, histological and transcriptional changes were highly similar between the three injury types, presumably because a common wound-healing program is employed across anatomical locations. However, we identified transcripts that were enriched in the limb compared to the flank and are associated with vertebrate limb development. Many of these genes were activated before blastema outgrowth and in situ hybridization showed that some of these genes were expressed in specific tissue types including the epidermis, peripheral nerve, and mesenchyme. We also identified a relatively small group of transcripts that were more highly expressed in innervated limbs versus denervated limbs. These transcripts encode for proteins that are associated with myelination of peripheral nerves, epidermal maintenance, and cell proliferation, suggesting that denervation affects myelinating Schwann cells, epidermal cell function, and proliferation of mesenchymal cells. Overall, our study identifies limb-specific and nerve-dependent genes that are upstream of regenerative growth, and thus promising candidates for the regulation of blastema formation. We used microarray analysis to determine the gene expression changes that take place during limb regeneration, flank wound healing, and an denervated amputated limb. Epidermal tissue and cells adhered to the epidermis were collected as samples. Two harvested samples was pooled for each animal. Four biological replicates were collected from uninjured epidermis (D0) and at 1, 3, and 7 days post injury.

Project description:Amputation of the axolotl forelimb results in the formation of a blastema, a transient tissue where progenitor cells accumulate prior to limb regeneration. Connective tissue (CT) – skeleton, periskeleton, tendon, dermis, interstitial cells – contributes the vast majority of cells that populate the blastema, however it is unclear how individual CT cells may reprogram their fate in order to rebuild the tetrapod limb. Here we use a combination of Cre-loxP reporter lineage tracking and single-cell (sc) RNA-seq to molecularly track, for the first time, adult CT cell heterogeneity and its transition to a limb blastema state. We uncover a multi-phasic molecular program where CT cell types found in the uninjured adult limb revert to a relatively homogenous progenitor state that participates in inflammation and extracellular matrix disassembly prior to proliferation, establishment of positional information, and ultimately re-differentiation. While the early regeneration transcriptome states are unique to the blastema, the later stages recapitulate embryonic limb development. Notably, we do not find evidence of a pre-existing blastema-like precursor nor limb bud-like progenitors in the uninjured adult tissue. However, we find that distinct CT subpopulations in the adult limb differentially contribute to proximal and distal portions of the regenerated limb. Together, our data illuminates molecular and cellular reprogramming during complex organ regeneration in a vertebrate.