Project description:Wnt/FGF20 signaling axis promotes migration of proximal blastema cell during tail regeneration of Gekko japonicus

Project description:Lizards cannot naturally regenerate limbs but are the closest known relatives of mammals capable of epimorphic tail regrowth. However, the mechanisms regulating lizard blastema derivation and chondrogenesis remain unclear. We utilized single-cell RNA sequencing analyses of regenerating lizard tails throughout the course of regeneration to assess diversity and heterogeneity in regeneating tail cell populations.

Project description:Abstract: Lizards are distinguished as the only amniotes, and closest relatives of mammals, capable of multilineage epimorphic regeneration. Tail blastemas of green anole lizards (Anolis carolinensis) consist of col3a1+ fibroblastic connective tissue cells enclosed in krt5+ wound epidermis (WE), both of which are required for regeneration. Blastema and WE formation are known to be closely associated with phagocytic cell populations, including macrophages and osteoclasts. However, it remains unclear what specific phagocytic cell types are required to stimulate regeneration. Here we explicitly assess the roles of osteoclast activity during blastema and WE formation in regenerating lizard tails. First, probe-sequencing was perfomed at regenerative timepoints on fibroblasts isolated based on col3a1 expression toward establishing pathways involved in stimulating blastema formation and subsequent regeneration. Next, treatments with osteoclast inhibitor zoledronic acid (ZA) was used to assess roles of osteoclast activity in lizard tail regeneration and fibroblast signlaing. ZA treatment stunted lizard tail regrowth, suggesting osteoclast activity was required for blastema formation and regeneration. Transcriptomic profiling of fibroblasts isolated from ZA- treated and control lizards linked inhibition of oseolat activity with limitations in fibroblats to form extracellular matrix and support WE formation. These results suggests that crosstalk between osteoclasts and fibroblasts regulate blastema and WE formation during lizard tail regeneration.

Project description:Mammalian digit-tip can regenerate upon amputation1-3, like amphibians. It is unknown why this capacity is limited to the area associated with the nail3-5. Here, we show that nail stem cells (NSCs) reside in the Wnt-suppressed proximal nail matrix and that the mechanisms governing NSC differentiation are directly coupled with their ability of orchestrating digit regeneration. Early nail progenitors located distal to the NCS region undergo Wnt-dependent differentiation into nail. Upon amputation, this Wnt activation is required for nail regeneration and also for attracting nerves that promote mesenchymal blastema growth, leading to regeneration of the entire digit. Amputations proximal to the Wnt-active nail progenitors result in failure to regenerate nail/digit. Nevertheless, β-catenin stabilization in the NSC region induced their regeneration. These results establish a link between NCS differentiation and digit regeneration, suggesting a utility of the NSCs in developing novel treatments for amputees. Nail matrix cells were harvested from proximal and distal matrix region by microdissection and processed to RNA extraction and hybridization on Affymetrix microarrays. We analyzed two proximal and two distal matrix cells.

Project description:Salamanders are capable of regenerating amputated limbs by generating a mass of lineage-restricted cells called a blastema. Blastemas only generate structures distal to their origin unless treated with retinoic acid (RA), which results in proximodistal (PD) limb duplications. Little is known about the transcriptional network that regulates PD duplication. In this study, we identified expression patterns that explain PD duplication including upregulation of proximal homeobox gene expression and silencing of distal-associated genes whereas limb truncation was associated with disrupted skeletal differentiation. Overall, mechanisms were identified that regulate RAR’s multifaceted roles in the salamander limb including regulation of skeletal patterning during epimorphic regeneration, skeletal tissue differentiation during regeneration, and homeostatic regeneration of intact limbs.

Project description:Innate regeneration following digit tip amputation is one of the few examples of epimorphic regeneration in mammals. Digit tip regeneration is mediated by the blastema, the same structure invoked during limb regeneration in some lower vertebrates. By genetic lineage analyses in mice, the digit tip blastema has been defined as a population of heterogeneous, lineage restructed progenitor cells. These previous studies, however, do not comprehensively evaluate blastema heterogeneity or address lineage restruction of closely related cell types. Here we report single cell RNA sequencing of over 38,000 cells from mouse digit tip blastemas and unamputated control digit tips and generate an atlas of the cell types participating in digit tip regeneration.

Project description:Innate regeneration following digit tip amputation is one of the few examples of epimorphic regeneration in mammals. Digit tip regeneration is mediated by the blastema, the same structure invoked during limb regeneration in some lower vertebrates. By genetic lineage analyses in mice, the digit tip blastema has been defined as a population of heterogeneous, lineage restructed progenitor cells. These previous studies, however, do not comprehensively evaluate blastema heterogeneity or address lineage restruction of closely related cell types. Here we report one additional single cell RNA sequencing sample (28 days post-amputation) to add to our already published 38,000 cells from mouse digit tip blastemas and unamputated control digit tips used to generate an atlas of the cell types participating in digit tip regeneration.

Project description:Epimorphic regeneration is the process by which complete regeneration of a complex structure such as a limb occurs through production of a proliferating blastema. This type of regeneration is rare among vertebrates but does occur in the African clawed frog Xenopus laevis, traditionally a model organism for the study of early development. Xenopus tadpoles can regenerate tails, limb buds and the lens of the eye, although the ability of the latter two organs to regenerate diminishes with advancing developmental stage. Using a heat shock inducible transgene that remains silent unless activated, we have established a stable line of transgenic Xenopus in which the BMP inhibitor Noggin can be over-expressed at any time during development. We have previously shown that activation of this transgene blocks regeneration of the tail and limb of Xenopus tadpoles. In the current study, we have taken advantage of this transgenic line to directly compare gene expression in same stage regenerating vs. non-regenerating hind limb buds. Using Affymetrix gene chip analysis, we have identified genes whose expression levels are linked to regenerative success. These include the BMP inhibitor Gremlin and the stress protein Hsp60 (no blastema in zebrafish). Analysis of overrepresented Gene Ontology functional groupings suggests that successful regeneration in the Xenopus hind limb depends on induction of stress response pathways. Furthermore, as expected, genes involved in embryonic development and growth are also significantly over-represented in regenerating early hind limb buds. Keywords: Differential expression, regeneration

Project description:Using genome-wide transcriptional profiling and whole-mount expression analyses of zebrafish larvae, we have identified hyaluronan synthase 3 (has3) as an upregulated gene during caudal fin regeneration. has3 expression is induced in the wound epithelium within hours after tail amputation, and its onset and maintenance requires fibroblast growth factor, phosphoinositide 3-kinase, and transforming growth factor-β signaling. Inhibition of hyaluronic acid (HA) synthesis by the small molecule 4-methylumbelliferone (4-MU) impaired tail regeneration in zebrafish larvae by preventing injury-induced cell proliferation. In addition, 4-MU reduced the expression of genes associated with wound epithelium and blastema function. Treatment with the glycogen synthase 3-kinase inhibitors rescued 4-MU-induced defects in cell proliferation and tail regeneration, even though only a subset of wound epithelium and blastema markers was restored. Our findings uncover a role for HA biosynthesis in zebrafish tail regeneration and its epistatic relationships with other regenerative processes.

Project description:Mammalian digit-tip can regenerate upon amputation1-3, like amphibians. It is unknown why this capacity is limited to the area associated with the nail3-5. Here, we show that nail stem cells (NSCs) reside in the Wnt-suppressed proximal nail matrix and that the mechanisms governing NSC differentiation are directly coupled with their ability of orchestrating digit regeneration. Early nail progenitors located distal to the NCS region undergo Wnt-dependent differentiation into nail. Upon amputation, this Wnt activation is required for nail regeneration and also for attracting nerves that promote mesenchymal blastema growth, leading to regeneration of the entire digit. Amputations proximal to the Wnt-active nail progenitors result in failure to regenerate nail/digit. Nevertheless, β-catenin stabilization in the NSC region induced their regeneration. These results establish a link between NCS differentiation and digit regeneration, suggesting a utility of the NSCs in developing novel treatments for amputees.