Project description:The Mexican axolotl provides a powerful model to investigate mechanisms of tissue regeneration. A recent chemical screen found that HDAC inhibitor romidepsin, administered for only 1-minute post amputation (1 MPA), blocks axolotl tail regeneration. Here, we tested the potential for cobalt chloride (CoCl2), a chemical stabilizer of HIF1a and inducer of hypoxia, to rescue romidepsin-inhibition of tail regeneration. Tail regeneration was partially rescued when embryos with amputated tails were co-treated with romidepsin and CoCl2. However, extending the CoCl2 dosage window either inhibited regeneration (CoCl2:0-30 MPA) or was lethal (CoCl2:0-24 hours post amputation; HPA). CoCl2:0-30 MPA caused tissue damage, tissue loss, and cell death at the distal tail tip, and blocked regeneration. In contrast, CoCl2 treatment of non-amputated embryos or CoCl2:60-90 MPA treatment of amputated embryos did not affect wound healing or inhibit tail regeneration. To further investigate the contrasting effects of CoCl2, microarray analysis was performed to identify differentially expressed genes at 3 HPA. CoCl2-romidepsin:1 MPA treatment significantly increased the expression of transcription factors associated with appendage regeneration, while CoCl2:0-30 MPA significantly increased expression of hemoglobin and platelet-specific transcripts, consistent with hemorrhage and an impaired hemostatic response. Also, CoCl2:0-30 MPA significantly increased expression of hypoxia inducible genes, including genes that encode Hif1a interacting proteins and heat shock proteins (HSP); in contrast, genes encoding TGFB signaling components were significantly downregulated. Using additional chemical inhibitors of tail regeneration, we identified transcriptional responses associated with HSP90 activity and TGFB signaling. Notably, geldanamcin decreased transcription of matrix metalloproteinases and sustained muscle-specific gene expression, suggesting a role for HSP90 in regulating extracellular matrix remodeling and muscle dedifferentiation. Our study shows the power of using chemical tools to precisely identify temporal windows within which critical biological processes are enacted during tissue regeneration.

Project description:Transcriptome studies are revealing the complex gene expression basis of limb regeneration in the primary salamander model – Ambystoma mexicanum (axolotl). To better understand this complexity, there is need to extend analyses to additional salamander species. Using microarray and RNA-Seq, we performed a comparative transcriptomic study using A. mexicanum and two other ambystomatid salamanders: A. andersoni, and A. maculatum. Salamanders were administered forelimb amputations and RNA was isolated and analyzed to identify 405 non-redundant genes that were commonly, differentially expressed 24 hours post amputation. Many of the upregulated genes are predicted to function in wound healing and developmental processes, while many of the downregulated genes are typically expressed in muscle. The conserved transcriptional changes identified in this study provide a high-confidence dataset for identifying factors that simultaneous orchestrate wound healing and regeneration processes in response to injury, and more generally for identifying genes that are essential for salamander limb regeneration.

Project description:Transcriptome studies are revealing the complex gene expression basis of limb regeneration in the primary salamander model – Ambystoma mexicanum (axolotl). To better understand this complexity, there is need to extend analyses to additional salamander species. Using microarray and RNA-Seq, we performed a comparative transcriptomic study using A. mexicanum and two other ambystomatid salamanders: A. andersoni, and A. maculatum. Salamanders were administered forelimb amputations and RNA was isolated and analyzed to identify 405 non-redundant genes that were commonly, differentially expressed 24 hours post amputation. Many of the upregulated genes are predicted to function in wound healing and developmental processes, while many of the downregulated genes are typically expressed in muscle. The conserved transcriptional changes identified in this study provide a high-confidence dataset for identifying factors that simultaneous orchestrate wound healing and regeneration processes in response to injury, and more generally for identifying genes that are essential for salamander limb regeneration.

Project description:The Mexican axolotl (Ambystoma mexicanum) is one member of a select group of vertebrate animals that has retained the amazing ability to regenerate multiple body parts. In addition to being an important model system for regeneration, the axolotl is also a leading model system for developmental biologists. Many genes used in development have been identified to be reused again during regeneration, however how this molecular circuitry is controlled during regeneration is unknown. In recent years microRNAs have been identified as key regulators of gene expression during development, in many diseases and also in regeneration. Here we have used deep sequencing combined with qRT-PCR to identify microRNAs that are involved in regulating regeneration in axolotl. This approach has enabled us to identify well known families of microRNAs and in addition to identify putative novel microRNAs that differentially regulated in the regenerating tissue. These findings suggest that microRNAs may play key roles in managing the spatial and temporal expression of genes important for ensuring that the correct tissues are regenerated. small RNA Sequencing (2 samples) in Ambystoma Mexicanum

Project description:Ambystoma mexicanum regeneration map

Project description:X1 neoblasts (G2/S/M cells) were isolated by FACS from injury site-proximal tissue in a timeseries during head (anterior) and tail (posterior) regeneration in Schmidtea mediterranea 24 samples: 2 treatments (head versus tail regeneration), 3 timepoints (0,24,48,72 hours post amputation), 3 biological replicates each condition

Project description:Ambystoma mexicanum brain regeneration time-course

Project description:Ambystoma mexicanum

Project description:Ambystoma Mexicanum

Project description:In contrast to humans, many amphibians are able to rapidly and completely regenerate complex tissues, including complete appendages. Following tail amputation, Xenopus tropicalis tadpoles quickly regenerate muscle, spinal cord, cartilage, vasculature and skin, all properly patterned in three dimensions. To better understand the molecular basis of this regenerative competence, we performed a transcriptional analysis of regeneration using RNA-Seq. We profiled the transcriptome at 6 timepoints during tail regeneration, and used clustering analysis to identify biological processes that are prioritized during different transitions in the regeneration process. Our work expands significantly on previous expression analyses of tail regeneration. We are able to refine the windows during which many key biological signaling processes act, including embryonic patterning signals, immune responses, bioelectrical signaling and apoptosis. By including multiple timepoints within the first 24 hours post-amputation, we have also identified new processes that are highly prioritized early in regeneration, including axonogenesis, chemotaxis, and RNA metabolism. Our work provides a deep database for researchers interested in appendage regeneration, and highlights new avenues for further study.