Project description:Comparative studies of vertebrate appendages offer a powerful framework for uncovering shared components of an ancestral regeneration toolkit. Here, we employed a multi-omics comparative approach leveraging the regenerative capacity of the axolotl, zebrafish, and Polypterus senegalus, a fish capable of full fin regeneration. We identified conserved markers of proximal and distal blastema territories, shared activation of DNA damage repair, hif1a-mediated hypoxia response, and sequential activation of pro- and anti-inflammatory program. Apical epithelial ridge markers were expressed in both the wound epidermis and distal mesenchyme during limb and fin regeneration. Notably, hif4a-expressing erythrocytes were uniquely associated with proximal limb and fin amputations but not fin rays, while epidermal myoglobin expression was upregulated only in Polypterus and zebrafish fins. Genome-wide chromatin profiling identified candidate regeneration-responsive elements and a conserved enrichment for AP-1 transcription factor binding. Together, these finding identify shared and derived mechanisms of limb and fin regeneration.

Project description:Comparative studies of vertebrate appendages offer a powerful framework for uncovering shared components of an ancestral regeneration toolkit. Here, we employed a multi-omics comparative approach leveraging the regenerative capacity of the axolotl, zebrafish, and Polypterus senegalus, a fish capable of full fin regeneration. We identified conserved markers of proximal and distal blastema territories, shared activation of DNA damage repair, hif1a-mediated hypoxia response, and sequential activation of pro- and anti-inflammatory program. Apical epithelial ridge markers were expressed in both the wound epidermis and distal mesenchyme during limb and fin regeneration. Notably, hif4a-expressing erythrocytes were uniquely associated with proximal limb and fin amputations but not fin rays, while epidermal myoglobin expression was upregulated only in Polypterus and zebrafish fins. Genome-wide chromatin profiling identified candidate regeneration-responsive elements and a conserved enrichment for AP-1 transcription factor binding. Together, these finding identify shared and derived mechanisms of limb and fin regeneration.

Project description:Comparative studies of vertebrate appendages offer a powerful framework for uncovering shared components of an ancestral regeneration toolkit. Here, we employed a multi-omics comparative approach leveraging the regenerative capacity of the axolotl, zebrafish, and Polypterus senegalus, a fish capable of full fin regeneration. We identified conserved markers of proximal and distal blastema territories, shared activation of DNA damage repair, hif1a-mediated hypoxia response, and sequential activation of pro- and anti-inflammatory program. Apical epithelial ridge markers were expressed in both the wound epidermis and distal mesenchyme during limb and fin regeneration. Notably, hif4a-expressing erythrocytes were uniquely associated with proximal limb and fin amputations but not fin rays, while epidermal myoglobin expression was upregulated only in Polypterus and zebrafish fins. Genome-wide chromatin profiling identified candidate regeneration-responsive elements and a conserved enrichment for AP-1 transcription factor binding. Together, these finding identify shared and derived mechanisms of limb and fin regeneration.

Project description:Comparative studies of vertebrate appendages offer a powerful framework for uncovering shared components of an ancestral regeneration toolkit. Here, we employed a multi-omics comparative approach leveraging the regenerative capacity of the axolotl, zebrafish, and Polypterus senegalus, a fish capable of full fin regeneration. We identified conserved markers of proximal and distal blastema territories, shared activation of DNA damage repair, hif1a-mediated hypoxia response, and sequential activation of pro- and anti-inflammatory program. Apical epithelial ridge markers were expressed in both the wound epidermis and distal mesenchyme during limb and fin regeneration. Notably, hif4a-expressing erythrocytes were uniquely associated with proximal limb and fin amputations but not fin rays, while epidermal myoglobin expression was upregulated only in Polypterus and zebrafish fins. Genome-wide chromatin profiling identified candidate regeneration-responsive elements and a conserved enrichment for AP-1 transcription factor binding. Together, these finding identify shared and derived mechanisms of limb and fin regeneration.

Project description:Previous studies of vertebrate appendage regeneration have shown that multiple genetic programs are moduled through regulatory factors. MicroRNAs are short highly conserved non-coding genes that suppress expression of target genes and thereby control multiple genetic programs. Given their important regulatory roles and evolutionary conservation, we hypothesize that microRNAs define a conserved genetic regulatory circuit important for appendage regeneration. We characterized microRNA expression during Polypterus senegalus (bichir) pectoral fin regeneration using small RNA sequencing. The same samples were assayed for mRNA expression using mRNA sequencing. Small RNA and mRNA gene expression profiling during 0, 3, 7 and 14 days post amputation.

Project description:Previous studies of vertebrate appendage regeneration have shown that multiple genetic programs are moduled through regulatory factors. MicroRNAs are short highly conserved non-coding genes that suppress expression of target genes and thereby control multiple genetic programs. Given their important regulatory roles and evolutionary conservation, we hypothesize that microRNAs define a conserved genetic regulatory circuit important for appendage regeneration. We characterized microRNA expression during Polypterus senegalus (bichir) pectoral fin regeneration using small RNA sequencing. The same samples were assayed for mRNA expression using mRNA sequencing.

Project description:The goal of this experiment is to test the hypothesis that hypothyroid zebrafish caudal fin possess proximalized gene expression profile. Transcriptome data was generated for proximal, middle and distal adult fin tissue of hypothyroid zebrafish, with euthyroid sibling fish as control.

Project description:Small RNA and mRNA expression profiling during Polypterus senegalus (bichir) pectoral fin regeneration

Project description:Mammalian genomes likely encode all gene products required to regenerate an amputated limb, yet they lack the correct instructions for strategically modulating those gene products to accomplish limb regeneration. Zebrafish and many other non-mammalian vertebrates possess these instructions, which exist as gene cis-regulatory elements. Here, to identify candidate tissue regeneration enhancer elements (TREEs) important for zebrafish fin regeneration, we performed ATAC-seq from bulk tissue or purified fibroblasts of uninjured and regenerating caudal fins. We identified thousands of DNA regions from each tissue type with dynamic accessibility during regeneration, and assigned these regions to proximal genes with corresponding changes in RNA levels. To determine whether these profiles revealed bona fide TREEs, we tested the sufficiency of several sequences in stable transgenic and mutant lines. These experiments identified new regulatory sequences near several induced and/or required genes, including fgf20a, cx43, and mdka, with unique expression domains for each confirmed TREE. Deletion of TREE sequences from the zebrafish genome revealed requirements and redundancies surrounding cis-regulatory regions. Our study generates a novel resource for dissecting the regulatory mechanisms of appendage regeneration.

Project description:Regenerating zebrafish fins have distal progenitor and proximal re-differentiation zones. A Wnt-producing "niche" population maintains distal cells in progenitor states. We sought to define molecular markers of niche cells to study their origins and fates and how they contribute to fin size and shape restoration.