Project description:The purpose of this experiment is to understand which transcripts are differentially expressed following exposure to TCDD. We used microarrays to understand global changes in gene signal intensity Adult zebrafish (danio rerio) were injected (i.p) to vehicle control or TCDD (70 ng/g) one day prior to heart ventricle amputation. A subset of fish were exposed but the hearts were not amputated. Amputated hearts were collected at 6 hours post amputation and 7 days post amputation and processed for microarray analysis

Project description:Illumina short-read sequencing of rRNA-depleted RNA composite sample: A single composite sample generated from a mixture of 8 time points (0, 1, 3, 6, 9, 12, 24, 48 hours post-amputation) plus one non-regenerating sample, representing WT specimens. PacBio Iso-Seq long-read sequencing of rRNA-depleted RNA from amputated WT S. mediterranea at 0 hpa. A single sample from WT worms at 0 hours post-amputation with rRNA depletion applied prior to library preparation.

Project description:Variability of regenerative potential among animals has long perplexed biologists. Based on their amazing regenerative abilities, planarians have become important models for understanding the molecular basis of regeneration; however, planarian species with limited regenerative abilities are also found. Despite the importance of understanding the differences between closely related, regenerating and non-regenerating organisms, few studies have focused on the evolutionary loss of regeneration, and the molecular mechanisms leading to such regenerative loss remain obscure. Here we examine Procotyla fluviatilis, a planarian with restricted ability to replace missing tissues, utilizing next-generation sequencing to define the gene expression programs active in regeneration-permissive and regeneration-deficient tissues. We found that Wnt signaling is aberrantly activated in regeneration-deficient tissues. Remarkably, down-regulation of canonical Wnt signaling in regeneration-deficient regions restores regenerative abilities: blastemas form and new heads regenerate in tissues that normally never regenerate. This work reveals that manipulating a single signaling pathway can reverse the evolutionary loss of regenerative potential. RNA-seq experiments to identify gene expression changes following amputation in body regions with variable regenerative potential. Adult Procotyla fluviatilis were amputated at sites either anterior or posterior to the pharynx. After 24 hours post-amputation, tissues near the amputation site were excised and RNA was extracted. Similar tissues were excised from uncut control animals. Samples were processed for RNA-seq using Illumina procedures. We generated a de novo P. fluviatilis transcriptome and used RNA sequencing (RNA-seq) to characterize transcripts from excised tissue fragments in Reg+ and Reg- body regions 24 hours post-amputation. We performed parallel analyses on tissues excised from intact animals at identical body regions to account for regional differences in transcripts, thereby identifying changes resulting from amputation. Samples A1-A3 = Regeneration-proficient (Reg+) tissue excision 24 hours after amputation. Samples B1-B3 = Tissue excision from regeneration-proficient (Reg+) region but not amputated. Samples C1-C3 = Tissue excision from regeneration-deficient (Reg-) tissues 24 hours after amputation. Samples D1, D3-D4 = Tissue excision from regeneration-deficient (Reg-) region that was not amputated.

Project description:The tails of stage NF50 Xenopus tropicalis were amputated and samples were collected at 0, 1 and 3 days post amputation. About 20 spinal cords were isolated manually and pooled for each sample. in biological triplicates at each time point.

Project description:The tails of stage NF50 Xenopus tropicalis tadpoles were amputated and samples were collected at 0 and 3 days post amputation. 10 spinal cords were isolated for each time point. After cell dissociation, single cell RNAseq was performed using 10X Genomics platform

Project description:Tail amputation by tail docking or as an extreme consequence of tail biting in commercial pig production has serious implications for animal welfare. Tail amputation causes peripheral nerve injury that might be associated with chronic lasting pain. The aim of this study was to investigate the short- and long-term effects of tail amputation in pigs on caudal DRG gene expression at different stages of development, particularly in relation to genes associated with nociception and pain. Microarray analysis was used to analyse whole DRG transcriptomes from tail amputated and sham-treated pigs 1, 8 and 16 weeks following tail treatment at either 3 or 63 days of age (8 pigs/treatment/age/time after treatment; n=96). Tail amputation induced marked changes in gene expression (up and down) compared to sham-treated intact controls for all treatment ages and time points after tail treatment. Sustained changes in gene expression in tail amputated pigs were still evident approximately 4 months after tail injury. Gene correlation network analysis revealed two gene coexpression clusters associated with amputation. Gene ontology (GO) enrichment analysis found the genes in Cluster A (124 genes) and Cluster B (61 genes) to be associated with both ‘inflammatory pain’ and ‘neuropathic pain ’. Key families of ion channels and receptors were significantly down-regulated compared to shams in Cluster A, in particular voltage-gated potassium channels and GABA receptors which are both linked to increased peripheral nerve excitability after axotomy. Up-regulated functional gene families in Cluster B were linked to transcription regulation, inflammation, tissue remodelling and regulatory neuropeptide activity. DRG gene expression profiles appear to reflect sustained tissue inflammation and repair (ca. 4 months) and pain signal modulation consistent with adaptive, compensatory responses linked to injury induced increases in peripheral somatosensory neuronal excitability in the tail stump. Tail amputation causes acute and sustained changes in peripheral somatosensory nerve function involving key mediators of inflammatory and neuropathic pain which have implications for long-term tail stump pain. The findings of this study may have ramifications for the effects of tail amputation in other species. We used microarray to investigate the effects of tail amputation on gene expression in the dorsal root ganglia of caudal nerves in pigs at 2 treatment ages and 3 time points after tail treatment

Project description:Adult zebrafish can completely regenerate their caudal fin following amputation. This complex process is initiated by the formation of an epithelial would cap over the amputation site by 12 hours post amputation (hpa). Once the cap is formed, mesenchymal cells proliferate and migrate from sites distal to the wound plane and accumulate under the epithelial cap forming the blastemal structure within 48 hpa. Blastemal cells proliferate and differentiate, replacing the amputated tissues, which are populated with angiogenic vessels and innervating nerves during the regenerative outgrowth phase which is completed around 14 days post amputation (dpa). Regenerative outgrowth does not occur in TCDD-exposed zebrafish. To identify the molecular pathways that are perturbed by TCDD exposure, male zebrafish were i.p. injected with 50 ng/g TCDD or vehicle and caudal fins were amputated. Regenerating fin tissue was collected at 1, 3 and 5 dpa for mRNA abundance analysis. Microarray analysis and quantitative real time PCR revealed that wound healing and regeneration alone altered the expression of nearly 900 genes by at least two fold between 1 and 5 dpa. TCDD altered the abundance of 370 genes at least two fold. Among these, several known aryl hydrocarbon responsive genes were identified in addition to several genes involved in extracellular matrix composition and metabolism. The profile of misexpressed genes is suggestive of impaired cellular differentiation and extracellular matrix composition potentially regulated by Sox9b. Experiment Overall Design: Regenerating fins were isolated at 1, 3 and 5 days post amputation. Three replicates were collected at each time point. 10 fins were pooled to comprise one replicate. Fish were dosed at 0 days post amputation with vehicle control alone or 50 ng/g TCDD. Experiment Overall Design: 1 Day Post Amputation Vehicle Exposed: GSM85187, GSM85188, and GSM85189 Experiment Overall Design: 1 Day Post Amputation TCDD Exposed: GSM85190, GSM85191, and GSM85192 Experiment Overall Design: 3 Days Post Amputation Vehicle Exposed: GSM85193, GSM85194, and GSM85195 Experiment Overall Design: 3 Day Post Amputation TCDD Exposed: GSM85196, GSM85197, and GSM85198 Experiment Overall Design: 5 Days Post Amputation Vehicle Exposed: GSM85199, GSM85200, and GSM85201 Experiment Overall Design: 5 Days Post Amputation TCDD Exposed: GSM85202, GSM85203, and GSM85204

Project description:We report global RNA expression profiles from whole zebrafish hearts 24 hours after ventricle amputation. Zebrafish were exposed to atropine or water following surgery. 15 zebrafish hearts were pooled per microarray chip. Amputated hearts of zebrafish exposed to atropine was compared to hearts of zebrafish exposed to water.

Project description:Adult zebrafish can completely regenerate their caudal fin following amputation. This complex process is initiated by the formation of an epithelial would cap over the amputation site by 12 hours post amputation (hpa). Once the cap is formed, mesenchymal cells proliferate and migrate from sites distal to the wound plane and accumulate under the epithelial cap forming the blastemal structure within 48 hpa. Blastemal cells proliferate and differentiate, replacing the amputated tissues, which are populated with angiogenic vessels and innervating nerves during the regenerative outgrowth phase which is completed around 14 days post amputation (dpa). Regenerative outgrowth does not occur in TCDD-exposed zebrafish. To identify the molecular pathways that are perturbed by TCDD exposure, male zebrafish were i.p. injected with 50 ng/g TCDD or vehicle and caudal fins were amputated. Regenerating fin tissue was collected at 1, 3 and 5 dpa for mRNA abundance analysis. Microarray analysis and quantitative real time PCR revealed that wound healing and regeneration alone altered the expression of nearly 900 genes by at least two fold between 1 and 5 dpa. TCDD altered the abundance of 370 genes at least two fold. Among these, several known aryl hydrocarbon responsive genes were identified in addition to several genes involved in extracellular matrix composition and metabolism. The profile of misexpressed genes is suggestive of impaired cellular differentiation and extracellular matrix composition potentially regulated by Sox9b. Keywords: Time course and TCDD exposure response

Project description:Decaying and expanding Erk gradients process memory of skeletal size during zebrafish fin regeneration