Project description:Xenopus laevis tadpoles are capable of limb regeneration following amputation, in a process which initially involves the formation of a blastema. However, Xenopus has full regenerative capacity only through premetamorphic stages. We have used the Affymetrix Xenopus laevis Genome Genechip® microarray to perform a large-scale screen of gene expression in the regeneration-complete, stage 53 (st53), and regeneration-incomplete, stage 57 (st57), hindlimbs at 1 and 5 days post-amputation. Through an exhaustive reannotation of the Genechip® and a variety of comparative bioinformatic analyses, we have identified genes that are differentially expressed between the regeneration-complete and –incomplete stages, detected the transcriptional changes associated with the regenerating blastema, and compared these results with those of other regeneration researchers. We focus particular attention on striking transcriptional activity observed in genes associated with patterning, stress response, and inflammation. Overall, this work provides the most comprehensive views yet of a regenerating limb and different transcriptional compositions of regeneration-competent and deficient tissues. Experiment Overall Design: This experiment measures gene expression in regeneration competent stage 53 and regeneration non-competent stage 57 Xenopus laevis hindlimbs, at 1 and 5 days post-amputation. Four replicates for each condition were used. Hindlimbs at either st53 or st57 were amputated unilaterally or bilaterally at the mid-zeugopodia level. One (1dPA) and 5 days (5dPA) after amputation tissues were collected 1mm proximal to the original level of amputation. Total RNA was isolated using RNaqueous micro kit (Ambion, inc.). One microgram of total RNA was amplified with the the Affymetrix 2 cycle kit and assayed per Genechip using standard Affymetrix protocols.

Project description:Zebrafish caudal fin regeneration is an established model to study tissue regeneration. In order to identify novel molecular signaling pathways critical for regeneration, we developed a rapid throughput in vivo regeneration assay. We screened a 2000 member structurally diverse small molecule library, followed by assessment of regenerative progression at three days post amputation. A cluster of glucocorticoids was identified among the “positive hits”. To identify the molecular targets of the activated glucocorticoid receptor, microarray analysis was performed using RNA isolated from the regenerates of control and glucocorticoid exposed zebrafish. We identified 673 transcripts that were differentially regulated. The level of expression and spatial expression pattern of select genes were completed by qPCR and by in situ hybridization, respectively. Altogether, these studies demonstrate the power of chemical genetics to identify chemical probes and their targets which will provide a path towards defining conserved regenerative pathways. Experiment Overall Design: The caudal fin of zebrafish larvae at 2days post fertilization were amputated and exposed to vehicle control alone or Beclomethasone . Regenerating fins were isolated at 1days post amputation. Three replicates were collected at each time point. 150 fins were pooled to comprise one replicate.

Project description:Zebrafish have the remarkable ability to regenerate body parts including the heart, spinal cord and fins by a process referred to as epimorphic regeneration. Recent studies have illustrated that similar to adult zebrafish, early life stage-larvae also possess the ability to regenerate the caudal fin. A comparative genomic analysis was used to determine the degree of conservation in gene expression among the regenerating adult caudal fin, adult heart and larval fin. Results indicate that these tissues respond to amputation/injury with strikingly similar genomic responses. Comparative analysis revealed raldh2, a rate-limiting enzyme for the synthesis of Retinoic acid (RA), as one of the highly induced genes across the three regeneration platforms. Experiment Overall Design: The caudal fin of zebrafish larvae at 2days post fertilization were amputated. Caudal fin tissue at 2dpf and regenerating fins were isolated at 1, 2and 3 days post amputation. Three replicates were collected at each time point. 150 fins were pooled to comprise one replicate.

Project description:Xenopus laevis tadpoles are capable of limb regeneration following amputation, in a process which initially involves the formation of a blastema. However, Xenopus has full regenerative capacity only through premetamorphic stages. We have used the Affymetrix Xenopus laevis Genome Genechip® microarray to perform a large-scale screen of gene expression in the regeneration-complete, stage 53 (st53), and regeneration-incomplete, stage 57 (st57), hindlimbs at 1 and 5 days post-amputation. Through an exhaustive reannotation of the Genechip® and a variety of comparative bioinformatic analyses, we have identified genes that are differentially expressed between the regeneration-complete and –incomplete stages, detected the transcriptional changes associated with the regenerating blastema, and compared these results with those of other regeneration researchers. We focus particular attention on striking transcriptional activity observed in genes associated with patterning, stress response, and inflammation. Overall, this work provides the most comprehensive views yet of a regenerating limb and different transcriptional compositions of regeneration-competent and deficient tissues. Keywords: Expression profiling

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:We used Nimblegen arrays with design 2007-11-06_Smed_ESTs_4_exp to measure changes in gene expression during a timecourse of regeneration of one side of the head in Schmidtea mediterranea flatworms. Following amputation of one side of the head, samples were collected from both the regeneration blastema and non-regenerating side of the head on days 2, 3, and 4 post-amputation. Gene expression in these samples was compared to that in non-regenerating control samples collected at the time of amputation.

Project description:We compared transcriptional profiles of regenerating zebrafish caudal fins following fin amputation with profiles from uninjured zebrafish caudal fins

Project description:Regenerating limbs retain their proximodistal (PD) positional identity following amputation. This positional identity is encoded genetically by PD patterning genes, which instruct blastema cells to regenerate the appropriate PD limb segment. Retinoic acid (RA) is known to specify proximal limb identity, but how RA concentration is established in the blastema is unknown. Here, we show that RA breakdown via CYP26B1 is essential for determining the RA concentration within blastemas. CYP26B1 inhibition molecularly reprograms distal blastemas into a proximal identity, phenocopying the effects of administering excess RA. We identify Shox as an RA responsive gene that is differentially expressed between proximally and distally amputated blastemas. Ablation of Shox results in shortened limbs with proximal skeletal elements that fail to undergo endochondral ossification. These results suggest that PD positional identity is determined by RA degradation and that targets of RA have a critical role in skeletal element formation during limb regeneration.

Project description:The distal mouse digit tip undergoes complex tissue regeneration following amputation, a process facilitated by the formation of a cellular structure called the blastema. Through single-cell RNA sequencing of the blastema, we identified the gene Mest (mesoderm specific transcript) highly expressed in a subset of blastemal fibroblasts. To determine if Mest expression is necessary for mouse digit tip regeneration, we analyzed Mest wildtype (WT) versus homozygous knockout (KO) post amputation digits. Through single-cell sequencing and FACS analysis of WT and KO regenerating tissues, we determined that this phenomenon was due to a prolonged immune response in the KO digits.

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