Abstract
BackgroundSalamanders are unique among vertebrates in their ability to completely regenerate amputated limbs through the mediation of blastema cells located at the stump ends. This regeneration is nerve-dependent because blastema formation and regeneration does not occur after limb denervation. To obtain the genomic information of blastema tissues, de novo transcriptomes from both blastema tissues and denervated stump ends of Ambystoma mexicanum (axolotls) 14 days post-amputation were sequenced and compared using Solexa DNA sequencing.ResultsThe sequencing done for this study produced 40,688,892 reads that were assembled into 307,345 transcribed sequences. The N50 of transcribed sequence length was 562 bases. A similarity search with known proteins identified 39,200 different genes to be expressed during limb regeneration with a cut-off E-value exceeding 10-5. We annotated assembled sequences by using gene descriptions, gene ontology, and clusters of orthologous group terms. Targeted searches using these annotations showed that the majority of the genes were in the categories of essential metabolic pathways, transcription factors and conserved signaling pathways, and novel candidate genes for regenerative processes. We discovered and confirmed numerous sequences of the candidate genes by using quantitative polymerase chain reaction and in situ hybridization.ConclusionThe results of this study demonstrate that de novo transcriptome sequencing allows gene expression analysis in a species lacking genome information and provides the most comprehensive mRNA sequence resources for axolotls. The characterization of the axolotl transcriptome can help elucidate the molecular mechanisms underlying blastema formation during limb regeneration.
Highlights
Salamanders are unique among vertebrates in their ability to completely regenerate amputated limbs through the mediation of blastema cells located at the stump ends
In a previous report [14], Monaghan et al generated over 1.7 million reads and approximately 400,000 unique sequences with a mean contig size of 215 bp for axolotl from a broader range of regeneration stages using 454 pyrosequencing
Using paired-end joining and gap-filling, we further assembled these contigs into 307,345 transcribed sequences with a mean size of 373 bp including 20,504 transcribed sequences larger than 1000 bp (Table 1)
Summary
Salamanders are unique among vertebrates in their ability to completely regenerate amputated limbs through the mediation of blastema cells located at the stump ends. This regeneration is nerve-dependent because blastema formation and regeneration does not occur after limb denervation. Next-generation sequencing (NGS) technology has become a cutting-edge approach for highthroughput sequence determination. This technology has dramatically improved the efficiency and speed of gene discovery in many studies [9,10], and has significantly accelerated and improved the sensitivity of gene expression profiling. Studies using transcriptome sequencing for organisms with complete genome sequencing have confirmed that the short-read products of NGS can be effectively assembled and used for gene discovery and comparison of gene expression profiles
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