Project description:Mnemiopsis leidyi

Project description:Mnemiopsis leidyi Raw sequence reads

Project description:Mnemiopsis leidyi Transcriptome or Gene expression

Project description:Mnemiopsis leidyi high resolution developmental transcriptomic time-course

Project description:Regeneration in the Ctenophore Mnemiopsis leidyi: A Transcriptomic Analysis

Project description:Single- and eight-cell stage Mnemiopsis leidyi RNAseq raw sequence reads

Project description:These data complement GEO accession GSE60478, a time-course of Mnemiopsis leidyi developmental gene expression for hours 0-13 and hour 20. The data here provide additional replicates for 0-13 and 20 hours as well as new timepoints 14–19. As in the original study (Levin et al. 2016 PMID: 26886793) data are from single embryos using the Cel-Seq (Single-Cell RNA-Seq by Multiplexed Linear Amplification PMID:22939981). Embryo processing, sequencing and sequence processing were performed in the same manner as the original analyses (GEO accession GSE60478) so these data should be completely compatible with that study.

Project description:Mnemiopsis leidyi strain:wild caught Genome sequencing and assembly

Project description:A time series from 1 hour to 9 hours post-fertilization (hpf) was collected for RNA-seq by students of the MBL Embryology Course to understand the shifts in gene expression occuring in the early embryo of Mnemiopsis leidyi.

Project description:Ctenophores’ amazing capacity of regeneration has fascinated biologists for centuries. The morphological features of ctenophore regeneration have been documented, but the molecular and cellular components behind this phenomenon have remained a mystery. Here, next generation sequencing technologies and transcriptomic analysis are used to investigate the regeneration dynamics in the ctenophore Mnemiopsis leidyi. The resulting data identify multiple signaling pathways that might be involved in ctenophore regeneration. These include evolutionarily conserved pathways, such as Ca2+-dependent and MAP-kinase signaling pathways, that are up regulated during regeneration, as well as genes involved in energetics and cytoskeleton function. The data also show evidence for involvement of dozens of ctenophore specific secretory molecules, their receptors and processing components that are important signal messengers in regeneration. A unique subset of transcription factors were also found to be involved in regeneration which may be upstream regulators of those signaling pathways. In summary, our data indicate that the strategies which ctenophores employ to regenerate use a unique combination of evolutionarily conserved and ctenophore specific signaling components. These data provide novel insights into the mechanisms of regeneration in the earliest branching taxa in Metazoa.