Project description:Polycistronic mRNAs transcribed from operons are resolved via the trans-splicing of a spliced leader (SL) RNA. The SL is also frequently trans-spliced to monocistronic transcripts. Using a modified cap analysis of gene expression (CAGE) protocol we mapped sites of SL trans-splicing genome-wide in the marine chordate Oikopleura dioica and find evidence for proposed functions of SL-trans-splicing. A recent hypothesis postulates that operons facilitate recovery from growth arrested states in metazoans. We examined the expression dynamics of operons across the life-cycle of the animal and during growth arrest recovery. We show that operons do not facilitate recovery from growth arrest in O. dioica. We find that operons are enriched in the germline and that trans-spliced transcripts are predominantly maternal., Interestingly, there is a TOP-like motif in the SL sequence, and trans-splicing in TOP mRNAs, indicating that trans-spliced mRNAs are targets for nutrient-dependent translational control in O. dioica. Total RNA from a number of stages across development were pooled and used in a modified DeepCAGE protocol. A custom designed spliced-leader primer (using the SL exon) was used in the 2nd strand synthesis step.

Project description:Polycistronic mRNAs transcribed from operons are resolved via the trans-splicing of a spliced leader (SL) RNA. The SL is also frequently trans-spliced to monocistronic transcripts. Using a modified cap analysis of gene expression (CAGE) protocol we mapped sites of SL trans-splicing genome-wide in the marine chordate Oikopleura dioica and find evidence for proposed functions of SL-trans-splicing. A recent hypothesis postulates that operons facilitate recovery from growth arrested states in metazoans. We examined the expression dynamics of operons across the life-cycle of the animal and during growth arrest recovery. We show that operons do not facilitate recovery from growth arrest in O. dioica. We find that operons are enriched in the germline and that trans-spliced transcripts are predominantly maternal., Interestingly, there is a TOP-like motif in the SL sequence, and trans-splicing in TOP mRNAs, indicating that trans-spliced mRNAs are targets for nutrient-dependent translational control in O. dioica.

Project description:Polycistronic mRNAs transcribed from operons are resolved via the trans-splicing of a spliced leader (SL) RNA. The SL is also frequently trans-spliced to monocistronic transcripts. Using a modified cap analysis of gene expression (CAGE) protocol we mapped sites of SL trans-splicing genome-wide in the marine chordate Oikopleura dioica and find evidence for proposed functions of SL-trans-splicing. A recent hypothesis postulates that operons facilitate recovery from growth arrested states in metazoans. We examined the expression dynamics of operons across the life-cycle of the animal and during growth arrest recovery. We show that operons do not facilitate recovery from growth arrest in O. dioica. We find that operons are enriched in the germline and that trans-spliced transcripts are predominantly maternal., Interestingly, there is a TOP-like motif in the SL sequence, and trans-splicing in TOP mRNAs, indicating that trans-spliced mRNAs are targets for nutrient-dependent translational control in O. dioica.

Project description:The developmental transcriptomics of every significant developmental stage of O. dioica at ultra-high resolution. 18 samples were included, each in technical triplicate (and one with 4 replicates). These samples included 12 developmental time-point providing high-resolution interrogation of the complete animal life cycle. A further 3 samples specifically interrogated adult ovary, testis and somatic tissues. Finally, 3 samples were included that covered animal transcriptomics response under restrictive conditions that induce developmental growth arrest.

Project description:Pristionchus pacificus trans-spliced transcriptome and operons

Project description:Under crowded, nutrient-limiting conditions, growth in the marine chordate O. dioica arrests until favorable conditions return. We profiled translation genome-wide using ribosome profiling in O. dioica during growth arrest and growth arrest recovery. We found that initial recovery is independent of nutrient-responsive, trans-spliced genes, suggesting that animal density is the primary trigger for the resumption of development in this species.

Project description:Protein synthesis is an energy-demanding process essential for cell proliferation and survival. Balancing the cost of protein synthesis with available resources has driven the evolution of its nutrient-dependent regulation. A central mechanism in this regulation is the repression of translation of the protein synthesis machinery during unfavorable growth conditions. This is mediated via mammalian target of rapamycin (mTOR), a master regulator of growth conserved from yeast to human. Despite extensive research, and the elucidation of a number of important factors, how mRNAs are translationally regulated by mTOR is still unclear. Repression depends on a 5’ Terminal Oligo Pyrimidine (TOP) motif which is conserved across vertebrates and present in Drosophila melanogaster. In Caenorhabditis elegans and the marine chordate Oikopleura dioica most TOP mRNAs are trans-spliced to a spliced leader. This results in the removal of the originally transcribed 5’ end and its replacement with a common short RNA sequence. In both species the 5’ end of the spliced leader is pyrimidine-enriched but does not meet strict requirements for a canonical TOP motif. How this affects the translational control of TOP mRNAs is unknown. Here, using transcriptome-wide ribosome profiling on whole animals treated with the mTOR inhibitor Torin 1, we show that trans-spliced TOP mRNAs in O. dioica are subject to mTOR-dependent translational control. We also show, using existing data, that trans-spliced transcripts in C. elegans are differentially translated upon recovery from starvation-induced developmental diapause. Together our results demonstrate that spliced leaders in metazoans are targets for mTOR-dependent translational control in response to nutrient availability. This indicates that trans-splicing in metazoans, the function of which has remained largely enigmatic, plays a key role in the coordinated translational regulation of growth-related genes. Moreover, our results reveal an innovative strategy for rapid evolution and developmental control of downstream targets of the ancient mTOR pathway.

Project description:Current approaches to profiling tissue-specific gene expression in C. elegans require delicate manipulation and are difficult under certain conditions, e.g. from dauer or aging worms. We have developed an easy and robust method for tissue-specific RNA-seq by taking advantage of the endogenous trans-splicing process. In this method, transgenic worms are generated in which a spliced leader (SL) RNA gene is fused with a sequence tag and driven by a tissue-specific promoter. Only in the tissue of interest, the tagged SL RNA gene is transcribed and then trans-spliced onto mRNAs. The tag allows enrichment and sequencing of mRNAs from that tissue only. As a proof of principle, we profiled the muscle transcriptome, which showed high coverage and efficient enrichment of muscle specific genes, with low background noise. To demonstrate the robustness of our method, we profiled muscle gene expression in dauer larvae and aging worms, revealing gene expression changes consistent with the physiology of these stages. The resulting muscle transcriptome also revealed 461 novel RNA transcripts, likely muscle-expressed long non-coding RNAs. In summary, the splicing-based RNA tagging (SRT) method provides a convenient and robust tool to profile trans-spliced genes and identify novel transcripts in a tissue-specific manner, with a low false positive rate.

Project description:Genome-wide map of spliced-leader-led trans-splice sites in Oikopleura dioica

Project description:Spliced leader trans-splicing is an essential RNA processing step that is required for the formation of mRNA in many eukaryotes, including C. elegans. However, the role of factors involved in this reaction is not well known. Here we further characterise the function of SNA-2, SNA-3, SUT-1 and SNR-2 involved in spliced leader 1 trans-splicing through identification of interacting proteins by immunoprecipitation followed by LC-MS/MS and label-free quantification.