Project description:In recent years, tagmentation-based library preparation using a hyperactive version of the Tn5 transposase gained more and more popularity. The limited hands-on time, robustness and high efficiency of the method are essential for the processing of next-generation sequencing libraries from little input material like single cells or the processing of hundreds of samples simultaneously. The hyperactive Tn5 is commercially available (Nextera XT DNA library preparation kit), however, high-throughput experiments with hundreds of samples are costly. Here, we present a highly reproducible Tn5 transposase purification strategy via an N-terminal His6-Sumo3 tag and the workflow for the tagmentation-based NGS library preparation. We demonstrate that NGS libraries processed with the in-house produced Tn5 are of the same quality like those processed with the Nextera XT DNA library preparation kit and that the purification of the transposase is reproducible across institutes. Producing the Tn5 transposase in-house allows for customized experimental design and reduces costs of large-scale experiments dramatically. We describe a novel single cell polyadenylation site mapping protocol that benefits from the fact that the in-house produced Tn5 can be loaded with any desired linker oligonucleotide for tagmentation.
Project description:In recent years, tagmentation-based library preparation using a hyperactive version of the Tn5 transposase gained more and more popularity. The limited hands-on time, robustness and high efficiency of the method are essential for the processing of next-generation sequencing libraries form little input material like single cells or the processing of hundreds of samples simultaneously. The hyperactive Tn5 is commercially available (Nextera XT DNA library preparation kit), however, high-throughput experiments with hundreds of samples are costly. Here, we present a highly reproducible Tn5 transposase purification strategy via an N-terminal His6-Sumo3 tag and the workflow for the tagmentation-based NGS library preparation. We demonstrate that NGS libraries processed with the in-house produced Tn5 are of the same quality like those processed with the Nextera XT DNA library preparation kit and that the purification of the transposase is reproducible across institutes. Producing the Tn5 transposase in-house allows for customized experimental design and reduces costs of large-scale experiments dramatically. We describe a novel single cell polyadenylation site mapping protocol that benefits from the fact that the in-house produced Tn5 can be loaded with any desired linker oligonucleotide for tagmentation.
Project description:Deep sequencing of single cell-derived genomic DNA and/or cDNAs brings novel insights into oncogenesis and embryogenesis. However, traditional library preparation for RNA-Seq requires multiple steps, including shearing the target DNA/RNA and following sequential enzymatic reactions, which result in consequent sample loss and stochastic variation at each step. Such variation may significantly affect the output from sequencing. We have found that a new technique of library preparation using hyperactive Tn5 transposase for the next-generation sequencer of Illumina's platform provided high-quality libraries from 100ng of short-length (average 700~800 bp) single-cell level cDNA. This new method reduced the number of steps in the protocol, which resulted in improved reproducibility and reduced variation among the specimens. Two methods of library preparation (sonication, tagmentation with hyperactive Tn5 transposase) were compared in the case of RNA-Seq for single-cell level cDNA. Technical triplicates were used.
Project description:We optimzed ATAC-seq library preparation for use with Drosophila melanogaster. The protocol addresses factors specific to fruit flies, such as the insect exoskeleton and smaller genome size. The optimized protocol provides guidelines for sample input, nuclei isolation, and enzymatic reaction times. The data included here were generated using our optimized library preparation workflow.
Project description:We evaluated the effect of the small RNA library preparation method on 5' tRNA-halves and miRNA abundance in libraries prepared from serum RNA using three commercially available small RNA library preparation kits (TruSeq small RNA library preparation kit v2 (Illumina), TailorMix miRNA sample preparation kit v2 (Seqmatic) and the NEBNext Multiplex Small RNA library prep kit (New England Biolabs)). RNA isolated from 100 µl of serum collected from healthy mice was used as input for the preparation of a small RNA library in duplicate and libraries were single end sequenced.
Project description:Deep sequencing of single cell-derived genomic DNA and/or cDNAs brings novel insights into oncogenesis and embryogenesis. However, traditional library preparation for RNA-Seq requires multiple steps, including shearing the target DNA/RNA and following sequential enzymatic reactions, which result in consequent sample loss and stochastic variation at each step. Such variation may significantly affect the output from sequencing. We have found that a new technique of library preparation using hyperactive Tn5 transposase for the next-generation sequencer of Illumina's platform provided high-quality libraries from 100ng of short-length (average 700~800 bp) single-cell level cDNA. This new method reduced the number of steps in the protocol, which resulted in improved reproducibility and reduced variation among the specimens.
