Project description:Assembling Chloroplast Genome Sequences of Jelutung rawa (Dyera polyphylla) using Both Short-read and Long-read Sequencing

Project description:Assembling Chloroplast Genome Sequences of Petai, Jengkol, Sungkai and Leprosula using Both Short-read and Long-read Sequencing

Project description:In the parasitic wasp Venturia canescens sexual and asexual populations coexist in sympatry and showed distinct foraging behaviours. By sequencing head transcriptome from sexual and asexual population, we assess transcriptomic divergence between the 2 populations.

Project description:Septobasidium canescens

Project description:Echinosphaeria canescens

Project description:Septobasidium canescens overview

Project description:Venturia canescens overview

Project description:Cercospora canescens overview

Project description:Penicillium canescens overview

Project description:Droplet-based single-cell sequencing techniques have provided unprecedented insight into cellular heterogeneities within tissues. However, these approaches only allow for the measurement of the distal parts of a transcript following short-read sequencing. Therefore, splicing and sequence diversity information is lost for the majority of the transcript. The application of long-read Nanopore sequencing to droplet-based methods is challenging because of the low base-calling accuracy currently associated with Nanopore sequencing. Although several approaches that use additional short-read sequencing to error-correct the barcode and UMI sequences have been developed, these techniques are limited by the requirement to sequence a library using both short- and long-read sequencing. Here we introduce a novel approach termed single-cell Barcode UMI Correction sequencing (scBUC-seq) to efficiently error-correct barcode and UMI oligonucleotide sequences synthesized by using blocks of dimeric nucleotides. The method can be applied to correct both short-read and long-read sequencing, thereby allowing users to recover more reads per cell that permits direct single-cell Nanopore sequencing for the first time. We illustrate our method by using species-mixing experiments to evaluate barcode assignment accuracy and multiple myeloma cell lines to evaluate differential isoform usage and Ewing’s sarcoma cells to demonstrate Ig fusion transcript analysis.