Project description:Library preparation methods development

Project description:We present here an integrated framework that allows inference of enzyme reactions during library preparation and which predicts characteristic coverage shapes for different protocols. Analysis of several existing (sc)RNA-seq datasets confirms our model and reveals polymerase processivities as mechanistic origins of the resulting coverage shapes. We show how correction factors are necessary for proper RNA-seq-based mRNA quantification. Finally, we demonstrate the sensitivity of our methodology in inferring increased processivities at lowered reaction temperatures, suggesting possible improvements to existing protocols. Our findings have broad implications for existing and future RNA-seq experiments.

Project description:Here, we present a standardized, “off-the-shelf” proteomics pipeline working in a single 96-well plate to achieve deep coverage of cellular proteomes with high throughput and scalability. This integrated pipeline streamlining a fully automated sample preparation platform, data independent acquisition (DIA) coupled with high field asymmetric waveform ion mobility spectrometer (FAIMS) interface, and an optimized library-free DIA database search strategy. Our systematic evaluation of FAIMS-DIA showed single compensation voltage (CV) at -35V not only yields deepest proteome coverage but also best correlates with DIA without FAIMS. Our in-depth comparison of direct-DIA database search engines showed Spectronaut outperforms others, providing highest quantifiable proteins. Next, we apply three common DIA strategies in characterizing human induced pluripotent stem cell (iPSC)-derived neurons and show single-shot MS using single CV(-35V)-FAIMS-DIA results in >9,000 quantifiable proteins with < 10% missing values, as well as superior reproducibility and accuracy compared to other existing DIA methods.

Project description:Evaluating different library preparation methods for Pool-seq

Project description:We systematically evaluated alternate strategies for WGBS studies, taking into account opportunites around library preparation methods, sequencing platforms and analysis pipeline optimization. We also assessed the performance and precision of the WGBS method relative to the methylation arrays, in an effort to provide data-driven recommendations for future WGBS studies, in particularly with respect to minimum coverage.

Project description:We systematically evaluated alternate strategies for WGBS studies, taking into account opportunites around library preparation methods, sequencing platforms and analysis pipeline optimization. We also assessed the performance and precision of the WGBS method relative to the methylation arrays, in an effort to provide data-driven recommendations for future WGBS studies, in particularly with respect to minimum coverage.

Project description:Microfluidic direct library preparation (DLP) single-cell whole-genome BAM files for third-passage patient-derived primary triple-negative breast cancer xenograft SA501X3F.

Project description:Microfluidic direct library preparation (DLP) single-cell whole-genome BAM files for fourth-passage patient-derived primary triple-negative breast cancer xenograft SA501X4F.

Project description:Integrated single-cell transcriptome and DNA methylome profiling has provided insight into the complex regulatory networks of cells. Existing methods are based on picking a single-cell and performing library construction in a tube, which is costly and cumbersome. Here, we propose DIRECT, a digital microfluidics-based method for simultaneous analysis of the methylome and transcriptome in a single library construction. The accuracy of DIRECT is demonstrated in comparison with bulk and single-omics data, and the high CpG site coverage of DIRECT allows for precise analysis of copy number variation information, enabling expansion of single cell analysis from two- to three-omics. By applying DIRECT to monitor the dynamics of mouse embryonic stem cell differentiation, the relationship between DNA methylation and changes in gene expression during differentiation was revealed. DIRECT enables accurate, robust, and reproducible single-cell DNA methylation and gene expression co-analysis at a lower cost and with greater efficiency, broadening the application scenarios of single-cell multi-omics analysis and revealing a more comprehensive and fine-grained map of cellular regulatory landscapes.

Project description:Intent of the experiment: evaluate whether copy number gains and losses occur throughout the processing of passaging, i.e. test the genomic stability of the patient-derived xenograft models. DNA was extracted from frozen xenograft samples of different passages. KAPA DNA Library Preparation Kit was used to prepare DNA libraries, which were sequenced at low coverage on a HiSeq2000 (Illumina) with a V3 flowcell generating 50bp reads. Raw reads were aligned to the human reference genome version hg19 with Burrows-Wheeler Aligner software package and after duplicate removal further analyzed with QDNAseq to exclude known regions with low mapping quality, correct for the genomic wave and to count the reads per bin. Binned data were further segmented with the ASCAT (Allele-Specific Copy number Analysis of Tumours) algorithm.