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Friday, February 5, 2021

Webinar: Opportunities for using PacBio Long-read sequencing for COVID-19 research

In this Labroots webinar, Meredith Ashby, Director of Microbial Genomics at PacBio, describes the utility of highly accurate long-read sequencing, known as HiFi sequencing, to understand the SARs-CoV-2 viral genome. HiFi sequencing enables mutation phasing and rare variant detection to understand viral stability and mutation rates, as well as providing insights into viral population structure for monitoring viral evolution. Ashby also shares how HiFi sequencing can be used to explore the host immune response to COVID-19, specifically by providing full-length sequencing of the B cell repertoire, IGH locus and HLA genes. Access additional COVID-19 Sequencing Tools and Resources at at…

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Friday, February 5, 2021

SMRT Leiden: Epigenomics in the ERA of third-generation sequencing: A large-scale study of the human pathogen Clostridioides difficile

In this SMRT Leiden 2020 Online Virtual Event presentation Pedro Oliveira of Mount Sinai shares his research on Clostridioides – a leading cause of nosocomial-acquired diarrhea and colitis across the developed world. In this study, Oliveira and coworkers performed the first comprehensive DNA methylome analysis of 36 human C. difficile isolates from a hospital setting using SMRT Sequencing and comparative epigenomics.

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Friday, February 5, 2021

SMRT Leiden: Calling all variants with HiFi reads

In this SMRT Leiden 2020 Online Virtual Event presentation, William Rowell of PacBio shares work on using HiFi reads – which combine the length of traditional long reads with the accuracy of short reads, making them great for comprehensive variant detection. This presentation covers the recommended workflows for detecting both small variants and structural variants from HiFi reads.

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Friday, February 5, 2021

Webinar: Increasing solve rates for rare and Mendelian diseases with long-read sequencing

Dr. Wenger gives attendees an update on PacBio’s long-read sequencing and variant detection capabilities on the Sequel II System and shares recommendations on how to design your own study using HiFi reads. Then, Dr. Sund from Cincinnati Children’s Hospital Medical Center describes how she has used long-read sequencing to solve rare neurological diseases involving complex structural rearrangements that were previously unsolved with standard methods.

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Friday, February 5, 2021

ASHG CoLab: PacBio HiFi reads for comprehensive characterization of genomes and single-cell isoform expression

In this ASHG 2020 CoLab presentation hear Principal Scientists, Aaron Wenger and Elizabeth Tseng share how highly accurate long reads (HiFi reads) provide comprehensive variant detection for both genomes and transcriptomes. Aaron Wenger describes how new improvements in protocols and analysis methods have increased scalability and accuracy of variant calling. As demonstrated in the precisionFDA Truth Challenge V2, HiFi reads (>99% accurate, 15 kb – 20 kb) now outperform short reads for single nucleotide and structural variant calling and match for small indels. This includes calling >30,000 small variants and >10,000 structural variants missed by short reads, many in medically…

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Friday, February 5, 2021

Webinar: SMRT Sequencing applications for human genomics and medicine

In this webinar, Adam Ameur of SciLifeLab at Uppsala University shares how he uses Single Molecule, Real-Time (SMRT) Sequencing applications for medical diagnostics and human genetics research, including sequencing of single genes and de novo assembly of human genomes as well as a new method for detection of CRISPR-Cas9 off-targets.

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Friday, February 5, 2021

Educational Video: Variant Detection with HiFi Reads – Understanding Results from the precisionFDA Truth Challenge

In this short video, Aaron Wenger, a Principal Scientist at PacBio, explains what highly accurate long reads, or HiFi reads, are and how they help to detect all variant types including single nucleotide, indels, and structural variants. He goes on to recap the precisionFDA Truth Challenge V2 which used Genome in a Bottle (GIAB) benchmarks to evaluate various sequencing technologies. In the 2020 challenge, when ranked for accuracy, PacBio HiFi reads delivered the highest precision and recall in all categories.

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Friday, February 5, 2021

Video Poster: Accurate, comprehensive variant calling in difficult-to-map genes using HiFi reads

Introduction: Around 5% (1,168) of protein-coding genes in the human genome contain an exon that is difficult to map with typical next-generation sequencing (NGS) read lengths due to homologous pseudogenes or segmental duplications. Among the difficult-to-map genes are 193 with known medical relevance, including CYP2D6, GBA, SMN1/2, and VWF. Long-read DNA sequencing provides increased mappability, accessing many of the difficult-to-map regions by connecting the homologous exon to neighboring unique sequence. Until recently, the read-level accuracy of long-read sequencing had made it challenging to accurately call small variants. The recently developed HiFi reads from the PacBio Sequel II System provide both…

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Friday, February 5, 2021

Webinar: Bioinformatics lunch & learn – A quick guide to metagenomic analysis with PacBio HiFi reads

In this webinar, scientists from PacBio share how using Single Molecule, Real-Time (SMRT) Sequencing, you can generate highly accurate long reads – HiFi reads – with 99% accuracy (Q20) and read lengths of 10 kb or more. This high resolution of each single molecule enables species or strain-level profiling of complex populations in both targeted and shotgun sequencing experiments. Genome assemblies are more cost effective than ever before when sequencing metagenomics samples with the Sequel II System.

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Friday, February 5, 2021

Video Poster: Long-read sequencing of the SARS-CoV-2 genome and the human immune repertoire

COVID-19 is caused by the infection of SARS-CoV-2, a member of the coronavirus family. Complete and accurate sequencing of the SARS-CoV-2 genome enables discovery and epidemiological tracing of mutations that may be important for antiviral and vaccine research. A complementary approach, sequencing the patients’ immune repertoire, allows for detection of neutralizing antibodies and understanding variation in the adaptive immune response. PacBio’s SMRT Sequencing uses circular consensus sequencing that can generate long, highly accurate (HiFi) reads. We find that a tiled multiplex PCR amplicon approach of ~1-2 kb fragments achieves a balanced tradeoff between ease of library preparation and robustness to…

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Friday, February 5, 2021

Video Poster: A new approach to Thalassemia and Ataxia carrier screening panels using CRISPR-Cas9 enrichment and long-read sequencing

Although PCR is a cost-effective way to enrich for genomic regions of interest for DNA sequencing, amplifying regions with extreme GC-content and long stretches of short tandem repeat (STR) sequences is often problematic and prone to sequence artifacts. This is especially true when developing multiplexed PCR assays for clinical applications such as carrier screening for multiple genes. The additional challenge is that all PCR primer pairs must be carefully selected to be compatible based on amplicon size and PCR conditions. Due to these experimental design constraints, a single tube with a high number of multiplexed PCR amplicons is difficult to…

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Friday, February 5, 2021

Video Poster: High-throughput HiFi library workflow for human whole genome sequencing on the Sequel II System

Recent advances in sequencing chemistry and software in the Sequel II System enable generating highly accurate long reads that are up to 25 kb in length with >99% accuracy. The high quality HiFi reads are suitable for variant detection of all types, from single nucleotides to structural variants. PacBio offers an end-to-end solution from sample preparation to data analysis. However, library construction is still a bottleneck making it difficult to implement into a high-throughput workflow for sequencing large number of samples. Input DNA requirements, DNA shearing and size-selection/fractionation are the most critical and challenging steps in the current procedure. In…

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