Your search keyword '"Hipp, Michael J"' showing total 3 results

1. Targeted genome fragmentation with CRISPR/Cas9 enables fast and efficient enrichment of small genomic regions and ultra-accurate sequencing with low DNA input (CRISPR-DS)

Author

Nachmanson, Daniela, Lian, Shenyi, Schmidt, Elizabeth K., Hipp, Michael J., Baker, Kathryn T., Zhang, Yuezheng, Tretiakova, Maria, Loubet-Senear, Kaitlyn, Kohrn, Brendan F., Salk, Jesse J., Kennedy, Scott R., and Risques, Rosa Ana

Abstract

Next-generation sequencing methods suffer from low recovery, uneven coverage, and false mutations. DNA fragmentation by sonication is a major contributor to these problems because it produces randomly sized fragments, PCR amplification bias, and end artifacts. In addition, oligonucleotide-based hybridization capture, a common target enrichment method, has limited efficiency for small genomic regions, contributing to low recovery. This becomes a critical problem in clinical applications, which value cost-effective approaches focused on the sequencing of small gene panels. To address these issues, we developed a targeted genome fragmentation approach based on CRISPR/Cas9 digestion that produces DNA fragments of similar length. These fragments can be enriched by a simple size selection, resulting in targeted enrichment of up to approximately 49,000-fold. Additionally, homogenous length fragments significantly reduce PCR amplification bias and maximize read usability. We combined this novel target enrichment approach with Duplex Sequencing, which uses double-strand molecular tagging to correct for sequencing errors. The approach, termed CRISPR-DS, enables efficient target enrichment of small genomic regions, even coverage, ultra-accurate sequencing, and reduced DNA input. As proof of principle, we applied CRISPR-DS to the sequencing of the exonic regions of TP53and performed side-by-side comparisons with standard Duplex Sequencing. CRISPR-DS detected previously reported pathogenic TP53mutations present as low as 0.1% in peritoneal fluid of women with ovarian cancer, while using 10- to 100-fold less DNA than standard Duplex Sequencing. Whether used as standalone enrichment or coupled with high-accuracy sequencing methods, CRISPR-based fragmentation offers a simple solution for fast and efficient small target enrichment.

Published

2018

2. Duplex Sequencing with Patient-Specific Hybrid Capture Panels Reveals Ultra-Low Frequency Measurable Residual Disease in Pediatric Acute Myeloid Leukemia

Author

Higgins, Jacob, Lo, Fang Yin, Hipp, Michael J., Valentine, Charles C., Williams, Lindsey N., Leonti, Amanda R., Ries, Rhonda E., Radich, Jerald P., Meshinchi, Soheil, Huang, Benjamin J., and Salk, Jesse J.

Abstract

Sensitive and specific detection of measurable residual disease (MRD) after treatment in pediatric acute myeloid leukemia (AML) is prognostic of relapse and is important for clinical decision making. Mutation-based methods are increasingly being used, but are hampered by the limited number of common driver gene mutations to target as clone markers. Additional targets would greatly increase MRD detection power. However, even in cases with many AML-defining mutations, it is the limited accuracy of current molecular methods which establishes the lower bounds of sensitivity. Here we describe an ultrasensitive approach for disease monitoring with personalized hybrid capture panels targeting hundreds of somatic mutations identified by whole genome sequencing (WGS), and using extremely accurate Duplex Sequencing (DS) in longitudinal samples. In a pilot cohort of 13 patients we demonstrate detection sensitivities several orders of magnitude beyond currently available single locus testing or less accurate sequencing.

Published

2020

3. Duplex Sequencing with Patient-Specific Hybrid Capture Panels Reveals Ultra-Low Frequency Measurable Residual Disease in Pediatric Acute Myeloid Leukemia

Author

Higgins, Jacob, Lo, Fang Yin, Hipp, Michael J., Valentine, Charles C., Williams, Lindsey N., Leonti, Amanda R., Ries, Rhonda E., Radich, Jerald P., Meshinchi, Soheil, Huang, Benjamin J., and Salk, Jesse J.

Abstract

Higgins: TwinStrand Biosciences: Current Employment. Lo:TwinStrand Biosciences: Current Employment. Hipp:TwinStrand Biosciences: Current Employment. Valentine:TwinStrand Biosciences: Current Employment. Williams:TwinStrand Biosciences: Current Employment. Radich:TwinStrand Biosciences: Research Funding. Salk:TwinStrand Biosciences: Current Employment.

Published

2020