Your search keyword '"Jin H. Bae"' showing total 9 results

1. Metastable hybridization-based DNA information storage to allow rapid and permanent erasure

Author

Jangwon Kim, Jin H. Bae, Michael Baym, and David Yu Zhang

Subjects

Science

Abstract

The chemical stability of DNA makes complete erasure of DNA-encoded data difficult. Here the authors mix true and false messages, differentiated by whether a truth marker oligo is bound to it, and show that brief exposure to elevated temperatures randomizes the binding of truth markers preventing data recovery.

Published

2020

2. Native characterization of nucleic acid motif thermodynamics via non-covalent catalysis

Author

Chunyan Wang, Jin H. Bae, and David Yu Zhang

Subjects

Science

Abstract

DNA hybridisation thermodynamics parameters underlie rational design of oligonucleotides for diagnostics and nanotechnology. Here, the authors present an accurate method to measure the free energy of a given DNA structure at specific temperature and buffer conditions.

Published

2016

3. Single duplex DNA sequencing with CODEC detects mutations with high sensitivity

Author

Jin H. Bae, Ruolin Liu, Eugenia Roberts, Erica Nguyen, Shervin Tabrizi, Justin Rhoades, Timothy Blewett, Kan Xiong, Gregory Gydush, Douglas Shea, Zhenyi An, Sahil Patel, Ju Cheng, Sainetra Sridhar, Mei Hong Liu, Emilie Lassen, Anne-Bine Skytte, Marta Grońska-Pęski, Jonathan E. Shoag, Gilad D. Evrony, Heather A. Parsons, Erica L. Mayer, G. Mike Makrigiorgos, Todd R. Golub, and Viktor A. Adalsteinsson

Subjects

Genetics

Abstract

Detecting mutations from single DNA molecules is crucial in many fields but challenging. Next-generation sequencing (NGS) affords tremendous throughput but cannot directly sequence double-stranded DNA molecules (‘single duplexes’) to discern the true mutations on both strands. Here we present Concatenating Original Duplex for Error Correction (CODEC), which confers single duplex resolution to NGS. CODEC affords 1,000-fold higher accuracy than NGS, using up to 100-fold fewer reads than duplex sequencing. CODEC revealed mutation frequencies of 2.72 × 10−8 in sperm of a 39-year-old individual, and somatic mutations acquired with age in blood cells. CODEC detected genome-wide, clonal hematopoiesis mutations from single DNA molecules, single mutated duplexes from tumor genomes and liquid biopsies, microsatellite instability with 10-fold greater sensitivity and mutational signatures, and specific tumor mutations with up to 100-fold fewer reads. CODEC enables more precise genetic testing and reveals biologically significant mutations, which are commonly obscured by NGS errors.

Published

2023

4. Metastable hybridization-based DNA information storage to allow rapid and permanent erasure

Author

Michael H. Baym, Jangwon Kim, David Zhang, and Jin H. Bae

Subjects

0301 basic medicine, Time Factors, Computer science, Science, Oligonucleotides, Information Storage and Retrieval, General Physics and Astronomy, 010402 general chemistry, ENCODE, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, DNA sequencing, Data recovery, 03 medical and health sciences, chemistry.chemical_compound, lcsh:Science, Synthetic biology, Multidisciplinary, Base Sequence, DNA synthesis, business.industry, Oligonucleotide, Temperature, Nucleic Acid Hybridization, Nanobiotechnology, Pattern recognition, General Chemistry, computer.file_format, humanities, 0104 chemical sciences, Solutions, 030104 developmental biology, chemistry, Bitmap, Erasure, Paintings, lcsh:Q, Artificial intelligence, business, computer, DNA computing and cryptography, DNA

Abstract

The potential of DNA as an information storage medium is rapidly growing due to advances in DNA synthesis and sequencing. However, the chemical stability of DNA challenges the complete erasure of information encoded in DNA sequences. Here, we encode information in a DNA information solution, a mixture of true message- and false message-encoded oligonucleotides, and enables rapid and permanent erasure of information. True messages are differentiated by their hybridization to a "truth marker” oligonucleotide, and only true messages can be read; binding of the truth marker can be effectively randomized even with a brief exposure to the elevated temperature. We show 8 separate bitmap images can be stably encoded and read after storage at 25 °C for 65 days with an average of over 99% correct information recall, which extrapolates to a half-life of over 15 years at 25 °C. Heating to 95 °C for 5 minutes, however, permanently erases the message., The chemical stability of DNA makes complete erasure of DNA-encoded data difficult. Here the authors mix true and false messages, differentiated by whether a truth marker oligo is bound to it, and show that brief exposure to elevated temperatures randomizes the binding of truth markers preventing data recovery.

Published

2020

5. Duplex-Repair enables highly accurate sequencing, despite DNA damage

Author

Jin H. Bae, Douglas Shea, Todd R. Golub, Timothy Blewett, G. Mike Makrigiorgos, Erica Nguyen, Kan Xiong, Ruolin Liu, Justin Rhoades, and Viktor A. Adalsteinsson

Subjects

Mutation, Dna duplex, Molecular Structure, DNA damage, Base pair, AcademicSubjects/SCI00010, High-Throughput Nucleotide Sequencing, Breast Neoplasms, Computational biology, DNA, Sequence Analysis, DNA, Biology, medicine.disease_cause, DNA sequencing, Narese/20, chemistry.chemical_compound, chemistry, Duplex (building), Genetics, medicine, Humans, Methods Online, Female

Abstract

Accurate DNA sequencing is crucial in biomedicine. Underlying the most accurate methods is the assumption that a mutation is true if altered bases are present on both strands of the DNA duplex. We now show that this assumption can be wrong. We establish that current methods to prepare DNA for sequencing, via ‘End Repair/dA-Tailing,’ may substantially resynthesize strands, leading amplifiable lesions or alterations on one strand to become indiscernible from true mutations on both strands. Indeed, we discovered that 7-17% and 32-57% of interior ‘duplex base pairs’ from cell-free DNA and formalin-fixed tumor biopsies, respectively, could be resynthesized in vitro and potentially introduce false mutations. To address this, we present Duplex-Repair, and show that it limits interior duplex base pair resynthesis by 8- to 464-fold, rescues the impact of induced DNA damage, and affords up to 8.9-fold more accurate duplex sequencing. Our study uncovers a major Achilles’ heel in sequencing and offers a solution to restore high accuracy.

Published

2021

6. CODEC enables ‘single duplex’ sequencing

Author

Viktor A. Adalsteinsson, Shervin Tabrizi, Todd R. Golub, Blewett T, Douglas Shea, An Z, Patel S, Justin Rhoades, Ruolin Liu, Greg Gydush, Makrigiorgos Gm, Jin H. Bae, Erica Nguyen, and Kan Xiong

Subjects

Computer science, Codec, Word error rate, Duplex (telecommunications), Computational biology, Error detection and correction, Massively parallel, Throughput (business), DNA sequencing, Sequence (medicine)

Abstract

Detecting mutations as rare as a single molecule is crucial in many fields such as cancer diagnostics and aging research but remains challenging. Third generation sequencers can read a double-stranded DNA molecule (a ‘single duplex’) in whole to identify true mutations on both strands apart from false mutations on either strand but with limited accuracy and throughput. Although next generation sequencing (NGS) can track dissociated strands with Duplex Sequencing, the need to sequence each strand independently severely diminishes its throughput. Here, we developed a hybrid method called Concatenating Original Duplex for Error Correction (CODEC) that combines the massively parallel nature of NGS with the single-molecule capability of third generation sequencing. CODEC physically links both strands to enable NGS to sequence a single duplex with a single read pair. By comparing CODEC and Duplex Sequencing, we showed that CODEC achieved a similar error rate (10−6) with 100 times fewer reads and conferred ‘single duplex’ resolution to most major NGS workflows.

Published

2021

7. Massively parallel enrichment of low-frequency alleles enables duplex sequencing at low depth

Author

Gregory, Gydush, Erica, Nguyen, Jin H, Bae, Timothy, Blewett, Justin, Rhoades, Sarah C, Reed, Douglas, Shea, Kan, Xiong, Ruolin, Liu, Fangyan, Yu, Ka Wai, Leong, Atish D, Choudhury, Daniel G, Stover, Sara M, Tolaney, Ian E, Krop, J, Christopher Love, Heather A, Parsons, G, Mike Makrigiorgos, Todd R, Golub, and Viktor A, Adalsteinsson

Subjects

Mutation, High-Throughput Nucleotide Sequencing, Humans, Sequence Analysis, DNA, Alleles, Oligonucleotide Array Sequence Analysis

Abstract

Assaying for large numbers of low-frequency mutations requires sequencing at extremely high depth and accuracy. Increasing sequencing depth aids the detection of low-frequency mutations yet limits the number of loci that can be simultaneously probed. Here we report a method for the accurate tracking of thousands of distinct mutations that requires substantially fewer reads per locus than conventional hybrid-capture duplex sequencing. The method, which we named MAESTRO (for minor-allele-enriched sequencing through recognition oligonucleotides), combines massively parallel mutation enrichment with duplex sequencing to track up to 10,000 low-frequency mutations, with up to 100-fold fewer reads per locus. We show that MAESTRO can be used to test for chimaerism by tracking donor-exclusive single-nucleotide polymorphisms in sheared genomic DNA from human cell lines, to validate whole-exome sequencing and whole-genome sequencing for the detection of mutations in breast-tumour samples from 16 patients, and to monitor the patients for minimal residual disease via the analysis of cell-free DNA from liquid biopsies. MAESTRO improves the breadth, depth, accuracy and efficiency of mutation testing by sequencing.

Published

2020

8. High-throughput methods for measuring DNA thermodynamics

Author

David Zhang, Jin H. Bae, and John Z. Fang

Subjects

AcademicSubjects/SCI00010, Oligonucleotides, Thermodynamics, Biology, 010402 general chemistry, 01 natural sciences, Measure (mathematics), Narese/4, 03 medical and health sciences, chemistry.chemical_compound, Genetics, Humans, Nucleotide Motifs, Throughput (business), 030304 developmental biology, 0303 health sciences, Oligonucleotide, DNA, High-Throughput Screening Assays, 0104 chemical sciences, chemistry, Methods Online, Nucleic Acid Conformation, Sequence motif

Abstract

Understanding the thermodynamics of DNA motifs is important for prediction and design of probes and primers, but melt curve analyses are low-throughput and produce inaccurate results for motifs such as bulges and mismatches. Here, we developed a new, accurate and high-throughput method for measuring DNA motif thermodynamics called TEEM (Toehold Exchange Energy Measurement). It is a refined framework of comparing two toehold exchange reactions, which are competitive strand displacement between oligonucleotides. In a single experiment, TEEM can measure over 1000 ΔG° values with standard error of roughly 0.05 kcal/mol.

Published

2020

9. fadD deletion and fadL overexpression in Escherichia coli increase hydroxy long-chain fatty acid productivity

Author

Beom Gi Park, Jin H. Bae, Pyung-Gang Lee, Eunok Jung, and Byung-Gee Kim

Subjects

Catabolite repression, Gene Expression, medicine.disease_cause, Applied Microbiology and Biotechnology, Palmitic acid, chemistry.chemical_compound, Coenzyme A Ligases, Marinobacter, Escherichia coli, medicine, FADD, chemistry.chemical_classification, biology, Fatty acid metabolism, Escherichia coli Proteins, Fatty Acids, Long-chain fatty acid transport, Fatty acid, General Medicine, Fatty Acid Transport Proteins, Recombinant Proteins, Metabolic Engineering, Biochemistry, chemistry, biology.protein, lipids (amino acids, peptides, and proteins), Long chain fatty acid, Gene Deletion, Bacterial Outer Membrane Proteins, Biotechnology

Abstract

A major problem of long-chain fatty acid (LCFA) hydroxylation using Escherichia coli is that FadD (long-chain fatty acyl-CoA synthetase), which is necessary for exogenous LCFA transport, also initiates cellular consumption of LCFA. In this study, an effective method to prevent the cellular consumption of LCFA without impairing its transport is proposed. The main idea is that a heterologous enzyme which consumes LCFA can replace FadD in LCFA transport. For the model heterologous enzyme, CYP153A from Marinobacter aquaeolei, which converts palmitic acid into ω-hydroxy palmitic acid, was expressed in E. coli. When fadD was deleted from an E. coli strain, CYP153A indeed maintained the ability to transport LCFA. A disadvantage of fadD deletion mutant is the fact that FadD deficiency downregulates the transcription of fadL (outer membrane LCFA transporter) via FadR (fatty acid metabolism regulator protein), was solved by fadL overexpression from a plasmid. In addition, the overexpression of fadL was able to offset catabolite repression on fadL, allowing glucose to be used as the primary carbon source. In conclusion, the strain with fadD deletion and fadL overexpression showed 5.5-fold increase in productivity compared to the wild-type strain, converting 2.6 g/L (10.0 mM) of palmitic acid into 2.4 g/L (8.8 mM) of ω-hydroxy palmitic acid in a shake flask. This simple genetic manipulation can be applied to any LCFA hydroxylation using E. coli.

Published

2014