BMC Genomics | |
Context-dependent DNA polymerization effects can masquerade as DNA modification signals | |
Yusuke Takahashi1  Shinichi Morishita1  Andrew Fire2  Massa Shoura2  | |
[1] Department of Computational Biology and Medical Sciences, Graduate School of Frontier Sciences, The University of Tokyo;Departments of Pathology and Genetics, School of Medicine, Stanford University; | |
关键词: DNA polymerization; DNA modification; Non-B DNA; Whole genome amplification; Single-molecule real-time (SMRT) sequencing; DNA N6-methyladenine; | |
DOI : 10.1186/s12864-022-08471-2 | |
来源: DOAJ |
【 摘 要 】
Abstract Background Single molecule measurements of DNA polymerization kinetics provide a sensitive means to detect both secondary structures in DNA and deviations from primary chemical structure as a result of modified bases. In one approach to such analysis, deviations can be inferred by monitoring the behavior of DNA polymerase using single-molecule, real-time sequencing with zero-mode waveguide. This approach uses a Single Molecule Real Time (SMRT)-sequencing measurement of time between fluorescence pulse signals from consecutive nucleosides incorporated during DNA replication, called the interpulse duration (IPD). Results In this paper we present an analysis of loci with high IPDs in two genomes, a bacterial genome (E. coli) and a eukaryotic genome (C. elegans). To distinguish the potential effects of DNA modification on DNA polymerization speed, we paired an analysis of native genomic DNA with whole-genome amplified (WGA) material in which DNA modifications were effectively removed. Adenine modification sites for E. coli are known and we observed the expected IPD shifts at these sites in the native but not WGA samples. For C. elegans, such differences were not observed. Instead, we found a number of novel sequence contexts where IPDs were raised relative to the average IPDs for each of the four nucleotides, but for which the raised IPD was present in both native and WGA samples. Conclusion The latter results argue strongly against DNA modification as the underlying driver for high IPD segments for C. elegans, and provide a framework for separating effects of DNA modification from context-dependent DNA polymerase kinetic patterns inherent in underlying DNA sequence for a complex eukaryotic genome.
【 授权许可】
Unknown