High-throughput DNA sequencing errors are reduced by orders of magnitude using circle sequencing

Lou, Dianne I.; Hussmann, Jeffrey A.; McBee, Ross M.; Acevedo, Ashley; Andino, Raul; Press, William H.; Sawyer, Sara L.

doi:10.1073/pnas.1319590110

Cited by 250 publications

(245 citation statements)

References 12 publications

(26 reference statements)

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“…The combination of in silico filtering and barcoding approaches allowed development of the workflow that had 15 times lower error rate than original CAPP-Seq approach. An interesting alternative to barcoding techniques capitalized on the increased read length possible with newer Illumina chemistry and suggested the use of rolling circle amplification to ensure redundant sequencing of individual DNA fragments (90). Briefly, DNA is fragmented to approximately 130 bp, denatured, circularized, and amplified using Phi29 polymerase.…”

Section: Error Suppression Methodsmentioning

confidence: 99%

“…Clearly, linearized fragments are excluded from subsequent rolling circle amplification and sequencing. This allowed the authors to achieve approximately 100-fold reduction in sequencing noise thereby improving specificity, but presumably at a cost to overall sensitivity due to the loss of some molecules prior to sequencing (90).…”

Section: Error Suppression Methodsmentioning

confidence: 99%

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Cell-free DNA (cfDNA): Clinical Significance and Utility in Cancer Shaped By Emerging Technologies

Volik¹,

Alcaide

Morin

et al. 2016

Molecular Cancer Research

295

235

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Precision oncology is predicated upon the ability to detect specific actionable genomic alterations and to monitor their adaptive evolution during treatment to counter resistance. Because of spatial and temporal heterogeneity and comorbidities associated with obtaining tumor tissues, especially in the case of metastatic disease, traditional methods for tumor sampling are impractical for this application. Known to be present in the blood of cancer patients for decades, cell-free DNA (cfDNA) is beginning to inform on tumor genetics, tumor burden, and mechanisms of progression and drug resistance. This substrate is amenable for inexpensive noninvasive testing and thus presents a viable approach to serial sampling for screening and monitoring tumor progression. The fragmentation, low yield, and variable admixture of normal DNA present formidable technical challenges for realization of this potential. This review summarizes the history of cfDNA discovery, its biological properties, and explores emerging technologies for clinically relevant sequence-based analysis of cfDNA in cancer patients. Molecular barcoding (or Unique Molecular Identifier, UMI)-based methods currently appear to offer an optimal balance between sensitivity, flexibility, and cost and constitute a promising approach for clinically relevant assays for near real-time monitoring of treatment-induced mutational adaptations to guide evidence-based precision oncology.

show abstract

Section: Error Suppression Methodsmentioning

confidence: 99%

Section: Error Suppression Methodsmentioning

confidence: 99%

Cell-free DNA (cfDNA): Clinical Significance and Utility in Cancer Shaped By Emerging Technologies

Volik¹,

Alcaide

Morin

et al. 2016

Molecular Cancer Research

295

235

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“…In addition, NGS is an emerging alternative of T-RFLP for community profiling and provide more indepth information but currently facing some critics. For example, rate of sequencing error in next generation sequencing is high than Sanger sequencing [51]. In addition, due to short read length it gives overestimate about microbial diversity and cannot use for species level resolution.…”

Section: Comparison Of T-rflp To Other Community Profiling Methodsmentioning

confidence: 99%

“…Kalia et al [52], Porwal et al [53] and Bhushan et al [54] used extensive database of 16S rRNA gene sequences and developed species specific framework, signature nucleotide and restriction digestion pattern to increase the taxonomic resolution in genus Clostridium, Bacillus, and Pseudomonas respectively. Different approaches used by Kalia et al [51] and Porwal et al [52] can be used to get more taxonomic resolution by designing the species specific framework for community analysis or for the study of effect of environmental perturbation on a particular species by T-RFLP or NGS. Although next generation sequencing is more attractive but at the same time it is cumbersome and costly as compared to T-RFLP.…”

Section: Comparison Of T-rflp To Other Community Profiling Methodsmentioning

confidence: 99%

Technicalities and Glitches of Terminal Restriction Fragment Length Polymorphism (T-RFLP)

et al. 2014

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Terminal restriction fragment length polymorphism (T-RFLP) is a rapid, robust, inexpensive and simple tool for microbial community profiling. Methods used for DNA extraction, PCR amplification and digestion of amplified products have a considerable impact on the results of T-RFLP. Pitfalls of the method skew the similarity analysis and compromise its high throughput ability. Despite a high throughput method of data generation, data analysis is still in its infancy and needs more attention. Current article highlights the limitations of the methods used for data generation and analysis. It also provides an overview of the recent methodological developments in T-RFLP which will assist the readers in obtaining real and authentic profiles of the microbial communities under consideration while eluding the inherent biases and technical difficulties.

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“…5 This has led to increased interest recently in refining NGS techniques to reduce error rates and noise to allow for detection of verylow-frequency mutations. [6][7][8] Several of these refinement methods rely on barcoding-type techniques in which sample molecules are tagged with unique identifiers (UIDs), an exogenous random sequences of nucleotides, prior to amplification. The tagged amplicons are then sequenced and post hoc grouped by UID into families to create a consensus sequence representing the original sample molecule, filtering out errors introduced in the amplification and sequencing process.…”

Section: Introductionmentioning

confidence: 99%

The Impact of Collisions on the Ability to Detect Rare Mutant Alleles Using Barcode-Type Next-Generation Sequencing Techniques

2017

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Barcoding techniques are used to reduce error from next-generation sequencing, with applications ranging from understanding tumor subclone populations to detecting circulating tumor DNA. Collisions occur when more than one sample molecule is tagged by the same unique identifier (UID) and can result in failure to detect very-low-frequency mutations and error in estimating mutation frequency. Here, we created computer models of barcoding technique, with and without amplification bias introduced by the UID, and analyzed the effect of collisions for a range of mutant allele frequencies (1e−6 to 0.2), number of sample molecules (10 000 to 1e7), and number of UIDs (4 10 -4 14 ). Inability to detect rare mutant alleles occurred in 0% to 100% of simulations, depending on collisions and number of mutant molecules. Collisions also introduced error in estimating mutant allele frequency resulting in underestimation of minor allele frequency. Incorporating an understanding of the effect of collisions into experimental design can allow for optimization of the number of sample molecules and number of UIDs to minimize the negative impact on rare mutant detection and mutant frequency estimation.

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High-throughput DNA sequencing errors are reduced by orders of magnitude using circle sequencing

Cited by 250 publications

References 12 publications

Cell-free DNA (cfDNA): Clinical Significance and Utility in Cancer Shaped By Emerging Technologies

Cell-free DNA (cfDNA): Clinical Significance and Utility in Cancer Shaped By Emerging Technologies

Technicalities and Glitches of Terminal Restriction Fragment Length Polymorphism (T-RFLP)

The Impact of Collisions on the Ability to Detect Rare Mutant Alleles Using Barcode-Type Next-Generation Sequencing Techniques

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