Effects of error-correction of heterozygous next-generation sequencing data

Fujimoto, M. Stanley; Bodily, Paul; Okuda, Nozomu; Clement, Mark J.; Snell, Quinn

doi:10.1186/1471-2105-15-s7-s3

Cited by 14 publications

(13 citation statements)

References 50 publications

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“…Additionally, it also does not look promising to correct reads without understanding causes of sequencing/library errors. The work (Fujimoto et al, 2014) confirms that error correction methods can not handle heterozygosity, and they introduce new mis-correction errors.…”

Section: Correction Of Errorssupporting

confidence: 56%

See 1 more Smart Citation

Computational problems of analysis of short next generation sequencing reads

Boekhorst¹,

Naumenko²,

Орлова³

et al. 2016

Vestn. VOGiS

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Секвенирование следующего поколения (NGS) с помощью корот ких прочтений ДНК вносит большой вклад в решение задач современной геномики, генетики, клеточной биологии и медицины, особенно в исследования метагеномики, сравни-тельной геномики, определение полиморфизмов, скрининг мутаций, транскриптомное профилирование, изучение ремо-делирования хроматина и многие другие приложения. Секве-ниро вание неустойчиво к техническим ошибкам, которые могут влиять на научные выводы. NGS технологии состоят из создания коллекции многочисленных коротких фрагментов ДНК, имену емой «библиотекой», получения молекулярных колоний и их дальнейшего массового параллельного секвени-рования. Такие секвенированные фрагменты называются «про-чтениями», они собираются (ассемблируются) в протяженные строки. Протяжен ные последовательности, в свою очередь, собираются в геномы для дальнейшего анализа. Вычислитель-ные/процессинговые ошибки и сбои секвенирования -это ошибки, возникающие при последующей цифровой обработке секвенированных образцов. Последующая обработка (процес-сирование) включает процедуры оценки качества, картирова-ния, ассемблирования и даже корректировки ошибочных дан ных. Данная статья рас сматривает вычислительные ошибки процессирования, компью терные и статистические подходы для их определения, а также представляет словарь терминоло-гии секвенирования. Рассмот рены задачи идентификации мутаций («Определение вариаций») в данных секвенирования и контроль качества их определения. Определение вариаций включает локальные вариации, такие как одиночные нуклео-тидные полиморфизмы, короткие вставки и делеции (инделы), и масштабные вариации (инверсии, трансло кации или боль шие Short read next generation sequencing (NGS) has significant impacts on modern genomics, genetics, cell biology and medicine, especially on meta-genomics, comparative genomics, polymorphism detection, mutation screening, transcriptome profiling, methylation profiling, chromatin remodelling and many more applications. However, NGS are prone for errors which complicate scientific conclusions. NGS technologies consist of shearing DNA molecules into collection of numerous small fragments, called a 'library' , and their further extensive parallel sequencing. These sequenced overlapping fragments are called 'reads' , they are assembled into contiguous strings. The contiguous sequences are in turn assembled into genomes for further analysis. Computational sequencing problems are those arising from numerical processing of sequenced samples. The numerical processing involves procedures such as: quality-scoring, mapping/assembling, and surprisingly, error-correction of a data. This paper is reviewing post-processing errors and computational methods to discern them. It also includes sequencing dictionary. We present here quality control of raw data, errors arising at the steps of alignment of sequencing reads to a reference genome and assembly. Finally this work presents identification of mutations ("Variant calling") in sequencing data and its quality control.

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Section: Correction Of Errorssupporting

confidence: 56%

“…However, an error correction might introduce new type of errors: mis-correction errors Fujimoto et al, 2014). And these errors are more difficult to correct back than technological errors.…”

Section: Correction Of Errorsmentioning

confidence: 99%

Computational problems of analysis of short next generation sequencing reads

Boekhorst¹,

Naumenko²,

Орлова³

et al. 2016

Vestn. VOGiS

View full text Add to dashboard Cite

show abstract

“…However, the paper's strong points surprisingly lead a reader to a negative conclusion: the paper sounds very convincing, that one should not introduce new mis-correcting errors. From Fujimoto et al research [245], one can find a conclusion similar to above: error correction methods cannot handle heterozygosity and introduce new mis-corrected errors.…”

Section: Problems and Best Practices To Solve Them In Error-correctionmentioning

confidence: 69%

“…An error correction might introduce new type of errors: miscorrection errors [245,246]. And these errors are harder to correct back than technological errors.…”

Section: Problems and Best Practices To Solve Them In Error-correctionmentioning

confidence: 99%

Computational Errors and Biases in Short Read Next Generation Sequencing

Abnizova¹,

Boekhorst²,

Orlov³

2017

J Proteomics Bioinform

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“…In NA12878 WGS, a 10.1 kb region from HLA-DQB1 harbors 584 phased SNPs, and another 11.7 kb region within HLA-DRB1 contains 249 phased SNPs. This finding has significant implication in biomedical studies, as there is increasing evidence that some diseases are associated with multiple linked variants [ 14 , 52 , 53 ]. Although short reads carry limited phase information if they contain two or more variation sites [ 54 ], long-range phasing through de novo assembly increases the chance of identifying variants linked to complex diseases.…”

Section: Discussionmentioning

confidence: 99%

Comparative analysis of de novo assemblers for variation discovery in personal genomes

Tian

Yan

Klee

et al. 2017

Briefings in Bioinformatics

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Current variant discovery approaches often rely on an initial read mapping to the reference sequence. Their effectiveness is limited by the presence of gaps, potential misassemblies, regions of duplicates with a high-sequence similarity and regions of high-sequence divergence in the reference. Also, mapping-based approaches are less sensitive to large INDELs and complex variations and provide little phase information in personal genomes. A few de novo assemblers have been developed to identify variants through direct variant calling from the assembly graph, micro-assembly and whole-genome assembly, but mainly for whole-genome sequencing (WGS) data. We developed SGVar, a de novo assembly workflow for haplotype-based variant discovery from whole-exome sequencing (WES) data. Using simulated human exome data, we compared SGVar with five variation-aware de novo assemblers and with BWA-MEM together with three haplotype- or local de novo assembly-based callers. SGVar outperforms the other assemblers in sensitivity and tolerance of sequencing errors. We recapitulated the findings on whole-genome and exome data from a Utah residents with Northern and Western European ancestry (CEU) trio, showing that SGVar had high sensitivity both in the highly divergent human leukocyte antigen (HLA) region and in non-HLA regions of chromosome 6. In particular, SGVar is robust to sequencing error, k-mer selection, divergence level and coverage depth. Unlike mapping-based approaches, SGVar is capable of resolving long-range phase and identifying large INDELs from WES, more prominently from WGS. We conclude that SGVar represents an ideal platform for WES-based variant discovery in highly divergent regions and across the whole genome.

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Effects of error-correction of heterozygous next-generation sequencing data

Cited by 14 publications

References 50 publications

Computational problems of analysis of short next generation sequencing reads

Computational problems of analysis of short next generation sequencing reads

Computational Errors and Biases in Short Read Next Generation Sequencing

Comparative analysis of de novo assemblers for variation discovery in personal genomes

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