A better scoring model for de novo peptide sequencing: the symmetric difference between explained and measured masses

Tschager, Thomas; Rösch, Simon; Gillet, Ludovic; Widmayer, Peter

doi:10.1186/s13015-017-0104-1

Cited by 3 publications

(17 citation statements)

References 26 publications

(38 reference statements)

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“…Notably, however, some peptides were only correctly identified using unprocessed data, suggesting that the deconvolution strategy still needs to be improved. Tschager et al . recently suggested a new scoring model for de novo sequencing, in which the algorithm minimizes the symmetric difference between explained and measured masses.…”

Section: Challenges For Current Methods and Novel Promising Avenuesmentioning

confidence: 99%

A Potential Golden Age to Come—Current Tools, Recent Use Cases, and Future Avenues for De Novo Sequencing in Proteomics

et al. 2018

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In shotgun proteomics, peptide and protein identification is most commonly conducted using database search engines, the method of choice when reference protein sequences are available. Despite its widespread use the database-driven approach is limited, mainly because of its static search space. In contrast, de novo sequencing derives peptide sequence information in an unbiased manner, using only the fragment ion information from the tandem mass spectra. In recent years, with the improvements in MS instrumentation, various new methods have been proposed for de novo sequencing. This review article provides an overview of existing de novo sequencing algorithms and software tools ranging from peptide sequencing to sequence-to-protein mapping. Various use cases are described for which de novo sequencing was successfully applied. Finally, limitations of current methods are highlighted and new directions are discussed for a wider acceptance of de novo sequencing in the community.

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Section: Challenges For Current Methods and Novel Promising Avenuesmentioning

confidence: 99%

A Potential Golden Age to Come—Current Tools, Recent Use Cases, and Future Avenues for De Novo Sequencing in Proteomics

et al. 2018

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“…We briefly describe the algorithm DeNovo [ 14 ] for computing a string of mass M that minimizes without considering retention times. We refer to [ 14 ] for a detailed description and a proof of correctness. Then, we describe algorithms for solving the de novo sequencing problem for each considered prediction model.…”

Section: Methodsmentioning

confidence: 99%

“…Similarly, we do not consider the fragment mass offsets of different ion types in the description. However, we do consider both offsets in the implementation of our algorithms using techniques described in [ 14 ].…”

Section: Problem Definitionmentioning

confidence: 99%

“…We recall the de novo peptide sequencing problem with respect to the symmetric difference scoring model [ 14 ]: Given a mass M and a set of fragment masses X (measured by the mass spectrometer), find a string of mass M that minimizes . Equivalently to computing a string with mass M that minimizes , we can compute a string that maximizes , as X is a fixed input and can be chosen.…”

Section: Problem Definitionmentioning

confidence: 99%

“…In the experimental evaluation, we are primarily interested in the impact of using the retention time information. We compare the identification rates of proposed algorithms for two prediction models with the identification rates of DeNovo [ 14 ], an algorithm that uses the same symmetric difference scoring model, but no retention time information. The symmetric difference scoring model already shows improved identification rates compared to the prevalent shared peak count scoring model [ 5 ] and this is further improved considering the retention time.…”

Section: Introductionmentioning

confidence: 99%

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Improved de novo peptide sequencing using LC retention time information

Frank

Hrúz

Tschager

et al. 2018

Algorithms Mol Biol

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BackgroundLiquid chromatography combined with tandem mass spectrometry is an important tool in proteomics for peptide identification. Liquid chromatography temporally separates the peptides in a sample. The peptides that elute one after another are analyzed via tandem mass spectrometry by measuring the mass-to-charge ratio of a peptide and its fragments. De novo peptide sequencing is the problem of reconstructing the amino acid sequences of a peptide from this measurement data. Past de novo sequencing algorithms solely consider the mass spectrum of the fragments for reconstructing a sequence.ResultsWe propose to additionally exploit the information obtained from liquid chromatography. We study the problem of computing a sequence that is not only in accordance with the experimental mass spectrum, but also with the chromatographic retention time. We consider three models for predicting the retention time and develop algorithms for de novo sequencing for each model.ConclusionsBased on an evaluation for two prediction models on experimental data from synthesized peptides we conclude that the identification rates are improved by exploiting the chromatographic information. In our evaluation, we compare our algorithms using the retention time information with algorithms using the same scoring model, but not the retention time.

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Postnovo: Postprocessing Enables Accurate and FDR-Controlled de Novo Peptide Sequencing

2018

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De novo sequencing offers an alternative to database search methods for peptide identification from mass spectra. Since it does not rely on a predetermined database of expected or potential sequences in the sample, de novo sequencing is particularly appropriate for samples lacking a well-defined or comprehensive reference database. However, the low accuracy of many de novo sequence predictions has prevented the widespread use of the variety of sequencing tools currently available. Here, we present a new open-source tool, Postnovo, that postprocesses de novo sequence predictions to find high-accuracy results. Postnovo uses a predictive model to rescore and rerank candidate sequences in a manner akin to database search postprocessing tools such as Percolator. Postnovo leverages the output from multiple de novo sequencing tools in its own analyses, producing many times the length of amino acid sequence information (including both full- and partial-length peptide sequences) at an equivalent false discovery rate (FDR) compared to any individual tool. We present a methodology to reliably screen the sequence predictions to a desired FDR given the Postnovo sequence score. We validate Postnovo with multiple data sets and demonstrate its ability to identify proteins that are missed by database search even in samples with paired reference databases.

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A better scoring model for de novo peptide sequencing: the symmetric difference between explained and measured masses

Cited by 3 publications

References 26 publications

A Potential Golden Age to Come—Current Tools, Recent Use Cases, and Future Avenues for De Novo Sequencing in Proteomics

A Potential Golden Age to Come—Current Tools, Recent Use Cases, and Future Avenues for De Novo Sequencing in Proteomics

Improved de novo peptide sequencing using LC retention time information

Postnovo: Postprocessing Enables Accurate and FDR-Controlled de Novo Peptide Sequencing

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