LysargiNase enhances protein identification on the basis of trypsin on formalin‐fixed paraffin‐embedded samples

Liu, Shu; Xu, Feng; Yin, Yongguang; Zhang, Junling; Wang, Fuqiang; Li, Yanchang; Xu, Ping

doi:10.1002/rcm.8479

Cited by 7 publications

(6 citation statements)

References 28 publications

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“…In this study, we obtained about 42.5% shared peptides (Figure F), which makes it more feasible to exactly pinpoint phosphosite by combining mirror spectra. The higher number of identified peptides from our LysargiNase was likely due to our self-developed LysargiNase with higher protease activity and stability …”

Section: Resultsmentioning

confidence: 99%

“…The higher number of identified peptides from our LysargiNase was likely due to our self-developed LysargiNase with higher protease activity and stability. 25 The combined spectrum is a pseudo-spectrum generated from mirror spectra between trypsin and LysargiNase. Note that according to our definition of mirror spectra (Supporting Information Figure 2A), the spectra of different phosphosites are not mirror spectra and will not be combined.…”

Section: Complementary Contribution Of Lysarginase To Ion Coveragementioning

confidence: 99%

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Unambiguous Phosphosite Localization through the Combination of Trypsin and LysargiNase Mirror Spectra in a Large-Scale Phosphoproteome Study

Peng

et al. 2020

J. Proteome Res.

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Understanding of the kinase-guided signaling pathways requires the identification and analysis of phosphosites. Mass spectrometry (MS)-based phosphoproteomics is a rapid and highly sensitive approach for high-throughput identification of phosphosites. However, phosphosite determination from MS data with a single protease is more likely to be ambiguous, regardless of the strategy used for phosphopeptide detection. Here, we explored the application of LysargiNase, which was recently reported to mirror trypsin in specificity to cleave arginine and lysine residues exclusively at the N-terminal side. We found that the combination of trypsin and LysargiNase mirror spectra resulted in higher ion coverage in MS2 spectra. The median ion coverage values of b ions in tryptic spectra, LysargiNase spectra, and combined spectra are 8.3, 20.5, and 25.0%, respectively. As for the median ion coverage of y ions, these values are 27.8, 10.0, and 32.3%. Higher ion coverage was helpful to pinpoint the precise phosphosites. Compared to trypsin alone, the combined use of trypsin and LysargiNase mirror spectra enabled 67.1% of mirror spectra with unreliable scores (confidence score <0.75) to become reliable (confidence score ≥ 0.75). Meanwhile, all of the mirror peptide-spectrum matches (PSMs) with multiple potential phosphosites from trypsin and LysargiNase digests could be assigned one precise phosphosite after applying the combination strategy. Besides, the combination strategy could identify more novel phosphosites than the union strategy did. We synthesized three phosphopeptides corresponding to the three novel phosphosites and validated the reliability of the identification. Taken together, our data demonstrated the distinctive potential of the combination strategy presented here for unambiguous phosphosite localization (Project accession PXD011178).

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Section: Resultsmentioning

confidence: 99%

Section: Complementary Contribution Of Lysarginase To Ion Coveragementioning

confidence: 99%

Unambiguous Phosphosite Localization through the Combination of Trypsin and LysargiNase Mirror Spectra in a Large-Scale Phosphoproteome Study

Peng

et al. 2020

J. Proteome Res.

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“…In addition, trypsin is typically used in bottom-up proteomic studies. However, arginine methylation, especially dimethylation, affects the cleavage efficiency of trypsin and subsequently increases miscleavage rate. , The combined effect of methylarginine clustering in protein sequences and miscleavages by trypsin can potentially lead to peptides too long to be identified by MS. Ulilysin (also called LysargiNase), a metalloprotease from Methanosarcina acetivorans, specifically cleaves at the N-terminal of arginine or lysine residues regardless of methylation status, − thus providing an alternative for proteomic profiling of cellular arginine methylation.…”

Section: Introductionmentioning

confidence: 99%

ETD-Based Proteomic Profiling Improves Arginine Methylation Identification and Reveals Novel PRMT5 Substrates

Lu,

Ye,

Zhang

et al. 2024

J. Proteome Res.

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Protein arginine methylations are important posttranslational modifications (PTMs) in eukaryotes, regulating many biological processes. However, traditional collision-based mass spectrometry methods inevitably cause neutral losses of methylarginines, preventing the deep mining of biologically important sites. Herein we developed an optimized mass spectrometry workflow based on electron-transfer dissociation (ETD) with supplemental activation for proteomic profiling of arginine methylation in human cells. Using symmetric dimethylarginine (sDMA) as an example, we show that the ETD-based optimized workflow significantly improved the identification and site localization of sDMA. Quantitative proteomics identified 138 novel sDMA sites as potential PRMT5 substrates in HeLa cells. Further biochemical studies on SERBP1, a newly identified PRMT5 substrate, confirmed the coexistence of sDMA and asymmetric dimethylarginine in the central RGG/RG motif, and loss of either methylation caused increased the recruitment of SERBP1 to stress granules under oxidative stress. Overall, our optimized workflow not only enabled the identification and localization of extensive, nonoverlapping sDMA sites in human cells but also revealed novel PRMT5 substrates whose sDMA may play potentially important biological functions.

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“…12,13 A valuable addition to proteomic workflows, ulilysin produces peptides with the desired N-terminally localized basic centers. Moreover, this protein has been readily implemented in several proteomics workflows ranging from use as a simple substitute for trypsin in conventional workflows (reviewed by Giansanti et al 14 and Trevisiol et al 15 ) to improved characterization of protein termini, 16,17 enhanced protein identification, 18 and improved de novo peptide sequencing. 19,20 Given the utility of enzymes with this dual N-terminal specificity, we sought to find related enzymes, which could be similarly useful while presenting enhanced activity, specificity, and versatility.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Moreover, this protein has been readily implemented in several proteomics workflows ranging from use as a simple substitute for trypsin in conventional workflows (reviewed by Giansanti et al and Trevisiol et al , enhanced protein identification, and improved de novo peptide sequencing. , Given the utility of enzymes with this dual N-terminal specificity, we sought to find related enzymes, which could be similarly useful while presenting enhanced activity, specificity, and versatility. To that end, our approach was to informatically screen for putative proteases with favorable molecular features (described below), characterize their specificity, produce a top candidate via recombinant protein expression, and profile that candidateʼs activity under numerous biochemical conditions.…”

Section: Introductionmentioning

confidence: 99%

Tryp-N: A Thermostable Protease for the Production of N-terminal Argininyl and Lysinyl Peptides

et al. 2020

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Bottom-up proteomics is a mainstay in protein identification and analysis. These studies typically employ proteolytic treatment of biological samples to generate suitably sized peptides for tandem mass spectrometric (MS) analysis. In MS, fragmentation of peptides is largely driven by charge localization. Consequently, peptides with basic centers exclusively on their N-termini produce mainly b-ions. Thus, it was long ago realized that proteases that yield such peptides would be valuable proteomic tools for achieving simplified peptide fragmentation patterns and peptide assignment. Work by several groups has identified such proteases, however, structural analysis of these suggested that enzymatic optimization was possible. We therefore endeavored to find enzymes that could provide enhanced activity and versatility while maintaining specificity. Using these previously described proteases as informatic search templates, we discovered and then characterized a thermophilic metalloprotease with N-terminal specificity for arginine and lysine. This enzyme, dubbed Tryp-N, affords many advantages including improved thermostability, solvent and detergent tolerance, and rapid digestion time.

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LysargiNase enhances protein identification on the basis of trypsin on formalin‐fixed paraffin‐embedded samples

Cited by 7 publications

References 28 publications

Unambiguous Phosphosite Localization through the Combination of Trypsin and LysargiNase Mirror Spectra in a Large-Scale Phosphoproteome Study

Unambiguous Phosphosite Localization through the Combination of Trypsin and LysargiNase Mirror Spectra in a Large-Scale Phosphoproteome Study

ETD-Based Proteomic Profiling Improves Arginine Methylation Identification and Reveals Novel PRMT5 Substrates

Tryp-N: A Thermostable Protease for the Production of N-terminal Argininyl and Lysinyl Peptides

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