Optimized data-independent acquisition approach for proteomic analysis at single-cell level

Wang, Yuefan; Lih, Tung-Shing Mamie; Chen, Lijun; Xu, Yuanwei; Kuczler, Morgan D.; Cao, Liwei; Pienta, Kenneth J.; Amend, Sarah R.; Zhang, Hui

doi:10.1186/s12014-022-09359-9

Cited by 20 publications

(13 citation statements)

References 43 publications

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“…Finally, as we are using very short gradients in this work (31 and 58 min methods run-to-run), peptide and protein identifications can be significantly increased by lengthening the runtime as previously tested by others. 16,17 Similarly, we opted not to include library-based searches or cosearching strategies with higher-load samples, not to confound our technical results by those enhancements obtained by search strategies offering ID transfer.…”

Section: Current Limitationsmentioning

confidence: 99%

“…Brunner et al included a similar platform during their recent demonstration of advances in instrument development to analyze single-cell proteomes on a trapped ion mobility mass spectrometer with diaPASEF . Currently, most single-cell proteomics and low-input proteomics studies were performed on an orbitrap mass analyzer instrument ,− or a time-of-flight instrument. ,, Linear ion traps stand as an attractive alternative mass analyzer to orbitraps for low-input applications in mass spectrometry-based proteomics thanks to their increased sensitivity and efficient scanning speed. To enhance the results of data acquisition for low-input quantitative proteomics experiments, data-independent acquisition (DIA) is an attractive approach, as precursor ions are fragmented and acquired independently from their intensity, which makes this acquisition method less biased and reduces missing values compared to data-dependent acquisition (DDA)…”

Section: Introductionmentioning

confidence: 99%

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High Sensitivity Limited Material Proteomics Empowered by Data-Independent Acquisition on Linear Ion Traps

et al. 2022

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In recent years, the concept of cell heterogeneity in biology has gained increasing attention, concomitant with a push toward technologies capable of resolving such biological complexity at the molecular level. For single-cell proteomics using Mass Spectrometry (scMS) and low-input proteomics experiments, the sensitivity of an orbitrap mass analyzer can sometimes be limiting. Therefore, low-input proteomics and scMS could benefit from linear ion traps, which provide faster scanning speeds and higher sensitivity than an orbitrap mass analyzer, however at the cost of resolution. We optimized an acquisition method that combines the orbitrap and linear ion trap, as implemented on a tribrid instrument, while taking advantage of the high-field asymmetric waveform ion mobility spectrometry (FAIMS) pro interface, with a prime focus on low-input applications. First, we compared the performance of orbitrap-versus linear ion trap mass analyzers. Subsequently, we optimized critical method parameters for low-input measurement by data-independent acquisition on the linear ion trap mass analyzer. We conclude that linear ion traps mass analyzers combined with FAIMS and Whisper flow chromatography are well-tailored for low-input proteomics experiments, and can simultaneously increase the throughput and sensitivity of large-scale proteomics experiments where limited material is available, such as clinical samples and cellular subpopulations.

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Section: Current Limitationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High Sensitivity Limited Material Proteomics Empowered by Data-Independent Acquisition on Linear Ion Traps

et al. 2022

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“…For the quantification in figure 2, samples were diluted in buffer A so it is possible that we were integrating background noise because the background is dropping at the same rate as the signal. Finally, as we are using very short gradients in this work (31min and 58min methods run-to-run), peptide and protein identifications can be significantly increased by lengthening the runtime as previously tested by others 16,17 . Similarly, we opted not to include library-based searches or co-searching strategies with higher-load samples, not to confound our technical results by those enhancements obtained by search strategies offering ID transfer.…”

Section: Current Limitationsmentioning

confidence: 92%

“…Brunner et al 5 included a similar platform during their recent demonstration of advances in instrument development to analyze single-cell proteomes on a trapped ion mobility mass spectrometer with diaPASEF 12 . Currently, most single-cell proteomics and low-input proteomics studies were performed on an orbitrap mass analyser instrument 4,[13][14][15][16][17] or a time-of-flight instrument 5,15,18 . Linear ion traps stand as an attractive alternative mass analyzer to orbitraps for low-input applications in mass spectrometry-based proteomics 19 thanks to their increased sensitivity and efficient scanning speed.…”

Section: Introductionmentioning

confidence: 99%

High sensitivity limited material proteomics empowered by data-independent acquisition on linear ion traps

Phlairaharn

Woltereck

Gregoire

et al. 2022

Preprint

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In recent years, the concept of cell heterogeneity in biology has gained increasing attention, concomitant with a push towards technologies capable of resolving such biological complexity at the molecular level. While RNA-based approaches have long been the method of choice, advances in mass spectrometry (MS)-based technologies have led to the ability to resolve cellular proteomes within minute sample quantities and, very recently, even down to a single cell. Current limitations are the incomplete proteome depth achieved and low sample throughput, and continued efforts are needed to push the envelope on instrument sensitivity, improved data acquisition methods, and chromatography. For single-cell proteomics using Mass Spectrometry (scMS) and low-input proteomics experiments, the sensitivity of an orbitrap mass analyzer can sometimes be limiting. Therefore, low-input proteomics and scMS could benefit from linear ion traps, which provide faster scanning speeds and higher sensitivity than an orbitrap mass analyzer, however, at the cost of resolution. We optimized and improved an acquisition method that combines the orbitrap and linear ion trap, as implemented on a tribrid instrument, while taking advantage of the high-field asymmetric waveform ion mobility spectrometry (FAIMS) pro interface, with a prime focus on low-input applications. First, we compared the performance of orbitrap- versus linear ion trap mass analyzers. Subsequently, we optimized critical method parameters for low-input measurement by data-independent acquisition (DIA) on the linear ion trap mass analyzer. We conclude that linear ion traps mass analyzers combined with FAIMS and WhisperTM flow chromatography are well-tailored for low-input proteomics experiments. They can simultaneously increase the throughput and sensitivity of large-scale proteomics experiments where limited material is available, such as clinical samples, cellular sub-populations, and eventually, scMS.

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“…Multiple studies have demonstrated that optimized acquisition methods (such as DIA) led to increased ion utilization which further resulted in enhanced coverage for SCP. 178,179 Together, these improvements drastically enhanced sensitivity resulting in increased protein identification and quantification from single-cell samples.…”

Section: Ms-basedmentioning

confidence: 99%

Recent advances in microfluidics for single-cell functional proteomics

et al. 2023

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Optimized data-independent acquisition approach for proteomic analysis at single-cell level

Cited by 20 publications

References 43 publications

High Sensitivity Limited Material Proteomics Empowered by Data-Independent Acquisition on Linear Ion Traps

High Sensitivity Limited Material Proteomics Empowered by Data-Independent Acquisition on Linear Ion Traps

High sensitivity limited material proteomics empowered by data-independent acquisition on linear ion traps

Recent advances in microfluidics for single-cell functional proteomics

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