One gene can give rise to many functionally distinct proteoforms, each of which has a characteristic molecular mass. Top-down mass spectrometry enables the analysis of intact proteins and proteoforms. Here members of the Consortium for Top-Down Proteomics provide a decision tree that guides researchers to robust protocols for mass analysis of intact proteins (antibodies, membrane proteins and others) from mixtures of varying complexity. We also present cross-platform analytical benchmarks using a protein standard sample, to allow users to gauge their proficiency.
Use of cyclooxygenase inhibitors and ligation for PDA in VLBW infants decreased over a 10-y period at the studied hospitals. Further evidence is needed to assess the impact of this change in PDA management.
Proteomic analysis of limited samples and single cells requires specialized methods that prioritize high sensitivity and minimize sample loss. Consequently, sample preparation is one of the most important steps in limited sample analysis workflows to prevent sample loss. In this work, we have eliminated sample handling and transfer steps by processing intact cells directly in the separation capillary, online with capillary electrophoresis coupled to tandem mass spectrometry (CE-MS/MS) for top-down proteomic (TDP) analysis of low numbers of mammalian cancer cells (<10) and single cells. We assessed spray voltage injection of intact cells from a droplet of cell suspension (∼1000 cells) and demonstrated 0−9 intact cells injected with a dependency on the duration of spray voltage application. Spray voltage applied for 2 min injected an average of 7 ± 2 cells and resulted in 33−57 protein and 40−88 proteoform identifications (N = 4). To analyze single cells, manual cell loading by hydrodynamic pressure was used. Replicates of single HeLa cells (N = 4) lysed on the capillary and analyzed by CE-MS/MS demonstrated a range of 17−40 proteins and 23−50 proteoforms identified. An additional cell line, THP-1, was analyzed at the single-cell level, and proteoform abundances were compared to show the capabilities of single-cell TDP (SC-TDP) for assessing cellular heterogeneity. This study demonstrates the initial application of TDP in single-cell proteome-level profiling. These results represent the highest reported identifications from TDP analysis of a single HeLa cell and prove the tremendous potential for CE-MS/MS on-capillary sample processing for high sensitivity analysis of single cells and limited samples.
In this work, we developed an ultra-sensitive CE-MS/ MS method for bottom-up proteomics analysis of limited samples, down to sub-nanogram levels of total protein. Analysis of 880 and 88 pg of the HeLa protein digest standard by CE-MS/MS yielded ∼1100 ± 46 and ∼160 ± 59 proteins, respectively, demonstrating higher protein and peptide identifications than the current state-ofthe-art CE-MS/MS-based proteomic analyses with similar amounts of sample. To demonstrate potential applications of our ultrasensitive CE-MS/MS method for the analysis of limited biological samples, we digested 500 and 1000 HeLa cells using a miniaturized in-solution digestion workflow. From 1-, 5-, and 10-cell equivalents injected from the resulted digests, we identified 744 ± 127, 1139 ± 24, and 1271 ± 6 proteins and 3353 ± 719, 5709 ± 513, and 8527 ± 114 peptide groups, respectively. Furthermore, we performed a comparative assessment of CE-MS/MS and two reversed-phased nano-liquid chromatography (RP-nLC-MS/MS) methods (monolithic and packed columns) for the analysis of a ∼10 ng HeLa protein digest standard. Our results demonstrate complementarity in the protein-and especially peptide-level identifications of the evaluated CE-MS-and RP-nLC-MS-based methods. The techniques were further assessed to detect post-translational modifications and highlight the strengths of the CE-MS/ MS approach in identifying potentially important and biologically relevant modified peptides. With a migration window of ∼60 min, CE-MS/MS identified ∼2000 ± 53 proteins on average from a single injection of ∼8.8 ng of the HeLa protein digest standard. Additionally, an average of 232 ± 10 phosphopeptides and 377 ± 14 N-terminal acetylated peptides were identified in CE-MS/MS analyses at this sample amount, corresponding to 2-and 1.5-fold more identifications for each respective modification found by nLC-MS/MS methods.
In this work, we pioneered the assessment of coupling
high-field
asymmetric waveform ion mobility spectrometry (FAIMS) with ultrasensitive
capillary electrophoresis hyphenated with tandem mass spectrometry
(CE-MS/MS) to achieve deeper proteome coverage of low nanogram amounts
of digested cell lysates. An internal stepping strategy using three
or four compensation voltages per analytical run with varied cycle
times was tested to determine optimal FAIMS settings and MS parameters
for the CE-FAIMS-MS/MS method. The optimized method applied to bottom-up
proteomic analysis of 1 ng of HeLa protein digest standard identified
1314 ± 30 proteins, 4829 ± 200 peptide groups, and 7577
± 163 peptide spectrum matches (PSMs) corresponding to a 16,
25, and 22% increase, respectively, over CE-MS/MS alone, without FAIMS.
Furthermore, the percentage of acquired MS/MS spectra that resulted
in PSMs increased nearly 2-fold with CE-FAIMS-MS/MS. Label-free quantitation
of proteins and peptides was also assessed to determine the precision
of replicate analyses from FAIMS methods with increased cycle times.
Our results also identified from 1 ng of HeLa protein digest without
any prior enrichment 76 ± 9 phosphopeptides, 18% of which were
multiphosphorylated. These results represent a 46% increase in phosphopeptide
identifications over the control experiments without FAIMS yielding
2.5-fold more multiphosphorylated peptides.
Through small changes in oximeter alarm settings, including revision of alarm limits, alarm delays, and age-specific alarm profiles, our NICUs significantly reduced nonactionable alarms without increasing hypoxemia.
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