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Multiple flavors of mass analyzers Single MS (peptide fingerprinting): Identifies m/z of peptide only Peptide id’d by comparison to database, of predicted.

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Presentation on theme: "Multiple flavors of mass analyzers Single MS (peptide fingerprinting): Identifies m/z of peptide only Peptide id’d by comparison to database, of predicted."— Presentation transcript:

1 Multiple flavors of mass analyzers Single MS (peptide fingerprinting): Identifies m/z of peptide only Peptide id’d by comparison to database, of predicted m/z of trypsinized proteins Tandem MS/MS (peptide sequencing): Pulls each peptide from the first MS Breaks up peptide bond Identifies each fragment based on m/z Collision cell 1 Now multiple types of collision cells: CID: collision induced dissociation ETD: electron transfer dissociation HCD: high-energy collision dissociation

2 Mass SpecMS Spectrum Ion sourceMass analyzerDetector Intro to Mass Spec (MS) Separate and identify peptide fragments by their Mass and Charge (m/z ratio) Basic principles: 1. Ionize (i.e. charge) peptide fragments 2. Separate ions by mass/charge (m/z) ratio 3. Detect ions of different m/z ratio 4. Compare to database of predicted m/z fragments for each genome 2

3 Mann Nat Reviews MBC. 5:699:711 3 How does each spectrum translate to amino acid sequence?

4 1.De novo sequencing: very difficult and not widely used (but being developed) for large-scale datasets 2.Matching observed spectra to a database of theoretical spectra 3.Matching observed spectra to a spectral database of previously seen spectra How does each spectrum translate to amino acid sequence? 4

5 Nesvizhskii (2010) J. Proteomics, 73:2092- 2123. -spectral matching is supposedly more accurate but … -limited to the number of peptides whose spectra have been observed before With either approach, observed spectra are processed to: group redundant spectra, remove bad spectra, recognized co-fragmentation, improve z estimates Many good spectra will not match a known sequence due to: absence of a target in DB, PTM modifies spectrum, constrained DB search, incorrect m or z estimate. 5

6 Result: peptide-to-spectral match (PSM) A major problem in proteomics is bad PSM calls … therefore statistical measures are critical Methods of estimating significance of PSMs: p- (or E-) value: compare score S of best PSM against distribution of all S for all spectra to all theoretical peptides FDR correction methods: 1.B&H FDR 2.Estimate the null distribution of RANDOM PSMs: - match all spectra to real (‘target’) DB and to fake (‘decoy) DB - often decoy DB is the same peptides in the library but reverse sequence one measure of FDR: 2*(# decoy hits) / (# decoy hits + # target hits) 3. Use #2 above to calculate posterior probabilities for EACH PSM 6

7 - mixture model approach: take the distribution of ALL scores S - this is a mixture of ‘correct’ PSMs and ‘incorrect’ PSMs - but we don’t know which are correct or incorrect - scores from decoy comparison are included, which can provide some idea of the distribution of ‘incorrect’ scores -EM or Bayesian approaches can then estimate the proportion of correct vs. incorrect PSM … based on each PSM score, a posterior probability is calculated FDR can be done at the level of PSM identification … but often done at the level of Protein identification 7

8 Error in PSM identification can amplify FDR in Protein identification Often focus on proteins identified by at least 2 different PSMs (or proteins with single PSMs of very high posterior probability) Nesvizhskii (2010) J. Proteomics, 73:2092- 2123. Some methods combine PSM FDR to get a protein FDR 8

9 Some practical guidelines for analyzing proteomics results 1.Know that abundant proteins are much easier to identify 2.# of peptides per protein is an important consideration - proteins ID’d with >1 peptide are more reliable - proteins ID’d with 1 peptide observed repeatedly are more reliable - note than longer proteins are more likely to have false PSMs 3.Think carefully about the p-value/FDR and know how it was calculated 4.Know that proteomics is no where near saturating … many proteins will be missed 9

10 Quantitative proteomics 1.Spectral counting 2.Isotope labeling (SILAC) 3.Isobaric tagging (iTRAQ & TMT) 4.SRM Either absolute measurements or relatively comparisons 10

11 Spectral counting counting the number of peptides and counts for each protein Challenges: - different peptides are more (or less) likely to be assayed - analysis of complex mixtures often not saturating – may miss some peptides in some runs newer high-mass accuracy machines alleviate these challenges - quantitation comes in comparing separate mass-spec runs … therefore normalization is critical and can be confounded by error - requires careful statistics to account for differences in: quality of run, likelihood of observing each peptide, likelihood of observing each protein (eg. based on length, solubility, etc) Advantages / Challenges + label-free quantitation; cells can be grown in any medium - requires careful statistics to quantify - subject to run-to-run variation / error 11

12 SILAC (Stable Isotope Labeling with Amino acids in Cell culture) Cells are grown separately in heavy ( 13 C) or light ( 12 C) amino acids (often K or R), lysates are mixed, then analyzed in the same mass-spec run Mass shift of one neutron allows deconvolution, and quantification, of peaks in the same run. Advantages / Challenges: + not affected by run-to-run variation - need special media to incorporate heavy aa’s, - can only compare (and quantify) 2 samples directly - incomplete label incorporation can confound MS/MS identification 12

13 Isobaric Tagging iTRAQ or Tandem Mass Tags, TMTs LTQ Velos Orbitrap Each peptide mix covalently tagged with one of 4, 6, or 8 chemical tags of identical mass Samples are then pooled and analyzed in the same MS run Collision before MS 2 breaks tags – Tags can be distinguished in the small-mass range and quantified to give relative abundance across up to 8 samples. Advantages / Challenges: + can analyze up to 8 samples, same run - still need to deal with normalization 13

14 Selective Reaction Monitoring (SRM) Targeted proteomics to quantify specific peptides with great accuracy -Specialized instrument capable of very sensitively measuring the transition of precursor peptide and one peptide fragment -Typically dope in heavy-labeled synthetic peptides of precisely known abundance to quantify Advantages: - best precision measurements Disadvantages: - need to identify ‘proteotypic’ peptides for doping controls - expensive to make many heavy peptides of precise abundance - limited number of proteins that can be analyzed 14

15 Phospho-proteomics and Post-translational modifications (PTMs) 15 phosphorylated (P’d) peptides are enriched, typically through chromatography - P’d peptides do not ionize as well as unP’d peptides - enrichment of P’d peptides ensures ionization and aids in mapping IMAC: immobilized metal ion affinity chromatography - phospho groups bind charged metals - contamination by negatively-charged peptides Titanium dioxide (TiO 2 ) column: - binds phospho groups (mono-P’d better than multi-P’d) SIMAC: Sequential Elution from IMAC: - IMAC followed by TiO 2 column Goal: identify which residues are phosphorylated (Ser, Thr, Tyr), mapped based on known m/z of phospho group

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