1. Proteomics Informatics David Fenyő

2. Course Information

3. Protein Identification and Quantitation
Samples
Peptides
Mass
Spectrometry
Quantity
intensity
m/z
Identity

4. Central Dogma of Molecular Biology
Transcription
Replication
Translation
Modification P

5. X X Central Dogma of Molecular Biology Slow Fast P Transcription
Replication
Slow
Degradation
Translation X
Fast
Degradation
Modification P X

6. Motivating Example: Protein Regulation
GRB7
ERBB4
Breast
Cancer
ERBB2
ERBB2
GRB7
ERBB4
ERBB2
ERBB2
GRB7
ERBB4
ERBB2
ERBB2

7. Motivating Example: Protein Complexes
Alber et al., Nature 2007

8. Motivating Example: Signaling
Choudhary & Mann, Nature Reviews Molecular Cell Biology 2010

9. Identified and Quantified Proteins
Mass Spectrometry Based Proteomics
Lysis
Fractionation
Digestion
Mass spectrometry
Peak Finding
Charge determination
De-isotoping
Integrating Peaks
Searching MS
Identified and Quantified Proteins

10. Ion Source Mass Analyzer Detector Mass Spectrometry intensity
mass/charge

11. y b Mass Spectrometry Mass Analyzer 1 Frag-mentation Detector
Ion Source
Mass Analyzer 2 y b

12. Example data – ESI-LC-MS/MS
m/z
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022
MS/MS
Time

13. Information Content in a Single Mass Measurement
Human 10 8 6
Avg. #of matching peptides 4 3 2 1
#of matching peptides
Tryptic peptide mass [Da]
S. cerevisiae 10 8 6
Avg. #of matching peptides 4 3 2 1
#of matching peptides
Tryptic peptide mass [Da]

14. Compare, score, test significance Identified peptides and proteins
Protein Identification by Mass Spectrometry
Samples
Peptides
MS/MS
Protein DB
Compare, score, test significance
Identified peptides and proteins

15. Repeat for all proteins Compare, Score, Test Significance
Tandem MS – Database Search
Sequence DB
Lysis
Fractionation
Pick Protein
Digestion
LC-MS
Pick Peptide
Repeat for all proteins
MS/MS
All Fragment
Masses
all peptides
Repeat for
MS/MS
Compare, Score, Test Significance

16. Search Results

17. Search Results
Most proteins show very reproducible peptide patterns

18. Search Results

19. Compare, Score, Test Significance
Spectrum Library Search
Spectrum
Library
Lysis
Fractionation
Digestion
LC-MS/MS
Pick
Spectrum
all spectra
Repeat for
MS/MS
Compare, Score, Test Significance
Identified Proteins

20. Interpretation of Mass SpectraK L E D F G S
m/z
% Relative Abundance
100
250
500
750
1000

21. Interpretation of Mass SpectraK L E D F G S K
1166 L
1020 E
907 D
778
663
534
405 F
292 G
145 S 88
b ions
m/z
% Relative Abundance
100
250
500
750
1000

22. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000

23. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022

24. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022

25. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022
113
113

26. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022
129
129

27. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022

28. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022

29. Interpretation of Mass SpectraK L E D F G S
147 K
1166 L
260
1020 E
389
907 D
504
778
633
663
762
534
875
405 F
1022
292 G
1080
145 S 88
y ions
b ions
m/z
% Relative Abundance
100
250
500
750
1000
[M+2H]2+
762
260
389
504
633
875
292
405
534
907
1020
663
778
1080
1022

30. De Novo Sequencing Sequences consistent with spectrum
Amino acid masses
762
100
875
[M+2H]2+
% Relative Abundance
633
292
405
260
389
534
1022
504
663
778
907
1020
1080
250
500
750
1000
m/z
Mass Differences
Sequences
consistent
with spectrum

31. Significance Testing
False protein identification is caused by random matching
An objective criterion for testing the significance of protein identification results is necessary.
The significance of protein identifications can be tested once the distribution of scores for false results is known.

32. C I Protein Quantitation by Mass Spectrometry Sample i Protein j Lysisij
Protein j
Lysis
Peptide k
Fractionation
Digestion MS I LC - MS ik

33. Protein Quantitation by Mass Spectrometry

34. Protein Quantitation by Mass Spectrometry

35. Protein Quantitation by Mass Spectrometry

36. Protein Quantitation by Mass Spectrometry
Light
Heavy
Lysis
Assumption: All losses after mixing are identical for the heavy and light isotopes and
Fractionation
Digestion
Sample i
Protein j
Peptide k
LC-MS MS H L
Oda et al. PNAS 96 (1999) 6591
Ong et al. MCP 1 (2002) 376

37. Protein Quantitation MS MS MS/MS MS/MS LC-MS Digestion Fractionation
Shotgun proteomics
LC-MS
Targeted MS
1. Records M/Z
1. Select precursor ion MS MS
Digestion
2. Selects peptides based on abundance and fragments
Fractionation
2. Precursor fragmentation
MS/MS
MS/MS
Lysis
3. Protein database search for peptide identification
3. Use Precursor-Fragment pairs for identification
Data Dependent Acquisition (DDA)
Uses predefined set of peptides

39. Compare, score, test significance Identified peptides and proteins
Proteogenomics
Samples
Peptides
MS/MS
Protein DB
Compare, score, test significance
Identified peptides and proteins

40. Proteogenomics Next-generation sequencing of the genome Samples
and transcriptome
Samples
Peptides
MS/MS
Sample-specific
Protein DB
Compare, score, test significance
Identified peptides and proteins

41. Proteogenomics Non-Tumor Sample Genome sequencing
Identify germline variants
Genome sequencing
RNA-Seq
Tumor Sample
Identify alternative splicing,
somatic variants and
novel expression
TCGAGAGCTG
TCGATAGCTG
Exon 1
Exon 2
Exon 3
Variants
Alt. Splicing
Novel Expression
Exon X
Fusion Genes
Gene X
Gene Y
Tumor Specific
Protein DB
Reference Human Database (Ensembl)

42. Proteogenomics
ERBB2
Breast
Cancer
Breast

43. Proteogenomics
ERBB2
Breast
Cancer
Breast
Ovarian
Cancer

44. Posttranslational Modifications
Peptide with two possible modification sites
Matching
MS/MS spectrum
Intensity
m/z
Which assignment does
the data support?
1, or 2, or 1 and 2?

45. Protein Interactions Digestion Mass spectrometry Identification E F AB
Digestion
Mass spectrometry
Identification

46. Data Analysis - Normalization
Normalized:
mean=0, std=1
Raw Data

47. Data Analysis - Normalization
Normalized
3 replicates
Normalized
3 replicates +
one more
replicate a
few months
later

48. Data Analysis

49. FDA calls them “in vitro diagnostic multivariate assays”
Molecular Markers
A molecular signature is a computational or mathematical model that links high-dimensional molecular information to phenotype or other response variable of interest.
FDA calls them “in vitro
diagnostic multivariate assays”