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Tao Liu1, Paul Piehowski1, Samuel Payne1, Sangtae Kim1, Jungkap Park1, Christopher Wilkins1, Carrie Nicora1, Yufeng Shen1, Rui Zhao1, Anil Shukla1, Ronald Moore1, Sherri Davies2, Shunqiang Li2, Reid Townsend2, Matthew Ellis3, Emily Boja4, Henry Rodriguez4, Karin Rodland1, and Richard D. Smith1
Introduction
Overview Methods Results
AcknowledgementsThis project was funded by NIH grant U24-CA-160019 from the National Cancer Institute Clinical Proteomic Tumor Analysis Consortium (CPTAC). Samples were analyzed using capabilities developed under this grant and NIGMS Biomedical Technology Research Resource P41GM103493, and performed in the Environmental Molecular Sciences Laboratory, a U.S. Department of Energy (DOE) Office of Biological and Environmental Research (OBER) national scientific user facility on the Pacific Northwest National Laboratory (PNNL) campus. PNNL is a multiprogram national laboratory operated by Battelle for the DOE under contract DE-AC05-76RL01830.
References1. Li et al., Cell Rep. 2013 Sep 26;4(6):1116-30
2. Ntai et al., Mol Cell Proteomics. 2016 Jan;15(1):45-56
ConclusionsComprehensive and reproducible detection of proteoforms
CONTACT: Tao Liu, Ph.D.Biological Sciences DivisionPacific Northwest National LaboratoryE-mail: tao.liu@pnnl.gov
• Many biologically active proteoforms cannot be identified or distinguished by conventional bottom-up approaches since the information is lost with trypsin digestion.
• Integrating data from bottom-up and top-down proteomics measurements with available genomic data enables characterization of protein variants, including coding polymorphisms, processing products, and post-translational modifications.
• There is an urgent need to be able to make comprehensive and reproducible measurements of proteoforms in biological or clinical samples.
• The available patient-derived xenografts (PDX) for two breast cancer subtypes (luminal B and basal)1
provide an ideal system for this evaluation.
• Our top-down proteomics pipeline provided significant improvement in proteome coverage, precision of the quantification, and the ability to identify statistically significant changes on proteoform abundances, in comparison to another recent report that analyzed proteoforms in the same PDX samples2.
• Although still relatively limited in coverage compared to the conventional bottom-up approach, top-down analysis provides a complementary view of the proteome (e.g., truncated and/or post-translationally modified proteoforms, variants, additional protein identifications).
• The top-down, bottom-up, and peptidomics analysis of the same PDX samples showed the same degree of changes in protein/peptide abundances between the two subtypes.
• The top-down measurements provided unique information on up-regulation of many proteoforms of histones and 60S ribosomal proteins as well as key pathway level changes (e.g., glycolysis) in the luminal subtype. This holds great promise in providing new insights into cancer biology.
• Fractionation and new technologies (e.g., SLIM IMS) will greatly improve proteome coverage.
• The widely used bottom-up proteomics approaches in many cases cannot identify or distinguish many different processed and/or modified versions of the gene products whose coverage is important for understanding the development and treatment of cancers.
• Bottom-up proteomics approaches are inherently limited by the “peptide-to-protein” inference problem, affecting both accuracy and precision of the quantification.
• We have recently developed a significantly improved top-down proteomics pipeline that allows for comprehensive quantitative intact proteoform measurements.
• Application of this pipeline to the comparative analysis of PDX models of basal and luminal B human breast cancer provided much improved performance in the ability to obtain both comprehensive proteome coverage, and precise intact proteoform quantification, resulting in novel biological insights otherwise unseen in bottom-up analysis approaches.
www.omics.pnl.govCareer Opportunities: For openings in the Integrative Omics Group at PNNL please visit http://omics.pnl.gov/careers
Washington human-in-mouse (WHIM) PDX samples representing luminal B (P6 and P33) and basal (P5 and P32) breast cancer subtypes
Top-down949 up and 929 down out of
3123 proteoforms at 0.05 FDR
Bottom-up2792 up and 2779 down out of
7412 proteins at 0.05 FDR
Peptidomics215 up and 235 down out of
815 peptides at 0.05 FDR1) clustering isotopomer envelopes across adjacent time and charge state; 2) the initial cluster is refined to accurately determine its elution-time span and range of charge states; 3) calculates the likelihood that the final cluster is an LC-MS feature.
K R A Q K TT R A M
1 Methyl
2 Methyls
1 Methyl, 1 Oxidation
1 Oxidation
2 Oxidations
No modification
Protein Extraction
8 M Urea; 1 mM PMSFPhosphatase inhibitor cocktail
Mechanical homogenizationIncubate 30 min at 37 °C
100 kDa MWCORetain filtrate
Buffer ExchangeLC-MS/MS Analysis
10 kDa MWCO; Buffer A Retain retentate
Acidify lysate: remove proteins incompatible with RPLC
Enrich LMW Proteome
LC: 75 um ID, 80 cm, C2 column, 3-h gradient MS: 240K MS; Top 3 CID MS/MS at 60K (Orbitrap Velos Elite)
Log2-scaled mean abundance)
14 16 18 20 22 24 26 28 30 32
CV
(%
)
0
50
100
150
0 10 20 30 40 50 60 70 80 90 1000
10
20
30
40
50
60
70
80
90
100
CV (%)
Cum
ulat
ive
perc
enta
ge (%
)
*
A total of 7392 differentially expressed, out of 14412 clustered features
Log-2 Fold Change
-10 -5 0 5 10 15
- Log
-2 fa
lse
disc
over
y ra
te
0
5
10
15
20
25
Log-2 Fold Change
-10 -5 0 5 10 15
- Log
-2 fa
lse
disc
over
y ra
te
0
5
10
15
20
25
30
A total of 1780 differentially expressed, out of 3123 proteoforms
Adjusted p-value < 0.01 fold change > 2
Upregulated proteins Downregulated proteinsREACTOME_INFLUENZA_VIRAL_RNA_TRANSCRIPTION_AND_REPLICATION HSIAO_HOUSEKEEPING_GENESREACTOME_PEPTIDE_CHAIN_ELONGATION REACTOME_DIABETES_PATHWAYSREACTOME_VIRAL_MRNA_TRANSLATION KEGG_OXIDATIVE_PHOSPHORYLATIONREACTOME_TRANSLATION KEGG_PARKINSONS_DISEASEREACTOME_REGULATION_OF_GENE_EXPRESSION_IN_BETA_CELLS REACTOME_FORMATION_OF_ATP_BY_CHEMIOSMOTIC_COUPLINGKEGG_RIBOSOME PROTON_TRANSPORTING_TWO_SECTOR_ATPASE_COMPLEXREACTOME_GTP_HYDROLYSIS_AND_JOINING_OF_THE_60S_RIBOSOMAL_SUBUNIT BIOCARTA_PROTEASOME_PATHWAYREACTOME_METABOLISM_OF_PROTEINS REACTOME_GLUCOSE_REGULATION_OF_INSULIN_SECRETIONREACTOME_FORMATION_OF_A_POOL_OF_FREE_40S_SUBUNITS REACTOME_REGULATION_OF_INSULIN_SECRETIONREACTOME_GENE_EXPRESSION REACTOME_INTEGRATION_OF_ENERGY_METABOLISMREACTOME_REGULATION_OF_BETA_CELL_DEVELOPMENT MITOCHONDRIAL_INNER_MEMBRANEREACTOME_INFLUENZA_LIFE_CYCLE MITOCHONDRIAL_ENVELOPESTRUCTURAL_CONSTITUENT_OF_RIBOSOMEREACTOME_INSULIN_SYNTHESIS_AND_SECRETIONSTRUCTURAL_MOLECULE_ACTIVITYREACTOME_PACKAGING_OF_TELOMERE_ENDSREACTOME_RNA_POLYMERASE_I_PROMOTER_OPENINGREACTOME_RNA_POLYMERASE_I_PROMOTER_CLEARANCEREACTOME_TELOMERE_MAINTENANCEREACTOME_TRANSLATION_INITIATION_COMPLEX_FORMATIONREACTOME_PROCESSING_OF_CAPPED_INTRON_CONTAINING_PRE_MRNAREACTOME_RNA_POLYMERASE_I_III_AND_MITOCHONDRIAL_TRANSCRIPTIONREACTOME_TRANSCRIPTIONKEGG_SPLICEOSOMEKEGG_OXIDATIVE_PHOSPHORYLATIONREACTOME_INTEGRATION_OF_ENERGY_METABOLISMREACTOME_PREFOLDIN_MEDIATED_TRANSFER_OF_SUBSTRATE_TO_CCT_TRICREACTOME_ELECTRON_TRANSPORT_CHAINREACTOME_MRNA_SPLICING_MINOR_PATHWAYNUCLEOBASENUCLEOSIDENUCLEOTIDE_AND_NUCLEIC_ACID_METABOLIC_PROCESS
Fisher exact testadjusted p value <0.05
Many proteoforms of histones and 60S ribosomal proteins showed upregulation in the luminal subtype
Green: KEGG defaultBlue: up in luminalRed: up in basalGrey: mixedBlank: not in human
Warburg Effect
Bottom-up7412
Top-down867
Peptidomics429
123
370
17731
Precise quantification of the proteoforms
Separation of the two BrCa subtypes
Comparison of top-down, bottom-up, and peptidomics results
Top-down vs. bottom-up: Enriched pathways
Example: Affected pathwaysLC-MS feature finding in ProMex
Sample preparation
Proteoform ID by sequence graphs
Comprehensive, Quantitative, Intact Proteoform Measurements of Patient-Derived Breast Tumor Xenografts Using an Improved Top-Down Proteomics Pipeline
1Biological Sciences Division, Pacific Northwest National Laboratory, Richland, WA; 2Department of Medicine, Washington University, St. Louis, MO; 3Department of Molecular and Cellular Biology, Baylor College of Medicine, Houston, TX; 4National Cancer Institute, National Institutes of Health, Bethesda, MD
P32: basal (WHIM2) P33: luminal B (WHIM16) Over 90% of all detected clustered features have CV <30% in abundance
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