Post on 21-Mar-2020
Clinical Proteomics:Clinical Proteomics:A Technology to shape the future?A Technology to shape the future?
Cyprus, Nov, 2010
Protein ChemistryProtein Chemistry//Proteomics/PeptideProteomics/PeptideSynthesisSynthesis and and ArrayArray UnitUnit
Institute of Biomedicine/AnatomyInstitute of Biomedicine/Anatomy
BiomedicumBiomedicum HelsinkiHelsinki, 00014 University of , 00014 University of Helsinki, FinlandHelsinki, Finland
E-Mail: marc.baumann@helsinki.fi
(http://research.med.helsinki.fi/corefacilities/proteinchem)
Over 1200 Researchers in only Medical Research(Cancer, Genetics, Developmental Medicine, Neuroscience etc.)
The Medical FacultyThe Medical Faculty
ProteomicsProteomics
What is it all about??What is it all about??
Proteomics in prostate cancer.
Banez LL, Srivastava S, Moul JW.
Center for Prostate Disease Research, Department of Surgery, Uniformed Services University of the Health Sciences, Rockville, Maryland, USA bDivision of Urology, Department of Surgery, Duke University Medical Center, Durham, North
Carolina, USA.
Curr Opin Urol. 2005 May;15(3):151-6.
Mol Cell Proteomics. 2005 Apr;4(4):345.
Proteomics of disease.
Celis JE, Korc M.
We know whatWe know what GenomicsGenomics is!is!
But, wBut, what hat is is ProteomicsProteomics??
2001: Human Genome Project Reveals
3,000,000,000 base pair nucleotides
= only 25,000 genes
=
Only 0.1% of each’s persons DNA differs from any other person
=
And that …And that …
The study of the Proteins expressed by a Genome
= Proteome
= Proteins
So… what makes the Difference?So… what makes the Difference?
same Genome - different Proteome
How can we study Proteomics?How can we study Proteomics?
The technology...The technology...
2D gel electrophoresis2D gel electrophoresis2D liquid chromatography2D liquid chromatography
Micro arraysMicro arrays
An An exampleexample
A technology to find changes in A technology to find changes in ProteomeProteome
Administration of a drug known to bind to an orphan receptor
• Changes in expression level of 23 proteins
A protein Array
TwoTwo--dimensional gel dimensional gel electrophoresis (2D)electrophoresis (2D)
1st dimension, IEF, Proteins are separatedaccording to their isoelectric point (IP) 2nd dimension, SDS-PAGE, Proteins are separated according to their molecular mass Efficient: More than a thousand proteins resolved in E-Coli cell lysates and ~8000 in brain lysates
pH 10
SDS-
PAG
E
pH 3
1st Dimension - Isoelectric Focusing
pH4 pH7
+ -+
pH5.5neutral
pI - isoelectric point
ready made Gel-strips
gelsurface
2DEMw
2nd Dimension - Isoelectric Focusing
Protein Fingerprint: 2Protein Fingerprint: 2--DEDE
pI 6.94.1
Mr(kDa)
200
15
AboutAbout 20002000proteinsproteins
2D-PAGE Direct In-situ Digest
To identify the separated proteins
Basic (+) Acidic (-)
#7
100 fmolrunning the gel- staining each spot of interest ( )- excise- in-gel digestion
PEPTIDE ANALYSIS
Trypsin digest
MALDI TOF/TOF
MALDI-TOF-MS
High Sample Throughput for thePost-Genomic Era
MALDI TOF
Schematic diagram of a Reflector MALDI-TOF mass spectrometer.
MALDI-TOF = Matrix Assisted Laser Desorption/Ionization -Time Of Flight
MALDI TOF/TOF
Quadrupole TOF/TOF
Quadrupole TOF/TOF
Quadrupole TOF/TOF
Typical mass spectrum from a protein band trypsin digest
1 RALRRAPALA AVPGGKPILC PRRTTAQLGP RRNPAWSLQA GRLFSTQTAE51 DKEEPLHSII SSTESVQGST SKHEFQAETK KLLDIVARSL YSEKEVFIRE101 LISNASDALE KLRHKLVSDG QALPEMEIHL QTNAEKGTIT IQDTGIGMTQ151 EELVSNLGTI ARSGSKAFLD ALQNQAEASS KIIGQFGVGF YSAFMVADRV201 EVYSRSAAPG SLGYQWLSDG SGVFEIAEAS GVRTGTKIII HLKSDCKEFS 251 SEARVRDVVT KYSNFVSFPL YLNGRRMNTL QAIWMMDPKD VGEWQHEEFY 301 RYVAQAHDKP RYTLHYKTDA PLNIRSIFYV PDMKPSMFDV SRELGSSVAL351 YSRKVLIQTK ATDILPKWLR FIRGVVDSED IPLNLSRELL QESALIRKLR401 DVLQQRLIKF FIDQSKKDAE KYAKFFEDYG LFMREGIVTA TEQEVKEDIA451 KLLRYESSAL PSGQLTSLSE YASRMRAGTR NIYYLCAPNR HLAEHSPYYE501 AMKKKDTEVL FCFEQFDELT LLHLREFDKK KLISVETDIV VDHYKEEKFE551 DRSPAAECLS EKETEELMAW MRNVLGSRVT NVKVTLRLDT HPAMVTVLEM601 GAARHFLRMQ QLAKTQEERA QLLQPTLEIN PRHALIKKLN HCAQASLAWL651 SCWWIRYTRT P
Number 1 match: tumor necrosis factor type 1 receptor associated protein TRAP-1 (Mr): 76030.27
Automated Database Search (MASCOT)Automated Database Search (MASCOT)
Total coverage: 33.4%
Even a single peptide is enough Even a single peptide is enough for Protein identification!for Protein identification!
We can do a peptide amino acid We can do a peptide amino acid sequence analysis by mass sequence analysis by mass
spectrometry!spectrometry!
2D-PAGE Direct In-situ Digest
(Unknown protein identification)
Basic (+) Acidic (-)
#7
100 fmolrunning the gel- staining each spot of interest ( )- excise- in-gel digestion
PEPTIDE ANALYSIS
Trypsin digest but take a single peptide to the MS!
MALDI MS TOF/TOF or Quadrupole MS TOF/TOF
MS-MS
Fragmentation of a single peptide inthe Mass Spectrometer
>>>> Database search
>>>> Identification of the whole protein
Number 1 match: tumor necrosis factor type 1 receptor associated protein TRAP-1 (Mr): 76030.27
Automated Database Search (MASCOT)Automated Database Search (MASCOT)
Sequence successfully identified
1 RALRRAPALA AVPGGKPILC PRRTTAQLGP RRNPAWSLQA GRLFSTQTAE51 DKEEPLHSII SSTESVQGST SKHEFQAETK KLLDIVARSL YSEKEVFIRE101 LISNASDALE KLRHKLVSDG QALPEMEIHL QTNAEKGTIT IQDTGIGMTQ151 EELVSNLGTI ARSGSKAFLD ALQNQAEASS KIIGQFGVGF YSAFMVADRV201 EVYSRSAAPG SLGYQWLSDG SGVFEIAEAS GVRTGTKIII HLKSDCKEFS 251 SEARVRDVVT KYSNFVSFPL YLNGRRMNTL QAIWMMDPKD VGEWQHEEFY 301 RYVAQAHDKP RYTLHYKTDA PLNIRSIFYV PDMKPSMFDV SRELGSSVAL351 YSRKVLIQTK ATDILPKWLR FIRGVVDSED IPLNLSRELL QESALIRKLR401 DVLQQRLIKF FIDQSKKDAE KYAKFFEDYG LFMREGIVTA TEQEVKEDIA451 KLLRYESSAL PSGQLTSLSE YASRMRAGTR NIYYLCAPNR HLAEHSPYYE501 AMKKKDTEVL FCFEQFDELT LLHLREFDKK KLISVETDIV VDHYKEEKFE551 DRSPAAECLS EKETEELMAW MRNVLGSRVT NVKVTLRLDT HPAMVTVLEM601 GAARHFLRMQ QLAKTQEERA QLLQPTLEIN PRHALIKKLN HCAQASLAWL651 SCWWIRYTRT P
What can Proteomics give us?What can Proteomics give us?
A typical case...A typical case...
ColorectalColorectal CryptCrypt -- PhysiologyPhysiology andand TransformationTransformation
Stem cells are located in the lower crypt poles, colonocytes are migrating to the surface of the crypt
Continuelly replacement in the toxic and mechanically stressing environment of the gut
Hyperproliferation is believed to precede adenoma formation
Loss of APC function leads to deregulated crypt homeostasis and is thought to be the initiating event in adenoma formation
Correlation of Histological Progression and MolecularChanges in Colorectal Cancer
Normal mucosa
Aberrant crypt foci
Early adenoma
Late adenoma
Invasive carcinoma
Metastasis
APC, -catenin mutation
K-ras mutation
18q loss, p53 mutation
Nm23 mut.
Samples
Normal
Polyp
Carcinoma
Liver metastasis
Tissue microdissection
Why Tissue Microdissection?
Normal Tissue
Tumor Tissue
You would like to isolate only the targeted diseased tissue
Laser-based microdissection:
Laser Capture Microdissection Laser Capture Microdissection (Arcturus Autopix)(Arcturus Autopix)
Laser Capture MicrodissectionLaser Capture Microdissection
Emmert-Buck et al (1996) Laser Capture Microdissection Science, Vol 274, Nro 8, p998-1001
Capturing of the vessels in the control Capturing of the vessels in the control brain slidebrain slide
Slide before capture
Slide after capture Cap with the selected tissue
Cap
*
Why Tissue Microdissection?
Cryostat section
Normal Tissue
Tumor Tissue
MALDI MS MALDI MS analysisanalysis directlydirectly fromfrom the the tissuetissuecapturedcaptured on the on the capcap membranemembrane
Electron micrograph, dermal artery with Electron micrograph, dermal artery with some granular osmiophilic materialsome granular osmiophilic material (GOM)(GOM)
CADASILdisease
Scanning/ Gel-Matching /Imageanalysis
Normal
Polyp
Tumor
Mass spectrometrical identification Statistics
NP
T M1st Dimension
2nd Dimension PC based matchingSample enrichment/preparation
2-DE Algorithm
PrincipalComponent
Analysis(t1,t2,t3)
normalnormalmetastasismetastasis
tumortumor
polyppolyp
N P T M N P T M
N=26 N=46
Deviating Proteins (n=112)Identification of 72
Controls: normal liver tissueHCT116 and Lovo cell lines
benign benignmaligne maligne
The left gel segment (a) is zoomed from the normal mucosa,
gel b represents the patients polyp and
gel c is the corresponding segment of the same patients adenocarcinoma
a b c
CR174N CR173P CR172T
Intra-individual expression differences of Cytokeratin 20 in patient 14.
EttanEttanTMTM DiGEDiGEthe quantitative approach to the quantitative approach to
do Proteomicsdo Proteomics
CyDye DIGE Fluor dyesMinimal labelling dyes
Label 50 µg of protein
3 colors: Cy™2, Cy3, Cy5
MW matched (~450Da)
Charge matched (positive)
Label -amino group of lysine
Sensitivity - 0.025 ng
Linear dynamic range over 4 orders of magnitude
Ettan™ DIGE systemAchieving accurate quantitative data
Protein extract 1label with Cy3
Pooled internalstandard label with Cy™2
Protein extract 2label with Cy5
Mix labelled extracts
2-DEseparation
Cy5
Typhoon™Variable Mode Imager
Cy3
Cy2
DeCyder™ Differential AnalysisSoftware
Overlay of normal and patient Overlay of normal and patient protein samplesprotein samples
Normal control = CyTM3 labelled - Blue
Patient A sample = Cy5 Labelled - Red
Increased abundance
Equal abundance
Reduced abundance
Also 2D Databases exist!
Protein Fingerprint: 2Protein Fingerprint: 2--DEDE
pI 6.94.1
Mr(kDa)
200
15
AboutAbout 20002000proteinsproteins
An Analytical Challenge = What about having thousands of proteins in the sample and the need
for automation?
Yeast database search reveals:
6,188 potential proteins
tryptic digestion
344,855 peptides
2D2D--LC/MS/MSLC/MS/MS(2(2--dimensional liquid chromatography mass spectrometry)dimensional liquid chromatography mass spectrometry)
Faster Protein Identification by MS/MSFaster Protein Identification by MS/MS
2D2D--LC/MS/MSLC/MS/MSInstrumental SetInstrumental Set--up SCX/RP/RPup SCX/RP/RP
Loading20 µl/min
Sample & Salt Plugs
µ-Precolumn300 µm i.d. x 1 mm, C8
Nano column75 µm i.d. x 15 cm, C18
Nano LCgradient
Z
SCX µ-Column300 µm i.d. x 5 mm Waste
z
Waters 2D-nano UPLC aquity LC
Loading20 µl/min
Sample & Salt Plugs
µ-Precolumn300 µm i.d. x 1 mm, C8
Nano column75 µm i.d. x 15 cm, C18
Nano LCgradient
Z
SCX µ-Column300 µm i.d. x 5 mm Waste
z
Waters nano-Aquity Nano LC system with
2D
2D2D--LC/MS/MSLC/MS/MSInstrumental SetInstrumental Set--up SCX/RP/RPup SCX/RP/RP
Loading20 µl/min
Sample
Nano LCgradient
Z
Waste
z
Each protein/peptide is separated accordingEach protein/peptide is separated accordingto their physicoto their physico--chemical identitychemical identity
We use the property of proteins/peptides to We use the property of proteins/peptides to behave differently in different pHbehave differently in different pH
The time for one analysis is The time for one analysis is critical?critical?
You can analyze thousands of compounds in a few hoursYou can analyze thousands of compounds in a few hours
You can analyze thousands of compounds in a few hoursYou can analyze thousands of compounds in a few hours
The whole 2D LC can be done in a chipThe whole 2D LC can be done in a chip
The whole 2D LC can be done in a chipThe whole 2D LC can be done in a chip
2D2D--CE/MS/MSCE/MS/MS
High throughput CE
10000 Capillaries
Capillary windows
Autosampler
LED detection (MIT, Forest et al, 2006)
DiagnoDiagno--ProteomicsProteomics
Printing proteins as microarrays for high-throughput function determination
Science. 2000 Sep 8;289(5485):1760-3.
Detecting protein-protein interactions on glass slides
BODIPY
CY3
CY5 and rapamycin
CY5 only
Everything together
Prot G P50 FRB
Printing proteins as microarrays for high-throughput function determination
Science. 2000 Sep 8;289(5485):1760-3.
A single slide holding 10,800 spots. Protein G was printed 10,799 times
A single spot of FRB was printed in row 27, column 109. The slide was probed with BODIPY,CY3, CY5 and rapamycin
Automated MicroAutomated Micro--Chip Robot loaderChip Robot loader
What else can we do?What else can we do?
DE C
2 DE
• Performance
Native IEF and native PAGE
5 variants of hemoglobin
pH 6.7 -7.7
Native IEF and SDS-PAGE
standard IEF proteins
pH 3-10
Denatured IEF and SDS-PAGE
GFAP protein variants expression differences
in control and Alzheimer diseased patients
pH 4-6
HbA1c
HbA
HbF
HbS
HbA2
control AD
SELDI = Chip based surface enchanced laser desorption analysis
The Chip
Current Developments In SELDI Affinity TechnologyMass Spectrometry Reviews, 23, 34-44, (2004)
High Throughput
Micro-Array technology in Proteomics
Protein arrays
Ab-micro array
Protein Array
Micro-Array technology in Proteomics
Microfluidics in a Chip for Proteomics
Biochip-IMB, Ltd.
Biochip-IMB, Ltd.
Express diagnostics tools CUSTOMIZED
IMSImaging mass spectrometry
PrinciplesPrinciplesTissue section (mouse brain)
2,000 15,000 30,000
Ion
inte
nsity
Acquisition x
Acq
uisi
tion
ym/z
12mm
• A laser is rastered over a defined area while acquiring a complete mass spectrum from each position, resulting in molecular images for multiple analytesCornett, et al., Nature Methods 2007
IMS workflowIMS workflow
Stoeckli, M, et al., Analytical Biochemistry 2002
Tissue slide for IMS
Benefits of MALDIBenefits of MALDI--IMSIMS
Analysis of entire sample in one reading
Previous knowledge of molecular composition is not necessary
Allows for investigation of disease formation, progression, and treatment
www.maldi-msi.org
MS imaging advantages
•No labeling requiredBiomolecules are functionally unmodified
•Image biomolecular modificationsPTM’s, Metabolites
•Detailed information on molecular identityBy 2D MALDI
•Large scope of different elements and molecules
Targeted labeling
Label free imaging
IMS vs. histochemical stainIMS vs. histochemical stain
Imaging MS applications……
Drug administration and detection
New Phytologist (2007) 173 : 438 –444m/z 381
m/z 543
m/z 705
Reconstruction of the Carbohydrate moietyOf WHEAT (Triticum aestivum)
Special Applications
Imaging of regions immunoreactive with anti-synaptophysin Ab in healthy human pancreas.
(A) Localization of synaptophysin positive cells by TAMSIM. The monoclonal rabbit anti-synaptophysin is conjugated with the tag El 307 (498 m/z). The false color green points in the section show the presence of the tag El 307 and thus synaptophysin positive cells.
(B) Classical IHC image with the anti-insulin Ab. The dark pink spots correspond to Langerhans islets and so the synaptophysin-positive cells. The distribution of synaptophysin positive cells in (A) is very similar to that in (B).
Immuno-MS-IMS
Thiery, G., et al., Proteomics 2008