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Techniques for RNA DetectionWhere Are We Headed?August 27, 2014
Brought to you by the Science/AAAS Custom Publishing Office
Participating Experts
Martin Stoddart, Ph.D. AO Research Institute DavosDavos, Switzerland
Don WeldonEMD MilliporeTemecula, CA
Webinar Series
Sponsored by:
Techniques for RNA DetectionWhere Are We Headed?August 27, 2014
Dr. Martin Stoddart, Principal InvestigatorAO Research Institute Davos, Switzerland
Techniques for RNA Detection:Where Are We Headed?
Overview
• Description of most common RNA detection
methods
• Considerations regarding their use
• Data from bone tissue engineering
• Refinement of the data obtained
• New avenues and future direction
Northern Blot
Sample
RNA Isolation
2D Gel Electrophoresis
RNA sizeseparation
TransferGel Membrane
Fix RNA
Incubate membrane with probe
Develop
End Point PCR
http://en.wikipedia.org/wiki/Polymerase_chain_reaction
Real Time PCR
Cell Lysis
Reverse Transcription
Polymerase Reaction
2∆∆CtNormalised Gene Expression
Global v CellG
radi
ent
Bin
ary
Increasing Expression Increasing Expression
Incr
easi
ng S
igna
l
In Situ hybridization
Bone tissue engineering
Early osteogenic markers
Alkaline phosphatase (ALP)Runx2
Late osteogenic markers
Alizarin red stainingCalcium45 incorporation
Runx2 - mRNA
human MSCs
early screening method
Day 28
Transcription Factors
• Include Master Genes such as Runx2 (osteoblast) and Sox9 (chondrocyte)
• Bind short, specific sequences in DNA promoters activating gene transcription
• Results in global regulation of many genes
• Provide an indication of cell fate - Early
AAAAA
Runx2P
Osteogenic differentiation
Stimulate with osteogenic mediumContaining dexamethasone
Human mRNA Analysis- Real time PCR
Day 0 Day 1 Day 3 Day 7 Day 14
Other factors?
Where Are We Headed? - 1) mRNA Ratios
Runx2/Sox9 mRNA ratio is correlated toCalcium45 incorporation
n = 12
Loebel C, et al. Tissue Engineering Part A, 2014, Aug 4
Sox9 mRNA silencing can enhanceosteogenesis in vitro
DEX
DEX + Sox9 siRNA
Calcium45 incorporation (day 28) Alizarin red staining (day 28)
n = 6
Loebel C, et al. Tissue Engineering Part A, 2014, Aug 4
Runx2
Runx2
Runx2 Runx2 Runx2
Hypertrophic chondrocyte
Resting Articular chondrocyte
ImmatureChondroblast
Mesenchymal Stem Cell
Preosteoblast ImmatureOsteoblast
MatureOsteoblast Osteocyte
Sox 5, 6, 9
Col X
Col IBSPOPNOCN
OSX
Mesenchymal stromal cell potential
Global v CellG
radi
ent
Bin
ary
Increasing Expression Increasing Expression
Where Are We Headed? 2) Non-destructive – individual cell
20
gold-quencheddye
capture strandTarget mRNA
Cell sortingbased on single probe
Cell sorting based on SMART-FLARE (Sox 9)
Sox9 P3FL= P9 Sox9 mfi low mfi 2,414 purity 95%
Sox9 p4FR= P10 Sox9 mfihigh mfi 7,102 purity 76%
1
4.771698659
0
1
2
3
4
5
6
Sox9 P3 Sox9 P4
RT-PCR
SmartFlare probes can be used for live cell sorting
Experimental Control ProbesAll Good Experiments Include the Proper Controls
Uptake Scramble Housekeeping
CONFIDENTIAL
0 Seed Primary hMSCs
UPTAKE-control 4µl per 200µl
FACS (UPTAKE)Add osteogenic and control medium, respectively
1
2
3
UPTAKE, Sox9 and scrambled Sox9 4µl per 200µl
4
5
6 FACS (UPTAKE, Sox9, scrambled Sox9)
Day
Methodology – Down-regulated gene
FACS (UPTAKE)
UPTAKE-control 4µl per 200µl
Growth medium Differentiation medium
mfi valuecontrol neg -uptake Cy5 1883 *scramble Cy5 967Sox9 Cy5 1588
mfi valuecontrol neg -uptake Cy5 1883 *scramble Cy5 892Sox9 Cy5 932
Sox9 Down-regulation
Sox 9+RunX2
Cell sorting based on double probes
RT-PCR
1
0.336
0.186
0
0.2
0.4
0.6
0.8
1
1.2
P3 Run X2 P4 RunX2 P5 RunX2
RunX21
0.7370.523
0
0.2
0.4
0.6
0.8
1
1.2
P3 Sox9 P4 Sox9 P5 Sox9
Sox9
Varying Differentiation states
1
0.390.51
0
0.2
0.4
0.6
0.8
1
1.2
P3 ALP P4 ALP P5 ALP
ALP
1
1.45
2.47
0
0.5
1
1.5
2
2.5
3
P3 Collagen I P4 Collagen I P5 Collagen I
Collagen I
10.93 0.88
0
0.2
0.4
0.6
0.8
1
1.2
P3 hOC P4 hOC P5 hOC
hOC (Osteocalcin)
Bone tissue engineering
early osteogenic markers
Alkaline phosphatase (ALP)Runx2
Runx2/Sox9 ratio
human MSCs
early screening method
Day 28
Late osteogenic markers
Alizarin red stainingCalcium45 incorporation
Acknowledgements
Musculoskeletal Regeneration Group AO Research Institute Davos
Bojun Li Claudia Loebel
Ursula MenzelFACS
This project has received funding from the European Union’s Seventh Framework Programme for research, technological development and demonstration under grant agreement no [NMP.2010.2.3-1]
Servier Medical Art- Creative Commons Licence (Slide Images)
Prof. Mauro Alini
Innovationsstiftung
Brought to you by the Science/AAAS Custom Publishing Office
Participating Experts
Webinar Series
Sponsored by:
Techniques for RNA DetectionWhere Are We Headed?August 27, 2014
Martin Stoddart, Ph.D. AO Research Institute DavosDavos, Switzerland
Don WeldonEMD MilliporeTemecula, CA
Techniques for RNA Detection: Where Are We Headed?
Don WeldonLead Application Scientist EMD Millipore
Scientists realized early on the best way to understand a biological organism is to observe it in its natural environment.
vs..
Observe with minimal /no disturbance
Identify individualsof interest
Leave with minimal /no disturbance
Ultimately we want to:
When Studying RNA:Let’s take the approach of biologists…not archeologists
Validation of Probes
150 (kDa)
250 (kDa)
blot: EGFR(~180kDa)
Normalized signal intensity = Blot/CBB
Unf
lare
d
Scra
mbl
e SF EG
FR
SF
No Changein Cell Viability
No Impacton Gene Expression
No Changein Protein Expression
150 (kDa)
250 (kDa)
2.07 2.07 2.12
Genome Wide Array ScreenViaCount™ Viability Assay
WorkflowWorkflow is a simple addition to Cell Culture
1. Reconstitute & Dilute
2. Add to cells in culture Allow to incubate overnight
3. Detect RNA levels via microscopy or Flow
Time Lapse MicroscopyDetection of ERBB2 in low and high expressing cells
Time Lapse MicroscopyDetection of ERBB2 in low and high expressing cells
Example of Live Cell RNA Detection
Live cell sorting of immune cells based on RNA
c-Myc Levels Decrease During MonocyteDifferentiation
J. Auwerx, Experientia 47 (1991)
Background:• c-Myc is a transcription factor • Downstream target genes play a role in cellular proliferation• Many cancers are known to show constitutive c-Myc expression
THP-1 Monocytes(high MYC) Undifferentiated THP-1
(high MYC)
Sorted cells returned to culture for
4 days to complete differentiation and further
functional characterization
THP-1 Monocytes(high MYC)
Enrich withFACS
after 1 day
Differentiate to Macrophages
with PMA
Add MYCSmartFlare™
Probe
Pre-Macrophages(decreased MYC)
Detecting RNA Levels During DifferentiationEnrichment Based on Decreased Expression
Enter Without Disturbing the Cell
Identify the IndividualCells of Interest
Leave Without Disturbing the Cell
Cell-based Phenotype: Bacterial killing assay
High Low
Characterization of Protein ProductsMilliplex cytokine assay post- stimulation (LPS)
Undifferentiated THP-1(high MYC)
Pre-Macrophages(decreased MYC)
FunctionalAssays
Detecting Differences in RNA ExpressionMultiplex protein and cell-based phenotype assays confirm function
0.
150.
300.
450.
600.
750.
Day 0 Day 5
MYC
mR
NA
Sm
artF
lare
MFI
MYC mRNA detection by SmartFlare™ Probe
0.
0.25
0.5
0.75
1.
1.25
Day 0 Day 5
Rel
ativ
e M
YC m
RN
A
MYC mRNA detection by qRT-PCR
Correlation of MYC RNA detection by SmartFlare™ Probe and qRT-PCR
MYC levels decrease during macrophage differentiation
RT-PCR and Live Cell RNA DetectionMYC mRNA expression decreases during monocyte differentiation
Undifferentiated THP-1 MonocytesTHP-1 Monocytes PMA 2 daysMonocytes PMA 5 days (macrophages)
MYC levels decrease during macrophage differentiation
Monitoring mRNA Expression ChangesMorphology and Expression
00.5
11.5
22.5
3
0 1 2 3 4 5 6 7 8
TNFa
(ng/
ml)
Stimulation (hours)
TNFalpha secretion over time in LPS-stimulated sort products
MYC highMYC low
Con
cent
ratio
n (p
g/m
l)
MYC mRNA sort products show distinct cytokine profiles
Cytokines secretion kinetics in response to LPS stimulation in MYC sort products
Stimulation (hours)
0
1
2
3
4
5
6
7
Con
cent
ratio
n (n
g/m
l) MYC high
MYC low
Detection of Distinct Cytokine ProfilesProfiles and Response to Stimulation are Unique to Cell Type
Multiplex
Live Cell Time-Lapse Imaging MovieRNA detection during a functional assay
Live Cell Time-Lapse Imaging MovieRNA detection during a functional assay
Summary
3
Native RNA was detected in live cells during differentiation
Protocol was simplified with direct addition to cell culture
Cells were enriched based on their RNA content through FACS
Additional functional assays were performed on the sort products
Starter Kit
Uptake
• Use as an initial test to determine the cell’s ability to endocytoseSmartFlare™ probes.
Scramble
• Use to determine the level of background fluorescence inside the cell and compare to target fluorescence.
Housekeeping
• Housekeeping genes can be used as positive controls to confirm the system is working in your culture conditions.
All good experiments utilize the proper controls
Visit www.emdmillipore.com/smartflare to see more technical information and application notes and to browse our list of SmartFlare™ probes available.
AcknowlegementsThe Application Development Team who Performed the Experiments:Yuko WilliamsAlex KoHaizhen Liu
EMD Millipore
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Participating ExpertsBrought to you by the Science/AAAS Custom Publishing Office
Webinar Series
Sponsored by:
Techniques for RNA DetectionWhere Are We Headed?August 27, 2014
Martin Stoddart, Ph.D. AO Research Institute DavosDavos, Switzerland
Don WeldonEMD MilliporeTemecula, CA
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Techniques for RNA DetectionWhere Are We Headed?August 27, 2014