forrest goodfellow, taejin kim, yingxiao wang department of bioengineering, college of engineering,...
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Forrest Goodfellow, Taejin Kim, Yingxiao Wang Department of Bioengineering, College of Engineering, University of Illinois at Urbana-Champaign
Extracellular Matrix Proteins and Mechanical Tension in Regulating FAK activity in Mesenchymal Stem Cells
Acknowledgments
EBICS Research Experience for Undergraduates
Beckman Institute for Advance Science and Technology
Citations
Seong J, Ouyang M, Kim T, Sun J, Wen PC, Lu S et al. Detection of focal adhesion kinase activation at membrane microdomains by fluorescence resonance energy transfer. Nat Commun 2011; 2: 406.
Wang Y, Shyy JY, Chien S. Annu Rev Biomed Eng. 2008;10:1.
Aim Previous experiments in the Wang Laboratory have observed FAK activation under an array of environmental conditions. The effects of substrate rigidity and the composition of the extracellular matrix were observed with the Cyto-FAK biosensor. Now, the intent is to investigate FAK activation with the Lyn-FAK biosensor. This investigation will allow for the observation of FAK activity within the cytosol as well as bound to the plasma membrane.
Introduction
Focal Adhesion Kinase (FAK) FAK is a 125 kD protein responsible for tyrosine phosphorylation. FAK is activated in response to environmental stimuli such as extracellular matrix proteins, and mechanical tension. FAK can exits in they cytosol or bound to the plasma membrane.
.
Fluorescent Resonance Energy Transfer (FRET) FRET biosensors are genetically engineered proteins containing two fluorescent protein sequences without disrupting the functionality of the protein. The Lyn-FAK biosensor allows for the visualization of membrane bound FAK and Cyto-FAK allows for the visualization of cytosolic FAK. FRET biosensors enable live cell imaging.
Preliminary Results
The Ctyo-FAK biosensor allows for the visualization of cytosolic FAK activation and numerical analysis with Metaflour imaging software enables the numerical characterization of FAK activation with the Cyto-FAK biosensor. On going experiments will allow for the comparison of Cyto-FAK and Lyn-FAK biosensors under identical environmental conditions.
Conclusions
FAK activation observed with the Lyn-FAK biosensor demonstrated an increase in FAK activation on harder substrates relative to soft substrates, and the FAK activation at 1 hour differs significantly. An explanation for the difference may be the kinetics of FAK activation caused by the different ECM proteins. FAK activation must be observed with the Lyn-FAK biosensor before any further insights can be made. Continued research will allow for an understand of FAK distribution with in the cell and answer several questions.
Is FAK synthesized in response to the environment?
Does FAK transiently bind to the plasma membrane?
Do ECM proteins effect the kinetics of FAK activation?
Figure 4: FRET ratios were calculated with Metaflour software. The FAK activation observed with the Cyto-FAK FRET ratio.
Figure 3: FRET Images captured with Cyto-FAK biosensor. Panels represent Fibronectin and Type I Collagen coated gel substrate dishes at 1 and 24 hours after hMSC were plated on the gel. The stiffness of the substrate is indicated in the lower left corner.
Method
Live Cell Imaging
After 1 hour and 24hours hMSC were imaged and FRET Ratio analyzed with Metaflour software
Passage to Gel Substrate DishesCells seeded on 0.6 kPa and 40 kPa dishes
coated with Fibronectin or Type I Collagen coating
Cellular TransfectionLipofectamine 2000 system utilized to introduce
the Lyn-FAK or Cyto-FAK plasmid
Culture of Mesenchymal Stem CellshMSC cultured in hMSCGM (Lonza) and
passaged 1 day prior to transfection
Fibronectin Type I Collagen1 h
0.6 kPa
1 h
0.6 kPa
24 h 24 h
0.6 kPa0.6 kPa
40 kPa 40 kPa
1 h 1 h
24 h
40 kPa 40 kPa
24 h
24h after seeding
1
1.04
1.08
1.12
1.16
1 2
FR
ET
ra
tio
(E
CF
P/Y
pe
t)
1
1.04
1.08
1.12
1.16
1 2
FR
ET
ra
tio
(E
CF
P/Y
pe
t)
Type I Collagen
Soft Hard Soft Hard
P=0.958231 P=0.301495
1
1.04
1.08
1.12
1.16
1.2
1.24
1 2
FR
ET
ra
tio
(E
CF
P/Y
pe
t)
1
1.04
1.08
1.12
1.16
1.2
1.24
1 2
FR
ET
ra
tio
(E
CF
P/Y
pe
t)
Soft Hard Soft Hard
P=0.002264
P=0.721078
Fibronectin
1h after seeding
Figure 1: (a) Polyacrylamide gel is used to simulate in virto environments of different mechanical tensions by varying the amount of cross-linked molecules (b) EM images of fibronectin and (c) collagen are ECM proteins responsible for cellular adhesion and play a role in FAK activation.
a b
cwww.spinal-research.org/
www.neuroniccollagen.com/www.nationaldiagnostics.com/
Figure 2: (a) indicates the design of the FAK biosensor and the phosphorylated tyrosine residue in red (b) Activated FAK will phosphorlate the biosensor’s substrate peptide and the proximity of ECPF and Ypet effects a change in FRET fluoresces.
Jihye seong, et al.
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