Visualizing the mechanical activation of Src

The mechanical environment crucially influences many cell functions. However, it remains largely mysterious how mechanical stimuli are transmitted into biochemical signals. Src is known to regulate the integrin–cytoskeleton interaction, which is essential for the transduction of mechanical stimuli. Using fluorescent resonance energy transfer (FRET), here we develop a genetically encoded Src reporter that enables the imaging and quantification of spatio-temporal activation of Src in live cells. We introduced a local mechanical stimulation to human umbilical vein endothelial cells (HUVECs) by applying laser-tweezer traction on fibronectin-coated beads adhering to the cells. Using the Src reporter, we observed a rapid distal Src activation and a slower directional wave propagation of Src activation along the plasma membrane. This wave propagated away from the stimulation site with a speed (mean ± s.e.m.) of 18.1 ± 1.7 nm s-1. This force-induced directional and long-range activation of Src was abolished by the disruption of actin filaments or microtubules. Our reporter has thus made it possible to monitor mechanotransduction in live cells with spatio-temporal characterization. We find that the transmission of mechanically induced Src activation is a dynamic process that directs signals via the cytoskeleton to spatial destinations.

The mechanical environment crucially influences many cell functions 1 . However, it remains largely mysterious how mechanical stimuli are transmitted into biochemical signals. Src is known to regulate the integrin-cytoskeleton interaction 2 , which is essential for the transduction of mechanical stimuli [3][4][5] . Using fluorescent resonance energy transfer (FRET), here we develop a genetically encoded Src reporter that enables the imaging and quantification of spatio-temporal activation of Src in live cells. We introduced a local mechanical stimulation to human umbilical vein endothelial cells (HUVECs) by applying laser-tweezer traction on fibronectin-coated beads adhering to the cells. Using the Src reporter, we observed a rapid distal Src activation and a slower directional wave propagation of Src activation along the plasma membrane. This wave propagated away from the stimulation site with a speed (mean 6 s.e.m.) of 18.1 6 1.7 nm s 21 . This force-induced directional and long-range activation of Src was abolished by the disruption of actin filaments or microtubules. Our reporter has thus made it possible to monitor mechanotransduction in live cells with spatio-temporal characterization. We find that the transmission of mechanically induced Src activation is a dynamic process that directs signals via the cytoskeleton to spatial destinations.
Mechanical stimuli activate integrins and the cytoskeleton to regulate cellular functions such as movement and adhesion 6 . When activated, integrins associate with Src via its SH3 domain, thus unmasking the Src kinase domain and activating Src 7 . Src can regulate integrin-cytoskeleton interaction 2 , and cause dissolution of actin stress fibres and the release of mechanical tensile stress 8,9 . We previously developed a FRET-based Src indicator 10 , but that reporter also responded to Abl, Lck and epidermal growth factor receptor (EGFR). Furthermore, mutation of the Tyr within the substrate sequence to Phe did not eliminate the FRET response, which cast doubt on the mechanism for the FRET response. We therefore sought an indicator with higher specificity and a better-defined response mechanism. A Src substrate peptide (WMEDYDYVHLQG, derived from a primary in vivo c-Src substrate-molecule p130cas 11,12 ) was designed to replace the original substrate (EIYGEF, identified by in vitro library screening 13 ) and to provide sufficient space for Src to gain access 14 (Fig. 1a). The proximity of the N and C terminals of the SH2 domain, revealed by its crystal structure 15 , should allow the juxtaposition of cyan and yellow fluorescent proteins (CFP and YFP) to yield a high FRET. On Src phosphorylation, the substrate peptide can bind to the phosphopeptide-binding pocket of the SH2 domain and separate YFP from CFP, thus decreasing the FRET (Fig. 1b). Phosphorylation of the purified reporter by Src in vitro enhanced CFP emission at the expense of YFP emission (Fig. 1c) and increased the cyan-to-yellow emission ratio by 25%, indicating a Src-induced loss of FRET. The specificity was very much better than for the previous Src indicator. The emission ratio changed by ,2% for other kinases (Yes, FAK, EGFR, Abl, Jak2 or Ser/Thr kinase ERK1) and changed moderately (,10%) only for Fyn, a close relative of Src (Fig. 1d). The Srcinduced loss of FRET is consistent with intramolecular complexation of the phosphorylated substrate with the SH2 domain and the consequent disruption of the close apposition of the CFP and YFP domains (Fig. 1b).
In HeLa cells transfected with the Src reporter, epidermal growth factor (EGF) induced a 25-35% emission ratio change ( Fig. 2a; Supplementary Movie 1). Introduction of the reporter did not affect the ERK activity with or without EGF stimulation (data not shown), suggesting that the reporter need not perturb endogenous cellular signalling. Mutations of either or both of the putative Src phosphorylation sites (Tyr 662 and 664) to Phe in the substrate peptide ( Fig. 1a) prevented the FRETresponse to EGF in HeLa cells (Fig. 2b). Mutation of Arg 175 to Val (Fig. 1a), eliminating SH2 domain binding to phosphorylated peptides 15 , also abrogated the EGFinduced FRET response. These results validate the phosphorylation-induced intramolecular (intra-reporter) interaction between the SH2 domain and substrate peptide as the mechanism for the FRET response. Immunoblotting revealed that EGF-induced tyrosine phosphorylation is abolished only by mutating both Tyr 662 and 664, but not either site alone (Fig. 2c), unlike the blockade of the FRET response by single mutations (Fig. 2b). Thus, the SH2 binding requires not only the phosphorylation of one of the two Tyr residues but also the integrity of the other Tyr in the substrate, consistent with the notion that the neighbouring amino acids of the phosphorylated site are important for SH2 binding 16 . Disruption of the SH2 domain by R175V mutation also blocked the EGF-induced tyrosine phosphorylation of the Src reporter ( Fig. 2c), suggesting that the SH2 domain of the reporter may assist in its association with activated Src to facilitate the phosphorylation process.
The EGF-induced FRET response in HeLa cells was reversed by PP1, a selective inhibitor of Src family tyrosine kinases, and was markedly reduced after pretreatment with PP1 (Fig. 2d). The normal platelet-derived growth factor (PDGF)-induced FRET response of the Src reporter was abolished in Src/Yes/Fyn tripleknockout (SYF 2/2 ) mouse embryonic fibroblasts (MEF) (Fig. 2e). Reconstitution of these SYF 2/2 cells with c-Src, but not c-Fyn, restored the FRETresponse. Reconstitution with c-Yes caused only a weak FRET response of the Src reporter. The small and delayed FRET response observed in the kinase-dead c-Src (Src_KD) group may be attributed to the residual activity of Src_KD. These results demonstrated the specificity of the Src reporter toward Src in mammalian cells.
CFP and FYP can form anti-parallel dimers 17 . To eliminate the unintended FRET resulting from intermolecular (between reporters) dimerization, we introduced A206K mutations into CFP and YFP to generate monomeric CFP and YFP 18 (Fig. 1a). These mutations did not alter the spectral properties of the Src reporter, but they led to a better dynamic range of FRET (43 versus 25% emission ratio change) in response to Src kinase in vitro (compare Fig. 2f with Fig. 1c) and a greater EGF-induced FRET response in HeLa cells that was reversible by EGF washout (Fig. 2g, Supplementary Fig. 1 and Supplementary Movie 2). This monomeric reporter was used for the study of mechano-activation of Src.
Beads coated with fibronectin, which binds to integrins and hence causes coupling with the cytoskeleton 19 , were applied to HUVECs. Consistent with the observation of Src activation by integrin clustering 7 , the fibronectin-coated beads caused a local FRET response of the Src reporter around the beads (  letters to nature not induce any significant FRET response (Supplementary Fig. 3b and Supplementary Movie 6), suggesting that specific integrincytoskeleton coupling is needed for the mechanotransduction.
The thin lamellipodia at the cell periphery, which are important in mechanotransduction, contain only limited copies of cytosolic Src reporters. Because significant amounts of CFP/YFP molecules are required to yield enough fluorescence above the endogenous autofluorescence background 20 , there is a need for controlled localization of the Src reporter to enhance its effective local concentration, especially in lamellipodia. Because the translocation of Src to the plasma membrane is a prerequisite for Src activation 7,21 , we targeted the monomeric Src reporter to the plasma membrane with a fusion of the 16 N-terminal residues from Lyn kinase 18 . The EGF-induced FRET response of this membrane-targeted reporter was reversed by PP1 ( Supplementary Fig. 4a and Supplementary Movie 7) and prevented by pretreatment with PP1 ( Supplementary  Fig. 4b and Supplementary Movie 8), indicating its specificity towards Src (Fig. 3b).
The application of pulling force via the laser tweezers on a bead coated with fibronectin, but not polylysine ( Supplementary Fig. 5), on the HUVECs expressing the membrane-targeted Src reporter led to a directional FRET response, with the majority of activations transmitted towards distal areas of the cell opposite to the force direction ( Fig. 3c; Supplementary Movie 9). This transmission consisted of an immediate distal Src activation and a slower wave-propagation of Src activation followed by lamellipodia protrusions at the cell periphery (Fig. 3c). Such FRET responses were absent with inactive reporters (for Y662F/Y664F see Supplementary Fig. 6a and Supplementary Movie 10; for R175V see Supplementary Fig. 6b and Supplementary Movie 11). In experiments where the speed of the wave propagation of Src-activation away from the stimulation site can be clearly measured, it was found to be 18.1^1.7 nm s 21 (mean^s.e.m.) ( Fig. 3d; Supplementary movie 12). This result indicates that a local force caused a directional and long-range transduction of Src-activation wave to spatial destinations.
We examined the roles of the cytoskeleton on this forceinduced Src activation. Disruption of actin filaments with cytochalasin D or microtubules with nocodazole blocked the forceinduced distal, but not local, FRET responses (Fig. 4a, b; Supplementary Movies 13,14). Polarity analysis of Src activation, by averaging the emission ratios of 36 evenly divided angular sections of each cell with the bead position as the centre, revealed that the local pulling force caused a cytoskeleton-dependent polarized FRET response pointing to the opposite direction (Fig. 4c, d).
Statistical analysis further showed that the mechanical force caused a cytoskeleton-dependent increase of the number of pixels with highly activated Src distal to the force-imposed bead, indicating a long-range mechano-activation of Src ( Fig. 4e;  Supplementary Fig. 7).
It is unclear where mechano-induced biochemical signals are initiated and how they are transmitted in the cell. Green fluorescent protein (GFP)-tagged fluorescent markers have been used to study the displacement of cellular organelles and the formation of a focal adhesion complex induced by mechanical stimuli [22][23][24][25] , but these inert fluorescence markers cannot monitor the dynamic signal transduction process. Our FRET-based Src reporter enables the visualization and quantification of the mechano-activated Src with high temporal and spatial resolution in live cells. The results indicate that local mechanical stimulation triggers a directional and long-range propagation of Src activation, for which cytoskeleton integrity is essential.
Integrin-mediated activation of Src at local sites by mechanical stimuli may induce p130cas/Dock180 association, Rac-Arp2/3 activation, cortical actin network nucleation and polymerization, and actin-ruffle extensions 26,27 . These Rac and actin activities in turn promote the recruitment and activation of Src at the tip of these newly assembled wave-like actin ruffles 28,29 , thus further inducing the in situ Rac activation and actin polymerization. This positively coordinated mechanism may result in a wave propagation of Src activation. The directionality of this wave propagation may be attributed to the initial local mechanical tension generated in a direction counter to the applied force. The applied force can also be mechanically transmitted quickly through tensed cytoskeleton network to distal locations and to activate Src 1 . This directional Src activation may release the tension 21 at desired destinations and rearrange the intracellular stress distribution, thus serving as a feedback mechanism for the cell to adapt to new mechanical environments (Fig. 4f). A

Laser-tweezers
A 1064-nm continuous-wave diode-pumped ND:YV0 4 laser with 5W power (Spectra-Physics) was used for the laser-tweezers experiments. The laser beam passes through a laser-beam expander, a steering mirror, and a dichroic long-pass beamsplitter to enter the microscope side port.

Gene construction and DNA plasmids
The gene for the Src reporter was constructed by polymerase chain reaction (PCR) amplification of the complementary DNA from the c-Src SH2 domain with a sense primer containing a SphI site and a reverse primer containing the gene sequence for a flexible linker, a substrate peptide derived from p130cas, and a SacI site. The PCR products were fused together with an N-terminal enhanced CFP and a C-terminal citrine (a version of enhanced YFP) 10 , as shown in Fig. 1a. Mutations of Y662/664F, Y662F, Y664F, R175V and A206K were conducted with the QuickChange method (Stratagene) Constructs were cloned into pRSET B (Invitrogen) using BamHI/EcoRI for bacterial expression and into pcDNA3 (Invitrogen) behind a Kozak sequence using HindIII/EcoRI for mammalian cell expression. The membrane-targeted CFP was constructed by PCR amplification of the monomeric CFP with a sense primer containing the codes for 16 N-terminal amino acids from Lyn kinase 18 to produce a membrane-targeted Src reporter. The various Src reporters and their mutants used in Figs 2b and c are abbreviated as: WT, the Src reporter (wild type); DM, Y662F and Y664F double mutations in the designed substrate peptide; Y662F or Y664F, the Y662F or Y644F single mutation in the substrate peptide, respectively; and R175V, the R175V mutation in the binding pocket of the SH2 domain.

Microscopy and image acquisition
The HeLa or MEF cells expressing the desired exogenous proteins were starved with 0.5% FBS for 36-48 h before being subjected to EGF (50 ng ml 21 ) or PDGF (10 ng ml 21 ) stimulation. During imaging, the cells were maintained in Hanks' balanced salt solution (HBSS) with 20 mM HEPES (pH 7.4) and 2 g l 21 D-glucose at 25 8C. Images were collected by using MetaFluor 6.0 software (Universal Imaging) with a 440DF20 excitation filter, a 455DRLP dichroic mirror, and two emission filters controlled by a filter changer (480DF30 for CFP and 535DF25 for YFP).
To image the mechanical-force-induced Src activation, HUVECs were first starved with 0.5% FBS for 24 h and then kept in CO 2 -independent medium without serum (Gibco BRL) at 37 8C in a thermostatic chamber. A Zeiss axiovert inverted microscope equipped with a 440DF20 excitation filter and a 455DRLP dichroic mirror was integrated with the laser-tweezers. CFP and YFP emission images were acquired simultaneously with an ORCA ER CCD camera (Hamamatsu) through a Dual-View module (Optical-Insights). The CFP and YFP images were aligned pixel-by-pixel with our customized Matlab program by maximizing the normalized cross-correlation coefficient of CFP and YFP fluorescence intensity images: Where C i,j and Y i,j are the intensity values at pixels (i, j) of the CFP and YFP images, and C and Y are the mean intensity values of the CFP and YFP images. The ratio images of aligned CFP/YFP were computed and created by the MetaFluor software to represent the FRET efficiency. CD or NOC, cytochalasin D or nocodazole treatment, respectively. e, HUVECs treated with cytochalasin D, nocodazole or DMSO were subjected to mechanical force for 15 min or kept as static control. Bar graphs represent mean^s.d. of the force-induced fold induction of distally activated (see Methods, with 80% threshold) pixel numbers. The asterisk indicates a significant difference (P , 0.05) before and after force application. f, A proposed model depicting the mechanism by which local mechanical forces induce directional and long-range Src activations.