ARTICLE

Received 29 Jul 2014 | Accepted 29 Sep 2014 | Published 20 Nov 2014

The interaction of lipids and proteins plays an important role in plasma membrane bioactivity, and much can be learned from their diffusion characteristics. Here we present the combination of super-resolution STED microscopy with scanning uorescence correlation spectroscopy (scanning STED-FCS, sSTED-FCS) to characterize the spatial and temporal heterogeneity of lipid interactions. sSTED-FCS reveals transient molecular interaction hotspots for a uorescent sphingolipid analogue. The interaction sites are smaller than 80 nm in diameter and lipids are transiently trapped for several milliseconds in these areas. In comparison, newly developed uorescent phospholipid and cholesterol analogues with improved phase-partitioning properties show more homogenous diffusion, independent of the preference for liquid-ordered or disordered membrane environments. Our results do not support the presence of nanodomains based on lipid-phase separation in the basal membrane of our cultured nonstimulated cells, and show that alternative interactions are responsible for the strong local trapping of our sphingolipid analogue.

DOI: 10.1038/ncomms6412

Scanning STED-FCS reveals spatiotemporal heterogeneity of lipid interaction in the plasma membrane of living cells

Alf Honigmann1,*, Veronika Mueller1,*, Haisen Ta1, Andreas Schoenle1, Erdinc Sezgin2, Stefan W. Hell1

& Christian Eggeling1,2

1 Department of NanoBiophotonics, Max-Planck-Institute for Biophysical Chemistry, Am Fassberg 11, Goettingen 37077, Germany. 2 MRC Human Immunology Unit, Weatherall Institute of Molecular Medicine, University of Oxford, Headley Way, Oxford OX3 9DS, UK. * These authors contributed equally to this work. Correspondence and requests for materials should be addressed to A.H. (email: mailto:[email protected]

Web End [email protected] ) or to C.E.(email: mailto:[email protected]

Web End [email protected] ).

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Resolving the various interactions of lipids and proteins in the eukaryotic plasma membrane (such as the possible formation of lipid rafts) with high temporal and spatial

resolution is at the basis of understanding its diverse functions1. However, decoding the multitudes of interactions between membrane proteins and lipids in the living cell has been hampered by the lack of appropriate methods (for example, ref. 1). A prominent approach to reveal molecular interactions in the plasma membrane of living mammalian cells is studying diffusion of lipids and proteins. Here the challenge is to noninvasively observe the molecular mobility with (i) single-molecule sensitivity, (ii) a spatial resolution at the macromolecular scale and (iii) a temporal resolution on the submillisecond range. We have previously introduced the combination of subdiffraction resolution stimulated emission depletion (STED) microscopy2,3 with single-molecule-based uorescence correlation spectroscopy (FCS; STED-FCS)4, matching all of the above requirements. STED-FCS enabled the direct observation of millisecond anomalous lipid and protein dynamics on spatial scales down to B30 nm, that is about an order of magnitude below the diffraction resolution limit of fareld light microscopy59. Specically, these experiments have shown hindered diffusion of various uorescent lipid analogues when incorporated into the plasma membrane of live mammalian cells. Only STED but not standard confocal FCS measurements revealed that these hindrances were because of transient interactions with immobile or slowly moving molecular entities, presumably proteins. For the diffusing lipid analogues, this resulted in lipid-specic transient arrests or traps, which lasted between 1 and 10 ms57,9,10. While these transient arrests could involve several molecules, the area in which the lipids dwelled during trapping were smaller than 20 nm in diameter57,9,10. Yet, the impact of the observed lipid interactions on cellular functionality still remains to be investigated, especially their relation to lipid nanodomains or lipid rafts. The lipid raft concept links the ability of lipids and proteins to segregate into liquid-ordered membrane phases with their need to form transient molecular complexes during cellular signalling1,7,11. Therefore, an important issue is to characterize the sites of lipid interactions. In particular, we need to understand how these involve liquid-disordered and -ordered membrane environments, and how they change over space and time. Unfortunately, mostly liquid-disordered preferring uorescent lipid analogues have been investigated in high-resolution studies so far. In addition, an accurate spatiotemporal characterization of the lipid interactions was impossible by our previous STED-FCS measurements, since these only allowed the acquisition of data at one single small observation spot at a time. The simultaneous recording of FCS data at multiple distinct spots of the plasma membrane would allow direct mapping of the mobility of lipid analogues with high spatial resolution.

Complementary to STED-FCS, single-molecule-tracking achieves nanometre spatial and millisecond temporal precision by following single isolated molecules in space and time over usually a large area of the membrane; however, the concomitant stochastic sampling yields low statistics and random coverage from a single measurement only. In principle, FCS-related methods such as Raster-Image-Correlation-Spectroscopy1214 and Spatiotemporal Image Correlation Spectroscopy15,16 addressed this limitation by determining directed motion and diffusion coefcients from raster scanned images. However, the current image correlation methods are either limited in temporal resolution and/or require averaging over too large (4300 nm in diameter) regions of interest. A potential remedy to the limitations of image correlation spectroscopy is the rapid recording of FCS data along a line or circle, as introduced by

scanning FCS12,17,18. Here we depict the use of scanning STEDFCS (sSTED-FCS)19,20 to study spatiotemporal heterogeneity of uorescent lipid analogues with different phase-partitioning properties in the plasma membrane of living cells. sSTED-FCS allows the distinct mapping of membrane dynamics on a several-micrometre-long scanning trajectory by a single 10-s measurement, with a maximum spatial resolution of 60 nm and submillisecond temporal resolution. We demonstrate that diffusion speeds as well as trapping characteristics of lipid analogues strongly change in space and time across the plasma membrane of living mammalian cells, independent of their preference for liquid-ordered or -disordered membrane environments, all in all contributing to an updated picture of plasma membrane organization.

ResultssSTED-FCS. Similar to single-point STED-FCS, the goal of sSTED-FCS is to determine modes of diffusion (such as free versus hindered) of uorescent reporter molecules on spatial scales smaller than the diffraction limit of light (oo250 nm).

Scanning the observation spot in FCS instead of keeping it xed can be used to, among other things, parallelize the measurement and therefore sample many spatially separated points simultaneously12,17,18. Applying the scanning approach to STED-FCS we intended to identify and map zones of hindered diffusion of uorescent lipid analogues in the plasma membrane of living cells with the highest spatiotemporal resolution possible. To achieve this, we started with a confocal microscope equipped with a galvanometric beam-scanning device (Methods and Supplementary Fig. 1). To record uorescence uctuations at multiple positions quasi-simultaneously, we continuously scanned the excitation laser diffraction spot (wavelength 640 nm, spot diameter d 250 nm measured as the full-width

at half-maximum (FWHM) intensity) in a circular orbit over the sample membrane at frequencies between f 1 and 6 kHz and

orbital radii between r 1 and 3 mm (Fig. 1a). With single-

photon-counting detectors, this arrangement enabled the simultaneous recording of uorescence time traces for each pixel of the scan orbit (photon counts over time for each pixel, depicted as an intensity carpet, Fig. 1b)17. Circular orbits were preferred over lines because a circular scan has no back-scan and thus no de- and acceleration phases. Temporal autocorrelation of the intensity carpet then resulted in the generation of FCS data at different spatial points (FCS data at each pixel of the orbital scan, depicted as a correlation carpet, Fig. 1c), as previously introduced in detail13,17,18. Independent tting of all FCS data of the correlation carpet enabled mapping of apparent diffusion coefcients Di (calculated from the average transit times tD,i, equation (1) in Methods) for each pixel i on the orbital scan. In addition, we calculated the spatial averaged values tD /tD,iSi

and D /DiSi from all pixel values (/ySi denoting the

averaging over all pixel values i). To achieve subdiffraction spatial resolution, we added a 780-nm pulsed STED laser to our scanning FCS set-up featuring a central intensity zero and which conned the spatial region of the observation spot to subdiffraction size (Fig. 1a). Continuous tuning of the observation spot diameter from d 40 to 250 nm was possible by varying the power of the

STED beam5,7.

First, we performed calibration measurements on supported lipid membranes to benchmark the performance of our sSTEDFCS set-up (Supplementary Notes and Supplementary Figs 2 and 3). We found that the scanning frequency f has to be at least four times higher than the average transit time tD of the uorescent molecules through the detection spot to accurately extract the diffusion dynamics by standard FCS analysis (f44/tD,

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Figure 1 | Principle of sSTED-FCS. (a) In our experiments the spot of the excitation laser was circularly scanned over the membrane for several seconds with a radius R41 mm and a frequency f 16 kHz, resulting in

(b) a uctuating uorescence time trace for each pixels along the orbital path (photon counts over time for each pixel of the orbital scan, intensity carpet). The size of the observation spot was subsequently decreased to sub-250 nm diameters using increasing powers PSTED of the STED laser,

featuring an intensity distribution with a central zero (insets).(c) Correlation carpet exemplied for simulated data of free Brownian diffusion. Left panels: confocal (upper) and STED (d 80 nm, lower) data

for a measurement time of 50 s. Total intensity (upper panels, normalized), correlation curves (correlation carpet, middle panels) and resulting transit times tD (lower panels, for STED only) for each pixel position of the orbital scan (scanning parameters: f 3.3 kHz, radius R 1 mm, pixel width

Dxpxl 15 nm). The correlation curves G(tc) are presented in colour code as

given in the colour scale bar. Large uctuations in the decaying correlation curves and corresponding values of tD indicate spatial heterogeneity in diffusion environments. Right panels: correlation carpets for STED (right)

and confocal (middle) at different 10-s subset of the left measurement, as labelled, possibly highlighting changes of spatial heterogeneity over time.

Supplementary Fig. 2). In the presented measurements, we therefore employed f 14 kHz. In STED-FCS experiments the

observation spot sizes are decreased to observation diameters far below the diffraction limit do250 nm, resulting in reduced values of tD (since the transit time scales with d, tD d2/(8ln(2)D)). As a

consequence of f44/tD, this puts a limit on the smallest spot size d that can be applied in sSTED-FCS. For example, in live cell experiments with uorescent lipid analogues, which have a typical average diffusion coefcient of D 0.5 mm2 s 1, the smallest spot

size accessible had a diameter of d 60 nm (tD 1.3 ms, that is, a

minimal frequency f 3 kHz). Similar to conventional scanning

FCS we were able to determine the observation spots diameter d from the measurement itself using spatial correlation analysis (Supplementary Fig. 3a)12,19. This is an important advantage in sSTED-FCS because the observation spot size d is a function of the STED laser power PSTED (Supplementary Fig. 3b) and previously d(PSTED) had to be calibrated by additional

measurements5,7. In addition, the obvious advantages of the scanning approach are the simultaneous observation of heterogeneity in diffusion dynamics at different points in space (Supplementary Fig. 3c), and the determination of average diffusion parameters (tD or D) with a large body of data for analysis from a single measurement only (Supplementary Fig. 3d).

Heterogeneous diffusion of lipids in the plasma membrane. Previous single-point STED-FCS experiments have exhibited distinct differences in the diffusion dynamics of Atto647N-labelled phosphoethanolamine (PE) and sphingomyelin (SM) lipid analogues (structures given in Fig. 2) when incorporated into the plasma membrane of living PtK2 cells. This is depicted in Fig. 3a, which shows the dependence of the apparent diffusion coefcient D(d) on the diameter d of the observation spot, as determined by the single-point FCS measurements for different intensities of the STED laser. The diffusion of the sphingolipid SM was hindered because of transient arrests (trapping, decrease in D towards smaller diameters d)57. These arrests were most probably caused by transient interactions with immobile or slowly moving molecular entities such as proteins, with trapping times in the range of 10 ms (with on- and off-rates of 80 s 1) and smaller than 20-nm-sized areas in which the lipids dwelled during trapping57,10. In contrast, transient interactions of PE were much weaker (with 190 s 1 on- and large 800 s 1 off-rates), disclosing an almost free diffusion mode in the STED-FCS recordings (almost constant values of D(d))57,10. To further characterize the lipid-trapping sites, especially with regards to their spatiotemporal heterogeneity, we revisited these single-point STED-FCS measurements using sSTED-FCS.

Figure 3b shows exemplary sSTED-FCS data of the diffusion of the PE and SM analogues. Lipid staining of mammalian PtK2 cells was achieved by incubating with bovine serum albumin (BSA)-complexed lipids. Measurements (that is, orbital scanning) were performed at the basal membrane of the cell, facing the cover glass, and regions with nonhomogenous uorescence intensity (rufes, sites of endocytosis) were avoided. Data were taken over 10 s for each of the ve different STED powers ranging from PSTED 0 (d 250 nm) to PSTED 110 mW (d 60 nm)

while scanning an orbit with f 3.3 kHz and radius R 1 mm. An

intensity carpet was generated with Dxpxl 15 nm pixilation

resulting in 4400 spatially distinct correlation curves per single data acquisition. As for the single-point measurements, sSTEDFCS showed a marked difference between PE and SM. While the confocal data of PE and SM were hardly distinguishable, the STED data of SM featured decays that were much more shifted to longer correlation lag times tc and much more stretched out than the decays for PE, which indicated a more pronounced hindrance of SM diffusion57. Fitting of the data resulted in 4400 values of the transit time tD,i (or apparent diffusion coefcient

Di d2/(8(ln2) tD,i), equation (1) in Methods) for each single

measurement at the different STED powers, establishing an

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Figure 2 | Molecular structures of the uorescent lipid and cholesterol analogues used in this study. Dye (red, Atto647N and KK114),linker (blue, numbers indicate numbers of repeats) and lipids/cholesterol (black). Note that the orientation and exact position of the dye with respect to the acyl chains might be different in the actual membrane environment.

average and s.d. of tD /tD,iSi and D /DiSi with large body of

data for analysis within only 10 s (Fig. 3c). This is a clear advantage over single-point STED-FCS, where a multitude of measurements, each lasting 10 s, were necessary to determine average values of diffusion parameters57. The dependence of D on the size of the observation spot conrmed transient molecular trapping for SM and close to free Brownian diffusion for PE as for the single-point measurements7. Obviously, while in earlier studies the acquisition of this dependence took hours and implied averaging over many cells and preparations, here the total recording time of the whole set of sSTED-FCS data (for ve different observation sizes) was only 50 s. This allowed us to look more deeply into the characteristics of the trapping.

The various sSTED-FCS data recorded for a single STED power showed a large heterogeneity in decay times (Fig. 3b). To explore this heterogeneity further, we investigated the spread in values of tD,i and Di in greater detail. Figure 4a plots the histogram of the values of the transit time tD,i obtained from 1,500 single-pixel data points gathered over six independent orbital scans of 30 s each. While the transit time histogram for free diffusion could be tted by a single Gaussian distribution (as expected from Monte-Carlo simulated data, Supplementary Fig. 4), the histograms of PE and SM clearly contained a second

slower component, whose fraction was increased when the spatial resolution was increased from the confocal d 250 nm value to,

in this case, d 80 nm in the STED recordings. To characterize

the slow component, we tted the main peak of the histograms by a single Gaussian distribution (Fig. 4a black and grey), while the data points omitted from the Gaussian t were regarded as the tail component (Fig. 4a red). With this classication, we estimated the average and s.d. of the apparent diffusion coefcient D for each fraction (Fig. 4b). While the average apparent diffusion coefcient of the main component D 0.4

0.5 mm2 s 1 was in the range of values reported earlier from FCS measurements of supposedly nearly free Brownian lipid diffusion in the plasma membrane7,21,22, the average values were lower for the tail (D 0.3 mm2s 1). When decreasing the observation spot

with STED, average values of the apparent diffusion coefcient (confocal: Dconf, STED: DSTED) hardly decreased for the main component of SM and PE, only slightly for the tail component of PE, but strongly for the tail component of SM. This is further quantied by the ratio DD DSTED/Dconf, which ranges from 0.85

for the main component of PE, 0.8 for the main component of SM, over 0.75 for the tail component of PE to o0.5 for the tail component of SM. As highlighted before (Fig. 3a,c), values of the ratio DD 1 depict free, while DDo1 depicts increased transient

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Figure 3 | sSTED-FCS of uorescent PE and SM lipid analogues in the plasma membrane of live mammalian PtK2 cells. (a) Complementary single-point STED-FCS. Dependency of the apparent diffusion coefcient D on the observation area (squared diameter d2), as determined for PE (red) and SM (blue) from 35 (PE) and 52 (SM) measurements on different spots of the same and different cells (error bars s.d. of the mean, s.d.m.).

PE diffusion was mainly free (blue-dashed line exemplies free diffusion with D 0.55 mm2 s 1), while the dependence of D(d2) of SM indicated

anomalous, trapped diffusion. (b) Exemplary temporal correlation curves G(tc) from single orbital scans over PE- (blue) and SM-labelled (red) cells for confocal (dark) and STED (sallow) recordings (d(STED) 60 nm),

respectively. Each correlation curve represents one spatial position on the scanning orbit. The STED recordings reveal a larger spread (heterogeneity) for PE and SM compared with confocal resolution. In addition, the transit times of SM were on average longer for the STED data compared with PE. (Inset: scanning confocal image of a PE-labelled PtK2 cell with the white circle indicating a typical orbital scan measurement. Scale bar 2 mm). (c)

The dependency of D(d2) determined with large body of data for analysis from ve sSTED-FCS within 50 s only (2,000 data points in total), revealing strongly hindered diffusion for SM and close to free diffusion for PE as in a (error bars s.d.m.). Scanning parameters: f 3.3 kHz, radius R 1 mm,

pixel width Dxpxl 15 nm.

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Figure 4 | Characterisation of lipid diffusion heterogeneities in the plasma membrane of live PtK2 cells. (a) Histograms of the transit times tD of PE (upper) and SM (lower) for confocal (d 250 nm, left) and STED

(d 80 nm, right) recordings comprising 1,500 data points (different

spatial positions) from six independent scans. The main peak of the histogram (black) was tted with a single Gaussian (red line) and the residuals classied as tail (red). Note the relative increase in the tail in the SM data when resolution was increased from confocal to STED, while for PE it was unchanged. (b) Average apparent diffusion coefcient D (upper panels) of the main component and the tail (red edge) for confocal (black) and STED (grey) recordings. Lower panel depicts the ratio DD DSTED/Dconf with one indicating free diffusion and oo1 indicating hindered diffusion (error bars s.d.m.). The ratios reveal that the tail component was caused

by strong hindered diffusion because of transient molecular trapping. (c) Relative amplitude of the tail component plotted against the mean diffusion coefcient for PE (black) and SM (red). Note how the STED recordings reveal the high fraction (E50%) of positions where SM on average diffused signicantly slower than PE. Shown are the mean values (spots) and standard deviations (lines).

0 PE SM SM

trapping.7 Consequently, the data of Fig. 4b indicate that the tail component represents membrane zones where molecules experienced strong transient trapping, while the main component represented those spatial positions where molecules were only slightly trapped or even mainly diffused freely. In total, SM seemed to be strongly trapped in 50 % of the plasma membrane area, while PE trapping occurred only at 25 % (Fig. 4c). Note that these conclusions could not be dened by the confocal recordings nor from six independent single-point STEDFCS measurements. Rather, for single-point STED-FCS experiments 1,500 individual acquisitions would have been required, taking several hours of measurement time and requiring several exchanges of samples. In contrast, we completed our sSTED-FCS experiments within a few minutes only on a single sample. From our previous single-point measurements we indirectly estimated that each SM lipid became trapped every 200300 nm on average, with an average diffusion coefcient of D 0.40.6 mm2 s 1 in-between the

trapping events, and an average trapping probability of B55%

in o80 nm large observations spots5,7. Deploying sSTED-FCS we now directly revealed the spatial pattern of the trapping sites, which was largely in agreement with the estimation from earlier single-point measurements.

To perceive the spatiotemporal heterogeneity of the membrane environment, we plotted the correlation data for each pixel position separately (correlation carpet, Figs 1c and 5). Here the decays Gi(tC) were normalized to Gi(tC-0) and represented by a colour code, with red showing high values of Gi(tC) at short

correlation lag times tC, blue the basal offset at large tC and the decay or average transit times tD,i can be estimated from the correlation lag times of the yellowish coloured region. Vertical uctuations of the yellowish parts over pixel position thus reveal strong uctuations in transit times along the scanning path. For comparison, the correlation carpet is shown from two consecutive

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PE SMconfocal STED

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Figure 5 | sSTED-FCS maps the spatial and temporal heterogeneity of the uorescent PE and SM lipid analogues in live PtK2 cells. Correlation carpets of PE (left two panels) and SM (right two panels) diffusion of confocal and STED recordings (as labelled) for consecutive 10-s measurement time intervals (as marked on the right side). Total intensity (respective upper panels, normalized), correlation carpets (respective middle panels) and tted transit times tD (respective lower panels). The correlation carpets show the normalized temporal correlation curves corresponding to the pixel positions on the scan orbit (x axis). The correlation amplitude G(tc) is depicted by the colour code, while the correlation time tc is encoded in the y axis. The respective transit times for every pixel on the scan trajectory can be estimated from the colour decay (yellow regions).

Large uctuations in transit times (tD) indicating positions of hindered diffusion are only revealed for SM in the STED recordings. The sites of hindered diffusion were smaller than 80 nm and transient, that is, they changed over consecutive time windows.

confocal and STED recordings of the same orbit. In addition, for each pixel we plotted the normalized signal intensity as well as the average transit times tD,i, as determined by averaging the signal over all times of the intensity carpet and from a t of equation (1) (Methods) to the correlation data, respectively. A strong spatial heterogeneity in tD,i is observable. Compared with the confocal correlation carpets and the correlation carpet expected for free diffusion (Fig. 1c), specically the SM sSTED-FCS data showed sites with strongly prolonged values of tD,i, which make up B50%

of the space. In contrast, the correlation carpets of PE are very similar to those expected for free diffusion, indicating only weak heterogeneity and coinciding with the previous observation of almost free diffusion (Fig. 3a).

To precisely determine the mode of diffusion (for example, values of DD) on each point of the scan trajectory we would have to change the size of the observation spot during a single scan, which is at the moment not possible. However, it is very likely that the sites of slow diffusion are caused by transient molecular arrest (that is, trapping), since we can clearly correlate this observation to the results obtained from the analysis of the sSTED-FCS data of Fig. 4, with the tail component obviously reecting the sites of strongly hindered diffusion, and the main component the rest of space. It has to be noted that the apparent diffusion coefcients of the main component, as well as its ratio DD, were on average slightly lower for SM than for PE (Fig. 4b).

Furthermore, values of tD,i of SM were on average slightly

prolonged compared with PE even outside the strong trapping sites (Fig. 5). Consequently, the SM lipid analogue detects sites of strong (DDo0.5) and weak (DD 0.8) transient molecular trapp

ing alternately over space, while PE shows only weak interactions (DD40.75), which were not clearly distinguishable in space.

Temporal heterogeneity. We next analysed the sSTED-FCS data over consecutive 10-s-time windows (Fig. 5) to estimate the persistence of the trapping sites. While the basic characteristics

stayed the same at each time point (that is, alternating strong and weak trapping sites), the time dependence of the data revealed strong spatiotemporal dynamics in lipid trapping. Note that the positions of the strong trapping sites as well as their total number differ between the consecutive recordings (Supplementary Table 1). Their widths on the other hand hardly exceeded the 80-nm-spatial resolution of our STED recordings, that is, the average size of the strong trapping sites was below 80 nm (Supplementary Table 1). Consequently, the trapping sites appeared to hardly move during the 10-s subsets (which would potentially blur the widths). Yet, the trapping sites must have persisted for up to the timescale of seconds during the 10-s subsets; otherwise, they would not have dominated the FCS decays at those points. We conclude that the trapping sites constantly appear and disappear within seconds. In addition, the trapping sites were on average separated by B200300 nm, and also the transit times at the spatial points in between the strong trapping sites (that is, the characteristics of the presumably weak interactions) uctuate from one 10-s subset to the next.

Note that the spatial heterogeneity in total intensity of the signal (upper layers Fig. 5) was much less pronounced than those of the diffusion and only weakly correlated, which indicates negligible formation of dominant clusters (in detail analysed in Fig. 7, and discussed further below). Overall, our sSTED-FCS data depict spatiotemporal variations in lipid membrane diffusion and interaction dynamics, which are inaccessible with confocal FCS recordings alone (whether single-point or scanning) and also not observable in single-point STED-FCS measurements5.

Molecular characteristics of strong trapping sites. We next investigated the molecular characteristics of the strong trapping sites, especially with regards to an increased lipid order as

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predicted for a lipid raft environment. We employed a new class of uorescent lipid and cholesterol analogues with improved properties for entering liquid-ordered and -disordered membrane regions compared with conventional uorescent lipid analogues23. Saturated 1,2-distearoyl-sn-glycero-3-phosphoeth-

anolamine (DSPE), unsaturated 1,2-dioleoyl-sn-glycero-3-phosphoethanolamine (DOPE) and cholesterol were labelled with the organic dye KK114 (ref. 24) at the head group via a hydrophilic PEG-linker with molecular weight 2 and 1 kDa (for structures, see Fig. 2). The existence of the PEG-linker

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c

confocal STED

150

DSPE-PEG

100

50

0

Frequency

100

50

0

DOPE-PEG Chol-PEG

100

50

0 0 20 40 60 80

0 10 20 30

Transit time tD [ms]

d

Tail

e

0.6

Main confocal STED

DOPE Chol DSPE DOPE Chol -PEG -PEG

conf. STED

50

DD [m s 1 ]

Rel. Amplitude of tail %

DOPE-PEG

DSPE-PEG

Chol-PEG

0.2

0

30

1.0

0.5

0 DSPE

10

0.1 0.3

0.5

D [ms1]

Figure 6 | sSTED-FCS analysis of the pegylated uorescent lipid and cholesterol analogues in the plasma membrane of live PtK2 cells. (a) Correlation carpets of DSPE-PEG (left), DOPE-PEG (middle) and Chol-PEG (right) diffusion for STED recordings (measurement time of 10 s) as in Fig. 5. Hardly any uctuations in transit times indicate negligible sites of strong hindered diffusion. The corresponding confocal correlation carpets and time-dependent changes in correlation carpets are depicted in Supplementary Fig. 6. (b) Dependency of D on the observation area (diameter d) for the pegylated analogues (as labelled). Shown are the average values and s.d.s as determined by sSTED-FCS (d 25080 nm, 1,500 data points) and single-point FCS (d 50 nm,

10 data points; error bars s.d.m.). Despite their different phase-partitioning preference, all analogues show comparable free Brownian motion.

(c) Histograms of the transit times tD of DSPE-PEG (upper), DOPE-PEG (middle) and Chol-PEG (lower) for confocal (d 250 nm, left) and STED

(d 80 nm, right) recordings comprising 1,500 data points (different spatial positions) from 10 independent scans. The main peak of the histogram (black)

was tted with a single Gaussian (red line) and the residuals classied as tail (red). Note the negligible relative increase in the tail when resolution was increased from confocal to STED, indicating only weak hindrances in diffusion. (d) Average apparent diffusion coefcient D (upper panels) of the main component and the tail (red edge) for confocal (black) and STED (grey) recordings, as determined from c. Lower panel depicts the ratio DD DSTED/Dconf with 1 indicating free diffusion and oo1 for hindered diffusion. The ratios indicate that the tail component was caused by hindered diffusion because of transient molecular trapping (error bars s.d.m.). (e) Relative amplitude of the tail component plotted against the mean diffusion coefcient,

as determined from d. Note that the fraction of the tail component does only slightly increase from confocal to STED recordings. Shown are the mean values (spots) and s.d.s of the mean (lines).

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2

50

1

0

Normalized transit timet D

PE (Ld) SM (Ld)

DSPE-PEG (Lo)

DOPE-PEG (Ld) Chol-PEG (Ld/Lo)

2

1

0 0 1 2

0 1 2

0

0 1 2

Normalized particle number N

2

0

Lipid rafts

1

Norm. transit time

0

Lo probe Ld probe

Lo+Ld probe Lo+Ld probe

2 No domains Local curvature

1

Lo domains

Trajectory

100 nm

0

1

2 1 2

0

Norm. particle number

Figure 7 | Investigating the correlation between local mobility and concentration of lipid analogues. (a) Two-dimensional frequency histogram of pair values of transit time tD and local concentration (average particle number N per observation spot) for the different lipid analogues (labelled, with Ld and Lo preference given) as calculated from the respective sSTED-FCS data of Figs 4 and 6 (1,500 data points each). For each correlation curve of the sSTED-FCS recordings values of tD and N were determined by tting Supplementary equation (1) to the curves. Normalized values of tD//tDS and N//NS were calculated by division with the respective average values /tDS and /NS over all pixels of each scan trajectory. Note the increased spread of values towards large tD for SM (without a correlation, indicating trapping), and the positive correlation (tilt to the right) for the pegylated lipid analogues. (b) Scheme of potential liquid-ordered (Lo) lipid domains (red) in a Ld environment (orange) of the plasma membrane and an exemplary scanning trajectory (grey). (c)

Scheme of expected tD//tDS versus N//NS correlation plots for different scenarios. (Upper panels) In case of transient incorporation into Lo domains (rafts) a positive correlation (right tilt) is expected for the Lo-probe (DSPE-PEG) and a negative correlation (left tilt) for the Ld-probe (DOPE-PEG, SM,

PE), respectively. However, no Lo- and Ld-probe-specic behaviour was detected. (Lower left panel) In absence of nanodomains no correlation is expected for all probes, with an isotropic distribution for a freely diffusing probe (red). (Lower right panel) A positive correlation (right tilt) is expected for locally curved membrane regions independent of phase preference, as observed for the pegylated probes. For a detailed description of the correlation analysis and explanation of the expected distributions see Supplementary Note 3.

dramatically improved the partitioning of the saturated phosphoglycerolipid DSPE-PEG-KK114 into liquid-ordered regions (partitioning coefcient of up to Lo% 80). As

expected, the unsaturated DOPE-PEG-KK114 preferred liquid-disordered regions (Lo%o30), while the cholesterol analogue

Chol-PEG-KK114 only slightly preferred the liquid-ordered phase (Lo% 5060) and therefore served as a neutral reporter

(for partitioning values of all analogues see Supplementary Fig. 5). Interestingly, none of these pegylated lipids revealed strong heterogeneity of diffusion as seen for the SM analogue in sSTED-

FCS measurements (Fig. 6a). The complete sSTED-FCS analysis exposed even less heterogeneity (and thus less possible interactions) for these analogues than for the PE analogue without the PEG-linker (Fig. 6be). While the inert PEG-linker may hinder head-group-specic lipid interactions, the data clearly demonstrate that the trapping sites of SM were independent of preference for lipid-ordered or -disordered environments. While trapping diffusion was rather specic for the sphingolipid and slightly for the PE analogue7,11, for the noninteracting pegylated analogues, regions of slightly lowered diffusion were mainly

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correlated with a small increase in local concentration of these analogues (Fig. 7a). This indicates that the strong heterogeneities in diffusion of the SM analogue were dominated by trapping (transient binding to slow-moving or immobilized objects), while the slight variations in local diffusion of the pegylated lipids were most likely caused by local membrane curvature (pits) (Fig. 7b).

DiscussionBy performing fast orbital beam scanning on a STED microscope and employing novel uorescent lipid analogues with different phase-partitioning characteristics, we substantially expanded our previous STED-FCS experiments. In contrast to single-point STED-FCS, the beam-scanning STED-FCS (sSTED-FCS) approach reported in this paper now allows (i) recording hundreds of correlation data and calculating average values of diffusion parameters within a measurement time of a few seconds only, which previously took minutes (Figs 3 and 4), (ii) studying molecular interactions at different spatial positions simultaneously and detecting neighbouring heterogeneous molecular environments with subdiffraction spatial resolution (Fig. 5),(iii) studying relatively slowly diffusing molecules, which was previously biased by photobleaching (Supplementary Fig. 7a) and(iv) abolishing the necessity for additional calibration measurements (Supplementary Fig. 3a). However, compared with single-point measurements the scanning process lowers the sampling rate of an individual correlation curve, thus reducing the signal-to-noise ratio on each pixel of the correlation carpet (Supplementary Fig. 7b). This becomes even more pronounced for STED recordings, since with reduced observation spots the transit time and often also the signal-to-noise ratio decrease6. However, if the spatial information is omitted and all pixels from the whole scanning trajectory are pooled (as in Fig. 3c), the statistical accuracy of a sSTED-FCS recording is higher than that of a nonscanned single-point FCS measurement (Supplementary Fig. 7b).

Note that the scanning process limits the fastest diffusion processes that can be studied as well as the spatial resolution of the sSTED-FCS experiments (Supplementary Fig. 2). In our case (as in usual scanning microscopes), the maximum applicable scanning frequency was several kHz (o6 kHz), that is, molecules should have a transit time through the observation spot of 40.8 ms. Lipids and fast-moving proteins on average diffuse with a coefcient Do1 mm2s 1 in the plasma membrane of living cells, that is, 40.8 ms transit times are only provided for observation spots of 46080 nm in diameter. Consequently, our current sSTED-FCS measurements provided typical spatial resolutions of 6080 nm. Sub-60-nm spatial resolution as achieved in previous single-point STED-FCS data are, however, sometimes required to more accurately characterize molecular dynamics, such as on- and off-rates of molecular complexes6. Therefore, single-point and scanning STED-FCS measurements may complement each other, as indicated in Fig. 7b and outlined further on.

The presented sSTED-FCS experiments enabled us to shed new light on the diffusion dynamics of lipids in plasma membranes of living mammalian cells, taking uorescent phospholipid, cholesterol and sphingolipid (SM) analogues as examples. For SM, we disclosed spatial alterations of sites of weak and strong trapping interactions (Fig. 5). The strong trapping sites were transient on timescales of seconds, did not diffuse as stable entities, were separated on average by 200300 nm and extended less than 80 nm in space (Fig. 5). Taking the results of our complementary single-point STED-FCS5,6 (Fig. 3a), we can conclude that in these strong trapping sites, SM transiently interacts with slow-moving

or immobilized membrane components such as proteins, with on- and off-rates in the range of 80 s 1. In addition, SM hardly moves during these trapping events5,10.

The sSTED-FCS experiments with the new pegylated uorescent phospholipid and cholesterol analogues revealed no signicant spatial heterogeneity or trapping sites (Fig. 6), independent of their preference for liquid-ordered or -disordered membrane environments (Supplementary Fig. 5). This and the fact that the employed SM analogue did not prefer liquid-ordered environments in model membranes7,11 let us conclude that the trapping sites observed for SM are not those molecular assemblies of high lipid order traditionally dened as lipid rafts. Rather than partitioning into lipid rafts based on lipid-phase separation, the observed interactions of SM seem to be specic molecular complexes such as between lipids and proteins7. While being stable for up to seconds, these complexes render a constant exchange of SM lipid molecules in the time range of milliseconds, and with negligible movement inside. In addition to these well-separated profound assemblies, the SM lipids demonstrated the possibility of weak anomalies in diffusion at every point in space. In contrast to this trapping diffusion, pegylated uorescent lipid and cholesterol analogues showed hardly any signs of molecular interactions. Analysis of the correlation between local mobility and concentration of the different lipid probes again indicates that with our current sSTED-FCS approach we were not able to detect phase-separated lipid nanodomains (rafts; Fig. 7). Rather, the very weak heterogeneity of the pegylated lipid analogues was most likely caused by out-of-plane diffusion, for example, in local membrane pits (Fig. 7b). Despite their different partitioning preferences, all three pegylated probes showed a positive correlation between local transit times and local concentration, which contradicts the predictions based on a pattern of distinct Lo and Ld domains (compare Fig. 7). This persistent positive correlation could be the result of projecting locally curved membrane topography on a at two-dimensional (2D) surface25, as it is carried out in the sSTED-FCS measurement. In any case, the effect of potential local membrane height differences on the diffusion of the probes is measurable but minor compared with the trapping of the SM analogue. We note that a separation into Lo and Ld phases as distinct as in ternary model membranes is not to be expected in the plasma membrane, as revealed from the signicantly reduced difference in molecular order between Lo and Ld regions in phase-separated giant plasma membrane vesicles generated from living cells (Supplementary Fig. 5)11. In addition, the resolution of our current (s)STED-FCS analysis might still be too low to observe small heterogeneity in diffusion because of more ordered nanodomains as small as o20 nm in diameter. Moreover, since our sSTED-FCS analysis so far probed only the basal plasma membrane of a limited number of cultured cell types, we may miss specialized membrane domains occurring either very sparsely or are localized on the apical or lateral side.

A more complete display of the observed molecular complexes of the SM analogue could arise from expanding sSTED-FCS to the simultaneous detection of multiple colours. This would allow labelling of multiple lipids or proteins and thus could highlight the lipid interaction partners. The complete disentangling of spatiotemporal heterogeneity into different diffusion modes of, for example, actin meshwork connement, partitioning into lipid domains and molecular trapping would require the determination of diffusion coefcients D(d) on multiple spatial scales d (compare Fig. 3a,c) during a single sSTED-FCS measurement. This is not possible with the current experimental scheme, since it would require simultaneous recordings at different STED laser intensities. However, as recently demonstrated, the D(d) dependency can be extracted out of a single STED-FCS measurement

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by using pulsed excitation in conjunction with a continuous-wave STED laser and subsequently correlating uorescence photons from increasing time delays relative to the excitation pulse (gated STED-FCS)26. In addition, expansion of sSTED-FCS to pair-correlation FCS20,27 will highlight obstacles in the diffusion pathways of the lipids, especially along all spatial directions when combined with circular beam-scanning13. Beam-scanning recordings on a STED microscope can also be combined with further uorescence uctuation spectroscopy approaches such as uorescence intensity distribution analysis or photon counting histograms28,29, and number and brightness analysis30, possibly highlighting changes in oligomerization states.

The sSTED-FCS experiments shown here once again underscored the power of combining molecular uctuation analysis with beam-scanning as well as with the tunable subdiffraction resolution of STED microscopy, thereby affording a powerful method for revealing molecular details of the cellular plasma membrane. With sSTED-FCS in hand, we should be able to expand the scope of STED-FCS experiments to study other cellular processes such as molecular transport into organelles with high spatiotemporal resolution31.

Methods

sSTED-FCS microscope. All sSTED-FCS experiments were performed on a confocal custom-built STED microscope whose main features are depicted in Supplementary Fig. 1. The confocal unit of the STED nanoscope consisted of an excitation and detection beam path. A bre-coupled pulsed laser diode operating at lexc

635 nm with a pulse length of 80 ps (LDH-P-635, PicoQuant, Berlin, Germany) was used for excitation of the red uorescence. After leaving the bre, the excitation beam was expanded and focused into the sample using an oil immersion objective (HCXPLAPO 100, NA 1.4, Leica Microsystems). The

uorescence emitted by the sample was collected by the same objective lens and separated from the excitation light by a custom-designed dichroic mirror (HQ640/ 40, AHF Analysentechnik, Tuebingen, Germany). In the following, the uorescence was focused on a multimode bre splitter (Fiber Optic Network Technology, Surrey, Canada). The aperture of the bre acted as a confocal pinhole of 0.78 of the diameter of the back-projected Airy disk. In addition, the bre 50:50 split the uorescence signal, which was then detected by two single-photon-counting modules (APD, SPCM-AQR-13-FC, Perkin Elmer Optoelectronics, Fremont, CA). The detector signals were acquired with a single-photon-counting PC card (SPC 830, Becker&Hickl, Berlin, Germany). The confocal set-up was extended by integrating a STED laser beam. A modelocked Titanium:Sapphire laser (Ti:Sa, MaiTai, Spectra-Physics, Mountain View, USA) acted as the STED laser emitting subpicosecond pulses around lSTED 780 nm with a repetition rate of 80 MHz.

The pulses of the STED laser were stretched to 250350 ps by dispersion in a SF6 glass rod of 50 cm length and a 120-m-long polarization maintaining single-mode bre (PMS, OZ Optics, Ontario, Canada). After the bre, the STED beam passed through a polymeric phase plate (RPC Photonics, Rochester, NY), which introduced a linear helical phase ramp 0rFr2p across the beam diameter.

This wavefront modication gave rise to the doughnut-shaped focal intensity distribution featuring a central intensity zero. The spatial overlay between excitation and STED laser was realized with a dichroic mirror (zt740sprdc, AHF Analysentechnik). The temporal synchronization of the excitation and STED pulses was achieved by triggering the pulses of the excitation laser using the trigger signal from an internal photodiode inside the STED laser and a home-built electronic delay unit, which allowed a manual adjustment of the delay with a temporal resolution of 25 ps. The circular polarization of the STED and excitation laser light in the focal plane was maintained by a combination of l/2 and l/4 retardation plates in both beam paths (B. Halle, Berlin, Germany).

Integration of a fast scanning unit enabled rapid scanning of the excitation and STED beam across the sample plane (Fig. 1a). A digital galvanometric two-mirror scanning unit (Yanus digital scan head, TILL Photonics, Grafeling, Germany) was used for this purpose. The combination of an achromatic scan lens and a tube lens in a 4f-conguration (focal lengths of 50 and of 240 mm, Leica, Wetzlar, Germany) realized a stationary beam position in the back aperture of the objective, preventing peripheral darkening within the focal plane at large scan ranges, such as vignetting. The maximal frequency of the Yanus scanner depended on the scan amplitude and varied between 1 and 6 kHz for scan amplitudes up to 150 mm, respectively.

The hardware and data acquisition were controlled by the software ImSpector (http://www.imspector.de/

Web End =http://www.imspector.de/).

Data acquisition, processing and analysis. In order to calculate the correlation function from the detected signal at each position of the scanned orbit, it was crucial to accurately determine the spatial origin of each detected photon. The data acquisition was controlled by the software ImSpector, which initialized and

generated the voltage waveforms for the scan movement and synchronized the data acquisition by the single-photon-counting PC card. Figure 1 depicts a typical recording in a scanning FCS experiment. Here the laser spots were continuously scanned along a circular trajectory of radius R 1.2 mm and frequency f 4 kHz

(Fig. 1a). The scan trajectory was subdivided into a dened number of pixels Npxl

(50400), and the intensity uctuations in time for each pixel were stored as a 2D array (intensity carpet, I(i,t) for each pixel i, Fig. 1b)12.

Since the diffusion of the particles does not depend on the incident laser light (which we can safely assume, following previous control measurements, even for the strong STED laser light57), we evaluated the temporal uctuations for each column of the intensity carpet by FCS. Using a multiple-tau algorithm, we correlated each column of the recorded intensity I(i,t) yielding a temporal correlation curve Gi(tc) /I(i,t) I(i,t tc)S//I(i,t)S2 for each pixel i (correlation

carpet, Fig. 1c, with tc denoting the temporal correlation time lag and /yS averaging over time t)12,13. Since the laser spots were scanned continuously along the scan trajectory, we had to choose pixel sizes Dxpxl much smaller than the diameter d of the observation area (as outlined in the Supplementary Notes, Methods). Only in this case, the observation spot was still sufciently well approximated by a Gaussian detection prole and the theoretical model of a single-spot FCS measurement could well be applied:

Gi tc

1 Ni

1

1 tc=tD;i

1

where Ni is the particle number (that is, the mean number of uorescent molecules in the detection spot, which is proportional to the concentration divided by the measurement volume (or area for 2D samples)) and tD,i is the average transit time of the uorescent molecules diffusing through the observation area. Fitting the above equation to the FCS data resulted in a value of the average transit time tD,i or

the apparent diffusion coefcient Di o02/(4 td,i) d2/(8 ln(2) td,i), and the particle

number Ni for each pixel i of the circular scan. Here o0 is the 1/e2 radius and d o0O(1 ln(2)) the diameter (given as the FWHM) of the observation spot

for a given STED intensity, which is either determined from measurements of the free-diffusing lipid analogue in a supported lipid bilayer (Methods) or from the spatial correlation analysis (equation (3)). One sSTED-FCS measurement thus resulted in Npxl values of tD,i or Di, which, on one hand, allowed the investigation of diffusion characteristics over space (by plotting tD,i or Di along the different

spatial coordinates i of the circular scan) and, on the other hand, allowed the determination of average values tD /tD,iSi and D /DiSi (with /ySi

denoting the averaging over all Npxl pixel values i) and s.d.s with large body of data for analysis.

Note that we in our sSTED-FCS analysis discarded the introduction of a parameter for anomalous diffusion, since we were mainly interested in values of the average transit time tD,i , which is accurately well extracted using equation (1)22.

The introduction of an additional anomaly parameter hardly changed the results obtained for tD,i, but rather decreased the accuracy of its determination, a reason why we kept the number of free tting parameters to a minimum. In previous single-point STED-FCS experiments, we had introduced an anomaly parameter to extract anomalies in diffusion from a single FCS curve5. An anomaly in diffusion is however already well extracted from a single sSTED-FCS analysis, since hundreds (Npxl) of FCS curves are simultaneously gathered. Hence, we used the heterogeneity in the distribution of the resulting values of tD,i (or Di) as a measure for the

respective extent of anomalous diffusion (compare Fig. 4).

All data analysis procedures were implemented into Matlab (The MathWorks Inc).

Spatiotemporal correlation analysis. The spatiotemporal correlation data of our sSTED-FCS experiments (Supplementary Figs 2 and 3) were calculated by the 2D spatiotemporal correlation function G(x,tc) /I(i,t) I(i x,t tc)S//I(i,t)Si,t2 of

the intensity carpet I(i,t) with x and tc denoting the spatial and temporal correlation lag times, respectively, and /ySi,t indicating the averaging overall spatial i and temporal t recordings. An important prerequisite for this analysis is that the spatial and temporal separations between adjacent pixels and subsequent scans is constant within the intensity carpet. As for the temporal correlation, for pixel sizes Dxpxl

much smaller than the diameter d of the Gaussian-shaped observation spot prole, the theoretical model of the spatiotemporal correlation function can be calculated according to12.

G x; tc

1N 1

1

exp

8 ln 2

D

d2

1tc x=v

!

2x2

2

Here D is the apparent diffusion coefcient, d the diameter of the observation spot (given as the FWHM as before) and v the scan velocity. The spatiotemporal correlation function is effectively split into two terms. The rst termexpresses the correlation because of the diffusional movement of the particles, rendering the average transit time tD d2/(8 ln(2) D), as it is extracted from

conventional FCS measurement (equation (1)). The second exponential term in contrast reects the correlation because of the scanning movement of the observation area.

For a scan velocity v that is much faster than the diffusion (v44D/d, which is a prerequisite of any scanning FCS measurement12,17,18), this expression

d 2 ln 2

4D tc xv

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decouples D from d, and the spatial correlation at zero lag time tc 0, G(x,0),

can be written as

G 0

1N 1

1

exp

2x2

d 2 ln 2

4D xv

8 ln 2

D

d2

1 x=v

!

1N exp

2x2

d 2 ln 2

!

3

realizing a straightforward determination of d. Hence, with the scan velocity v known from the scanning speed, tting both equations (2) and (3) to the experimental data allowed us to simultaneously determine the two quantities D and d in a single measurement, making the characterization of d from control experiments on model membranes obsolete19.

Sample preparation. 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) and Ganglioside GM1 (Ovine Brain) were purchased from Avanti (Avanti Polar Lipids Inc., Alabaster, Alabama, USA). Cholera Toxin B (CtxB) subunit was purchased from Sigma-Aldrich and labelled with the amine reactive dye KK114-NHS24 (now AbberiorSTAR, Abberior) according to the standard protocol, resulting in less than or equal to two dyes per CtxB. The two lipid analogues labelled with the organic dye Atto647N, N-(Atto647N)-1,2-dipalmitoyl-sn-glycero-3-PE (head-group labelling; DPPE-Atto647N or simply PE) and N-(Atto647N)-sphingosylphosphocholine (acyl-chain replacement; SM-Atto647N or simply SM) were purchased from Atto-Tec (ATTO-TEC GmbH, Siegen, Germany). The lipids labelled with the organic dye KK114, PE-KK114, DSPE-PEG(2k)-KK114 (or simply DSPE-PEG, head-group labelling), DOPE-PEG(2k)-KK114 (or simply DOPE-PEG, head-group labelling) and Cholesterol-PEG(1k)-KK114 (or simply Chol-PEG) were synthesized as described previously23 using starting compounds DSPE-PEG(2000)-NH2, DOPE-PEG(2000)-NH2 (Avanti Polar Lipids), Cholesterol-PEG(1000)-NH2 (Nanocs Inc., NY, USA) and the amine reactive dye KK114-NHS24. The molecular structures of all uorescent lipid analogues are depicted in Fig. 2.

Supported lipid bilayers were prepared as described in ref. 23. Glass Cover slides were cleaned in a 3:1 mixture of concentrated H2SO4 and 30% H2O2. After acid cleaning, the glass slides were extensively rinsed with pure water and then stored in water for not longer than a week. Finally, the single phase liquid-disordered bilayers were made by spin-coating (2,000 r.p.m.) 20 ml of DOPC (2 g l 1 in methanolchloroform). After 10 min solvent evaporation under vacuum the sample was hydrated with 150 mM NaCl, 10 mM TRIS/HCl pH 7.4 and rinsed several times until a clean single bilayer remained on the surface. For the sSTED-FCS experiments of Supplementary Fig. 2, 0.01% of PE-KK114 was added to DOPC, and for those of Supplementary Fig. 3 0.1% of GM1 were added to DOPC, 100 nM of the labelled CtxB added after spin-coating and unbound CtxB rinsed off after 5 min of incubation.

The mammalian PtK2 cell line (epithelia kidney cells from Potorous tridactylis) was the same as in previous measurements57,10,11 and was cultured in Dulbeccos Modied Eagle Medium (DMEM) supplemented with 5% fetal calf serum,100 U ml 1 penicillin, 100 mg ml 1 streptomycin (all Invitrogen) and 1 mM pyruvate (Sigma) at 37 C kept within a water-saturated atmosphere of 5% CO2 in air. Before the experiments, cells were seeded on standard glass coverslips (no. 1.5, that is 1018 mm in thickness) to a conuence of B70% and grown at 37 C for 24 h.

Incorporation of the uorescently labelled lipid analogues to the plasma membrane of live PtK2 cell was performed as described in ref. 5. The passive incorporation of the lipids was facilitated via the formation of a bovine serum albumin (BSA) complex of the lipid analogue. The BSA complex was prepared by drying 100 nmol of the lipid stock solution under a stream of nitrogen. The dried lipids were then dissolved in 5 ml of ethanol and subsequently diluted in 1 ml of defatted BSA solution (7 g l 1 defatted BSA in DMEM without phenol-red buffered with 10 mM HEPES, pH 7.4). The stock solution of the pegylated cholesterol analogue was prepared in PBS without BSA. The BSAlipidstock solution was then diluted in HDMEM to a nal concentration of 5500 nM, varying for the individual uorescent lipid analogues. Previous to the uorescent labelling, the cells were washed in warm HDMEM and incubated with the diluted BSAlipid solution for 5 min at 37 C. Afterwards, cells were washed in HDMEM and mounted into a microscope chamber.

Measurements were taken at room temperature and completed after 30 min before any signicant morphological changes in the cell occurred. All measurements were carried out for at least 10 s, providing a correlation time longer than two orders of magnitude times the typical transient time of the labelled lipids through the confocal observation area. As detailed previously5,7,9, we ensured a non-detectable (at least by STED-FCS) inuence by the dye label (apart from an altered liquid-ordered partitioning preference), and that the observation times were given by the transit times through the observation spot and not shortened because of photobleaching, and that biasing effects by the excitation or STED light because of photobleaching, heating or other (nonlinear) effects and diffusion of nonintegrated lipids (or dye tags) could be excluded.

sSTED-FCS simulations. To estimate the signicance of the spatiotemporal heterogeneities observed in our sSTED-FCS experiments, we performed computer

simulations of free Brownian diffusion. Simulations of sSTED-FCS were run in MATLAB. Free diffusion of single particles in an 8 8-mm simulation box with

periodic boundaries was simulated by adding random step sizes for the x and y coordinates independently drawn from a normal distribution with s O(2D Dt),

where D is the lateral diffusion coefcient and Dt the sampling time. Fluorescence uctuations of each pixel on a circular trajectory centred in the middle of the simulation box were calculated as described in ref. 32. The average counts per molecule, which is a function of the properties of the uorescence dye and the collection efciency of set-up, and the dark count rate (noise) were adjusted to match the experimental conditions.

Partitioning experiments. Partitioning preference of the uorescent lipid analogues into less and more ordered membrane regions (liquid-disordered Ld and liquid-ordered Lo membrane phases) was determined from uorescence scanning experiments (Zeiss 710 confocal) on phase-separated giant unilamellar vesicles of a ternary lipid mixture (DOPC:SM:cholesterol (2:2:1)) and on phase-separated giant plasma membrane vesicles, generated from PtK2 cells33. The Lo-partitioning coefcient Lo% F(Lo)/[F(Lo) F(Ld)] was calculated from the uorescence

intensity prole of a line scan through Lo and Ld phases where the Ld phase was marked by the uorescent membrane molecule Fast-DIO (Invitrogen)11.

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Acknowledgements

We thank Tanja Gilat (MPI Gttingen) for help with the cell culture, Vladimir Belov and Gyuzel Mitronova (MPI Gttingen) for the synthesis of the pegylated uorescent lipid analogues, Debora Machado Andrade (MPI Gttingen) for fruitful discussions, Dominic Waithe (WIMM, Oxford) for help with the Supplementary Table 1, and Veronica Buckle (WIMM, Oxford) for proofreading. This work was supported by the German Research Foundation within the SFB 755 (project B11), MRC funding to C.E., and the EMBO long-term fellowship to E.S.

Author contributions

V.M. and A.H. designed and conducted experiments and analysed the data. H.T. helped with the experiments. E.S. performed the partitioning experiments. A.S. helped with the software IMSPECTOR to drive the experimental set-up. C.E., S.W.H. and A.H. designed the research. C.E. and A.H. wrote the manuscript. All authors contributed in discussing the data, experiments and manuscript.

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How to cite this article: Honigmann, A. et al. Scanning STED-FCS reveals spatio-temporal heterogeneity of lipid interaction in the plasma membrane of living cells. Nat. Commun. 5:5412 doi: 10.1038/ncomms6412 (2014).

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