Abstract
Nature is known to engineer complex compositional and dynamical platforms in biological membranes. Understanding this complex landscape requires techniques to simultaneously detect membrane re-organization and dynamics at the nanoscale. Using super-resolution stimulated emission depletion (STED) microscopy coupled with fluorescence correlation spectroscopy (FCS), we reveal direct experimental evidence of dynamic heterogeneity at the nanoscale in binary phospholipid-cholesterol bilayers. Domain formation on the length scale of ~200–600 nm due to local cholesterol compositional heterogeneity is found to be more prominent at high cholesterol content giving rise to distinct intra-domain lipid dynamics. STED-FCS reveals unique dynamical crossover phenomena at length scales of ~100–150 nm within each of these macroscopic regions. The extent of dynamic heterogeneity due to intra-domain hindered lipid diffusion as reflected from the crossover length scale, is driven by cholesterol packing and organization, uniquely influenced by phospholipid type. These results on simple binary model bilayer systems provide novel insights into pathways leading to the emergence of complex nanodomain substructures with implications for a wide variety of membrane mediated cellular events.
Similar content being viewed by others
Introduction
In the cell membrane, cholesterol plays a key role in regulating various biophysical and biochemical processes. Specific interactions with other membrane lipids and proteins not only helps maintain both membrane structural integrity and fluidity but also modulates events such as signalling, transport and binding1. The distribution of cholesterol varies widely in mammalian cell membranes, with concentrations ranging from ~20–30%2 in the plasma membrane and ~1% in the endoplasmic reticulum (ER), of the total lipid content in the cell3. Cholesterol is widely believed to be the key driving force behind formation of compositionally and dynamically heterogeneous nanodomains in cell membranes, critical for various biological activities including signalling, viral infections and membrane trafficking4,5,6,7,8. In view of the widely accepted paradigm that biological membranes organize into domains of different compositions and sizes, both at the nano- and microscale, a large number of studies have focussed on investigating domain formation and phase separation in model phospholipid-cholesterol membranes using both experimental9,10,11 theoretical12, 13 and molecular dynamics14, 15 techniques. The current view emerging out of these studies is that domains are dynamic, heterogeneous structures rich in cholesterol and sphingomyelin (SM), ranging from ~10–200 nm in diameter, and present in the lipid membranes of all eukaryotic cells8.
In order to connect lipid structure and domain formation, model ternary systems involve a combination of high melting saturated lipids, a low melting unsaturated lipid and cholesterol16. In such systems, domain formation is related to the presence of co-existing phases in the phase separated regimes. However domain formation at micron and sub-micron scales have also been observed in simple binary phospholipid-cholesterol systems, and can arise from the coexistence of a liquid-ordered (L o ) and a liquid-disordered (L d ) phase within the membranes or even exist in the absence of distinct phase separation above the melting temperature of the given phospholipid17. Several independent techniques have been used to verify the presence of nanoscale domains in a variety of model bilayer systems, involving multiple lipid components and/or peptides and proteins18,19,20,21,22,23,24,25,26,27,28. For example, recently 50 nm lipid nanodomains with a domain lifetime of 220 ± 60 ms has been observed using interferometric scattering microscopy (iSCAT) microscopy in phase-separated DOPC:bSM(1:1) droplet interface bilayers29.
The intriguing possibility of observing nanoscale domain formation in the absence of distinct thermodynamic phase separation in minimal two-component phospholipid-cholesterol membranes, particularly at high cholesterol concentrations has recently received renewed attention15, 30, 31. Recent molecular simulation studies suggest that nanoscale domain formation can also exist within an otherwise homogeneous L o and/or L d phase indicating the emergence of complex nanoscale morphology driven by phospholipid-cholesterol interactions14, 15, 32. The key question which remains unanswered despite, at least, two decades of intense research is whether there exists a universal underlying physical principle to explain the emergence of nanoscale compositional and dynamical heterogeneity. In an attempt to explain the emergence of this phenomenon several models have been proposed33,34,35.
Obtaining microscopic insight on the causal connection between lipid composition and nanodomain formation has proven difficult, largely, due to the small length scales involved (10–100 nm). To probe the existence, origin and extent of such spatio-temporal biomembrane platforms at the nanoscale, super-resolution microscopy techniques, especially stimulated emission depletion based technique (STED)36, in combination with fluorescence correlation spectroscopy (STED-FCS)37,38,39,40,41 could provide a powerful means to correlate dynamics with local nanoscale membrane structures. STED-FCS studies on plasma membrane revealed complex nanoscale lipid dynamics attributed to the affinity of sphingomyelin to cholesterol40. This and more recent studies suggest the ability of STED-FCS to probe nanoscale dynamical heterogeneity of lipids in model membranes and potentially probe domain specific dynamics within length scales of 10’s of nm’s41.
Here, we report extensive studies on supported phospholipid bilayer platforms with variable phospholipid and cholesterol composition using STED-FCS to directly detect the presence and emergence of nanodomains in the simplest of two-component lipid bilayers. For this purpose we have chosen lipid bilayer systems consisting of either a low melting unsaturated 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) lipid, a low melting mono-unsaturated 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) or a high melting saturated lipid 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC), in combination with cholesterol (Chl) with variable composition. At 50% cholesterol composition, we observe, a bimodal distribution of liquid-like diffusivities in confocal FCS, confirming the presence of heterogeneous lipid partitioning in an otherwise homogeneous bilayer. Strikingly, STED-FCS measurements reveals the existence of crossover at length scales of ~100–150 nm, in diffusion behavior within the spatially distinct regions as observed in confocal FCS. This dynamically distinct signature at the nanoscale has not been measured before. Further, the presence of Brownian/non-Brownian dynamics with or without a length-scale dependent crossover is dependent on the location of the domains in the dynamically distinct regions. At a lower cholesterol concentration of 33% only a weak evidence of non-Brownian dynamics is observed in DOPC and DMPC bilayers. Our results provide clear evidence of the rich level of nanoscale dynamical heterogeneity possible in two-component low melting lipid bilayers mediated by cholesterol and lipid saturation, with a direct and quantitative estimate of the length scales at which the heterogeneity exists. Since the experimentally observed dynamical crossover occurs without an underlying structural transition on the same length scale it is possible that this lipid dynamics is akin to glass-like dynamics recently reported using molecular dynamics simulations of a single component high melting gel-like phospholipid bilayer33. Further, our STED-FCS results on model membranes sheds light not only on the pathways for inducing nanosized proteolipid domains in eukaryotic cell membranes, but also opens up the feasibility of probing intra-domain lipid dynamics to obtain insight into various bio-membrane mediated processes occurring at the nanoscale.
Results
Cholesterol concentration dependent lipid dynamical heterogeneity
Supported lipid bilayers (SLBs) containing different lipids such as DOPC, POPC and DMPC with variable concentration of cholesterol were prepared using the Langmuir-Blodgett (LB) technique. The isotherms of cholesterol/phospholipid mixed monolayer did not show demixing, and the successful transfer of two consecutive monolayers were performed at a holding surface pressure of 35 mN/m (Fig. S1, SI) with a transfer ratio of 1 ± 0.1. Optical imaging and fluorescence correlation spectroscopy (FCS) measurements were carried out within 4–5 h of the LB transfer at 24 ± 2 °C. At 25 and 33% cholesterol, confocal and STED microscopy of the SLBs revealed a fairly homogeneous bilayer with uniform distribution of fluorescent intensity of Atto488-PE stained prior to bilayer fabrication (Figs S2–4, SI). Lipid diffusion is a commonly used parameter to detect distinct co-existing phases. Fluorescence correlation spectroscopy (FCS) revealed a unimodal lipid diffusion (for fitting procedure and analysis of FCS, see Fig. S5, SI) indicative of the absence of any phase separation for the SLBs at these intermediate compositions of cholesterol (Fig. S6, SI). The mean lipid diffusivity, D (refer Eq. S3 in SI), decreased in bilayers going from DOPC (highest) to DMPC (lowest) for a given cholesterol concentration and generally decreased linearly with increasing cholesterol concentration for a given lipid consistent with earlier measurements42. The generally accepted phase diagram for binary systems at intermediate cholesterol concentrations indicate a co-existence of L d and L o phases43, 44. Although we do not find any evidence of coexisting phases in our confocal and FCS diffusivity measurements at these concentrations, our results do not necessarily invalidate the proposed thermodynamic phase diagram. It might only indicate that the spatial extent of the co-existing phases if present lies below the detection limits of the optical techniques used in our measurements. The absence of distinct phase separation into L o and L d phases in our images has been recently proposed as an alternative to the traditional co-existence view17, 45. This picture is largely consistent with reports for DOPC and POPC membranes with cholesterol where phase co-existence was not detected using pulse field gradient, NMR diffusivity measurements46, 47 with only a weak diffusivity contrast observed around 300 K for DMPC. Most of the studies which determine phase diagrams are based on measurements which do not have spatial resolution and domains if present are estimated to lie below the optical detection limit46. Further, optical microscopy measurements which reveal the co-existing phases at this composition and measurement temperature used in our study are absent.
On the other hand for SLBs with 50% cholesterol the situation changes dramatically and both confocal and STED images (Fig. 1), reveal the appearance of domain formation on the scale of 200–600 nm in these bilayers, distinctly visible in both DOPC and DMPC systems (see line profile analyses, Fig. S7a–c, SI), while it is much weaker in POPC. Various studies suggest that most lipid bilayers at such high cholesterol content should be in a homogeneous L o phase45, 48. However, there are also reports which suggest the presence of cholesterol induced microstructure in the L o phase at high cholesterol content31, 49 before the onset of crystallization. Nevertheless, a bimodal distribution of lipid diffusivities, emerge in these SLBs as revealed by confocal FCS (Fig. 1G–L). The difference in diffusivities between the two emerging sub-populations is larger for the symmetric (two long fatty acid chains with equal number of carbon atoms, C n ) lipids DOPC (C 18) and DMPC (C 14) when compared with the asymmetric POPC (unequal number of carbon atoms in fatty acid chain, C 18 and C 16) where the sub-populations are not clearly separated.
Since domain formation is driven by the addition of cholesterol, it is reasonable to expect an inhomogeneous distribution of cholesterol in the two emerging populations at 50% cholesterol. Based on the values of the lipid diffusivities, D we identify and henceforth refer to the high D regions as F while the low D regions will be called S. For DOPC, F corresponds to cholesterol poor regions (regions II in Fig. 1) while for DMPC, F corresponds to cholesterol rich regions (regions I in Fig. 1). This distinction is not that easily identifiable for POPC but tentatively regions I corresponds to F for POPC. In addition we would also like to point out that the Atto488-PE as the fluorescent dye marker for our bilayer membranes does not partition exclusively to cholesterol rich or cholesterol poor phases. Complementary cholesterol extraction experiments with β-cyclodextrin (CD) (see Figs S8–10, SI) clearly shows a differential extraction rate for cholesterol from the regions S and F, supporting our conclusions that these phases correspond to cholesterol-rich and cholesterol-poor regions respectively for DOPC and vice versa for DMPC. Additionally, at a low cholesterol content (25%) depletion of cholesterol is faster for DOPC and moderate for DMPC bilayers (cf. Figs S9 a and S11, SI) suggesting that cholesterol reorganization and binding is a function of phospholipid-cholesterol interactions. To summarize our observations from microscopy images and FCS data in confocal mode with a spatial resolution of ~200 nm, we observe large scale (200–600 nm, cf. Fig. S7d–f, SI) heterogeneities in membrane lipid dynamics for the highest cholesterol concentration of 50%. At all concentration below this, the membrane appear largely homogeneous in imaging and unimodal diffusivity in confocal based measurement. Further, we would like to point out that the highest concentration of cholesterol studied in our work is well below the solubility limit of cholesterol for two-component binary phospholipid-cholesterol mixtures. It has also been suggested that a solubility limit of cholesterol in DOPC bilayers is 0.6713, 50, 51, above which cholesterol precipitates as monohydrate crystals52, or forms immiscible cholesterol bilayer domains53 due to demixing. The possibility of demixing can be discarded due to the fact that there is no large scale domain or crystallite formation observed in our bilayers as evidenced from differential interference contrast (DIC) image (see Fig. S12, SI).
We have recently shown that incubation of binary phospholipid-cholesterol model bilayers with cholesterol dependent pore-forming proteins, Listeriolysin O (LLO), at lower cholesterol concentration (below 50%), leads to appearance of dynamically heterogeneous nanoscale proteo-lipid domains39. The formation of such nanoscale domains is induced by the affinity for cholesterol with the LLO protein and mediated by cholesterol reorganization in the membranes. However, is it possible that such domains can exist even in the absence of proteins driven simply by the enhanced concentration of cholesterol? In other words, is protein a necessary component in membranes for the appearance of nanoscale dynamical heterogeneity or can they emerge as a consequence of cholesterol-phospholipid interactions above a threshold cholesterol concentration in a two-component phospholipid-cholesterol bilayer.
Spatially resolved lipid dynamics at low cholesterol concentration using STED-FCS
For this purpose, we performed FCS in super-resolution STED mode40 by varying the STED excitation power to reduce the observation volume to well below the diffraction limit (<200 nm). The calibration of focal spot diameters (d) were made from the STED-FCS measurements of the Atto488-PE fluorescent lipid in supported pristine DOPC lipid bilayers (SI). Pristine refers to a pure lipid bilayer without cholesterol which is not expected to show any anomalous dynamics. Figure 2 describes the dependence of the transit time τ D as a function of the observation diameter (d), as extracted from the respective STED power dependent auto-correlation data of pristine phospholipid and phospholipid-cholesterol binary mixture bilayers. The power dependent correlation data reflects the nature of diffusion of lipids in the bilayer membrane corresponding to this length scale, d. The variation of τ D with d 2 can provide insight into the underlying diffusion mechanism in the system54,55,56,57,58. The transit time,
where, d is the diameter of the confocal or STED focal spot, D eff is an effective diffusion coefficient and t 0 is the intercept. For Brownian diffusion t 0 = 0, and D eff = D. The diffusion coefficient, D eff , can be obtained from the slope of the τ D vs d 2 data and is tabulated in Table 1 using Eq. 1. Non-zero values of t 0 (positive or negative) have been connected to various non-Brownian mechanisms due to hindered diffusion involving presence of fluid-like nanodomains, meshwork structure or gel-like nanodomains59,60,61,62,63. The domain size, ω can be estimated by setting d = ω for τ D = 0 in Eq. 1. This leads to a valid domain size only when t 0 < 0 from Eq. 2 62,
While t 0 > 0 is indicative of an underlying hindered diffusion mechanism, estimating the domain size in this regime is not straightforward. Hence we only provide domain size estimates for t 0 < 0. Nevertheless, t 0 < 0 could also describe meshwork-like diffusion, which is however unrealistic in a two-component system as described before63. For DOPC bilayers (Fig. 2A), τ D increases with increase in cholesterol content for all values of d 2 reflecting the lower values of D with increasing cholesterol content. Up to 25% cholesterol (open red circles) Brownian lipid diffusion was observed for all length scales (d). In contrast, for 33% cholesterol containing DOPC bilayers (open blue circles), a dynamical crossover is observed at a length scale, ξ ≃ 120 nm. Although similar dynamical crossover phenomenon was observed in our earlier work38 with DOPC:Chl(3:1) bilayers incubated with pore forming proteins, this is a unique observation of such crossover behavior in binary DOPC-cholesterol membranes. Above ξ, lipid dynamics corresponds to free diffusion (t 0 = 0) while below this length scale the positive value of t 0 (~0.2) suggests the emergence of hindered lipid diffusion due to the presence of dynamically partitioning nanodomains54, 59,60,61. In contrast for POPC bilayers, we observed Brownian diffusion (Fig. 2B) for all cholesterol concentrations up to 33% cholesterol, for all d, indicating the absence of any substructures at least above the lowest length scale (80 nm) sampled in our STED-FCS experiments. For the case of pristine and 25% cholesterol containing DMPC bilayers (red open circle), the diffusion is Brownian. We note that τ D values for pristine DMPC are always higher than the pristine DOPC and POPC bilayers irrespective of any STED power, indicating the lowered gel-like diffusivities (Fig. S6, SI) in DMPC when compared with the more fluid-like DOPC and POPC bilayers at the measurement temperature. However, at 33% cholesterol (open blue circle), a distinct dynamical crossover at ξ =103 nm was observed for the DMPC bilayer. Unlike the case of DOPC, free Brownian diffusion is not observed in either of the regimes, above and below ξ, and t 0 values were found to be 0.26 and 0.9, respectively.
Unravelling intra-domain lipid dynamics at high cholesterol concentration
At 50% cholesterol concentration (Fig. 3A–C), we observe two dynamically distinct regions referred to as S and F (Fig. 1) for all the lipids, with the distinction being the strongest for DOPC and the least for POPC. STED-FCS allows us to compare and differentiate between the lipid dynamics in these dynamically distinct regions which manifest at length scales of 100 nm or less. The length scale dependent transit time data for DOPC (cf. Fig. 3A, closed symbol) in the domain I (S) reveals a distinct crossover at, ξ = 160 nm above which the intercept is negative (t 0 = −2.27) while for d 2 values below ξ a positive intercept (t 0 = 0.29) is observed. Thus in both regimes Brownian diffusion is not observed. The length scale at which dynamical heterogeneity, as revealed by the crossover, is clearly enhanced when compared with the 33% DOPC cholesterol bilayer. The very large negative intercept which has been observed earlier in lipid bilayer membranes has usually been associated with hindered lipid dynamics in the presence of a meshwork54, 59,60,61. However this situation has also been attributed to dynamics due to gel-like domains62, 63 which is the more relevant interpretation for the supported bilayer platforms used in this study. These observations are quite unique since both dynamical regimes show hindered diffusion. In contrast for region II (F), which from our images appear to represent the majority fraction (Fig. 1), the overall dynamics is closer to Brownian with a weak crossover observed at 142 nm, which is smaller than the crossover observed for region S. Significantly the STED-FCS data reveals for the first time distinct intra-domain lipid dynamics with strong heterogeneity in the cholesterol enriched region S and expectedly, more uniform and fluid-like dynamics in the region F, due to nanodomain partitioning. STED-FCS thus reveals this unique nanodomain dynamical texture within dynamically distinct regions, in an otherwise fluid phospholipid bilayer, which has not been observed thus far with various strategies for spot variation FCS.
Contrast this behavior with that observed for POPC:Chl (1:1) bilayers shown in Fig. 3B. Consistent with the confocal FCS observations of a small difference in mean lipid D (Fig. 1K) the τ d values in region I (F) and II (S) are similar at larger d 2. However significant differences emerge upon reducing d 2. More interestingly, region II (S) shows almost free Brownian diffusion over the entire range of observable d 2, in our experiments, whereas region I (F) shows evidence of hindered diffusion and heterogeneous dynamics with a strong crossover at ξ = 127 nm. Further, t 0 is negative, suggestive of lipid dynamics in gel-like domains, above ξ = 127 nm, while it exhibits a small but finite positive value for t 0 below this length scale which is indicative of small deviation from free diffusion due to dynamically partitioning domains60, 62. In contrast in region S only a weak dynamical crossover is observed at ξ = 148 nm. This is also opposite to what was observed for DOPC bilayers.
For DMPC bilayers, on the other hand, Fig. 3C shows that both regions I (F) and II (S) exhibits distinct dynamical crossovers. In region F, Brownian diffusion is observed above ξ ≃ 150 nm and shows nanodomain mediated hindered diffusion below this length scale. In region S, a strong dynamical crossover at ξ = 142 nm separates regions having negative intercept of t 0 = −1.77, corresponding to lipid dynamics in gel-like regions (ω ~ 97 nm) followed by dynamics in more permeable nanodomains below this length scale ξ. The various parameters obtained from analysis of the STED-FCS data, for the 50% cholesterol containing lipid bilayers is summarized in Table 1. In cases where t 0 > 0 it is not possible to extract domain sizes, ω, either using Eq. 2 or using the dynamical crossover length scale, to free diffusion, for smaller values of d 2. What is significant is the unique observation of dynamical crossovers at length scales ranging from 100–150 nm which is enabled by our STED-FCS measurements including cases where the dynamics does not correspond to free diffusion in either regime. To our knowledge such dynamical anomalies have not been observed earlier with any mode of FCS measurements.
In order to check whether these observed dynamical heterogeneities are caused by pinning of lipids due to inherent substrate effects we carried out similar measurements (cf. Figs S13–16, SI) on polymer cushioned bilayer platforms which have been widely used in the supported bilayer literature64, 65. In our study, we have used poly(acrylic acid) (PAA) which is routinely used as a polymer cushion. In the polymer cushioned bilayers, we observed qualitatively similar morphology and lipid dynamics with distinct crossover phenomena (cf. Fig. S16, SI) as reported for the supported bilayers prepared on uncushioned substrates.
Discussion
In this work, we studied cholesterol concentration dependent nanoscale heterogeneity directed by the interplay of cholesterol concentration and phospholipid properties in minimal two-component phospholipid-cholesterol bilayers. Our STED-FCS results below the diffraction limit (<200 nm) provide crucial insights toward the length scale dependent diffusion crossover due to the presence of substructures at higher cholesterol content. Domain formation as visualized by confocal microscopy images are pronounced for symmetric DOPC and DMPC lipids when compared with the asymmetric POPC lipid. POPC is known46 to partition cholesterol to a lesser extent due to the presence of single saturated tail42. As a consequence cholesterol organization and domain formation is reduced with POPC when compared to the symmetric lipids, DOPC and DMPC. While we do not study dynamics of a “single” nanodomain (of dimension ~100 nm or less) when we sample lipid dynamics within a macrodomain of dimensions ~200–600 nm or more, in the absence of heterogeneity one would expect the diffusion to be Brownian at all length scales. However, depending on cholesterol and lipid composition we indeed find different values of lipid diffusivities at different length scales indicating inherent heterogeneity of lipid dynamics driven by the local environment/viscosity etc. Recent MD simulations33 of single component DPPC membranes suggests that dynamic heterogeneity and nanodomain formation can be driven by density correlations akin to supercooled liquids, and can occur in the absence of critical fluctuations or inherent compositional heterogeneity commonly associated as a requirement for domain formation and dynamic heterogeneity. Significantly, there are no reports of nanoscale domain formation or dynamic heterogeneity in fluid phase or liquid crystalline bilayers.
Using STED-FCS we establish the conditions for onset of nanodomains with clearly quantified length scales below the optical diffraction limit in simple cholesterol-phospholipid bilayers. The emergence of nanoscale heterogeneity and the length scales at which this occurs is a strong function of the cholesterol content. At 25% cholesterol we do not detect the presence of dynamic heterogeneity in any of the lipid bilayers investigated. However at 33% we observe the emergence of weak nanoscale dynamical heterogeneity only in STED-FCS mode for DOPC and DMPC bilayers, but not for POPC. Hence the measured dynamical crossover length scales, ξ, for DOPC and DMPC, provides direct evidence for the existence of such dynamical nanodomains in bilayer membranes even in a situation where there is no manifestation of macro-phase separation. Thus, the STED-FCS data at the lower cholesterol concentrations already provides crucial insights about the existence of inherent nanoscale heterogeneity in the lipid dynamics and their dependence on cholesterol-phospholipid interactions1, 14, 32. It is possible that heterogeneity, if present in the case of POPC, might occur at length scales below our instrument resolution of 80 nm or at higher cholesterol concentration. At 33% cholesterol and measured temperatures, DMPC, which is the only high melting lipid investigated in this study, lies in the proximity of L o /L d phase boundary43, 66, 67. Although clear phase separation is not observed in these bilayers, the observed dynamical heterogeneity is possibly connected with this location on the phase diagram. In the case of DOPC where there is no phase co-existence68, 69 the weak nanoscale heterogeneity suggests the formation of nanodomains driven by non-ideal mixing of disordered low melting phospholipids and cholesterol17, 44, 67, 70, 71.
At higher cholesterol concentrations (50%) DOPC and DMPC are expected to lie in the L o part of the phase diagram48. For these bilayers, cholesterol rich and poor domains can be discerned with length scale of 200–600 nm in confocal microscopy as indicated earlier. Lipid saturation is found to play a critical role, with cholesterol rich domains showing slower diffusivity in the DOPC bilayers while cholesterol rich domains in DMPC show an opposite trend with higher diffusivity, compared to their complementary phase in their respective bilayers. The formation of cholesterol rich and poor domains, and their respective nanoscale intra-domain lipid dynamics illustrate the interplay between phospholipid-cholesterol interactions and phospholipid type; stronger interactions with DMPC which leads to greater fluidization in cholesterol rich regions (F) and weaker interactions with DOPC resulting in lower mobility in cholesterol rich regions (S). In POPC even at 50% cholesterol concentration macroscale domain formation is not expected and this is consistent with the absence of regions with well separated lipid mobilities in confocal FCS as observed for DOPC and DMPC. However in STED-FCS we not only find strong evidence of the presence of two populations of lipid mobilities as the probe volume is reduced below the diffraction limit, we also observe significantly different dynamics in these two populations.
Our study thus reveals that the extent of heterogeneity above an optimal cholesterol concentration is strongly influenced by the physical properties of phospholipid component which dictates lipid re-organisation and microstructure at the nanoscale. Various reports suggest that the role of solid substrates and bilayer preparation methods influence the complex dynamics and phase behavior in bilayer membranes72,73,74,75,76,77. However our results indicates that the observed morphological and dynamical heterogeneity as evidenced from the crossover in diffusion behavior are intrinsic to the lipid bilayer composition and not a function of the underlying substrate (polymer or glass). The absence of direct contact either in uncushioned (presence of ~2–3 nm water layer) or polymer cushioned bilayers, helps mitigate substrate effects for the diffusion measurements. On the contrary, it is worth mentioning that substrate-bilayer interactions may have some similarity to the coupling between the plasma membrane and cytoskeleton matrix in real cells, lending additional support to the use of solid supported bilayers in our study.
While it is widely believed that appearance of L o nanodomains in an L d environment requires the presence of both low and high melting lipids along with cholesterol which is expected to lead to the co-existence of fluid phases, our results establish that neither of these conditions are absolutely necessary for the formation of such domains. In three-component membranes, one would expect a fast diffusion in a homogeneous L d membrane and slow diffusion within a homogeneous L o phase. However in our case, the dynamic heterogeneity (crossover in diffusion behavior) which occurs in both the homogeneous membrane as observed at intermediate cholesterol compositions (33%) and within a homogeneous region (cholesterol rich and poor domains at 50% cholesterol containing membranes) suggests that these are not limited to domain formation. On the other hand, the fact that nanoscale dynamic heterogeneity and domain formation is not connected to phase separation indicates that the origins of the dynamical crossovers could be similar to the dynamic heterogeneity related to caging effects commonly observed in supercooled liquids and glasses78, 79. Further the emergence of these nanoscale heterogeneities could also be attributed to non-ideal lipid mixing67, 80 leading to formation of regions which are otherwise difficult to detect by conventional microscopy methods. In addition, in an alternate model based on a microemulsion perspective81, 82, size estimates of these nanodomains are ~100 nm, which is remarkably similar to the observed values of domains sizes and crossover length scales in our STED-FCS measurements.
Conclusions
In summary, our results reveal the existence of a rich level of nanoscale dynamic heterogeneity even in minimal systems, consisting of two- component phospholipid-cholesterol bilayers. Our STED-FCS results provide, for the first time, direct estimates of the length scale of dynamical nanoscale domains as well as the inherent heterogeneity that exists within these domains themselves. Further, the complexity of nanodomain formation and dynamics is revealed by crossovers between regimes ranging from free to hindered or even between two types of hindered diffusion. Extent of cholesterol partitioning and type of bulk phospholipid properties determines this intra-domain dynamical heterogeneity indicating their intimate correlation. The key results of our work lies in the observation of Brownian and non-Brownian lipid dynamics within these “substructures” in otherwise homogeneous spatial regimes. This non-Brownian dynamics is manifested both in terms of the observation of a non-zero intercept in FCS diffusion law plots, below the diffraction limit, signifying hindered lipid diffusion, as well as clear dynamical crossovers within each of these domains. While the FCS diffusion law anomalies has been attributed to regions of different lipid mobilities, compared to the surrounding, the observation of dynamical crossovers can be interpreted to represent a length scale which separates two regions of distinct lipid dynamics. Further, the observed dynamic heterogeneity observed in this study is independent of the substrate and depends solely on the bulk membrane composition and chemistry. Understanding the underlying dynamics below the diffraction limit in minimal two-component model biomembrane platforms especially at high cholesterol content, will shed light on the sub-structures associated with functional nanodomains present in the real cell membrane. Finally, with the advent of super-resolution gated STED83, 84, where resolutions up to 30 nm are feasible, assessing the complexity due to surface curvature, presence of transmembrane proteins and cytoskeleton effects on the dynamics and assembly of plasma membrane components at the nanoscale will continue to provide novel insights in membrane biology and biophysics.
Materials and Methods
Phospholipids such as DOPC (>99% purity), POPC (>99% purity) and DMPC (>99% purity) and cholesterol (Chl, >98% purity) was obtained from Avanti polar lipids. 3-aminopropyl triethoxysilane (APTES), and 450k MW poly(acrylic acid) (PAA), were purchased from Sigma-Aldrich (USA) and used without further purification. Fluorescent probe 1,2-dimyristoyl-sn-glycero-3-phosphoethanolamine labeled with Atto488 was obtained from ATTO-TEC GmbH, Germany. The lipid solutions (1 mM) were prepared in chloroform (HPLC grade, Sigma Aldrich) and sprayed on the water subphase for the formation of interfacial monolayers. Ultrapure water with a resistivity of 18.2 Ωcm was used as the subphase for all monolayer studies produced by a two-stage Elix-3 and Milli-Q (Millipore Academic) system. Prior to the experiment, the mini trough was cleaned with ethanol (extra pure AR grade, Fine Chemicals, India) several times and finally rinsed with ultra pure water.
Fabrication of supported lipid bilayers
Supported lipid bilayers are prepared by the layer-by-layer transfer (two layers) of lipid monolayers onto a hydrophilic glass (Piranha treated) substrate (20 × 20 mm, Glaswarenfabrik Karl Hecht GmbH and Co KG, Germany); this planar configuration is ideally suited for observation using fluorescence microscopy. To make the bilayer luminescent, dye tagged lipid (Atto488-PE, 5 × 10−4 mol%) was mixed thoroughly with pristine phospholipid or phospholipid-cholesterol mixture before spreading at air-water interface. Multiple compression-expansion cycles of the monolayers are followed at a constant trough temperature of 15 ± 1 °C before the collapse surface pressure. The layer-by-layer transfer of monolayers were transferred at a highly condensed surface pressure of 35 mNm−1. PAA cushioned bilayers were prepared by using the procedure adopted by El-khouri et al.85. In brief, the Piranha treated glass substrates were transferred to a toluene solution of (aminopropyl)triethoxysilane (APTES) with APTES/toluene = 1:50(vol/vol) and were kept at 100 °C for 2 h. The unbound APTES was removed by gently washing with toluene. PAA solution (3 mg/ml) in methanol was then spin coated (2000 rpm, 30 s) and kept for 4 h at 200 °C which induced amide formation between the PAA carboxylic acid and the amine functionality at the surface APTES. The two leaflets of the bilayers were deposited on this PAA cushion layer by using Langmuir-Blodgett/Langmuir-Schaefer (LB/LS) technique. After transfer, the bilayers were always stored under water without exposing to air for further use.
STED-FCS measurement and analysis
For imaging and FCS, we applied STED-FCS nanoscopy using a commercial CW-STED setup (SP5x, Leica Microsystems GmbH, Mannheim, Germany). FCS data acquisition was set for a total duration of 10 s for both confocal- and STED-FCS recordings. The detailed descriptions of analysis are given in SI. At least 30 to 50 independent measurements were made for each sample at different positions and the FCS protocol was repeated for three independent sample sets to confirm the reproducibility of the data.
References
Ikonen, E. Cellular cholesterol trafficking and compartmentalization. Nat. Rev. Mol. Cell Biol. 9, 125–138 (2008).
van Meer, G., Voelker, D. R. & Feigenson, G. W. Membrane lipids: where they are and how they behave. Nat. Rev. Mol. Cell Biol. 9, 112–124 (2008).
Lange, Y. Disposition of intracellular cholesterol in human fibroblasts. J. Lipid Res. 32, 329–339 (1991).
Simons, K. & Ikonen, E. Functional rafts in cell membranes. Nature 387, 569–572 (1997).
Simons, K. & Vaz, W. L. Model systems, lipid rafts, and cell membranes. Annu. Rev. Biophys. Biomol. Struct. 33, 269–295 (2004).
Mukherjee, S. & Maxfield, F. R. Membrane domains. Annu. Rev. Cell Dev. Biol. 20, 839–866 (2004).
Jacobson, K., Mouritsen, O. G. & Anderson, R. G. Lipid rafts: at a crossroad between cell biology and physics. Nat. Cell. Biol. 9, 7–14 (2007).
Pike, L. J. Rafts defined: a report on the Keystone Symposium on Lipid Rafts and Cell Function. J. Lipid Res. 47, 1597–1598 (2006).
Shimshick, E. J. & McConnell, H. M. Lateral phase separations in binary mixtures of cholesterol and phospholipids. Biochem. Biophys. Res. Commun. 53, 446–451 (1973).
Rubenstein, J. L., Smith, B. A. & McConnell, H. M. Lateral diffusion in binary mixtures of cholesterol and phosphatidylcholines. Proc. Natl Acad. Sci. USA 76, 15–18 (1979).
Radhakrishnan, A. & McConnell, H. M. Electric field effect on cholesterol-phospholipid complexes. Proc. Natl Acad. Sci. USA 97, 1073–1078 (2000).
Martinez-Seara, H., Róg, T., Karttunen, M., Vattulainen, I. & Reigada, R. Cholesterol induces specific spatial and orientational order in cholesterol/phospholipid membranes. PLoS One 5, e11162 (2010).
Alwarawrah, M., Dai, J. & Huang, J. A molecular view of the cholesterol condensing effect in DOPC lipid bilayers. J. Phys. Chem. B 114, 7516–7523 (2010).
Sodt, A. J., Sandar, M. L., Gawrisch, K., Pastor, R. W. & Lyman, E. The molecular structure of the liquid-ordered phase of lipid bilayers. J. Am. Chem. Soc. 136, 725–732 (2014).
Javanainen, M., Martinez-Seara, H. & Vattulainen, I. Nanoscale membrane domain formation driven by cholesterol. Sci. Rep. 7, 1143 (2017).
Elson, E. L., Fried, E., Dolbow, J. E. & Genin, G. M. Phase separation in biological membranes: integration of theory and experiment. Annu. Rev. Biophys. 39, 207–226 (2010).
Veatch, S. L. & Keller, S. L. Seeing spots: complex phase behavior in simple membranes. Biochim. Biophys. Acta 1746, 172–185 (2005).
Štefl, M. et al. Dynamics and size of cross-linking-induced lipid nanodomains in model membranes. Biophys. J. 102, 2104–2113 (2012).
Šachl, R. et al. On multivalent receptor activity of GM1 in cholesterol containing membranes. Biochim. Biophys. Acta. 1853, 850–857 (2015).
Shi, J. et al. GM1 clustering inhibits cholera toxin binding in supported phospholipid membranes. J. Am. Chem. Soc. 129, 5954–5961 (2007).
Jacobson, K., Mouritsen, O. G. & Anderson, R. G. Lipid rafts: at a crossroad between cell biology and physics. Nat. Cell Biol. 9, 7–14 (2007).
Rothberg, K. G. et al. Caveolin, a protein component of caveolae membrane coats. Cell 68, 673–682 (1992).
Janmey, P. A. & Lindberg, U. Cytoskeletal regulation: rich in lipids. Nat. Rev., Mol. Cell Biol. 5, 658–666 (2004).
Epand, R. M. et al. An apolipoprotein AI mimetic peptide: membrane interactions and the role of cholesterol. Biochemistry 43, 5073–5083 (2004).
Wu, H.-M., Lin, Y.-H., Yen, T.-C. & Hsieh, C.-L. Nanoscopic substructures of raft-mimetic liquid-ordered membrane domains revealed by high-speed single-particle tracking. Sci. Rep. 6, 20542 (2016).
Spillane, K. M. et al. High-speed single-particle tracking of GM1 in model membranes reveals anomalous diffusion due to interleaflet coupling and molecular pinning. Nano Lett. 14, 5390–5397 (2014).
Ashrafzadeh, P. & Parmryd, I. Methods applicable to membrane nanodomain studies? Essays Biochem. 57, 57–68 (2015).
Belička, M., Weitzerab, A. & Pabst, G. High-resolution structure of coexisting nanoscopic and microscopic lipid domains. Soft Matter 13, 1823–1833 (2017).
de Wit, G., Danial, J. S. H., Kukura, P. & Wallace, M. I. Dynamic label-free imaging of lipid nanodomains. Proc. Natl. Acad. Sci. USA 112, 12299–12303 (2015).
Armstrong, C. L., Häussler, W., Seydel, T., Katsaras, J. & Rheinstädter, M. C. Nanosecond lipid dynamics in membranes containing cholesterol. Soft matter 10, 2600–2611 (2014).
Mainali, L., Raguz, M. & Subczynski, W. K. Formation of cholesterol bilayer domains precedes formation of cholesterol crystals in cholesterol/dimyristoylphosphatidylcholine membranes: EPR and DSC studies. J. Phys. Chem. B 17, 8994–9003 (2013).
Meinhardt, S., Vink, R. L. C. & Schmid, F. Monolayer curvature stabilizes nanoscale raft domains in mixed lipid bilayers. Proc. Natl Acad. Sci. USA 110, 4476–4481 (2013).
Shafique, N., Kennedy, K. E., Douglas, J. F. & Starr, F. W. Quantifying the heterogeneous dynamics of a simulated dipalmitoylphosphatidylcholine (DPPC) membrane. J. Phys. Chem. B 120, 5172–5182 (2016).
Ehrig, J., Petrov, E. P. & Schwille, P. Near-critical fluctuations and cytoskeleton-assisted phase separation lead to subdiffusion in cell membranes. Biophys. J. 100, 80–89 (2011).
Schick, M. Membrane heterogeneity: Manifestation of a curvature-induced microemulsion. Phy. Rev. E 85, 031902 (2012).
Hell, S. W. Microscopy and its focal switch. Nat. Methods 6, 24–32 (2009).
Honigmann, A. et al. Scanning STED-FCS reveals spatiotemporal heterogeneity of lipid interaction in the plasma membrane of living cells. Nat. Commun. 5, 5412 (2014).
Sarangi, N. K., Ilanila, I. P., Ayappa, K. G., Visweswariah, S. S. & Basu, J. K. Super-resolution stimulated emission depletion-fluorescence correlation spectroscopy reveals nanoscale membrane reorganization induced by pore-forming proteins. Langmuir 32, 9649–9657 (2016).
Sarangi, N. K., Ayappa, K. G., Visweswariah, S. S. & Basu, J. K. Nanoscale dynamics of phospholipids reveals optimal assembly mechanism of pore-forming proteins in bilayer membranes. Phys. Chem. Chem. Phys. 18, 29935–29945 (2016).
Eggeling, C. et al. Direct observation of the nanoscale dynamics of membrane lipids in a living cell. Nature 457, 1159–1162 (2009).
Mueller, V. et al. STED nanoscopy reveals molecular details of cholesterol- and cytoskeleton-modulated lipid interactions in living cells. Biophys J 101, 1651–1660 (2011).
Kahya, N. & Schwille, P. How phospholipid-cholesterol interactions modulate lipid lateral diffusion, as revealed by fluorescence correlation spectroscopy. J Fluoresc 16, 671–678 (2006).
Marsh, D. Liquid-ordered phases induced by cholesterol: A compendium of binary phase diagrams. Biochim. Biophys. Acta 1798, 688–699 (2010).
Suga, K. & Umakoshi, H. Detection of nanosized ordered domains in DOPC/DPPC and DOPC/Ch binary lipid mixture systems of large unilamellar vesicles using a TEMPO quenching method. Langmuir 29, 4830–4838 (2013).
Schmid, F. Physical mechanisms of micro-and nanodomain formation in multicomponent lipid membranes. Biochim Biophys Acta 1859, 509–528 (2017).
Filippov, A., Orädd, G. & Lindblom, G. The effect of cholesterol on the lateral diffusion of phospholipids in oriented bilayers. Biophys J. 84, 3079–3086 (2003).
Lindblom, G. & Orädd, G. Lipid lateral diffusion and membrane heterogeneity. Biochim Biophys Acta. 1788, 234–44 (2009).
de Almeida, R. F. M. & Joly, E. Crystallization around solid-like nanosized docks can explain the specificity, diversity, and stability of membrane microdomains. Front Plant Sci. 5, 72 (2014).
Honerkamp-Smith, R. et al. Line tensions, correlation lengths, and critical exponents in lipid membranes near critical points. Biophys J. 95, 236–246 (2008).
Parker, A., Miles, K., Cheng, K. H. & Huang, J. Lateral distribution of cholesterol in dioleoylphosphatidylcholine lipid bilayers: cholesterol-phospholipid interactions at high Cholesterol Limit. Biophys J. 86, 1532–1544 (2004).
Ali, M. R., Cheng, K. H. & Huang, J. Assess the nature of cholesterol–lipid interactions through the chemical potential of cholesterol in phosphatidylcholine bilayers. Proc. Natl. Acad. Sci. USA 104, 5372–5377 (2007).
Huang, J. & Feigenson, G. W. A microscopic interaction model of maximum solubility of cholesterol in lipid bilayers. Biophys J. 76, 2142–2157 (1999).
Subczynski, W. K., Raguz, M., Widomska, J., Mainali, L. & Konovalov, A. Functions of cholesterol and the cholesterol bilayer domain specific to the fiber-cell plasma membrane of the eye Lens. J Membr Biol. 245, 51–68 (2012).
Macháň, R. & Hof, M. Lipid diffusion in planar membranes investigated by fluorescence correlation spectroscopy. Biochim Biophys Acta 1798, 1377–1391 (2010).
Basit, H., Lopez, S. G. & Keyes, T. E. Fluorescence correlation and lifetime correlation spectroscopy applied to the study of supported lipid bilayer models of the cell membrane. Methods 68, 286–299 (2014).
Ganguly, S. & Chattopadhyay, A. Cholesterol depletion mimics the effect of cytoskeletal destabilization on membrane dynamics of the serotonin1A receptor: A zFCS study. Biophys J. 99, 1397–1407 (2010).
Bag, N., Ng, X. W., Sankaran, J. & Wohland, T. Spatiotemporal mapping of diffusion dynamics and organization in plasma membranes. Methods Appl. Fluoresc. 4, 034003 (2016).
Huang, H., Simsek, M. F., Jin, W. & Pralle, A. Effect of receptor dimerization on membrane lipid raft structure continuously quantified on single cells by camera based fluorescence correlation spectroscopy. PLoS ONE 10, e0121777 (2015).
Wawrezinieck, L., Rigneault, H., Marguet, D. & Lenne, P. F. Fluorescence correlation spectroscopy diffusion laws to probe the sub-micron cell membrane organization. Biophys J. 89, 4029–4042 (2005).
He, H. T. & Marguet, D. Detecting nanodomains in living cell membrane by fluorescence correlation spectroscopy. Annu. Rev. Phys. Chem. 62, 417–436 (2011).
Lenne, P. F. et al. Dynamic molecular confinement in the plasma membrane by microdomains and the cytoskeleton meshwork. EMBO J. 25, 3245–3256 (2006).
Favard, C., Wenger, J., Lenne, P. F. & Rigneault, H. FCS diffusion laws in two-phase lipid membranes: determination of domain mean size by experiments and Monte Carlo simulations. Biophys J. 100, 1242–1251 (2011).
Wachsmuth, M., Waldeck, W. & Langowski, J. Anomalous diffusion of fluorescent probes inside living cell nuclei investigated by spatially-resolved fluorescence correlation spectroscopy. J. Mol. Biol. 298, 677–689 (2000).
Czolkos, I., Jesorka, A. & Orwar, O. Molecular phospholipid films on solid supports. Soft Matter 7, 4562–4576 (2011).
Andersson, J. & Köper, I. Tethered and polymer supported bilayer lipid membranes: structure and function. Membranes 6, 30 (2016).
Almeida, P. F. F., Vaz, W. L. C. & Thompson, T. E. Lateral diffusion in the liquid phases of dimyristoylphosphatidylcholine/cholesterol lipid bilayers: a free volume analysis. Biochemistry 31, 6739–6747 (1992).
Almeida, P. F. F. Thermodynamics of lipid interactions in complex bilayers. Biochim. Biophys. Acta 1788, 72–85 (2009).
Pommella, A., Brooks, N. J., Seddon, J. M. & Garbina, V. Selective flow-induced vesicle rupture to sort by membrane mechanical properties. Sci Rep. 5, 13163 (2015).
Kahya, N. & Schwille, P. Fluorescence correlation studies of lipid domains in model membranes. Mol Membr Biol. 23, 29–39 (2006).
Lagane, B., Mazères, S., Le Grimellec, C., Cézanne, L. & Lopez, A. Lateral distribution of cholesterol in membranes probed by means of a pyrene-labelled cholesterol: effects of acyl chain unsaturation. Biophys Chem. 95, 7–22 (2002).
McConnell, H. M. & Radhakrishnan, A. Condensed complexes of cholesterol and phospholipids. Biochim Biophys Acta. 1610, 159–173 (2003).
Scomparin, C., Lecuyer, S., Ferreira, M., Charitat, T. & Tinland, B. Diffusion in supported lipid bilayers: Influence of substrate and preparation technique on the internal dynamics. Eur. Phys. J. E 28, 211–220 (2009).
Sterling, S. M., Dawes, R., Allgeyer, E. S., Ashworth, S. L. & Neivandt, D. J. Comparison of actin- and glass-Supported phospholipid bilayer diffusion coefficients. Biophys. J. 108, 1946–1953 (2015).
Fujimoto, T. & Parmryd, I. Interleaflet coupling, pinning, and leaflet asymmetry—major players in plasma membrane nanodomain formation. Front. Cell Dev. Biol. 4, 155 (2017).
Garg, S., Rühe, J., Lüdtke, K., Jordan, R. & Naumann, C. A. Domain registration in raft-mimicking lipid mixtures studied using polymer-tethered lipid bilayers. Biophys. J. 92, 1263–1270 (2007).
Goksu, E. I. & Longo, M. L. Ternary lipid bilayers containing cholesterol in a high curvature silica xerogel environment. Langmuir 26, 8614–8624 (2010).
Seeger, H. M., Di Cerbo, A., Alessandrini, A. & Facci, P. Supported lipid bilayers on mica and silicon oxide: comparison of the Main phase transition behavior. J. Phys. Chem. B 114, 8926–8933 (2010).
Ediger, M. D., Angell, C. A. & Nagel, S. R. Supercooled liquids and glasses. J. Phys. Chem. 100, 13200–13212 (1996).
Ediger, M. D. & Harrowell, P. Perspective: Supercooled liquids and glasses. J. Chem. Phys. 137, 080901 (2012).
Ackerman, D. G. & Feigenson, G. W. Lipid bilayers: clusters, domains and phases. Essays Biochem. 57, 33–42 (2015).
Schick, M. Membrane heterogeneity: manifestation of a curvature-induced microemulsion. Phys. Rev. E Stat. Nonlin. Soft Matter Phys. 85, 031902–031904 (2012).
Shlomovitz, R., Maibaum, L. & Schick, M. Macroscopic phase separation, modulated phases, and microemulsions: a unified picture of rafts. Biophys J. 106, 1979–1985 (2014).
Vicidomini, G. et al. STED nanoscopy with time-gated detection: theoretical and experimental aspects. PLoS One. 8, e54421 (2013).
Vicidomini, G. et al. Sharper low-power STED nanoscopy by time gating. Nat Methods. 8, 571–573 (2011).
El-Khouri, R. J. et al. pH responsive polymer cushions for probing membrane environment interactions. Nano Lett. 11, 2169–2172 (2011).
Acknowledgements
The authors thank the Department of Science and Technology, New Delhi, India for the financial support through a special project (DST-IRHPA). N.K.S. acknowledges the Dr. D.S. Kothari Post doctoral fellowship from UGC, Govt. of India.
Author information
Authors and Affiliations
Contributions
K.G.A. and J.K.B. designed the research; N.K.S. executed the experiment(s), collected and analyzed the data and discussed with J.K.B. and K.G.A.; and J.K.B., K.G.A. and N.K.S. wrote the paper.
Corresponding authors
Ethics declarations
Competing Interests
The authors declare that they have no competing interests.
Additional information
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Sarangi, N.K., Ayappa, K.G. & Basu, J.K. Complex dynamics at the nanoscale in simple biomembranes. Sci Rep 7, 11173 (2017). https://doi.org/10.1038/s41598-017-11068-5
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-017-11068-5
- Springer Nature Limited
This article is cited by
-
Nanomechanical properties of cholesterol-rich domains in mica-supported unsaturated lipid bilayer: an atomic force microscopy study
Bulletin of Materials Science (2023)
-
Measuring nanoscale diffusion dynamics in cellular membranes with super-resolution STED–FCS
Nature Protocols (2019)
-
Applications of STED fluorescence nanoscopy in unravelling nanoscale structure and dynamics of biological systems
Journal of Biosciences (2018)