Abstract
The actin nodule is a novel F-actin structure present in platelets during early spreading. However, only limited detail is known regarding nodule organization and function. Here we use electron microscopy, SIM and dSTORM super-resolution, and live-cell TIRF microscopy to characterize the structural organization and signalling pathways associated with nodule formation. Nodules are composed of up to four actin-rich structures linked together by actin bundles. They are enriched in the adhesion-related proteins talin and vinculin, have a central core of tyrosine phosphorylated proteins and are depleted of integrins at the plasma membrane. Nodule formation is dependent on Wiskott–Aldrich syndrome protein (WASp) and the ARP2/3 complex. WASp−/− mouse blood displays impaired platelet aggregate formation at arteriolar shear rates. We propose actin nodules are platelet podosome-related structures required for platelet–platelet interaction and their absence contributes to the bleeding diathesis of Wiskott–Aldrich syndrome.
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Introduction
The actin cytoskeleton plays an important role in many processes in platelets and their precursor cell the megakaryocyte1,2. Actin is essential for the maintenance of platelet morphology and for the rapid change in shape following platelet activation. Actin also regulates platelet surface glycoprotein signalling and thrombus stability3,4,5,6,7,8. In the megakaryocyte, actin plays a critical role in the formation of proplatelets and in mediating degradation of the extracellular matrix (ECM) at sites of podosome formation9,10,11,12.
The actin cytoskeleton is assembled into a wide variety of structures including filopodia, lamellipodia, stress-fibres, podosomes, spreading initiation centres (SICs) and actin comets13,14,15,16,17,18. These structures perform various functions and are regulated by a mixture of common and specific pathways. For example, in platelets, severing and uncapping of actin filaments by gelsolin19 provides free filament ends for ARP2/3 complex dependent actin polymerization leading to a rapid increase in the F-actin content of platelets19. Regulation and organization of ARP2/3-dependent polymerization occurs downstream of members of the Rho GTPases and nucleation promoting factors (NPFs). This is illustrated in platelets by the critical role of Rac1 in lamellipodia formation downstream of both tyrosine kinase and G protein-coupled receptors4,20. In contrast, the signalling pathway to platelet filopodia formation is unclear with contradictory results from different Cdc42-knockout mouse studies. Pleines et al.21 used a platelet and megakaryocyte-specific Cdc42 knockout to demonstrate that this GTPase contributed to filopodia formation downstream of the von Willebrand receptor complex, GPIb-IX-V, but was dispensable for filopodia formation on fibrinogen, which binds to integrin αIIbβ3. In contrast, Akbar et al.22 showed Cdc42 was required for filopodia on fibrinogen and collagen. Furthermore, Rif, another Rho GTPase, which has been shown to be important for generating filopodia in other cells, is dispensable for platelet filopodia formation23. Thus, there are cell- and agonist-specific pathways of regulation of actin-based structures.
Recently, we have characterized two specialized actin structures in megakaryocytes and platelets, namely podosomes and nodules, respectively12,24. Podosomes are actin structures that were originally described in osteoclasts and monocytic cells25. They are short-lived, F-actin structures enriched in integrins, Src family kinases (SFK) and the ARP2/3 complex, which are regulated by the activity of Wiskott–Aldrich syndrome protein (WASp). Protein localization is tightly regulated in podosomes and underlies the distinctive structure of an F-actin, ARP2/3 and WASp core surrounded by an integrin, talin and vinculin ring16. We have shown that podosomes are required for megakaryocytes to degrade basement membranes enabling proplatelets to reach the bloodstream and form platelets17. We speculate that loss of podosome formation may contribute to the reduced count and altered size of platelets in patients with Wiskott–Aldrich syndrome (WAS). However, this alone is unlikely to explain the marked bleeding diathesis in WAS, as individuals with similar platelets counts do not exhibit excessive bleeding.
The actin nodule is a novel actin structure found in platelets during early adhesion and spreading on multiple ECM proteins24. Nodules are absent in fully spread platelets where the F-actin is rearranged into stress-fibres. Like podosomes, they are F-actin-rich structures that are dependent on actin polymerization and SFK activity. They contain multiple signalling, actin-binding and adhesion proteins, including Fyn, Rac1, ARP2/3 and integrins. The rapid and early formation of nodules and their absence in fully spread platelets led us to previously speculate that they may play a role in lamellipodia and stress-fibre formation24. There have been no further studies on their regulation since our original report and we know very little about their structural organization and regulation. Nevertheless, the similar composition of nodules and podosomes suggests that they may be related structures and may therefore share a dependency on WASp.
There are two members of the WASp family in the mammalian genome, N-WASp and WASp. N-WASp has a ubiquitous distribution; WASp is restricted to haematopoietic cells26. Patients with function-disrupting mutations or absence of WASp suffer from WAS and display a range of immune cell related phenotypes, microthrombocytopenia and excessive bleeding27. WASp is required for formation of podosomes in megakaryocytes9,12 and in humans this is associated with a defect in platelet count, size and morphology (in mice, although platelet count is reduced, size is not altered in the absence of WASp28). However, it is likely that additional defects contribute to the bleeding diathesis, which is disproportionate to the reduction in platelet count. Although WASp is not required for filopodia formation, it has been shown to be required for normal spreading on fibrinogen and clot retraction29,30,31,32. Thus, it appears that multiple defects contribute to the bleeding diathesis in WAS patients.
The aim of this study is to use state-of-the-art microscopy to characterize the organization of proteins at actin nodules and to determine the role of WASp in their regulation. We use a combination of electron microscopy (EM), structured illumination microscopy (SIM) and direct stochastic optical reconstruction microscopy (dSTORM) super-resolution microscopy, and total internal reflection fluorescence (TIRF) microscopy to monitor nodule formation and organization. Moreover, we demonstrate a key role for WASp in nodule formation in human and mouse platelets and that loss of nodules is associated with impaired platelet adhesion and aggregation at arteriolar shear rates, consistent with a critical role for nodules in adhesive processes. Thus, we provide a possible molecular explanation for the bleeding diathesis observed in WAS and for the role of WASp in platelets, namely in regulating nodule formation.
Results
Actin nodules form an interconnected network in platelets
‘Conventional’ epifluorescent and confocal microscopy have a physical spatial resolution of ∼250 nm in XY and, at best, 500 nm in Z planes due to the diffraction of light through the optics of the microscope. Recently several techniques have been developed to overcome this diffraction limit allowing spatial separation of fluorophores in the order of 10–100 nm in XY (known collectively as super-resolution, reviewed in ref. 33). To investigate the organization of actin and other proteins at the nodule at nanometre resolution, we used SIM and dSTORM on platelets spread on fibrinogen-coated surfaces.
The actin cytoskeleton of human platelets was stained with Alexa488-phalloidin and imaged using SIM, which gives an approximate doubling in XY resolution when compared with diffraction-limited epifluorescence (Supplementary Fig. 1a–c). This analysis revealed that actin nodules form part of an interconnected actin network within spreading human platelets (Fig. 1a). Nodules are interconnected via bundles of actin which radiate from their dense actin core (Fig. 1a and Supplementary Fig. 1d, arrows). SIM further reveals that single nodules imaged in diffraction-limited epifluorescence microscopy consist of between 1–4 bright foci of F-actin (Fig. 1a and Supplementary Fig. 1d, arrowheads). This organization of nodules has been observed in platelets from multiple donors in independent experiments. These images are strikingly similar to scanning EM images of platelet cytoskeletons, which show the actin nodules as closely packed F-actin foci linked by actin fibres (Fig. 1c).
We also spread mouse platelets on fibrinogen, stained with Alexa488-phalloidin and imaged using SIM. This again revealed that actin fibres radiate from individual nodules (arrows in Fig. 1b). Interestingly, while some nodules did appear as multiple foci, in general the mouse actin nodules were smaller than those observed in human and were predominantly found as single actin-structures (Compare Fig. 1b with Fig. 1a and Supplementary Fig. 1d).
Actin nodules link sites of adhesion to the cytoskeleton
To further investigate the structure of nodules, we counterstained human platelets with antibodies against the extracellular portion the αIIb chain of the major platelet integrin αIIbβ3, the actin-binding proteins vinculin and talin or a pan-phosphotyrosine antibody, and analysed them using SIM and dSTORM.
Using SIM the integrin can be seen to form a diffuse lawn over the platelet surface except at actin nodules where it was either absent from the nodule core or concentrated around the outside of the nodule and absent from the core (Fig. 2a and Supplementary Fig. 2). Line scans of fluorescence intensity for both actin and integrin confirms that in the majority of nodules (∼90% of 774 nodules from 78 cells, n=3 experiments) the integrin is depleted from the actin-rich core region (Fig. 2a,b dashed line and Supplementary Fig. 2). Furthermore, ∼50% of platelets also contained some nodules where, in addition to the central depletion, integrin was also enriched at the periphery of the actin core (Fig. 2a,b solid line and Supplementary Fig. 2). These data indicate that either there are subsets of nodules with different patterns of integrin organization or perhaps, more likely, the pattern of integrin distribution at nodules changes over the lifetime of the nodule.
To further resolve the spatial distribution of integrin at the actin nodule, we used dSTORM in TIRF to monitor αIIb on the platelet surface (Fig. 3). This method is able to localize individual molecules with a precision of ∼20 nm33. As before, a lawn of αIIb was observed over the surface of the platelet with clearly defined integrin depleted zones in the centre of the actin nodules (Fig. 3a). Experiments were also performed in which the integrin was labelled after spreading and fixation and these showed the same pattern of integrin staining. This indicated that the depleted region was not due to an unlabelled, internal pool of integrin being brought to the surface during nodule formation. Quantitative cluster mapping, which has been used to analyse the distribution of protein molecules using dSTORM data34, identifies molecules displaying a more clustered distribution than would be expected above random. This is presented as a cluster heatmap with ‘hot’ colours identifying highly clustered molecules (Fig. 3b) with a high L(r) value. Analysis of regions of platelets where there are no nodules shows that αIIb is distributed evenly over the surface of the platelet with no significant clustering as indicated by the prevalence of ‘cold’ colours in the heatmap (Fig. 3b, top row). Binary threshold analysis of the cluster map indicates very few regions of the platelet where there is no integrin present. In comparison, analysis of the integrin distribution at nodules shows that in all cases an integrin depleted-zone is present at the centre of the nodule (Fig. 3b, Middle row). This is in agreement with SIM data (Fig. 2). In addition, some nodules show regions where integrin molecules appear to be clustered adjacent to the depleted zone indicated by ‘hot’ colours in the cluster heat-map (Fig. 3b, bottom row). Together, SIM and dSTORM data indicate that αIIbβ3 is excluded from the platelet surface below the actin nodules and that the pattern of integrin around nodules changes during their lifetime.
To further these studies, we used SIM to investigate the location of additional actin-binding proteins. We focused on talin and vinculin, which are often found at sites of cell adhesion and are associated with podosomes16. SIM revealed that both talin and vinculin are enriched at nodules (Fig. 4a,b), but their distribution is different from that of F-actin. Quantifying the pattern of line scan intensities of actin nodules counterstained with either talin or vinculin into three categories (enriched at nodule periphery; enriched at nodule core; or no obvious enrichment) revealed that 76.4±4.3% and 74.6±9.4% of actin nodules had talin and vinculin, respectively, enriched at their periphery (Fig. 4c; >660 nodules from ≥60 cells, mean±s.d., n=3 experiments for each protein). Similar to the results with integrin, a mixture of patterns of localization was observed within individual platelets, which again may reflect kinetic changes during their lifetime.
Protein phosphorylation is important for platelet signalling with many key proteins being phosphorylated during platelet activation. Since nodules are dynamic structures and SFK activity is required for their formation24 we investigated whether they were signalling hubs using the presence of phosphotyrosine as a marker of signalling. Both SIM (Fig. 5a) and dSTORM (Fig. 5b) showed that small foci of phosphotyrosine activity are seen across the platelet, and that greater than 90% of actin nodules label strongly with the pan-phosphotyrosine antibody 4G10 (Fig. 5a,b; 546 nodules from 45 cells) indicating that they are sites of signalling activity. Quantitative cluster mapping of 25 nodules and 25 non-nodule regions from dSTORM images indicated that the mean area (±s.d.) of clustered phosphotyrosine labelling at the actin nodule is significantly larger (∼10 times) than clusters seen throughout the remainder of the cell (0.065±0.018 μm2 at nodules versus 0.007±0.007 μm2 outside of nodules; cluster threshold L(r)=100, P<0.001, Student’s t-test). Furthermore, there is a significant difference in the molecular density of clustered phosphotyrosine between nodule-associated clusters and the other clusters found throughout the platelet (23,259±10,831 versus 15,130±14,408 fluorescent events detected μm−2; P=0.008, Student’s t-test) (Fig. 5c). Taken together, these data indicate that nodules are sites linking interaction with the ECM and the actin cytoskeleton and are sites of tyrosine phosphorylation-mediated signalling activity. These proteins are also enriched at SICs; however, the absence of key SIC markers at nodules indicates that nodules are distinct from SICs (Supplementary Note 1 and Supplementary Fig. 3).
Actin nodules are dynamic highly regulated structures
The super-resolution data suggest that actin nodules are heterogeneous structures that change their organization over their lifetime. Lifeact-GFP, a 17-amino acid peptide that labels the F-actin cytoskeleton35, can be used to monitor formation of F-actin structures without interfering with either their formation or function36,37. We have carried out several platelet function assays comparing platelets from Lifeact-GFP mice with those from wild-type mice and have found that expression of Lifeact-GFP does not affect their function37 and therefore, we used Lifeact-GFP mouse platelets and TIRF to visualize nodule formation at the cell-matrix interface in real time.
Time-lapse TIRF movies of Lifeact-GFP platelets settling onto fibrinogen-coated glass-bottomed dishes demonstrated that nodules rapidly form as platelets adhere and begin to spread (Fig. 6a and Supplementary Movie 1). Subsequently, the platelets continue to make nodules and filopodia as the cells spread out to form the characteristic spiky appearance of mouse platelets on fibrinogen. The number of actin nodules per mouse platelet increases rapidly in the first 20 s of spreading and then levels off, averaging between four and six nodules per platelet (Fig. 6b). The average diameter (measured at the widest point) of an actin nodule in fixed samples was 0.50±0.12 μm (mean±s.d.) with the majority (>95%) of them in the range 0.25 to 0.62 μm. The median lifetime of an actin nodule was 22.1 s (25% percentile=13.5 and 75% percentile=36.3;>400 nodules) (Fig. 6c).
We analysed the surface area of the nodules over their lifetime to determine whether they change in their appearance. We synchronized the size measurements by recording surface area in the first and last frame that the nodules were present and then at 25, 50 and 75% of their lifetime (Fig. 6d). These data indicated that nodules are fairly uniform in size at appearance and disappearance (surface area at appearance=0.22±0.07 μm2 and at disappearance=0.22±0.07 μm2, mean±s.d.); however, over the course of their lifetime they increase in size by up to 50% at mid-lifetime (0.31±0.09 μm2). This increase was significant compared with that at appearance and disappearance (P<0.001; One way ANOVA & Tukey’s multiple comparison). This change may reflect the ‘flattening’ down of the nodules onto the surface rather than a change in size. We investigated this further by imaging the same actin nodules in both TIRF and Epifluorescence (Supplementary Movie 2). Increased actin polymerization will result in increased fluorescence intensity in both modalities. However, we observed a consistent increase in TIRF intensity above that of Epifluorescence (Fig. 6e) suggesting that the nodules were increasing in size and also moving downwards in Z, and therefore into the higher intensity region of the TIRF evanescent wave38. This movement in Z was quantified by inputting the TIRF intensity values from 118 nodules (n=3 experiments) into equation 4 (ref. 39) to generate the mean (±s.d.) distance moved towards the substrate. This was calculated as 34.6±19.0 nm, which is in the order of the size of integrins40. These data support the hypothesis that nodules both increase in size, due to actin polymerization, and change their position in Z during their lifetime. We also measured the lateral displacement or mobility of individual actin nodules from TIRF timelapses and found all actin nodules are fixed in their location (Supplementary Fig. 4). Together these data indicate that actin nodules are formed rapidly upon platelet activation/adhesion, are tightly controlled in terms of size and lifetime and are immobile in XY but move towards the substrate in Z. These properties are also observed for megakaryocyte podosomes; however, in contrast to podosomes, we have shown that actin nodules do not degrade the fibrinogen matrix (Supplementary Note 2 & Supplementary Fig. 5).
WASp is required for actin nodule formation
Podosome formation in megakaryocytes requires the action of the protein WASp9,12. In view of the similarities to podosomes, we investigated whether nodule formation also requires WASp. Platelets from mouse models either lacking WASp (WASp KO)28, or expressing a mutant form of WASP that has a critical tyrosine-residue mutated rendering it unable to be activated (WASp Y293F) 41, were spread on fibrinogen and stained with phalloidin. Control mouse platelets displayed nodules as previously described (Fig. 7a,b and Supplementary Fig. 6). However, nodules were absent in WASp KO and WASp Y293F platelets, even though adhesion on fibrinogen was not altered and both filopodia and lamellipodia formation was similar to controls (Fig. 7a and Supplementary Fig. 6). Small bright actin foci were occasionally seen, but these were not observed in all cells and had a morphology that was distinct from nodules (Fig. 7a). Measurement of the platelet surface area showed a small (∼10%) but significant reduction in surface area when compared with litter-matched controls (Fig. 7c).
To investigate the role of WASp in actin nodule formation in human platelets, we analysed platelet spreading from two WAS patients. Patient #1 had a c.134 C>T mutation in WASp resulting in a p.T45M missense alteration, which disrupts the interaction with WASp interacting protein (WIP)42. Patient #2 had a c.IVS6+2T>C mutation, which affects splicing and is predicted to give rise to WASp null platelets43,44. Both sets of patient platelets were able to adhere and spread on fibrinogen but actin nodules were absent (Fig. 7d,e). Furthermore, quantification of spreading showed a significant reduction in platelet surface area for patient #2 (WASp null; 21.5±10.5 μm2 versus 25.0±13.2 μm2 for control, P=0.02. Data are mean±s.d. analysed by ANOVA and Tukey’s multiple comparison) and a reduction, albeit non-significant, for patient #1 (22.2±11.7 μm2 versus 25.0±13.2 μm2 for control, P=0.09) (Fig. 7f). Taken together these data indicate that WASp is required for the formation of nodules in both mouse and human platelets and also contributes to spreading.
WASp recruits ARP2/3 complex to form actin nodules
In light of the key role for WASp in nodule formation, we characterized the role of the ARP2/3 complex in actin nodule formation. Pre-treatment of mouse platelets with an inhibitor of ARP2/3 activity completely blocked spreading and actin nodule formation on a fibrinogen-coated surface (Supplementary Fig. 7 and Supplementary Movie 3). Although this indicated that ARP2/3 is required for actin nodule formation, this blockage could result from inhibition of spreading per-se. To understand the interplay between WASp and ARP2/3 in terms of nodule formation, control and WAS patient platelets were labelled for p34, a subunit of the ARP2/3 complex, to determine whether localization was affected in cells which could not make nodules. In control platelets displaying nodules (Fig. 8a, top row), ARP2/3 was seen as small punctate foci throughout the platelet, with larger and more intense foci observed at nodules (Fig. 8a, arrows). However, in WAS patient samples, which did not form nodules, no bright foci of ARP2/3 labelling were observed, whereas the small punctate foci across the platelet appeared unaltered (Fig. 8a, bottom panel). In fully spread human platelets lacking nodules, the pattern of ARP2/3 was the same in both control and WAS patient samples, that is, the small punctate foci of p34 were observed across the platelet with an enrichment of ARP2/3 and actin at the lamellipodia (Fig. 8b, arrows). Taken together these data are consistent with a model in which nodule formation is dependent on the activity of WASp, which recruits and activates ARP2/3 complex. However, ARP2/3 recruitment and activity at other parts of the cell (for example, lamellipodia) is unaffected by the absence of WASp or the presence of functionally inactive WASp.
WASp is required for platelet aggregate formation under flow
We hypothesize that actin nodules are adhesive structures due to their association with integrins and adhesion-related proteins. However, although platelets from WASp KO mice and WAS patients do not have nodules, they display only a mild spreading defect in static adhesion and spreading assays. To further investigate this role in adhesion, we examined whether the absence of WASp impairs platelet adhesion or aggregation under flow conditions. Mouse models of WAS exhibit a reduction in platelet count and a normal platelet size compared with the severe microthrombocytopenia associated with the human disease28,41. The latter prevents interpretation of flow studies on human platelets and so studies were undertaken on WASp-KO platelets. Whole blood from WT and WASp-KO mice was flowed over collagen at a shear rate of 3,000 s−1. While WT platelets adhered and formed the characteristic 3D platelet aggregates (Fig. 9a), WASp-KO platelets were only able to adhere to the collagen surface as monolayers and small aggregates (Fig. 9b and Supplementary Movie 4). Quantification of the surface area covered by the aggregates demonstrates that WASp-KO platelet aggregates covered just under 50% of the surface area of WT controls (Student’s t-Test, P=0.0097, 10 fields of view from n=3 experiments; Fig. 9c). Using fluorescence intensity as a measure of aggregate volume, we confirmed that WASp-KO platelets formed a monolayer and significantly smaller aggregates than WT controls (P=0.0411; Fig. 9d). This effect is specific to a functional defect with the WASp-KO platelets and not due to the reduced platelet count as WT blood with platelet count matched to those of the WASp KO platelets displayed normal aggregate formation at 3,000 s−1 (Supplementary Fig.8). As platelet–platelet interactions appeared to be affected by the absence of WASp, we performed low shear flow (600 s−1) over fibrinogen, which mediates platelet–platelet adhesion (Fig. 9e,f and Supplementary Movie 5). We observed a greater than 50% reduction in adhesion in the WASP KO compared with the WT and those platelets that did adhere were less spread (Fig. 9g,h). Taken together these results support the idea that nodules play a role in both platelet adhesion to the ECM substrate and fibrinogen-mediated platelet-platelet interactions. Thus, this indicates that adhesion via actin nodules is important for platelet capture under high shear flow conditions.
Discussion
This study has used cutting-edge microscopy to characterize actin nodule structure and function, in both human and mouse platelets, at high spatial and temporal resolution. dSTORM and SIM provide a detailed image of protein localization in platelets to within ∼20 and ∼100 nm, respectively, which is a considerable advance over conventional light microscopy. In addition, dSTORM has enabled quantitative analysis of protein distribution. This has revealed that nodules in human platelets are composed of up to four actin centres linked by actin bundles and display differential organization of adhesion-related proteins. Furthermore, using platelets from WAS patients and a mouse model of the disease, we demonstrate that nodules are WASp-dependent structures and provide evidence that they are important for platelet aggregate formation and stability under flow conditions. We propose that the loss of nodules in platelets contributes to pathological bleeding in WAS patients.
The enhanced resolution provided by SIM and dSTORM, and studies on mutant mice, has allowed us to conclude that nodules are platelet podosome-like structures formed during the early stage of spreading. We were able to rule out that nodules represent an alternative, early adhesion-related structure, namely SICs18, through the demonstration that they do not co-localize with the SIC markers RACK1 or RNA and the distribution of actin is different18. Nodules, like podosomes, have an actin-rich core and a distinct ring of proteins16. In addition, nodule formation is dependent on WASp and ARP2/3 activity. However, nodules are distinct from podosomes on the basis of their relatively small size and fast turnover rate (∼10–40 s compared with 5–15 min for megakaryocyte podosomes12). A further property of podosomes is their ability to interact with and degrade the ECM. Megakaryocyte podosomes have been shown to use MMPs to degrade the underlying substrate and this, coupled with actin polymerization at the podosome core, provides the force necessary to protrude through the basement membrane to extend proplatelets into the bloodstream12. Interestingly WASp-KO megakaryocytes, which do not form podosomes, are unable to degrade the substrate and this may explain the release of platelets in the bone marrow9,12. In contrast, MMP inhibition does not affect nodule formation and nodules are not involved in substrate degradation. This difference is consistent with the shorter lifetime of nodules versus megakaryocyte podosomes.
Super-resolution microscopy has been applied to the study of podosomes to provide detail on their nanostructure45,46. dSTORM imaging of podosomes in dendritic cells (DCs) found that podosomes were interconnected by actin bundles radiating from the dense actin core46, bearing a strong resemblance to the actin-based interconnections of nodules in platelets. In DCs, the integrin αMβ2 was homogenously distributed as ‘islets’ over the surface of the cell except at podosomes where it was completely excluded from the actin core46. In osteoclasts, integrins have been reported to localize to different regions of the podosome, with β3 integrins tending to localize to the outer ring while β1 localizes to the core (reviewed in ref. 16). Therefore, nodules are not alone in showing a distinct pattern of integrin organization relative to their inner core. In podosomes, this exclusion has been linked to regions of the membrane that are in close contact with the ECM46 and presumably is due to physical exclusion of surface molecules. In this study we observe an increase in the apparent size of actin nodules during their lifetime and have shown that this increase is due to both increased actin polymerization (this study and ref. 24) and movement of the nodule closer to the substrate. This actin polymerization-induced downward movement of the membrane towards the substrate could explain the physical exclusion of integrins from these regions47.
The adhesion-related proteins talin and vinculin are characteristic of the ring structure of podosomes in many cell types including megakaryocytes16. However, in DCs, talin and vinculin have been shown to have a differential patterning around the podosomes. Talin exhibited a similar distribution to the integrin (homogenously distributed but depleted from the podosome core), whereas vinculin was enriched around the actin core and along the radiating actin bundles46. In platelets, using SIM, we see both talin and vinculin throughout the platelet with enrichment of both around the nodule core. Both talin and vinculin have been shown to be important for mechano-sensing48,49. This role is achieved through the ability of talin to link the actin cytoskeleton to activated integrins, which supports adhesion to the ECM50 and platelet–platelet interactions51. The link between actin and integrins is reinforced by the binding of vinculin. The vinculin head domain binds to sites along the talin rod domain, and its tail domain binds to actin52,53. The role of vinculin in reinforcing, rather than being essential for mechano-sensing, is highlighted by the increase in bleeding times observed in vinculin-null mice despite platelet function being unaffected54. The dynamic, interconnected nature of actin nodules and the organization of integrins and adhesion-related proteins at these structures lead us to predict that actin nodules play a role in mechano-coupling between platelets and the substrate or platelets and other platelets as proposed in Fig. 10. Furthermore, the observation that moesin and α-actinin molecules that are known to link actin filaments to membranes and to be involved in mechano-sensing, respectively55,56,57, are enriched at actin nodules (Supplementary Fig. 9), provides further (indirect) evidence for this hypothesis.
Our lab has previously shown that SFK and actin polymerization is required for stable platelet aggregate formation under flow conditions58. We have shown here that the actin polymerization required for nodule formation is dependent on the WASp-ARP2/3 axis as WASp-KO platelets do not have nodules. However, ARP2/3 activity downstream of other NPFs (for example, Scar/WAVE59) is unaffected as WASp-null platelets are still able to form lamellipodia and correctly localize ARP2/3 to lamellipodia in spread platelets. Our data show that while WASp-KO platelets have a small defect in spreading under static assays, it is under conditions mimicking arterial shear rates that the major effect is observed. WASp-KO platelets do not adhere as efficiently to collagen or fibrinogen under flow conditions and form only monolayers and small aggregates on collagen at high shear rates. Consistent with this, nodules can be seen in platelets spreading on other substrates such as collagen or VWF (plus botrocetin)24. The formation of nodules, however, is most prevalent in platelets spreading on fibrinogen. Fibrinogen is a ligand for the αIIbβ3 integrin and is primarily involved in platelet–platelet interactions in thrombus formation. This dependency on WASp implicates a role for actin nodules in platelet-substrate and platelet-platelet adhesion under shear and may underlie the increase in bleeding in WAS patients and unstable primary platelet plugs in mouse tail bleeding assays in the absence of WASp31.
In summary, we have provided strong evidence for the role of WASp in platelets. We show that it is required for the formation of actin nodules, structures, which share some similarities with podosomes, and demonstrate that it is required for robust aggregate formation under flow conditions.
Methods
Reagents
Human Fibrinogen (Plasminogen, von Willebrand Factor and Fibronectin depleted) was obtained from Enzyme Research Laboratories (Swansea, UK). Horm collagen was obtained from Takeda (High Wycombe, UK). Alexa488-fibrinogen, Alexa488-phalloidin, Alexa568-phalloidin, Anti-rabbit-Alexa568 (A-11036), Anti-mouse-Alexa568 (A-11031) and Anti-mouse-Alexa647 (A-21235) secondary antibodies were purchased from Life Technologies (Paisley, UK). The 35-mm uncoated glass bottomed dishes with No1.5 coverslips were obtained from MatTek Corporation (Massachusetts, USA). Monoclonal Anti-vinculin (clone hVIN-1, V9131), Anti-Talin (Clone 8d4, T3287), 10% neutral buffered Formalin solution, monoclonal Anti-Moesin (Clone 38/87, M7060) and anti-α-actinin (A2543) were purchased from Sigma (Poole, UK). Monoclonal Anti-Phosphotyrosine (clone 4G10, 05-1050), Anti p34-Arc(ARPC2, 07-227) and ARP2/3 complex inhibitor 1 (CK666) were purchased from Merck-Millipore (Middlesex, UK). Monoclonal Mouse Anti-Human CD41 (αIIb)-FITC (clone 5B12, F708801-2) was obtained from Dako UK (Cambridgeshire, UK). Mouse Anti-RACK1 (clone20/RACK1) was purchased from BD Transduction Laboratories (Oxford, UK, 610178). Sytox-Green was purchased from Life Technologies (Paisley, UK). GM6001 was purchased from Merck Millipore (Watford, UK). Unless specified otherwise, antibodies were used at a dilution of 1:250 of the supplied stock solution. All fluorescent secondary antibodies and phalloidin were used at a 1:300 dilution.
Mice
The 9- to 12-week-old C57Blk6, Lifeact-GFP60, WASp KO28 or WASp Y293F41 mice were maintained in IVCs under 12 h light/dark cycle at a constant temperature of 20 °C with food and water given ad libitum at BMSU, Birmingham University, UK. All experiments were performed in accordance with UK laws (Animal [Scientific Procedures] Act 1986) with approval of local ethics committee (Birmingham Animal Welfare and Ethical Review Board—AWERB) under a Home Office approved project licence.
Platelet preparation
Human blood samples for platelet isolation were donated by healthy volunteers under the following licence: ERN_11-0175 ‘The regulation of activation of platelets’ (UoB). Washed platelets were prepared as previously described4. In brief, blood was drawn by venipuncture from healthy volunteers into sodium citrate and acid/citrate/dextrose. Platelet-rich plasma (PRP) was prepared by centrifugation of whole blood at 200 × g for 20 min. The platelets were then isolated from PRP by centrifugation at 1,000 × g for 10 min in the presence of prostacyclin (0.1 μg ml−1). The pellet was resuspended in modified Tyrodes buffer (129 mM NaCl, 0.34 mM Na2HPO4, 2.9 mM KCl, 12 mM NaHCO3, 20 mM HEPES, 5 mM glucose, 1 mM MgCl2; pH 7.3) containing 0.1 μg ml−1 prostacyclin. The platelets were washed once via centrifugation (1,000 × g for 10 min) and resuspended at the desired concentration with modified Tyrodes buffer.
Washed platelet samples of mouse were prepared as previously described4. In brief, blood was drawn from CO2 terminally anaesthetized mice from the vena cava and taken into 100 μl of acid/citrate/dextrose. PRP was obtained by centrifugation at 200 × g for 6 min. Washed platelets were prepared via centrifugation of PRP at 1,000 × g in the presence of prostacyclin (0.1 μg ml−1) for 6 min. The pellet was resuspended in modified Tyrode buffer to the desired platelet level.
Wiskott–Aldrich syndrome patients
This study was approved by the National Research Ethics Service Committee West Midlands—Edgbaston (REC reference: 06/MRE07/36) and participants and controls gave written informed consent in accordance with the Declaration of Helsinki.
Patient #1 c. 134C>T WASP mutation predicting a p. T45M missense alteration. This disrupts binding of WASp to WIP binding leading to increased WASp degradation42. This patient expressed very low levels of WASp.
Patient #2 c. IVS6+2T>C mutation that affects splicing and is predicted to give rise to WASp null platelets43,44. This patient expressed no WASp.
Platelet spreading and staining
For fixed cell imaging experiments, washed and rested platelets were diluted to 2 × 107 cells ml−1 in modified Tyrodes buffer and allowed to spread on glass bottomed dishes coated with fibrinogen (100 μg ml−1) for 30 min at 37 °C. Adhered cells were rinsed briefly twice with phosphate buffered saline (PBS) and fixed for 10 min with 10% formalin solution. Fixed samples were washed three times with PBS and also between each step of the staining procedure. Fixed platelets were treated with 50 mM NH4Cl for 10 min to quench residual formalin fluorescence, permeabilized with 0.1% Triton X-100 in PBS for 5 min and then stained with antibodies or phalloidin as required. Samples for N-SIM imaging were mounted in Hydromount and stored at room temperature. Samples for dSTORM imaging were stored in PBS at room temperature and protected from light until imaged. When required, platelets were treated with the ARP2/3 inhibitor, CK666 (10 μm)61,62, or Monoclonal Mouse Anti-Human CD41 (αIIb)-FITC for 10 min at 37 °C before spreading. Following imaging (see below), platelet surface area was measured using ImageJ (NIH, Bethesda, USA). Data were analysed using Graphpad Prism v6 (Graphpad, California, USA).
Treatment of platelets with the MMP inhibitor GM6001
Washed human platelets at 2 × 107 cells ml−1 were treated with 100 μM GM6001, or the same volume of DMSO as a vehicle control, for 10 min at 37 °C before being spread for 30 min on Alexa488-fibrinogen-coated coverslips. Platelets were then fixed in formalin, permeabilized, stained for actin with Alexa568-phalloidin and imaged by z-stack confocal microscopy using a Leica SP2 inverted confocal with the 63 × objective. Five fields of view (59 × 59 μm) were taken per treatment, per experiment (n=3; a total of >360 platelets per treatment). Platelet number per field of view, surface area and number of nodules μm−2 were calculated using the Nikon NIS Elements v4.1 software.
Flow-adhesion assay
Blood from three WT and three WASP-KO mice was drawn into sodium heparin (10 U ml−1) and PPACK (D-phenylalanyl-L-prolyl-L-arginine chloromethyl ketone–40 μM). Glass capillaries, 0.1 × 1 mm internal diameter (Camlab, Cambridge, UK) were coated with 100 μg ml−1 Horm collagen or 100 μg ml−1 fibrinogen overnight at 4 °C then blocked with 5 mg ml−1 heat-inactivated BSA in PBS for 1 h at room temperature. The capillaries were mounted on the stage of an inverted microscope (DM IRB; Leica), connected to a Harvard pump driven flow system and rinsed through with PBS to remove the BSA block. The blood was pre-incubated with DiOC6 (3,3′-dihexyloxacarbocyanine iodide–2 μM) for 10 min before perfusion through the chamber at 37 °C at the shear rate and duration indicated in the text and figure legend. Platelet aggregates were washed with modified-Tyrode’s buffer at the same flow rate as the blood for 5 min and then immediately imaged by DIC and z-stack fluorescence microscopy on a Zeiss Axiovert 200 M with a 63 × objective. Ten fields of view, along the length of the capillary, per flow experiment were imaged. For flow over Horm collagen platelet aggregate formation was assessed in ImageJ by thresholding the fluorescence image to identify the aggregates. The mean surface area (μm2) of individual thrombi was assessed in both WT and KO. The mean fluorescence intensity of the aggregates was then calculated as a measure of the aggregate volume. To test the effect of reduced platelet count on platelet aggregate formation, samples of WT mouse blood had the platelet count recorded before being split in half; one aliquot was centrifuged at 200 × g. for 6 min to produce (PRP) and a red blood cell fraction. The PRP had PGI2 (0.1 μg ml−1 PGI2 per ml PRP) added and was spun for a further 6 min at 1,000 × g to pellet the platelets. This platelet-poor plasma (PPP) was added back to the red cell fraction to generate reconstituted blood with a reduced platelet count. The second aliquot was left untreated, except for the addition of an equivalent concentration of PGI2. WT and platelet-depleted blood were then mixed in the appropriate ratios to give blood with platelet counts ranging from 1,200 to 282 × 103 platelets μl−1. For analysis of the fibrinogen flow data the number of platelets per field of view (10 per experiment) were manually counted using the ImageJ plugin ‘Cell counter’. Individual platelets were then scored as being (1) unspread, (2) having filopodia, (3) having lamellipodia and expressed as a percentage of the total platelets counted in that field of view. Student’s t-tests were carried out in Graphpad Prism v6 to assess significance.
Total internal reflection fluorescence microscopy
Live Lifeact-GFP platelets were imaged using an Olympus IX81 Inverted microscope with a 60x Plan Apo 1.49NA oil-immersion objective and a Hammamatsu ORCA-R2 C10600 12-bit CCD. Samples were excited with a 491-50 Diode type laser. For the dual TIRF—Epifluorescence live cell imaging of actin nodules a 150 × objective (UAPON 150XOTIRF, 1.45 NA, Olympus) was used with the same Olympus TIRF microscope. The 491-nm laser was set at the same power and gain, with the angle of the laser altered to achieve TIRF (with a penetration depth of 100 nm) and then immediately switched to widefield (Epi) illumination. Images were taken every 2 s and drift in Z was minimized with Olympus Z-drift correction (ZDC). Images were acquired using Xcellence Advanced Live Cell Imaging System 1.1. Post-imaging analysis was performed using Nikon NIS Elements v4.1 and ImageJ 1.47v.
To calculate the nodule movement in Z, regions of interest (ROIs) were drawn around nodules that were seen to appear and disappear within the timeframe of the movie. The intensity of both the TIRF and Epi channels were measured and plotted against time. The vast majority of nodules showed a much greater increase in intensity in TIRF than in Epi, indicating movement towards the coverslip. With the assumption that the contribution to intensity from actin polymerization was minimal the movement in Z can be calculated from the TIRF intensity values over time using equations 1, 2, 3, 439:
Where I0 is the intensity of the laser, z the distance from the coverslip and d the penetration depth (a function of TIRF angle and refractive index). Assuming that pixel value is proportional to the intensity of the TIRF field then
Where P is the pixel intensity value and C is a constant, which depends on detector sensitivity, detector gain and fluorophore concentration. We know that these factors remain constant between TIRF and Epi images then C remains the same for different time points. Therefore, the ratio of pixel intensities at two time points equals
This rearranges to
Using this equation the movement in Z of an actin nodule between each time point was calculated. From this the overall movement of an actin nodule, from first appearance to disappearance, was plotted against time. Values for each nodule were calculated in Excel 2010 and graphs plotted in Graphpad Prism v6.
Structured illumination microscopy
Samples were imaged on a Nikon N-SIM system consisting of a Ti-E stand with Perfect Focus, 100 × 1.49 NA TIRF objective lens, Nikon LU5 laser bed (488 and 561 nm laser lines), 3D SIM grating and Andor DU897 EMCCD camera. Images were captured using Nikon NIS Elements v4.1 and reconstructed using slice reconstruction in NIS elements. Post-imaging analysis was performed using NIS Elements v4.1 and ImageJ 1.47v.
STORM imaging and cluster analysis
Samples were imaged on a Nikon N-STORM system in dSTORM mode consisting of a Ti-E stand with Perfect Focus, 100 × 1.49 NA TIRF objective lens, Agilent MLC400 high power laser bed (647 nm laser line) and Andor DU897 EMCCD camera. Samples were imaged in a PBS buffer containing MEA (100 mM) and GLOX (10% v/v) to induce fluorophore blinking63. Twenty thousand frames were captured using Nikon NIS Elements v4.1 and reconstructed using STORM analysis module 1.1. Samples were drift corrected and rendered using Gaussian rendering. Spots present in the final reconstructed images represent individually identified fluorescent blinking events. Post-imaging analysis was performed using Nikon NIS Elements v4.1. For information: the median localization precision, a measure used to assess quality of super-resolution images64, routinely achieved for 4G10 imaging was 12.8 nm (range 1.58 to 37.6 nm) and for CD41 it was 17.9 nm (range 2.8–66.4 nm), calculated from five images. Cluster analysis was performed on the dSTORM data in MATLAB using a custom made algorithm as described by Owen et al.34, based on Ripley’s K-function and Getis and Franklin’s Local Point Pattern analysis and described briefly here.
The K-function, K(r), for a molecule, j, within an analysed region of area A containing n molecules in total is defined as:
Where dij is the distance from molecule j to molecule i. In essence, this value is the number of molecules found within a radius r of molecule j, divided by the mean molecular density (n/A) of the region. Since the value of K(r) scales as r2 the K-function is typically linearized to generate the L-function such that L(r)=sqrt(K(r)/π) so:
Here, the value of L(r) was computed for each molecule in a region. For analysis, the region of interest was set at 1 μm2, and the spatial scale analysed (r) was set to 50 nm. Thus,
To generate a pseudo-coloured cluster map, the values of L(50) at each point, j, where interpolated onto a 5 nm resolution grid (Matlab ‘v4’ interpolation algorithm). This cluster map could then have an upper and lower threshold applied to them to generate binary maps. Areas of the map below the lower threshold were defined as being holes—where the local molecular density is low relative to the mean molecular density, whereas areas above the upper threshold were defined as clusters. For integrin analysis the lower binary threshold was set at L(50)=20 and the upper binary threshold was set at L(50)=70. For pTyr analysis the upper binary threshold for clustering was set at L(50)=100. Twenty-five ROIs containing actin nodules and 25 without were analysed for pTyr clustering quantification. All dSTORM analyses were performed on human platelets.
SEM prep and imaging
Platelet cytoskeletons were isolated by permeabilizing cells with PHEM buffer (60 mM Pipes, 25 mM Hepes, 10 mM EGTA, and 2 mM MgCl2) containing 0.75% Triton X-100 for 2 min. Cytoskeletons were then fixed with 1% glutaraldehyde in PHEM for 10 min Water washed coverslips of platelet cytoskeletons were rapidly frozen, freeze-dried, and coated with platinum and carbon. Replicas were picked up on carbon-formvar-coated copper grids and examined with a JEOL JEM-1200 EX transmission electron microscope at an accelerating voltage of 80 kV.
Additional information
How to cite this article: Poulter, N. S. et al. Platelet actin nodules are podosome-like structures dependent on Wiskott–Aldrich syndrome protein and ARP2/3 complex. Nat. Commun. 6:7254 doi: 10.1038/ncomms8254 (2015).
References
Boyles, J., Fox, J. E., Phillips, D. R. & Stenberg, P. E. Organization of the cytoskeleton in resting, discoid platelets: preservation of actin filaments by a modified fixation that prevents osmium damage. J. Cell Biol. 101, 1463–1472 (1985).
Hartwig, J. H. & DeSisto, M. The cytoskeleton of the resting human blood platelet: structure of the membrane skeleton and its attachment to actin filaments. J. Cell Biol. 112, 407–425 (1991).
Falet, H. et al. A novel interaction between FlnA and Syk regulates platelet ITAM-mediated receptor signaling and function. J. Exp. Med. 207, 1967–1979 (2010).
McCarty, O. J. et al. Rac1 is essential for platelet lamellipodia formation and aggregate stability under flow. J. Biol. Chem. 280, 39474–39484 (2005).
Pollitt, A. Y. et al. Phosphorylation of CLEC-2 is dependent on lipid rafts, actin polymerization, secondary mediators, and Rac. Blood 115, 2938–2946 (2010).
Shattil, S. J., Kashiwagi, H. & Pampori, N. Integrin signaling: the platelet paradigm. Blood 91, 2645–2657 (1998).
Watson, S. P. Platelet activation by extracellular matrix proteins in haemostasis and thrombosis. Curr. Pharm. Des. 15, 1358–1372 (2009).
Watson, S. P., Auger, J. M., McCarty, O. J. & Pearce, A. C. GPVI and integrin alphaIIb beta3 signaling in platelets. J. Thromb. Haemost. 3, 1752–1762 (2005).
Sabri, S. et al. Deficiency in the Wiskott-Aldrich protein induces premature proplatelet formation and platelet production in the bone marrow compartment. Blood 108, 134–140 (2006).
Italiano, J. E. Jr., Patel-Hett, S. & Hartwig, J. H. Mechanics of proplatelet elaboration. J. Thromb. Haemost. 5, (Suppl 1): 18–23 (2007).
Chen, Y. et al. The abnormal proplatelet formation in MYH9-related macrothrombocytopenia results from an increased actomyosin contractility and is rescued by myosin IIA inhibition. J. Thromb. Haemost. 11, 2163–2175 (2013).
Schachtner, H. et al. Megakaryocytes assemble podosomes that degrade matrix and protrude through basement membrane. Blood 121, 2542–2552 (2013).
Burridge, K. & Wittchen, E. S. The tension mounts: stress fibers as force-generating mechanotransducers. J. Cell Biol. 200, 9–19 (2013).
Lambrechts, A., Gevaert, K., Cossart, P., Vandekerckhove, J. & Van Troys, M. Listeria comet tails: the actin-based motility machinery at work. Trends Cell Biol. 18, 220–227 (2008).
Ridley, A. J. Life at the leading edge. Cell 145, 1012–1022 (2011).
Schachtner, H., Calaminus, S. D., Thomas, S. G. & Machesky, L. M. Podosomes in adhesion, migration, mechanosensing and matrix remodeling. Cytoskeleton (Hoboken) 70, 572–589 (2013).
Yang, C. & Svitkina, T. Filopodia initiation: focus on the Arp2/3 complex and formins. Cell Adh. Migr. 5, 402–408 (2011).
de Hoog, C. L., Foster, L. J. & Mann, M. RNA and RNA binding proteins participate in early stages of cell spreading through spreading initiation centers. Cell 117, 649–662 (2004).
Falet, H. et al. Importance of free actin filament barbed ends for Arp2/3 complex function in platelets and fibroblasts. Proc. Natl Acad. Sci. USA 99, 16782–16787 (2002).
Pleines, I. et al. Rac1 is essential for phospholipase C-gamma2 activation in platelets. Pflugers Arch. 457, 1173–1185 (2009).
Pleines, I. et al. Multiple alterations of platelet functions dominated by increased secretion in mice lacking Cdc42 in platelets. Blood 115, 3364–3373 (2010).
Akbar, H. et al. Gene targeting implicates Cdc42 GTPase in GPVI and non-GPVI mediated platelet filopodia formation, secretion and aggregation. PLoS ONE 6, e22117 (2011).
Goggs, R., Savage, J. S., Mellor, H. & Poole, A. W. The small GTPase Rif is dispensable for platelet filopodia generation in mice. PLoS ONE 8, e54663 (2013).
Calaminus, S. D., Thomas, S., McCarty, O. J., Machesky, L. M. & Watson, S. P. Identification of a novel, actin-rich structure, the actin nodule, in the early stages of platelet spreading. J. Thromb. Haemost. 6, 1944–1952 (2008).
Linder, S. & Kopp, P. Podosomes at a glance. J. Cell Sci. 118, 2079–2082 (2005).
Snapper, S. B. & Rosen, F. S. The Wiskott-Aldrich syndrome protein (WASP): roles in signaling and cytoskeletal organization. Annu. Rev. Immunol. 17, 905–929 (1999).
Moulding, D. A., Record, J., Malinova, D. & Thrasher, A. J. Actin cytoskeletal defects in immunodeficiency. Immunol. Rev. 256, 282–299 (2013).
Snapper, S. B. et al. Wiskott-Aldrich syndrome protein-deficient mice reveal a role for WASP in T but not B cell activation. Immunity 9, 81–91 (1998).
Gross, B. S. et al. Regulation and function of WASp in platelets by the collagen receptor, glycoprotein VI. Blood 94, 4166–4176 (1999).
Lutskiy, M. I., Shcherbina, A., Bachli, E. T., Cooley, J. & Remold-O'Donnell, E. WASP localizes to the membrane skeleton of platelets. Br. J. Haematol. 139, 98–105 (2007).
Shcherbina, A. et al. WASP plays a novel role in regulating platelet responses dependent on alphaIIbbeta3 integrin outside-in signalling. Br. J. Haematol. 148, 416–427 (2010).
Tsuboi, S., Nonoyama, S. & Ochs, H. D. Wiskott-Aldrich syndrome protein is involved in alphaIIb beta3-mediated cell adhesion. EMBO Rep. 7, 506–511 (2006).
Leung, B. O. & Chou, K. C. Review of super-resolution fluorescence microscopy for biology. Appl. Spectrosc. 65, 967–980 (2011).
Owen, D. M. et al. PALM imaging and cluster analysis of protein heterogeneity at the cell surface. J. Biophotonics 3, 446–454 (2010).
Riedl, J. et al. Lifeact: a versatile marker to visualize F-actin. Nat. Methods 5, 605–607 (2008).
Lemieux, M. G. et al. Visualization of the actin cytoskeleton: Different F-actin-binding probes tell different stories. Cytoskeleton 71, 157–169 (2014).
Schachtner, H. et al. Tissue inducible Lifeact expression allows visualization of actin dynamics in vivo and ex vivo. Eur. J. Cell Biol. 91, 923–929 (2012).
Mattheyses, A. L., Simon, S. M. & Rappoport, J. Z. Imaging with total internal reflection fluorescence microscopy for the cell biologist. J. Cell Sci. 123, 3621–3628 (2010).
Axelrod, D., Burghardt, T. P. & Thompson, N. L. Total internal reflection fluorescence. Annu. Rev. Biophys. Bioeng. 13, 247–268 (1984).
Campbell, I. D. & Humphries, M. J. Integrin structure, activation, and interactions. Cold Spring Harb. Perspect. Biol. 3, a004994 (2011).
Blundell, M. P. et al. Phosphorylation of WASp is a key regulator of activity and stability in vivo. Proc. Natl Acad. Sci. USA 106, 15738–15743 (2009).
de la Fuente, M. A. et al. WIP is a chaperone for Wiskott-Aldrich syndrome protein (WASP). Proc. Natl Acad. Sci. USA 104, 926–931 (2007).
Andreu, N. et al. Identification and characterization of a novel splice-site mutation in a patient with Wiskott-Aldrich syndrome. J. Hum. Genet. 48, 590–593 (2003).
Lutskiy, M. I., Rosen, F. S. & Remold-O'Donnell, E. Genotype-proteotype linkage in the Wiskott-Aldrich syndrome. J. Immunol. 175, 1329–1336 (2005).
Cox, S. et al. Bayesian localization microscopy reveals nanoscale podosome dynamics. Nat. Method 9, 195–200 (2012).
van den Dries, K. et al. Dual-color superresolution microscopy reveals nanoscale organization of mechanosensory podosomes. Mol. Biol. Cell 24, 2112–2123 (2013).
Delon, J., Stoll, S. & Germain, R. N. Imaging of T-cell interactions with antigen presenting cells in culture and in intact lymphoid tissue. Immunol. Rev. 189, 51–63 (2002).
Lee, S. E., Kamm, R. D. & Mofrad, M. R. Force-induced activation of talin and its possible role in focal adhesion mechanotransduction. J. Biomech. 40, 2096–2106 (2007).
Mierke, C. T. et al. Mechano-coupling and regulation of contractility by the vinculin tail domain. Biophys. J. 94, 661–670 (2008).
Calderwood, D. A., Campbell, I. D. & Critchley, D. R. Talins and kindlins: partners in integrin-mediated adhesion. Nat. Rev. Mol. Cell Biol. 14, 503–517 (2013).
Petrich, B. G. et al. Talin is required for integrin-mediated platelet function in hemostasis and thrombosis. J. Exp. Med. 204, 3103–3111 (2007).
Ziegler, W. H., Liddington, R. C. & Critchley, D. R. The structure and regulation of vinculin. Trends Cell Biol. 16, 453–460 (2006).
Humphries, J. D. et al. Vinculin controls focal adhesion formation by direct interactions with talin and actin. J. Cell Biol. 179, 1043–1057 (2007).
Mitsios, J. V. et al. What is vinculin needed for in platelets? J. Thromb. Haemost. 8, 2294–2304 (2010).
Neisch, A. L. & Fehon, R. G. Ezrin, Radixin and Moesin: key regulators of membrane-cortex interactions and signaling. Curr. Opin. Cell Biol. 23, 377–382 (2011).
Tadokoro, S. et al. A potential role for alpha-actinin in inside-out alphaIIbbeta3 signaling. Blood 117, 250–258 (2011).
van den Dries, K. et al. Interplay between myosin IIA-mediated contractility and actin network integrity orchestrates podosome composition and oscillations. Nat. Commun. 4, 1412 (2013).
Auger, J. M. & Watson, S. P. Dynamic tyrosine kinase-regulated signaling and actin polymerization mediate aggregate stability under shear. Arterioscler. Thromb. Vasc. Biol. 28, 1499–1504 (2008).
Calaminus, S. D. et al. A major role for Scar/WAVE-1 downstream of GPVI in platelets. J. Thromb. Haemost. 5, 535–541 (2007).
Riedl, J. et al. Lifeact mice for studying F-actin dynamics. Nat. Meth 7, 168–169 (2010).
Nolen, B. J. et al. Characterization of two classes of small molecule inhibitors of Arp2/3 complex. Nature 460, 1031–1034 (2009).
Hetrick, B., Han, M. S., Helgeson, L. A. & Nolen, B. J. Small molecules CK-666 and CK-869 inhibit actin-related protein 2/3 complex by blocking an activating conformational change. Chem. Biol. 20, 701–712 (2013).
Dempsey, G. T., Vaughan, J. C., Chen, K. H., Bates, M. & Zhuang, X. Evaluation of fluorophores for optimal performance in localization-based super-resolution imaging. Nat. Methods 8, 1027–1036 (2011).
Betzig, E. et al. Imaging intracellular fluorescent proteins at nanometer resolution. Science 313, 1642–1645 (2006).
Acknowledgements
We thank the British Heart Foundation (NH/11/6/29061 & CH/03/003SP1), Wellcome Trust (088410/Z/09/Z), EPSRC (EP/F50053X/1) and Great Ormond Street Hospital BRC for providing funding. We thank John Harris from Kings College London and Kate Passam, Dan Metcalf & Alan Monk from Nikon (UK) for support and helpful discussions on super-resolution imaging; Mike Blundell at UCL Institute of Child Health for assistance with the WASp mice. We also thank the Birmingham Advanced Light Microscope (BALM) facility and Jeremy Pike for continued support with imaging and analysis of TIRF data.
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N.S.P. performed experiments and prepared the manuscript; A.Y.P. performed experiments and prepared figures; A.D., D.M., J.H.H. & D.M.O. performed experiments; G.B.N., M.J.H., Z.P. & J.Z.R. discussed results; A.J.T. provided mouse and patient samples for experiments; S.P.W. conceptualized the study and prepared the manuscript; S.G.T conceptualized the study, performed experiments and prepared the manuscript.
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Supplementary Information
Supplementary Figures 1-9, Supplementary Notes 1-2 and Supplementary References (PDF 1581 kb)
Supplementary Movie 1
Three representative Lifeact-GFP mouse platelets spreading on fibrinogen surface showing the dynamic nature of actin nodules. Scale bar = 5μm. Image taken every 2 seconds. (MOV 926 kb)
Supplementary Movie 2
Lifeact-GFP mouse platelets spreading on fibrinogen and imaged in TIRF (left panel; green) and Epi (right panel; magenta). Laser power and detector gain setting kept constant with rapid switching between TIRF and Epi modes. Boxed region indicates the representative nodule described in Figure 6e & f. Scale bar = 5μm. Image taken every 2 seconds. (MOV 11189 kb)
Supplementary Movie 3
Effect of 20μM CK666 on Lifeact-GFP mouse platelet spreading. The platelets in the right hand panel were treated with the inhibitor for 10 min prior to spreading on a fibrinogen surface. Scale bar = 5μm. Image taken every 2.5 seconds. (MOV 4010 kb)
Supplementary Movie 4
Wildtype or WASp KO mouse whole blood labelled with DICO6 and flowed over Horm collagen at a shear of 3000s-1 for 1.5 minutes. Scale bar = 20μm. (MOV 864 kb)
Supplementary Movie 5
Wildtype or WASp KO mouse whole blood, labelled with DICO6 and flowed over fibrinogen at a shear of 600s-1 for 4 minutes. Scale bar = 10μm. (MOV 2633 kb)
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Poulter, N., Pollitt, A., Davies, A. et al. Platelet actin nodules are podosome-like structures dependent on Wiskott–Aldrich syndrome protein and ARP2/3 complex. Nat Commun 6, 7254 (2015). https://doi.org/10.1038/ncomms8254
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DOI: https://doi.org/10.1038/ncomms8254
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