Daniel Rönnlund

Spatial distribution of Na + -K + -ATPase in dendritic spines dissected by nanoscale superresolution STED microscopy

BackgroundThe Na+,K+-ATPase plays an important role for ion homeostasis in virtually all mammalian cells, including neurons. Despite this, there is as yet little known about the isoform specific distribution in neurons.ResultsWith help of superresolving stimulated emission depletion microscopy the spatial distribution of Na+,K+-ATPase in dendritic spines of cultured striatum neurons have been dissected. The found compartmentalized distribution provides a strong evidence for the confinement of neuronal Na+,K+-ATPase (α3 isoform) in the postsynaptic region of the spine.ConclusionsA compartmentalized distribution may have implications for the generation of local sodium gradients within the spine and for the structural and functional interaction between the sodium pump and other synaptic proteins. Superresolution microscopy has thus opened up a new perspective to elucidate the nature of the physiological function, regulation and signaling role of Na+,K+-ATPase from its topological distribution in dendritic spines.

LytA, Major Autolysin of Streptococcus pneumoniae, Requires Access to Nascent Peptidoglycan

Background: The regulation of cell wall hydrolysis by the pneumococcal autolysin LytA is poorly understood. Results: The cell wall is susceptible to extracellular LytA only during the stationary phase or after cell wall synthesis inhibition. Conclusion: LytA is regulated on the substrate level, where peptidoglycan modifications likely prevent LytA hydrolysis. Significance: The control of amidases is essential for bacterial survival, cell-wall synthesis, and division. The pneumococcal autolysin LytA is a virulence factor involved in autolysis as well as in fratricidal- and penicillin-induced lysis. In this study, we used biochemical and molecular biological approaches to elucidate which factors control the cytoplasmic translocation and lytic activation of LytA. We show that LytA is mainly localized intracellularly, as only a small fraction was found attached to the extracellular cell wall. By manipulating the extracellular concentration of LytA, we found that the cells were protected from lysis during exponential growth, but not in the stationary phase, and that a defined threshold concentration of extracellular LytA dictates the onset of autolysis. Stalling growth through nutrient depletion, or the specific arrest of cell wall synthesis, sensitized cells for LytA-mediated lysis. Inhibition of cell wall association via the choline binding domain of an exogenously added enzymatically inactive form of LytA revealed a potential substrate for the amidase domain within the cell wall where the formation of nascent peptidoglycan occurs.

Oncogenes induce a vimentin filament collapse mediated by HDAC6 that is linked to cell stiffness

Significance Oncogenes deregulate fundamental cellular functions, which can lead to the development of tumors and metastases. We show that oncogenes change the spatial organization of the vimentin fibers of the intracellular cytoskeleton, induce cell stiffness, and promote the invasive capacity of cells. We further show that this vimentin reorganization and increased cell stiffness requires histone deacetylase 6 (HDAC6). Taken together, these data support the concept that oncogenes can induce cellular stiffness via HDAC6-dependent reorganization of the vimentin filament network. These findings—that key molecules in oncogenic cell transformation, such as oncogenes and HDAC6, can modulate cell stiffness—highlight the importance of the need for further investigation of the mechanical properties of cells to better understand the mechanisms behind tumor and metastasis formation. Oncogenes deregulate fundamental cellular functions, which can lead to development of tumors, tumor-cell invasion, and metastasis. As the mechanical properties of cells govern cell motility, we hypothesized that oncogenes promote cell invasion by inducing cytoskeletal changes that increase cellular stiffness. We show that the oncogenes simian virus 40 large T antigen, c-Myc, and cyclin E induce spatial reorganization of the vimentin intermediate filament network in cells. At the cellular level, this reorganization manifests as increased width of vimentin fibers and the collapse of the vimentin network. At nanoscale resolution, the organization of vimentin fibers in these oncogene-expressing cells was more entangled, with increased width of the fibers compared with control cells. Expression of these oncogenes also resulted in up-regulation of the tubulin deacetylase histone deacetylase 6 (HDAC6) and altered spatial distribution of acetylated microtubules. This oncogene expression also induced increases in cellular stiffness and promoted the invasive capacity of the cells. Importantly, HDAC6 was required and sufficient for the structural collapse of the vimentin filament network, and was required for increased cellular stiffness of the oncogene-expressing cells. Taken together, these data are consistent with the possibility that oncogenes can induce cellular stiffness via an HDAC6-induced reorganization of the vimentin intermediate filament network.

Nearest neighbor analysis of dopamine D1 receptors and Na+-K+-ATPases in dendritic spines dissected by STED microscopy

Protein localization in dendritic spines is the focus of intense investigations within neuroscience. Applications of super‐resolution microscopy to dissect nanoscale protein distributions, as shown in this work with dual‐color STED, generate spatial correlation coefficients having quite small values. This means that colocalization analysis to some extent looses part of its correlative impact. In this study we thus introduced nearest neighbor analysis to quantify the spatial relations between two important proteins in neurons, the dopamine D1 receptor and Na+,K+‐ATPase. The analysis gave new information on how dense the D1 receptor and Na+,K+‐ATPase constituting nanoclusters are located both with respect to the homogenous (self to same) and the heterogeneous (same to other) topology. The STED dissected nanoscale topologies provide evidence for both a joint as well as a separated confinement of the D1 receptor and the Na+,K+‐ATPase in the postsynaptic areas of dendritic spines. This confined topology may have implications for generation of local sodium gradients and for structural and functional interactions modulating slow synaptic transmission processes. Microsc. Res. Tech., 2011.

Fluorescence Nanoscopy of Platelets Resolves Platelet‐State Specific Storage, Release and Uptake of Proteins, Opening up Future Diagnostic Applications

Dysregulation of how platelets store, sequester and release specific proteins seems to be implicated in many disease states, including cancer. Dual-color immunofluorescence stimulated emission depletion (STED) microscopy with 40 nm resolution is used to map pro-angiogenic VEGF, anti-angiogenic PF-4 and fibrinogen in >300 individual platelets. This reveals that these proteins are stored in a segmented, zonal manner within regional clusters, significantly smaller than the size of an α-granule. No colocalization between the different proteins is observed. Upon platelet activation by thrombin or ADP, the proteins undergo significant spatial rearrangements, including alterations in the size and number of the protein clusters, and specific for a certain protein and the type of activation induced. Following these observations, a simple assignment procedure is used to show that the three distinct states of platelets (non-, ADP- and thrombin-activated) can be identified based on the average size, number and peripheral localization profiles of the regional protein clusters within the platelets. Thus, high-resolution spatial mapping of specific proteins is a useful procedure to detect and characterize deviations in the selective storage, release and uptake of these proteins in the platelets. Since these deviations seem to be specific for, and may even underlie, certain patophysiological states, these findings may have interesting diagnostic and therapeutic implications.

Spatial organization of proteins in metastasizing cells

The ability of tumor cells to invade into the surrounding tissue is linked to defective adhesive and mechanical properties of the cells, which are regulated by cell surface adhesions and the intracellular filamentous cytoskeleton, respectively. With the aim to further reveal the underlying mechanisms and provide new strategies for early cancer diagnostics, we have used ultrahigh resolution stimulated emission depletion (STED) microscopy as a means to identify metastasizing cells, based on their subcellular protein distribution patterns reflecting their specific adhesive and mechanical properties. We have compared the spatial distribution of cell‐matrix adhesion sites and the vimentin filamentous systems in a matched pair of primary, normal, and metastatic human fibroblast cells. We found that the metastatic cells showed significantly increased densities and more homogenous distributions of nanoscale adhesion‐related particles. Moreover, they showed an increase in the number but reduced sizes of the areas of cell‐matrix adhesion complexes. The organization of the vimentin intermediate filaments was also found to be significantly different in the metastasizing cells, showing an increased entanglement and loss of directionality. Image analysis procedures were established, allowing an objective detection and characterization of these features and distinction of metastatic cells from their normal counterparts. In conclusion, our results suggest that STED microscopy provides a novel tool to identify metastasizing cells from a very sparse number of cells, based on the altered spatial distribution of the cell‐matrix adhesions and intermediate filaments.

Rho GTPases link cellular contractile force to the density and distribution of nanoscale adhesions

The ability of cells to adhere and to exert contractile forces governs their capacity to move within an organism. The cytoskeletal regulators of the Rho GTPase proteins are involved in control of the contractile forces of cells. To elucidate the basis of cell migration, we analyzed contractile forces and nanoscale adhesion‐related particles in single cells expressing constitutively active variants of Rho GTPases by using traction‐force microscopy and ultra‐high‐resolution stimulated emission depletion microscopy, respectively. RhoAV14 induced large increases in the contractile forces of single cells, with Rac1L61 and RhoDV26 having more moderate effects. The RhoAV14‐ and RhoDV26‐induced forces showed similar spatial distributions and were accompanied by reduced or unaltered cell spreading. In contrast, the Rac1L61‐induced force had different, scattered, force distributions that were linked to increased cell spreading. All three of these Rho GTPase activities caused a loss of thick stress fibers and focal adhesions and a more homogenous distribution of nanoscale adhesion‐related particles over the ventral surface of the cells. Interestingly, only RhoAV14 increased the density of these particles. Our data suggest a Rac1‐specific mode for cells to generate contractile forces. Importantly, increased density and a more homogenous distribution of these small adhesion‐related particles promote cellular contractile forces.— Gad, A. K. B., Rönnlund, D., Spaar, A., Savchenko, A. A., Petranyi, G., Blom, H., Szekely, L., Widengren, J., Aspenström, P. Rho GTPases link cellular contractile force to the density and distribution of nanoscale adhesions. FASEB J. 26, 2374‐2382 (2012). www.fasebj.org

Multicolor Fluorescence Nanoscopy by Photobleaching: Concept, Verification, and Its Application To Resolve Selective Storage of Proteins in Platelets

Fluorescence nanoscopy provides means to discern the finer details of protein localization and interaction in cells by offering an order of magnitude higher resolution than conventional optical imaging techniques. However, these super resolution techniques put higher demands on the optical system and the fluorescent probes, making multicolor fluorescence nanoscopy a challenging task. Here we present a new and simple procedure, which exploits the photostability and excitation spectra of dyes to increase the number of simultaneous recordable targets in STED nanoscopy. We use this procedure to demonstrate four-color STED imaging of platelets with ≤40 nm resolution and low crosstalk. Platelets can selectively store, sequester, and release a multitude of different proteins, in a manner specific for different physiological and disease states. By applying multicolor nanoscopy to study platelets, we can achieve spatial mapping of the protein organization with a high resolution for multiple proteins at the same time and in the same cell. This provides a means to identify specific platelet activation states for diagnostic purposes and to understand the underlying protein storage and release mechanisms. We studied the organization of the pro- and antiangiogenic proteins VEGF and PF-4, together with fibrinogen and filamentous actin, and found distinct features in their respective protein localization. Further, colocalization analysis revealed only minor overlap between the proteins VEGF and PF-4 indicating that they have separate storage and release mechanisms, corresponding well with their opposite roles as pro- and antiangiogenic proteins, respectively.

Spatial Distribution of DARPP-32 in Dendritic Spines

The phosphoprotein DARPP-32 (dopamine and cyclic adenosine 3´, 5´-monophosphate-regulated phosphoprotein, 32 kDa) is an important component in the molecular regulation of postsynaptic signaling in neostriatum. Despite the importance of this phosphoprotein, there is as yet little known about the nanoscale distribution of DARPP-32. In this study we applied superresolution stimulated emission depletion microscopy (STED) to assess the expression and distribution of DARPP-32 in striatal neurons. Primary culture of striatal neurons were immunofluorescently labeled for DARPP-32 with Alexa-594 and for the dopamine D1 receptor (D1R) with atto-647N. Dual-color STED microscopy revealed discrete localizations of DARPP-32 and D1R in the spine structure, with clustered distributions in both head and neck. Dissected spine structures reveal that the DARPP-32 signal rarely overlapped with the D1R signal. The D1R receptor is positioned in an “aggregated” manner primarily in the spine head and to some extent in the neck, while DARPP-32 forms several neighboring small nanoclusters spanning the whole spine structure. The DARPP-32 clusters have a mean size of 52 +/- 6 nm, which is close to the resolution limit of the microscope and corresponds to the physical size of a few individual phosphoprotein immunocomplexes. Dissection of synaptic proteins using superresolution microscopy gives possibilities to reveal in better detail biologically relevant information, as compared to diffraction-limited microscopy. In this work, the dissected postsynaptic topology of the DARPP-32 phosphoprotein provides strong evidence for a compartmentalized and confined distribution in dendritic spines. The protein topology and the relatively low copy number of phosphoprotein provides a conception of DARPP-32’s possibilities to fine-tune the regulation of synaptic signaling, which should have an impact on the performance of the neuronal circuits in which it is expressed.

SLC10A4 is a vesicular amine-associated transporter modulating dopamine homeostasis.

BACKGROUND The neuromodulatory transmitters, biogenic amines, have profound effects on multiple neurons and are essential for normal behavior and mental health. Here we report that the orphan transporter SLC10A4, which in the brain is exclusively expressed in presynaptic vesicles of monoaminergic and cholinergic neurons, has a regulatory role in dopamine homeostasis. METHODS We used a combination of molecular and behavioral analyses, pharmacology, and in vivo amperometry to assess the role of SLC10A4 in dopamine-regulated behaviors. RESULTS We show that SLC10A4 is localized on the same synaptic vesicles as either vesicular acetylcholine transporter or vesicular monoamine transporter 2. We did not find evidence for direct transport of dopamine by SLC10A4; however, synaptic vesicle preparations lacking SLC10A4 showed decreased dopamine vesicular uptake efficiency. Furthermore, we observed an increased acidification in synaptic vesicles isolated from mice overexpressing SLC10A4. Loss of SLC10A4 in mice resulted in reduced striatal serotonin, noradrenaline, and dopamine concentrations and a significantly higher dopamine turnover ratio. Absence of SLC10A4 led to slower dopamine clearance rates in vivo, which resulted in accumulation of extracellular dopamine. Finally, whereas SLC10A4 null mutant mice were slightly hypoactive, they displayed hypersensitivity to administration of amphetamine and tranylcypromine. CONCLUSIONS Our results demonstrate that SLC10A4 is a vesicular monoaminergic and cholinergic associated transporter that is important for dopamine homeostasis and neuromodulation in vivo. The discovery of SLC10A4 and its role in dopaminergic signaling reveals a novel mechanism for neuromodulation and represents an unexplored target for the treatment of neurological and mental disorders.