Tilman E. Schäffer’s research while affiliated with University of Tübingen and other places

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Publications (145)


Hemin induces platelet death via furin. (A) Percentage of AnnexinV‐positive cells activated for 30 min with hemin (12.5 or 25 μM) or C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) and the effects of pretreatment (10 min) with furin inhibitor SSM3 (25 μM) measured by flow cytometry; plotted: Mean ± SD; n = 6; statistics: RM one‐way ANOVA; *p < .05; **p < .01; Normality of the data was assessed using the Shapiro–Wilk test prior to statistical analysis. (B) Flow cytometry analysis of reduction of mitochondrial membrane potential (ΔΨm) induced by hemin (12.5 and 25 μM) in comparison to C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) and the effects of furin inhibitor SSM3 (25 μM) using TMRE; plotted: Mean ± SD; n = 6; statistics: RM one‐way ANOVA; *p < .05; ****p < .0001; Normality of the data was assessed using the Shapiro–Wilk test prior to statistical analysis. (C) Generation of reactive oxygen species induced by hemin (3.1 or 6.25 μM) in comparison to C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) and the effects of furin inhibitor SSM3 (25 μM) measured by flow cytometry using H2DCFDA as a ROS‐indicator; plotted: Mean ± SD; n = 4; statistics: One‐way Kruskal–Wallis ANOVA; *p < .05; **p < .01. (D) Representative intracellular Ca²⁺ release measurement after hemin (3.1 μM) or C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) stimulation analyzed by fluorescent dye Fluo‐4 AM with plate reader (GloMax®‐Multi Detection System) and statistical analysis (right) of the area under the curve (AUC); plotted: Mean ± SD; n = 6; statistics: RM one‐way ANOVA; *p < .05; **p < .01; Normality of the data was assessed using the Shapiro–Wilk test prior to statistical analysis.
Inhibition of furin modulates changes of hemin‐dependent platelet phenotype. (A) Multi‐color flow cytometric analysis (anti‐CD42b, PAC‐1, AnnexinV) of concentration and time‐dependent platelet subtypes after hemin (3.1; 6.25; 12.5 and 25 μM) or C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) stimulation measured every 5 min. Subtype distribution in percent as stacked bar graphs. Subtypes: Resting (CD42⁺, PAC‐1⁻, AnnexinV⁻), aggregatory (CD42b⁺, PAC‐1⁺, AnnexinV⁻), procoagulant (CD42b⁺, PAC‐1⁻, AnnexinV⁺), cell‐death (CD42b⁻, PAC‐1⁻, AnnexinV⁺), N/A: Remaining combinations; Plotted: N = 4. (B and C) Modulatory effect of preincubation (10 min) with furin inhibitor SSM3 (25 μM) on hemin and C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) induced platelet subpopulations after 45 min of incubation measured by flow cytometry; plotted: Mean ± SD; n = 4; statistics: Mann–Whitney U test; *p < .05, **p < .01.
Hemin‐induced changes in platelet lipidome is attenuated by furin inhibition. (A) Measurement of platelet lipid peroxidation via BODIPY C11 as a lipid peroxidation sensor after hemin (12.5 or 25 μM) or C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) stimulation with or without preincubation of 25 μM SSM3. Decrease of BODIPY C11 signal indicates increased lipid peroxidation; plotted: Mean ± SD; n = 6; statistics: RM one‐way ANOVA; *p < .05; **p < .01; ***p < .001; Normality of the data was assessed using the Shapiro–Wilk test prior to statistical analysis. (B) Heat map summarizing all measured oxylipins after z‐score normalization detected in a mass spectrometry approach and their alterations under hemin stimulation (3.1 and 25 μM) as well as the effect of preincubation with 25 μM SSM3, plotted: N = 8. (C and D) Detailed analysis of oxylipins and their precursor arachidonic acid (AA) after hemin stimulation. (C) Low hemin concentration (3.1 μM) does not significantly change platelet oxylipins. (D) Analysis of oxylipin alterations following stimulation with high hemin concentration (25 μM) as well as the attenuating effect of preincubation with 25 μM SSM3; (C and D) plotted: Mean ± SD; n ≥7; statistics: Ordinary one‐way ANOVA; ns not significant, *p < .05; **p < .01; ***p < .001; ****p < .0001; Normality of the data was assessed using the Shapiro–Wilk test prior to statistical analysis.
Hemin‐induced disintegration of platelet plasma membrane is mitigated by furin inhibition. (A) Sample images of typical platelet topography (upper row) and stiffness (middle row) of spread platelets activated with various hemin concentrations or C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) captured by scanning ion conductance microscopy (SICM) and equivalent morphologies acquired by differential interference contrast microscopy (lower row). Scale bar = 5 μm. Analysis revealed four distinct morphological phenotypes (spread platelets, ballooning platelets, platelets with microvesicle generation, ferroptotic residuals). Stacked bar graphs show morphological subtype distribution in percent depending on type of stimulation. Statistical analysis of platelets topography and stiffness depending on their morphological subtype; plotted: Mean ± SD; n ≥3; statistics: One‐way Kruskal–Wallis ANOVA; *p < .05; **p < .01; ***p < .001. (B) Sample images of F‐actin staining using phalloidin Alexa 488 with platelets spread on fibrinogen after activation with hemin (6.25 or 25 μM) or C&T (5 μg/mL CRP‐XL; thrombin 0.1 U/mL) with or without preincubation of furin inhibitor SSM3 (25 μM). Scale bar = 5 μm. Statistical analysis of the F‐actin area [μm²] per platelet; plotted: Mean ± SD; n = 4; statistics: Mann–Whitney U test; ns not significant, *p < .05. (C) Flow cytometry analysis of platelet‐derived microvesicle defined as events smaller than 1 μM induced by hemin (12.5 or 25 μM) and C&T (5 μg/mL CRP‐XL; 0.1 U/mL thrombin) with or without preincubation of furin inhibitor SSM3 (25 μM); plotted: Mean ± SD; n ≥3; statistics: Mixed‐effects analysis; ns not significant; *p < .05; ***p < .001. Normality of the data was assessed using the Shapiro–Wilk test prior to statistical analysis. (D) Light transmission aggregometry measurements of washed platelets activated with isolated HPMV; plotted: Mean ± SD; n = 5; statistics: Mann–Whitney U test; **p < .01. (E) Representative fluorescence microscopy images of ex vivo thrombus formation stained with DiOC6 (upper row, scale = 200 μm) and corresponding intensity surface plots (lower row). Isolated human platelets were perfused over a collagen‐coated surface (100 μg/mL) for 15 min at a shear rate of 500 s⁻¹ after activation with or without isolated HPMVs. Statistical analysis of thrombus coverage; plotted: Mean ± SD; n = 4; statistics: Mann–Whitney U test; *p < .05. (F) Representative fluorescence microscopy images of ex vivo thrombus formation stained with DiOC6 (upper row, scale = 50 μm), corresponding intensity surface plots (lower row) and statistical analysis (right). Whole blood was perfused over a collagen‐coated surface (100 μg/mL) for 15 min at a shear rate of 1000 s⁻¹ after 5 min incubation with or without isolated HPMVs. Statistical analysis of thrombus coverage; plotted: Mean ± SD; n = 6; statistics: Mann–Whitney U test; **p < .01. (G) Representative fluorescence microscopy images of ex vivo thrombus formation stained with DiOC6 (left, scale = 200 μm) and statistical analysis (right). Whole blood was perfused over a collagen‐coated surface (100 μg/mL) for 15 min at a shear rate of 1000 s⁻¹ after 5 min incubation with autologous hemin‐activated washed platelets (25 μM hemin) or unstimulated washed platelets (control). Statistical analysis of thrombus coverage; plotted: Mean ± SD; n = 4; statistics: Mann–Whitney U test; *p < .05.
Hemin promotes platelet activation and plasma membrane disintegration regulated by the subtilisin‐like proprotein convertase furin
  • Article
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November 2024

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Platelet activation plays a critical role in thrombosis and hemostasis. Several pathophysiological situations lead to hemolysis, resulting in the liberation of free ferric iron‐containing hemin. Hemin has been shown to activate platelets and induce thrombo‐inflammation. Classical antiplatelet therapy failed to prevent hemin‐induced platelet activation. Thus, the aim of the present study was to characterize the mechanism of hemin‐induced platelet death (ferroptosis). We evaluated the in vitro effect of hemin on platelet activation, signaling, oxylipins, and plasma membrane destruction using light transmission aggregometry, ex vivo thrombus formation, multiparametric flow cytometry, micro‐UHPLC mass spectrometry for oxylipin profiling, and scanning ion conductance microscopy (SICM). We found that hemin induces platelet cell death indicated by increased ROS levels, phosphatidyl serine (PS) exposure, and loss of mitochondrial membrane potential (ΔΨm). Further, hemin causes lipid peroxidation and generation of distinct oxylipins, which strongly affects plasma membrane integrity leading to generation of platelet‐derived microvesicles. Interestingly, hemin‐dependent platelet death (ferroptosis) is specifically regulated by the subtilisin‐like proprotein convertase furin. In summary, platelet undergo a non‐apoptotic cell death mediated by furin. Inhibition of furin may offer a therapeutic strategy to control hemin‐induced thrombosis and thrombo‐inflammation at a site of hemolysis.

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Targeting Cyclophilin A in the Cardiac Microenvironment Preserves Heart Function and Structure in Failing Hearts

August 2024

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55 Reads

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1 Citation

Circulation Research

BACKGROUND Cardiac hypertrophy is characterized by remodeling of the myocardium, which involves alterations in the ECM (extracellular matrix) and cardiomyocyte structure. These alterations critically contribute to impaired contractility and relaxation, ultimately leading to heart failure. Emerging evidence implicates that extracellular signaling molecules are critically involved in the pathogenesis of cardiac hypertrophy and remodeling. The immunophilin CyPA (cyclophilin A) has been identified as a potential culprit. In this study, we aimed to unravel the interplay between eCyPA (extracellular CyPA) and myocardial dysfunction and evaluate the therapeutic potential of inhibiting its extracellular accumulation to improve heart function. METHODS Employing a multidisciplinary approach encompassing in silico, in vitro, in vivo, and ex vivo experiments we studied a mouse model of cardiac hypertrophy and human heart specimen to decipher the interaction of CyPA and the cardiac microenvironment in highly relevant pre-/clinical settings. Myocardial expression of CyPA (immunohistology) and the inflammatory transcriptome (NanoString) was analyzed in human cardiac tissue derived from patients with nonischemic, noninflammatory congestive heart failure (n=187). These analyses were paralleled by a mouse model of Ang (angiotensin) II–induced heart failure, which was assessed by functional (echocardiography), structural (immunohistology, atomic force microscopy), and biomolecular (Raman spectroscopy) analyses. The effect of inhibiting eCyPA in the cardiac microenvironment was evaluated using a newly developed neutralizing anti-eCyPA monoclonal antibody. RESULTS We observed a significant accumulation of eCyPA in both human and murine-failing hearts. Importantly, higher eCyPA expression was associated with poor clinical outcomes in patients ( P =0.043) and contractile dysfunction in mice (Pearson correlation coefficient, −0.73). Further, myocardial expression of eCyPA was critically associated with an increase in myocardial hypertrophy, inflammation, fibrosis, stiffness, and cardiac dysfunction in vivo. Antibody-based inhibition of eCyPA prevented (Ang II)-induced myocardial remodeling and dysfunction in mice. CONCLUSIONS Our study provides strong evidence of the pathogenic role of eCyPA in remodeling, myocardial stiffening, and dysfunction in heart failure. The findings suggest that antibody-based inhibition of eCyPA may offer a novel therapeutic strategy for nonischemic heart failure. Further research is needed to evaluate the translational potential of these interventions in human patients with cardiac hypertrophy.


Chiral Electrokinetic Phenomena in Single Nanopores

August 2024

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13 Reads

Electroanalysis

The arrangement of solvent molecules and ions at solid–liquid interfaces determines electrochemical properties that are important in separations platforms, sensing technologies, and energy‐storage systems. Here we show that single glass and polymer pores in contact with propylene carbonate (PC) solutions of LiClO 4 exhibit an effective surface potential that is modulated by the enantiomeric excess of the solvent. In particular, electrochemical and electrokinetic measurements of ionic transport through glass pipettes and polymer pores reveal that the effective surface potential is significantly lower in solutions prepared using enantiomerically pure PC than in solutions prepared using racemic PC. Both pore systems became positively charged in all racemic solutions examined in the range of LiClO 4 concentrations between 1 mM and 100 mM, whereas solutions in ( R )‐(+)‐PC induced a positive surface potential only at concentrations above ~5 mM. The effective surface potential is quantified through asymmetry in current–voltage curves and zeta‐potential measurements. Vibrational sum‐frequency‐generation experiments on LiClO 4 solutions in racemic and enantiomerically pure PC indicate that the surface lipid‐bilayer‐like region in the former is more strongly organized than in the latter, dictating the favorable positions for lithium and perchlorate ions in each case. The more ordered molecular packing in the racemic liquid leads to accumulation of lithium ions on the outside of the bilayer, creating a higher effective positive charge. Our results highlight the extreme sensitivity of the interfacial potential on molecular organization of the solvent, and the relatively unexplored role that chirality can play in electrokinetic phenomena.


Mechanical Implications of Cellular Viscoelasticity, Cortex Polarity, Superelasticity, and Cell-Cell Junctions in Curved Tissues

August 2024

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63 Reads

Investigations of the response of curved epithelia derived from MDCK-II cells to external deformation involved indentation-relaxation experiments using colloidal probe microscopy. Notably, hemicysts exhibited lower tissue tension, greater compliance, and increased fluidity compared to cysts. The primary response to deformation turned out to be the in-plane expansion of the basal cortex/membrane of cells. Additionally, drug treatments applied to curved tissue, along with deformation of tailored mutants (such as E-cadherin knockout), revealed that tissue compliance over short time scales is influenced by an interplay of viscoelastic properties in individual cells, their apical-basal polarity, superelasticity of the shell, and excess interfacial area. Meanwhile, tissue resilience predominantly depends on the integrity of cell-cell contacts.


Figure S1: (A) Ion current as a function of the z-position. The current decreases with a decreasing pipette-sample distance. The dashed lines indicate the current drop at 99.5% of the saturation current I0 with the corresponding z-position. (B) High-resolution topography image of a platelet and its height profile along the dashed line. (C) HS-SICM platelet volume distributions for 3 individual donors and log-normal fit (black dashed curves). (D) Comparison of MPV and PDW measurements using HS-SICM and a cell counter (gold standard). The MPV and the PDW calculated from the HS-SICM data on washed platelets are in good agreement (within 10-25% deviation) with the values from the cell counter (data acquired from whole blood). (E) Imaging speed improvement (factor 2.5) by reducing the number of pixels on the substrate. (F) Saturation ion current I0 as a function of time before and after the exchange of the isotonic buffer solution with a hypotonic buffer solution with 40% H2O at t = 0 s.
Figure S2: (A) Platelet topography image series of Figure 1C showing more frames at the used frame rate of 7 s/frame. A hypotonic shock with 40% H2O was induced at time t = 0. (B-E) Volume-vs-time curves of individual platelets at different osmotic shock conditions (B: 10% H2O; C: 20% H2O; D: 30% H2O; E: 152 mM sorbitol).
Figure S3: (A) Swelling time ts for a hypotonic shock with different osmolarities. (B) Swelling rate as a function of the initial volume V0, showing a linear correlation. (C) Swelling rate (left) and regulation rate (right) of small (V0 < 12 fL) and large (V0 ≥ 12 fL) platelets, at a hypotonic shock with 40% H2O. (D) Relative regulated volume ΔVreg / V0 for different H2O percentages. (E) Relative area (Ap / A0) at t = ts for different H2O percentages, with initial area A0. (F) Platelet topography image after hypotonic shock with 80% H2O showing the formation of a filopodium (arrow). (G) Topography image series of a platelet showing filopodia formation (t = 376 s), see Supplementary Movie 3 for the complete image sequence. A hypotonic shock with 80% H2O was induced at time t = 0.
Figure S4: (A) Representative SICM topography overview image of platelets on collagen fibers (left) with a zoom-in to a single platelet (right). (B) Relative volume-vs-time of representative individual platelets (dashed lines) during a hypotonic shock for cytoD-treated platelets. Solid lines and shaded areas represent the mean and standard deviation, respectively, of all measured cytoD-treated platelets. (C) Average relative platelet volume (V / V0) vs. time during addition of cytoD at t = -10 min and hypotonic shock with 40% H2O at t = 0 (N = 21). (D) Average relative platelet volume (V / V0) vs. time during addition of DMSO at t = 0 min (N = 19), as a control for the cytoD measurements. Error bars denote standard deviation. (E) Regulated volume ΔVreg for normal (untreated) and cytoD-treated platelets. (F) Variation σ of the relative end volume Vend / V0 for normal and cytoD-treated platelets. Error bars denote the SESD. (G) Initial volume V0 and (H) relative peak volume Vp / V0. Significance in (F) was determined using the F-test.
Figure S5: (A) Non-osmotic volume (green slope corresponds to a non-osmotic fraction of 0.33 ± 0.01 that is independent of V0) and (B) non-osmotic fraction vs. the initial volume V0 for all measured normal platelets.
Volume Regulation and Non-Osmotic Volume of Individual Human Platelets Quantified by High-Speed Scanning Ion Conductance Microscopy

August 2024

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30 Reads

Thrombosis and Haemostasis

Background Platelets are anucleate cells that play an important role in wound closure following vessel injury. Maintaining a constant platelet volume is critical for platelet function. For example, water-induced swelling can promote procoagulant activity and initiate thrombosis. However, techniques for measuring changes in platelet volume such as light transmittance or impedance techniques have inherent limitations as they only allow qualitative measurements or do not work on the single-cell level. Methods Here, we introduce high-speed scanning ion conductance microscopy (HS-SICM) as a new platform for studying volume regulation mechanisms of individual platelets. We optimized HS-SICM to quantitatively image the morphology of adherent platelets as a function of time at scanning speeds up to 7 seconds per frame and with 0.1 fL precision. Results We demonstrate that HS-SICM can quantitatively measure the rapid swelling of individual platelets after a hypotonic shock and the following regulatory volume decrease (RVD). We found that the RVD of thrombin-, ADP-, and collagen-activated platelets was significantly reduced compared with nonactivated platelets. Applying the Boyle–van't Hoff relationship allowed us to extract the nonosmotic volume and volume fraction on a single-platelet level. Activation by thrombin or ADP, but not by collagen, resulted in a decrease of the nonosmotic volume, likely due to a release reaction, leaving the total volume unaffected. Conclusion This work shows that HS-SICM is a versatile tool for resolving rapid morphological changes and volume dynamics of adherent living platelets.



Excessive endometrial PlGF- Rac1 signalling underlies endometrial cell stiffness linked to pre-eclampsia

May 2024

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57 Reads

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1 Citation

Communications Biology

Cell stiffness is regulated by dynamic interaction between ras-related C3 botulinum toxin substrate 1 (Rac1) and p21 protein-activated kinase 1 (PAK1) proteins, besides other biochemical and molecular regulators. In this study, we investigated how the Placental Growth Factor (PlGF) changes endometrial mechanics by modifying the actin cytoskeleton at the maternal interface. We explored the global effects of PlGF in endometrial stromal cells (EnSCs) using the concerted approach of proteomics, atomic force microscopy (AFM), and electrical impedance spectroscopy (EIS). Proteomic analysis shows PlGF upregulated RhoGTPases activating proteins and extracellular matrix organization-associated proteins in EnSCs. Rac1 and PAK1 transcript levels, activity, and actin polymerization were significantly increased with PlGF treatment. AFM further revealed an increase in cell stiffness with PlGF treatment. The additive effect of PlGF on actin polymerization was suppressed with siRNA-mediated inhibition of Rac1, PAK1, and WAVE2. Interestingly, the increase in cell stiffness by PlGF treatment was pharmacologically reversed with pravastatin, resulting in improved trophoblast cell invasion. Taken together, aberrant PlGF levels in the endometrium can contribute to an altered pre-pregnancy maternal microenvironment and offer a unifying explanation for the pathological changes observed in conditions such as pre-eclampsia (PE).




Citations (65)


... Such an approach could be used in future studies for the investigation of the influence of mechanical stretching on different cytoskeletal structures, as well as mechanosensitive transcription factors and protein kinases). [65,66] ...

Reference:

StretchView – A Multi‐Axial Cell‐Stretching Device for Long‐Term Automated Videomicroscopy of Living Cells
ERK Activation Waves Coordinate Mechanical Cell Competition Leading to Collective Elimination via Extrusion of Bacterially-Infected Cells
  • Citing Preprint
  • January 2024

... Nanopipette sensing is a versatile approach that relies on glass capillaries that have been melted and pulled to a small aperture for highly sensitive electrical measurements to study single molecules, materials, and living cells [1][2][3][4][5] . By precisely controlling the movement of the nanopipette, highresolution mapping of physical properties like topography, stiffness, permeability, and surface charge is possible [6][7][8][9][10][11][12] . Moreover, nanopipettes are used to locally control extraction and delivery processes, including sampling/delivery to single cells and surface patterning [13][14][15][16][17][18] . ...

Measuring the Shape, Stiffness, and Interface Tension of Droplets with the Scanning Ion Conductance Microscope
  • Citing Article
  • June 2024

ACS Nano

... PlGF is produced in many organs and cells including the human endometrium, decidua, placenta, uterine natural killer cells and trophoblasts cells [40]. Endometrial PlGF is higher in the proliferative phase with expression levels declining in the secretory phase, higher levels of PlGF were associated with implantation failure after IVF [41,42]. ...

Excessive endometrial PlGF- Rac1 signalling underlies endometrial cell stiffness linked to pre-eclampsia

Communications Biology

... Recent investigations have explored the roles of PPIases in various contexts, particularly in regulatory mechanisms within cellular processes [7], cancer pathways [8], neurodegeneracy [9], inflammation [10], virulence [11], stress response [12], cell cycle regulation [13], chromatin remodelling [14], regulation of transcription factors [15], and gene expression facilitated by RNA [16]. Based on substrate specificity, similarity in structural features and susceptibility to natural inhibitors, peptidyl prolyl isomerases can be categorized into three major subfamilies: cyclophilins, FK506-binding proteins (FKBPs) and parvulins [5]. ...

Cyclophilin A is a ligand for RAGE in thrombo-inflammation
  • Citing Article
  • January 2024

Cardiovascular Research

... While the in vitro stent flow chamber system introduces fluid flow and shear stress, it lacks other mechanical forces of the physiological in vivo microenvironment such as extracellular matrix stiffness or stretch 21,22 . Microthrombotic events were observed in all half devices within the region of direct contact between the strut and the glass coverslip. ...

The phosphodiesterase 2A controls lymphatic junctional maturation via cGMP-dependent notch signaling
  • Citing Article
  • December 2023

Developmental Cell

... Collagen is destroyed in the body by the action of proteolytic enzymes, such as collagenase. To slow down the biodegradation of collagen-based biomaterials and give them additional strength, various methods of chemical crosslinking of collagen are used, the most famous of which is treatment with chromium solutions [23]. ...

Characterization of the effect of chromium salts on tropocollagen molecules and molecular aggregates
  • Citing Article
  • May 2023

International Journal of Biological Macromolecules

... Here, we aim to provide a comprehensive overview of the mechanical properties of the cell-hydrogel system, with a particular focus on another prominent method-the use of scanning ion conductance microscopy (SICM). This technique is a powerful tool for investigating mechanical properties, offering high-resolution cell imaging and quantitative analysis [40][41][42]. In this study, MCF-7 breast cancer cells were chosen as a convenient and well-researched model for investigating the mechanical properties of the cell-soft hydrogel system using a novel alternative method, SICM. ...

Mechanics of migrating platelets investigated with scanning ion conductance microscopy

Nanoscale

... Such a soluble form of the protein is able to interact with intact, membrane-bound F11R/JAM-A. 31 Interactions with integrins and tetraspanins F11R/JAM-A interacts laterally with integrins and tetraspanins. At least two tetraspanins, CD9 and CD151 21,32,33, act as intermediaries in the formation of ternary complexes of F11R/JAM-A with integrins such as α3β1 or αvβ3 in endothelial or epithelial cells [32][33][34][35] or with platelet-specific αIIbβ3. ...

Homophilic Interaction Between Transmembrane-JAM-A and Soluble JAM-A Regulates Thrombo-Inflammation

JACC Basic to Translational Science

... Recent suggestions indicate that hemorrhagic complications arise not only from thrombocytopenia but also from qualitative structural and functional defects in platelets. MYH9 mutant platelets present with reduced contractile force generation and impaired clot retraction, thus leading to decreased thrombus formation and stability as well as increased bleeding tendency [57][58][59]. These inclusion bodies can be classified into types I, II, and III according to their abnormal localization pattern of NMIIA aggregates, such as number, size, and shape [62,63]. ...

Reduced platelet forces underlie impaired hemostasis in mouse models of MYH9-related disease

Science Advances

... Conventional antiplatelet drugs are insufficient to mitigate hemin-dependent platelet activation [19]. Only recently, we have defined platelet ACKR3 (formerly known as CXCR7) as inhibitory receptor on platelets [24][25][26]. Previously, we discovered that the expression of ACKR3 on the platelet plasma membrane is dynamically regulated upon activation [27,28]. Platelet ACKR3 mediates antiapoptotic effects of platelets [29,30] and loss of the receptor is associated with platelet hyperreactivity and apoptosis [25]. ...

ACKR3 regulates platelet activation and ischemia-reperfusion tissue injury