Your search keyword '"Guck, Jochen"' showing total 73 results

1. Bile Is a Selective Elevator for Mucosal Mechanics and Transport.

Author

Hanio, Simon, Möllmert, Stephanie, Möckel, Conrad, Choudhury, Susobhan, Höpfel, Andreas I., Zorn, Theresa, Endres, Sebastian, Schlauersbach, Jonas, Scheller, Lena, Keßler, Christoph, Scherf-Clavel, Oliver, Bellstedt, Peter, Schubert, Ulrich S., Pöppler, Ann-Christin, Heinze, Katrin G., Guck, Jochen, and Meinel, Lorenz

Published

2023

2. Bile Is a Selective Elevator for Mucosal Mechanics and Transport

Author

Hanio, Simon, Möllmert, Stephanie, Möckel, Conrad, Choudhury, Susobhan, Höpfel, Andreas I., Zorn, Theresa, Endres, Sebastian, Schlauersbach, Jonas, Scheller, Lena, Keßler, Christoph, Scherf-Clavel, Oliver, Bellstedt, Peter, Schubert, Ulrich S., Pöppler, Ann-Christin, Heinze, Katrin G., Guck, Jochen, and Meinel, Lorenz

Abstract

Mucus mechanically protects the intestinal epithelium and impacts the absorption of drugs, with a largely unknown role for bile. We explored the impacts of bile on mucosal biomechanics and drug transport within mucus. Bile diffused with square-root-of-time kinetics and interplayed with mucus, leading to transient stiffening captured in Brillouin images and a concentration-dependent change from subdiffusive to Brownian-like diffusion kinetics within the mucus demonstrated by differential dynamic microscopy. Bile-interacting drugs, Fluphenazine and Perphenazine, diffused faster through mucus in the presence of bile, while Metoprolol, a drug with no bile interaction, displayed consistent diffusion. Our findings were corroborated by rat studies, where co-dosing of a bile acid sequestrant substantially reduced the bioavailability of Perphenazine but not Metoprolol. We clustered over 50 drugs based on their interactions with bile and mucin. Drugs that interacted with bile also interacted with mucin but not vice versa. This study detailed the dynamics of mucus biomechanics under bile exposure and linked the ability of a drug to interact with bile to its abbility to interact with mucus.

Published

2023

3. IL-3 receptor signalling suppresses chronic intestinal inflammation by controlling mechanobiology and tissue egress of regulatory T cells

Author

Ullrich, Karen Anne-Marie, Derdau, Julia, Baltes, Carsten, Battistella, Alice, Rosso, Gonzalo, Uderhardt, Stefan, Schulze, Lisa Lou, Liu, Li-Juan, Dedden, Mark, Spocinska, Marta, Kainka, Lucina, Kubánková, Markéta, Mu¨ller, Tanja Martina, Schmidt, Nina-Maria, Becker, Emily, Ben Brahim, Oumaima, Atreya, Imke, Finotto, Susetta, Prots, Iryna, Wirtz, Stefan, Weigmann, Benno, López-Posadas, Rocío, Atreya, Raja, Ekici, Arif Bu¨lent, Lautenschla¨ger, Franziska, Guck, Jochen, Neurath, Markus F, and Zundler, Sebastian

Abstract

IL-3 has been reported to be involved in various inflammatory disorders, but its role in inflammatory bowel disease (IBD) has not been addressed so far. Here, we determined IL-3 expression in samples from patients with IBD and studied the impact of Il3or Il3rdeficiency on T cell-dependent experimental colitis. We explored the mechanical, cytoskeletal and migratory properties of Il3r−/−and Il3r+/+T cells using real-time deformability cytometry, atomic force microscopy, scanning electron microscopy, fluorescence recovery after photobleaching and in vitroand in vivocell trafficking assays. We observed that, in patients with IBD, the levels of IL-3 in the inflamed mucosa were increased. In vivo, experimental chronic colitis on T cell transfer was exacerbated in the absence of Il-3 or Il-3r signalling. This was attributable to Il-3r signalling-induced changes in kinase phosphorylation and actin cytoskeleton structure, resulting in increased mechanical deformability and enhanced egress of Tregs from the inflamed colon mucosa. Similarly, IL-3 controlled mechanobiology in human Tregs and was associated with increased mucosal Treg abundance in patients with IBD. Collectively, our data reveal that IL-3 signaling exerts an important regulatory role at the interface of biophysical and migratory T cell features in intestinal inflammation and suggest that this might be an interesting target for future intervention.

Published

2023

4. Caveolin-1 dolines form a distinct and rapid caveolae-independent mechanoadaptation system

Author

Lolo, Fidel-Nicolás, Walani, Nikhil, Seemann, Eric, Zalvidea, Dobryna, Pavón, Dácil María, Cojoc, Gheorghe, Zamai, Moreno, Viaris de Lesegno, Christine, Martínez de Benito, Fernando, Sánchez-Álvarez, Miguel, Uriarte, Juan José, Echarri, Asier, Jiménez-Carretero, Daniel, Escolano, Joan-Carles, Sánchez, Susana A., Caiolfa, Valeria R., Navajas, Daniel, Trepat, Xavier, Guck, Jochen, Lamaze, Christophe, Roca-Cusachs, Pere, Kessels, Michael M., Qualmann, Britta, Arroyo, Marino, and del Pozo, Miguel A.

Abstract

In response to different types and intensities of mechanical force, cells modulate their physical properties and adapt their plasma membrane (PM). Caveolae are PM nano-invaginations that contribute to mechanoadaptation, buffering tension changes. However, whether core caveolar proteins contribute to PM tension accommodation independently from the caveolar assembly is unknown. Here we provide experimental and computational evidence supporting that caveolin-1 confers deformability and mechanoprotection independently from caveolae, through modulation of PM curvature. Freeze-fracture electron microscopy reveals that caveolin-1 stabilizes non-caveolar invaginations—dolines—capable of responding to low-medium mechanical forces, impacting downstream mechanotransduction and conferring mechanoprotection to cells devoid of caveolae. Upon cavin-1/PTRF binding, doline size is restricted and membrane buffering is limited to relatively high forces, capable of flattening caveolae. Thus, caveolae and dolines constitute two distinct albeit complementary components of a buffering system that allows cells to adapt efficiently to a broad range of mechanical stimuli.

Published

2023

5. Epithelial RAC1-dependent cytoskeleton dynamics controls cell mechanics, cell shedding and barrier integrity in intestinal inflammation

Author

Martínez-Sánchez, Luz del Carmen, Ngo, Phuong Anh, Pradhan, Rashmita, Becker, Lukas-Sebastian, Boehringer, David, Soteriou, Despina, Kubankova, Marketa, Schweitzer, Christine, Koch, Tatyana, Thonn, Veronika, Erkert, Lena, Stolzer, Iris, Gu¨nther, Claudia, Becker, Christoph, Weigmann, Benno, Klewer, Monika, Daniel, Christoph, Amann, Kerstin, Tenzer, Stefan, Atreya, Raja, Bergo, Martin, Brakebusch, Cord, Watson, Alastair J M, Guck, Jochen, Fabry, Ben, Atreya, Imke, Neurath, Markus F, and López-Posadas, Rocío

Abstract

ObjectiveIncreased apoptotic shedding has been linked to intestinal barrier dysfunction and development of inflammatory bowel diseases (IBD). In contrast, physiological cell shedding allows the renewal of the epithelial monolayer without compromising the barrier function. Here, we investigated the role of live cell extrusion in epithelial barrier alterations in IBD.DesignTaking advantage of conditional GGTase and RAC1 knockout mice in intestinal epithelial cells (Pggt1biΔIECand Rac1iΔIECmice), intravital microscopy, immunostaining, mechanobiology, organoid techniques and RNA sequencing, we analysed cell shedding alterations within the intestinal epithelium. Moreover, we examined human gut tissue and intestinal organoids from patients with IBD for cell shedding alterations and RAC1 function.ResultsEpithelial Pggt1bdeletion led to cytoskeleton rearrangement and tight junction redistribution, causing cell overcrowding due to arresting of cell shedding that finally resulted in epithelial leakage and spontaneous mucosal inflammation in the small and to a lesser extent in the large intestine. Both in vivo and in vitro studies (knockout mice, organoids) identified RAC1 as a GGTase target critically involved in prenylation-dependent cytoskeleton dynamics, cell mechanics and epithelial cell shedding. Moreover, inflamed areas of gut tissue from patients with IBD exhibited funnel-like structures, signs of arrested cell shedding and impaired RAC1 function. RAC1 inhibition in human intestinal organoids caused actin alterations compatible with arresting of cell shedding.ConclusionImpaired epithelial RAC1 function causes cell overcrowding and epithelial leakage thus inducing chronic intestinal inflammation. Epithelial RAC1 emerges as key regulator of cytoskeletal dynamics, cell mechanics and intestinal cell shedding. Modulation of RAC1 might be exploited for restoration of epithelial integrity in the gut of patients with IBD.

Published

2023

6. Estimation of the mass density of biological matter from refractive index measurements

Author

Möckel, Conrad, Beck, Timon, Kaliman, Sara, Abuhattum, Shada, Kim, Kyoohyun, Kolb, Julia, Wehner, Daniel, Zaburdaev, Vasily, and Guck, Jochen

Abstract

The quantification of physical properties of biological matter gives rise to novel ways of understanding functional mechanisms. One of the basic biophysical properties is the mass density (MD). It affects the dynamics in sub-cellular compartments and plays a major role in defining the opto-acoustical properties of cells and tissues. As such, the MD can be connected to the refractive index (RI) via the well known Lorentz-Lorenz relation, which takes into account the polarizability of matter. However, computing the MD based on RI measurements poses a challenge, as it requires detailed knowledge of the biochemical composition of the sample. Here we propose a methodology on how to account for assumptions about the biochemical composition of the sample and respective RI measurements. To this aim, we employ the Biot mixing rule of RIs alongside the assumption of volume additivity to find an approximate relation of MD and RI. We use Monte-Carlo simulations and Gaussian propagation of uncertainty to obtain approximate analytical solutions for the respective uncertainties of MD and RI. We validate this approach by applying it to a set of well-characterized complex mixtures given by bovine milk and intralipid emulsion and employ it to estimate the MD of living zebrafish (Danio rerio) larvae trunk tissue. Our results illustrate the importance of implementing this methodology not only for MD estimations but for many other related biophysical problems, such as mechanical measurements using Brillouin microscopy and transient optical coherence elastography.

Published

2024

7. Omega-3 supplementation changes the physical properties of leukocytes but not erythrocytes in healthy individuals: An exploratory trial.

Author

Schuchardt, Jan Philipp, Kräter, Martin, Schlögel, Maximilian, Guck, Jochen, van Oirschot-Hermans, Brigitte A., Bos, Jennifer, van Wijk, Richard, Tintle, Nathan L, Westra, Jason, Kerlikowsky, Felix, Hahn, Andreas, and Harris, William S.

Abstract

• First investigation of the effect of fish oil supplementation on the physical properties of blood cells using deformability cytometry (DC). • No effect on red blood cell deformability in healthy adults using Lorrca and DC. • Changes in deformability properties of monocytes, neutrophils, and lymphocytes. • Results suggest that leukocytes become softer and deform under hydrodynamic force in circulation. n3-PUFA impact health in several ways, including cardiovascular protection and anti-inflammatory effects, but the underlying mechanisms are not fully understood. In this exploratory study involving 31 healthy subjects, we aimed to investigate the effects of 12 weeks of fish-oil supplementation (1500 mg EPA+DHA/day) on the physical properties of multiple blood cell types. We used deformability cytometry (DC) for all cell types and Laser-assisted Optical Rotational Red Cell Analysis (Lorrca) to assess red blood cell (RBC) deformability. We also investigated the correlation between changes in the physical properties of blood cells and changes in the Omega-3 Index (O3I), defined as the relative content of EPA+DHA in RBCs. Following supplementation, the mean±SD O3I increased from 5.3 %±1.5 % to 8.3 %±1.4 % (p < 0.001). No significant changes in RBC properties were found by both techniques. However, by DC we observed a consistent pattern of physical changes in lymphocytes, neutrophils and monocytes. Among these were significant increases in metrics correlated with the cells' deformability resulting in less stiff cells. The results suggest that leukocytes become softer and have an increased ability to deform under induced short-term physical stress such as hydrodynamic force in the circulation. These changes could impact immune function since softer leukocytes can potentially circulate more easily and could facilitate a more rapid response to systemic inflammation or infection. In conclusion, fish-oil supplementation modulates some physical properties of leukocyte-subfractions, potentially enhancing their biological function. Further studies are warranted to explore the impact of n3-PUFA on blood cell biology, particularly in disease states associated with leukocyte dysregulation. [ABSTRACT FROM AUTHOR]

Published

2024

8. p21 Prevents the Exhaustion of CD4+ T Cells Within the Antitumor Immune Response Against Colorectal Cancer.

Author

Thoma, Oana-Maria, Naschberger, Elisabeth, Kubánková, Markéta, Larafa, Imen, Kramer, Viktoria, Menchicchi, Bianca, Merkel, Susanne, Britzen-Laurent, Nathalie, Jefremow, André, Grützmann, Robert, Koop, Kristina, Neufert, Clemens, Atreya, Raja, Guck, Jochen, Stürzl, Michael, Neurath, Markus F., and Waldner, Maximilian J.

Abstract

T cells are crucial for the antitumor response against colorectal cancer (CRC). T-cell reactivity to CRC is nevertheless limited by T-cell exhaustion. However, molecular mechanisms regulating T-cell exhaustion are only poorly understood. We investigated the functional role of cyclin-dependent kinase 1a (Cdkn1a or p21) in cluster of differentiation (CD) 4+ T cells using murine CRC models. Furthermore, we evaluated the expression of p21 in patients with stage I to IV CRC. In vitro coculture models were used to understand the effector function of p21-deficient CD4+ T cells. We observed that the activation of cell cycle regulator p21 is crucial for CD4+ T-cell cytotoxic function and that p21 deficiency in type 1 helper T cells (Th1) leads to increased tumor growth in murine CRC. Similarly, low p21 expression in CD4+ T cells infiltrated into tumors of CRC patients is associated with reduced cancer-related survival. In mouse models of CRC, p21-deficient Th1 cells show signs of exhaustion, where an accumulation of effector/effector memory T cells and CD27/CD28 loss are predominant. Immune reconstitution of tumor-bearing Rag1−/− mice using ex vivo-treated p21-deficient T cells with palbociclib, an inhibitor of cyclin-dependent kinase 4/6, restored cytotoxic function and prevented exhaustion of p21-deficient CD4+ T cells as a possible concept for future immunotherapy of human disease. Our data reveal the importance of p21 in controlling the cell cycle and preventing exhaustion of Th1 cells. Furthermore, we unveil the therapeutic potential of cyclin-dependent kinase inhibitors such as palbociclib to reduce T-cell exhaustion for future treatment of patients with colorectal cancer. [Display omitted] Gate-keeper p21 is important for preventing cluster of differentiation 4-positive T-cell exhaustion in colorectal cancer. Targeting the cell cycle machinery in cluster of differentiation 4-positive T cells might improve their antitumor response. [ABSTRACT FROM AUTHOR]

Published

2024

9. HIF2α is a direct regulator of neutrophil motility

Author

Sormendi, Sundary, Deygas, Mathieu, Sinha, Anupam, Bernard, Mathilde, Krüger, Anja, Kourtzelis, Ioannis, Le Lay, Gregoire, Sáez, Pablo J., Gerlach, Michael, Franke, Kristin, Meneses, Ana, Kräter, Martin, Palladini, Alessandra, Guck, Jochen, Coskun, Ünal, Chavakis, Triantafyllos, Vargas, Pablo, and Wielockx, Ben

Abstract

Orchestrated recruitment of neutrophils to inflamed tissue is essential during the initiation of inflammation. Inflamed areas are usually hypoxic, and adaptation to reduced oxygen pressure is typically mediated by hypoxia pathway proteins. However, it remains unclear how these factors influence the migration of neutrophils to and at the site of inflammation during their transmigration through the blood-endothelial cell barrier, as well as their motility in the interstitial space. Here, we reveal that activation of hypoxia-inducible factor 2 (HIF2α) as a result of a deficiency in HIF prolyl hydroxylase domain protein 2 (PHD2) boosts neutrophil migration specifically through highly confined microenvironments. In vivo, the increased migratory capacity of PHD2-deficient neutrophils resulted in massive tissue accumulation in models of acute local inflammation. Using systematic RNA sequencing analyses and mechanistic approaches, we identified RhoA, a cytoskeleton organizer, as the central downstream factor that mediates HIF2α-dependent neutrophil motility. Thus, we propose that the novel PHD2-HIF2α-RhoA axis is vital to the initial stages of inflammation because it promotes neutrophil movement through highly confined tissue landscapes.

Published

2021

10. Rapid computational cell-rotation around arbitrary axes in 3D with multi-core fiber

Author

Sun, Jiawei, Koukourakis, Nektarios, Guck, Jochen, and Czarske, Jürgen W.

Abstract

Optical trapping is a vital tool in biology, allowing precise optical manipulation of nanoparticles, micro-robots, and cells. Due to the low risk of photodamage and high trap stiffness, fiber-based dual-beam traps are widely used for optical manipulation of large cells. Besides trapping, advanced applications like 3D refractive index tomography need a rotation of cells, which requires precise control of the forces, for example, the acting-point of the forces and the intensities in the region of interest (ROI). A precise rotation of large cells in 3D about arbitrary axes has not been reported yet in dual-beam traps. We introduce a novel dual-beam optical trap in which a multi-core fiber (MCF) is transformed to a phased array, using wavefront shaping and computationally programmable light. The light-field distribution in the trapping region is holographically controlled within 0.1 s, which determines the orientation and the rotation axis of the cell with small retardation. We demonstrate real-time controlled rotation of HL60 cells about all 3D axes with a very high degree of freedom by holographic controlled light through an MCF with a resolution close to the diffraction limit. For the first time, the orientation of the cell can be precisely controlled about all 3D axes in a dual-beam trap. MCFs provide much higher flexibility beyond the bulky optics, enabling lab-on-a-chip applications and can be easily integrated for applications like contactless cell surgery, refractive index tomography, cell-elasticity measurement, which require precise 3D manipulation of cells.

Published

2021

11. A buoyant nucleus is a universal characteristic of eukaryotic cells

Author

Biswas, Abin, Kim, Kyoohyun, Munoz, Omar, Zaburdaev, Vasily, Reber, Simone, and Guck, Jochen

Published

2024

12. The Relative Densities of Cytoplasm and Nuclear Compartments Are Robust against Strong Perturbation

Author

Kim, Kyoohyun and Guck, Jochen

Abstract

The cell nucleus is a compartment in which essential processes such as gene transcription and DNA replication occur. Although the large amount of chromatin confined in the finite nuclear space could install the picture of a particularly dense organelle surrounded by less dense cytoplasm, recent studies have begun to report the opposite. However, the generality of this newly emerging, opposite picture has so far not been tested. Here, we used combined optical diffraction tomography and epi-fluorescence microscopy to systematically quantify the mass densities of cytoplasm, nucleoplasm, and nucleoli of human cell lines, challenged by various perturbations. We found that the nucleoplasm maintains a lower mass density than cytoplasm during cell cycle progression by scaling its volume to match the increase of dry mass during cell growth. At the same time, nucleoli exhibited a significantly higher mass density than the cytoplasm. Moreover, actin and microtubule depolymerization and changing chromatin condensation altered volume, shape, and dry mass of those compartments, whereas the relative distribution of mass densities was generally unchanged. Our findings suggest that the relative mass densities across membrane-bound and membraneless compartments are robustly conserved, likely by different as-of-yet unknown mechanisms, which hints at an underlying functional relevance. This surprising robustness of mass densities contributes to an increasing recognition of the importance of physico-chemical properties in determining cellular characteristics and compartments.

Published

2020

13. Intelligent image-based deformation-assisted cell sorting with molecular specificity

Author

Nawaz, Ahmad Ahsan, Urbanska, Marta, Herbig, Maik, Nötzel, Martin, Kräter, Martin, Rosendahl, Philipp, Herold, Christoph, Toepfner, Nicole, Kubánková, Markéta, Goswami, Ruchi, Abuhattum, Shada, Reichel, Felix, Müller, Paul, Taubenberger, Anna, Girardo, Salvatore, Jacobi, Angela, and Guck, Jochen

Abstract

Although label-free cell sorting is desirable for providing pristine cells for further analysis or use, current approaches lack molecular specificity and speed. Here, we combine real-time fluorescence and deformability cytometry with sorting based on standing surface acoustic waves and transfer molecular specificity to image-based sorting using an efficient deep neural network. In addition to general performance, we demonstrate the utility of this method by sorting neutrophils from whole blood without labels.

Published

2020

14. A comparison of microfluidic methods for high-throughput cell deformability measurements

Author

Urbanska, Marta, Muñoz, Hector E., Shaw Bagnall, Josephine, Otto, Oliver, Manalis, Scott R., Di Carlo, Dino, and Guck, Jochen

Abstract

The mechanical phenotype of a cell is an inherent biophysical marker of its state and function, with many applications in basic and applied biological research. Microfluidics-based methods have enabled single-cell mechanophenotyping at throughputs comparable to those of flow cytometry. Here, we present a standardized cross-laboratory study comparing three microfluidics-based approaches for measuring cell mechanical phenotype: constriction-based deformability cytometry (cDC), shear flow deformability cytometry (sDC) and extensional flow deformability cytometry (xDC). All three methods detect cell deformability changes induced by exposure to altered osmolarity. However, a dose-dependent deformability increase upon latrunculin B-induced actin disassembly was detected only with cDC and sDC, which suggests that when exposing cells to the higher strain rate imposed by xDC, cellular components other than the actin cytoskeleton dominate the response. The direct comparison presented here furthers our understanding of the applicability of the different deformability cytometry methods and provides context for the interpretation of deformability measurements performed using different platforms.

Published

2020

15. Image-based cell sorting using artificial intelligence

Author

Tsia, Kevin K., Goda, Keisuke, Herbig, Maik, Nawaz, Ahmad Ahsan, Urbanska, Marta, Nötzel, Martin, Kräter, Martin, Rosendahl, Philipp, Herold, Christoph, Töpfner, Nicole, Kubankova, Marketa, Goswami, Ruchi, Abuhattum, Shada, Reichel, Felix, Müller, Paul, Taubenberger, Anna, Girardo, Salvatore, Jacobi, Angela, and Guck, Jochen

Published

2020

16. Zebrafish Spinal Cord Repair Is Accompanied by Transient Tissue Stiffening

Author

Möllmert, Stephanie, Kharlamova, Maria A., Hoche, Tobias, Taubenberger, Anna V., Abuhattum, Shada, Kuscha, Veronika, Kurth, Thomas, Brand, Michael, and Guck, Jochen

Abstract

Severe injury to the mammalian spinal cord results in permanent loss of function due to the formation of a glial-fibrotic scar. Both the chemical composition and the mechanical properties of the scar tissue have been implicated to inhibit neuronal regrowth and functional recovery. By contrast, adult zebrafish are able to repair spinal cord tissue and restore motor function after complete spinal cord transection owing to a complex cellular response that includes axon regrowth and is accompanied by neurogenesis. The mechanical mechanisms contributing to successful spinal cord repair in adult zebrafish are, however, currently unknown. Here, we employ atomic force microscopy-enabled nanoindentation to determine the spatial distributions of apparent elastic moduli of living spinal cord tissue sections obtained from uninjured zebrafish and at distinct time points after complete spinal cord transection. In uninjured specimens, spinal gray matter regions were stiffer than white matter regions. During regeneration after transection, the spinal cord tissues displayed a significant increase of the respective apparent elastic moduli that transiently obliterated the mechanical difference between the two types of matter before returning to baseline values after the completion of repair. Tissue stiffness correlated variably with cell number density, oligodendrocyte interconnectivity, axonal orientation, and vascularization. This work constitutes the first quantitative mapping of the spatiotemporal changes of spinal cord tissue stiffness in regenerating adult zebrafish and provides the tissue mechanical basis for future studies into the role of mechanosensing in spinal cord repair.

Published

2020

17. High-Throughput Microfluidic Characterization of Erythrocyte Shapes and Mechanical Variability

Author

Reichel, Felix, Mauer, Johannes, Nawaz, Ahmad Ahsan, Gompper, Gerhard, Guck, Jochen, and Fedosov, Dmitry A.

Abstract

The motion of red blood cells (RBCs) in microchannels is important for microvascular blood flow and biomedical applications such as blood analysis in microfluidics. The current understanding of the complexity of RBC shapes and dynamics in microchannels is mainly based on several simulation studies, but there are a few systematic experimental investigations. Here, we present a combined study that systematically characterizes RBC behavior for a wide range of flow rates and channel sizes. Even though simulations and experiments generally show good agreement, experimental observations demonstrate that there is no single well-defined RBC state for fixed flow conditions but rather a broad distribution of states. This result can be attributed to the inherent variability in RBC mechanical properties, which is confirmed by a model that takes the variation in RBC shear elasticity into account. This represents a significant step toward a quantitative connection between RBC behavior in microfluidic devices and their mechanical properties, which is essential for a high-throughput characterization of diseased cells.

Published

2019

18. Real‐time deformability cytometry reveals sequential contraction and expansion during neutrophil priming

Author

Bashant, Kathleen R., Vassallo, Arlette, Herold, Christoph, Berner, Reinhard, Menschner, Leonhard, Subburayalu, Julien, Kaplan, Mariana J., Summers, Charlotte, Guck, Jochen, Chilvers, Edwin R., and Toepfner, Nicole

Abstract

It has become increasingly apparent that the biomechanical properties of neutrophils impact on their trafficking through the circulation and in particularly through the pulmonary capillary bed. The retention of polarized or shape‐changed neutrophils in the lungs was recently proposed to contribute to acute respiratory distress syndrome pathogenesis. Accordingly, this study tested the hypothesis that neutrophil priming is coupled to morpho‐rheological (MORE) changes capable of altering cell function. We employ real‐time deformability cytometry (RT‐DC), a recently developed, rapid, and sensitive way to assess the distribution of size, shape, and deformability of thousands of cells within seconds. During RT‐DC analysis, neutrophils can be easily identified within anticoagulated “whole blood” due to their unique granularity and size, thus avoiding the need for further isolation techniques, which affect biomechanical cell properties. Hence, RT‐DC is uniquely suited to describe the kinetics of MORE cell changes. We reveal that, following activation or priming, neutrophils undergo a short period of cell shrinking and stiffening, followed by a phase of cell expansion and softening. In some contexts, neutrophils ultimately recover their un‐primed mechanical phenotype. The mechanism(s) underlying changes in human neutrophil size are shown to be Na+/H+antiport‐dependent and are predicted to have profound implications for neutrophil movement through the vascular system in health and disease. Real‐time deformability cytometry demonstrates that primed neutrophils initially contract and then expand in a Na+/H+antiport‐dependent manner, with the latter phase associated with increased deformability.

Published

2019

19. The relationship between metastatic potential and in vitro mechanical properties of osteosarcoma cells

Author

Holenstein, Claude N., Horvath, Aron, Schär, Barbara, Schoenenberger, Angelina D., Bollhalder, Maja, Goedecke, Nils, Bartalena, Guido, Otto, Oliver, Herbig, Maik, Guck, Jochen, Müller, Daniel A., Snedeker, Jess G., and Silvan, Unai

Abstract

During cancer development, malignant cells acquire biomechanical properties that render them more competitive in the neoplastic microenvironment. We have combined the best established high- and semi-high throughput techniques to measure the morphological and mechanical properties of bone cancer cells of different malignancies.

Published

2019

20. Mechanical Mapping of Spinal Cord Growth and Repair in Living Zebrafish Larvae by Brillouin Imaging

Author

Schlüßler, Raimund, Möllmert, Stephanie, Abuhattum, Shada, Cojoc, Gheorghe, Müller, Paul, Kim, Kyoohyun, Möckel, Conrad, Zimmermann, Conrad, Czarske, Jürgen, and Guck, Jochen

Abstract

The mechanical properties of biological tissues are increasingly recognized as important factors in developmental and pathological processes. Most existing mechanical measurement techniques either necessitate destruction of the tissue for access or provide insufficient spatial resolution. Here, we show for the first time to our knowledge a systematic application of confocal Brillouin microscopy to quantitatively map the mechanical properties of spinal cord tissues during biologically relevant processes in a contact-free and nondestructive manner. Living zebrafish larvae were mechanically imaged in all anatomical planes during development and after spinal cord injury. These experiments revealed that Brillouin microscopy is capable of detecting the mechanical properties of distinct anatomical structures without interfering with the animal’s natural development. The Brillouin shift within the spinal cord remained comparable during development and transiently decreased during the repair processes after spinal cord transection. By taking into account the refractive index distribution, we explicitly determined the apparent longitudinal modulus and viscosity of different larval zebrafish tissues. Importantly, mechanical properties differed between tissues in situ and in excised slices. The presented work constitutes the first step toward an in vivo assessment of spinal cord tissue mechanics during regeneration, provides a methodical basis to identify key determinants of mechanical tissue properties, and allows us to test their relative importance in combination with biochemical and genetic factors during developmental and regenerative processes.

Published

2018

21. A comparison of methods to assess cell mechanical properties

Author

Wu, Pei-Hsun, Aroush, Dikla, Asnacios, Atef, Chen, Wei-Chiang, Dokukin, Maxim, Doss, Bryant, Durand-Smet, Pauline, Ekpenyong, Andrew, Guck, Jochen, Guz, Nataliia, Janmey, Paul, Lee, Jerry, Moore, Nicole, Ott, Albrecht, Poh, Yeh-Chuin, Ros, Robert, Sander, Mathias, Sokolov, Igor, Staunton, Jack, Wang, Ning, Whyte, Graeme, and Wirtz, Denis

Abstract

The mechanical properties of cells influence their cellular and subcellular functions, including cell adhesion, migration, polarization, and differentiation, as well as organelle organization and trafficking inside the cytoplasm. Yet reported values of cell stiffness and viscosity vary substantially, which suggests differences in how the results of different methods are obtained or analyzed by different groups. To address this issue and illustrate the complementarity of certain approaches, here we present, analyze, and critically compare measurements obtained by means of some of the most widely used methods for cell mechanics: atomic force microscopy, magnetic twisting cytometry, particle-tracking microrheology, parallel-plate rheometry, cell monolayer rheology, and optical stretching. These measurements highlight how elastic and viscous moduli of MCF-7 breast cancer cells can vary 1,000-fold and 100-fold, respectively. We discuss the sources of these variations, including the level of applied mechanical stress, the rate of deformation, the geometry of the probe, the location probed in the cell, and the extracellular microenvironment. This Analysis compares and contrasts methods for measuring the mechanical properties of cells by applying the different approaches to the same breast cancer cell line.

Published

2018

22. Real-time fluorescence and deformability cytometry

Author

Rosendahl, Philipp, Plak, Katarzyna, Jacobi, Angela, Kraeter, Martin, Toepfner, Nicole, Otto, Oliver, Herold, Christoph, Winzi, Maria, Herbig, Maik, Ge, Yan, Girardo, Salvatore, Wagner, Katrin, Baum, Buzz, and Guck, Jochen

Abstract

The throughput of cell mechanical characterization has recently approached that of conventional flow cytometers. However, this very sensitive, label-free approach still lacks the specificity of molecular markers. Here we developed an approach that combines real-time 1D-imaging fluorescence and deformability cytometry in one instrument (RT-FDC), thus opening many new research avenues. We demonstrated its utility by using subcellular fluorescence localization to identify mitotic cells and test for mechanical changes in those cells in an RNA interference screen.

Published

2018

23. Toll-Like Receptor-Mediated Upregulation of CXCL16 in Psoriasis Orchestrates Neutrophil Activation

Author

Steffen, Sabine, Abraham, Susanne, Herbig, Maik, Schmidt, Franziska, Blau, Kristin, Meisterfeld, Susann, Beissert, Stefan, Guck, Jochen, and Günther, Claudia

Abstract

Innate immune processes are central in the development of the chronic inflammatory skin disease psoriasis. Studying stimulation of keratinocytes, monocytes, and dendritic cells by type I interferons or ligation of Toll-like receptors 1/2, 2/6, or 7, but not 7/8, resulted in enhanced surface expression and secretion of CXC chemokine ligand (CXCL) 16. The corresponding CXC chemokine receptor 6 was expressed on neutrophils whose recruitment into skin is important, especially in early psoriatic disease. Using the recently developed technique real-time deformability cytometry demonstrated that CXCL16 and IL-8 decreased the stiffness and enhanced deformation of neutrophils facilitating transmigration through vessel wall. In addition, CXCL16 potently induced migration of neutrophils and enhanced the chemotactic effect of IL-8. The positive feedback loop was supported by IL-8 enhancing CXCL16 production of neutrophils. Blocking of CXCL16 expression by effective treatment of psoriasis patients with tumor necrosis factor−α blockers further supported the pathogenic role of this chemokine. In summary, the data link innate immune stimulation to CXCL16 upregulation and neutrophil infiltration into skin. CXCL16 could therefore represent a potent future target for treatment of psoriasis.

Published

2018

24. The F-actin modifier villin regulates insulin granule dynamics and exocytosis downstream of islet cell autoantigen 512.

Author

Mziaut, Hassan, Mulligan, Bernard, Hoboth, Peter, Otto, Oliver, Ivanova, Anna, Herbig, Maik, Schumann, Desiree, Hildebrandt, Tobias, Dehghany, Jaber, Sönmez, Anke, Münster, Carla, Meyer-Hermann, Michael, Guck, Jochen, Kalaidzidis, Yannis, and Solimena, Michele

Abstract

Objective Insulin release from pancreatic islet β cells should be tightly controlled to avoid hypoglycemia and insulin resistance. The cortical actin cytoskeleton is a gate for regulated exocytosis of insulin secretory granules (SGs) by restricting their mobility and access to the plasma membrane. Prior studies suggest that SGs interact with F-actin through their transmembrane cargo islet cell autoantigen 512 (Ica512) (also known as islet antigen 2/Ptprn). Here we investigated how Ica512 modulates SG trafficking and exocytosis. Methods Transcriptomic changes in Ica512 −/− mouse islets were analyzed. Imaging as well as biophysical and biochemical methods were used to validate if and how the Ica512- regulated gene villin modulates insulin secretion in mouse islets and insulinoma cells. Results The F-actin modifier villin was consistently downregulated in Ica512 −/− mouse islets and in Ica512 -depleted insulinoma cells. Villin was enriched at the cell cortex of β cells and dispersed villin −/− islet cells were less round and less deformable. Basal mobility of SGs in villin -depleted cells was enhanced. Moreover, in cells depleted either of villin or Ica512 F-actin cages restraining cortical SGs were enlarged, basal secretion was increased while glucose-stimulated insulin release was blunted. The latter changes were reverted by overexpressing villin in Ica512 -depleted cells, but not vice versa . Conclusion Our findings show that villin controls the size of the F-actin cages restricting SGs and, thus, regulates their dynamics and availability for exocytosis. Evidence that villin acts downstream of Ica512 also indicates that SGs directly influence the remodeling properties of the cortical actin cytoskeleton for tight control of insulin secretion. [ABSTRACT FROM AUTHOR]

Published

2016

25. 3D extracellular matrix interactions modulate tumour cell growth, invasion and angiogenesis in engineered tumour microenvironments.

Author

Taubenberger, Anna V., Bray, Laura J., Haller, Barbara, Shaposhnykov, Artem, Binner, Marcus, Freudenberg, Uwe, Guck, Jochen, and Werner, Carsten

Subjects

EXTRACELLULAR matrix proteins, CANCER invasiveness, NEOVASCULARIZATION, CANCER cell growth, CANCER research, MESENCHYMAL stem cells, ENDOTHELIAL cells

Abstract

Interactions between tumour cells and extracellular matrix proteins of the tumour microenvironment play crucial roles in cancer progression. So far, however, there are only a few experimental platforms available that allow us to study these interactions systematically in a mechanically defined three-dimensional (3D) context. Here, we have studied the effect of integrin binding motifs found within common extracellular matrix (ECM) proteins on 3D breast (MCF-7) and prostate (PC-3, LNCaP) cancer cell cultures, and co-cultures with endothelial and mesenchymal stromal cells. For this purpose, matrix metalloproteinase-degradable biohybrid poly(ethylene) glycol-heparin hydrogels were decorated with the peptide motifs RGD, GFOGER (collagen I), or IKVAV (laminin-111). Over 14 days, cancer spheroids of 100–200 μm formed. While the morphology of poorly invasive MCF-7 and LNCaP cells was not modulated by any of the peptide motifs, the aggressive PC-3 cells exhibited an invasive morphology when cultured in hydrogels comprising IKVAV and GFOGER motifs compared to RGD motifs or nonfunctionalised controls. PC-3 (but not MCF-7 and LNCaP) cell growth and endothelial cell infiltration were also significantly enhanced in IKVAV and GFOGER presenting gels. Taken together, we have established a 3D culture model that allows for dissecting the effect of biochemical cues on processes relevant to early cancer progression. These findings provide a basis for more mechanistic studies that may further advance our understanding of how ECM modulates cancer cell invasion and how to ultimately interfere with this process. Statement of Significance Threedimensional in vitro cancer models have generated great interest over the past decade. However, most models are not suitable to systematically study the effects of environmental cues on cancer development and progression. To overcome this limitation, we have developed an innovative hydrogel platform to study the interactions between breast and prostate cancer cells and extracellular matrix ligands relevant to the tumour microenvironment. Our results show that hydrogels with laminin- and collagen-derived adhesive peptides induce a malignant phenotype in a cell-line specific manner. Thus, we have identified a method to control the incorporation of biochemical cues within a three dimensional culture model and anticipate that it will help us in better understanding the effects of the tumour microenvironment on cancer progression. [ABSTRACT FROM AUTHOR]

Published

2016

26. Best practices for reporting throughput in biomedical research

Author

Herbig, Maik, Isozaki, Akihiro, Di Carlo, Dino, Guck, Jochen, Nitta, Nao, Damoiseaux, Robert, Kamikawaji, Shogo, Suyama, Eigo, Shintaku, Hirofumi, Wu, Angela Ruohao, Nikaido, Itoshi, and Goda, Keisuke

Published

2022

27. Initiation of acute graft-versus-host disease by angiogenesis

Author

Riesner, Katarina, Shi, Yu, Jacobi, Angela, Kräter, Martin, Kalupa, Martina, McGearey, Aleixandria, Mertlitz, Sarah, Cordes, Steffen, Schrezenmeier, Jens-Florian, Mengwasser, Jörg, Westphal, Sabine, Perez-Hernandez, Daniel, Schmitt, Clemens, Dittmar, Gunnar, Guck, Jochen, and Penack, Olaf

Abstract

The inhibition of inflammation-associated angiogenesis ameliorates inflammatory diseases by reducing the recruitment of tissue-infiltrating leukocytes. However, it is not known if angiogenesis has an active role during the initiation of inflammation or if it is merely a secondary effect occurring in response to stimuli by tissue-infiltrating leukocytes. Here, we show that angiogenesis precedes leukocyte infiltration in experimental models of inflammatory bowel disease and acute graft-versus-host disease (GVHD). We found that angiogenesis occurred as early as day+2 after allogeneic transplantation mainly in GVHD typical target organs skin, liver, and intestines, whereas no angiogenic changes appeared due to conditioning or syngeneic transplantation. The initiation phase of angiogenesis was not associated with classical endothelial cell (EC) activation signs, such as Vegfa/VEGFR1+2 upregulation or increased adhesion molecule expression. During early GVHD at day+2, we found significant metabolic and cytoskeleton changes in target organ ECs in gene array and proteomic analyses. These modifications have significant functional consequences as indicated by profoundly higher deformation in real-time deformability cytometry. Our results demonstrate that metabolic changes trigger alterations in cell mechanics, leading to enhanced migratory and proliferative potential of ECs during the initiation of inflammation. Our study adds evidence to the hypothesis that angiogenesis is involved in the initiation of tissue inflammation during GVHD.

Published

2017

28. Initiation of acute graft-versus-host disease by angiogenesis

Author

Riesner, Katarina, Shi, Yu, Jacobi, Angela, Kräter, Martin, Kalupa, Martina, McGearey, Aleixandria, Mertlitz, Sarah, Cordes, Steffen, Schrezenmeier, Jens-Florian, Mengwasser, Jörg, Westphal, Sabine, Perez-Hernandez, Daniel, Schmitt, Clemens, Dittmar, Gunnar, Guck, Jochen, and Penack, Olaf

Abstract

The inhibition of inflammation-associated angiogenesis ameliorates inflammatory diseases by reducing the recruitment of tissue-infiltrating leukocytes. However, it is not known if angiogenesis has an active role during the initiation of inflammation or if it is merely a secondary effect occurring in response to stimuli by tissue-infiltrating leukocytes. Here, we show that angiogenesis precedes leukocyte infiltration in experimental models of inflammatory bowel disease and acute graft-versus-host disease (GVHD). We found that angiogenesis occurred as early as day+2 after allogeneic transplantation mainly in GVHD typical target organs skin, liver, and intestines, whereas no angiogenic changes appeared due to conditioning or syngeneic transplantation. The initiation phase of angiogenesis was not associated with classical endothelial cell (EC) activation signs, such as Vegfa/VEGFR1+2upregulation or increased adhesion molecule expression. During early GVHD at day+2, we found significant metabolic and cytoskeleton changes in target organ ECs in gene array and proteomic analyses. These modifications have significant functional consequences as indicated by profoundly higher deformation in real-time deformability cytometry. Our results demonstrate that metabolic changes trigger alterations in cell mechanics, leading to enhanced migratory and proliferative potential of ECs during the initiation of inflammation. Our study adds evidence to the hypothesis that angiogenesis is involved in the initiation of tissue inflammation during GVHD.

Published

2017

29. Volume Transitions of Isolated Cell Nuclei Induced by Rapid Temperature Increase

Author

Chan, Chii J., Li, Wenhong, Cojoc, Gheorghe, and Guck, Jochen

Abstract

Understanding the physical mechanisms governing nuclear mechanics is important as it can impact gene expression and development. However, how cell nuclei respond to external cues such as heat is not well understood. Here, we studied the material properties of isolated nuclei in suspension using an optical stretcher. We demonstrate that isolated nuclei regulate their volume in a highly temperature-sensitive manner. At constant temperature, isolated nuclei behaved like passive, elastic and incompressible objects, whose volume depended on the pH and ionic conditions. When the temperature was increased suddenly by even a few degrees Kelvin, nuclei displayed a repeatable and reversible temperature-induced volume transition, whose sign depended on the valency of the solvent. Such phenomenon is not observed for nuclei subjected to slow heating. The transition temperature could be shifted by adiabatic changes of the ambient temperature, and the magnitude of temperature-induced volume transition could be modulated by modifying the chromatin compaction state and remodeling processes. Our findings reveal that the cell nucleus can be viewed as a highly charged polymer gel with intriguing thermoresponsive properties, which might play a role in nuclear volume regulation and thermosensing in living cells.

Published

2017

30. Mapping the mechanical heterogeneity of the brain, and why this matters (Conference Presentation)

Author

Larin, Kirill V., Sampson, David D., and Guck, Jochen R.

Published

2017

31. Niche WNT5A regulates the actin cytoskeleton during regeneration of hematopoietic stem cells

Author

Schreck, Christina, Istvánffy, Rouzanna, Ziegenhain, Christoph, Sippenauer, Theresa, Ruf, Franziska, Henkel, Lynette, Gärtner, Florian, Vieth, Beate, Florian, M. Carolina, Mende, Nicole, Taubenberger, Anna, Prendergast, Áine, Wagner, Alina, Pagel, Charlotta, Grziwok, Sandra, Götze, Katharina S., Guck, Jochen, Dean, Douglas C., Massberg, Steffen, Essers, Marieke, Waskow, Claudia, Geiger, Hartmut, Schiemann, Mathias, Peschel, Christian, Enard, Wolfgang, and Oostendorp, Robert A.J.

Abstract

Here, we show that the Wnt5a-haploinsufficient niche regenerates dysfunctional HSCs, which do not successfully engraft in secondary recipients. RNA sequencing of the regenerated donor Lin− SCA-1+ KIT+ (LSK) cells shows dysregulated expression of ZEB1-associated genes involved in the small GTPase-dependent actin polymerization pathway. Misexpression of DOCK2, WAVE2, and activation of CDC42 results in apolar F-actin localization, leading to defects in adhesion, migration and homing of HSCs regenerated in a Wnt5a-haploinsufficient microenvironment. Moreover, these cells show increased differentiation in vitro, with rapid loss of HSC-enriched LSK cells. Our study further shows that the Wnt5a-haploinsufficient environment similarly affects BCR-ABLp185 leukemia-initiating cells, which fail to generate leukemia in 42% of the studied recipients, or to transfer leukemia to secondary hosts. Thus, we show that WNT5A in the bone marrow niche is required to regenerate HSCs and leukemic cells with functional ability to rearrange the actin cytoskeleton and engraft successfully.

Published

2017

32. Mechanosensing is critical for axon growth in the developing brain

Author

Koser, David E, Thompson, Amelia J, Foster, Sarah K, Dwivedy, Asha, Pillai, Eva K, Sheridan, Graham K, Svoboda, Hanno, Viana, Matheus, Costa, Luciano da F, Guck, Jochen, Holt, Christine E, and Franze, Kristian

Abstract

During nervous system development, neurons extend axons along well-defined pathways. The current understanding of axon pathfinding is based mainly on chemical signaling. However, growing neurons interact not only chemically but also mechanically with their environment. Here we identify mechanical signals as important regulators of axon pathfinding. In vitro, substrate stiffness determined growth patterns of Xenopus retinal ganglion cell axons. In vivo atomic force microscopy revealed a noticeable pattern of stiffness gradients in the embryonic brain. Retinal ganglion cell axons grew toward softer tissue, which was reproduced in vitro in the absence of chemical gradients. To test the importance of mechanical signals for axon growth in vivo, we altered brain stiffness, blocked mechanotransduction pharmacologically and knocked down the mechanosensitive ion channel piezo1. All treatments resulted in aberrant axonal growth and pathfinding errors, suggesting that local tissue stiffness, read out by mechanosensitive ion channels, is critically involved in instructing neuronal growth in vivo.

Published

2016

33. A Nanoprinted Model of Interstitial Cancer Migration Reveals a Link between Cell Deformability and Proliferation

Author

Panagiotakopoulou, Magdalini, Bergert, Martin, Taubenberger, Anna, Guck, Jochen, Poulikakos, Dimos, and Ferrari, Aldo

Abstract

Metastatic progression of tumors requires the coordinated dissemination of cancerous cells through interstitial tissues and their replication in distant body locations. Despite their importance in cancer treatment decisions, key factors, such as cell shape adaptation and the role it plays in dense tissue invasion by cancerous cells, are not well understood. Here, we employ a 3D electrohydrodynamic nanoprinting technology to generate vertical arrays of topographical pores that mimic interstitial tissue resistance to the mesenchymal migration of cancerous cells, in order to determine the effect of nuclear size, cell deformability, and cell-to-substrate adhesion on tissue invasion efficiency. The high spatial and temporal resolution of our analysis demonstrates that the ability of cells to deform depends on the cell cycle phase, peaks immediately after mitosis, and is key to the invasion process. Increased pore penetration efficiency by cells in early G1 phase also coincided with their lower nuclear volume and higher cell deformability, compared with the later cell cycle stages. Furthermore, artificial decondensation of chromatin induced an increase in cell and nuclear deformability and improved pore penetration efficiency of cells in G1. Together, these results underline that along the cell cycle cells have different abilities to dynamically remodel their actin cytoskeleton and induce nuclear shape changes, which determines their pore penetration efficiency. Thus, our results support a mechanism in which cell proliferation and pore penetration are functionally linked to favor the interstitial dissemination of metastatic cells.

Published

2016

34. Extracting Cell Stiffness from Real-Time Deformability Cytometry: Theory and Experiment

Author

Mietke, Alexander, Otto, Oliver, Girardo, Salvatore, Rosendahl, Philipp, Taubenberger, Anna, Golfier, Stefan, Ulbricht, Elke, Aland, Sebastian, Guck, Jochen, and Fischer-Friedrich, Elisabeth

Abstract

Cell stiffness is a sensitive indicator of physiological and pathological changes in cells, with many potential applications in biology and medicine. A new method, real-time deformability cytometry, probes cell stiffness at high throughput by exposing cells to a shear flow in a microfluidic channel, allowing for mechanical phenotyping based on single-cell deformability. However, observed deformations of cells in the channel not only are determined by cell stiffness, but also depend on cell size relative to channel size. Here, we disentangle mutual contributions of cell size and cell stiffness to cell deformation by a theoretical analysis in terms of hydrodynamics and linear elasticity theory. Performing real-time deformability cytometry experiments on both model spheres of known elasticity and biological cells, we demonstrate that our analytical model not only predicts deformed shapes inside the channel but also allows for quantification of cell mechanical parameters. Thereby, fast and quantitative mechanical sampling of large cell populations becomes feasible.

Published

2015

35. Single-cell diffraction tomography with optofluidic rotation about a tilted axis

Author

Dholakia, Kishan, Spalding, Gabriel C., Müller, Paul, Schürmann, Mirjam, Chan, Chii J., and Guck, Jochen

Published

2015

36. Myosin II Activity Softens Cells in Suspension

Author

Chan, Chii J., Ekpenyong, Andrew E., Golfier, Stefan, Li, Wenhong, Chalut, Kevin J., Otto, Oliver, Elgeti, Jens, Guck, Jochen, and Lautenschläger, Franziska

Abstract

The cellular cytoskeleton is crucial for many cellular functions such as cell motility and wound healing, as well as other processes that require shape change or force generation. Actin is one cytoskeleton component that regulates cell mechanics. Important properties driving this regulation include the amount of actin, its level of cross-linking, and its coordination with the activity of specific molecular motors like myosin. While studies investigating the contribution of myosin activity to cell mechanics have been performed on cells attached to a substrate, we investigated mechanical properties of cells in suspension. To do this, we used multiple probes for cell mechanics including a microfluidic optical stretcher, a microfluidic microcirculation mimetic, and real-time deformability cytometry. We found that nonadherent blood cells, cells arrested in mitosis, and naturally adherent cells brought into suspension, stiffen and become more solidlike upon myosin inhibition across multiple timescales (milliseconds to minutes). Our results hold across several pharmacological and genetic perturbations targeting myosin. Our findings suggest that myosin II activity contributes to increased whole-cell compliance and fluidity. This finding is contrary to what has been reported for cells attached to a substrate, which stiffen via active myosin driven prestress. Our results establish the importance of myosin II as an active component in modulating suspended cell mechanics, with a functional role distinctly different from that for substrate-adhered cells.

Published

2015

37. Comparison of stresses on homogeneous spheroids in the optical stretcher computed with geometrical optics and generalized Lorenz-Mie theory.

Author

Boyde, Lars, Ekpenyong, Andrew, Whyte, Graeme, and Guck, Jochen

Published

2012

38. Exact analytical expansion of an off-axis Gaussian laser beam using the translation theorems for the vector spherical harmonics.

Author

Boyde, Lars, Chalut, Kevin J., and Guck, Jochen

Published

2011

39. Characterizing single suspended cells by optorheology.

Author

Wottawah, Falk, Schinkinger, Stefan, Lincoln, Bryan, Ebert, Susanne, Müller, Karla, Sauer, Frank, Travis, Kort, and Guck, Jochen

Subjects

CELLS, FIBROBLASTS, CYTOSKELETON, ACTIN, PROTEIN genetics

Abstract

Abstract: The measurement of the mechanical properties of individual cells has received much attention in recent years. In this paper we describe the application of optically induced forces with an optical stretcher to perform step-stress experiments on individual suspended fibroblasts. The conversion from creep-compliance to frequency-dependent complex shear modulus reveals characteristic viscoelastic signatures of the underlying cytoskeleton and its dynamic molecular properties. Both normal and cancerous fibroblasts display a single stress relaxation time in the observed time and frequency space that can be related to the transient binding of actin crosslinking proteins. In addition, shear modulus and steady-state viscosity of the shell-like actin cortex as the main module resisting small deformations are extracted. These values in combination with insight into the cells’ architecture are used to explain their different deformability. This difference can then be exploited to distinguish normal from cancerous cells. The nature of the optical stretcher as an optical trap allows easy incorporation in a microfluidic system with automatic trapping and alignment of the cells, and thus a high measurement throughput. This carries the potential for using the microfluidic optical stretcher to investigate cellular processes involving the cytoskeleton and to diagnose diseases related to cytoskeletal alterations. [Copyright &y& Elsevier]

Published

2005

40. Su095 REAL-TIME DEFORMABILITY CYTOMETRY (RT-DC) REVEALS NOVEL CORRELATIONS BETWEEN INFLAMMATION AND MECHANICAL PROPERTIES OF NEUTROPHILS IN IBD PATIENTS.

Author

Ganzleben, Ingo, Müller, Hannah, Thoma, Oana-Maria, Kubánková, Markéta, Jefremow, André, Guck, Jochen, Neurath, Markus, and Waldner, Maximilian

Published

2021

41. Chromatin Decondensation and Nuclear Softening Accompany Nanog Downregulation in Embryonic Stem Cells

Author

Chalut, Kevin J., Höpfler, Markus, Lautenschläger, Franziska, Boyde, Lars, Chan, Chii Jou, Ekpenyong, Andrew, Martinez-Arias, Alfonso, and Guck, Jochen

Abstract

The interplay between epigenetic modification and chromatin compaction is implicated in the regulation of gene expression, and it comprises one of the most fascinating frontiers in cell biology. Although a complete picture is still lacking, it is generally accepted that the differentiation of embryonic stem (ES) cells is accompanied by a selective condensation into heterochromatin with concomitant gene silencing, leaving access only to lineage-specific genes in the euchromatin. ES cells have been reported to have less condensed chromatin, as they are capable of differentiating into any cell type. However, pluripotency itself—even prior to differentiation—is a split state comprising a naïve state and a state in which ES cells prime for differentiation. Here, we show that naïve ES cells decondense their chromatin in the course of downregulating the pluripotency marker Nanog before they initiate lineage commitment. We used fluorescence recovery after photobleaching, and histone modification analysis paired with a novel, to our knowledge, optical stretching method, to show that ES cells in the naïve state have a significantly stiffer nucleus that is coupled to a globally more condensed chromatin state. We link this biophysical phenotype to coinciding epigenetic differences, including histone methylation, and show a strong correlation of chromatin condensation and nuclear stiffness with the expression of Nanog. Besides having implications for transcriptional regulation and embryonic cell sorting and suggesting a putative mechanosensing mechanism, the physical differences point to a system-level regulatory role of chromatin in maintaining pluripotency in embryonic development.

Published

2012

42. Comparison of stresses on homogeneous spheroids in the optical stretcher computed with geometrical optics and generalized Lorenz–Mie theory

Author

Boyde, Lars, Ekpenyong, Andrew, Whyte, Graeme, and Guck, Jochen

Abstract

We present two electromagnetic frameworks to compare the surface stresses on spheroidal particles in the optical stretcher (a dual-beam laser trap that can be used to capture and deform biological cells). The first model is based on geometrical optics (GO) and limited in its applicability to particles that are much greater than the incident wavelength. The second framework is more sophisticated and hinges on the generalized Lorenz–Mie theory (GLMT). Despite the difference in complexity between both theories, the stress profiles computed with GO and GLMT are in good agreement with each other (relative errors are on the order of 1–10%). Both models predict a diminishing of the stresses for larger wavelengths and a strong increase of the stresses for shorter laser-cell distances. Results indicate that surface stresses on a spheroid with an aspect ratio of 1.2 hardly differ from the stresses on a sphere of similar size. Knowledge of the surface stresses and whether or not they redistribute during the stretching process is of crucial importance in real-time applications of the stretcher that aim to discern the viscoelastic properties of cells for purposes of cell characterization, sorting, and medical diagnostics.

Published

2012

43. Validation and perspectives of a femtosecond laser fabricated monolithic optical stretcher

Author

Bellini, Nicola, Bragheri, Francesca, Cristiani, Ilaria, Guck, Jochen, Osellame, Roberto, and Whyte, Graeme

Abstract

The combination of high power laser beams with microfluidic delivery of cells is at the heart of high-throughput, single-cell analysis and disease diagnosis with an optical stretcher. So far, the challenges arising from this combination have been addressed by externally aligning optical fibres with microfluidic glass capillaries, which has a limited potential for integration into lab-on-a-chip environments. Here we demonstrate the successful production and use of a monolithic glass chip for optical stretching of white blood cells, featuring microfluidic channels and optical waveguides directly written into bulk glass by femtosecond laser pulses. The performance of this novel chip is compared to the standard capillary configuration. The robustness, durability and potential for intricate flow patterns provided by this monolithic optical stretcher chip suggest its use for future diagnostic and biotechnological applications.

Published

2012

44. Exact analytical expansion of an off-axis Gaussian laser beam using the translation theorems for the vector spherical harmonics

Author

Boyde, Lars, Chalut, Kevin J., and Guck, Jochen

Abstract

The interaction of a Gaussian laser beam with a particle that is located off axis is a fundamental problem encountered across many scientific fields, including biological physics, chemistry, and medicine. For spherical geometries, generalized Lorenz–Mie theory affords a solution of Maxwell’s equations for the scattering from such a particle. The solution can be obtained by expanding the laser fields in terms of vector spherical harmonics (VSHs). However, the computation of the VSH expansion coefficients for off-axis beams has proven challenging. In the present study, we provide a very viable, theoretical framework to efficiently compute the sought-after expansion coefficients with high numerical accuracy. We use the existing theory for the expansion of an on-axis laser beam and employ Cruzan’s translation theorems [Q. Appl. Math.20, 33 (1962)QAMAAY0033-569X] for the VSHs to obtain a description for more general off-axis beams. The expansion coefficients for the off-axis laser beam are presented in an analytical form in terms of an infinite series over the underlying translation coefficients. A direct comparison of the electromagnetic fields of such a beam expansion with the original laser fields and with results obtained using numerical quadratures shows excellent agreement (relative errors are on the order of ≲10^−3). In practice, the analytical approach presented in this study has numerous applications, reaching from multiparticle scattering problems in atmospheric physics and climatology to optical trapping, sorting, and sizing techniques.

Published

2011

45. Mesenchymal Stem Cell Mechanics from the Attached to the Suspended State

Author

Maloney, John M., Nikova, Dessy, Lautenschläger, Franziska, Clarke, Emer, Langer, Robert, Guck, Jochen, and Van Vliet, Krystyn J.

Abstract

Human mesenchymal stem cells (hMSCs) are therapeutically useful cells that are typically expanded in vitro on stiff substrata before reimplantation. Here we explore MSC mechanical and structural changes via atomic force microscopy and optical stretching during extended passaging, and we demonstrate that cytoskeletal organization and mechanical stiffness of attached MSC populations are strongly modulated over 15 population doublings in vitro. Cytoskeletal actin networks exhibit significant coarsening, attendant with decreasing average mechanical compliance and differentiation potential of these cells, although expression of molecular surface markers does not significantly decline. These mechanical changes are not observed in the suspended state, indicating that the changes manifest themselves as alterations in stress fiber arrangement rather than cortical cytoskeleton arrangement. Additionally, optical stretching is capable of investigating a previously unquantified structural transition: remodeling-induced stiffening over tens of minutes after adherent cells are suspended. Finally, we find that optically stretched hMSCs exhibit power-law rheology during both loading and recovery; this evidence appears to be the first to originate from a biophysical measurement technique not involving cell-probe or cell-substratum contact. Together, these quantitative assessments of attached and suspended MSCs define the extremes of the extracellular environment while probing intracellular mechanisms that contribute to cell mechanical response.

Published

2010

46. Interaction of Gaussian beam with near-spherical particle: an analytic-numerical approach for assessing scattering and stresses

Author

Boyde, Lars, Chalut, Kevin J., and Guck, Jochen

Abstract

We derive a straightforward theoretical method to determine the electromagnetic fields for the incidence of a monochromatic laser beam on a near-spherical dielectric particle. The beam-shape coefficients are obtained from the radial laser fields and expressed as a finite series in a form that has, to our knowledge, not been published before. Our perturbation approach to solve Maxwell's equations in spherical coordinates employs two alternative techniques to match the boundary conditions: an analytic approach for small particles with low eccentricity and an adapted point-matching method for larger spheroids with higher aspect ratios. We present results for the internal and external fields, scattering intensities, and stresses exerted on the particle. While similarly accurate as others, our approach is easily implemented numerically and thus particularly useful in praxis, e.g., for analyzing optical traps, such as the optical stretcher.

Published

2009

47. Interaction of Gaussian beam with near-spherical particle: an analytic-numerical approach for assessing scattering and stresses

Author

Boyde, Lars, Chalut, Kevin J., and Guck, Jochen

Abstract

We derive a straightforward theoretical method to determine the electromagnetic fields for the incidence of a monochromatic laser beam on a near-spherical dielectric particle. The beam-shape coefficients are obtained from the radial laser fields and expressed as a finite series in a form that has, to our knowledge, not been published before. Our perturbation approach to solve Maxwell's equations in spherical coordinates employs two alternative techniques to match the boundary conditions: an analytic approach for small particles with low eccentricity and an adapted point-matching method for larger spheroids with higher aspect ratios. We present results for the internal and external fields, scattering intensities, and stresses exerted on the particle. While similarly accurate as others, our approach is easily implemented numerically and thus particularly useful in praxis, e.g., for analyzing optical traps, such as the optical stretcher.

Published

2009

48. Unbiased retrieval of frequency-dependent mechanical properties from noisy time-dependent signals

Author

Abuhattum, Shada, Kuan, Hui-Shun, Müller, Paul, Guck, Jochen, and Zaburdaev, Vasily

Abstract

The mechanical response of materials to dynamic loading is often quantified by the frequency-dependent complex modulus. Probing materials directly in the frequency domain faces technical challenges such as a limited range of frequencies, long measurement times, or small sample sizes. Furthermore, many biological samples, such as cells or tissues, can change their properties upon repetitive probing at different frequencies. Therefore, it is common practice to extract the material properties by fitting predefined mechanical models to measurements performed in the time domain. This practice, however, precludes the probing of unique and yet unexplored material properties. In this report, we demonstrate that the frequency-dependent complex modulus can be robustly retrieved in a model-independent manner directly from time-dependent stress-strain measurements. While applying a rolling average eliminates random noise and leads to a reliable complex modulus in the lower frequency range, a Fourier transform with a complex frequency helps to recover the material properties at high frequencies. Finally, by properly designing the probing procedure, the recovery of reliable mechanical properties can be extended to an even wider frequency range. Our approach can be used with many state-of-the-art experimental methods to interrogate the mechanical properties of biological and other complex materials.

Published

2022

49. Quantitative imaging of Caenorhabditis elegansdauer larvae during cryptobiotic transition

Author

Kim, Kyoohyun, Gade, Vamshidhar R., Kurzchalia, Teymuras V., and Guck, Jochen

Abstract

Upon starvation or overcrowding, the nematode Caenorhabditis elegansenters diapause by forming a dauer larva, which can then further survive harsh desiccation in an anhydrobiotic state. We have previously identified the genetic and biochemical pathways essential for survival — but without detailed knowledge of their material properties the mechanistic understanding of this intriguing phenomenon remains incomplete. Here we employed optical diffraction tomography (ODT) to quantitatively assess the internal mass density distribution of living larvae in the reproductive and diapause stages. ODT revealed that the properties of the dauer larvae undergo a dramatic transition upon harsh desiccation. Moreover, mutants that are sensitive to desiccation displayed structural abnormalities in the anhydrobiotic stage that could not be observed by conventional microscopy. Our advance opens a door to quantitatively assessing the transitions in material properties and structure necessary to fully understand an organism on the verge of life and death.

Published

2022

50. Optical Deformability as an Inherent Cell Marker for Testing Malignant Transformation and Metastatic Competence

Author

Guck, Jochen, Schinkinger, Stefan, Lincoln, Bryan, Wottawah, Falk, Ebert, Susanne, Romeyke, Maren, Lenz, Dominik, Erickson, Harold M., Ananthakrishnan, Revathi, Mitchell, Daniel, Käs, Josef, Ulvick, Sydney, and Bilby, Curt

Abstract

The relationship between the mechanical properties of cells and their molecular architecture has been the focus of extensive research for decades. The cytoskeleton, an internal polymer network, in particular determines a cell's mechanical strength and morphology. This cytoskeleton evolves during the normal differentiation of cells, is involved in many cellular functions, and is characteristically altered in many diseases, including cancer. Here we examine this hypothesized link between function and elasticity, enabling the distinction between different cells, by using a microfluidic optical stretcher, a two-beam laser trap optimized to serially deform single suspended cells by optically induced surface forces. In contrast to previous cell elasticity measurement techniques, statistically relevant numbers of single cells can be measured in rapid succession through microfluidic delivery, without any modification or contact. We find that optical deformability is sensitive enough to monitor the subtle changes during the progression of mouse fibroblasts and human breast epithelial cells from normal to cancerous and even metastatic state. The surprisingly low numbers of cells required for this distinction reflect the tight regulation of the cytoskeleton by the cell. This suggests using optical deformability as an inherent cell marker for basic cell biological investigation and diagnosis of disease.

Published

2005