@article{661, abstract = {During embryonic development, mechanical forces are essential for cellular rearrangements driving tissue morphogenesis. Here, we show that in the early zebrafish embryo, friction forces are generated at the interface between anterior axial mesoderm (prechordal plate, ppl) progenitors migrating towards the animal pole and neurectoderm progenitors moving in the opposite direction towards the vegetal pole of the embryo. These friction forces lead to global rearrangement of cells within the neurectoderm and determine the position of the neural anlage. Using a combination of experiments and simulations, we show that this process depends on hydrodynamic coupling between neurectoderm and ppl as a result of E-cadherin-mediated adhesion between those tissues. Our data thus establish the emergence of friction forces at the interface between moving tissues as a critical force-generating process shaping the embryo.}, author = {Smutny, Michael and Ákos, Zsuzsa and Grigolon, Silvia and Shamipour, Shayan and Ruprecht, Verena and Capek, Daniel and Behrndt, Martin and Papusheva, Ekaterina and Tada, Masazumi and Hof, Björn and Vicsek, Tamás and Salbreux, Guillaume and Heisenberg, Carl-Philipp J}, issn = {14657392}, journal = {Nature Cell Biology}, pages = {306 -- 317}, publisher = {Nature Publishing Group}, title = {{Friction forces position the neural anlage}}, doi = {10.1038/ncb3492}, volume = {19}, year = {2017}, } @article{1249, abstract = {Actin and myosin assemble into a thin layer of a highly dynamic network underneath the membrane of eukaryotic cells. This network generates the forces that drive cell- and tissue-scale morphogenetic processes. The effective material properties of this active network determine large-scale deformations and other morphogenetic events. For example, the characteristic time of stress relaxation (the Maxwell time τM) in the actomyosin sets the timescale of large-scale deformation of the cortex. Similarly, the characteristic length of stress propagation (the hydrodynamic length λ) sets the length scale of slow deformations, and a large hydrodynamic length is a prerequisite for long-ranged cortical flows. Here we introduce a method to determine physical parameters of the actomyosin cortical layer in vivo directly from laser ablation experiments. For this we investigate the cortical response to laser ablation in the one-cell-stage Caenorhabditis elegans embryo and in the gastrulating zebrafish embryo. These responses can be interpreted using a coarse-grained physical description of the cortex in terms of a two-dimensional thin film of an active viscoelastic gel. To determine the Maxwell time τM, the hydrodynamic length λ, the ratio of active stress ζΔμ, and per-area friction γ, we evaluated the response to laser ablation in two different ways: by quantifying flow and density fields as a function of space and time, and by determining the time evolution of the shape of the ablated region. Importantly, both methods provide best-fit physical parameters that are in close agreement with each other and that are similar to previous estimates in the two systems. Our method provides an accurate and robust means for measuring physical parameters of the actomyosin cortical layer. It can be useful for investigations of actomyosin mechanics at the cellular-scale, but also for providing insights into the active mechanics processes that govern tissue-scale morphogenesis.}, author = {Saha, Arnab and Nishikawa, Masatoshi and Behrndt, Martin and Heisenberg, Carl-Philipp J and Julicher, Frank and Grill, Stephan}, journal = {Biophysical Journal}, number = {6}, pages = {1421 -- 1429}, publisher = {Biophysical Society}, title = {{Determining physical properties of the cell cortex}}, doi = {10.1016/j.bpj.2016.02.013}, volume = {110}, year = {2016}, } @article{1817, abstract = {Vertebrates have a unique 3D body shape in which correct tissue and organ shape and alignment are essential for function. For example, vision requires the lens to be centred in the eye cup which must in turn be correctly positioned in the head. Tissue morphogenesis depends on force generation, force transmission through the tissue, and response of tissues and extracellular matrix to force. Although a century ago D'Arcy Thompson postulated that terrestrial animal body shapes are conditioned by gravity, there has been no animal model directly demonstrating how the aforementioned mechano-morphogenetic processes are coordinated to generate a body shape that withstands gravity. Here we report a unique medaka fish (Oryzias latipes) mutant, hirame (hir), which is sensitive to deformation by gravity. hir embryos display a markedly flattened body caused by mutation of YAP, a nuclear executor of Hippo signalling that regulates organ size. We show that actomyosin-mediated tissue tension is reduced in hir embryos, leading to tissue flattening and tissue misalignment, both of which contribute to body flattening. By analysing YAP function in 3D spheroids of human cells, we identify the Rho GTPase activating protein ARHGAP18 as an effector of YAP in controlling tissue tension. Together, these findings reveal a previously unrecognised function of YAP in regulating tissue shape and alignment required for proper 3D body shape. Understanding this morphogenetic function of YAP could facilitate the use of embryonic stem cells to generate complex organs requiring correct alignment of multiple tissues. }, author = {Porazinski, Sean and Wang, Huijia and Asaoka, Yoichi and Behrndt, Martin and Miyamoto, Tatsuo and Morita, Hitoshi and Hata, Shoji and Sasaki, Takashi and Krens, Gabriel and Osada, Yumi and Asaka, Satoshi and Momoi, Akihiro and Linton, Sarah and Miesfeld, Joel and Link, Brian and Senga, Takeshi and Castillo Morales, Atahualpa and Urrutia, Araxi and Shimizu, Nobuyoshi and Nagase, Hideaki and Matsuura, Shinya and Bagby, Stefan and Kondoh, Hisato and Nishina, Hiroshi and Heisenberg, Carl-Philipp J and Furutani Seiki, Makoto}, journal = {Nature}, number = {7551}, pages = {217 -- 221}, publisher = {Nature Publishing Group}, title = {{YAP is essential for tissue tension to ensure vertebrate 3D body shape}}, doi = {10.1038/nature14215}, volume = {521}, year = {2015}, } @article{1900, abstract = {Epithelial cell layers need to be tightly regulated to maintain their integrity and correct function. Cell integration into epithelial sheets is now shown to depend on the N-WASP-regulated stabilization of cortical F-actin, which generates distinct patterns of apical-lateral contractility at E-cadherin-based cell-cell junctions.}, author = {Behrndt, Martin and Heisenberg, Carl-Philipp J}, journal = {Nature Cell Biology}, number = {2}, pages = {127 -- 129}, publisher = {Nature Publishing Group}, title = {{Lateral junction dynamics lead the way out}}, doi = {10.1038/ncb2913}, volume = {16}, year = {2014}, } @inbook{6178, abstract = {Mechanically coupled cells can generate forces driving cell and tissue morphogenesis during development. Visualization and measuring of these forces is of major importance to better understand the complexity of the biomechanic processes that shape cells and tissues. Here, we describe how UV laser ablation can be utilized to quantitatively assess mechanical tension in different tissues of the developing zebrafish and in cultures of primary germ layer progenitor cells ex vivo.}, author = {Smutny, Michael and Behrndt, Martin and Campinho, Pedro and Ruprecht, Verena and Heisenberg, Carl-Philipp J}, booktitle = {Tissue Morphogenesis}, editor = {Nelson, Celeste}, isbn = {9781493911639}, issn = {1940-6029}, pages = {219--235}, publisher = {Springer}, title = {{UV laser ablation to measure cell and tissue-generated forces in the zebrafish embryo in vivo and ex vivo}}, doi = {10.1007/978-1-4939-1164-6_15}, volume = {1189}, year = {2014}, } @article{1912, abstract = {Kupffer's vesicle (KV) is the zebrafish organ of laterality, patterning the embryo along its left-right (LR) axis. Regional differences in cell shape within the lumen-lining KV epithelium are essential for its LR patterning function. However, the processes by which KV cells acquire their characteristic shapes are largely unknown. Here, we show that the notochord induces regional differences in cell shape within KV by triggering extracellular matrix (ECM) accumulation adjacent to anterior-dorsal (AD) regions of KV. This localized ECM deposition restricts apical expansion of lumen-lining epithelial cells in AD regions of KV during lumen growth. Our study provides mechanistic insight into the processes by which KV translates global embryonic patterning into regional cell shape differences required for its LR symmetry-breaking function.}, author = {Compagnon, Julien and Barone, Vanessa and Rajshekar, Srivarsha and Kottmeier, Rita and Pranjic-Ferscha, Kornelija and Behrndt, Martin and Heisenberg, Carl-Philipp J}, journal = {Developmental Cell}, number = {6}, pages = {774 -- 783}, publisher = {Cell Press}, title = {{The notochord breaks bilateral symmetry by controlling cell shapes in the Zebrafish laterality organ}}, doi = {10.1016/j.devcel.2014.11.003}, volume = {31}, year = {2014}, } @phdthesis{1403, abstract = {A variety of developmental and disease related processes depend on epithelial cell sheet spreading. In order to gain insight into the biophysical mechanism(s) underlying the tissue morphogenesis we studied the spreading of an epithelium during the early development of the zebrafish embryo. In zebrafish epiboly the enveloping cell layer (EVL), a simple squamous epithelium, spreads over the yolk cell to completely engulf it at the end of gastrulation. Previous studies have proposed that an actomyosin ring forming within the yolk syncytial layer (YSL) acts as purse string that through constriction along its circumference pulls on the margin of the EVL. Direct biophysical evidence for this hypothesis has however been missing. The aim of the thesis was to understand how the actomyosin ring may generate pulling forces onto the EVL and what cellular mechanism(s) may facilitate the spreading of the epithelium. Using laser ablation to measure cortical tension within the actomyosin ring we found an anisotropic tension distribution, which was highest along the circumference of the ring. However the low degree of anisotropy was incompatible with the actomyosin ring functioning as a purse string only. Additionally, we observed retrograde cortical flow from vegetal parts of the ring into the EVL margin. Interpreting the experimental data using a theoretical distribution that models the tissues as active viscous gels led us to proposen that the actomyosin ring has a twofold contribution to EVL epiboly. It not only acts as a purse string through constriction along its circumference, but in addition constriction along the width of the ring generates pulling forces through friction-resisted cortical flow. Moreover, when rendering the purse string mechanism unproductive EVL epiboly proceeded normally indicating that the flow-friction mechanism is sufficient to drive the process. Aiming to understand what cellular mechanism(s) may facilitate the spreading of the epithelium we found that tension-oriented EVL cell divisions limit tissue anisotropy by releasing tension along the division axis and promote epithelial spreading. Notably, EVL cells undergo ectopic cell fusion in conditions in which oriented-cell division is impaired or the epithelium is mechanically challenged. Taken together our study of EVL epiboly suggests a novel mechanism of force generation for actomyosin rings through friction-resisted cortical flow and highlights the importance of tension-oriented cell divisions in epithelial morphogenesis.}, author = {Behrndt, Martin}, pages = {91}, publisher = {IST Austria}, title = {{Forces driving epithelial spreading in zebrafish epiboly}}, year = {2014}, } @article{2282, abstract = {Epithelial spreading is a common and fundamental aspect of various developmental and disease-related processes such as epithelial closure and wound healing. A key challenge for epithelial tissues undergoing spreading is to increase their surface area without disrupting epithelial integrity. Here we show that orienting cell divisions by tension constitutes an efficient mechanism by which the enveloping cell layer (EVL) releases anisotropic tension while undergoing spreading during zebrafish epiboly. The control of EVL cell-division orientation by tension involves cell elongation and requires myosin II activity to align the mitotic spindle with the main tension axis. We also found that in the absence of tension-oriented cell divisions and in the presence of increased tissue tension, EVL cells undergo ectopic fusions, suggesting that the reduction of tension anisotropy by oriented cell divisions is required to prevent EVL cells from fusing. We conclude that cell-division orientation by tension constitutes a key mechanism for limiting tension anisotropy and thus promoting tissue spreading during EVL epiboly.}, author = {Campinho, Pedro and Behrndt, Martin and Ranft, Jonas and Risler, Thomas and Minc, Nicolas and Heisenberg, Carl-Philipp J}, journal = {Nature Cell Biology}, pages = {1405 -- 1414}, publisher = {Nature Publishing Group}, title = {{Tension-oriented cell divisions limit anisotropic tissue tension in epithelial spreading during zebrafish epiboly}}, doi = {10.1038/ncb2869}, volume = {15}, year = {2013}, } @article{2950, abstract = {Contractile actomyosin rings drive various fundamental morphogenetic processes ranging from cytokinesis to wound healing. Actomyosin rings are generally thought to function by circumferential contraction. Here, we show that the spreading of the enveloping cell layer (EVL) over the yolk cell during zebrafish gastrulation is driven by a contractile actomyosin ring. In contrast to previous suggestions, we find that this ring functions not only by circumferential contraction but also by a flow-friction mechanism. This generates a pulling force through resistance against retrograde actomyosin flow. EVL spreading proceeds normally in situations where circumferential contraction is unproductive, indicating that the flow-friction mechanism is sufficient. Thus, actomyosin rings can function in epithelial morphogenesis through a combination of cable-constriction and flow-friction mechanisms.}, author = {Behrndt, Martin and Salbreux, Guillaume and Campinho, Pedro and Hauschild, Robert and Oswald, Felix and Roensch, Julia and Grill, Stephan and Heisenberg, Carl-Philipp J}, journal = {Science}, number = {6104}, pages = {257 -- 260}, publisher = {American Association for the Advancement of Science}, title = {{Forces driving epithelial spreading in zebrafish gastrulation}}, doi = {10.1126/science.1224143}, volume = {338}, year = {2012}, } @article{3245, abstract = {How cells orchestrate their behavior during collective migration is a long-standing question. Using magnetic tweezers to apply mechanical stimuli to Xenopus mesendoderm cells, Weber etal. (2012) now reveal, in this issue of Developmental Cell, a cadherin-mediated mechanosensitive response that promotes cell polarization and movement persistence during the collective mesendoderm migration in gastrulation.}, author = {Behrndt, Martin and Heisenberg, Carl-Philipp J}, journal = {Developmental Cell}, number = {1}, pages = {3 -- 4}, publisher = {Cell Press}, title = {{Spurred by resistance mechanosensation in collective migration}}, doi = {10.1016/j.devcel.2011.12.018}, volume = {22}, year = {2012}, } @article{3373, abstract = {The use of optical traps to measure or apply forces on the molecular level requires a precise knowledge of the trapping force field. Close to the trap center, this field is typically approximated as linear in the displacement of the trapped microsphere. However, applications demanding high forces at low laser intensities can probe the light-microsphere interaction beyond the linear regime. Here, we measured the full nonlinear force and displacement response of an optical trap in two dimensions using a dual-beam optical trap setup with back-focal-plane photodetection. We observed a substantial stiffening of the trap beyond the linear regime that depends on microsphere size, in agreement with Mie theory calculations. Surprisingly, we found that the linear detection range for forces exceeds the one for displacement by far. Our approach allows for a complete calibration of an optical trap.}, author = {Jahnel, Marcus and Behrndt, Martin and Jannasch, Anita and Schaeffer, Erik and Grill, Stephan}, journal = {Optics Letters}, number = {7}, pages = {1260 -- 1262}, publisher = {Optica Publishing Group}, title = {{Measuring the complete force field of an optical trap}}, doi = {10.1364/OL.36.001260}, volume = {36}, year = {2011}, }