Your search keyword '"Kristian Franze"' showing total 112 results

1. Plakoglobin is a mechanoresponsive regulator of naive pluripotency

Author

Timo N. Kohler, Joachim De Jonghe, Anna L. Ellermann, Ayaka Yanagida, Michael Herger, Erin M. Slatery, Antonia Weberling, Clara Munger, Katrin Fischer, Carla Mulas, Alex Winkel, Connor Ross, Sophie Bergmann, Kristian Franze, Kevin Chalut, Jennifer Nichols, Thorsten E. Boroviak, and Florian Hollfelder

Subjects

Science

Abstract

Abstract Biomechanical cues are instrumental in guiding embryonic development and cell differentiation. Understanding how these physical stimuli translate into transcriptional programs will provide insight into mechanisms underlying mammalian pre-implantation development. Here, we explore this type of regulation by exerting microenvironmental control over mouse embryonic stem cells. Microfluidic encapsulation of mouse embryonic stem cells in agarose microgels stabilizes the naive pluripotency network and specifically induces expression of Plakoglobin (Jup), a vertebrate homolog of β-catenin. Overexpression of Plakoglobin is sufficient to fully re-establish the naive pluripotency gene regulatory network under metastable pluripotency conditions, as confirmed by single-cell transcriptome profiling. Finally, we find that, in the epiblast, Plakoglobin was exclusively expressed at the blastocyst stage in human and mouse embryos – further strengthening the link between Plakoglobin and naive pluripotency in vivo. Our work reveals Plakoglobin as a mechanosensitive regulator of naive pluripotency and provides a paradigm to interrogate the effects of volumetric confinement on cell-fate transitions.

Published

2023

2. StemBond hydrogels control the mechanical microenvironment for pluripotent stem cells

Author

Céline Labouesse, Bao Xiu Tan, Chibeza C. Agley, Moritz Hofer, Alexander K. Winkel, Giuliano G. Stirparo, Hannah T. Stuart, Christophe M. Verstreken, Carla Mulas, William Mansfield, Paul Bertone, Kristian Franze, José C. R. Silva, and Kevin J. Chalut

Subjects

Science

Abstract

The independent control of substrate stiffness and tethering of extracellular matrix to substrates for mechanical signalling investigations remains challenging. Here the authors present StemBond hydrogels, with stable ECM tethering that can be varied independently of stiffness, and use these to modulate the function of mouse and human pluripotent stem cells.

Published

2021

3. Unrestrained growth of correctly oriented microtubules instructs axonal microtubule orientation

Author

Maximilian AH Jakobs, Assaf Zemel, and Kristian Franze

Subjects

axons, neurons, microtubule orientation, microtubule polarity, Medicine, Science, Biology (General), QH301-705.5

Abstract

In many eukaryotic cells, directed molecular transport occurs along microtubules. Within neuronal axons, transport over vast distances particularly relies on uniformly oriented microtubules, whose plus-ends point towards the distal axon tip (anterogradely polymerizing, or plus-end-out). However, axonal microtubules initially have mixed orientations, and how they orient during development is not yet fully understood. Using live imaging of primary Drosophila melanogaster neurons, we found that, in the distal part of the axon, catastrophe rates of plus-end-out microtubules were significantly reduced compared to those of minus-end-out microtubules. Physical modelling revealed that plus-end-out microtubules should therefore exhibit persistent long-term growth, while growth of minus-end-out microtubules should be limited, leading to a bias in overall axonal microtubule orientation. Using chemical and physical perturbations of microtubule growth and genetic perturbations of the anti -catastrophe factor p150, which was enriched in the distal axon tip, we confirmed that the enhanced growth of plus-end-out microtubules is critical for achieving uniform microtubule orientation. Computer simulations of axon development integrating the enhanced plus-end-out microtubule growth identified here with previously suggested mechanisms, that is, dynein-based microtubule sliding and augmin-mediated templating, correctly predicted the long-term evolution of axonal microtubule orientation as found in our experiments. Our study thus leads to a holistic explanation of how axonal microtubules orient uniformly, a prerequisite for efficient long-range transport essential for neuronal functioning.

Published

2022

4. Axons in the Chick Embryo Follow Soft Pathways Through Developing Somite Segments

Author

Julia Schaeffer, Isabell P. Weber, Amelia J. Thompson, Roger J. Keynes, and Kristian Franze

Subjects

AFM, axon pathfinding, tissue stiffness, somite polarity, nervous system development, spinal motor axons, Biology (General), QH301-705.5

Abstract

During patterning of the peripheral nervous system, motor axons grow sequentially out of the neural tube in a segmented fashion to ensure functional integration of the motor roots between the surrounding cartilage and bones of the developing vertebrae. This segmented outgrowth is regulated by the intrinsic properties of each segment (somite) adjacent to the neural tube, and in particular by chemical repulsive guidance cues expressed in the posterior half. Yet, knockout models for such repulsive cues still display initial segmentation of outgrowing motor axons, suggesting the existence of additional, yet unknown regulatory mechanisms of axon growth segmentation. As neuronal growth is not only regulated by chemical but also by mechanical signals, we here characterized the mechanical environment of outgrowing motor axons. Using atomic force microscopy-based indentation measurements on chick embryo somite strips, we identified stiffness gradients in each segment, which precedes motor axon growth. Axon growth was restricted to the anterior, softer tissue, which showed lower cell body densities than the repulsive stiffer posterior parts at later stages. As tissue stiffness is known to regulate axon growth during development, our results suggest that motor axons also respond to periodic stiffness gradients imposed by the intrinsic mechanical properties of somites.

Published

2022

5. Towards brain-tissue-like biomaterials

Author

Eneko Axpe, Gorka Orive, Kristian Franze, and Eric A. Appel

Subjects

Science

Abstract

Many biomaterials have been developed which aim to match the elastic modulus of the brain for improved interfacing. However, other properties such as ultimate toughness, tensile strength, poroviscoelastic responses, energy dissipation, conductivity, and mass diffusivity also need to be considered.

Published

2020

6. Contact inhibition controls cell survival and proliferation via YAP/TAZ-autophagy axis

Author

Mariana Pavel, Maurizio Renna, So Jung Park, Fiona M. Menzies, Thomas Ricketts, Jens Füllgrabe, Avraham Ashkenazi, Rebecca A. Frake, Alejandro Carnicer Lombarte, Carla F. Bento, Kristian Franze, and David C. Rubinsztein

Subjects

Science

Abstract

At high cell density or when plated on soft matrix, YAP/TAZ are redistributed from the nucleus to the cytosol, becoming transcriptionally inactive. Here the authors show that at high cell density, autophagosome formation is impaired due to reduced YAP/TAZ-dependent transcription of actomyosin genes

Published

2018

7. Laminin Levels Regulate Tissue Migration and Anterior-Posterior Polarity during Egg Morphogenesis in Drosophila

Author

María C. Díaz de la Loza, Alfonsa Díaz-Torres, Federico Zurita, Alicia E. Rosales-Nieves, Emad Moeendarbary, Kristian Franze, María D. Martín-Bermudo, and Acaimo González-Reyes

Subjects

collective migration, epithelial migration, laminin, integrin, anterior-posterior polarity, Drosophila oogenesis, Biology (General), QH301-705.5

Abstract

Basement membranes (BMs) are specialized extracellular matrices required for tissue organization and organ formation. We study the role of laminin and its integrin receptor in the regulation of tissue migration during Drosophila oogenesis. Egg production in Drosophila involves the collective migration of follicle cells (FCs) over the BM to shape the mature egg. We show that laminin content in the BM increases with time, whereas integrin amounts in FCs do not vary significantly. Manipulation of integrin and laminin levels reveals that a dynamic balance of integrin-laminin amounts determines the onset and speed of FC migration. Thus, the interplay of ligand-receptor levels regulates tissue migration in vivo. Laminin depletion also affects the ultrastructure and biophysical properties of the BM and results in anterior-posterior misorientation of developing follicles. Laminin emerges as a key player in the regulation of collective cell migration, tissue stiffness, and the organization of anterior-posterior polarity in Drosophila.

Published

2017

8. The soft mechanical signature of glial scars in the central nervous system

Author

Emad Moeendarbary, Isabell P. Weber, Graham K. Sheridan, David E. Koser, Sara Soleman, Barbara Haenzi, Elizabeth J. Bradbury, James Fawcett, and Kristian Franze

Subjects

Science

Abstract

Glial scars are thought to provide a biochemical and mechanical barrier to neuronal regeneration post-injury, but the mechanical properties of the scars have not been studied in detail. Here the authors perform atomic force microscopy measurements of glial scars from the injured rat cortex and spinal cord, and find that brain tissue softens in response to the injury.

Published

2017

9. KymoButler, a deep learning software for automated kymograph analysis

Author

Maximilian AH Jakobs, Andrea Dimitracopoulos, and Kristian Franze

Subjects

kymographs, kymograms, transport, neurons, artificial intelligence, machine learning, Medicine, Science, Biology (General), QH301-705.5

Abstract

Kymographs are graphical representations of spatial position over time, which are often used in biology to visualise the motion of fluorescent particles, molecules, vesicles, or organelles moving along a predictable path. Although in kymographs tracks of individual particles are qualitatively easily distinguished, their automated quantitative analysis is much more challenging. Kymographs often exhibit low signal-to-noise-ratios (SNRs), and available tools that automate their analysis usually require manual supervision. Here we developed KymoButler, a Deep Learning-based software to automatically track dynamic processes in kymographs. We demonstrate that KymoButler performs as well as expert manual data analysis on kymographs with complex particle trajectories from a variety of different biological systems. The software was packaged in a web-based ‘one-click’ application for use by the wider scientific community (https://deepmirror.ai/kymobutler). Our approach significantly speeds up data analysis, avoids unconscious bias, and represents another step towards the widespread adaptation of Machine Learning techniques in biological data analysis.

Published

2019

10. Rapid changes in tissue mechanics regulate cell behaviour in the developing embryonic brain

Author

Amelia J Thompson, Eva K Pillai, Ivan B Dimov, Sarah K Foster, Christine E Holt, and Kristian Franze

Subjects

atomic force microscopy, mechanics, stiffness, mechanotransduction, durotaxis, axon guidance, Medicine, Science, Biology (General), QH301-705.5

Abstract

Tissue mechanics is important for development; however, the spatio-temporal dynamics of in vivo tissue stiffness is still poorly understood. We here developed tiv-AFM, combining time-lapse in vivo atomic force microscopy with upright fluorescence imaging of embryonic tissue, to show that during development local tissue stiffness changes significantly within tens of minutes. Within this time frame, a stiffness gradient arose in the developing Xenopus brain, and retinal ganglion cell axons turned to follow this gradient. Changes in local tissue stiffness were largely governed by cell proliferation, as perturbation of mitosis diminished both the stiffness gradient and the caudal turn of axons found in control brains. Hence, we identified a close relationship between the dynamics of tissue mechanics and developmental processes, underpinning the importance of time-resolved stiffness measurements.

Published

2019

11. Effect of vital dyes on human corneal endothelium and elasticity of Descemet's membrane.

Author

Isabell P Weber, Mrinal Rana, Peter B M Thomas, Ivan B Dimov, Kristian Franze, and Madhavan S Rajan

Subjects

Medicine, Science

Abstract

The purpose of this study was to evaluate the effects of vital dyes on human Descemet's membranes (DMs) and endothelia. DMs of 25 human cadaveric corneas with research consent were treated with dyes routinely used in Descemet membrane endothelial keratoplasty (DMEK), 0.05% Trypan blue (TB) or a combination of 0.15% Trypan blue, 0.025% Brilliant blue and 4% Polyethylene glycol (commercial name Membrane Blue Dual; MB). The effects of these two dyes on (i) endothelial cell viability, (ii) DM mechanical properties as assessed by atomic force microscopy, and iii) qualitative DM dye retention were tested for two varying exposure times (one or four minutes). No significant differences in cell toxicity were observed between treatments with TB and MB at the two different exposure times (P = 0.21). Further, both dyes led to a significant increase in DM stiffness: exposure to TB and MB for one minute increased the apparent elastic modulus of the DM by 11.2% (P = 8*10-3) and 17.7%, respectively (P = 4*10-6). A four-minute exposure led to an increase of 8.6% for TB (P = 0.004) and 13.6% for MB (P = 0.03). Finally, at 25 minutes, the dye retention of the DM was considerably better for MB compared to TB. Taken together, a one-minute exposure to MB was found to improve DM visibility compared to TB, with a significant increase in DM stiffness and without detrimental effects on endothelial cell viability. The use of MB could therefore improve (i) visibility of the DM scroll, and (ii) intraoperative unfolding, enhancing the probability of successful DMEK surgery.

Published

2017

12. ECM-Regulator timp Is Required for Stem Cell Niche Organization and Cyst Production in the Drosophila Ovary.

Author

John R Pearson, Federico Zurita, Laura Tomás-Gallardo, Alfonsa Díaz-Torres, María Del Carmen Díaz de la Loza, Kristian Franze, María D Martín-Bermudo, and Acaimo González-Reyes

Subjects

Genetics, QH426-470

Abstract

The extracellular matrix (ECM) is a pivotal component adult tissues and of many tissue-specific stem cell niches. It provides structural support and regulates niche signaling during tissue maintenance and regeneration. In many tissues, ECM remodeling depends on the regulation of MMP (matrix metalloproteinase) activity by inhibitory TIMP (tissue inhibitors of metalloproteinases) proteins. Here, we report that the only Drosophila timp gene is required for maintaining the normal organization and function of the germline stem cell niche in adult females. timp mutant ovaries show reduced levels of both Drosophila Collagen IV α chains. In addition, tissue stiffness and the cellular organization of the ovarian niche are affected in timp mutants. Finally, loss of timp impairs the ability of the germline stem cell niche to generate new cysts. Our results demonstrating a crucial role for timp in tissue organization and gamete production thus provide a link between the regulation of ECM metabolism and tissue homeostasis.

Published

2016

13. Mechanical behavior of the hippocampus and corpus callosum: An attempt to reconcile ex vivo with in vivo and micro with macro properties

Author

Gergerly Bertalan, Julia Becker, Heiko Tzschätzsch, Anna Morr, Helge Herthum, Mehrgan Shahryari, Ryan D. Greenhalgh, Jing Guo, Leif Schröder, Christian Alzheimer, Silvia Budday, Kristian Franze, Jürgen Braun, Ingolf Sack, Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

MR elastography, Corpus callosum, White matter, Biomedical Engineering, Brain, Viscoelasticity, Brain tissue, Hippocampus, Magnetic Resonance Imaging, Biomaterials, Atomic force microscopy, Mice, MRE, Mechanics of Materials, Humans, Animals, Elasticity Imaging Techniques, AFM

Abstract

Mechanical properties of brain tissue are very complex and vary with the species, region, method, and dynamic range, and between in vivo and ex vivo measurements. To reconcile this variability, we investigated in vivo and ex vivo stiffness properties of two distinct regions in the human and mouse brain - the hippocampus (HP) and the corpus callosum (CC) - using different methods. Under quasi-static conditions, we examined ex vivo murine HP and CC by atomic force microscopy (AFM). Between 16 and 40Hz, we investigated the in vivo brains of healthy volunteers by magnetic resonance elastography (MRE) in a 3-T clinical scanner. At high-frequency stimulation between 1000 and 1400Hz, we investigated the murine HP and CC ex vivo and in vivo with MRE in a 7-T preclinical system. HP and CC showed pronounced stiffness dispersion, as reflected by a factor of 32-36 increase in shear modulus from AFM to low-frequency human MRE and a 25-fold higher shear wave velocity in murine MRE than in human MRE. At low frequencies, HP was softer than CC, in both ex vivo mouse specimens (p

Published

2023

14. Effective cell membrane tension is independent of polyacrylamide substrate stiffness

Author

Eva Kreysing, Jeffrey Mc Hugh, Sarah K Foster, Kurt Andresen, Ryan D Greenhalgh, Eva K Pillai, Andrea Dimitracopoulos, Ulrich F Keyser, Kristian Franze, Hugh, Jeffrey Mc [0000-0001-5155-2655], Andresen, Kurt [0000-0002-7773-6716], Pillai, Eva K [0000-0002-4662-3356], Keyser, Ulrich F [0000-0003-3188-5414], Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

4003 Biomedical Engineering, 1.1 Normal biological development and functioning, 1 Underpinning research, Bioengineering, Generic health relevance, 3101 Biochemistry and Cell Biology, 40 Engineering, 31 Biological Sciences

Abstract

Most animal cells are surrounded by a cell membrane and an underlying actomyosin cortex. Both structures are linked, and they are under tension. In-plane membrane tension and cortical tension both influence many cellular processes, including cell migration, division, and endocytosis. However, while actomyosin tension is regulated by substrate stiffness, how membrane tension responds to mechanical substrate properties is currently poorly understood. Here, we probed the effective membrane tension of neurons and fibroblasts cultured on glass and polyacrylamide substrates of varying stiffness using optical tweezers. In contrast to actomyosin-based traction forces, both peak forces and steady-state tether forces of cells cultured on hydrogels were independent of substrate stiffness and did not change after blocking myosin II activity using blebbistatin, indicating that tether and traction forces are not directly linked. Peak forces in fibroblasts on hydrogels were about twice as high as those in neurons, indicating stronger membrane–cortex adhesion in fibroblasts. Steady-state tether forces were generally higher in cells cultured on hydrogels than on glass, which we explain by a mechanical model. Our results provide new insights into the complex regulation of effective membrane tension and pave the way for a deeper understanding of the biological processes it instructs.

Published

2023

15. Regenerative capacity of neural tissue scales with changes in tissue mechanics post injury

Author

Alejandro Carnicer-Lombarte, Damiano G. Barone, James W. Fawcett, and Kristian Franze

Abstract

Spinal cord injuries have devastating consequences for humans, as mammalian neurons of the central nervous system (CNS) cannot regenerate. In the peripheral nervous system (PNS), however, neurons may regenerate to restore lost function following injury. While mammalian CNS tissue softens after injury, how PNS tissue mechanics changes in response to mechanical trauma is currently poorly understood. Here we characterised mechanical rat nerve tissue properties before and afterin vivocrush and transection injuries using atomic force microscopy-based indentation measurements. Unlike CNS tissue, PNS tissue significantly stiffened after both types of tissue damage, likely mainly due to an increase in collagen I levels. Schwann cells, which crucially support PNS regeneration, became more motile and proliferative on stiffer substratesin vitro, suggesting that changes in tissue stiffness may play a key role in facilitating or impeding nervous system regeneration.

Published

2022

16. Retinal regions shape human and murine Müller cell proteome profile and functionality

Author

Lew Kaplan, Corinne Drexler, Anna M. Pfaller, Santra Brenna, Kirsten A. Wunderlich, Andrea Dimitracopoulos, Juliane Merl‐Pham, Maria‐Theresa Perez, Ursula Schlötzer‐Schrehardt, Volker Enzmann, Marijana Samardzija, Berta Puig, Peter Fuchs, Kristian Franze, Stefanie M. Hauck, Antje Grosche, Kaplan, Lew [0000-0003-4336-2768], Brenna, Santra [0000-0001-8233-2110], Enzmann, Volker [0000-0003-4384-4855], Grosche, Antje [0000-0003-0338-7530], and Apollo - University of Cambridge Repository

Subjects

Müller cells, glial heterogeneity, Proteomics, retina, EPPK1, Proteome, Ependymoglial Cells, 610 Medicine & health, Cellular and Molecular Neuroscience, Mice, Neurology, Eppk1, Müller Cells, Glial Heterogeneity, Macula, Retina, Retinal Cone Photoreceptor Cells, Humans, Animals, macula, ddc:610, 610 Medizin und Gesundheit, Neuroglia

Abstract

The human macula is a highly specialized retinal region with pit‐like morphology and rich in cones. How Müller cells, the principal glial cell type in the retina, are adapted to this environment is still poorly understood. We compared proteomic data from cone‐ and rod‐rich retinae from human and mice and identified different expression profiles of cone‐ and rod‐associated Müller cells that converged on pathways representing extracellular matrix and cell adhesion. In particular, epiplakin (EPPK1), which is thought to play a role in intermediate filament organization, was highly expressed in macular Müller cells. Furthermore, EPPK1 knockout in a human Müller cell‐derived cell line led to a decrease in traction forces as well as to changes in cell size, shape, and filopodia characteristics. We here identified EPPK1 as a central molecular player in the region‐specific architecture of the human retina, which likely enables specific functions under the immense mechanical loads in vivo.

Published

2022

17. Mutation of the ALS/FTD-associated RNA-binding protein FUS alters axonal cytoskeletal organisation

Author

Francesca W. van Tartwijk, Lucia C.S. Wunderlich, Ioanna Mela, Stanislaw Makarchuk, Maximilian A.H Jakobs, Seema Qamar, Kristian Franze, Gabriele S. Kaminski Schierle, Peter H. St George-Hyslop, Julie Qiaojin Lin, Christine E. Holt, and Clemens F. Kaminski

Abstract

SummaryAberrant condensation and localisation of the RNA-binding protein fused in sarcoma (FUS) occur in variants of amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). ALS is also associated with cytoskeletal defects, genetically and through observations of compromised axonal transport. Here, we asked whether compromised axonal cytoskeletal organisation is an early feature of FUS-associated ALS/FTD. We used an ALS-associated mutant FUS(P525L) and the FTD-mimic hypomethylated FUS, FUS(16R), to investigate the common and distinct cytoskeletal changes found in these two reportedXenopusmodels. Combining a novel atomic force microscopy (AFM)-based approach forin vitrocytoskeletal characterisation andin vivoaxonal branching analysis, we found that mutant FUS reduced actin density in the dynamically remodelling growth cone, and reduced axonal branch complexity. We furthermore found evidence of an axon looping defect for FUS(P525L). Therefore, we show that compromised actin remodelling is potentially an important early event in FUS-associated pathogenesis.Abstract Figure

Published

2022

18. Author response: Unrestrained growth of correctly oriented microtubules instructs axonal microtubule orientation

Author

Maximilian AH Jakobs, Assaf Zemel, and Kristian Franze

Published

2022

19. Soft Polydimethylsiloxane-Supported Lipid Bilayers for Studying T Cell Interactions

Author

Edward Jenkins, Simon J. Davis, David Klenerman, Jane Humphrey, Ana Filipa L.O.M. Santos, Ivan B Dimov, James McColl, Alexander K. Winkel, Anna Lippert, Kevin Y. Chen, Kristian Franze, Lippert, Anna [0000-0003-0463-6535], Humphrey, Jane [0000-0002-6825-1426], Franze, Kristian [0000-0002-8425-7297], Klenerman, David [0000-0001-7116-6954], and Apollo - University of Cambridge Repository

Subjects

0303 health sciences, Polydimethylsiloxane, Chemistry, T-Lymphocytes, T cell, Lipid Bilayers, Biophysics, Substrate (chemistry), Articles, Cell Communication, Mechanical resistance, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, medicine.anatomical_structure, Elastic Modulus, medicine, Mechanosensitive channels, Dimethylpolysiloxanes, Receptor, Lipid bilayer, 030217 neurology & neurosurgery, 030304 developmental biology, Calcium signaling

Abstract

Much of what we know about the early stages of T cell activation has been obtained from studies of T cells interacting with glass-supported lipid bilayers that favor imaging but are orders of magnitude stiffer than typical cells. We developed a method for attaching lipid bilayers to polydimethylsiloxane polymer supports, producing “soft bilayers” with physiological levels of mechanical resistance (Young’s modulus of 4 kPa). Comparisons of T cell behavior on soft and glass-supported bilayers revealed that whereas late stages of T cell activation are thought to be substrate-stiffness dependent, early calcium signaling was unaffected by substrate rigidity, implying that early steps in T cell receptor triggering are not mechanosensitive. The exclusion of large receptor-type phosphatases was observed on the soft bilayers, however, even though it is yet to be demonstrated at authentic cell-cell contacts. This work sets the stage for an imaging-based exploration of receptor signaling under conditions closely mimicking physiological cell-cell contact.

Published

2021

20. Prevention of the foreign body response to implantable medical devices by inflammasome inhibition

Author

Damiano G. Barone, Alejandro Carnicer-Lombarte, Panagiotis Tourlomousis, Russell S. Hamilton, Malwina Prater, Alexandra L. Rutz, Ivan B. Dimov, George G. Malliaras, Stephanie P. Lacour, Avril A. B. Robertson, Kristian Franze, James W. Fawcett, Clare E. Bryant, Barone, Damiano [0000-0002-0091-385X], Tourlomousis, Panagiotis [0000-0002-6152-8066], Hamilton, Russell S [0000-0002-0598-3793], Prater, Malwina [0000-0002-8202-5345], Malliaras, George [0000-0002-4582-8501], Lacour, Stephanie P [0000-0001-9075-4022], Robertson, Avril AB [0000-0002-9652-8357], Franze, Kristian [0000-0002-8425-7297], Bryant, Clare [0000-0002-2924-0038], Apollo - University of Cambridge Repository, Barone, Damiano G [0000-0002-0091-385X], Malliaras, George G [0000-0002-4582-8501], and Bryant, Clare E [0000-0002-2924-0038]

Subjects

Multidisciplinary, peripheral-nerve injury, Inflammasomes, Macrophages, receptor, mcc950, Prostheses and Implants, macrophage, electrode, Foreign Bodies, il-1-beta, foreign body reaction, nlrp3 inflammasome, recovery, recruitment, rodents, NLR Family, Pyrin Domain-Containing 3 Protein, immune-response, Humans, neural interfaces, dendritic cells

Abstract

SignificanceImplantable electronic medical devices (IEMDs) are used for some clinical applications, representing an exciting prospect for the transformative treatment of intractable conditions such Parkinson's disease, deafness, and paralysis. The use of IEMDs is limited at the moment because, over time, a foreign body reaction (FBR) develops at the device-neural interface such that ultimately the IEMD fails and needs to be removed. Here, we show that macrophage nucleotide-binding oligomerization domain-like receptor family pyrin domain containing 3 (NLRP3) inflammasome activity drives the FBR in a nerve injury model yet integration of an NLRP3 inhibitor into the device prevents FBR while allowing full healing of damaged neural tissue to occur., Part of the RNA-Seq work was performed with the Genomics and Transcriptomics Core, which is funded by the UK Medical Research Council (MRC) Metabolic Disease Unit (MRC_MC_UU_00014/5) and a Wellcome Trust Major Award (208363/Z/17/Z), and guidance from Marcella Ma, whom the authors wish to thank. CEB was supported by a Wellcome Trust Investigator award (108045/Z/15/Z). This work was also supported by the UK Wellcome Trust (Translational Medicine and Therapeutics PhD Programme Fellowship 109511/Z/15/Z to DGB), the UK Health Education England and the National Institute for Health Research (HEE/ NIHR ICA Program Clinical Lectureship CL-2019-14-004 to DGB), the UK Medical Research Council (MRC) and the Sackler Foundation (doctoral training grant RG70550 to ACL), the Engineering and Physical Sciences Research Council (EPSRC) Cambridge NanoDTC (EP/L015978/1), the Centre for Trophoblast Research (MP and RSH), the Whitaker International Scholars Program (ALR), the European Commission’s Horizon 2020 (Marie Sklodowska-Curie Fellowship 797506 to ALR), the Bertarelli Foundation (SPL), the European Research Council (Consolidator Award 772426 to KF), the UK Biotechnology and Biological Sciences Research Council (Research Grant BB/N006402/1 to KF), and the Alexander von Humboldt Foundation (Humboldt Professorship to KF).

Published

2022

21. Plakoglobin is a mechanoresponsive regulator of naïve pluripotency

Author

Timo N. Kohler, Joachim De Jonghe, Anna L. Ellerman, Ayaka Yanagida, Michael Herger, Erin M. Slatery, Katrin Fischer, Carla Mulas, Alex Winkel, Connor Ross, Sophie Bergmann, Kristian Franze, Kevin Chalut, Jennifer Nichols, Thorsten E. Boroviak, and Florian Hollfelder

Abstract

Biomechanical cues are instrumental in guiding embryonic development and cell differentiation. Understanding how these physical stimuli translate into transcriptional programs could provide insight into mechanisms underlying mammalian pre-implantation development. Here, we explore this by exerting microenvironmental control over mouse embryonic stem cells (ESCs). Microfluidic encapsulation of ESCs in agarose microgels stabilized the naïve pluripotency network and specifically induced expression of Plakoglobin (Jup), a vertebrate homologue of β-catenin. Indeed, overexpression of Plakoglobin was sufficient to fully re-establish the naïve pluripotency gene regulatory network under metastable pluripotency conditions, as confirmed by single-cell transcriptome profiling. Finally, we found that in the epiblast, Plakoglobin was exclusively expressed at the blastocyst stage in human and mouse embryos – further strengthening the link between Plakoglobin and naïve pluripotency in vivo. Our work reveals Plakoglobin as a mechanosensitive regulator of naïve pluripotency and provides a paradigm to interrogate the effects of volumetric confinement on cell-fate transitions.Highlights3D agarose spheres stabilize the naïve pluripotency network in mouse ESCs.Volumetric confinement induces expression of Plakoglobin, a vertebrate homologue of β-catenin.Plakoglobin expression in the epiblast is specific to pre-implantation human and mouse embryos.Plakoglobin overexpression maintains naïve pluripotency independently of β-catenin.

Published

2022

22. Cell surface fluctuations regulate early embryonic lineage sorting

Author

Davide A. D. Cassani, Jennifer Nichols, Raphael Blumenfeld, Irene M. Aspalter, Ruby Peters, Henry De Belly, Kevin J. Chalut, Giuliano Giuseppe Stirparo, Ayaka Yanagida, Ewa K. Paluch, Christopher Revell, Elena Corujo-Simon, Sarra Achouri, Kristian Franze, Blumenfeld, Rafi [0000-0001-7201-2164], Franze, Kristian [0000-0002-8425-7297], Paluch, Ewa [0000-0003-4691-2323], Chalut, Kevin [0000-0001-6200-9690], and Apollo - University of Cambridge Repository

Subjects

Lineage (genetic), morphogenesis, Embryonic Development, General Biochemistry, Genetics and Molecular Biology, Mice, medicine, Inner cell mass, cell surface dynamics, Animals, Cell Lineage, cell surface mechanics, Yolk sac, cell sorting, Mammals, Cell Membrane, Endoderm, lineage segregation, Embryo, embryo development, Cell Differentiation, Cell sorting, Embryo, Mammalian, Embryonic stem cell, Cell biology, Protein Transport, medicine.anatomical_structure, Blastocyst, Cell culture, Epiblast

Abstract

In development, lineage segregation of multiple lineages must be coordinated in time and space. An important example is the mammalian inner cell mass (ICM), in which the primitive endoderm (PrE, founder of the yolk sac) physically segregates from the epiblast (EPI, founder of the foetus). The physical mechanisms that determine this spatial segregation between EPI and PrE are still poorly understood. Here, we identify an asymmetry in cell-cell affinity, a mechanical property thought to play a significant role in tissue sorting in other systems, between EPI and PrE precursors (pEPI and pPrE). However, a computational model of cell sorting indicated that these differences alone appeared insufficient to explain the spatial segregation. We also observed significantly greater surface fluctuations in pPrE compared to pEPI. Including the enhanced surface fluctuation in pPrE in our simulation led to robust cell sorting. We identify phospho-ERM regulated membrane tension as an important mediator of the increased surface fluctuations in pPrE. Using aggregates of engineered cell lines with different surface fluctuation levels cells with higher surface fluctuations were consistently excluded to the outside of the aggregate. These cells behaved similarly when incorporated in the embryo. Surface fluctuations-driven segregation is reminiscent of activity-induced phase separation, a sorting phenomenon in colloidal physics. Together, our experiments and model identify dynamic cell surface fluctuations, in addition to static mechanical properties, as a key factor for orchestrating the correct spatial positioning of the founder embryonic lineages.

Published

2022

23. The mechanical regulation of Eph/ephrin signaling in the developing brain

Author

Jana Sipkova, Sudipta Mukherjee, and Kristian Franze

Subjects

Biophysics

Published

2023

24. Effective cell membrane tension is independent of polyacrylamide substrate stiffness

Author

Eva K Pillai, Jeffrey Mc Hugh, Ryan D. Greenhalgh, Andrea Dimitracopoulos, Ulrich F. Keyser, Sarah Foster, Kurt Andresen, Kristian Franze, and Eva Kreysing

Subjects

Chemistry, Tension (physics), Stiffness, Cell migration, macromolecular substances, Adhesion, Endocytosis, Cell membrane, medicine.anatomical_structure, Self-healing hydrogels, Myosin, medicine, Biophysics, medicine.symptom

Abstract

Most animal cells are surrounded by a cell membrane and an underlying actomyosin cortex. Both structures are linked with each other, and they are under tension. Membrane tension and cortical tension both influence many cellular processes, including cell migration, division, and endocytosis. However, while actomyosin tension is regulated by substrate stiffness, how membrane tension responds to mechanical substrate properties is currently poorly understood. Here, we probed the effective membrane tension of neurons and fibroblasts cultured on glass and polyacrylamide substrates of varying stiffness using optical tweezers. In contrast to actomyosin-based traction forces, both peak forces and steady state tether forces of cells cultured on hydrogels were independent of substrate stiffness and did not change after blocking myosin II activity using blebbistatin, indicating that tether and traction forces are not directly linked with each other. Peak forces on hydrogels were about twice as high in fibroblasts if compared to neurons, indicating stronger membrane-cortex adhesion in fibroblasts. Finally, tether forces were generally higher in cells cultured on hydrogels compared to cells cultured on glass, which we attribute to substrate-dependent alterations of the actomyosin cortex and an inverse relationship between tension along stress fibres and cortical tension. Our results provide new insights into the complex regulation of membrane tension, and they pave the way for a deeper understanding of biological processes instructed by it.

Published

2021

25. StemBond hydrogels control the mechanical microenvironment for pluripotent stem cells

Author

Bao Xiu Tan, Céline Labouesse, Carla Mulas, Alexander K. Winkel, Moritz Hofer, Christophe M. Verstreken, Chibeza C. Agley, Kevin J. Chalut, José C. R. Silva, Giuliano Giuseppe Stirparo, Paul Bertone, Kristian Franze, William Mansfield, Hannah T. Stuart, Labouesse, Céline [0000-0002-9791-898X], Hofer, Moritz [0000-0002-9714-0143], Stirparo, Giuliano G. [0000-0002-5911-8682], Verstreken, Christophe M. [0000-0001-9038-1094], Mulas, Carla [0000-0002-9492-6482], Franze, Kristian [0000-0002-8425-7297], Silva, José C. R. [0000-0001-5487-1117], Chalut, Kevin J. [0000-0001-6200-9690], Apollo - University of Cambridge Repository, Stirparo, Giuliano G [0000-0002-5911-8682], Verstreken, Christophe M [0000-0001-9038-1094], Silva, José CR [0000-0001-5487-1117], Chalut, Kevin J [0000-0001-6200-9690], and Chalut, Kevin [0000-0001-6200-9690]

Subjects

Pluripotent Stem Cells, Embryonic stem cells, 631/61/54/2295, Science, Cell Culture Techniques, General Physics and Astronomy, 631/61/2320, macromolecular substances, Matrix (biology), 13, Mechanotransduction, Cellular, 14, Stem-cell biotechnology, General Biochemistry, Genetics and Molecular Biology, 38, 38/91, Extracellular matrix, 631/532/2435, 82/80, Mice, 631/532/2117, Stem cell fate specification, 13/100, 14/3, Cell Adhesion, 38/88, Animals, Humans, 14/19, Induced pluripotent stem cell, Cells, Cultured, Multidisciplinary, Chemistry, technology, industry, and agriculture, article, Reprogramming, Cell Differentiation, Hydrogels, General Chemistry, Embryonic stem cell, Cell biology, Biomechanical Phenomena, Extracellular Matrix, Self-healing hydrogels, 14/63, Biomaterials - cells, Stem cell

Abstract

Funder: Medical Research Council (UK) Career Development Award (G1100312/1), Funder: Medical Research Council (UK) MR/M011089/1 Wellcome Trust-Medical Research Council core funding to the Wellcome-MRC Cambridge Stem Cell Institute, Studies of mechanical signalling are typically performed by comparing cells cultured on soft and stiff hydrogel-based substrates. However, it is challenging to independently and robustly control both substrate stiffness and extracellular matrix tethering to substrates, making matrix tethering a potentially confounding variable in mechanical signalling investigations. Moreover, unstable matrix tethering can lead to poor cell attachment and weak engagement of cell adhesions. To address this, we developed StemBond hydrogels, a hydrogel in which matrix tethering is robust and can be varied independently of stiffness. We validate StemBond hydrogels by showing that they provide an optimal system for culturing mouse and human pluripotent stem cells. We further show how soft StemBond hydrogels modulate stem cell function, partly through stiffness-sensitive ERK signalling. Our findings underline how substrate mechanics impact mechanosensitive signalling pathways regulating self-renewal and differentiation, indicating that optimising the complete mechanical microenvironment will offer greater control over stem cell fate specification.

Published

2021

26. Vinculin is required for neuronal mechanosensing but not for axon outgrowth

Author

Ashwaq Albaraky, Karin A. Jansen, Cristina Melero, Paul Atherton, Kristian Franze, Federico Dajas-Bailador, Andrea Dimitracopoulos, Christoph Ballestrem, Adam J Reid, and De Yao Wang

Subjects

Neurons, Focal Adhesions, Integrins, Neurite, biology, Integrin, Neuronal Outgrowth, Motility, Signal transducing adaptor protein, Cell Biology, Vinculin, Mechanotransduction, Cellular, Axons, Cell biology, Extracellular Matrix, Extracellular matrix, Focal adhesion, Mice, Focal Adhesion Protein-Tyrosine Kinases, biology.protein, Cell Adhesion, Animals, Growth cone

Abstract

Integrin receptors are transmembrane proteins that bind to the extracellular matrix (ECM). In most animal cell types integrins cluster together with adaptor proteins at focal adhesions that sense and respond to external mechanical signals. In the central nervous system (CNS), ECM proteins are sparsely distributed, the tissue is comparatively soft and neurons do not form focal adhesions. Thus, how neurons sense tissue stiffness is currently poorly understood. Here, we found that integrins and the integrin-associated proteins talin and focal adhesion kinase (FAK) are required for the outgrowth of neuronal processes. Vinculin, however, whilst not required for neurite outgrowth was a key regulator of integrin-mediated mechanosensing of neurons. During growth, growth cones of axons of CNS derived cells exerted dynamic stresses of around 10–12 Pa on their environment, and axons grew significantly longer on soft (0.4 kPa) compared to stiff (8 kPa) substrates. Depletion of vinculin blocked this ability of growth cones to distinguish between soft and stiff substrates. These data suggest that vinculin in neurons acts as a key mechanosensor, involved in the regulation of growth cone motility.

Published

2021

27. Unrestrained growth of correctly oriented microtubules instructs axonal microtubule orientation

Author

Maximilian Ah Jakobs, Assaf Zemel, and Kristian Franze

Subjects

medicine.anatomical_structure, nervous system, Live cell imaging, Chemistry, Microtubule, Molecular Transport, Biophysics, medicine, Enhanced growth, Orientation (graph theory), Axon, Physical modelling

Abstract

SummaryIn many eukaryotic cells, directed molecular transport occurs along microtubules. Within neuronal axons, transport over vast distances particularly relies on uniformly oriented microtubules, whose +-ends point towards the distal axon tip (+end out). However, axonal microtubules initially have mixed orientations, and how they orient during development is not yet fully understood. Using live imaging of primary Drosophila melanogaster neurons and physical modelling, we found that +end out microtubules are less likely to undergo catastrophe near the advancing axon tip, leading to their persistent long-term growth. In contrast, oppositely oriented microtubules remain short. Using chemical and physical perturbations of microtubule growth and genetic perturbations of the anti -catastrophe factor p150, which was enriched in the distal axon tip, we confirmed that the enhanced growth of +end out microtubules is critical for achieving uniform microtubule orientation. Computer simulations of axon development mimicking the enhanced +end out microtubule growth identified here along with previously proposed mechanisms correctly predicted the long-term evolution of axonal microtubule orientation as found in our experiments, highlighting the importance of the reduced catastrophe rate of +end out microtubules near the advancing axon tip in establishing uniform microtubule polarity. Our study thus leads to a holistic explanation of how axonal microtubules orient uniformly, a prerequisite for efficient long-range transport essential for neuronal functioning.

Published

2021

28. All-Optical Detection of Neuronal Membrane Depolarization in Live Cells Using Colloidal Quantum Dots

Author

Richard Chen, Ulrich F. Keyser, James Xiao, Giorgio Divitini, Kristian Franze, Raj Pandya, Neil C. Greenham, Sarah Foster, Akshay Rao, and Mustafa Caglar

Subjects

Letter, Materials science, Photoluminescence, Neuronal membrane, Bioengineering, 02 engineering and technology, Membrane Potentials, Cell membrane, Xenopus laevis, All optical, medicine, Animals, General Materials Science, Calcium Signaling, Colloids, Neurons, Quantum dots, business.industry, Mechanical Engineering, voltage sensing, technology, industry, and agriculture, Depolarization, General Chemistry, equipment and supplies, 021001 nanoscience & nanotechnology, Condensed Matter Physics, electric field, medicine.anatomical_structure, Microscopy, Fluorescence, Quantum dot, Optoelectronics, Calcium, photoluminescence, live cell, Colloidal quantum dots, 0210 nano-technology, business, Luminescence

Abstract

Luminescent semiconductor quantum dots (QDs) have recently been suggested as novel probes for imaging and sensing cell membrane voltages. However, a key bottleneck for their development is a lack of techniques to assess QD responses to voltages generated in the aqueous electrolytic environments typical of biological systems. Even more generally, there have been relatively few efforts to assess the response of QDs to voltage changes in live cells. Here, we develop a platform for monitoring the photoluminescence (PL) response of QDs under AC and DC voltage changes within aqueous ionic environments. We evaluate both traditional CdSe/CdS and more biologically compatible InP/ZnS QDs at a range of ion concentrations to establish their PL/voltage characteristics on chip. Wide-field, few-particle PL measurements with neuronal cells show the QDs can be used to track local voltage changes with greater sensitivity (ΔPL up to twice as large) than state-of-the-art calcium imaging dyes, making them particularly appealing for tracking subthreshold events. Additional physiological observation studies showed that while CdSe/CdS dots have greater PL responses on membrane depolarization, their lower cytotoxicity makes InP/ZnS far more suitable for voltage sensing in living systems. Our results provide a methodology for the rational development of QD voltage sensors and highlight their potential for imaging changes in cell membrane voltage.

Published

2019

29. The Orsay Virus as a model for population-wide viral infection dynamics

Author

Eric A. Miska, Pirenne L, Jakobs Mah, David Jordan, and Kristian Franze

Subjects

education.field_of_study, Orsay virus, Isolation (health care), Host (biology), Population, Virulence, RNA virus, Computational biology, Biology, biology.organism_classification, medicine.disease_cause, Virus, Pandemic, medicine, education

Abstract

To this day, epidemics pose a considerable threat to mankind. Experimental models that simulate the spread of infectious diseases are thus crucial to the inception of effective control policies. Current models have had great success incorporating virulence and host immune response but do rarely take host genetics, behavior and host environment into account. Here, we present a full-scale imaging setup that utilizes the infection of the nematode C. elegans with a positive-stranded RNA virus (Orsay Virus) to probe key epidemiological parameters and simulate the spread of infection in a whole population. We demonstrate that our system is able to quantify infection levels and host behavior at a high sampling rate and show that different host genetic backgrounds can influence viral spread, while also highlighting the influence of infection on various host behaviors. Future work will allow the isolation of key behavioral and environmental factors that affect viral spread, potentially enabling novel policies to combat the spread of viral infections.Significance StatementIn the ongoing COVID-19 pandemic, we struggle to find effective control policies that “stop the spread”. While current animal models of virus spread in populations are highly sophisticated, they rarely explore effects of host behavior and its environment. We developed an experimental animal model system that allows us to visualize virus transmission in whole populations of C. elegans while also measuring behaviors. We were able to demonstrate how C. elegans genetics influences the progression of viral infection in a population and how animals adjust their behavior when infected. In the future, we envision that animal model systems like ours are used to test the effects of viral control policies on viral spread before they are applied in real world scenarios.

Published

2021

30. Decision letter: Endoglycan plays a role in axon guidance by modulating cell adhesion

Author

Kristian Franze

Subjects

ENDOGLYCAN, Chemistry, Axon guidance, Cell adhesion, Neuroscience

Published

2020

31. An optic ray theory for durotactic axon guidance

Author

Kristian Franze, Hadrien Oliveri, and Alain Goriely

Subjects

Physics, Nervous system, Classical mechanics, medicine.anatomical_structure, Durotaxis, Quantitative Biology::Neurons and Cognition, Bundle, Biological neural network, medicine, Refraction (sound), Axon guidance, Rigidity (psychology), Axon

Abstract

During the development of the nervous system, neurons extend bundles of axons that grow and meet other neurons to form the neuronal network. Robust guidance mechanisms are needed for these bundles to migrate and reach their functional target. Directional information depends on external cues such as chemical or mechanical gradients. Unlike chemotaxis that has been extensively studied, the role and mechanism of durotaxis, the directed response to variations in substrate rigidity, remain unclear. We model bundle migration and guidance by rigidity gradients by using the theory of morphoelastic rods. We show that at a rigidity interface, the motion of axon bundles follows a simple behavior analogous to optic ray theory and obeys Snell’s law for refraction and reflection. We use this powerful analogy to demonstrate that axons can be guided by the equivalent of optical lenses and fibers created by regions of different stiffnesses.

Published

2020

32. Theory for Durotactic Axon Guidance

Author

Hadrien Oliveri, Alain Goriely, Kristian Franze, Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

Physics, Nervous system, Neurons, Durotaxis, Quantitative Biology::Neurons and Cognition, Xenopus, Models, Neurological, General Physics and Astronomy, Rigidity (psychology), 01 natural sciences, Refraction, Axons, Axon Guidance, Biomechanical Phenomena, medicine.anatomical_structure, Classical mechanics, Bundle, 0103 physical sciences, medicine, Biological neural network, Animals, Axon guidance, Axon, Nerve Net, 010306 general physics

Abstract

During the development of the nervous system, neurons extend bundles of axons that grow and meet other neurons to form the neuronal network. Robust guidance mechanisms are needed for these bundles to migrate and reach their functional target. Directional information depends on external cues such as chemical or mechanical gradients. Unlike chemotaxis that has been extensively studied, the role and mechanism of durotaxis, the directed response to variations in substrate rigidity, remain unclear. We model bundle migration and guidance by rigidity gradients by using the theory of morphoelastic rods. We show that, at a rigidity interface, the motion of axon bundles follows a simple behavior analogous to optic ray theory and obeys Snell's law for refraction and reflection. We use this powerful analogy to demonstrate that axons can be guided by the equivalent of optical lenses and fibers created by regions of different stiffnesses.

Published

2020

33. Spatial heterogeneity of cell-matrix adhesive forces predicts human glioblastoma migration

Author

Alexandre Kabla, Astrid Wendler, Ivan B Dimov, Bill Zong Jia, Colin Watts, Kristian Franze, R Rezk, Athina E. Markaki, Markaki, Athina E [0000-0002-2265-1256], Franze, Kristian [0000-0002-8425-7297], Kabla, Alexandre J [0000-0002-0280-3531], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, cell migration, Cell, Brain tumor, cell-matrix adhesion, Time-lapse microscopy, Extracellular matrix, 03 medical and health sciences, 0302 clinical medicine, Cell-matrix adhesion, Glioma, Biopsy, medicine, AcademicSubjects/MED00300, 030304 developmental biology, 0303 health sciences, medicine.diagnostic_test, Chemistry, glioblastoma, Cell migration, Adhesion, medicine.disease, 030104 developmental biology, medicine.anatomical_structure, Cell culture, Basic and Translational Investigations, Cancer research, AcademicSubjects/MED00310, 030217 neurology & neurosurgery

Abstract

BackgroundGlioblastoma (GBM) is a highly aggressive incurable brain tumor. The main cause of mortality in GBM patients is the invasive rim of cells migrating away from the main tumor mass and invading healthy parts of the brain. Although motion is driven by forces, our current understanding of the physical factors involved in glioma infiltration remains limited. This study aims to investigate the adhesion properties within and between patients’ tumors on a cellular level and test whether these properties correlate with cell migration.MethodsNine tissue samples were taken from spatially separated sections during 5-aminolevulinic acid (5-ALA) fluorescence guided surgery. Navigated biopsy samples were collected from strongly fluorescent tumor cores, a weak fluorescent tumor rim, and non-fluorescent tumor margins. A microfluidics device was built to induce controlled shear forces to detach cells from monolayer cultures. Cells were cultured on low modulus polydimethylsiloxane representative of the stiffness of brain tissue. Cell migration and morphology were then obtained using time lapse microscopy.ResultsGBM cell populations from different tumor fractions of the same patient exhibited different migratory and adhesive behaviors. These differences were associated with sampling location and amount of 5-ALA fluorescence. Cells derived from weak- and non-fluorescent tumor tissue were smaller, adhered less well, and migrated quicker than cells derived from strongly fluorescent tumor mass.ConclusionGBM tumors are biomechanically heterogeneous. Selecting multiple populations and broad location sampling are therefore important to consider for drug testing.Key pointsGBM tumors are biomechanically heterogeneousGBM cell migration is inversely correlated with cell-matrix adhesion strength5-ALA fluorescence intensity during surgery correlates with the motility properties of GBM cellsImportance of the studyThis is the first study to compare single cell migration and cell-matrix adhesion strength of GBM, using cell lines derived from different tumors and from different regions within the same tumor. Not accounting for internal sampling location within each tumor obscures differences in cell morphology, motility and adhesion properties between patients. Peripherical and marginal tumor cells have different adhesion profiles and are highly migratory compared to those found in the core of the tumor. Aggressive regions of the tumor (highly motile) are linked to the spatial distribution of adhesion strength and are strongly associated with 5-ALA fluorescence intensity. Preclinical tests aimed at developing a treatment for GBM using anti-invasive drugs or adhesion inhibitors, would benefit from using cell lines derived from the tumor periphery (with low 5-ALA intensity) rather than cell lines derived from the tumor core.

Published

2020

34. Integrating Chemistry and Mechanics: The Forces Driving Axon Growth

Author

Kristian Franze, Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

forces, Growth Cones, neurons, Biology, Models, Biological, 03 medical and health sciences, 0302 clinical medicine, Animals, Humans, Mechanotransduction, 030304 developmental biology, mechanotransduction, 0303 health sciences, pathfinding, Cell Biology, mechanosensitivity, Axon growth, Axons, Axon Guidance, Biomechanical Phenomena, Chemistry, nervous system, Current (fluid), Pathfinding, Neuroscience, 030217 neurology & neurosurgery, guidance, Developmental Biology

Abstract

The brain is our most complex organ. During development, neurons extend axons, which may grow over long distances along well-defined pathways to connect to distant targets. Our current understanding of axon pathfinding is largely based on chemical signaling by attractive and repulsive guidance cues. These cues instruct motile growth cones, the leading tips of growing axons, where to turn and where to stop. However, it is not chemical signals that cause motion—motion is driven by forces. Yet, our current understanding of the mechanical regulation of axon growth is very limited. In this review, I discuss the origin of the cellular forces controlling axon growth and pathfinding, and how mechanical signals encountered by growing axons may be integrated with chemical signals. This mechanochemical cross talk is an important but often overlooked aspect of cell motility that has major implications for many physiological and pathological processes involving neuronal growth., ERC

Published

2020

35. Robust T-cell signaling triggered on soft polydimethylsiloxane-supported lipid-bilayers

Author

Edward Jenkins, Ivan B Dimov, Kevin Y. Chen, Simon J. Davis, David Klenerman, Alexander K. Winkel, Anna Lippert, Jane Humphrey, Ana Filipa L.O.M. Santos, James McColl, and Kristian Franze

Subjects

chemistry.chemical_compound, Polydimethylsiloxane, chemistry, Phosphatase, T-cell receptor, Biophysics, Mechanosensitive channels, Protein tyrosine phosphatase, Lipid bilayer, Receptor, Calcium signaling

Abstract

The T-cell receptor (TCR) is thought to be triggered either by mechano-transduction or local tyrosine phosphatase exclusion at cell-cell contacts. However, the effects of the mechanical properties of activating surfaces have only been tested for late-stage T-cell activation, and phosphatase segregation has mostly been studied on glass-supported lipid bilayers that favor imaging but are orders-of-magnitude stiffer than typical cells. We developed a method for attaching lipid bilayers to polydimethylsiloxane polymer supports, producing ‘soft bilayers’ with physiological levels of mechanical resistance (Young’s modulus of 4 kPa). Comparisons of T-cell behavior on soft and glass-supported bilayers revealed that early calcium signaling is unaffected by substrate rigidity, implying that early steps in TCR triggering are not mechanosensitive. Robust phosphatase exclusion was observed on the soft bilayers, however, suggesting it likely occurs at cell-cell contacts. This work sets the stage for an imaging-based exploration of receptor signaling under conditions closely mimicking physiological cell-cell contact.

Published

2020

36. Cortical cell stiffness is independent of substrate mechanics

Author

Nils M. Kronenberg, Kristian Franze, Malte C. Gather, Timo Betz, Guillaume Charras, Bernhard Wallmeyer, Johannes Rheinlaender, Andrea Dimitracopoulos, Kevin J. Chalut, Rheinlaender, Johannes [0000-0002-1976-9245], Kronenberg, Nils M [0000-0001-6386-3848], Gather, Malte C [0000-0002-4857-5562], Betz, Timo [0000-0002-1548-0655], Charras, Guillaume [0000-0002-7902-0279], Franze, Kristian [0000-0002-8425-7297], Apollo - University of Cambridge Repository, EPSRC, University of St Andrews. School of Physics and Astronomy, University of St Andrews. Sir James Mackenzie Institute for Early Diagnosis, University of St Andrews. Centre for Biophotonics, and University of St Andrews. Biomedical Sciences Research Complex

Subjects

Polyacrylamide, Chemistry(all), QH301 Biology, Composite number, 02 engineering and technology, Microscopy, Atomic Force, ERISM, 01 natural sciences, Substrate Specificity, Cell stiffness, Indentation, Microscopy, Susbtrate stiffness, General Materials Science, R2C, QC, Cerebral Cortex, 0303 health sciences, Stiffness, Cell Differentiation, Mechanics, Adhesion, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Finite element method, Stiffening, Mechanics of Materials, AFM, Deformation (engineering), medicine.symptom, BDC, polyacrylamide, 0210 nano-technology, cell stiffness, Materials science, substrate stiffness, 010402 general chemistry, Article, 03 medical and health sciences, QH301, Materials Science(all), Elastic Modulus, medicine, stiffening, Elastic modulus, 030304 developmental biology, Mechanical Engineering, technology, industry, and agriculture, Substrate (chemistry), DAS, General Chemistry, 0104 chemical sciences, body regions, QC Physics

Abstract

Funding: We acknowledge funding from the German Science Foundation (DFG grant numbers RH 147/1-1 to J.R., EXC 1003 CiM to T.B.), the Herchel Smith Foundation (postdoctoral fellowship to A.D.), the Royal Society (University Research Fellowship to K.J.C.), the UK EPSRC (programme grant number EP/P030017/1 to M.C.G.), the Human Frontier Science Program (HFSP grant number RGP0018/2017 to T.B.), the European Research Council (consolidator grant numbers 772798 to K.J.C., 771201 to T.B., 647186 to G.C. and 772426 to K.F.), and the UK BBSRC (equipment grant number BB/R000042/1 to G.C. and research project grant number BB/N006402/1 to K.F.). Cortical stiffness is an important cellular property that changes during migration, adhesion and growth. Previous atomic force microscopy (AFM) indentation measurements of cells cultured on deformable substrates have suggested that cells adapt their stiffness to that of their surroundings. Here we show that the force applied by AFM to a cell results in a significant deformation of the underlying substrate if this substrate is softer than the cell. This ‘soft substrate effect’ leads to an underestimation of a cell’s elastic modulus when analysing data using a standard Hertz model, as confirmed by finite element modelling and AFM measurements of calibrated polyacrylamide beads, microglial cells and fibroblasts. To account for this substrate deformation, we developed a ‘composite cell–substrate model’. Correcting for the substrate indentation revealed that cortical cell stiffness is largely independent of substrate mechanics, which has major implications for our interpretation of many physiological and pathological processes. Postprint

Published

2020

37. The Costs of Close Contacts: Visualizing the Energy Landscape of Cell Contacts at the Nanoscale

Author

Alexander K. Winkel, Simon J. Davis, David Klenerman, Steven F. Lee, Edward Jenkins, Aleks Ponjavic, Anna Lippert, Klara Kulenkampff, Jane Humphrey, Ana Filipa L.O.M. Santos, Kristian Franze, James McColl, Kulenkampff, Klara [0000-0001-7121-2957], Lippert, Anna [0000-0003-0463-6535], Humphrey, Jane [0000-0002-6825-1426], Franze, Kristian [0000-0002-8425-7297], Lee, Steven [0000-0003-4492-5139], Klenerman, David [0000-0001-7116-6954], and Apollo - University of Cambridge Repository

Subjects

0303 health sciences, Chemistry, T-Lymphocytes, Cell, Biophysics, Receptors, Antigen, T-Cell, Energy landscape, Adhesion, Articles, Receptor–ligand kinetics, Synapse, Diffusion, 03 medical and health sciences, Kinetics, 0302 clinical medicine, medicine.anatomical_structure, Quantum dot, medicine, Signal transduction, Lipid bilayer, 030217 neurology & neurosurgery, 030304 developmental biology, Signal Transduction

Abstract

Cell-cell contacts often underpin signaling between cells. For immunology, the binding of a T cell receptor to an antigen-presenting pMHC initiates downstream signaling and an immune response. Although this contact is mediated by proteins on both cells creating interfaces with gap sizes typically around 14 nm, many, often contradictory observations have been made regarding the influence of the contact on parameters such as the binding kinetics, spatial distribution, and diffusion of signaling proteins within the contact. Understanding the basic physical constraints on probes inside this crowded environment will help inform studies on binding kinetics and dynamics of signaling of relevant proteins in the synapse. By tracking quantum dots of different dimensions for extended periods of time, we have shown that it is possible to obtain the probability of a molecule entering the contact, the change in its diffusion upon entry, and the impact of spatial heterogeneity of adhesion protein density in the contact. By analyzing the contacts formed by a T cell interacting with adhesion proteins anchored to a supported lipid bilayer, we find that probes are excluded from contact entry in a size-dependent manner for gap-to-probe differences of 4.1 nm. We also observed probes being trapped inside the contact and a decrease in diffusion of up to 85% in dense adhesion protein contacts. This approach provides new, to our knowledge, insights into the nature of cell-cell contacts, revealing that cell contacts are highly heterogeneous because of topography- and protein-density-related processes. These effects are likely to profoundly influence signaling between cells.

Published

2020

38. Defining the adult neural stem cell niche proteome identifies key regulators of adult neurogenesis

Author

David C. Martinelli, Favio Salinas, Christian Friess, Magdalena Götz, Jovica Ninkovic, Herbert B. Schiller, Jürgen Cox, Amelia J Thompson, Matthew J. Sticco, Kristian Franze, Judith Fischer-Sternjak, and Jacob Kjell

Subjects

Proteomics, transglutaminase2, Proteome, extracellular matrix, Neurogenesis, Niche, Subventricular zone, Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Neural Stem Cells, Neuroblast, transit-amplifying progenitor, Genetics, medicine, Animals, C1ql3, Cerebral Cortex, Extracellular Matrix, Olfactory Bulb, S100a6, Subventricular Zone, Tissue Stiffness, Transglutaminase2, Transit-amplifying Progenitor, tissue stiffness, Stem Cell Niche, 030304 developmental biology, 0303 health sciences, subventricular zone, Cell Biology, Neural stem cell, Olfactory bulb, Transplantation, medicine.anatomical_structure, nervous system, Cerebral cortex, olfactory bulb, cerebral cortex, Molecular Medicine, neuroblast, Neuroscience, 030217 neurology & neurosurgery

Abstract

Summary The mammalian brain contains few niches for neural stem cells (NSCs) capable of generating new neurons, whereas other regions are primarily gliogenic. Here we leverage the spatial separation of the sub-ependymal zone NSC niche and the olfactory bulb, the region to which newly generated neurons from the sub-ependymal zone migrate and integrate, and present a comprehensive proteomic characterization of these regions in comparison to the cerebral cortex, which is not conducive to neurogenesis and integration of new neurons. We find differing compositions of regulatory extracellular matrix (ECM) components in the neurogenic niche. We further show that quiescent NSCs are the main source of their local ECM, including the multi-functional enzyme transglutaminase 2, which we show is crucial for neurogenesis. Atomic force microscopy corroborated indications from the proteomic analyses that neurogenic niches are significantly stiffer than non-neurogenic parenchyma. Together these findings provide a powerful resource for unraveling unique compositions of neurogenic niches., Graphical Abstract, Highlights • Proteomics define the NSC niche-specific extracellular matrix • Detergent-solubility profiling reveals extracellular matrix architecture • Transglutaminase 2 regulates neurogenesis • Stiffness is increased in the neurogenic niches of the brain, The physical properties of stem cell niches are thought to mediate important regulatory functions. Here we provide a proteomic resource of the neural stem cell niche in comparison to gliogenic brain parenchyma, highlighting stiffness and the enzyme transglutaminase 2 as key regulators of neurogenesis.

Published

2020

39. Foreign body reaction is triggeredin vivoby cellular mechanosensing of implants stiffer than host tissue

Author

Kristian Franze, Russell S. Hamilton, Ivan B Dimov, George G. Malliaras, James W. Fawcett, Damiano G. Barone, Clare E. Bryant, Malwina Prater, Stéphanie P. Lacour, Xiaohui Zhao, Alejandro Carnicer-Lombarte, and Alexandra L. Rutz

Subjects

0303 health sciences, Materials science, Healthy tissue, 02 engineering and technology, 021001 nanoscience & nanotechnology, Host tissue, medicine.disease, 3. Good health, 03 medical and health sciences, chemistry.chemical_compound, Silicone, chemistry, Fibrosis, medicine, Mechanosensitive channels, Implant, Foreign body, 0210 nano-technology, 030304 developmental biology, Biomedical engineering, Therapeutic strategy

Abstract

Medical implants offer a unique and powerful therapeutic approach in many areas of medicine. However, their lifetime is often limited as they may cause a foreign body reaction (FBR) leading to their encapsulation by scar tissue1–4. Despite the importance of this process, how cells recognise implanted materials is still poorly understood5, 6. Here, we show how the mechanical mismatch between implants and host tissue leads to FBR. Fibroblasts and macrophages, which are both crucially involved in mediating FBR, became activated when cultured on materials just above the stiffness found in healthy tissue. Coating implants with a thin layer of hydrogel or silicone with a tissue-like elastic modulus of ∼1 kPa or below led to significantly reduced levels of inflammation and fibrosis after chronic implantation both in peripheral nerves and subcutaneously. This effect was linked to the nuclear localisation of the mechanosensitive transcriptional regulator YAP in vivo. Hence, we identify the mechanical mismatch between implant and tissue as a driver of FBR. Soft implant coatings matching the mechanical properties of host tissue minimized FBR and may be used as a novel therapeutic strategy to improve long-term biomedical implant stability without extensive modification of current implant manufacturing techniques, thus facilitating clinical translation. One sentence summary Foreign body reaction to medical implants can be avoided by matching the stiffness of the implant surface to that of the host tissue.

Published

2019

40. StemBond hydrogels optimise the mechanical microenvironment for embryonic stem cells

Author

Christophe M. Verstreken, Kristian Franze, Alex Winkel, Chibeza C. Agley, Moritz Hofer, Paul Bertone, William Mansfield, José C. R. Silva, Céline Labouesse, Bao Xiu Tan, Hannah T. Stuart, Kevin J. Chalut, and Giuliano Giuseppe Stirparo

Subjects

0303 health sciences, Tethering, Chemistry, Cell, technology, industry, and agriculture, Embryonic stem cell, Cell biology, Extracellular matrix, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Stem cell fate specification, Self-healing hydrogels, medicine, Mechanosensitive channels, Reprogramming, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Studies of mechanical signalling are typically performed by comparing cells cultured on soft and stiff hydrogel-based substrates. However, it is challenging to independently and robustly control both substrate stiffness and tethering of extracellular matrix (ECM) to substrates, making ECM tethering a potentially confounding variable in mechanical signalling investigations. Moreover, poor ECM tethering can lead to weak cell attachment. To address this, we developed StemBond hydrogels, a hydrogel formulation in which ECM tethering is stable and can be varied independently of stiffness. We show that soft StemBond hydrogels provide an optimal format for culturing embryonic stem (ES) cells. We find that soft StemBond substrates improve the homogeneity of ES cell populations, boost their self-renewal, and increase the efficiency of cellular reprogramming. Our findings underline how soft microenvironments impact mechanosensitive signalling pathways regulating self-renewal and differentiation, indicating that optimising the complete mechanical microenvironment will offer greater control over stem cell fate specification.

Published

2019

41. Mechanical Regulation of Neurite Polarization and Growth: A Computational Study

Author

Assaf Zemel, Kristian Franze, Maximilian Ah Jakobs, Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

Physics, Neurons, 0303 health sciences, Mechanical load, Neurite, Biophysics, Polarization (waves), Microtubules, Axons, Article, Local pattern, 03 medical and health sciences, 0302 clinical medicine, Neurite growth, Microtubule, Molecular motor, Neurites, Cytoskeleton, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The densely packed microtubule (MT) array found in neuronal cell projections (neurites) serves two fundamental functions simultaneously: it provides a mechanically stable track for molecular motor-based transport and produces forces that drive neurite growth. The local pattern of MT polarity along the neurite shaft has been found to differ between axons and dendrites. In axons, the neurons' dominating long projections, roughly 90% of the MTs orient with their rapidly growing plus end away from the cell body, whereas in vertebrate dendrites, their orientations are locally mixed. Molecular motors are known to be responsible for cytoskeletal ordering and force generation, but their collective function in the dense MT cytoskeleton of neurites remains elusive. We here hypothesized that both the polarity pattern of MTs along the neurite shaft and the shaft's global extension are simultaneously driven by molecular motor forces and should thus be regulated by the mechanical load acting on the MT array as a whole. To investigate this, we simulated cylindrical bundles of MTs that are cross-linked and powered by molecular motors by iteratively solving a set of force-balance equations. The bundles were subjected to a fixed load arising from actively generated tension in the actomyosin cortex enveloping the MTs. The magnitude of the load and the level of motor-induced connectivity between the MTs have been varied systematically. With an increasing load and decreasing motor-induced connectivity between MTs, the bundles became wider in cross section and extended more slowly, and the local MT orientational order was reduced. These results reveal two, to our knowledge, novel mechanical factors that may underlie the distinctive development of the MT cytoskeleton in axons and dendrites: the cross-linking level of MTs by motors and the load acting on this cytoskeleton during growth.

Published

2019

42. F-actin dynamics regulates mammalian organ growth and cell fate maintenance

Author

Arianna Pocaterra, Marco Montagner, Mariaceleste Aragona, Alejandro Carnicer-Lombarte, Giulia Santinon, Andrea Ghisleni, Gianmaria Pennelli, Francesca Galuppini, Andrea Dimitracopoulos, Nils C. Gauthier, Kristian Franze, Sirio Dupont, Irene Brian, Mattia Forcato, Patrizia Romani, Silvio Bicciato, Paola Braghetta, Dimitracopoulos, Andrea [0000-0001-6776-4214], Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, CAPZ, Stress fiber, Mechanotransduction, Cell Cycle Proteins, Cell fate determination, Protein Serine-Threonine Kinases, Mechanotransduction, Cellular, Capping protein, Focal adhesion, 03 medical and health sciences, Mice, 0302 clinical medicine, Hippo, Conditional gene knockout, Animals, Humans, Hepatocyte cell fate maintenance, Hippo Signaling Pathway, Cells, Cultured, Adaptor Proteins, Signal Transducing, YAP1, CapZ Actin Capping Protein, Mice, Knockout, Hippo signaling pathway, Glucose metabolism, Organ growth, Hepatology, F-actin dynamics, Chemistry, Intracellular Signaling Peptides and Proteins, Gluconeogenesis, CapZ, YAP-Signaling Proteins, Liver homeostasis, Xenobiotic metabolism, YAP, Actins, Elasticity, Cell biology, 030104 developmental biology, Liver, Hepatocytes, 030211 gastroenterology & hepatology, Signal Transduction

Abstract

BACKGROUND & AIMS: In vitro, several data indicate that cell function can be regulated by the mechanical properties of cells and of the microenvironment. Cells measure these features by developing forces via their actomyosin cytoskeleton, and respond accordingly by transducing forces into biochemical signals that instruct cell behavior. Among these, the transcriptional coactivators YAP/TAZ recently emerged as key factors mediating multiple responses to actomyosin contractility. However, whether mechanical cues regulate adult liver tissue homeostasis, and whether this occurs through YAP/TAZ, remains largely unaddressed. METHODS & RESULTS: Here we show that the F-actin capping protein CAPZ is a critical negative regulator of actomyosin contractility and mechanotransduction. Capzb inactivation alters stress fiber and focal adhesion dynamics leading to enhanced myosin activity, increased cellular traction forces, and increased liver stiffness. In vitro, this rescues YAP from inhibition by a small geometry; in vivo, inactivation of Capzb in the adult mouse liver induces YAP activation in parallel to the Hippo pathway, causing extensive hepatocyte proliferation and leading to striking organ overgrowth. Moreover, Capzb is required for the maintenance of the differentiated hepatocyte state, for metabolic zonation, and for gluconeogenesis. In keeping with changes in tissue mechanics, inhibition of the contractility regulator ROCK, or deletion of the Yap1 mechanotransducer, reverse the phenotypes emerging in Capzb-null livers. CONCLUSIONS: These results indicate a previously unrecognized role for CAPZ in tuning the mechanical properties of cells and tissues, which is required in hepatocytes for the maintenance of the differentiated hepatocyte state and to regulate organ size. More in general, it indicates for the first time a physiological role of mechanotransduction in maintaining tissue homeostasis in mammals. LAY SUMMARY: The mechanical properties of cells and tissues (i.e. whether they are soft or stiff) are thought to be important regulators of cell behavior. A recent advancement in our understanding of these phenomena has been the identification of YAP and TAZ as key factors mediating the biological responses of cells to mechanical signals in vitro. However, whether the mechanical properties of cells and/or the mechanical regulation of YAP/TAZ are relevant for mammalian tissue physiology remains unknown. Here we challenge this issue by genetic inactivation of CAPZ, a protein that regulates the cytoskeleton, i.e. the cells' scaffold by which they sense mechanical cues. We found that inactivation of CAPZ alters cells' and liver tissue's mechanical properties, leading to YAP hyperactivation. In turn, this profoundly alters liver physiology, causing organ overgrowth, defects in liver cell differentiation and metabolism. These results reveal a previously uncharacterized role for mechanical signals for the maintenance of adult liver homeostasis.

Published

2019

43. Tissue stiffness at the human maternal–fetal interface

Author

Jake R. Thomas, Jan J. Brosens, Andrew M. Sharkey, Lucy Gardner, Yassen Abbas, Michelle L. Oyen, Alejandro Carnicer-Lombarte, Ashley Moffett, Kristian Franze, and Graham J. Burton

Subjects

animal structures, Placenta, Library science, Microscopy, Atomic Force, blastocyst implantation, Endometrium, 03 medical and health sciences, 0302 clinical medicine, trophoblast invasion, Cell Movement, Pregnancy, Elastic Modulus, Decidua, Humans, Maternal fetal, Social role, tissue stiffness, human, Embryo Implantation, Blastocyst implantation, reproductive and urinary physiology, 030304 developmental biology, Training grant, Reproductive Biology, 0303 health sciences, 030219 obstetrics & reproductive medicine, Infertility therapy, urogenital system, Rehabilitation, Obstetrics and Gynecology, Placentation, Extracellular Matrix, Drug Combinations, Pregnancy Trimester, First, Blastocyst, Tissue specimen, Reproductive Medicine, Vascular flow, embryonic structures, Elasticity Imaging Techniques, Original Article, Female, Proteoglycans, Collagen, Laminin, Tissue stiffness, Psychology, mechanics

Abstract

STUDY QUESTION What is the stiffness (elastic modulus) of human nonpregnant secretory phase endometrium, first trimester decidua, and placenta? SUMMARY ANSWER The stiffness of decidua basalis, the site of placental invasion, was an order of magnitude higher at 103 Pa compared to 102 Pa for decidua parietalis, nonpregnant endometrium and placenta. WHAT IS KNOWN ALREADY Mechanical forces have profound effects on cell behavior, regulating both cell differentiation and migration. Despite their importance, very little is known about their effects on blastocyst implantation and trophoblast migration during placental development because of the lack of mechanical characterization at the human maternal–fetal interface. STUDY DESIGN, SIZE, DURATION An observational study was conducted to measure the stiffness of ex vivo samples of human nonpregnant secretory endometrium (N = 5) and first trimester decidua basalis (N = 6), decidua parietalis (N = 5), and placenta (N = 5). The stiffness of the artificial extracellular matrix (ECM), Matrigel®, commonly used to study migration of extravillous trophoblast (EVT) in three dimensions and to culture endometrial and placental organoids, was also determined (N = 5). PARTICIPANTS/MATERIALS, SETTING, METHODS Atomic force microscopy was used to perform ex vivo direct measurements to determine the stiffness of fresh tissue samples. Decidua was stained by immunohistochemistry (IHC) for HLA-G+ EVT to confirm whether samples were decidua basalis or decidua parietalis. Endometrium was stained with hematoxylin and eosin to confirm the presence of luminal epithelium. Single-cell RNA sequencing data were analyzed to determine expression of ECM transcripts by decidual and placental cells. Fibrillin 1, a protein identified by these data, was stained by IHC in decidua basalis. MAIN RESULTS AND THE ROLE OF CHANCE We observed that decidua basalis was significantly stiffer than decidua parietalis, at 1250 and 171 Pa, respectively (P LARGE SCALE DATA N/A LIMITATIONS, REASONS FOR CAUTION Tissue stiffness was derived by ex vivo measurements on blocks of fresh tissue in the absence of blood flow. The nonpregnant endometrium samples were obtained from women undergoing treatment for infertility. These may not reflect the stiffness of endometrium from normal fertile women. WIDER IMPLICATIONS OF THE FINDINGS These results provide direct measurements of tissue stiffness during the window of implantation and first trimester of human pregnancy. They serve as a basis of future studies exploring the impact of mechanics on embryo implantation and development of the placenta. The findings provide important baseline data to inform matrix stiffness requirements when developing in vitro models of trophoblast stem cell development and migration that more closely resemble the decidua in vivo. STUDY FUNDING/COMPETING INTEREST(S) This work was supported by the Centre for Trophoblast Research, the Wellcome Trust (090108/Z/09/Z, 085992/Z/08/Z), the Medical Research Council (MR/P001092/1), the European Research Council (772426), an Engineering and Physical Sciences Research Council Doctoral Training Award (1354760), a UK Medical Research Council and Sackler Foundation Doctoral Training Grant (RG70550) and a Wellcome Trust Doctoral Studentship (215226/Z/19/Z).

Published

2019

44. Author response: KymoButler, a deep learning software for automated kymograph analysis

Author

Maximilian Ah Jakobs, Kristian Franze, and Andrea Dimitracopoulos

Subjects

Kymograph, Software, business.industry, Computer science, Deep learning, Artificial intelligence, Software engineering, business

Published

2018

45. Mechanochemical Crosstalk Produces Cell-Intrinsic Patterning of the Cortex to Orient the Mitotic Spindle

Author

Oscar M. Lancaster, Matthieu Piel, Buzz Baum, Pragya Srivastava, Guillaume Salbreux, Roie Shlomovitz, Maël Le Berre, Andrea Dimitracopoulos, Kristian Franze, Zaw Win, Agathe Chaigne, University College of London [London] (UCL), Biologie Cellulaire et Cancer, Institut Curie [Paris]-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), University of Cambridge [UK] (CAM), and The Francis Crick Institute [London]

Subjects

0301 basic medicine, Dynein, Mitosis, Spindle Apparatus, [SDV.BC]Life Sciences [q-bio]/Cellular Biology, Biology, Mechanotransduction, Cellular, Microtubules, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Humans, Dyneins, Cell biology, Chromatin, Spindle apparatus, 030104 developmental biology, Ran, Interphase, General Agricultural and Biological Sciences, Astral microtubules, 030217 neurology & neurosurgery, HeLa Cells, Signal Transduction

Abstract

International audience; Proliferating animal cells are able to orient their mitotic spindles along their interphase cell axis, setting up the axis of cell division, despite rounding up as they enter mitosis. This has previously been attributed to molecular memory and, more specifically, to the maintenance of adhesions and retraction fibers in mitosis [1-6], which are thought to act as local cues that pattern cortical Gαi, LGN, and nuclear mitotic apparatus protein (NuMA) [3, 7-18]. This cortical machinery then recruits and activates Dynein motors, which pull on astral microtubules to position the mitotic spindle. Here, we reveal a dynamic two-way crosstalk between the spindle and cortical motor complexes that depends on a Ran-guanosine triphosphate (GTP) signal [12], which is sufficient to drive continuous monopolar spindle motion independently of adhesive cues in flattened human cells in culture. Building on previous work [1, 12, 19-23], we implemented a physical model of the system that recapitulates the observed spindle-cortex interactions. Strikingly, when this model was used to study spindle dynamics in cells entering mitosis, the chromatin-based signal was found to preferentially clear force generators from the short cell axis, so that cortical motors pulling on astral microtubules align bipolar spindles with the interphase long cell axis, without requiring a fixed cue or a physical memory of interphase shape. Thus, our analysis shows that the ability of chromatin to pattern the cortex during the process of mitotic rounding is sufficient to translate interphase shape into a cortical pattern that can be read by the spindle, which then guides the axis of cell division.

Published

2020

46. Microtubule Polarity in Axons is Sorted by a Molecular Gradient of Dynactin

Author

Kristian Franze and Maximilian Ah Jakobs

Subjects

Polarity (physics), Chemistry, Microtubule, Biophysics, Dynactin

Published

2020

47. Measuring the Effect of Substrate Stiffness on Cell Membrane Tension Using Optical Tweezers

Author

Kristian Franze, Jeffrey Mc Hugh, Eva Kreysing, Sarah Foster, Kurt Andresen, and Ulrich F. Keyser

Subjects

Cell membrane, medicine.anatomical_structure, Materials science, Optical tweezers, Tension (physics), Biophysics, medicine, Substrate stiffness, Composite material

Published

2020

48. Predicting local tissue mechanics using immunohistochemistry

Author

Kristian Franze, David E. Koser, Emadaldin Moeendarbary, and Stefanie Kuerten

Subjects

Myelin, medicine.anatomical_structure, Materials science, Atomic force microscopy, Nervous tissue, Cell density, medicine, Immunohistochemistry, Stiffness, Tissue mechanics, medicine.symptom, Spinal cord, Biomedical engineering

Abstract

Local tissue stiffness provides an important signal to which cells respond in vivo. However, assessing tissue mechanics is currently challenging and requires sophisticated technology. We here developed a model quantitatively predicting nervous tissue stiffness heterogeneities at cellular resolution based on cell density, myelin and GFAP fluorescence intensities. These histological parameters were identified by a correlation analysis of atomic force microscopy-based elasticity maps of spinal cord sections and immunohistochemical stainings. Our model provides a simple tool to estimate local stiffness distributions in nervous tissue, and it can easily be expanded to other tissue types, thus paving the way for studies of the role of mechanical signals in development and pathology.

Published

2018

49. Rapid changes in tissue mechanics regulate cell behaviour in the developing embryonic brain

Author

Amelia J, Thompson, Eva K, Pillai, Ivan B, Dimov, Sarah K, Foster, Christine E, Holt, and Kristian, Franze

Subjects

musculoskeletal diseases, Retinal Ganglion Cells, animal structures, Embryo, Nonmammalian, Xenopus, Short Report, durotaxis, Mitosis, Cell Count, macromolecular substances, Physics of Living Systems, Xenopus laevis, stiffness, Animals, Optic Tract, mechanotransduction, atomic force microscopy, axon guidance, technology, industry, and agriculture, Brain, Axons, Biomechanical Phenomena, body regions, Cell Body, mechanics, Developmental Biology

Abstract

Tissue mechanics is important for development; however, the spatio-temporal dynamics of in vivo tissue stiffness is still poorly understood. We here developed tiv-AFM, combining time-lapse in vivo atomic force microscopy with upright fluorescence imaging of embryonic tissue, to show that during development local tissue stiffness changes significantly within tens of minutes. Within this time frame, a stiffness gradient arose in the developing Xenopus brain, and retinal ganglion cell axons turned to follow this gradient. Changes in local tissue stiffness were largely governed by cell proliferation, as perturbation of mitosis diminished both the stiffness gradient and the caudal turn of axons found in control brains. Hence, we identified a close relationship between the dynamics of tissue mechanics and developmental processes, underpinning the importance of time-resolved stiffness measurements., eLife digest Neurons in the brain form an intricate network that follows a precise template. For example, in a young frog embryo, the neurons from the eyes send out thin structures, called axons, which navigate along a well-defined path and eventually connect with the visual centres of the brain. This journey requires the axons to take a sharp turn so they can wire with the right brain structures. Axons find their paths not only by following chemical signals but also by reacting to the stiffness of their environment. In an older frog embryo for instance, the brain is stiffer at the front, and softer at the back. As neurons from the eyes make their way through the brain, they turn to follow this gradient, moving away from stiffer areas towards the softer regions. Here, Thompson, Pillai et al. investigate when and how this stiffness gradient is established in frogs. To do so, a new technique was developed. Called time-lapse in vivo atomic force microscopy, the method measures how brain stiffness changes over time in a live embryo, while also taking images of the growing axons. The experiments show that the stiffness gradient arose within tens of minutes, just as the first ‘pioneering’ axons from the eyes began to grow across the brain. These axons then responded to the gradient, turning towards the softer tissue. Changes in the number of cells in the underlying brain tissue governed the formation of the gradient, with rapidly stiffening areas containing more cells than those that remained soft. In fact, using drugs that stop cells from dividing reduced both the mechanical gradient and the turning response of the axons. The technique developed by Thompson, Pillai et al. is a useful tool that can help elucidate how variations in stiffness control the brain wiring process. It could also be used to look into how other developmental or regenerative processes, such as the way neurons reconnect after injuries to the brain or spinal cord, may be regulated by mechanical tissue properties.

Published

2018

50. Simultaneous in vivo time-lapse stiffness mapping and fluorescence imaging of developing tissue

Author

Kristian Franze, Eva K Pillai, Ivan B Dimov, Amelia J Thompson, and Christine E. Holt

Subjects

0303 health sciences, Fluorescence-lifetime imaging microscopy, biology, Chemistry, Dynamics (mechanics), Xenopus, Stiffness, Embryonic Tissue, biology.organism_classification, 03 medical and health sciences, 0302 clinical medicine, In vivo, medicine, Biophysics, Tissue mechanics, Tissue stiffness, medicine.symptom, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Tissue mechanics is important for development; however, the spatio-temporal dynamics of in vivo tissue stiffness is still poorly understood. We here developed tiv-AFM, combining time-lapse in vivo atomic force microscopy with upright fluorescence imaging of embryonic tissue, to show that in the developing Xenopus brain, a stiffness gradient evolves over time because of differential cell proliferation. Subsequently, axons turn to follow this gradient, underpinning the importance of time-resolved mechanics measurements.

Published

2018