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

51. Tissue stiffening coordinates morphogenesis by triggering collective cell migration in vivo

Author

Elias H. Barriga, Roberto Mayor, Kristian Franze, Guillaume Charras, Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Integrins, Mesoderm, Epithelial-Mesenchymal Transition, animal structures, Population, Morphogenesis, Biology, Cardiovascular System, Mechanotransduction, Cellular, Article, Xenopus laevis, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, Hardness, medicine, Animals, Epithelial–mesenchymal transition, Mechanotransduction, education, education.field_of_study, Multidisciplinary, Convergent extension, Gastrulation, Neural crest, Extracellular Matrix, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Neural Crest, embryonic structures, Female, 030217 neurology & neurosurgery

Abstract

Collective cell migration is essential for morphogenesis, tissue remodelling and cancer invasion. In vivo, groups of cells move in an orchestrated way through tissues. This movement involves mechanical as well as molecular interactions between cells and their environment. While the role of molecular signals in collective cell migration is comparatively well understood, how tissue mechanics influence collective cell migration in vivo remains unknown. Here we investigated the importance of mechanical cues in the collective migration of the Xenopus laevis neural crest cells, an embryonic cell population whose migratory behaviour has been likened to cancer invasion. We found that, during morphogenesis, the head mesoderm underlying the cephalic neural crest stiffens. This stiffening initiates an epithelial-to-mesenchymal transition in neural crest cells and triggers their collective migration. To detect changes in their mechanical environment, neural crest cells use mechanosensation mediated by the integrin-vinculin-talin complex. By performing mechanical and molecular manipulations, we show that mesoderm stiffening is necessary and sufficient to trigger neural crest migration. Finally, we demonstrate that convergent extension of the mesoderm, which starts during gastrulation, leads to increased mesoderm stiffness by increasing the cell density underneath the neural crest. These results show that convergent extension of the mesoderm has a role as a mechanical coordinator of morphogenesis, and reveal a link between two apparently unconnected processes-gastrulation and neural crest migration-via changes in tissue mechanics. Overall, we demonstrate that changes in substrate stiffness can trigger collective cell migration by promoting epithelial-to-mesenchymal transition in vivo. More broadly, our results raise the idea that tissue mechanics combines with molecular effectors to coordinate morphogenesis.

Published

2018

52. The role of cell body density in ruminant retina mechanics assessed by atomic force and Brillouin microscopy

Author

Isabell P, Weber, Seok Hyun, Yun, Giuliano, Scarcelli, and Kristian, Franze

Subjects

Elastic Modulus, Animals, Reproducibility of Results, sense organs, Microscopy, Atomic Force, Retina, Sheep, Domestic, Article, Biomechanical Phenomena

Abstract

Cells in the central nervous system (CNS) respond to the stiffness of their environment. CNS tissue is mechanically highly heterogeneous, thus providing motile cells with region-specific mechanical signals. While CNS mechanics has been measured with a variety of techniques, reported values of tissue stiffness vary greatly, and the morphological structures underlying spatial changes in tissue stiffness remain poorly understood. We here exploited two complementary techniques, contact-based atomic force microscopy and contact-free Brillouin microscopy, to determine the mechanical properties of ruminant retinae, which are built up by different tissue layers. As in all vertebrate retinae, layers of high cell body densities (‘nuclear layers’) alternate with layers of low cell body densities (‘plexiform layers’). Different tissue layers varied significantly in their mechanical properties, with the photoreceptor layer being the stiffest region of the retina, and the inner plexiform layer belonging to the softest regions. As both techniques yielded similar results, our measurements allowed us to calibrate the Brillouin microscopy measurements and convert the Brillouin shift into a quantitative assessment of elastic tissue stiffness with optical resolution. Similar as in the mouse spinal cord and the developing Xenopus brain, we found a strong correlation between nuclear densities and tissue stiffness. Hence, the cellular composition of retinae appears to strongly contribute to local tissue stiffness, and Brillouin microscopy shows a great potential for the application in vivo to measure the mechanical properties of transparent tissues.

Published

2017

53. Laminin levels regulate tissue migration and anterior-posterior polarity during egg morphogenesis in Drosophila

Author

Acaimo González-Reyes, Federico Zurita, Emad Moeendarbary, María D. Martín-Bermudo, Kristian Franze, Alicia E. Rosales-Nieves, Alfonsa Díaz-Torres, María del Carmen Díaz de la Loza, Medical Research Council (UK), European Commission, Ministerio de Economía y Competitividad (España), Junta de Andalucía, Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Integrins, integrin, Integrin, Morphogenesis, collective migration, Biology, General Biochemistry, Genetics and Molecular Biology, Basement Membrane, Article, 03 medical and health sciences, 0302 clinical medicine, Oogenesis, Ovarian Follicle, laminin, Laminin, Cell Movement, Cell polarity, medicine, Animals, Drosophila Proteins, lcsh:QH301-705.5, Basement membrane, anterior-posterior polarity, Tissue migration, Cell Polarity, epithelial migration, Cell biology, 030104 developmental biology, medicine.anatomical_structure, lcsh:Biology (General), Drosophila oogenesis, Ultrastructure, biology.protein, Drosophila, Female, 030217 neurology & neurosurgery, Drosophila Protein

Abstract

Summary 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., Graphical Abstract, Highlights • Follicle cells with constant integrin levels face increasing laminin in fly oogenesis • Integrin-laminin levels fix the timing and speed of egg chamber rotation in vivo • Laminin depletion affects the ultrastructure and biophysical properties of the ECM • Laminin depletion results in anterior-posterior misorientation of developing follicles, Collective cell migration requires cell-ECM interactions. Using the fruit fly ovary, Díaz de la Loza et al. find that the ECM component laminin controls the onset and speed of epithelial sheet migration. Because laminin depletion also results in aberrant anterior-posterior polarity, laminin regulates coordinated migration during organogenesis and maintains axial polarity.

Published

2017

54. How mechanics orchestrate morphogenesis: Mesodermal stiffening triggers neural crest migration in vivo

Author

Elias H. Barriga, Guillaume Charras, Kristian Franze, and Roberto Mayor

Subjects

0301 basic medicine, 03 medical and health sciences, Embryology, 030104 developmental biology, In vivo, Morphogenesis, Neural crest, Biology, Developmental biology, Developmental Biology, Cell biology, Stiffening

Published

2017

55. How light traverses the inverted vertebrate retina

Author

Kristian Franze, Mike Francke, Andreas Reichenbach, and Silke Agte

Subjects

Retina, Visual acuity, Optical fiber, genetic structures, Pixel, business.industry, Scattering, Retinal, Anatomy, Biology, eye diseases, Light scattering, Photoreceptor cell, law.invention, chemistry.chemical_compound, Optics, medicine.anatomical_structure, chemistry, law, medicine, sense organs, medicine.symptom, business

Abstract

In our eyes, as in the eyes of all vertebrates, images of the environment are projected on­to an inverted retina, where photons must pass through most of the retinal layers before being captured by the light-sensitive cells. Light scattering in these retinal layers must decrease the signal-to-noise ratio of the im­ages and thus interfere with clear vision. Sur­prisingly however, our eyes display splendid visual abilities. This apparent contradiction could be resolved if intraretinal light scatter­ing were to be minimized by built-in opti­cal elements that facilitate light transmission through the tissue. Indeed, we were able to show that one function of radial glial (Mül­ler) cells is to act as effective optical fibers in the living retina, bypassing the light-scatter­ing structures in front of the light-sensitive cells. Each Müller cell serves as a ‘private’ light cable, providing one individual cone photo­receptor cell with its appropriate pixel of the environmental image, thus optimizing spe­cial resolution and visual acuity.

Published

2014

56. Brain tissue stiffness regulates neuronal development and function

Author

Kristian Franze

Subjects

General Neuroscience, medicine, Stiffness, Brain tissue, Biology, medicine.symptom, Neuroscience, Function (biology)

Published

2019

57. Author Correction: Niche stiffness underlies the ageing of central nervous system progenitor cells

Author

Björn Neumann, David H. Rowitch, Chibeza C. Agley, Chao Zhao, Robin J.M. Franklin, Isabell P. Weber, Carlo Viscomi, Staffan Holmqvist, Amelia J Thompson, Kevin J. Chalut, Myfanwy Hill, Michael Segel, Amar Sharma, Kristian Franze, Ginez A. Gonzalez, and Adam Young

Subjects

Multidisciplinary, medicine.anatomical_structure, Ageing, Central nervous system, Niche, medicine, Stiffness, Biology, medicine.symptom, Progenitor cell, Neuroscience

Published

2019

58. Mechanics in Neuronal Development and Repair

Author

Jochen Guck, Paul A. Janmey, and Kristian Franze

Subjects

Central Nervous System, Nervous system, Multiple Sclerosis, Central nervous system, Biomedical Engineering, Medicine (miscellaneous), Biomechanical Phenomena, Animals, Humans, Medicine, Cytoskeleton, Spinal Cord Injuries, Neurons, Neuromechanics, business.industry, Multiple sclerosis, Nervous tissue, Brain, medicine.disease, Axons, Elasticity, Extracellular Matrix, Normal functioning, medicine.anatomical_structure, Spinal Cord, Neuroglia, Stress, Mechanical, business, Neuroscience, Signal Transduction, Biomedical engineering

Abstract

Biological cells are well known to respond to a multitude of chemical signals. In the nervous system, chemical signaling has been shown to be crucially involved in development, normal functioning, and disorders of neurons and glial cells. However, there are an increasing number of studies showing that these cells also respond to mechanical cues. Here, we summarize current knowledge about the mechanical properties of nervous tissue and its building blocks, review recent progress in methodology and understanding of cellular mechanosensitivity in the nervous system, and provide an outlook on the implications of neuromechanics for future developments in biomedical engineering to aid overcoming some of the most devastating and currently incurable CNS pathologies such as spinal cord injuries and multiple sclerosis.

Published

2013

59. 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

Central Nervous System, Collagen Type IV, Neurons, Neocortex, Microscopy, Atomic Force, Article, Nerve Regeneration, Rats, Cicatrix, nervous system, Spinal Cord, Glial Fibrillary Acidic Protein, Animals, Vimentin, Female, Laminin, Neuroglia

Abstract

Injury to the central nervous system (CNS) alters the molecular and cellular composition of neural tissue and leads to glial scarring, which inhibits the regrowth of damaged axons. Mammalian glial scars supposedly form a chemical and mechanical barrier to neuronal regeneration. While tremendous effort has been devoted to identifying molecular characteristics of the scar, very little is known about its mechanical properties. Here we characterize spatiotemporal changes of the elastic stiffness of the injured rat neocortex and spinal cord at 1.5 and three weeks post-injury using atomic force microscopy. In contrast to scars in other mammalian tissues, CNS tissue significantly softens after injury. Expression levels of glial intermediate filaments (GFAP, vimentin) and extracellular matrix components (laminin, collagen IV) correlate with tissue softening. As tissue stiffness is a regulator of neuronal growth, our results may help to understand why mammalian neurons do not regenerate after injury., 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

2016

60. Long-term imaging of cellular forces with high precision by elastic resonator interference stress microscopy

Author

Simon J. Powis, Johanna A. Knipper, Malte C. Gather, Giuliano Scarcelli, Jessica G. Borger, Anja Steude, Kristian Franze, Nils M. Kronenberg, Philipp Liehm, European Research Council, University of St Andrews. School of Physics and Astronomy, University of St Andrews. School of Medicine, University of St Andrews. Biomedical Sciences Research Complex, and University of St Andrews. Cellular Medicine Division

Subjects

0301 basic medicine, Time Factors, QH301 Biology, T-Lymphocytes, Displacement (vector), Mice, 0302 clinical medicine, Interference (communication), Cell Movement, Microscopy, Dictyostelium, R2C, QC, 0303 health sciences, Mice, Inbred BALB C, Microscopy, Video, Resolution (electron density), 3T3 Cells, Cell biology, Biomechanical Phenomena, Extracellular Matrix, Podosomes, BDC, Biological system, Materials science, Mice, Transgenic, Time-Lapse Imaging, Stress (mechanics), QH301, 03 medical and health sciences, Resonator, Optics, Cell Adhesion, Animals, Humans, Microscopy, Interference, Sensitivity (control systems), 030304 developmental biology, business.industry, Macrophages, DAS, Cell Biology, Fibroblasts, Frame rate, T Technology, Elasticity, QC Physics, 030104 developmental biology, Stress, Mechanical, business, 030217 neurology & neurosurgery

Abstract

This project has received funding from the Human Frontiers Science Program (RGY0074/2013), the Scottish Funding Council (via SUPA), the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 640012), the EPSRC DTP (EP/L505079/1), the RS MacDonald Charitable Trust and the MRC (G1100116 and G110312/1). Cellular forces are crucial for many biological processes but current methods to image them have limitations with respect to data analysis, resolution and throughput. Here, we present a robust approach to measure mechanical cell–substrate interactions in diverse biological systems by interferometrically detecting deformations of an elastic micro-cavity. Elastic resonator interference stress microscopy (ERISM) yields stress maps with exceptional precision and large dynamic range (2 nm displacement resolution over a >1 μm range, translating into 1 pN force sensitivity). This enables investigation of minute vertical stresses (

Published

2016

61. Fumarate is an epigenetic modifier that elicits epithelial-to-mesenchymal transition

Author

Timothy Isaac Johnson, Christian Frezza, Maxine Gia Binh Mg Tran, Patrick H. Maxwell, Simone Cardaci, Pedro R. Cutillas, Eamonn R. Maher, Haiyang Yun, Emanuel Gonçalves, Anne Y. Warren, Alizee Vercauteren Drubbel, Julio Saez-Rodriguez, Eyal Gottlieb, Sebastian Julian Theobald, Vincent J. Gnanapragasam, Brian J. P. Huntly, Sandra R Abbo, Vincent Zecchini, Ana S. H. Costa, Edoardo Gaude, Kristian Franze, Sarah Foster, Marco Sciacovelli, Vinothini Rajeeve, Warren, Anne [0000-0002-1170-7867], Gnanapragasam, Vincent [0000-0003-4722-4207], Franze, Kristian [0000-0002-8425-7297], Huntly, Brian [0000-0003-0312-161X], Maher, Eamonn [0000-0002-6226-6918], Maxwell, Patrick [0000-0002-0338-2679], Frezza, Christian [0000-0002-3293-7397], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Epithelial-Mesenchymal Transition, Cell, Biology, medicine.disease_cause, Epigenesis, Genetic, Fumarate Hydratase, Mesoderm, Mice, 03 medical and health sciences, Fumarates, Cell Movement, microRNA, medicine, Animals, Humans, Life Science, Epithelial–mesenchymal transition, Epigenetics, Transcription factor, Cells, Cultured, Multidisciplinary, Kidney Neoplasms, 3. Good health, MicroRNAs, HEK293 Cells, 030104 developmental biology, Histone, medicine.anatomical_structure, Biochemistry, Fumarase, biology.protein, Cancer research, Transcriptome, Carcinogenesis, Transcription Factors

Abstract

Mutations of the tricarboxylic acid cycle enzyme fumarate hydratase cause hereditary leiomyomatosis and renal cell cancer1. Fumarate hydratase-deficient renal cancers are highly aggressive and metastasize even when small, leading to a very poor clinical outcome2. Fumarate, a small molecule metabolite that accumulates in fumarate hydratase-deficient cells, plays a key role in cell transformation, making it a bona fide oncometabolite3. Fumarate has been shown to inhibit α-ketoglutarate-dependent dioxygenases that are involved in DNA and histone demethylation4, 5. However, the link between fumarate accumulation, epigenetic changes, and tumorigenesis is unclear. Here we show that loss of fumarate hydratase and the subsequent accumulation of fumarate in mouse and human cells elicits an epithelial-to-mesenchymal-transition (EMT), a phenotypic switch associated with cancer initiation, invasion, and metastasis6. We demonstrate that fumarate inhibits Tet-mediated demethylation of a regulatory region of the antimetastatic miRNA cluster6 mir-200ba429, leading to the expression of EMT-related transcription factors and enhanced migratory properties. These epigenetic and phenotypic changes are recapitulated by the incubation of fumarate hydratase-proficient cells with cell-permeable fumarate. Loss of fumarate hydratase is associated with suppression of miR-200 and the EMT signature in renal cancer and is associated with poor clinical outcome. These results imply that loss of fumarate hydratase and fumarate accumulation contribute to the aggressive features of fumarate hydratase-deficient tumours.

Published

2016

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

Author

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

Subjects

Retinal Ganglion Cells, 0301 basic medicine, Nervous system, Neurogenesis, durotaxis, Biology, Mechanotransduction, Cellular, Retina, Article, biomechanics, Xenopus laevis, 03 medical and health sciences, Mechanosensitive ion channel, brain stiffness, medicine, Animals, Visual Pathways, Mechanotransduction, Zebrafish, axon guidance, General Neuroscience, PIEZO1, stiffness gradient, Brain, CÉREBRO, mechanosensitivity, Axons, 3. Good health, 030104 developmental biology, medicine.anatomical_structure, nervous system, Retinal ganglion cell, Mechanosensitive channels, Axon guidance, stretch-activated ion channels, AFM, Neuroscience

Abstract

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

Published

2016

63. Complex Stiffness Gradient Substrates for Studying Mechanotactic Cell Migration

Author

Kristian Franze, Cheng-Hwa R. Kuo, Easan Sivaniah, James D. Brenton, and Jian Xian

Subjects

musculoskeletal diseases, animal structures, Materials science, Surface Properties, Polyacrylamide, Acrylic Resins, Mechanotransduction, Cellular, Mice, chemistry.chemical_compound, Cell Movement, Elastic Modulus, medicine, Animals, General Materials Science, Composite material, Elastic modulus, Durotaxis, Atomic force microscopy, Mechanical Engineering, Stiffness, Cell migration, 3T3 Cells, equipment and supplies, musculoskeletal system, body regions, chemistry, Mechanics of Materials, medicine.symptom, Layer (electronics)

Abstract

Polyacrylamide gels are cast upon a stiff support with controlled topography, resulting in a thin gel layer of variable height. The topographical profiles project a stiffness map onto the gel, resulting in controlled linear and non-linear 2D stiffness gradients. Fibroblasts, which migrate towards stiffer substrates, accumulate in areas with a gel thickness below 15 μm.

Published

2012

64. Reversible Switching between Superhydrophobic States on a Hierarchically Structured Surface

Author

Lauri Sainiemi, Sami Franssila, Tuukka Verho, Chris Bower, Pierce Andrew, Kristian Franze, Robin H. A. Ras, Juuso T. Korhonen, Ville Jokinen, Olli Ikkala, Perustieteiden korkeakoulu, School of Science, Department of Applied Physics, Teknillisen fysiikan laitos, Aalto-yliopisto, and Aalto University

Subjects

Surface (mathematics), Engineering, reversible transition, ta221, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, silicone nanofilaments, Contact angle, two-tier, optical data storage, ta216, contact angle, ta218, micropillars, wetting, Multidisciplinary, ta214, ta114, business.industry, Physics, bistable, 021001 nanoscience & nanotechnology, Trapped air, Materials science, 0104 chemical sciences, Chemistry, Wetting transition, Physical Sciences, Wetting, 0210 nano-technology, business, Science, technology and society, superhydrophobicity

Abstract

Nature offers exciting examples for functional wetting properties based on superhydrophobicity, such as the self-cleaning surfaces on plant leaves and trapped air on immersed insect surfaces allowing underwater breathing. They inspire biomimetic approaches in science and technology. Superhydrophobicity relies on the Cassie wetting state where air is trapped within the surface topography. Pressure can trigger an irreversible transition from the Cassie state to the Wenzel state with no trapped air—this transition is usually detrimental for nonwetting functionality and is to be avoided. Here we present a new type of reversible, localized and instantaneous transition between two Cassie wetting states, enabled by two-level (dual-scale) topography of a superhydrophobic surface, that allows writing, erasing, rewriting and storing of optically displayed information in plastrons related to different length scales.

Published

2012

65. Atomic force microscopy and its contribution to understanding the development of the nervous system

Author

Kristian Franze

Subjects

Nervous system, Atomic force microscopy, Models, Neurological, High resolution, Biology, Microscopy, Atomic Force, Nervous System, medicine.anatomical_structure, Microscopy, Genetics, medicine, Biophysics, Animals, Humans, Neuroscience, Developmental Biology

Abstract

While our understanding of the influence of biochemical signaling on cell functioning is increasing rapidly, the consequences of mechanical signaling are currently poorly understood. However, cells of the nervous system respond to their mechanical environment; their mechanosensitivity has important implications for development and disease. Atomic force microscopy provides a powerful technique to investigate the mechanical interaction of cells with their environment with high resolution. This method can be used to obtain high-resolution surface topographies, stiffness maps, and apply well-defined forces to samples at different length scales. This review summarizes recent advances of atomic force microscopy, provides an overview about state-of-the-art measurements, and suggests directions for future applications to investigate the involvement of mechanics in the development of the nervous system.

Published

2011

66. Growth cones as soft and weak force generators

Author

Daniel Koch, Josef A. Käs, Yun-Bi Lu, Timo Betz, and Kristian Franze

Subjects

genetic structures, Neurogenesis, Growth Cones, Viscoelasticity, Optics, medicine, Animals, Humans, Elasticity (economics), Growth cone, Cytoskeleton, Multidisciplinary, Tractive force, Viscosity, Chemistry, business.industry, Stiffness, Mechanics, Actin cytoskeleton, Actins, Elasticity, Biomechanical Phenomena, Physical Sciences, sense organs, Lamellipodium, medicine.symptom, business

Abstract

Many biochemical processes in the growth cone finally target its biomechanical properties, such as stiffness and force generation, and thus permit and control growth cone movement. Despite the immense progress in our understanding of biochemical processes regulating neuronal growth, growth cone biomechanics remains poorly understood. Here, we combine different experimental approaches to measure the structural and mechanical properties of a growth cone and to simultaneously determine its actin dynamics and traction force generation. Using fundamental physical relations, we exploited these measurements to determine the internal forces generated by the actin cytoskeleton in the lamellipodium. We found that, at timescales longer than the viscoelastic relaxation time of τ = 8.5 ± 0.5 sec, growth cones show liquid-like characteristics, whereas at shorter time scales they behaved elastically with a surprisingly low elastic modulus of E = 106 ± 21 Pa. Considering the growth cone’s mechanical properties and retrograde actin flow, we determined the internal stress to be on the order of 30 pN per μm 2 . Traction force measurements confirmed these values. Hence, our results indicate that growth cones are particularly soft and weak structures that may be very sensitive to the mechanical properties of their environment.

Published

2011

67. The Integration of Mechanical and Chemical Signalling in the Developing Brain

Author

Kristian Franze

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, Chemistry, Chemical signalling, Biophysics, 02 engineering and technology, 021001 nanoscience & nanotechnology, 0210 nano-technology, Neuroscience

Published

2018

68. Force Generation by Molecular-Motor-Powered Microtubule Bundles; Implications for Neuronal Polarization and Growth

Author

Kristian Franze, Assaf Zemel, Maximilian Ah Jakobs, Jakobs, Maximilian [0000-0002-0879-7937], Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

Physics, Force generation, Dynamics (mechanics), neuronal polarization, molecular motors, lcsh:RC321-571, Quantitative Biology::Subcellular Processes, microtubules, Cellular and Molecular Neuroscience, axon outgrowth, Microtubule, Bundle, Percolation, Molecular motor, Biophysics, force generation, Cytoskeleton, Polarization (electrochemistry), Neuroscience, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Original Research

Abstract

The heavily cross-linked microtubule (MT) bundles found in neuronal processes play a central role in the initiation, growth and maturation of axons and dendrites; however, a quantitative understanding of their mechanical function is still lacking. We here developed computer simulations to investigate the dynamics of force generation in 1D bundles of MTs that are cross-linked and powered by molecular motors. The motion of filaments and the forces they exert are investigated as a function of the motor type (unipolar or bipolar), MT density and length, applied load, and motor connectivity. We demonstrate that only unipolar motors (e.g., kinesin-1) can provide the driving force for bundle expansion, while bipolar motors (e.g., kinesin-5) oppose it. The force generation capacity of the bundles is shown to depend sharply on the fraction of unipolar motors due to a percolation transition that must occur in the bundle. Scaling laws between bundle length, force, MT length and motor fraction are presented. In addition, we investigate the dynamics of growth in the presence of a constant influx of MTs. Beyond a short equilibration period, the bundles grow linearly in time. In this growth regime, the bundle extends as one mass forward with most filaments sliding with the growth velocity. The growth velocity is shown to be dictated by the inward flux of MTs, to inversely scale with the load and to be independent of the free velocity of the motors. These findings provide important molecular-level insights into the mechanical function of the MT cytoskeleton in normal axon growth and regeneration after injury.

Published

2015

69. Muller glia provide essential tensile strength to the developing retina

Author

Julia Oswald, Ryan B. MacDonald, Takeshi Yoshimatsu, William A. Harris, Owen Randlett, and Kristian Franze

Subjects

genetic structures, Central nervous system, Ependymoglial Cells, Retinoschisis, Biology, Microscopy, Atomic Force, Retina, In vivo, Tensile Strength, Report, medicine, Animals, Zebrafish, Research Articles, Cell Biology, Anatomy, medicine.disease, biology.organism_classification, eye diseases, Cell biology, medicine.anatomical_structure, nervous system, Neuroglia, sense organs, Muller glia

Abstract

When the formation of Müller glia is inhibited in the zebrafish retina, a major consequence is that the retina begins to rip apart due to a loss of the mechanical resilience that these glial cells provide to the neural tissue., To investigate the cellular basis of tissue integrity in a vertebrate central nervous system (CNS) tissue, we eliminated Müller glial cells (MG) from the zebrafish retina. For well over a century, glial cells have been ascribed a mechanical role in the support of neural tissues, yet this idea has not been specifically tested in vivo. We report here that retinas devoid of MG rip apart, a defect known as retinoschisis. Using atomic force microscopy, we show that retinas without MG have decreased resistance to tensile stress and are softer than controls. Laser ablation of MG processes showed that these cells are under tension in the tissue. Thus, we propose that MG act like springs that hold the neural retina together, finally confirming an active mechanical role of glial cells in the CNS.

Published

2015

70. Microglia mechanics : immune activation alters traction forces and durotaxis

Author

Rajesh Shahapure, Elke Ulbricht, Kristian Franze, Hélène O. B. Gautier, Malte C. Gather, David E. Koser, Giuliano Scarcelli, Gerhard Holzapfel, Lars Bollmann, Human Frontiers Science Programme, University of St Andrews. School of Physics and Astronomy, University of St Andrews. Biomedical Sciences Research Complex, Franze, Kristian [0000-0002-8425-7297], and Apollo - University of Cambridge Repository

Subjects

LPS, medicine.medical_treatment, education, NDAS, Random walk, migration, Traction force microscopy, lcsh:RC321-571, foreign body reaction, random walk, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Foreign body reaction, medicine, biased random walk, Gliosis, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Migration, 030304 developmental biology, Original Research, 0303 health sciences, Durotaxis, Microglia, Chemistry, mechanotaxis, Stiffness, Traction (orthopedics), Actin cytoskeleton, Mechanotaxis, medicine.anatomical_structure, gliosis, Biased random walk, Biophysics, RC0321, medicine.symptom, CNS, Neuroscience, RC0321 Neuroscience. Biological psychiatry. Neuropsychiatry, 030217 neurology & neurosurgery, Microglial cells

Abstract

This work was supported by the Austrian Agency for International Cooperation in Education and Research (Scholarship to LB), Faculty of Computer Science and Biomedical Engineering at Graz University of Technology (Scholarship to LB), German National Academic Foundation (Scholarship to DK), Wellcome Trust/University of Cambridge Institutional Strategic Support Fund (Research Grant to KF), Isaac Newton Trust (Research Grant 14.07 (m) to KF), Leverhulme Trust (Research Project Grant RPG-2014-217 to KF), UK Medical Research Council (Career Development Award to KF), and the Human Frontier Science Program (Young Investigator Grant RGY0074/2013 to GS, MG, and KF). Date of Acceptance: 31/08/2015 Microglial cells are key players in the primary immune response of the central nervous system. They are highly active and motile cells that chemically and mechanically interact with their environment. While the impact of chemical signaling on microglia function has been studied in much detail, the current understanding of mechanical signaling is very limited. When cultured on compliant substrates, primary microglial cells adapted their spread area, morphology, and actin cytoskeleton to the stiffness of their environment. Traction force microscopy revealed that forces exerted by microglia increase with substrate stiffness until reaching a plateau at a shear modulus of ~5 kPa. When cultured on substrates incorporating stiffness gradients, microglia preferentially migrated toward stiffer regions, a process termed durotaxis. Lipopolysaccharide-induced immune-activation of microglia led to changes in traction forces, increased migration velocities and an amplification of durotaxis. We finally developed a mathematical model connecting traction forces with the durotactic behavior of migrating microglial cells. Our results demonstrate that microglia are susceptible to mechanical signals, which could be important during central nervous system development and pathologies. Stiffness gradients in tissue surrounding neural implants such as electrodes, for example, could mechanically attract microglial cells, thus facilitating foreign body reactions detrimental to electrode functioning. Publisher PDF

Published

2015

71. Atomic force microscopy-based force measurements on animal cells and tissues

Author

Hélène O B, Gautier, Amelia J, Thompson, Sarra, Achouri, David E, Koser, Kathrin, Holtzmann, Emad, Moeendarbary, and Kristian, Franze

Subjects

Organ Specificity, Cells, Optical Imaging, Adhesiveness, Animals, Humans, Microscopy, Atomic Force, Biomechanical Phenomena

Abstract

During development, normal functioning, as well as in certain pathological conditions, cells are influenced not only by biochemical but also by mechanical signals. Over the past two decades, atomic force microscopy (AFM) has become one of the key tools to investigate the mechanical properties and interactions of biological samples. AFM studies have provided important insights into the role of mechanical signaling in different biological processes. In this chapter, we introduce different applications of AFM-based force measurements, from experimental setup and sample preparation to data acquisition and analysis, with a special focus on nervous system mechanics. Combined with other microscopy techniques, AFM is a powerful tool to reveal novel information about molecular, cell, and tissue mechanics.

Published

2015

72. Atomic force microscopy-based force measurements on animal cells and tissues

Author

David E. Koser, Amelia J Thompson, Kristian Franze, Sarra Achouri, Hélène O. B. Gautier, Kathrin Holtzmann, and Emadaldin Moeendarbary

Subjects

Normal functioning, Atomic force microscopy, Microscopy, technology, industry, and agriculture, Biophysics, Tissue mechanics, Scanning Force Microscopy, Biology

Abstract

During development, normal functioning, as well as in certain pathological conditions, cells are influenced not only by biochemical but also by mechanical signals. Over the past two decades, atomic force microscopy (AFM) has become one of the key tools to investigate the mechanical properties and interactions of biological samples. AFM studies have provided important insights into the role of mechanical signaling in different biological processes. In this chapter, we introduce different applications of AFM-based force measurements, from experimental setup and sample preparation to data acquisition and analysis, with a special focus on nervous system mechanics. Combined with other microscopy techniques, AFM is a powerful tool to reveal novel information about molecular, cell, and tissue mechanics.

Published

2015

73. Development of the anterior-posterior axis is a self-organizing process in the absence of maternal cues in the mouse embryo

Author

Francesco Antonica, Kristian Franze, Monika Bialecka, Magdalena Zernicka-Goetz, Ivan Bedzhov, Joanna Kosalka, Agata P. Zielinska, and Amelia J Thompson

Subjects

animal structures, Body Patterning, Mammalian, Endoderm, Anterior Posterior Axis, Mammalian embryology, Embryo, Cell Biology, Anatomy, Biology, Embryo, Mammalian, Mice, medicine.anatomical_structure, embryonic structures, medicine, Animals, Molecular Biology, Neuroscience, Process (anatomy), Letter to the Editor

Abstract

Development of the anterior-posterior axis is a self-organizing process in the absence of maternal cues in the mouse embryo

Published

2015

74. GABAAreceptors in Müller glial cells of the human retina

Author

Andreas Bringmann, Bernd Biedermann, Peter Wiedemann, Frank Faude, Andreas Reichenbach, and Kristian Franze

Subjects

medicine.medical_specialty, GABAA receptor, Receptor expression, Bicuculline, Biology, GABAA-rho receptor, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Endocrinology, nervous system, Neurology, chemistry, Muscimol, Internal medicine, Biophysics, medicine, GABAergic, sense organs, Reversal potential, Picrotoxin, medicine.drug

Abstract

The present study was aimed at characterizing the GABA(A) receptor-mediated currents in acutely isolated glial (Muller) cells of the human retina and investigating their subcellular localization across the Muller cell membrane. Extracellular application of GABA evoked two current responses in human Muller cells: a fast transient GABA(A) receptor-mediated current that inactivated within 10 s and that was independent of extracellular Na(+), and a sustained current that was dependent on extracellular Na(+) and that was mediated by high-affinity GABA transporters. The receptor current was half-maximally activated at a GABA concentration of 32 microM, while the transporter current showed an affinity constant of 7.9 microM GABA. The receptor currents were blocked by bicuculline and picrotoxin and were also activated by muscimol or by other amino acids. The receptor currents are Cl(-) currents, as indicated by the close relationship between the reversal potential of these currents and the Cl(-) equilibrium potential. Using perforated-patch recordings, a mean intracellular Cl(-) concentration of 37 +/- 12 mM was determined in human Muller cells. Using electrophysiological and fluorescence imaging methods, it was revealed that GABA(A) receptors are unevenly distributed across the Muller cell membrane, with higher densities at the endfoot, at the soma, and at the distal sclerad end of the cells. It is concluded that GABA(A) receptor expression may allow a sensing of retinal GABAergic neuronal signal transmission by Muller cells.

Published

2004

75. Selective staining by vital dyes of Müller glial cells in retinal wholemounts

Author

Mike Francke, Andreas Bringmann, Jens Grosche, Kristian Franze, Andreas Reichenbach, Peter Wiedemann, Ortrud Uckermann, Ianors Iandiev, Leon Kohen, and Sebastian Wolf

Subjects

Retina, Cell signaling, Glutamate receptor, chemistry.chemical_element, Retinal, Calcium, Biology, Cell biology, Cellular and Molecular Neuroscience, chemistry.chemical_compound, medicine.anatomical_structure, Calcium imaging, Neurology, chemistry, Biochemistry, medicine, Neuroglia, sense organs, Neurotransmitter

Abstract

Muller glial cells within the retina may respond to different signaling molecules with an elevation of their intracellular free calcium. To prove the localization of the recorded calcium responses in Muller cells within acutely isolated retinal wholemounts, retinal pieces from adult animals and humans were exposed to different vital dyes just after the calcium imaging records were finished. The dyes, Mitotracker Orange, Mitotracker Green, Celltracker Orange, Celltracker Green, and monochlorobimane, are all selectively taken up by Muller glial cells, while neuronal cells remain largely devoid of the dyes. By using this method, it can be demonstrated that the free calcium alterations within the wholemounts indeed occur within Muller cells. Moreover, the cross-sectional areas of (dye-filled) Muller glial cell bodies, as well as of (dye-free) neuronal cell bodies, can be measured in retinal wholemounts, and the spatial densities of both types of cells can be determined. The vital dye loading of Muller cells may facilitate investigations of stimulus-induced alterations of retinal glial cell physiology and morphology.

Published

2003

76. Effect of vital dyes on human corneal endothelium and elasticity of Descemet’s membrane

Author

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

Subjects

Male, 0301 basic medicine, lcsh:Medicine, Penetrating Keratoplasty, Epithelium, Stiffness, Polyethylene Glycols, Cornea, chemistry.chemical_compound, 0302 clinical medicine, Animal Cells, Medicine and Health Sciences, lcsh:Science, Coloring Agents, Staining, Microscopy, Multidisciplinary, Benzenesulfonates, Endothelium, Corneal, Ophthalmic Procedures, Middle Aged, Atomic Force Microscopy, 3. Good health, Membrane Staining, Endothelial stem cell, Treatment Outcome, medicine.anatomical_structure, Physical Sciences, Toxicity, Female, Trypan blue, Anatomy, Cellular Types, Research Article, Adult, Corneal endothelium, medicine.medical_specialty, Endothelium, Cell Survival, Ocular Anatomy, Materials Science, Material Properties, Surgical and Invasive Medical Procedures, Polyethylene glycol, Research and Analysis Methods, 03 medical and health sciences, Ocular System, Elastic Modulus, Ophthalmology, Cadaver, medicine, Mechanical Properties, Humans, Descemet Membrane, Aged, Scanning Probe Microscopy, lcsh:R, Biology and Life Sciences, Endothelial Cells, Epithelial Cells, Cell Biology, Trypan Blue, Elasticity, Surgery, Descemet's membrane, Biological Tissue, 030104 developmental biology, chemistry, Specimen Preparation and Treatment, Keratoplasty, Cardiovascular Anatomy, 030221 ophthalmology & optometry, lcsh:Q, Descemet Stripping Endothelial Keratoplasty

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

77. The relationship between glial cell mechanosensitivity and foreign body reactions in the central nervous system

Author

Kristian Franze, Clare E. Bryant, Pouria Moshayedi, James W. Fawcett, Jochen Guck, Jessica C. F. Kwok, Gilbert Ng, and Giles S.H. Yeo

Subjects

Central Nervous System, Materials science, Central nervous system, Blotting, Western, Biophysics, FBR, Bioengineering, 02 engineering and technology, Mechanotransduction, Cellular, Stiffness, Biomaterials, Rats, Sprague-Dawley, 03 medical and health sciences, Downregulation and upregulation, medicine, Animals, Gliosis, 030304 developmental biology, 0303 health sciences, Microglia, Nervous tissue, Foreign-Body Reaction, Implant, Anatomy, 021001 nanoscience & nanotechnology, Cell biology, Rats, Brain implant, medicine.anatomical_structure, Mechanics of Materials, Astrocytes, Ceramics and Composites, medicine.symptom, 0210 nano-technology, Astrocyte, Neuroglia

Abstract

Devices implanted into the body become encapsulated due to a foreign body reaction. In the central nervous system (CNS), this can lead to loss of functionality in electrodes used to treat disorders. Around CNS implants, glial cells are activated, undergo gliosis and ultimately encapsulate the electrodes. The primary cause of this reaction is unknown. Here we show that the mechanical mismatch between nervous tissue and electrodes activates glial cells. Both primary rat microglial cells and astrocytes responded to increasing the contact stiffness from physiological values (G′ ∼ 100 Pa) to shear moduli G′ ≥ 10 kPa by changes in morphology and upregulation of inflammatory genes and proteins. Upon implantation of composite foreign bodies into rat brains, foreign body reactions were significantly enhanced around their stiff portions in vivo. Our results indicate that CNS glial cells respond to mechanical cues, and suggest that adapting the surface stiffness of neural implants to that of nervous tissue could minimize adverse reactions and improve biocompatibility.

Published

2013

78. The mechanical control of nervous system development

Author

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

Subjects

Nervous system, Mechanotransduction, Neurogenesis, Models, Neurological, Biophysics, Context (language use), Biology, Mechanics, Mechanotransduction, Cellular, Nervous System, Mechanosensitivity, Stiffness, Cell Movement, medicine, Animals, Nervous System Physiological Phenomena, Progenitor cell, Control (linguistics), Molecular Biology, Force, General function, Axon extension, Brain, Biomechanical Phenomena, Mechanotaxis, medicine.anatomical_structure, Brain folding, Tension, Nerve Net, Biological system, Neuroscience, Developmental Biology

Abstract

The development of the nervous system has so far, to a large extent, been considered in the context of biochemistry, molecular biology and genetics. However, there is growing evidence that many biological systems also integrate mechanical information when making decisions during differentiation, growth, proliferation, migration and general function. Based on recent findings, I hypothesize that several steps during nervous system development, including neural progenitor cell differentiation, neuronal migration, axon extension and the folding of the brain, rely on or are even driven by mechanical cues and forces.

Published

2013

79. Auxetic nuclei in embryonic stem cells exiting pluripotency

Author

Ulrich F. Keyser, Crystal R. McClain, Stefano Pagliara, Kevin J. Chalut, Kristian Franze, Robin J.M. Franklin, Cynthia L. Fisher, George W. Wylde, and Alexandre Kabla

Subjects

Pluripotent Stem Cells, Somatic cell, Cellular differentiation, Nanotechnology, Embryoid body, Article, Mice, Animals, General Materials Science, Mechanotransduction, Induced pluripotent stem cell, Embryonic Stem Cells, Cell Nucleus, Chemistry, Mechanical Engineering, digestive, oral, and skin physiology, Cell Differentiation, General Chemistry, Condensed Matter Physics, Chromatin Assembly and Disassembly, Embryonic stem cell, Cell biology, Endothelial stem cell, Mechanics of Materials, embryonic structures, Reprogramming

Abstract

Embryonic stem cells (ESCs) self-renew in a state of naïve pluripotency in which they are competent to generate all somatic cells1. It has been hypothesized that, before irreversibly committing, ESCs pass through at least one metastable transition state2-4. This transition would represent a gateway for differentiation and reprogramming of somatic cells5,6. We sought a mechanical phenotype of transition by probing the nuclear response to compressive and tensile forces and found that, during transition, nuclei of ESCs are auxetic: they displayed a cross-sectional expansion when stretched and a cross-sectional contraction when compressed, and their stiffness increased under compression. We show that the auxetic phenotype of transition ESC nuclei is driven at least in part by global chromatin decondensation. Through the regulation of molecular turnover in the differentiating nucleus by external forces, auxeticity could be a key element in mechanotransduction. Our findings highlight the importance of nuclear structure in the regulation of differentiation and reprogramming.

Published

2013

80. Correction: Corrigendum: Fumarate is an epigenetic modifier that elicits epithelial-to-mesenchymal transition

Author

Anne Warren, Pedro R. Cutillas, Sandra R Abbo, Sarah Q. Foster, Simone Cardaci, Alizee Vercauteren Drubbel, Maxine Gia Binh Tran, Timothy Isaac Johnson, Vinothini Rajeeve, Patrick H. Maxwell, Christian Frezza, Marco Sciacovelli, Julio Saez-Rodriguez, Vincent Zecchini, Eyal Gottlieb, Edoardo Gaude, Ana S. H. Costa, Sebastian Julian Theobald, Vincent J. Gnanapragasam, Kristian Franze, Brian J. P. Huntly, Emanuel Gonçalves, Eamonn R. Maher, and Haiyang Yun

Subjects

0301 basic medicine, Multidisciplinary, Accession number (library science), Epigenetic modifier, Biology, Accession, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Biochemistry, 030220 oncology & carcinogenesis, Cancer metabolism, Gene expression, Cancer research, Affymetrix genechip, Epithelial–mesenchymal transition

Abstract

Nature 537, 544–547 (2016); doi:10.1038/nature19353 In this Letter, the ArrayExpress accession number provided for the gene expression data for Sdhb-deficient cells should have been ‘ E-MTAB-4349’, rather than the Affymetrix GeneChip platform accession ‘A-AFFY-130’; this has been corrected in the online versions of the paper.

Published

2016

81. Photonic crystal light collectors in fish retina improve vision in turbid water

Author

Mike Francke, Meik Landsberger, Dorothee Haverkate, Moritz Kreysing, Gerhard von der Emde, Jacob Engelmann, Carlos Mora-Ferrer, Hartwig Wolburg, Stefan Schuster, Elke Ulbricht, Hans-Joachim Wagner, Kristian Franze, Janina Ruiter, Roland Pusch, Jens Grosche, Sarah Schumacher, Stefan Streif, Johannes Kacza, Andreas Reichenbach, Felix Makarov, James K. Bowmaker, and Jochen Guck

Subjects

genetic structures, Light, Retina, chemistry.chemical_compound, Optics, biology.animal, Goldfish, medicine, Animals, Vision, Ocular, Photonic crystal, Physics, Gnathonemus, Multidisciplinary, biology, business.industry, Fishes, Vertebrate, Retinal, Turbid water, biology.organism_classification, eye diseases, Rod Photoreceptors, medicine.anatomical_structure, chemistry, Predatory Behavior, %22">Fish , sense organs, business, Photoreceptor Cells, Vertebrate

Abstract

Seeing in the Dark Elephantnose fish are known to use electrosensing to navigate their murky freshwater environment. However, unlike some other animals from dark environments, they have retained their eyes and some dependence on vision. While most vertebrate vision optimizes either photon catch (for increased light capture) or visual acuity, Kreysing et al. (p. 1700 ) show that the unique structures of the grouped retinae found in the eyes of this species matches rod and cone sensitivity, which allows for the simultaneous use of both types of photoreceptors over a large range of dim light intensities.

Published

2012

82. Live Cells as Optical Fibers in the Vertebrate Retina

Author

Andreas Reichenbach, Silke Agte, Stephan Junek, Alexej Savvinov, Jens Grosche, Serguei N. Skatchkov, Antje Wurm, Kristian Franze, and Jochen Guck

Subjects

Physics, Retina, Optical fiber, genetic structures, business.industry, High resolution, Retinal, eye diseases, law.invention, chemistry.chemical_compound, Retinal tissue, Optics, medicine.anatomical_structure, chemistry, law, Aliasing, medicine, sense organs, Transparency (data compression), business, Vertebrate retina

Abstract

The vertebrate eye is equipped with an inverted-type retina; that means, light must pass through all proximal retinal layers before it arrives at the photoreceptor cells which are aligned at the back of the tissue. Though it is often stated that the transparency of the intact vertebrate retina is ‘almost total’ (Enoch and Glisman, 1966), it contains numerous structures which differ in size and refractive index. These differences should lead to significant scattering. Accordingly, it has been pointed out that the situation in the inverted retina ‘is equivalent to placing a thin diffusing screen directly over the film in your camera’ (Goldsmith, 1990). In fact, many current digital cameras posses such a "diffusing screen", in order to prevent artifacts due to the discrete and periodic sampling of the image: the anti-aliasing filter. As the layout of the retina exhibits a similar sampling strategy, one might hypothesize that the cell layers in front of the photoreceptors act as an anti-aliasing filter. However, the fact that aliasing artifacts can be observed in the vertebrate eye (Coletta et al. 1990) argues against such a hypothesis. On the contrary, these reports confirm the high resolution provided by the vertebrate retina, close to its physical limits. We will discuss here whether this apparent discrepancy is resolved by the presence of cellular light guides within the retinal tissue.

Published

2012

83. Metastable Underwater Superhydrophobicity

Author

Kathrin Holtzmann, Kristian Franze, Ullrich Steiner, and Rosa Poetes

Subjects

Materials science, Chemical physics, Metastability, General Physics and Astronomy, Nanotechnology, Substrate (electronics), Wetting, Underwater

Abstract

Superhydrophobicity is generally considered to be a thermodynamically stable wetting state. The stability of the plastron (the thin air film separating the substrate from the water in the superhydrophobic state) was studied in underwater experiments. The plastron exhibited a rapid decay after a well defined onset time, which was found to be dependent on the immersion depth. The plastron decay is explained in terms of a model, which is based on confocal microscopy measurements. The limited underwater plastron stability explains the rarity of permanently submerged superhydrophobic surfaces in nature and limits their scope for commercial applications.

Published

2010

84. Dual-beam laser traps in biology and medicine: when one beam is not enough

Author

Moritz Kreysing, Kristian Franze, Ulysse Delabre, Lars Boyde, Kevin J. Chalut, Andrew Ekpenyong, Franziska Lautenschläger, Graeme Whyte, and Jochen Guck

Subjects

Condensed Matter::Quantum Gases, Physics, genetic structures, business.industry, Rotation, Laser, eye diseases, Dual beam, Quantitative Biology::Cell Behavior, law.invention, Trap (computing), Optics, Optical tweezers, law, Optical stretcher, sense organs, Physics::Atomic Physics, business, Beam (structure), Laser beams

Abstract

Optical traps are nowadays quite ubiquitous in biophysical and biological studies. The term is often used synonymously with optical tweezers, one particular incarnation of optical traps. However, there is another kind of optical trap consisting of two non-focused, counter-propagating laser beams. This dual-beam trap predates optical tweezers by almost two decades and currently experiences a renaissance. The advantages of dual-beam traps include lower intensities on the trapped object, decoupling from imaging optics, and the possibility to trap cells and cell clusters up to 100 microns in diameter. When used for deforming cells this trap is referred to as an optical stretcher. I will review several applications of such traps in biology and medicine for the detection of cancer cells, sorting stem cells, testing light guiding properties of retinal cells and the controlled rotation of cells for single cell tomography.

Published

2010

85. Mechanical difference between white and gray matter in the rat cerebellum measured by scanning force microscopy

Author

Hélène O. B. Gautier, Andreas F. Christ, Pouria Moshayedi, James W. Fawcett, Kristian Franze, Jochen Guck, Ragnhildur Thóra Káradóttir, and Robin J.M. Franklin

Subjects

Materials science, Models, Neurological, Biomedical Engineering, Biophysics, Grey matter, Microscopy, Atomic Force, White matter, Rats, Sprague-Dawley, Optics, Indentation, Cerebellum, Elastic Modulus, Microscopy, medicine, Animals, Orthopedics and Sports Medicine, Elasticity (economics), Elastic modulus, business.industry, Rehabilitation, Biomechanics, Stiffness, Biomechanical Phenomena, Rats, medicine.anatomical_structure, Female, Stress, Mechanical, medicine.symptom, business, Biomedical engineering

Abstract

The mechanical properties of tissues are increasingly recognized as important cues for cell physiology and pathology. Nevertheless, there is a sparsity of quantitative, high-resolution data on mechanical properties of specific tissues. This is especially true for the central nervous system (CNS), which poses particular difficulties in terms of preparation and measurement. We have prepared thin slices of brain tissue suited for indentation measurements on the micrometer scale in a near-native state. Using a scanning force microscope with a spherical indenter of radius ∼20μm we have mapped the effective elastic modulus of rat cerebellum with a spatial resolution of 100μm. We found significant differences between white and gray matter, having effective elastic moduli of K=294±74 and 454±53Pa, respectively, at 3μm indentation depth (n(g)=245, n(w)=150 in four animals, p

Published

2010

86. Retinal glial (Müller ) cells: sensing and responding to tissue stretch

Author

Andreas Reichenbach, Joachim Zajadacz, Kristian Franze, Niclas Lindqvist, and Qing Liu

Subjects

Cell type, Basic fibroblast growth factor, Guinea Pigs, Biology, Mechanotransduction, Cellular, Calcium in biology, Retina, chemistry.chemical_compound, Downregulation and upregulation, Extracellular, medicine, Animals, Rats, Long-Evans, Extracellular Signal-Regulated MAP Kinases, Fluorescent Dyes, Retinal, Anatomy, Immunohistochemistry, Cell biology, Rats, medicine.anatomical_structure, chemistry, Microscopy, Fluorescence, Calcium, Fibroblast Growth Factor 2, sense organs, Stress, Mechanical, Mechanoreceptors, Neuroglia, Proto-Oncogene Proteins c-fos, Intracellular

Abstract

Purpose. To test whether Muller glial cells sense, and respond to, mechanical tension in the retina. Methods. A device was designed to stretch the retina at right angles to its surface, across retinal layers. Pieces of retina were mounted between two hollow tubes, and uniaxial force was applied to the tissue using a micrometer-stepping motor. Muller cells were selectively stained with the fluorescent, calciumsensitive dye X-Rhod-1 and were monitored in real time during retinal stretch in vitro. Immunohistochemistry was used to study protein levels and activation of intracellular pathways in stretched retinas. Results. Muller cells responded acutely with transient increases in fluorescence during stretch, indicative of increased intracellular calcium levels. All the Muller cells elongated uniformly, and there was no apparent difference between retinal layers in resistance against mechanical deformation. After stretch, Muller cells showed fast activation of extracellular signal-regulated kinase (after 15 minutes), upregulation of transcription factor c-Fos (after 1 hour), and basic fibroblast growth factor (after 3 hours). No changes in intermediate filament protein expression were observed in Muller cells up to 3 hours after stretch. Conclusions. A novel technique was developed for real-time monitoring of Muller cells during retinal stretch, which allowed the identification of Muller cells as a mechanoresponsive cell type. Mechanical stress triggers molecular responses in Muller cells that could prevent retinal damage. © Association for Research in Vision and Ophthalmology.

Published

2009

87. Neurite Branch Retraction Is Caused by a Threshold-Dependent Mechanical Impact

Author

Paul A. Janmey, Andreas Reichenbach, Johannes Bayer, Timo Betz, Jens C. Gerdelmann, Michael Gögler, Josef A. Käs, Michael Weick, Yun-Bi Lu, Steve Pawlizak, Melike Lakadamyali, Katja Rillich, and Kristian Franze

Subjects

Cell type, Neurite, Chemistry, Mechanical impact, Biophysics, Nanotechnology, Adhesion, Ion Channels, Biomechanical Phenomena, Cell Line, Rats, nervous system, Cell Adhesion, Neurites, Cellular Biophysics and Electrophysiology, Animals, Calcium, Stress, Mechanical, Signal transduction, Cell adhesion, Growth cone, Ion channel, Signal Transduction

Abstract

Recent results indicate that, in addition to chemical cues, mechanical stimuli may also impact neuronal growth. For instance, unlike most other cell types, neurons prefer soft substrates. However, the mechanisms responsible for the neuronal affinity for soft substrates have not yet been identified. In this study, we show that, in vitro, neurons continuously probe their mechanical environment. Growth cones visibly deform substrates with a compliance commensurate with their own. To understand the sensing of stiff substrates by growth cones, we investigated their precise temporal response to well-defined mechanical stress. When the applied stress exceeded a threshold of 274 +/- 41 pN/microm(2), neurons retracted and re-extended their processes, thereby enabling exploration of alternative directions. A calcium influx through stretch-activated ion channels and the detachment of adhesion sites were prerequisites for this retraction. Our data illustrate how growing neurons may detect and avoid stiff substrates--as a mechanism involved in axonal branch pruning--and provide what we believe is novel support of the idea that mechanics may act as guidance cue for neuronal growth.

Published

2009

88. Biomechanics of the CNS

Author

Andreas Reichenbach, Kristian Franze, and Josef A. Käs

Subjects

Normal functioning, Atomic force microscopy, Biomechanics, Biology, Neuroscience

Abstract

For a long time, neurosciences have focused on biochemical, molecular, and electrophysiological aspects of cell functioning. However, there is an increasing awareness of the importance of biomechanics in physiology and pathology of the central nervous system (CNS). In the first part of this review we provide physical basics necessary to understand biomechanical measurements, we introduce the cytoskeleton as a major contributor to a cell’s passive and active mechanical behavior, and we discuss some of the methods nowadays used to quantify mechanical properties. In the second part we present actual data on CNS mechanics, and we discuss the impact of passive mechanical material properties and active mechanical behavior of cells on the development, normal functioning and pathology of the CNS.

Published

2008

89. Optical neuronal guidance

Author

Allen, Ehrlicher, Timo, Betz, Björn, Stuhrmann, Michael, Gögler, Daniel, Koch, Kristian, Franze, Yunbi, Lu, and Josef, Käs

Subjects

Neurons, Mice, Optics and Photonics, Time Factors, Lasers, Neurites, Animals, PC12 Cells, Actins, Rats

Abstract

We present a novel technique to noninvasively control the growth and turning behavior of an extending neurite. A highly focused infrared laser, positioned at the leading edge of a neurite, has been found to induce extension/turning toward the beam's center. This technique has been used successfully to guide NG108-15 and PC12 cell lines [Ehrlicher, A., Betz, T., Stuhrmann, B., Koch, D. Milner, V. Raizen, M. G., and Kas, J. (2002). Guiding neuronal growth with light. Proc. Natl. Acad. Sci. USA 99, 16024-16028], as well as primary rat and mouse cortical neurons [Stuhrmann, B., Goegler, M., Betz, T., Ehrlicher, A., Koch, D., and Kas, J. (2005). Automated tracking and laser micromanipulation of cells. Rev. Sci. Instr. 76, 035105]. Optical guidance may eventually be used alone or with other methods for controlling neurite extension in both research and clinical applications.

Published

2007

90. Muller cells are living optical fibers in the vertebrate retina

Author

Christian Foja, Serguei N. Skatchkov, Detlev Schild, Kristian Franze, Kort Travis, Andreas Reichenbach, Jens Grosche, Jochen Guck, Stefan Schinkinger, and Ortrud Uckermann

Subjects

Male, Optical fiber, genetic structures, Light, Cell Survival, Guinea Pigs, Biology, Refraction, Ocular, Retina, law.invention, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Optics, Confocal microscopy, law, medicine, Animals, Cell Shape, 030304 developmental biology, 0303 health sciences, Multidisciplinary, business.industry, Lasers, Retinal, fiberoptic plate, glial cells, refractive index, light guides, optical trap, Biological Sciences, Refraction, eye diseases, Reflection (mathematics), medicine.anatomical_structure, chemistry, Vertebrates, 030221 ophthalmology & optometry, Biophysics, Female, sense organs, business, Refractive index, Parallel array

Abstract

Although biological cells are mostly transparent, they are phase objects that differ in shape and refractive index. Any image that is projected through layers of randomly oriented cells will normally be distorted by refraction, reflection, and scattering. Counterintuitively, the retina of the vertebrate eye is inverted with respect to its optical function and light must pass through several tissue layers before reaching the light-detecting photoreceptor cells. Here we report on the specific optical properties of glial cells present in the retina, which might contribute to optimize this apparently unfavorable situation. We investigated intact retinal tissue and individual Müller cells, which are radial glial cells spanning the entire retinal thickness. Müller cells have an extended funnel shape, a higher refractive index than their surrounding tissue, and are oriented along the direction of light propagation. Transmission and reflection confocal microscopy of retinal tissue in vitro and in vivo showed that these cells provide a low-scattering passage for light from the retinal surface to the photoreceptor cells. Using a modified dual-beam laser trap we could also demonstrate that individual Müller cells act as optical fibers. Furthermore, their parallel array in the retina is reminiscent of fiberoptic plates used for low-distortion image transfer. Thus, Müller cells seem to mediate the image transfer through the vertebrate retina with minimal distortion and low loss. This finding elucidates a fundamental feature of the inverted retina as an optical system and ascribes a new function to glial cells.

Published

2007

91. Optical Neuronal Guidance

Author

Michael Gögler, Kristian Franze, Allen J. Ehrlicher, Daniel Koch, Timo Betz, Josef A. Käs, Björn Stuhrmann, and Yun-Bi Lu

Subjects

Novel technique, Neurite, Neurite extension, Neuronal Growth, Anatomy, Cortical neurons, Biology, Neuroscience

Abstract

We present a novel technique to noninvasively control the growth and turning behavior of an extending neurite. A highly focused infrared laser, positioned at the leading edge of a neurite, has been found to induce extension/turning toward the beam's center. This technique has been used successfully to guide NG108–15 and PC12 cell lines [Ehrlicher, A., Betz, T., Stuhrmann, B., Koch, D. Milner, V. Raizen, M. G., and Kas, J. (2002). Guiding neuronal growth with light. Proc. Natl. Acad. Sci. USA 99, 16024–16028], as well as primary rat and mouse cortical neurons [Stuhrmann, B., Goegler, M., Betz, T., Ehrlicher, A., Koch, D., and Kas, J. (2005). Automated tracking and laser micromanipulation of cells. Rev. Sci. Instr . 76, 035105]. Optical guidance may eventually be used alone or with other methods for controlling neurite extension in both research and clinical applications.

Published

2007

92. Viscoelastic properties of individual glial cells and neurons in the CNS

Author

Paul A. Janmey, Josef A. Käs, Christian Steinhäuser, Andreas Reichenbach, Yun-Bi Lu, Gerald Seifert, Jochen Guck, Frank Kirchhoff, Hartwig Wolburg, Kristian Franze, and Er-Qing Wei

Subjects

Central Nervous System, Cell type, Cell, Central nervous system, Guinea Pigs, Biology, Microscopy, Atomic Force, Hippocampus, Retina, Mice, Organelle, medicine, Animals, Neurons, Multidisciplinary, Anatomy, Biological Sciences, Elasticity, Cell biology, Neuroepithelial cell, medicine.anatomical_structure, nervous system, Neuroglia, Soma, Stress, Mechanical, Rheology

Abstract

One hundred fifty years ago glial cells were discovered as a second, non-neuronal, cell type in the central nervous system. To ascribe a function to these new, enigmatic cells, it was suggested that they either glue the neurons together (the Greek word “γλια” means “glue”) or provide a robust scaffold for them (“support cells”). Although both speculations are still widely accepted, they would actually require quite different mechanical cell properties, and neither one has ever been confirmed experimentally. We investigated the biomechanics of CNS tissue and acutely isolated individual neurons and glial cells from mammalian brain (hippocampus) and retina. Scanning force microscopy, bulk rheology, and optically induced deformation were used to determine their viscoelastic characteristics. We found that ( i ) in all CNS cells the elastic behavior dominates over the viscous behavior, ( ii ) in distinct cell compartments, such as soma and cell processes, the mechanical properties differ, most likely because of the unequal local distribution of cell organelles, ( iii ) in comparison to most other eukaryotic cells, both neurons and glial cells are very soft (“rubber elastic”), and ( iv ) intriguingly, glial cells are even softer than their neighboring neurons. Our results indicate that glial cells can neither serve as structural support cells (as they are too soft) nor as glue (because restoring forces are dominant) for neurons. Nevertheless, from a structural perspective they might act as soft, compliant embedding for neurons, protecting them in case of mechanical trauma, and also as a soft substrate required for neurite growth and facilitating neuronal plasticity.

Published

2006

93. GABA(A) receptors in Müller glial cells of the human retina

Author

Bernd, Biedermann, Andreas, Bringmann, Kristian, Franze, Frank, Faude, Peter, Wiedemann, and Andreas, Reichenbach

Subjects

Dose-Response Relationship, Drug, Action Potentials, Humans, GABA-A Receptor Agonists, Receptors, GABA-A, Neuroglia, Retina, gamma-Aminobutyric Acid

Abstract

The present study was aimed at characterizing the GABA(A) receptor-mediated currents in acutely isolated glial (Müller) cells of the human retina and investigating their subcellular localization across the Müller cell membrane. Extracellular application of GABA evoked two current responses in human Müller cells: a fast transient GABA(A) receptor-mediated current that inactivated within 10 s and that was independent of extracellular Na(+), and a sustained current that was dependent on extracellular Na(+) and that was mediated by high-affinity GABA transporters. The receptor current was half-maximally activated at a GABA concentration of 32 microM, while the transporter current showed an affinity constant of 7.9 microM GABA. The receptor currents were blocked by bicuculline and picrotoxin and were also activated by muscimol or by other amino acids. The receptor currents are Cl(-) currents, as indicated by the close relationship between the reversal potential of these currents and the Cl(-) equilibrium potential. Using perforated-patch recordings, a mean intracellular Cl(-) concentration of 37 +/- 12 mM was determined in human Müller cells. Using electrophysiological and fluorescence imaging methods, it was revealed that GABA(A) receptors are unevenly distributed across the Müller cell membrane, with higher densities at the endfoot, at the soma, and at the distal sclerad end of the cells. It is concluded that GABA(A) receptor expression may allow a sensing of retinal GABAergic neuronal signal transmission by Müller cells.

Published

2004

94. Selective staining by vital dyes of Müller glial cells in retinal wholemounts

Author

Ortrud, Uckermann, Ianors, Iandiev, Mike, Francke, Kristian, Franze, Jens, Grosche, Sebastian, Wolf, Leon, Kohen, Peter, Wiedemann, Andreas, Reichenbach, and Andreas, Bringmann

Subjects

Staining and Labeling, Guinea Pigs, Animals, Humans, Rabbits, In Vitro Techniques, Coloring Agents, Neuroglia, Retina, Rats

Abstract

Müller glial cells within the retina may respond to different signaling molecules with an elevation of their intracellular free calcium. To prove the localization of the recorded calcium responses in Müller cells within acutely isolated retinal wholemounts, retinal pieces from adult animals and humans were exposed to different vital dyes just after the calcium imaging records were finished. The dyes, Mitotracker Orange, Mitotracker Green, Celltracker Orange, Celltracker Green, and monochlorobimane, are all selectively taken up by Müller glial cells, while neuronal cells remain largely devoid of the dyes. By using this method, it can be demonstrated that the free calcium alterations within the wholemounts indeed occur within Müller cells. Moreover, the cross-sectional areas of (dye-filled) Müller glial cell bodies, as well as of (dye-free) neuronal cell bodies, can be measured in retinal wholemounts, and the spatial densities of both types of cells can be determined. The vital dye loading of Müller cells may facilitate investigations of stimulus-induced alterations of retinal glial cell physiology and morphology.

Published

2003

95. Complex Stiffness Gradient Substrates for Studying Mechanotactic Cell Migration (Adv. Mater. 45/2012)

Author

James D. Brenton, Easan Sivaniah, Cheng-Hwa R. Kuo, Jian Xian, and Kristian Franze

Subjects

Durotaxis, Materials science, Mechanics of Materials, Atomic force microscopy, Mechanical Engineering, medicine, Stiffness, General Materials Science, Nanotechnology, Cell migration, medicine.symptom

Published

2012

96. Spatial mapping of the mechanical properties of the living retina using scanning force microscopy

Author

Andreas Reichenbach, Mike Francke, Nicole Körber, Kristian Franze, Jochen Guck, Katrin Günter, and Andreas F. Christ

Subjects

Retina, Materials science, business.industry, Stiffness, Nerve fiber, Retinal, Inner limiting membrane, General Chemistry, Condensed Matter Physics, chemistry.chemical_compound, medicine.anatomical_structure, Optics, chemistry, medicine, Biophysics, Mechanosensitive channels, sense organs, medicine.symptom, business, Ganglion cell layer, Elastic modulus

Abstract

The retina is an active soft material, in which mechanosensitive cells are thought to respond to the local mechanical heterogeneity they encounter during development and adult physiological functioning. The retina is also constantly exposed to mechanical stress with shear and traction forces acting at its inner surface. Consequences of these forces depend on the tissue's resistance to deformation, which is characterized by its stiffness. However, currently there is a lack of high-resolution data on retinal mechanical properties. Here, we used scanning force microscopy to determine the apparent elastic modulus K of the retinal inner surface along the length of the eye with sub-millimetre resolution, and compared characteristic K values of the retinal quadrants. We found that the inner retina is a mechanically inhomogeneous tissue. Most elastic moduli were in the range of 940 to 1800 Pa; significant differences were found between areas less than 50 µm apart. To identify the origin of this mechanical inhomogeneity, we investigated the size and distribution of structures comprising the retinal surface: large cell bodies in the ganglion cell layer, nerve fibers, inner limiting membrane, and Muller cell endfeet. Our data suggest that the distribution of compliant nerve fiber bundles and stiff neuronal cell bodies contributes most to the mechanical properties of the inner retina. These data offer a basis for understanding cellular mechanoresistivity and -sensitivity in the retina as a mechanically active tissue, and they may help to understand mechanisms and consequences of a variety of retino-pathological processes and their surgical treatment.

Published

2011

97. The biophysics of neuronal growth

Author

Jochen Guck and Kristian Franze

Subjects

Physics, nervous system, Biophysics, General Physics and Astronomy, Neuronal Growth

Abstract

For a long time, neuroscience has focused on biochemical, molecular biological and electrophysiological aspects of neuronal physiology and pathology. However, there is a growing body of evidence indicating the importance of physical stimuli for neuronal growth and development. In this review we briefly summarize the historical background of neurobiophysics and give an overview over the current understanding of neuronal growth from a physics perspective. We show how biophysics has so far contributed to a better understanding of neuronal growth and discuss current inconsistencies. Finally, we speculate how biophysics may contribute to the successful treatment of lesions to the central nervous system, which have been considered incurable until very recently.

Published

2010

98. Mechanosensitivity of astrocytes on optimized polyacrylamide gels analyzed by quantitative morphometry

Author

Luciano da Fontoura Costa, Jochen Guck, Stéphanie P. Lacour, James W. Fawcett, Kristian Franze, Pouria Moshayedi, and Andreas F. Christ

Subjects

Cell type, Polyacrylamide, Acrylic Resins, Nanotechnology, engineering.material, Mechanotransduction, Cellular, Models, Biological, chemistry.chemical_compound, Coating, In vivo, Cell Adhesion, Substrate stiffness, medicine, Animals, Humans, Computer Simulation, General Materials Science, Cells, Cultured, Focal Adhesions, CÉLULAS-TRONCO, Significant difference, Condensed Matter Physics, Rats, medicine.anatomical_structure, chemistry, Astrocytes, Biophysics, engineering, Stress, Mechanical, Elongation, Shear Strength, Gels, Astrocyte

Abstract

Cells are able to detect and respond to mechanical cues from their environment. Previous studies have investigated this mechanosensitivity on various cell types, including neural cells such as astrocytes. In this study, we have carefully optimized polyacrylamide gels, commonly used as compliant growth substrates, considering their homogeneity in surface topography, mechanical properties, and coating density, and identified several potential pitfalls for the purpose of mechanosensitivity studies. The resulting astrocyte response to growth on substrates with shear storage moduli of G' = 100 Pa and G' = 10 kPa was then evaluated as a function of coating density of poly-D-lysine using quantitative morphometric analysis. Astrocytes cultured on stiff substrates showed significantly increased perimeter, area, diameter, elongation, number of extremities and overall complexity if compared to those cultured on compliant substrates. A statistically significant difference in the overall morphological score was confirmed with an artificial intelligence-based shape analysis. The dependence of the cells' morphology on PDL coating density seemed to be weak compared to the effect of the substrate stiffness and was slightly biphasic, with a maximum at 10–100 µg ml − 1 PDL concentration. Our finding suggests that the compliance of the surrounding tissue in vivo may influence astrocyte morphology and behavior.

Published

2010

99. Living Optical Elements in the Vertebrate Retina

Author

Jochen Guck, Thomas Cremer, Boris Joffe, Andreas Reichenbach, Moritz Kreysing, Leo Peichl, and Kristian Franze

Subjects

Optical fiber, genetic structures, Biophysics, macromolecular substances, Biology, law.invention, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Optics, Confocal microscopy, law, medicine, Outer nuclear layer, 030304 developmental biology, 0303 health sciences, Retina, Scattering, business.industry, Retinal, Refraction, eye diseases, medicine.anatomical_structure, chemistry, sense organs, business, Refractive index, 030217 neurology & neurosurgery

Abstract

While cells are mostly transparent they are phase objects that differ in shape and refractive index. Any image that is projected through layers of cells will normally be distorted by refraction, reflection, and scattering. Strangely, the retina of the vertebrate eye is inverted with respect to its optical function and light must pass through several tissue layers before reaching the light-sensitive photoreceptor cells, with each photon having a chance of being scattered. Here we report how nature has optimized this apparently unfavourable situation. We investigated the optical properties of retinal tissue and individual Muller cells, which are radial glial cells spanning the entire thickness of the retina. Using confocal microscopy, quantitative refractometry, and a modified fiber-based dual-beam laser trap, we found that these cells act as optical fibers and guide light, which would otherwise be scattered, from the retinal surface to the photoreceptor cells. Their parallel arrangement in the retina is reminiscent of fiber-optic plates used for low-distortion image transfer. Behind the Muller cells, there seems to be a specific adaptation of the rod photoreceptor nuclei for improved light transmission through the outer nuclear layer of nocturnal animals. These nuclei have an inverted chromatin structure that turns them into micro-lenses channeling the light through the ONL. These findings ascribe a new function to glial cells, demonstrate the first nuclear adaptation for an optical function, and shed new light on the inverted retina as an optical system.

Published

2009

100. Glue or goo? mechanical properties of glial cells and neurons in the CNS

Author

F. Kirchhoff, C. Steinhäuser, Yi Lu, A. Reichenbach, H. Wolburg, Jochen Guck, Kristian Franze, Paul A. Janmey, and Josef A. Käs

Subjects

Chemistry, Rehabilitation, Biomedical Engineering, Biophysics, Orthopedics and Sports Medicine, GLUE, Cell biology

Published

2006