Your search keyword '"Alison E. Patteson"' showing total 45 results

1. Vimentin is a key regulator of cell mechanosensing through opposite actions on actomyosin and microtubule networks

Author

Farid Alisafaei, Kalpana Mandal, Renita Saldanha, Maxx Swoger, Haiqian Yang, Xuechen Shi, Ming Guo, Heidi Hehnly, Carlos A. Castañeda, Paul A. Janmey, Alison E. Patteson, and Vivek B. Shenoy

Subjects

Biology (General), QH301-705.5

Abstract

Abstract The cytoskeleton is a complex network of interconnected biopolymers consisting of actin filaments, microtubules, and intermediate filaments. These biopolymers work in concert to transmit cell-generated forces to the extracellular matrix required for cell motility, wound healing, and tissue maintenance. While we know cell-generated forces are driven by actomyosin contractility and balanced by microtubule network resistance, the effect of intermediate filaments on cellular forces is unclear. Using a combination of theoretical modeling and experiments, we show that vimentin intermediate filaments tune cell stress by assisting in both actomyosin-based force transmission and reinforcement of microtubule networks under compression. We show that the competition between these two opposing effects of vimentin is regulated by the microenvironment stiffness. These results reconcile seemingly contradictory results in the literature and provide a unified description of vimentin’s effects on the transmission of cell contractile forces to the extracellular matrix.

Published

2024

2. Antibacterial and Cytocompatible pH-Responsive Peptide Hydrogel

Author

Dona Imanga Upamadi Edirisinghe, Areetha D’Souza, Maryam Ramezani, Robert J. Carroll, Quenten Chicón, Cheyene L. Muenzel, Jonathan Soule, Mary Beth Browning Monroe, Alison E. Patteson, and Olga V. Makhlynets

Subjects

hydrogel, pH sensitive, antimicrobial, cytocompatible, self-healing, rheology, Organic chemistry, QD241-441

Abstract

A short peptide, FHHF-11, was designed to change stiffness as a function of pH due to changing degree of protonation of histidines. As pH changes in the physiologically relevant range, G′ was measured at 0 Pa (pH 6) and 50,000 Pa (pH 8). This peptide-based hydrogel is antimicrobial and cytocompatible with skin cells (fibroblasts). It was demonstrated that the incorporation of unnatural AzAla tryptophan analog residue improves the antimicrobial properties of the hydrogel. The material developed can have a practical application and be a paradigm shift in the approach to wound treatment, and it will improve healing outcomes for millions of patients each year.

Published

2023

3. The propagation of active-passive interfaces in bacterial swarms

Author

Alison E. Patteson, Arvind Gopinath, and Paulo E. Arratia

Subjects

Science

Abstract

The study of interfaces in bacterial systems is of relevance to the spreading of bacterial colonies and pathological infections. Here the authors investigate the dynamics of active/passive interfaces in bacterial swarms and find that the boundary can be described as a propagating, diffuse elastic interface.

Published

2018

4. Mechanobiology as a tool for addressing the genotype-to-phenotype problem in microbiology

Author

Merrill E. Asp, Minh-Tri Ho Thanh, Subarna Dutta, Jessica A. Comstock, Roy D. Welch, and Alison E. Patteson

Subjects

General Medicine

Abstract

The central hypothesis of the genotype–phenotype relationship is that the phenotype of a developing organism (i.e., its set of observable attributes) depends on its genome and the environment. However, as we learn more about the genetics and biochemistry of living systems, our understanding does not fully extend to the complex multiscale nature of how cells move, interact, and organize; this gap in understanding is referred to as the genotype-to-phenotype problem. The physics of soft matter sets the background on which living organisms evolved, and the cell environment is a strong determinant of cell phenotype. This inevitably leads to challenges as the full function of many genes, and the diversity of cellular behaviors cannot be assessed without wide screens of environmental conditions. Cellular mechanobiology is an emerging field that provides methodologies to understand how cells integrate chemical and physical environmental stress and signals, and how they are transduced to control cell function. Biofilm forming bacteria represent an attractive model because they are fast growing, genetically malleable and can display sophisticated self-organizing developmental behaviors similar to those found in higher organisms. Here, we propose mechanobiology as a new area of study in prokaryotic systems and describe its potential for unveiling new links between an organism's genome and phenome.

Published

2023

5. Stochastic bounds of aggregation dynamics distinguish near-wild-type from wild-type strains in social bacteria

Author

Merrill E. Asp, Eduardo A. Caro, Roy D. Welch, and Alison E. Patteson

Abstract

The genotype-to-phenotype problem (G2P) for multicellular development asks how genetic inputs control collective phenotypic outputs. It is a difficult problem even to observe. On the genotype side, the phenotypic impact of mutation is often subtle due at least partly to gene redundancy and myriad other factors. On the phenotype side, biological and even technical developmental replicates can display significant phenotypic variation due at least in part to stochasticity, again with other factors. We attempt to partially resolve the G2P inputs and outputs from the obfuscating effects of factors like redundancy and stochasticity. As a model organism, we selected the biofilm-forming speciesMyxococcus xanthus, a motile self-organizing bacterium that forms three-dimensional cell aggregates that grow and mature into spore-filled fruiting bodies when under starvation stress. We developed data acquisition tools and analysis and visualization methods that can produce a topological map ofM. xanthusdevelopment. We demonstrate that even subtle effects on developmental dynamics caused by mutation can be identified, discriminated, characterized, and given statistical significance.

Published

2023

6. How cells wrap around virus-like particles using extracellular filamentous protein structures

Author

Sarthak Gupta, Christian D. Santangelo, Alison E. Patteson, and J. M. Schwarz

Subjects

Biological Physics (physics.bio-ph), FOS: Biological sciences, Cell Behavior (q-bio.CB), Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, Quantitative Biology - Cell Behavior, Physics - Biological Physics, Condensed Matter - Soft Condensed Matter

Abstract

Nanoparticles, such as viruses, can enter cells via endocytosis. During endocytosis, the cell surface wraps around the nanoparticle to effectively eat it. Prior focus has been on how nanoparticle size and shape impacts endocytosis. However, inspired by the noted presence of extracellular vimentin affecting viral and bacteria uptake, as well as the structure of coronaviruses, we construct a computational model in which both the cell-like construct and the virus-like construct contain filamentous protein structures protruding from their surfaces. We then study the impact of these additional degrees of freedom on viral wrapping. We find that cells with an optimal density of filamentous extracellular components (ECCs) are more likely to be infected as they uptake the virus faster and use relatively less cell surface area per individual virus. At the optimal density, the cell surface folds around the virus, and folds are faster and more efficient at wrapping the virus than crumple-like wrapping. We also find that cell surface bending rigidity helps generate folds, as bending rigidity enhances force transmission across the surface. However, changing other mechanical parameters, such as the stretching stiffness of filamentous ECCs or virus spikes, can drive crumple-like formation of the cell surface. We conclude with the implications of our study on the evolutionary pressures of virus-like particles, with a particular focus on the cellular microenvironment that may include filamentous ECCs., 15 pages, 8 figures

Published

2023

7. Extracellular vimentin is sufficient to promote cell attachment, spreading, and motility by a mechanism involving N-acetyl glucosamine-containing structures

Author

Robert Bucki, Daniel V. Iwamoto, Xuechen Shi, Katherine E. Kerr, Fitzroy J. Byfield, Łukasz Suprewicz, Karol Skłodowski, Julian Sutaria, Paweł Misiak, Agnieszka Wilczewska, Sekar Ramachandran, Aaron Wolfe, Minh-Tri Ho Thanh, Eli Whalen, Alison E. Patteson, and Paul A. Janmey

Abstract

Vimentin intermediate filaments form part of the cytoskeleton of mesenchymal cells, but under pathological conditions often associated with inflammation, vimentin filaments depolymerize as the result of phosphorylation or citrullination, and vimentin oligomers are secreted or released into the extracellular environment. In the extracellular space, vimentin can bind surfaces of other cells and the extracellular matrix, and the interaction between extracellular vimentin and other cell types can trigger changes in cellular functions, such as activation of fibroblasts to a fibrotic phenotype. The mechanism by which extracellular vimentin binds external cell membranes and whether vimentin alone can act as an adhesive anchor for cells is largely uncharacterized. Here, we show that various cell types (normal and vimentin null fibroblasts, mesenchymal stem cells, A549 lung carcinoma cells) attach to and spread on polyacrylamide hydrogel substrates covalently linked to vimentin. Using traction force microscopy and spheroid expansion assays, we characterize how different cell types respond to extracellular vimentin. Cell attachment to and spreading on vimentin-coated surfaces is inhibited by hyaluronic acid (HA) degrading enzymes, HA synthase inhibitors, soluble heparin, or N-acetyl glucosamine, treatments that have little or no effect on the same cell types binding to collagen-coated hydrogels. These studies highlight the effectiveness of substrate-bound vimentin as a ligand for cells and suggest that carbohydrate structures, including the glycocalyx and glycosylated cell surface proteins that contain N-acetyl glucosamine, form a novel class of adhesion receptors for extracellular vimentin.

Published

2022

8. Transcription regulates bleb formation and stability independent of nuclear rigidity

Author

Isabel K. Berg, Marilena L. Currey, Sarthak Gupta, Yasmin Berrada, Bao Nyugen Viet, Mai Pho, Alison E. Patteson, J. M. Schwarz, Edward J. Banigan, and Andrew D. Stephens

Abstract

Chromatin is an essential component of nuclear mechanical response and shape that maintains nuclear compartmentalization and function. The biophysical properties of chromatin alter nuclear shape and stability, but little is known about whether or how major genomic functions can impact the integrity of the nucleus. We hypothesized that transcription might affect cell nuclear shape and rupture through its effects on chromatin structure and dynamics. To test this idea, we inhibited transcription with the RNA polymerase II inhibitor alpha-amanitin in wild type cells and perturbed cells that present increased nuclear blebbing. Transcription inhibition suppresses nuclear blebbing for several cell types, nuclear perturbations, and transcription inhibitors. Furthermore, transcription is necessary for robust nuclear bleb formation, bleb stabilization, and bleb-based nuclear ruptures. These morphological effects appear to occur through a novel biophysical pathway, since transcription does not alter either chromatin histone modification state or nuclear rigidity, which typically control nuclear blebbing. We find that active/phosphorylated RNA pol II Ser5, marking transcription initiation, is enriched in nuclear blebs relative to DNA. Thus, transcription initiation is a hallmark of nuclear blebs. Polymer simulations suggest that motor activity within chromatin, such as that of RNA pol II, can generate active forces that deform the nuclear periphery, and that nuclear deformations depend on motor dynamics. Our data provide evidence that the genomic function of transcription impacts nuclear shape stability, and suggests a novel mechanism, separate and distinct from chromatin rigidity, for regulating large-scale nuclear shape and function.

Published

2022

9. Phenotypic similarity is a measure of functional redundancy within homologous gene families

Author

Jessica A. Comstock, Merrill E. Asp, Fatmagül Bahar, Isabella Lee, Alison E. Patteson, and Roy D. Welch

Abstract

Robustness to the impact of mutation can mitigate phenotypes that have the potential to inform gene function. This robustness is often encoded into the genome through gene duplication, among other mechanisms. Duplication is a source of structurally similar genes that can retain some functional overlap as they diverge, and as such contribute to functional redundancy in the face of mutation. While redundancies have been explored in groups of two or three paralogs by generating double and triple mutants, it is unclear to what extent larger homologous gene families contribute to robustness through functional redundancy. Here, we used phenotypic similarity as an indicator of functional redundancy to explore the extent to which homologous gene families contribute to redundancy in function. We hypothesize that, since functional redundancy is more likely to occur within gene families where genes are structurally similar, mutant strains within the same gene families would be more phenotypically similar. We generated 265 single-gene disruptions in four homologous gene families of Myxococcus xanthus, used time-lapse microscopy to generate time series of multicellular development, and developed an image analysis pipeline to compare phenotypic characteristics among different strains. We show that mutant strains cluster by gene family in the phenotypic feature space with principal component analysis, demonstrating that families of homologs can contain extensive functional redundancy networks.

Published

2022

10. Bacterial activity hinders particle sedimentation

Author

Bryan O. Torres Maldonado, Prashant K. Purohit, Alison E. Patteson, Paulo E. Arratia, and Jaspreet Singh

Subjects

Population, FOS: Physical sciences, 01 natural sciences, Physics::Geophysics, Quantitative Biology::Cell Behavior, 010305 fluids & plasmas, Diffusion, Physical Phenomena, Physics::Fluid Dynamics, 0103 physical sciences, Escherichia coli, Bacterial activity, 010306 general physics, education, Physics::Atmospheric and Oceanic Physics, education.field_of_study, Chemistry, Fluid Dynamics (physics.flu-dyn), Front (oceanography), Physics - Fluid Dynamics, General Chemistry, Sedimentation, Condensed Matter Physics, Mean squared displacement, Flow velocity, Chemical physics, Particle, Dispersion (chemistry)

Abstract

Sedimentation in active fluids has come into focus due to the ubiquity of swimming micro-organisms in natural and industrial processes. Here, we investigate sedimentation dynamics of passive particles in a fluid as a function of bacteria E. coli concentration. Results show that the presence of swimming bacteria significantly reduces the speed of the sedimentation front even in the dilute regime, in which the sedimentation speed is expected to be independent of particle concentration. Furthermore, bacteria increase the dispersion of the passive particles, which determines the width of the sedimentation front. For short times, particle sedimentation speed has a linear dependence on bacterial concentration. Mean square displacement data shows, however, that bacterial activity decays over long experimental (sedimentation) times. An advection-diffusion equation coupled to bacteria population dynamics seems to capture concentration profiles relatively well. A single parameter, the ratio of single particle speed to the bacteria flow speed can be used to predict front sedimentation speed., Comment: Soft Matter, (2021). arXiv admin note: substantial text overlap with arXiv:1710.04068

Published

2021

11. The role of vimentin-nuclear interactions in persistent cell motility through confined spaces

Author

Jennifer Schwarz, Alison E. Patteson, and Sarthak Gupta

Subjects

Physics, biology, Chemistry, Cell, General Physics and Astronomy, FOS: Physical sciences, Vimentin, macromolecular substances, Condensed Matter - Soft Condensed Matter, Article, Cell nucleus, medicine.anatomical_structure, Centrosome, Microtubule, Biological Physics (physics.bio-ph), Cell polarity, biology.protein, medicine, Biophysics, Soft Condensed Matter (cond-mat.soft), Physics - Biological Physics, Cytoskeleton, Intermediate filament, Nucleus, Actin

Abstract

The ability of cells to move through small spaces depends on the mechanical properties of the cellular cytoskeleton and on nuclear deformability. In mammalian cells, the cytoskeleton is comprised of three interacting, semi-flexible polymer networks: actin, microtubules, and intermediate filaments (IF). Recent experiments of mouse embryonic fibroblasts with and without vimentin have shown that the IF vimentin plays a role in confined cell motility. We, therefore, develop a minimal model of cells moving through confined geometries that effectively includes all three types of cytoskeletal filaments with a cell consisting of an actomyosin cortex and a deformable cell nucleus and mechanical connections between the two cortices the outer actomyosin one and the inner nuclear one. By decreasing the amount of vimentin, we find that the cell speed is typically faster for vimentin-null cells as compared to cells with vimentin. Vimentin-null cells also contain more deformed nuclei in confinement. Finally, vimentin affects nucleus positioning within the cell. By positing that as the nucleus position deviates further from the center of mass of the cell, microtubules become more oriented in a particular direction to enhance cell persistence or polarity, we show that vimentin-nulls are more persistent than vimentin-full cells. The enhanced persistence indicates that the vimentin-null cells are more subjugated by the confinement since their internal polarization mechanism that depends on cross-talk of the centrosome with the nucleus and other cytoskeletal connections is diminished. In other words, the vimentin-null cells rely more heavily on external cues. Our modeling results present a quantitative interpretation for recent experiments and have implications for understanding the role of vimentin in the epithelial-mesenchymal transition., Comment: 16 pages, 13 figures

Published

2022

12. Vimentin Intermediate Filaments Can Enhance or Abate Active Cellular Forces in a Microenvironmental Stiffness-Dependent Manner

Author

Farid Alisafaei, Kalpana Mandal, Maxx Swoger, Haiqian Yang, Ming Guo, Paul A Janmey, Alison E Patteson, and Vivek B. Shenoy

Subjects

macromolecular substances

Abstract

The mechanical properties of cells are largely determined by the cytoskeleton, which is a complex network of interconnected biopolymers consisting of actin filaments, microtubules, and intermediate filaments. While disruption of the actin filament and microtubule networks is known to decrease and increase cell-generated forces, respectively, the effect of intermediate filaments on cellular forces is not well understood. Using a combination of theoretical modeling and experiments, we show that disruption of vimentin intermediate filaments can either increase or decrease cell-generated forces, depending on microenvironment stiffness, reconciling seemingly opposite results in the literature. On the one hand, vimentin is involved in the transmission of actomyosin-based tensile forces to the matrix and therefore enhances traction forces. On the other hand, vimentin reinforces microtubules and their stability under compression, thus promoting the role of microtubules in suppressing cellular traction forces. We show that the competition between these two opposing effects of vimentin is regulated by the microenvironment stiffness. For low matrix stiffness, the force-transmitting role of vimentin dominates over their microtubule-reinforcing role and therefore vimentin increases traction forces. At high matrix stiffness, vimentin decreases traction forces as the microtubule-reinforcing role of vimentin becomes more important with increasing matrix stiffness. Our theory reconciles seemingly disparate experimental observations on the role of vimentin in active cellular forces and provides a unified description of stiffness-dependent chemo-mechanical regulation of cell contractility by vimentin.SignificanceVimentin is a marker of the epithelial to mesenchymal transition which takes place during important biological processes including embryogenesis, metastasis, tumorigenesis, fibrosis, and wound healing. While the roles of the actin and microtubule networks in the transmission of cellular forces to the extracellular matrix are known, it is not clear how vimentin intermediate filaments impact cellular forces. Here, we show that vimentin impacts cellular forces in a matrix stiffness-dependent manner. Disruption of vimentin in cells on soft matrices reduces cellular forces, while it increases cellular forces in cells on stiff matrices. Given that cellular forces are central to both physiological and pathological processes, our study has broad implications for understanding the effect of vimentin on cellular forces in different microenvironments.

Published

2022

13. Dynamic remodeling of fiber networks with stiff inclusions under compressive loading

Author

Bobby Carroll, Minh-Tri Ho Thanh, and Alison E Patteson

Subjects

Biomaterials, Biomedical Engineering, General Medicine, Molecular Biology, Biochemistry, Article, Biotechnology

Abstract

The ability of tissues to sustain and withstand mechanical stress is critical to tissue development and healthy tissue maintenance. The mechanical properties of tissues are typically considered to be dominated by the fibrous extracellular matrix (ECM) component of tissues. Fiber network mechanics can capture certain mechanical features of tissues, such as shear strain stiffening, but is insufficient in describing the compressive response of certain tissues and blood clots that are rich in extracellular matrix. To understand the mechanical response of tissues, we employ a contemporary mechanical model, a fibrous network of fibrin embedded with inert bead inclusions that preserve the volume-conserving constraints of cells in tissues. Combining bulk mechanical rheology and a custom imaging device, we show that the presence of inclusions alters the local dynamic remodeling of the networks undergoing uniaxial compressive strains and demonstrate non-affine correlated motion within a fiber-bead network, predicted to stretch fibers in the network and lead to the ability of the network to stiffen under compression, a key feature of real tissues. These findings have important implications for understanding how local structural properties of cells and ECM fibers impact the bulk mechanical response of real tissues. STATEMENT OF SIGNIFICANCE: To understand why real tissue stiffens under compression, we study a model tissue system which also stiffens: a fibrin network embedded with stiff beads. We design a device that images compression of both fiber and fiber-bead networks. Distinct from previous imaging studies, this setup can dynamically capture network deformation on scales larger than single fibers. From the videos, we see fluid flow and network remodeling are both critical to compression behavior. The fiber-bead network has faster fluid flow, reduced network recovery, and correlated motion during network relaxation. We hypothesize that the beads hinder network relaxation of stretched fibers, thus retaining the applied stress and exhibiting stiffening. Our findings reveal important details for modeling tissue mechanics towards optimizing healthcare.

Published

2022

14. Spreading rates of bacterial colonies depend on substrate stiffness and permeability

Author

Merrill E Asp, Minh-Tri Ho Thanh, Danielle A Germann, Robert J Carroll, Alana Franceski, Roy D Welch, Arvind Gopinath, and Alison E Patteson

Subjects

biochemical phenomena, metabolism, and nutrition

Abstract

The ability of bacteria to colonize and grow on different surfaces is an essential process for biofilm development. Here, we report the use of synthetic hydrogels with tunable stiffness and porosity to assess physical effects of the substrate on biofilm development. Using time-lapse microscopy to track the growth of expanding Serratia marcescens colonies, we find that biofilm colony growth can increase with increasing substrate stiffness, unlike what is found on traditional agar substrates. Using traction force microscopy-based techniques, we find that biofilms exert transient stresses correlated over length scales much larger than a single bacterium, and that the magnitude of these forces also increases with increasing substrate stiffness. Our results are consistent with a model of biofilm development in which the interplay between osmotic pressure arising from the biofilm and the poroelastic response of the underlying substrate controls biofilm growth and morphology.

Published

2022

15. Vimentin Intermediate Filaments Mediate Cell Morphology on Viscoelastic Substrates

Author

Maxx Swoger, Sarthak Gupta, Elisabeth E. Charrier, Michael Bates, Heidi Hehnly, and Alison E. Patteson

Subjects

Biomaterials, Actin Cytoskeleton, Mice, Biochemistry (medical), Biomedical Engineering, Intermediate Filaments, Animals, Vimentin, General Chemistry, Fibroblasts, Cell Shape, Cytoskeleton

Abstract

The ability of cells to take and change shape is a fundamental feature underlying development, wound repair, and tissue maintenance. Central to this process is physical and signaling interactions between the three cytoskeletal polymeric networks: F-actin, microtubules, and intermediate filaments (IFs). Vimentin is an IF protein that is essential to the mechanical resilience of cells and regulates cross-talk among the cytoskeleton, but its role in how cells sense and respond to the surrounding extracellular matrix is largely unclear. To investigate vimentin's role in substrate sensing, we designed polyacrylamide hydrogels that mimic the elastic and viscoelastic nature of

Published

2022

16. Rab11 endosomes and Pericentrin coordinate centrosome movement during pre-abscission in vivo

Author

Nikhila Krishnan, Maxx Swoger, Lindsay I Rathbun, Peter J Fioramonti, Judy Freshour, Michael Bates, Alison E Patteson, and Heidi Hehnly

Subjects

Centrosome, Ecology, rab GTP-Binding Proteins, Health, Toxicology and Mutagenesis, Animals, Plant Science, Endosomes, Antigens, Biochemistry, Genetics and Molecular Biology (miscellaneous), Zebrafish

Abstract

The last stage of cell division involves two daughter cells remaining interconnected by a cytokinetic bridge that is cleaved during abscission. Conserved between the zebrafish embryo and human cells, we found that the oldest centrosome moves in a Rab11-dependent manner towards the cytokinetic bridge sometimes followed by the youngest. Rab11-endosomes are organized in a Rab11-GTP dependent manner at the mother centriole during pre-abscission, with Rab11 endosomes at the oldest centrosome being more mobile compared with the youngest. The GTPase activity of Rab11 is necessary for the centrosome protein, Pericentrin, to be enriched at the centrosome. Reduction in Pericentrin expression or optogenetic disruption of Rab11-endosome function inhibited both centrosome movement towards the cytokinetic bridge and abscission, resulting in daughter cells prone to being binucleated and/or having supernumerary centrosomes. These studies suggest that Rab11-endosomes contribute to centrosome function during pre-abscission by regulating Pericentrin organization resulting in appropriate centrosome movement towards the cytokinetic bridge and subsequent abscission.

Published

2022

17. Rab11 endosomes coordinate centrosome number and movement following mitotic exit

Author

Judy Freshour, Peter J. Fioramonti, Nikhila Krishnan, Heidi Hehnly, Alison E. Patteson, Maxx Swoger, and Michael Bates

Subjects

Abscission, Dependent manner, Cell division, Centrosome, Endosome, Mitotic exit, Danio, Biology, biology.organism_classification, Zebrafish, Cell biology

Abstract

SUMMARYThe last stage of cell division involves two daughter cells remaining interconnected by a cytokinetic bridge that is cleaved in a process called abscission. During pre-abscission, we identified that the centrosome moves in a Rab11-dependent manner towards the cytokinetic bridge in human cells grown in culture and in an in vivo vertebrate model, Danio rerio (zebrafish). Rab11-endosomes are dynamically organized in a Rab11-GTP dependent manner at the centrosome during pre-abscission and this organization is required for the centrosome protein, pericentrin, to be enriched at the centrosome. Using zebrafish embryos, we found that reduction in pericentrin expression or optogenetically disrupting Rab11-endosome function inhibited centrosome movement towards the cytokinetic bridge and abscission resulting in daughter cells prone to being binucleated and/or having supernumerary centrosomes. These studies suggest that Rab11-endosomes contribute to centrosome function during pre-abscission by regulating pericentrin organization resulting in appropriate centrosome movement towards the cytokinetic bridge and subsequent abscission.

Published

2021

18. Compressing cell nuclei: from nonlinear mechanics to nontrivial shapes

Author

Sarthak Gupta, Edward J. Banigan, Alison E. Patteson, and Jennifer M. Schwarz

Subjects

Biophysics

Published

2022

19. Emergence of tissue-like mechanics from fibrous networks confined by close-packed cells

Author

Paul A. Janmey, Katarzyna Pogoda, Xingyu Chen, Alison E. Patteson, Katrina Cruz, Vivek B. Shenoy, Anne van Oosten, and Likang Chin

Subjects

chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, Materials science, 02 engineering and technology, Polymer, engineering.material, 021001 nanoscience & nanotechnology, Viscoelasticity, Stiffening, 03 medical and health sciences, chemistry, Rheology, Volume fraction, engineering, Biopolymer, Elasticity (economics), Composite material, 0210 nano-technology, Softening, 030304 developmental biology

Abstract

The viscoelasticity of the crosslinked semiflexible polymer networks—such as the internal cytoskeleton and the extracellular matrix—that provide shape and mechanical resistance against deformation is assumed to dominate tissue mechanics. However, the mechanical responses of soft tissues and semiflexible polymer gels differ in many respects. Tissues stiffen in compression but not in extension1–5, whereas semiflexible polymer networks soften in compression and stiffen in extension6,7. In shear deformation, semiflexible polymer gels stiffen with increasing strain, but tissues do not1–8. Here we use multiple experimental systems and a theoretical model to show that a combination of nonlinear polymer network elasticity and particle (cell) inclusions is essential to mimic tissue mechanics that cannot be reproduced by either biopolymer networks or colloidal particle systems alone. Tissue rheology emerges from an interplay between strain-stiffening polymer networks and volume-conserving cells within them. Polymer networks that soften in compression but stiffen in extension can be converted to materials that stiffen in compression but not in extension by including within the network either cells or inert particles to restrict the relaxation modes of the fibrous networks that surround them. Particle inclusions also suppress stiffening in shear deformation; when the particle volume fraction is low, they have little effect on the elasticity of the polymer networks. However, as the particles become more closely packed, the material switches from compression softening to compression stiffening. The emergence of an elastic response in these composite materials has implications for how tissue stiffness is altered in disease and can lead to cellular dysfunction9–11. Additionally, the findings could be used in the design of biomaterials with physiologically relevant mechanical properties. Tissue rheology emerges from the interplay between fibrous networks and cell inclusions, and the mechanical properties of tissues are modulated by restricting the relaxation modes of fibres close to volume-conserving cells.

Published

2019

20. How do biofilms feel their environment?

Author

Arvind Gopinath, M. Tri Ho Thanh, Alison E. Patteson, and Merrill Asp

Subjects

Pore size, Chemistry, Biofilm, FOS: Physical sciences, biochemical phenomena, metabolism, and nutrition, Substrate (biology), Traction force microscopy, Time-lapse microscopy, Biological Physics (physics.bio-ph), Substrate stiffness, Biophysics, Osmotic pressure, Physics - Biological Physics, Biofilm growth

Abstract

The ability of bacteria to colonize and grow on different surfaces is an essential process for biofilm development and depends on complex biomechanical interactions between the biofilm and the underlying substrate. Changes in the physical properties of the underlying substrate are known to alter biofilm expansion, but the mechanisms by which biofilms sense and respond to physical features of their environment are still poorly understood. Here, we report the use of synthetic polyacrylamide hydrogels with tunable stiffness and controllable pore size to assess physical effects of the substrate on biofilm development. Using time lapse microscopy to track the growth of expanding Serratia marcescens colonies, we find that biofilm colony growth can increase with increasing substrate stiffness on purely elastic substrates, unlike what is found on traditional agar substrates. Using traction force microscopy, we find that biofilms exert transient stresses correlated over length scales much larger than a single bacterium. Our results are consistent with a model of biofilm development in which the interplay between osmotic pressure arising from the biofilm and the poroelastic response of the underlying substrate controls biofilm growth and morphology.

Published

2021

21. A Data-Driven Statistical Description for the Hydrodynamics of Active Matter

Author

Ahmad Borzou, Jennifer Schwarz, and Alison E. Patteson

Subjects

Physics, Steady state, Statistical Mechanics (cond-mat.stat-mech), Spacetime, Entropy (statistical thermodynamics), Gaussian, FOS: Physical sciences, General Physics and Astronomy, Swarm behaviour, Condensed Matter - Soft Condensed Matter, Active matter, Complex dynamics, symbols.namesake, Flow (mathematics), symbols, Soft Condensed Matter (cond-mat.soft), Statistical physics, Condensed Matter - Statistical Mechanics

Abstract

Modeling living systems at the collective scale can be very challenging because the individual constituents can themselves be complex and the respective interactions between the constituents are not fully understood. With the advent of high throughput experiments and in the age of big data, data-driven methods are on the rise to overcome these challenges. To directly uncover the underlying physical principles, we present a data-driven method for obtaining the phase-space density such that the solution to the stochastic dynamic equation for active matter readily emerges, from which time and space dependence of physical order parameters can be readily extracted. If the system is near a steady state, we illuminate how to construct a field theory to subsequently make physical predictions about the system. The method is first developed analytically and subsequently calibrated using simulated data. The method is then applied to an experimental system of particles actively driven by a {\it Serratia marcescens} bacterial swarm and in the presence of spatially localized UV light. The analysis demonstrates that the particles are in the steady-state before and sometime after the UV light and obey a Gaussian field theory with a spatially-varying "mass" in those regimes. This novel, yet simple, finding is surprising given the complex dynamics of the bacterial swarm. In response to the UV light, we demonstrate that there is a net flow of the particles away from the UV light and that the entropy of the particles increases away from the light. We conclude with a discussion of additional potential applications of our data-driven method such as when the internal structure of the individual constituents dynamically changes to result in a modified stochastic dynamic equation governing the system., 15 pages, 9 figures, comments are welcome

Published

2021

22. Materials science and mechanosensitivity of living matter

Author

Alison E. Patteson, Merrill E. Asp, and Paul A. Janmey

Subjects

Reviews, General Physics and Astronomy

Abstract

Living systems are composed of molecules that are synthesized by cells that use energy sources within their surroundings to create fascinating materials that have mechanical properties optimized for their biological function. Their functionality is a ubiquitous aspect of our lives. We use wood to construct furniture, bacterial colonies to modify the texture of dairy products and other foods, intestines as violin strings, bladders in bagpipes, and so on. The mechanical properties of these biological materials differ from those of other simpler synthetic elastomers, glasses, and crystals. Reproducing their mechanical properties synthetically or from first principles is still often unattainable. The challenge is that biomaterials often exist far from equilibrium, either in a kinetically arrested state or in an energy consuming active state that is not yet possible to reproduce de novo. Also, the design principles that form biological materials often result in nonlinear responses of stress to strain, or force to displacement, and theoretical models to explain these nonlinear effects are in relatively early stages of development compared to the predictive models for rubberlike elastomers or metals. In this Review, we summarize some of the most common and striking mechanical features of biological materials and make comparisons among animal, plant, fungal, and bacterial systems. We also summarize some of the mechanisms by which living systems develop forces that shape biological matter and examine newly discovered mechanisms by which cells sense and respond to the forces they generate themselves, which are resisted by their environment, or that are exerted upon them by their environment. Within this framework, we discuss examples of how physical methods are being applied to cell biology and bioengineering.

Published

2022

23. Cell nuclei as cytoplasmic rheometers

Author

Alison E. Patteson and Jennifer Schwarz

Subjects

Cell Nucleus, Cytoplasm, Chemistry, Rheometer, Cell, Biophysics, Articles, Cell biology, Quantitative Biology::Cell Behavior, medicine.anatomical_structure, medicine, Rheology, Cytoskeleton

Abstract

Mechanical properties of the cell are important biomarkers for probing its architectural changes caused by cellular processes and/or pathologies. The development of microfluidic technologies has enabled measuring the cell’s mechanical properties at high throughput so that mechanical phenotyping can be applied to large samples in reasonable timescales. These studies typically measure the stiffness of the cell as the only mechanical biomarker and do not disentangle the rheological contributions of different structural components of the cell, including the cell cortex, the interior cytoplasm and its immersed cytoskeletal structures, and the nucleus. Recent advancements in high-speed fluorescent imaging have enabled probing the deformations of the cell cortex while also tracking different intracellular components in rates applicable to microfluidic platforms. We present a, to our knowledge, novel method to decouple the mechanics of the cell cortex and the cytoplasm by analyzing the correlation between the cortical deformations that are induced by external microfluidic flows and the nucleus displacements, induced by those cortical deformations, i.e., we use the nucleus as a high-throughput microrheological probe to study the rheology of the cytoplasm, independent of the cell cortex mechanics. To demonstrate the applicability of this method, we consider a proof-of-concept model consisting of a rigid spherical nucleus centered in a spherical cell. We obtain analytical expressions for the time-dependent nucleus velocity as a function of the cell deformations when the interior cytoplasm is modeled as a viscous, viscoelastic, porous, and poroelastic material and demonstrate how the nucleus velocity can be used to characterize the linear rheology of the cytoplasm over a wide range of forces and timescales/frequencies.

Published

2020

24. A torsion-based rheometer for measuring viscoelastic material properties

Author

Alison E. Patteson, Katherine Kerr, Dawei Song, Elise Jutzeler, and Merrill Asp

Subjects

Younger age, Rheology, Computer science, Rheometer, Torsion (mechanics), Mechanical engineering, Limiting, Ideal solution, Material properties, Viscoelasticity

Abstract

Rheology and the study of viscoelastic materials is an integral part of engineering and the study of biophysical systems however the cost of a rheometer is only feasible for colleges, universities and research laboratories. Even if a rheometer can be purchased it is bulky and delicately calibrated limiting its usefulness to the laboratory itself. The design presented here is less than a tenth of the cost of a professional rheometer and portable making it the ideal solution for high school students as a way to introduce viscoelasticity at a younger age as well as for use in the field for obtaining preliminary rheological data.

Published

2020

25. Vimentin tunes cell migration on collagen by controlling β1 integrin activation and clustering

Author

Wilson Lee, Jelena Tanic, Sevil Abbasi, Zofia Ostrowska-Podhorodecka, Paul A. Janmey, Alison E. Patteson, Christopher A. McCulloch, Isabel Ding, Pamma D. Arora, and Richard S.C. Liu

Subjects

Integrin, Cell, Vimentin, macromolecular substances, CDC42, Focal adhesion, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, medicine, Cell Adhesion, Cluster Analysis, Paxillin, 030304 developmental biology, 0303 health sciences, biology, Integrin beta1, Cell migration, Cell Biology, Cell biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, biology.protein, Collagen, Mesenchymal cell migration

Abstract

Vimentin is a structural protein that is required for mesenchymal cell migration and directly interacts with actin, β1 integrin and paxillin. We examined how these interactions enable vimentin to regulate cell migration on collagen. In fibroblasts, depletion of vimentin increased talin-dependent activation of β1 integrin by more than 2-fold. Loss of vimentin was associated with reduction of β1 integrin clustering by 50% and inhibition of paxillin recruitment to focal adhesions by more than 60%, which was restored by vimentin expression. This reduction of paxillin was associated with 65% lower Cdc42 activation, a 60% reduction of cell extension formation and a greater than 35% decrease in cell migration on collagen. The activation of PAK1, a downstream effector of Cdc42, was required for vimentin phosphorylation and filament maturation. We propose that vimentin tunes cell migration through collagen by acting as an adaptor protein for focal adhesion proteins, thereby regulating β1 integrin activation, resulting in well-organized, mature integrin clusters. This article has an associated First Person interview with the first author of the paper.

Published

2020

26. Vimentin intermediate filaments mediate cell shape on visco-elastic substrates

Author

Michael Bates, Maxx Swoger, Alison E. Patteson, Sarthak Gupta, Heidi Hehnly, and Elisabeth E. Charrier

Subjects

Extracellular matrix, biology, Microtubule, Chemistry, Biophysics, Extracellular, biology.protein, Vimentin, macromolecular substances, Cytoskeleton, Intermediate filament, Process (anatomy), Embryonic stem cell

Abstract

The ability of cells to take and change shape is a fundamental feature underlying development, wound repair, and tissue maintenance. Central to this process is physical and signaling interactions between the three cytoskeletal polymeric networks: F-actin, microtubules, and intermediate filaments (IFs). Vimentin is an IF protein that is essential to the mechanical resilience of cells and regulates cross-talk amongst the cytoskeleton, but its role in how cells sense and respond to the surrounding extracellular matrix is largely unclear. To investigate vimentin’s role in substrate sensing, we designed polyacrylamide hydrogels that mimic the elastic and viscoelastic nature of in vivo tissues. Using wild-type and vimentin-null mouse embryonic fibroblasts, we show that vimentin enhances cell spreading on viscoelastic substrates, even though it has little effect in the limit of purely elastic substrates. Our results provide compelling evidence that the vimentin cytoskeletal network is a physical modulator of how cells sense and respond to mechanical properties of their extracellular environment.

Published

2020

27. Dynamic nuclear structure emerges from chromatin crosslinks and motors

Author

Kuang Liu, Edward J. Banigan, Jennifer Schwarz, and Alison E. Patteson

Subjects

Quantitative Biology - Subcellular Processes, Shell (structure), General Physics and Astronomy, macromolecular substances, 01 natural sciences, Chromosomes, Protein filament, 03 medical and health sciences, 0302 clinical medicine, 0103 physical sciences, medicine, Humans, 010306 general physics, Subcellular Processes (q-bio.SC), 030304 developmental biology, Cell Nucleus, Physics, 0303 health sciences, Chemistry, Molecular Motor Proteins, Dynamics (mechanics), technology, industry, and agriculture, Nuclear structure, Chromosome, Chromatin, Nuclear shape, Cell nucleus, medicine.anatomical_structure, Models, Chemical, FOS: Biological sciences, Biophysics, 030217 neurology & neurosurgery, Lamin

Abstract

The cell nucleus houses the chromosomes, which are linked to a soft shell of lamin filaments. Experiments indicate that correlated chromosome dynamics and nuclear shape fluctuations arise from motor activity. To identify the physical mechanisms, we develop a model of an active, crosslinked Rouse chain bound to a polymeric shell. System-sized correlated motions occur but require both motor activity {\it and} crosslinks. Contractile motors, in particular, enhance chromosome dynamics by driving anomalous density fluctuations. Nuclear shape fluctuations depend on motor strength, crosslinking, and chromosome-lamina binding. Therefore, complex chromatin dynamics and nuclear shape emerge from a minimal, active chromosome-lamina system., 18 pages, 21 figures

Published

2020

28. A tissue-engineered human trabecular meshwork hydrogel for advanced glaucoma disease modeling

Author

Alison E. Patteson, Haiyan Li, Nasim Annabi, Preethi S. Ganapathy, Tyler Bague, Alexander Kirschner, W. Daniel Stamer, Ana N. Strat, Samuel Herberg, Haven Roberts, and Robert W. Weisenthal

Subjects

Pyridines, Glaucoma, Real-Time Polymerase Chain Reaction, Models, Biological, Dexamethasone, Contractility, Extracellular matrix, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Biomimetic Materials, Trabecular Meshwork, Hyaluronic acid, medicine, Humans, Enzyme Inhibitors, Eye Proteins, Glucocorticoids, Actin, Glycoproteins, Aged, 80 and over, rho-Associated Kinases, Tissue engineered, Tissue Engineering, biology, Cell growth, Chemistry, Hydrogels, medicine.disease, Amides, Immunohistochemistry, Sensory Systems, Actins, Elastin, Cell biology, Fibronectin, Ophthalmology, Cytoskeletal Proteins, medicine.anatomical_structure, Gene Expression Regulation, Self-healing hydrogels, biology.protein, Female, sense organs, Trabecular meshwork, Glaucoma, Open-Angle

Abstract

PurposeAbnormal human trabecular meshwork (HTM) cell function and extracellular matrix (ECM) remodeling contribute to HTM stiffening in primary open-angle glaucoma (POAG). Most current cellular HTM model systems do not sufficiently replicate the complex native three dimensional (3D) cell-ECM interface, which makes them less than ideal to investigate POAG pathology. Tissue-engineered protein-based hydrogels are ideally positioned to overcome shortcomings of current models. Here, we report a novel biomimetic HTM hydrogel and test its utility as a POAG disease model.MethodsHTM hydrogels were engineered by mixing normal donor-derived HTM cells with collagen type I, elastin-like polypeptide and hyaluronic acid, each containing photoactive functional groups, followed by UV light-activated free-radical crosslinking. Glaucomatous conditions were induced with dexamethasone (DEX), and therapeutic effects of the Rho-associated kinase (ROCK) inhibitor Y27632 on cytoskeletal organization and tissue-level function, contingent on HTM cell-ECM interactions, were assessed.ResultsDEX exposure increased HTM hydrogel contractility, f-actin and alpha smooth muscle actin abundance and rearrangement, ECM remodeling, and fibronectin and collagen type IV deposition, all contributing to HTM hydrogel condensation and stiffening consistent with recent data from normal vs. glaucomatous HTM tissue. Y27632 treatment produced precisely the opposite effects and attenuated the DEX-induced pathologic changes, resulting in HTM hydrogel relaxation and softening.ConclusionsWe have developed a biomimetic HTM hydrogel model for detailed investigation of 3D cell-ECM interactions under normal and simulated glaucomatous conditions. Its bidirectional responsiveness to pharmaceutical challenge and rescue suggests promising potential to serve as screening platform for new POAG treatments with focus on HTM biomechanics.

Published

2020

29. The vimentin cytoskeleton: When polymer physics meets cell biology

Author

Alison E. Patteson, Robert J. Carroll, Daniel V. Iwamoto, and Paul A. Janmey

Subjects

Polymers, Cell, Biophysics, Motility, FOS: Physical sciences, Vimentin, macromolecular substances, Article, Physical Phenomena, 03 medical and health sciences, Mice, 0302 clinical medicine, Structural Biology, Microtubule, medicine, Intermediate Filament Protein, Animals, Humans, Physics - Biological Physics, Intermediate filament, Cytoskeleton, Molecular Biology, 030304 developmental biology, 0303 health sciences, biology, Mesenchymal stem cell, Cell Biology, Cell biology, medicine.anatomical_structure, Biological Physics (physics.bio-ph), biology.protein, 030217 neurology & neurosurgery

Abstract

The proper functions of tissues depend on the ability of cells to withstand stress and maintain shape. Central to this process is the cytoskeleton, comprised of three polymeric networks: F-actin, microtubules, and intermediate filaments (IFs). IF proteins are among the most abundant cytoskeletal proteins in cells; yet they remain some of the least understood. Their structure and function deviate from those of their cytoskeletal partners, F-actin and microtubules. IF networks show a unique combination of extensibility, flexibility and toughness that confers mechanical resilience to the cell. Vimentin is an IF protein expressed in mesenchymal cells. This review highlights exciting new results on the physical biology of vimentin intermediate filaments and their role in allowing whole cells and tissues to cope with stress.

Published

2020

30. Extracellular Vimentin as a Target Against SARS‐CoV‐2 Host Cell Invasion

Author

Robert Bucki, Jennifer Schwarz, Joanna Reszeć, Ewelina Piktel, Alison E. Patteson, Łukasz Suprewicz, Krzysztof Pyrc, Natalia Marcinczyk, Marzena Lenart, Fitzroy J. Byfield, Daniel V. Iwamoto, Sarthak Gupta, Robert J. Carroll, Paul A. Janmey, Maxx Swoger, and Danielle A. Germann

Subjects

Cell type, viruses, Cell, Vimentin, Article, Antibodies, Biomaterials, medicine, Extracellular, Intermediate Filament Protein, Humans, General Materials Science, Receptor, skin and connective tissue diseases, biology, Chemistry, SARS-CoV-2, fungi, COVID-19, General Chemistry, In vitro, Cell biology, respiratory tract diseases, body regions, medicine.anatomical_structure, Spike Glycoprotein, Coronavirus, biology.protein, Antibody, Protein Binding, Biotechnology

Abstract

Infection of human cells by pathogens, including SARS-CoV-2, typically proceeds by cell surface binding to a crucial receptor. The primary receptor for SARS-CoV-2 is the angiotensin-converting enzyme 2 (ACE2), yet new studies reveal the importance of additional extracellular co-receptors that mediate binding and host cell invasion by SARS-CoV-2. Vimentin is an intermediate filament protein that is increasingly recognized as being present on the extracellular surface of a subset of cell types, where it can bind to and facilitate pathogens’ cellular uptake. To determine whether vimentin might bind with SARS-CoV-2 and facilitates its uptake, SARS-CoV-2 pseudoviruses coated with the SARS-CoV-2 spike protein and their interaction with vimentin was investigated. Dynamic light scattering shows that vimentin binds to SARS-CoV-2 pseudovirus coated with the SARS-CoV-2 spike protein, and antibodies against vimentin block in vitro SARS-CoV-2 pseudovirus infection of ACE2-expressing cells. Our results are consistent with a model in which extracellular vimentin acts a co-receptor for SARS-CoV-2 spike protein with a binding affinity less than that of the spike protein with ACE2. Extracellular vimentin may thus serve as a critical component of the SARS-CoV-2 spike protein-ACE2 complex in mediating SARS-CoV-2 cell entry, and vimentin-targeting agents may yield new therapeutic strategies for preventing and slowing SARS-CoV-2 infection.

Published

2021

31. Loss of Vimentin Enhances Cell Motility through Small Confining Spaces

Author

Paul A. Janmey, Katarzyna Pogoda, Koushik Mandal, Alison E. Patteson, Zofia Ostrowska-Podhorodecka, Robert Bucki, Fitzroy J. Byfield, Piotr Deptuła, Peter A. Galie, Elisabeth E. Charrier, and Christopher A. McCulloch

Subjects

Cell, Motility, Vimentin, 02 engineering and technology, macromolecular substances, 010402 general chemistry, 01 natural sciences, Traction force microscopy, Article, Biomaterials, Mice, Microtubule, Cell Movement, medicine, Animals, General Materials Science, Intermediate filament, Cytoskeleton, Myosin Type II, biology, Chemistry, Hydrogels, General Chemistry, 021001 nanoscience & nanotechnology, Embryonic stem cell, 0104 chemical sciences, Biomechanical Phenomena, Capillaries, medicine.anatomical_structure, biology.protein, Biophysics, NIH 3T3 Cells, Collagen, 0210 nano-technology, Biotechnology

Abstract

The migration of cells through constricting spaces or along fibrous tracks in tissues is important for many biological processes and depends on the mechanical properties of a cytoskeleton made up of three different filaments: F-actin, microtubules, and intermediate filaments. The signaling pathways and cytoskeletal structures that control cell motility on 2D are often very different from those that control motility in 3D. Previous studies have shown that intermediate filaments can promote actin-driven protrusions at the cell edge, but have little effect on overall motility of cells on flat surfaces. They are however important for cells to maintain resistance to repeated compressive stresses that are expected to occur in vivo. Using mouse embryonic fibroblasts derived from wild-type and vimentin-null mice, it is found that loss of vimentin increases motility in 3D microchannels even though on flat surfaces it has the opposite effect. Atomic force microscopy and traction force microscopy experiments reveal that vimentin enhances perinuclear cell stiffness while maintaining the same level of acto-myosin contractility in cells. A minimal model in which a perinuclear vimentin cage constricts along with the nucleus during motility through confining spaces, providing mechanical resistance against large strains that could damage the structural integrity of cells, is proposed.

Published

2019

32. Vimentin protects the structural integrity of the nucleus and suppresses nuclear damage caused by large deformations

Author

Katarzyna Pogoda, Stephen A. Adam, Alison E. Patteson, Paul A. Janmey, Amir Vahabikashi, Robert D. Goldman, and Anne E. Goldman

Subjects

0303 health sciences, biology, Chemistry, Cell, Motility, Vimentin, Cell migration, Embryonic stem cell, Cell biology, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, biology.protein, medicine, Intermediate Filament Protein, Intermediate filament, Nucleus, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Mammalian cells frequently migrate through tight spaces during normal embryogenesis, wound healing, diapedesis or in pathological situations such as metastasis. The nucleus has recently emerged as an important factor in regulating 3D cell migration. At the onset of migratory behavior, cells often initiate the expression of vimentin, an intermediate filament protein which forms networks extending from a juxtanuclear cage to the cell periphery. However, the role of vimentin intermediate filaments (VIFs) in regulating nuclear shape and mechanics remains unknown. Here, we used wild type and vimentin-null mouse embryonic fibroblasts to show that VIFs regulate nuclear shape, motility, and the ability of cells to resist large deformations. The results show that loss of VIFs alters nuclear shape, reduces perinuclear stiffness, and enhances motility in 3D. These changes increase nuclear rupture and activation of DNA damage repair mechanisms, which are rescued by exogenous re-expression of vimentin. Our findings show that VIFs provide mechanical support to protect the nucleus and genome during migration.

Published

2019

33. Loops versus lines and the compression stiffening of cells

Author

Alison E. Patteson, Anne van Oosten, Tyler Engstrom, Mahesh Chandrasekhar Gandikota, Jennifer Schwarz, Katarzyna Pogoda, and Paul A. Janmey

Subjects

Materials science, Polymers, FOS: Physical sciences, 02 engineering and technology, Condensed Matter - Soft Condensed Matter, Atomic packing factor, Microscopy, Atomic Force, Article, 03 medical and health sciences, Mice, Rheology, Cell Behavior (q-bio.CB), Animals, Loop modeling, Physics - Biological Physics, Composite material, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Fibrin, Vesicle, General Chemistry, Polymer, Actomyosin, Fibroblasts, Models, Theoretical, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Stiffening, Nonlinear system, chemistry, Biological Physics (physics.bio-ph), FOS: Biological sciences, Compressibility, Quantitative Biology - Cell Behavior, Soft Condensed Matter (cond-mat.soft), 0210 nano-technology

Abstract

Both animal and plant tissue exhibit a nonlinear rheological phenomenon known as compression stiffening, or an increase in moduli with increasing uniaxial compressive strain. Does such a phenomenon exist in single cells, which are the building blocks of tissues? One expects an individual cell to compression soften since the semiflexible biopolymer-based cytoskeletal network maintains the mechanical integrity of the cell and in vitro semiflexible biopolymer networks typically compression soften. To the contrary, we find that mouse embryonic fibroblasts (mEFs) compression stiffen under uniaxial compression via atomic force microscopy (AFM) studies. To understand this finding, we uncover several potential mechanisms for compression stiffening. First, we study a single semiflexible polymer loop modeling the actomyosin cortex enclosing a viscous medium modeled as an incompressible fluid. Second, we study a two-dimensional semiflexible polymer/fiber network interspersed with area-conserving loops, which are a proxy for vesicles and fluid-based organelles. Third, we study two-dimensional fiber networks with angular-constraining crosslinks, i.e. semiflexible loops on the mesh scale. In the latter two cases, the loops act as geometric constraints on the fiber network to help stiffen it via increased angular interactions. We find that the single semiflexible polymer loop model agrees well with our AFM experiments until approximately 35% compressive strain. We also find for the fiber network with area-conserving loops model that the stress-strain curves are sensitive to the packing fraction and size distribution of the area-conserving loops, thereby creating a mechanical fingerprint across different cell types. Finally, we make comparisons between this model and experiments on fibrin networks interlaced with beads as well as discuss the tissue-scale implications of cellular compression stiffening., Comment: 19 pages, 17 figures

Published

2019

34. Cell-induced confinement effects in soft tissue mechanics

Author

Dawei Song, Alison E. Patteson, Jordan Shivers, Paul A. Janmey, and Fred C. MacKintosh

Subjects

010302 applied physics, Soft tissue mechanics, Materials science, Mechanism (biology), Cell, General Physics and Astronomy, Soft tissue, 02 engineering and technology, 021001 nanoscience & nanotechnology, Compression (physics), 01 natural sciences, Stiffening, medicine.anatomical_structure, Tissue engineering, Rheology, 0103 physical sciences, medicine, Biophysics, 0210 nano-technology

Abstract

The mechanical properties of tissues play a critical role in their normal and pathophysiological functions such as tissue development, aging, injury, and disease. Understanding tissue mechanics is important not only for designing realistic biomimetic materials for tissue engineering and drug testing but also for developing novel diagnostic techniques and medical interventions. Tissues are heterogeneous materials consisting of cells confined within extracellular matrices (ECMs), both of which derive their structural integrity, at least in part, from networks of biopolymers. However, the rheology of purified reconstituted biopolymer networks fails to explain many key aspects of tissue mechanics. Notably, purified networks typically soften under applied compression, whereas many soft tissues like liver, fat, and brain instead stiffen when compressed. While continuum models can readily capture this compression-stiffening behavior, the underlying mechanism is not fully understood. In this perspective paper, we discuss several recently proposed microscopic mechanisms that may explain compression stiffening of soft tissues. These mechanisms include (I) interactions between the ECM and volume-preserving inclusions that promote extension-dominated stiffening of fibrous ECMs when subject to uniform compression, (II) ECM interactions with rigid inclusions under non-uniform compression, (III) other internal physical constraints that cause compression stiffening of cells and ECMs, and (IV) propagation of compressive forces through jammed, compression-stiffening cells. We further identify a few of the many open problems in understanding the structure–function relationship of soft-tissue mechanics.

Published

2021

35. Active colloids in complex fluids

Author

Arvind Gopinath, Paulo E. Arratia, and Alison E. Patteson

Subjects

Collective behavior, Steady state, Materials science, Polymers and Plastics, FOS: Physical sciences, Surfaces and Interfaces, Condensed Matter - Soft Condensed Matter, 01 natural sciences, 010305 fluids & plasmas, Active matter, Suspension (chemistry), Colloid and Surface Chemistry, Rheology, Biological Physics (physics.bio-ph), Chemical physics, 0103 physical sciences, Newtonian fluid, Soft Condensed Matter (cond-mat.soft), Physics - Biological Physics, Physical and Theoretical Chemistry, Current (fluid), 010306 general physics, Complex fluid

Abstract

We review recent work on active colloids or swimmers, such as self-propelled microorganisms, phoretic colloidal particles, and artificial micro-robotic systems, moving in fluid-like environments. These environments can be water-like and Newtonian but can frequently contain macromolecules, flexible polymers, soft cells, or hard particles, which impart complex, nonlinear rheological features to the fluid. While significant progress has been made on understanding how active colloids move and interact in Newtonian fluids, little is known on how active colloids behave in complex and non-Newtonian fluids. An emerging literature is starting to show how fluid rheology can dramatically change the gaits and speeds of individual swimmers. Simultaneously, a moving swimmer induces time dependent, three dimensional fluid flows, that can modify the medium (fluid) rheological properties. This two-way, non-linear coupling at microscopic scales has profound implications at meso- and macro-scales: steady state suspension properties, emergent collective behavior, and transport of passive tracer particles. Recent exciting theoretical results and current debate on quantifying these complex active fluids highlight the need for conceptually simple experiments to guide our understanding., Comment: 6 figures

Published

2016

36. BioEssays 11/2020

Author

Robert D. Goldman, Alison E. Patteson, Amir Vahabikashi, and Paul A. Janmey

Subjects

General Biochemistry, Genetics and Molecular Biology

Published

2020

37. Mechanical and Non‐Mechanical Functions of Filamentous and Non‐Filamentous Vimentin

Author

Alison E. Patteson, Amir Vahabikashi, Paul A. Janmey, and Robert D. Goldman

Subjects

Intermediate Filaments, Vimentin, macromolecular substances, Biology, Bacterial Physiological Phenomena, Mechanotransduction, Cellular, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Extracellular, Animals, Humans, Cytoskeleton, Intermediate filament, Mechanical Phenomena, 030304 developmental biology, 0303 health sciences, Cell migration, Virus Internalization, Cell biology, Severe acute respiratory syndrome-related coronavirus, Host-Pathogen Interactions, biology.protein, Wound healing, 030217 neurology & neurosurgery, Function (biology)

Abstract

Intermediate filaments (IFs) formed by vimentin are less understood than their cytoskeletal partners, microtubules and F-actin, but the unique physical properties of IFs, especially their resistance to large deformations, initially suggest a mechanical function. Indeed, vimentin IFs help regulate cell mechanics and contractility, and in crowded 3D environments they protect the nucleus during cell migration. Recently, a multitude of studies, often using genetic or proteomic screenings show that vimentin has many non-mechanical functions within and outside of cells. These include signaling roles in wound healing, lipogenesis, sterol processing, and various functions related to extracellular and cell surface vimentin. Extracellular vimentin is implicated in marking circulating tumor cells, promoting neural repair, and mediating the invasion of host cells by viruses, including SARS-CoV, or bacteria such as Listeria and Streptococcus. These findings underscore the fundamental role of vimentin in not only cell mechanics but also a range of physiological functions. Also see the video abstract here https://youtu.be/YPfoddqvz-g.

Published

2020

38. Loss of vimentin intermediate filaments decreases peri-nuclear stiffness and enhances cell motility through confined spaces

Author

Fitzroy J. Byfield, Alison E. Patteson, Katarzyna Pogoda, Peter A. Galie, Robert Bucki, Elisabeth E. Charrier, Paul A. Janmey, and Piotr Deptuła

Subjects

0303 health sciences, biology, Chemistry, 030302 biochemistry & molecular biology, Cell, FOS: Physical sciences, Motility, Vimentin, macromolecular substances, Cell biology, 03 medical and health sciences, medicine.anatomical_structure, Downregulation and upregulation, Biological Physics (physics.bio-ph), FOS: Biological sciences, Cell Behavior (q-bio.CB), medicine, biology.protein, Quantitative Biology - Cell Behavior, Intermediate Filament Protein, Physics - Biological Physics, Wound healing, Cytoskeleton, Intermediate filament, 030304 developmental biology

Abstract

The migration of cells through tight constricting spaces or along fibrous tracks in tissues is important for biological processes, such as embryogenesis, wound healing, and cancer metastasis, and depends on the mechanical properties of the cytoskeleton. Migratory cells often express and upregulate the intermediate filament protein vimentin. The viscoelasticity of vimentin networks in shear deformation has been documented, but its role in motility is largely unexplored. Here, we studied the effects of vimentin on cell motility and stiffness using mouse embryo fibroblasts derived from wild-type and vimentin-null mice. We find that loss of vimentin increases motility through small pores and along thin capillaries. Atomic force microscopy measurements reveal that the presence of vimentin enhances the perinuclear stiffness of the cell, to an extent that depends on surface ligand presentation and therefore signaling from extracellular matrix receptors. Together, our results indicate that vimentin hinders three-dimensional motility by providing mechanical resistance against large strains and may thereby protect the structural integrity of cells.

Published

2018

39. Quenching an active swarm: Effects of light exposure on collective motility in swarmingSerratia marcescenscolonies

Author

Arvind Gopinath, Alison E. Patteson, Junyi Yang, and Paulo E. Arratia

Subjects

0303 health sciences, Post exposure, biology, 030306 microbiology, Chemistry, Swarming (honey bee), Motility, Swarm behaviour, biology.organism_classification, 03 medical and health sciences, Light intensity, 13. Climate action, Serratia marcescens, Biophysics, Bacteria, 030304 developmental biology, Light exposure

Abstract

Swarming colonies of the light responsive bacteriaSerratia marcescensgrown on agar exhibit robust fluctuating large-scale collective flows that include arrayed vortices, jets, and sinuous streamers. We study the immobilization and quenching of these large-scale flows when the moving swarm is exposed to light with a substantial ultra-violet component. We map the response to light in terms of two independent parameters - the light intensity and duration of exposure and identify the conditions under which mobility is affected significantly. For small exposure times and/or low intensities, we find collective mobility to be negligibly affected. Increasing exposure times and/or intensity to higher values temporarily suppresses collective mobility. Terminating exposure allows bacteria regain motility and eventually reestablish large scale flows. For long exposure times or at high intensities, exposed bacteria become paralyzed, with macroscopic speeds eventually reducing to zero. In this process, they form highly aligned, jammed domains. Individual domains eventually coalesce into a large macroscopic domain with mean radial extent growing as the square root of exposure time. Post exposure, active bacteria dislodge exposed bacteria from these jammed configurations; initial dissolution rates are found to be strongly dependent on duration of exposure suggesting that caging effects are substantial at higher exposure times. Based on our experimental observations, we propose a minimal Brownian dynamics model to examine the escape of exposed bacteria from the region of exposure. Our results complement studies on planktonic bacteria and inform models for pattern formation in gradated illumination.

Published

2018

40. The propagation of active-passive interfaces in bacterial swarms

Author

Paulo E. Arratia, Alison E. Patteson, and Arvind Gopinath

Subjects

0301 basic medicine, Intravital Microscopy, Interface (Java), Ultraviolet Rays, Science, Movement, General Physics and Astronomy, Boundary (topology), Pattern formation, FOS: Physical sciences, Curvature, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Physics - Biological Physics, lcsh:Science, Mixing (physics), Serratia marcescens, 030304 developmental biology, Physics, 0303 health sciences, Multidisciplinary, 030306 microbiology, Swarm behaviour, food and beverages, General Chemistry, Mechanics, Active passive, 3. Good health, Active matter, 030104 developmental biology, Flow (mathematics), Biological Physics (physics.bio-ph), lcsh:Q, Biological system

Abstract

Propagating interfaces are ubiquitous in nature, underlying instabilities and pattern formation in biology and material science. Physical principles governing interface growth are well understood in passive settings; however, our understanding of interfaces in active systems is still in its infancy. Here, we study the evolution of an active-passive interface using a model active matter system, bacterial swarms. We use ultra-violet light exposure to create compact domains of passive bacteria within Serratia marcescens swarms, thereby creating interfaces separating motile and immotile cells. Post-exposure, the boundary re-shapes and erodes due to self-emergent collective flows. We demonstrate that the active-passive boundary acts as a diffuse interface with mechanical properties set by the flow. Intriguingly, interfacial velocity couples to local swarm speed and interface curvature, raising the possibility that an active analogue to classic Gibbs-Thomson-Stefan conditions may control this boundary propagation., The study of interfaces in bacterial systems is of relevance to the spreading of bacterial colonies and pathological infections. Here the authors investigate the dynamics of active/passive interfaces in bacterial swarms and find that the boundary can be described as a propagating, diffuse elastic interface.

Published

2018

41. Quenching active swarms: effects of light exposure on collective motility in swarming Serratia marcescens

Author

Arvind Gopinath, Alison E. Patteson, Junyi Yang, and Paulo E. Arratia

Subjects

food.ingredient, Light, biology, Chemistry, Biomedical Engineering, Biophysics, Swarming (honey bee), Quorum Sensing, Motility, Life Sciences–Physics interface, Bioengineering, biology.organism_classification, Models, Biological, Biochemistry, Microbiology, Biomaterials, food, Serratia marcescens, Agar, Bacteria, Biotechnology, Light exposure

Abstract

Swarming colonies of the light-responsive bacteria Serratia marcescens grown on agar exhibit robust fluctuating large-scale flows that include arrayed vortices, jets and sinuous streamers. We study the immobilization and quenching of these collective flows when the moving swarm is exposed to intense wide-spectrum light with a substantial ultraviolet component. We map the emergent response of the swarm to light in terms of two parameters—light intensity and duration of exposure—and identify the conditions under which collective motility is impacted. For small exposure times and/or low intensities, we find collective motility to be negligibly affected. Increasing exposure times and/or intensity to higher values suppresses collective motility but only temporarily. Terminating exposure allows bacteria to recover and eventually reestablish collective flows similar to that seen in unexposed swarms. For long exposure times or at high intensities, exposed bacteria become paralysed and form aligned, jammed regions where macroscopic speeds reduce to zero. The effective size of the quenched region increases with time and saturates to approximately the extent of the illuminated region. Post-exposure, active bacteria dislodge immotile bacteria; initial dissolution rates are strongly dependent on duration of exposure. Based on our experimental observations, we propose a minimal Brownian dynamics model to examine the escape of exposed bacteria from the region of exposure. Our results complement studies on planktonic bacteria, inform models of patterning in gradated illumination and provide a starting point for the study of specific wavelengths on swarming bacteria.

Published

2019

42. Emergence of tissue-like mechanics from fibrous networks confined by close-packed cells

Author

Anne S G, van Oosten, Xingyu, Chen, LiKang, Chin, Katrina, Cruz, Alison E, Patteson, Katarzyna, Pogoda, Vivek B, Shenoy, and Paul A, Janmey

Subjects

Male, Fibrin, Erythrocytes, Cell Count, Glioma, Fibroblasts, Models, Biological, Elasticity, Biomechanical Phenomena, Cell Line, Extracellular Matrix, Rats, Mice, Inbred C57BL, Rats, Sprague-Dawley, Mice, Biopolymers, Adipose Tissue, Animals, Humans, Rheology, Blood Coagulation

Abstract

The viscoelasticity of the crosslinked semiflexible polymer networks-such as the internal cytoskeleton and the extracellular matrix-that provide shape and mechanical resistance against deformation is assumed to dominate tissue mechanics. However, the mechanical responses of soft tissues and semiflexible polymer gels differ in many respects. Tissues stiffen in compression but not in extension

Published

2016

43. Particle diffusion in active fluids is non-monotonic in size

Author

Alison E. Patteson, Paulo E. Arratia, Arvind Gopinath, and Prashant K. Purohit

Subjects

Materials science, FOS: Physical sciences, 02 engineering and technology, Péclet number, Condensed Matter - Soft Condensed Matter, Thermal diffusivity, 01 natural sciences, Models, Biological, Minimal model, Diffusion, symbols.namesake, 0103 physical sciences, Escherichia coli, Physics - Biological Physics, Diffusion (business), Particle Size, 010306 general physics, Range (particle radiation), General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Biological Physics (physics.bio-ph), Chemical physics, symbols, Soft Condensed Matter (cond-mat.soft), Particle, Thermodynamics, Particle size, 0210 nano-technology, Dimensionless quantity

Abstract

We experimentally investigate the effect of particle size on the motion of passive polystyrene spheres in suspensions of Escherichia coli. Using particles covering a range of sizes from 0.6 to 39 microns, we probe particle dynamics at both short and long time scales. In all cases, the particles exhibit super-diffusive ballistic behavior at short times before eventually transitioning to diffusive behavior. Surprisingly, we find a regime in which larger particles can diffuse faster than smaller particles: the particle long-time effective diffusivity exhibits a peak in particle size, which is a deviation from classical thermal diffusion. We also find that the active contribution to particle diffusion is controlled by a dimensionless parameter, the Peclet number. A minimal model qualitatively explains the existence of the effective diffusivity peak and its dependence on bacterial concentration. Our results have broad implications on characterizing active fluids using concepts drawn from classical thermodynamics., 5 Figures

Published

2016

44. Running and tumbling with E. coli in polymeric solutions

Author

Paulo E. Arratia, Alison E. Patteson, Arvind Gopinath, and Mark Goulian

Subjects

Fluid viscosity, Rotation, Polymers, Motility, FOS: Physical sciences, 02 engineering and technology, Condensed Matter - Soft Condensed Matter, 01 natural sciences, Article, Diffusion, Cell Movement, 0103 physical sciences, Escherichia coli, Physics - Biological Physics, Elasticity (economics), 010306 general physics, chemistry.chemical_classification, Multidisciplinary, Viscosity, Chemistry, Chemotaxis, Fluid Dynamics (physics.flu-dyn), Rotational diffusion, Polymer, Physics - Fluid Dynamics, 021001 nanoscience & nanotechnology, Elasticity, Solutions, Swimming speed, Biological Physics (physics.bio-ph), Biophysics, Soft Condensed Matter (cond-mat.soft), 0210 nano-technology

Abstract

Run-and-tumble motility is widely used by swimming microorganisms including numerous prokaryotic and eukaryotic organisms. Here, we experimentally investigate the run-and-tumble dynamics of the bacterium E. coli in polymeric solutions. We find that even small amounts of polymer in solution can drastically change E. coli dynamics: cells tumble less and their velocity increases, leading to an enhancement in cell translational diffusion and a sharp decline in rotational diffusion. We show that suppression of tumbling is due to fluid viscosity while the enhancement in swimming speed is mainly due to fluid elasticity. Visualization of single fluorescently labeled DNA polymers reveals that the flow generated by individual E. coli is sufficiently strong to stretch polymer molecules and induce elastic stresses in the fluid, which in turn can act on the cell in such a way to enhance its transport. Our results show that the transport and spread of chemotactic cells can be independently modified and controlled by the fluid material properties.

Published

2015

45. The role of vimentin–nuclear interactions in persistent cell motility through confined spaces

Author

Sarthak Gupta, Alison E Patteson, and J M Schwarz

Subjects

cell motility in confinement, cell polarity in confinement, vimentin, cytoskeleton, cell nucleus, Science, Physics, QC1-999

Abstract

The ability of cells to move through small spaces depends on the mechanical properties of the cellular cytoskeleton and on nuclear deformability. In mammalian cells, the cytoskeleton is composed of three interacting, semi-flexible polymer networks: actin, microtubules, and intermediate filaments (IF). Recent experiments of mouse embryonic fibroblasts with and without vimentin have shown that the IF vimentin plays a role in confined cell motility. Here, we develop a minimal model of a cell moving through a microchannel that incorporates explicit effects of actin and vimentin and implicit effects of microtubules. Specifically, the model consists of a cell with an actomyosin cortex and a deformable cell nucleus and mechanical linkages between the two. By decreasing the amount of vimentin, we find that the cell speed increases for vimentin-null cells compared to cells with vimentin. The loss of vimentin increases nuclear deformation and alters nuclear positioning in the cell. Assuming nuclear positioning is a read-out for cell polarity, we propose a new polarity mechanism which couples cell directional motion with cytoskeletal strength and nuclear positioning and captures the abnormally persistent motion of vimentin-null cells, as observed in experiments. The enhanced persistence indicates that the vimentin-null cells are more controlled by the confinement and so less autonomous, relying more heavily on external cues than their wild-type counterparts. Our modeling results present a quantitative interpretation for recent experiments and have implications for understanding the role of vimentin in the epithelial–mesenchymal transition.

Published

2021