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46 results on '"Srivastava, Vasudha"'

1. Configurational entropy is an intrinsic driver of tissue structural heterogeneity

Author

Srivastava, Vasudha, Hu, Jennifer L, Garbe, James C, Veytsman, Boris, Shalabi, Sundus F, Yllanes, David, Thomson, Matt, LaBarge, Mark A, Huber, Greg, and Gartner, Zev J

Subjects
Biochemistry and Cell Biology, Physical Sciences, Biological Sciences, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Cell fluctuations, Cell sorting, Entropy, Heterogeneity, Interfacial mechanics, Mammary organoids, Statistical mechanics, Tissue self-organization
Abstract

Tissues comprise ordered arrangements of cells that can be surprisingly disordered in their details. How the properties of single cells and their microenvironment contribute to the balance between order and disorder at the tissue-scale remains poorly understood. Here, we address this question using the self-organization of human mammary organoids as a model. We find that organoids behave like a dynamic structural ensemble at the steady state. We apply a maximum entropy formalism to derive the ensemble distribution from three measurable parameters - the degeneracy of structural states, interfacial energy, and tissue activity (the energy associated with positional fluctuations). We link these parameters with the molecular and microenvironmental factors that control them to precisely engineer the ensemble across multiple conditions. Our analysis reveals that the entropy associated with structural degeneracy sets a theoretical limit to tissue order and provides new insight for tissue engineering, development, and our understanding of disease progression.

Published
2023

2. Programming the Self-Organization of Endothelial Cells into Perfusable Microvasculature

Author

Cabral, Katelyn A, Srivastava, Vasudha, Graham, Austin J, Coyle, Maxwell C, Stashko, Connor, Weaver, Valerie, and Gartner, Zev J

Subjects
Engineering, Biomedical Engineering, Bioengineering, 1.1 Normal biological development and functioning, Underpinning research, Endothelial Cells, Neovascularization, Physiologic, Tissue Engineering, Microvessels, Extracellular Matrix, engineered tissues, engineered microvasculature, bioprinting, cell patterning, optimization, cell behavior, microenvironment, tissue morphogenesis, vasculogenesis, Biochemistry and Cell Biology, Materials Engineering, Biomedical engineering
Abstract

The construction of three-dimensional (3D) microvascular networks with defined structures remains challenging. Emerging bioprinting strategies provide a means of patterning endothelial cells (ECs) into the geometry of 3D microvascular networks, but the microenvironmental cues necessary to promote their self-organization into cohesive and perfusable microvessels are not well known. To this end, we reconstituted microvessel formation in vitro by patterning thin lines of closely packed ECs fully embedded within a 3D extracellular matrix (ECM) and observed how different microenvironmental parameters influenced EC behaviors and their self-organization into microvessels. We found that the inclusion of fibrillar matrices, such as collagen I, into the ECM positively influenced cell condensation into extended geometries such as cords. We also identified the presence of a high-molecular-weight protein(s) in fetal bovine serum that negatively influenced EC condensation. This component destabilized cord structure by promoting cell protrusions and destabilizing cell-cell adhesions. Endothelial cords cultured in the presence of fibrillar collagen and in the absence of this protein activity were able to polarize, lumenize, incorporate mural cells, and support fluid flow. These optimized conditions allowed for the construction of branched and perfusable microvascular networks directly from patterned cells in as little as 3 days. These findings reveal important design principles for future microvascular engineering efforts based on bioprinting and micropatterning techniques. Impact statement Bioprinting is a potential strategy to achieve microvascularization in engineered tissues. However, the controlled self-organization of patterned endothelial cells into perfusable microvasculature remains challenging. We used DNA Programmed Assembly of Cells to create cell-dense, capillary-sized cords of endothelial cells with complete control over their structure. We optimized the matrix and media conditions to promote self-organization and maturation of these endothelial cords into stable and perfusable microvascular networks.

Published
2023

3. Patterning and folding of intestinal villi by active mesenchymal dewetting

Author

Huycke, Tyler R., Häkkinen, Teemu J., Miyazaki, Hikaru, Srivastava, Vasudha, Barruet, Emilie, McGinnis, Christopher S., Kalantari, Ali, Cornwall-Scoones, Jake, Vaka, Dedeepya, Zhu, Qin, Jo, Hyunil, Oria, Roger, Weaver, Valerie M., DeGrado, William F., Thomson, Matt, Garikipati, Krishna, Boffelli, Dario, Klein, Ophir D., and Gartner, Zev J.

Published
2024
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4. EPH/EPHRIN regulates cellular organization by actomyosin contractility effects on cell contacts

Author

Kindberg, Abigail A, Srivastava, Vasudha, Muncie, Jonathon M, Weaver, Valerie M, Gartner, Zev J, and Bush, Jeffrey O

Subjects
Biochemistry and Cell Biology, Biological Sciences, Underpinning research, 1.1 Normal biological development and functioning, Actin Cytoskeleton, Actomyosin, Animals, Cell Adhesion, Cell Movement, Ephrins, HEK293 Cells, Humans, Mice, Morphogenesis, Protein Binding, Receptors, Eph Family, Signal Transduction, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences
Abstract

EPH/EPHRIN signaling is essential to many aspects of tissue self-organization and morphogenesis, but little is known about how EPH/EPHRIN signaling regulates cell mechanics during these processes. Here, we use a series of approaches to examine how EPH/EPHRIN signaling drives cellular self-organization. Contact angle measurements reveal that EPH/EPHRIN signaling decreases the stability of heterotypic cell:cell contacts through increased cortical actomyosin contractility. We find that EPH/EPHRIN-driven cell segregation depends on actomyosin contractility but occurs independently of directed cell migration and without changes in cell adhesion. Atomic force microscopy and live cell imaging of myosin localization support that EPH/EPHRIN signaling results in increased cortical tension. Interestingly, actomyosin contractility also nonautonomously drives increased EPHB2:EPHB2 homotypic contacts. Finally, we demonstrate that changes in tissue organization are driven by minimization of heterotypic contacts through actomyosin contractility in cell aggregates and by mouse genetics experiments. These data elucidate the biomechanical mechanisms driving EPH/EPHRIN-based cell segregation wherein differences in interfacial tension, regulated by actomyosin contractility, govern cellular self-organization.

Published
2021

6. Organoid models for mammary gland dynamics and breast cancer

Author

Srivastava, Vasudha, Huycke, Tyler R, Phong, Kiet T, and Gartner, Zev J

Subjects
Biochemistry and Cell Biology, Biological Sciences, Breast Cancer, Cancer, Women's Health, Biotechnology, 1.1 Normal biological development and functioning, Aetiology, Underpinning research, 2.1 Biological and endogenous factors, Animals, Breast Neoplasms, Female, Humans, Mammary Glands, Animal, Mammary Glands, Human, Models, Biological, Morphogenesis, Organoids, Mammary organoids, Mammary gland development, Breast cancer models, Tissue structure dynamics, Developmental Biology, Biochemistry and cell biology
Abstract

The mammary gland is a highly dynamic tissue that undergoes repeated cycles of growth and involution during pregnancy and menstruation. It is also the site from which breast cancers emerge. Organoids provide an in vitro model that preserves several of the cellular, structural, and microenvironmental features that dictate mammary gland function in vivo and have greatly advanced our understanding of glandular biology. Their tractability for genetic manipulation, live imaging, and high throughput screening have facilitated investigation into the mechanisms of glandular morphogenesis, structural maintenance, tumor progression, and invasion. Opportunities remain to enhance cellular and structural complexity of mammary organoid models, including incorporating additional cell types and hormone signaling.

Published
2020

7. MULTI-seq: sample multiplexing for single-cell RNA sequencing using lipid-tagged indices

Author

McGinnis, Christopher S, Patterson, David M, Winkler, Juliane, Conrad, Daniel N, Hein, Marco Y, Srivastava, Vasudha, Hu, Jennifer L, Murrow, Lyndsay M, Weissman, Jonathan S, Werb, Zena, Chow, Eric D, and Gartner, Zev J

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Genetics, Breast Cancer, Women's Health, Human Genome, Cancer Genomics, Cancer, Biotechnology, 1.1 Normal biological development and functioning, Underpinning research, Animals, Base Sequence, HEK293 Cells, High-Throughput Nucleotide Sequencing, Humans, Lipids, Sequence Analysis, RNA, Single-Cell Analysis, Technology, Medical and Health Sciences, Developmental Biology, Biological sciences
Abstract

Sample multiplexing facilitates scRNA-seq by reducing costs and identifying artifacts such as cell doublets. However, universal and scalable sample barcoding strategies have not been described. We therefore developed MULTI-seq: multiplexing using lipid-tagged indices for single-cell and single-nucleus RNA sequencing. MULTI-seq reagents can barcode any cell type or nucleus from any species with an accessible plasma membrane. The method involves minimal sample processing, thereby preserving cell viability and endogenous gene expression patterns. When cells are classified into sample groups using MULTI-seq barcode abundances, data quality is improved through doublet identification and recovery of cells with low RNA content that would otherwise be discarded by standard quality-control workflows. We use MULTI-seq to track the dynamics of T-cell activation, perform a 96-plex perturbation experiment with primary human mammary epithelial cells and multiplex cryopreserved tumors and metastatic sites isolated from a patient-derived xenograft mouse model of triple-negative breast cancer.

Published
2019

8. Characterizing cellular mechanical phenotypes with mechano-node-pore sensing.

Author

Kim, Junghyun, Han, Sewoon, Lei, Andy, Miyano, Masaru, Bloom, Jessica, Srivastava, Vasudha, Stampfer, Martha M, Gartner, Zev J, LaBarge, Mark A, and Sohn, Lydia L

Subjects
Biosensors, Label-free, Mechanical phenotyping, Microfluidics, Node-Pore Sensing, Stem Cell Research, Stem Cell Research - Nonembryonic - Human, Bioengineering, 2.1 Biological and endogenous factors, Aetiology, microfluidics, mechanical phenotyping, node-pore sensing, biosensors, label-free
Abstract

The mechanical properties of cells change with their differentiation, chronological age, and malignant progression. Consequently, these properties may be useful label-free biomarkers of various functional or clinically relevant cell states. Here, we demonstrate mechano-node-pore sensing (mechano-NPS), a multi-parametric single-cell-analysis method that utilizes a four-terminal measurement of the current across a microfluidic channel to quantify simultaneously cell diameter, resistance to compressive deformation, transverse deformation under constant strain, and recovery time after deformation. We define a new parameter, the whole-cell deformability index (wCDI), which provides a quantitative mechanical metric of the resistance to compressive deformation that can be used to discriminate among different cell types. The wCDI and the transverse deformation under constant strain show malignant MCF-7 and A549 cell lines are mechanically distinct from non-malignant, MCF-10A and BEAS-2B cell lines, and distinguishes between cells treated or untreated with cytoskeleton-perturbing small molecules. We categorize cell recovery time, ΔTr, as instantaneous (ΔTr ~ 0 ms), transient (ΔTr ≤ 40ms), or prolonged (ΔTr > 40ms), and show that the composition of recovery types, which is a consequence of changes in cytoskeletal organization, correlates with cellular transformation. Through the wCDI and cell-recovery time, mechano-NPS discriminates between sub-lineages of normal primary human mammary epithelial cells with accuracy comparable to flow cytometry, but without antibody labeling. Mechano-NPS identifies mechanical phenotypes that distinguishes lineage, chronological age, and stage of malignant progression in human epithelial cells.

Published
2018

9. MAGIC matrices: freeform bioprinting materials to support complex and reproducible organoid morphogenesis

Author

Graham, Austin J., primary, Khoo, Michelle W.L., additional, Srivastava, Vasudha, additional, Viragova, Sara, additional, Parekh, Kavita, additional, Morley, Cameron D., additional, Bird, Malia, additional, Lebel, Paul, additional, Kumar, Sanjay, additional, Klein, Ophir, additional, Gómez-Sjöberg, Rafael, additional, and Gartner, Zev J., additional

Published
2024
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10. Mechanoaccumulative Elements of the Mammalian Actin Cytoskeleton.

Author

Schiffhauer, Eric, Luo, Tianzhi, Mohan, Krithika, Srivastava, Vasudha, Qian, Xuyu, Griffis, Eric, Iglesias, Pablo, and Robinson, Douglas

Subjects
Actin Cytoskeleton, Actinin, Animals, Filamins, HEK293 Cells, HeLa Cells, Humans, Mice, Myosin Type II, NIH 3T3 Cells
Abstract

To change shape, divide, form junctions, and migrate, cells reorganize their cytoskeletons in response to changing mechanical environments [1-4]. Actin cytoskeletal elements, including myosin II motors and actin crosslinkers, structurally remodel and activate signaling pathways in response to imposed stresses [5-9]. Recent studies demonstrate the importance of force-dependent structural rearrangement of α-catenin in adherens junctions [10] and vinculins molecular clutch mechanism in focal adhesions [11]. However, the complete landscape of cytoskeletal mechanoresponsive proteins and the mechanisms by which these elements sense and respond to force remain to be elucidated. To find mechanosensitive elements in mammalian cells, we examined protein relocalization in response to controlled external stresses applied to individual cells. Here, we show that non-muscle myosin II, α-actinin, and filamin accumulate to mechanically stressed regions in cells from diverse lineages. Using reaction-diffusion models for force-sensitive binding, we successfully predicted which mammalian α-actinin and filamin paralogs would be mechanoaccumulative. Furthermore, a Goldilocks zone must exist for each protein where the actin-binding affinity must be optimal for accumulation. In addition, we leveraged genetic mutants to gain a molecular understanding of the mechanisms of α-actinin and filamin catch-bonding behavior. Two distinct modes of mechanoaccumulation can be observed: a fast, diffusion-based accumulation and a slower, myosin II-dependent cortical flow phase that acts on proteins with specific binding lifetimes. Finally, we uncovered cell-type- and cell-cycle-stage-specific control of the mechanosensation of myosin IIB, but not myosin IIA or IIC. Overall, these mechanoaccumulative mechanisms drive the cells response to physical perturbation during proper tissue development and disease.

Published
2016

11. Cell Blebbing in Confined Microfluidic Environments.

Author

Ibo, Markela, Srivastava, Vasudha, Robinson, Douglas, and Gagnon, Zachary

Subjects
Actin Cytoskeleton, Biological Phenomena, Cell Movement, Cyclic AMP, Dictyostelium, Microfluidics, Osmolar Concentration, Physiological Phenomena, Pseudopodia
Abstract

Migrating cells can extend their leading edge by forming myosin-driven blebs and F-actin-driven pseudopods. When coerced to migrate in resistive environments, Dictyostelium cells switch from using predominately pseudopods to blebs. Bleb formation has been shown to be chemotactic and can be influenced by the direction of the chemotactic gradient. In this study, we determine the blebbing responses of developed cells of Dictyostelium discoideum to cAMP gradients of varying steepness produced in microfluidic channels with different confining heights, ranging between 1.7 μm and 3.8 μm. We show that microfluidic confinement height, gradient steepness, buffer osmolarity and Myosin II activity are important factors in determining whether cells migrate with blebs or with pseudopods. Dictyostelium cells were observed migrating within the confines of microfluidic gradient channels. When the cAMP gradient steepness is increased from 0.7 nM/μm to 20 nM/μm, cells switch from moving with a mixture of blebs and pseudopods to moving only using blebs when chemotaxing in channels with confinement heights less than 2.4 μm. Furthermore, the size of the blebs increases with gradient steepness and correlates with increases in myosin-II localization at the cell cortex. Reduction of intracellular pressure by high osmolarity buffer or inhibition of myosin-II by blebbistatin leads to a decrease in bleb formation and bleb size. Together, our data reveal that the protrusion type formed by migrating cells can be influenced by the channel height and the steepness of the cAMP gradient, and suggests that a combination of confinement-induced myosin-II localization and cAMP-regulated cortical contraction leads to increased intracellular fluid pressure and bleb formation.

Published
2016

14. Patterning and folding of intestinal villi by active mesenchymal dewetting

Author

Huycke, Tyler R., primary, Miyazaki, Hikaru, additional, Häkkinen, Teemu J., additional, Srivastava, Vasudha, additional, Barruet, Emilie, additional, McGinnis, Christopher S., additional, Kalantari, Ali, additional, Cornwall-Scoones, Jake, additional, Vaka, Dedeepya, additional, Zhu, Qin, additional, Jo, Hyunil, additional, DeGrado, William F., additional, Thomson, Matt, additional, Garikipati, Krishna, additional, Boffelli, Dario, additional, Klein, Ophir D., additional, and Gartner, Zev J., additional

Published
2023
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15. A Summer Academic Research Experience for Disadvantaged Youth

Author

Kabacoff, Cathryn, Srivastava, Vasudha, and Robinson, Douglas N.

Abstract

Internships are an effective way of connecting high school students in a meaningful manner to the sciences. Disadvantaged minorities have fewer opportunities to participate in internships, and are underrepresented in both science, technology, engineering, and mathematics majors and careers. We have developed a Summer Academic Research Experience (SARE) program that provides an enriching academic internship to underrepresented youth. Our program has shown that to have a successful internship for these disadvantaged youth, several issues need to be addressed in addition to scientific mentoring. We have found that it is necessary to remediate and/or fortify basic academic skills for students to be successful. In addition, students need to be actively coached in the development of professional skills, habits, and attitudes necessary for success in the workplace. With all these factors in place, these youths can become better students, compete on a more level playing field in their internships, and increase their potential of participating actively in the sciences in the future.

Published
2013
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23. Cigarette smoke disrupts monolayer integrity by altering epithelial cell-cell adhesion and cortical tension

Author

Nishida, Kristine, primary, Brune, Kieran A., additional, Putcha, Nirupama, additional, Mandke, Pooja, additional, O’Neal, Wanda K., additional, Shade, Danny, additional, Srivastava, Vasudha, additional, Wang, Menghan, additional, Lam, Hong, additional, An, Steven S., additional, Drummond, M. Bradley, additional, Hansel, Nadia N., additional, Robinson, Douglas N., additional, and Sidhaye, Venkataramana K., additional

Published
2017
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25. Contractility kits promote assembly of the mechanoresponsive cytoskeletal network.

Author

Kothari, Priyanka, Srivastava, Vasudha, Aggarwal, Vasudha, Tchernyshyov, Irina, Van Eyk, Jennifer E., Ha, Taekjip, and Robinson, Douglas N.

Subjects
*CONTRACTILITY (Biology), *CYTOSKELETAL proteins, *RNA-binding proteins
Abstract

Cellular contractility is governed by a control system of proteins that integrates internal and external cues to drive diverse shape change processes. This contractility controller includes myosin II motors, actin crosslinkers and protein scaffolds, which exhibit robust and cooperative mechanoaccumulation. However, the biochemical interactions and feedback mechanisms that drive the controller remain unknown. Here, we use a proteomics approach to identify direct interactors of two key nodes of the contractility controller in the social amoeba Dictyostelium discoideum: the actin crosslinker cortexillin I and the scaffolding protein IQGAP2. We highlight several unexpected proteins that suggest feedback from metabolic and RNA-binding proteins on the contractility controller. Quantitative in vivo biochemicalmeasurements reveal direct interactions between myosin II and cortexillin I, which form the core mechanosensor. Furthermore, IQGAP1 negatively regulates mechanoresponsiveness by competing with IQGAP2 for binding the myosin II–cortexillin I complex. These myosin II–cortexillin I–IQGAP2 complexes are pre-assembled into higher-order mechanoresponsive contractility kits (MCKs) that are poised to integrate into the cortex upon diffusional encounter coincident with mechanical inputs. [ABSTRACT FROM AUTHOR]

Published
2019
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42. Mimicking the mechanical properties of the cell cortex by the self-assembly of an actin cortex in vesicles.

Author

Tianzhi Luo, Srivastava, Vasudha, Yixin Ren, and Robinson, Douglas N.

Subjects
*CYTOSKELETON, *CELL membranes, *ARTIFICIAL cells, *MICROSTRUCTURE, *DISTRIBUTION (Probability theory)
Abstract

The composite of the actin cytoskeleton and plasma membrane plays important roles in many biological events. Here, we employed the emulsion method to synthesize artificial cells with biomimetic actin cortex in vesicles and characterized their mechanical properties. We demonstrated that the emulsion method provides the flexibility to adjust the lipid composition and protein concentrations in artificial cells to achieve the desired size distribution, internal microstructure, and mechanical properties. Moreover, comparison of the cortical elasticity measured for reconstituted artificial cells to that of real cells, including those manipulated using genetic depletion and pharmacological inhibition, strongly supports that actin cytoskeletal proteins are dominant over lipid molecules in cortical mechanics. Our study indicates that the assembly of biological systems in artificial cells with purified cellular components provides a powerful way to answer biological questions. [ABSTRACT FROM AUTHOR]

Published
2014
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43. MAGIC matrices: freeform bioprinting materials to support complex and reproducible organoid morphogenesis.

Author

Graham AJ, Khoo MWL, Srivastava V, Viragova S, Kim H, Parekh K, Hennick KM, Bird M, Goldhammer N, Yu JZ, Morley CD, Lebel P, Kumar S, Rosenbluth JM, Nowakowski TJ, Klein O, Gómez-Sjöberg R, and Gartner ZJ

Abstract

Organoids are powerful models of tissue physiology, yet their applications remain limited due to their relatively simple morphology and high organoid-to-organoid structural variability. To address these limitations we developed a soft, composite yield-stress extracellular matrix that supports optimal organoid morphogenesis following freeform 3D bioprinting of cell slurries at tissue-like densities. The material is designed with two temperature regimes: at 4 °C it exhibits reversible yield-stress behavior to support long printing times without compromising cell viability. When transferred to cell culture at 37 °C, the material cross-links and exhibits similar viscoelasticity and plasticity to basement membrane extracts such as Matrigel. We first characterize the rheological properties of MAGIC matrices that optimize organoid morphogenesis, including low stiffness and high stress relaxation. Next, we combine this material with a custom piezoelectric printhead that allows more reproducible and robust self-organization from uniform and spatially organized tissue "seeds." We apply MAGIC matrix bioprinting for high-throughput generation of intestinal, mammary, vascular, salivary gland, and brain organoid arrays that are structurally similar to those grown in pure Matrigel, but exhibit dramatically improved homogeneity in organoid size, shape, maturation time, and efficiency of morphogenesis. The flexibility of this method and material enabled fabrication of fully 3D microphysiological systems, including perfusable organoid tubes that experience cyclic 3D strain in response to pressurization. Furthermore, the reproducibility of organoid structure increased the statistical power of a drug response assay by up to 8 orders-of-magnitude for a given number of comparisons. Combined, these advances lay the foundation for the efficient fabrication of complex tissue morphologies by canalizing their self-organization in both space and time., Competing Interests: Declaration of Interest A.J.G., R.G.S., and Z.J.G. are co-inventors on a patent regarding the design and application of the embedded bioprinting material and piezoelectric printhead (U.S. Provisional Patent Application No. 63/605,710). Z.J.G. is an equity holder in Scribe biosciences, Provenance Bio, and Serotiny.

Published
2024
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44. Patterning and folding of intestinal villi by active mesenchymal dewetting.

Author

Huycke TR, Miyazaki H, Häkkinen TJ, Srivastava V, Barruet E, McGinnis CS, Kalantari A, Cornwall-Scoones J, Vaka D, Zhu Q, Jo H, DeGrado WF, Thomson M, Garikipati K, Boffelli D, Klein OD, and Gartner ZJ

Abstract

Tissue folding generates structural motifs critical to organ function. In the intestine, bending of a flat epithelium into a periodic pattern of folds gives rise to villi, the numerous finger-like protrusions that are essential for nutrient absorption. However, the molecular and mechanical mechanisms driving the initiation and morphogenesis of villi remain a matter of debate. Here, we identify an active mechanical mechanism that simultaneously patterns and folds intestinal villi. We find that PDGFRA+ subepithelial mesenchymal cells generate myosin II-dependent forces sufficient to produce patterned curvature in neighboring tissue interfaces. At the cell-level, this occurs through a process dependent upon matrix metalloproteinase-mediated tissue fluidization and altered cell-ECM adhesion. By combining computational models with in vivo experiments, we reveal these cellular features manifest at the tissue-level as differences in interfacial tensions that promote mesenchymal aggregation and interface bending through a process analogous to the active de-wetting of a thin liquid film., Competing Interests: DECLARATION OF INTERESTS ZJG and CSM hold patents related to the MULTI-seq barcoding method. ZJG is an equity holder in Scribe biosciences, Provenance Bio, and Serotiny.

Published
2023
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45. Configurational entropy is an intrinsic driver of tissue structural heterogeneity.

Author

Srivastava V, Hu JL, Garbe JC, Veytsman B, Shalabi SF, Yllanes D, Thomson M, LaBarge MA, Huber G, and Gartner ZJ

Abstract

Tissues comprise ordered arrangements of cells that can be surprisingly disordered in their details. How the properties of single cells and their microenvironment contribute to the balance between order and disorder at the tissue-scale remains poorly understood. Here, we address this question using the self-organization of human mammary organoids as a model. We find that organoids behave like a dynamic structural ensemble at the steady state. We apply a maximum entropy formalism to derive the ensemble distribution from three measurable parameters - the degeneracy of structural states, interfacial energy, and tissue activity (the energy associated with positional fluctuations). We link these parameters with the molecular and microenvironmental factors that control them to precisely engineer the ensemble across multiple conditions. Our analysis reveals that the entropy associated with structural degeneracy sets a theoretical limit to tissue order and provides new insight for tissue engineering, development, and our understanding of disease progression., Competing Interests: DECLARATION OF INTERESTS Z.J.G. is an equity holder in Scribe biosciences, Provenance Bio, and Serotiny.

Published
2023
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46. Cigarette smoke disrupts monolayer integrity by altering epithelial cell-cell adhesion and cortical tension.

Author

Nishida K, Brune KA, Putcha N, Mandke P, O'Neal WK, Shade D, Srivastava V, Wang M, Lam H, An SS, Drummond MB, Hansel NN, Robinson DN, and Sidhaye VK

Subjects
Adherens Junctions metabolism, Aged, Biomechanical Phenomena, Cadherins metabolism, Cell Adhesion, Cell Death, Cell Membrane Permeability, Cytoskeleton metabolism, Female, Humans, Male, Middle Aged, Myosin Type II metabolism, Pulmonary Disease, Chronic Obstructive blood, Pulmonary Disease, Chronic Obstructive pathology, Epithelial Cells pathology, Smoking
Abstract

Chronic obstructive pulmonary disease (COPD) is a major cause of morbidity and mortality. Cigarette smoke (CS) drives disease development and progression. The epithelial barrier is damaged by CS with increased monolayer permeability. However, the molecular changes that cause this barrier disruption and the interaction between adhesion proteins and the cytoskeleton are not well defined. We hypothesized that CS alters monolayer integrity by increasing cell contractility and decreasing cell adhesion in epithelia. Normal human airway epithelial cells and primary COPD epithelial cells were exposed to air or CS, and changes measured in protein levels. We measured the cortical tension of individual cells and the stiffness of cells in a monolayer. We confirmed that the changes in acute and subacute in vitro smoke exposure reflect protein changes seen in cell monolayers and tissue sections from COPD patients. Epithelial cells exposed to repetitive CS and those derived from COPD patients have increased monolayer permeability. E-cadherin and β-catenin were reduced in smoke exposed cells as well as in lung tissue sections from patients with COPD. Moreover, repetitive CS caused increased tension in individual cells and cells in a monolayer, which corresponded with increased polymerized actin without changes in myosin IIA and IIB total abundance. Repetitive CS exposure impacts the adhesive intercellular junctions and the tension of epithelial cells by increased actin polymer levels, to further destabilize cell adhesion. Similar changes are seen in epithelial cells from COPD patients indicating that these findings likely contribute to COPD pathology., (Copyright © 2017 the American Physiological Society.)

Published
2017
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