Your search keyword '"Hannezo E"' showing total 76 results

1. Theory of mechano-chemical patterning in biphasic biological tissues

Author

Recho, P., Hallou, A., and Hannezo, E.

Subjects

Physics - Biological Physics, Quantitative Biology - Cell Behavior, Quantitative Biology - Tissues and Organs

Abstract

The formation of self-organized patterns is key to the morphogenesis of multicellular organisms, although a comprehensive theory of biological pattern formation is still lacking. Here, we propose a minimal model combining tissue mechanics to morphogen turnover and transport in order to explore new routes to patterning. Our active description couples morphogen reaction-diffusion, which impact on cell differentiation and tissue mechanics, to a two-phase poroelastic rheology, where one tissue phase consists of a poroelastic cell network and the other of a permeating extracellular fluid, which provides a feedback by actively transporting morphogens. While this model encompasses previous theories approximating tissues to inert monophasic media, such as Turing's reaction-diffusion model, it overcomes some of their key limitations permitting pattern formation via any two-species biochemical kinetics thanks to mechanically induced cross-diffusion flows. Moreover, we describe a qualitatively different advection-driven Keller-Segel instability which allows for the formation of patterns with a single morphogen, and whose fundamental mode pattern robustly scales with tissue size. We discuss the potential relevance of these findings for tissue morphogenesis.

Published

2018

2. Spatiotemporal dynamics of self-organized branching in pancreas-derived organoids

Author

Randriamanantsoa, S., Papargyriou, A., Maurer, H. C., Peschke, K., Schuster, M., Zecchin, G., Steiger, K., Öllinger, R., Saur, D., Scheel, C., Rad, R., Hannezo, E., Reichert, M., and Bausch, A. R.

Published

2022

3. Curvature in biological systems: its quantification, emergence and implications across the scales

Author

Schamberger, B., Roschger, A., Ziege, R., Anselme, K., Amar, M.B., Bykowski, M., Castro, A.P.G., Cipitria, A., Coles, R., Dimova, R., Eder, M., Ehrig, S., Escudero, L.M., Evans, M.E., Fernandes, P.R., Fratzl, P., Geris, L., Gierlinger, N., Hannezo, E., Iglič, A., Kirkensgaard, J.J.K., Kollmannsberger, P., Kowalewska, Ł., Kurniawan, N.A., Papantoniou, I., Pieuchot, L., Pires, T.H.V., Renner, L., Sageman-Furnas, A., Schröder-Turk, G.E., Sengupta, A., Sharma, V.R., Tagua, A., Tomba, C., Trepat, X., Waters, S.L., Yeo, E., Bidan, C.M., and Dunlop, J.W.C.

Subjects

Cardiovascular and Metabolic Diseases

Abstract

Surface curvature both emerges from, and influences the behavior of, living objects at length scales ranging from cell membranes to single cells to tissues and organs. The relevance of surface curvature in biology has been supported by numerous recent experimental and theoretical investigations in recent years. In this review, we first give a brief introduction to the key ideas of surface curvature in the context of biological systems and discuss the challenges that arise when measuring surface curvature. Giving an overview of the emergence of curvature in biological systems, its significance at different length scales becomes apparent. On the other hand, summarizing current findings also shows that both single cells and entire cell sheets, tissues or organisms respond to curvature by modulating their shape and their migration behavior. Finally, we address the interplay between the distribution of morphogens or micro-organisms and the emergence of curvature across length scales with examples demonstrating these key mechanistic principles of morphogenesis. Overall, this review highlights that curved interfaces are not merely a passive by-product of the chemical, biological and mechanical processes but that curvature acts also as a signal that co-determines these processes. This article is protected by copyright. All rights reserved.

Published

2023

4. A Unifying Theory of Branching Morphogenesis

Author

Simons, BD, Hannezo, E, Simons, Benjamin [0000-0002-3875-7071], and Apollo - University of Cambridge Repository

Subjects

mammary gland, kidney, prostate, self-organisation, branching morphogenesis, mathematical modelling, branching and annihilating random walks, out-of-equilibrium processes

Abstract

The morphogenesis of branched organs remains a subject of abiding interest. Although much is known about the underlying signaling pathways, it remains unclear how macroscopic features of branched organs, including their size, network topology and spatial patterning, are encoded. Here we show that, in mouse mammary gland, kidney and human prostate, these features can be explained quantitatively within a single unifying framework of branching and annihilating random walks. Based on quantitative analyses of large-scale organ reconstructions and proliferation kinetics measurements, we propose that morphogenesis follows from the proliferative activity of equipotent tips that stochastically branch and randomly explore their environment, but compete neutrally for space, becoming proliferatively inactive when in proximity with neighboring ducts. These results show that complex branched epithelial structures in mammalian tissues develop as a self-organized process, reliant upon a strikingly simple, but generic, rule, without recourse to a rigid and deterministic sequence of genetically programmed events.

Published

2017

5. Multipotent Basal Stem Cells, Maintained in Localized Proximal Niches, Support Directed Long-Ranging Epithelial Flows in Human Prostates

Author

Moad, M, Hannezo, E, Buczacki, S, Wilson, L, El-Sherif, A, Sims, D, Pickard, R, Wright, N, Williamson, S, Turnbull, D, Taylor, R, Greaves, L, Robson, C, Simons, B, Heer, R, Buczacki, Simon [0000-0002-2975-416X], Simons, Benjamin [0000-0002-3875-7071], and Apollo - University of Cambridge Repository

Subjects

Male, Notch, education, Primary Cell Culture, Gene Expression, Laser Capture Microdissection, DNA, Mitochondrial, Article, Spheroids, Cellular, basal, Humans, Cell Lineage, Stem Cell Niche, lcsh:QH301-705.5, health care economics and organizations, organoids, luminal, prostate, Manchester Cancer Research Centre, ResearchInstitutes_Networks_Beacons/mcrc, Multipotent Stem Cells, DLK1, Calcium-Binding Proteins, Membrane Proteins, Cell Differentiation, Epithelial Cells, prostate cancer, branch, stem cell, niche, lcsh:Biology (General), Intercellular Signaling Peptides and Proteins, RNA, epithelium, Biomarkers

Abstract

Summary Sporadic mitochondrial DNA mutations serve as clonal marks providing access to the identity and lineage potential of stem cells within human tissues. By combining quantitative clonal mapping with 3D reconstruction of adult human prostates, we show that multipotent basal stem cells, confined to discrete niches in juxta-urethral ducts, generate bipotent basal progenitors in directed epithelial migration streams. Basal progenitors are then dispersed throughout the entire glandular network, dividing and differentiating to replenish the loss of apoptotic luminal cells. Rare lineage-restricted luminal stem cells, and their progeny, are confined to proximal ducts and provide only minor contribution to epithelial homeostasis. In situ cell capture from clonal maps identified delta homolog 1 (DLK1) enrichment of basal stem cells, which was validated in functional spheroid assays. This study establishes significant insights into niche organization and function of prostate stem and progenitor cells, with implications for disease., Graphical Abstract, Highlights • Discrete, proximal stem cell niche domains in juxta-urethral ducts • Basal stem cells generate large-scale, directed, and cohesive cell migration streams • Bipotent basal progenitors maintain the luminal compartment • DLK1 marks stem cells in situ that recapitulate gland histology in 3D culture, Moad et al. find that multipotent prostate basal stem cells, marked by delta homolog 1 (DLK1), reside in proximal ducts and generate directed large-scale epithelial flows traversing the entire length of the branching gland network. This work describes mechanisms underlying 3D epithelial homeostasis in a complex branching tissue.

Published

2016

6. Growth, homeostatic regulation and stem cell dynamics in tissues

Author

Hannezo, E., primary, Prost, J., additional, and Joanny, J.-F., additional

Published

2014

7. Instabilities of Monolayered Epithelia: Shape and Structure of Villi and Crypts

Author

Hannezo, E., primary, Prost, J., additional, and Joanny, J.-F., additional

Published

2011

8. Chronique

Author

Hannezo, E.

Published

1898

9. Identity and dynamics of mammary stem cells during branching morphogenesis

Author

Scheele, CLGJ, Hannezo, E, Muraro, MJ, Zomer, A, Langedijk, NSM, Van Oudenaarden, A, Simons, BD, and Van Rheenen, J

Subjects

Models, Molecular, Stochastic Processes, Gene Expression Profiling, Stem Cells, 3. Good health, Mice, Mammary Glands, Animal, Morphogenesis, Animals, Cell Lineage, Female, Sexual Maturation, Single-Cell Analysis, Cell Proliferation

Abstract

During puberty, the mouse mammary gland develops into a highly branched epithelial network. Owing to the absence of exclusive stem cell markers, the location, multiplicity, dynamics and fate of mammary stem cells (MaSCs), which drive branching morphogenesis, are unknown. Here we show that morphogenesis is driven by proliferative terminal end buds that terminate or bifurcate with near equal probability, in a stochastic and time-invariant manner, leading to a heterogeneous epithelial network. We show that the majority of terminal end bud cells function as highly proliferative, lineage-committed MaSCs that are heterogeneous in their expression profile and short-term contribution to ductal extension. Yet, through cell rearrangements during terminal end bud bifurcation, each MaSC is able to contribute actively to long-term growth. Our study shows that the behaviour of MaSCs is not directly linked to a single expression profile. Instead, morphogenesis relies upon lineage-restricted heterogeneous MaSC populations that function as single equipotent pools in the long term.

10. Self-organized pattern formation in the developing mouse neural tube by a temporal relay of BMP signaling.

Author

Lehr S, Brückner DB, Minchington TG, Greunz-Schindler M, Merrin J, Hannezo E, and Kicheva A

Abstract

Developing tissues interpret dynamic changes in morphogen activity to generate cell type diversity. To quantitatively study bone morphogenetic protein (BMP) signaling dynamics in the mouse neural tube, we developed an embryonic stem cell differentiation system tailored for growing tissues. Differentiating cells form striking self-organized patterns of dorsal neural tube cell types driven by sequential phases of BMP signaling that are observed both in vitro and in vivo. Data-driven biophysical modeling showed that these dynamics result from coupling fast negative feedback with slow positive regulation of signaling by the specification of an endogenous BMP source. Thus, in contrast to relays that propagate morphogen signaling in space, we identify a BMP signaling relay that operates in time. This mechanism allows for a rapid initial concentration-sensitive response that is robustly terminated, thereby regulating balanced sequential cell type generation. Our study provides an experimental and theoretical framework to understand how signaling dynamics are exploited in developing tissues., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

11. Temporal variability and cell mechanics control robustness in mammalian embryogenesis.

Author

Fabrèges D, Corominas-Murtra B, Moghe P, Kickuth A, Ichikawa T, Iwatani C, Tsukiyama T, Daniel N, Gering J, Stokkermans A, Wolny A, Kreshuk A, Duranthon V, Uhlmann V, Hannezo E, and Hiiragi T

Subjects

Animals, Mice, Rabbits, Actomyosin metabolism, Blastocyst physiology, Blastocyst cytology, Cell Division, Stochastic Processes, Blastomeres cytology, Blastomeres physiology, Embryo, Mammalian cytology, Embryo, Mammalian physiology, Embryonic Development

Abstract

How living systems achieve precision in form and function despite their intrinsic stochasticity is a fundamental yet ongoing question in biology. We generated morphomaps of preimplantation embryogenesis in mouse, rabbit, and monkey embryos, and these morphomaps revealed that although blastomere divisions desynchronized passively, 8-cell embryos converged toward robust three-dimensional shapes. Using topological analysis and genetic perturbations, we found that embryos progressively changed their cellular connectivity to a preferred topology, which could be predicted by a physical model in which actomyosin contractility and noise facilitate topological transitions, lowering surface energy. This mechanism favored regular embryo packing and promoted a higher number of inner cells in the 16-cell embryo. Synchronized division reduced embryo packing and generated substantially more misallocated cells and fewer inner-cell-mass cells. These findings suggest that stochasticity in division timing contributes to robust patterning.

Published

2024

12. Tissue Active Matter: Integrating Mechanics and Signaling into Dynamical Models.

Author

Brückner DB and Hannezo E

Abstract

The importance of physical forces in the morphogenesis, homeostatic function, and pathological dysfunction of multicellular tissues is being increasingly characterized, both theoretically and experimentally. Analogies between biological systems and inert materials such as foams, gels, and liquid crystals have provided striking insights into the core design principles underlying multicellular organization. However, these connections can seem surprising given that a key feature of multicellular systems is their ability to constantly consume energy, providing an active origin for the forces that they produce. Key emerging questions are, therefore, to understand whether and how this activity grants tissues novel properties that do not have counterparts in classical materials, as well as their consequences for biological function. Here, we review recent discoveries at the intersection of active matter and tissue biology, with an emphasis on how modeling and experiments can be combined to understand the dynamics of multicellular systems. These approaches suggest that a number of key biological tissue-scale phenomena, such as morphogenetic shape changes, collective migration, or fate decisions, share unifying design principles that can be described by physical models of tissue active matter., (Copyright © 2024 Cold Spring Harbor Laboratory Press; all rights reserved.)

Published

2024

13. Modelling the dynamics of mammalian gut homeostasis.

Author

Corominas-Murtra B and Hannezo E

Subjects

Animals, Intestinal Mucosa, Homeostasis, Mammals, Stem Cells metabolism, Signal Transduction

Abstract

Homeostatic balance in the intestinal epithelium relies on a fast cellular turnover, which is coordinated by an intricate interplay between biochemical signalling, mechanical forces and organ geometry. We review recent modelling approaches that have been developed to understand different facets of this remarkable homeostatic equilibrium. Existing models offer different, albeit complementary, perspectives on the problem. First, biomechanical models aim to explain the local and global mechanical stresses driving cell renewal as well as tissue shape maintenance. Second, compartmental models provide insights into the conditions necessary to keep a constant flow of cells with well-defined ratios of cell types, and how perturbations can lead to an unbalance of relative compartment sizes. A third family of models address, at the cellular level, the nature and regulation of stem fate choices that are necessary to fuel cellular turnover. We also review how these different approaches are starting to be integrated together across scales, to provide quantitative predictions and new conceptual frameworks to think about the dynamics of cell renewal in complex tissues., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

14. Lineage tracing identifies heterogeneous hepatoblast contribution to cell lineages and postembryonic organ growth dynamics.

Author

Unterweger IA, Klepstad J, Hannezo E, Lundegaard PR, Trusina A, and Ober EA

Subjects

Animals, Cell Lineage, Hepatocytes metabolism, Epithelial Cells, Cell Differentiation, Cell Proliferation, Zebrafish, Liver metabolism

Abstract

To meet the physiological demands of the body, organs need to establish a functional tissue architecture and adequate size as the embryo develops to adulthood. In the liver, uni- and bipotent progenitor differentiation into hepatocytes and biliary epithelial cells (BECs), and their relative proportions, comprise the functional architecture. Yet, the contribution of individual liver progenitors at the organ level to both fates, and their specific proportion, is unresolved. Combining mathematical modelling with organ-wide, multispectral FRaeppli-NLS lineage tracing in zebrafish, we demonstrate that a precise BEC-to-hepatocyte ratio is established (i) fast, (ii) solely by heterogeneous lineage decisions from uni- and bipotent progenitors, and (iii) independent of subsequent cell type-specific proliferation. Extending lineage tracing to adulthood determined that embryonic cells undergo spatially heterogeneous three-dimensional growth associated with distinct environments. Strikingly, giant clusters comprising almost half a ventral lobe suggest lobe-specific dominant-like growth behaviours. We show substantial hepatocyte polyploidy in juveniles representing another hallmark of postembryonic liver growth. Our findings uncover heterogeneous progenitor contributions to tissue architecture-defining cell type proportions and postembryonic organ growth as key mechanisms forming the adult liver., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Unterweger et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

15. Self-organized and directed branching results in optimal coverage in developing dermal lymphatic networks.

Author

Uçar MC, Hannezo E, Tiilikainen E, Liaqat I, Jakobsson E, Nurmi H, and Vaahtomeri K

Subjects

Animals, Mice, Humans, Biophysics, Disease Models, Animal, Extracellular Fluid, Ear Auricle, Lymphatic Vessels

Abstract

Branching morphogenesis is a ubiquitous process that gives rise to high exchange surfaces in the vasculature and epithelial organs. Lymphatic capillaries form branched networks, which play a key role in the circulation of tissue fluid and immune cells. Although mouse models and correlative patient data indicate that the lymphatic capillary density directly correlates with functional output, i.e., tissue fluid drainage and trafficking efficiency of dendritic cells, the mechanisms ensuring efficient tissue coverage remain poorly understood. Here, we use the mouse ear pinna lymphatic vessel network as a model system and combine lineage-tracing, genetic perturbations, whole-organ reconstructions and theoretical modeling to show that the dermal lymphatic capillaries tile space in an optimal, space-filling manner. This coverage is achieved by two complementary mechanisms: initial tissue invasion provides a non-optimal global scaffold via self-organized branching morphogenesis, while VEGF-C dependent side-branching from existing capillaries rapidly optimizes local coverage by directionally targeting low-density regions. With these two ingredients, we show that a minimal biophysical model can reproduce quantitatively whole-network reconstructions, across development and perturbations. Our results show that lymphatic capillary networks can exploit local self-organizing mechanisms to achieve tissue-scale optimization., (© 2023. Springer Nature Limited.)

Published

2023

16. CCR7 acts as both a sensor and a sink for CCL19 to coordinate collective leukocyte migration.

Author

Alanko J, Uçar MC, Canigova N, Stopp J, Schwarz J, Merrin J, Hannezo E, and Sixt M

Subjects

Receptors, CCR7, Ligands, Cell Movement, Leukocytes

Abstract

Immune responses rely on the rapid and coordinated migration of leukocytes. Whereas it is well established that single-cell migration is often guided by gradients of chemokines and other chemoattractants, it remains poorly understood how these gradients are generated, maintained, and modulated. By combining experimental data with theory on leukocyte chemotaxis guided by the G protein-coupled receptor (GPCR) CCR7, we demonstrate that in addition to its role as the sensory receptor that steers migration, CCR7 also acts as a generator and a modulator of chemotactic gradients. Upon exposure to the CCR7 ligand CCL19, dendritic cells (DCs) effectively internalize the receptor and ligand as part of the canonical GPCR desensitization response. We show that CCR7 internalization also acts as an effective sink for the chemoattractant, dynamically shaping the spatiotemporal distribution of the chemokine. This mechanism drives complex collective migration patterns, enabling DCs to create or sharpen chemotactic gradients. We further show that these self-generated gradients can sustain the long-range guidance of DCs, adapt collective migration patterns to the size and geometry of the environment, and provide a guidance cue for other comigrating cells. Such a dual role of CCR7 as a GPCR that both senses and consumes its ligand can thus provide a novel mode of cellular self-organization.

Published

2023

17. Curvature in Biological Systems: Its Quantification, Emergence, and Implications across the Scales.

Author

Schamberger B, Ziege R, Anselme K, Ben Amar M, Bykowski M, Castro APG, Cipitria A, Coles RA, Dimova R, Eder M, Ehrig S, Escudero LM, Evans ME, Fernandes PR, Fratzl P, Geris L, Gierlinger N, Hannezo E, Iglič A, Kirkensgaard JJK, Kollmannsberger P, Kowalewska Ł, Kurniawan NA, Papantoniou I, Pieuchot L, Pires THV, Renner LD, Sageman-Furnas AO, Schröder-Turk GE, Sengupta A, Sharma VR, Tagua A, Tomba C, Trepat X, Waters SL, Yeo EF, Roschger A, Bidan CM, and Dunlop JWC

Subjects

Cell Membrane, Morphogenesis, Mechanical Phenomena

Abstract

Surface curvature both emerges from, and influences the behavior of, living objects at length scales ranging from cell membranes to single cells to tissues and organs. The relevance of surface curvature in biology is supported by numerous experimental and theoretical investigations in recent years. In this review, first, a brief introduction to the key ideas of surface curvature in the context of biological systems is given and the challenges that arise when measuring surface curvature are discussed. Giving an overview of the emergence of curvature in biological systems, its significance at different length scales becomes apparent. On the other hand, summarizing current findings also shows that both single cells and entire cell sheets, tissues or organisms respond to curvature by modulating their shape and their migration behavior. Finally, the interplay between the distribution of morphogens or micro-organisms and the emergence of curvature across length scales is addressed with examples demonstrating these key mechanistic principles of morphogenesis. Overall, this review highlights that curved interfaces are not merely a passive by-product of the chemical, biological, and mechanical processes but that curvature acts also as a signal that co-determines these processes., (© 2023 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2023

18. Cell cycle dynamics control fluidity of the developing mouse neuroepithelium.

Author

Bocanegra-Moreno L, Singh A, Hannezo E, Zagorski M, and Kicheva A

Abstract

As developing tissues grow in size and undergo morphogenetic changes, their material properties may be altered. Such changes result from tension dynamics at cell contacts or cellular jamming. Yet, in many cases, the cellular mechanisms controlling the physical state of growing tissues are unclear. We found that at early developmental stages, the epithelium in the developing mouse spinal cord maintains both high junctional tension and high fluidity. This is achieved via a mechanism in which interkinetic nuclear movements generate cell area dynamics that drive extensive cell rearrangements. Over time, the cell proliferation rate declines, effectively solidifying the tissue. Thus, unlike well-studied jamming transitions, the solidification uncovered here resembles a glass transition that depends on the dynamical stresses generated by proliferation and differentiation. Our finding that the fluidity of developing epithelia is linked to interkinetic nuclear movements and the dynamics of growth is likely to be relevant to multiple developing tissues., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2023.)

Published

2023

19. A Guide Toward Multi-scale and Quantitative Branching Analysis in the Mammary Gland.

Author

Hannezo E and Scheele CLGJ

Subjects

Animals, Morphogenesis genetics, Cell Lineage, Mammary Glands, Animal, Epithelial Cells

Abstract

The mammary gland consists of a bilayered epithelial structure with an extensively branched morphology. The majority of this epithelial tree is laid down during puberty, during which actively proliferating terminal end buds repeatedly elongate and bifurcate to form the basic structure of the ductal tree. Mammary ducts consist of a basal and luminal cell layer with a multitude of identified sub-lineages within both layers. The understanding of how these different cell lineages are cooperatively driving branching morphogenesis is a problem of crossing multiple scales, as this requires information on the macroscopic branched structure of the gland, as well as data on single-cell dynamics driving the morphogenic program. Here we describe a method to combine genetic lineage tracing with whole-gland branching analysis. Quantitative data on the global organ structure can be used to derive a model for mammary gland branching morphogenesis and provide a backbone on which the dynamics of individual cell lineages can be simulated and compared to lineage-tracing approaches. Eventually, these quantitative models and experiments allow to understand the couplings between the macroscopic shape of the mammary gland and the underlying single-cell dynamics driving branching morphogenesis., (© 2023. The Authors.)

Published

2023

20. Chiral and nematic phases of flexible active filaments.

Author

Dunajova Z, Mateu BP, Radler P, Lim K, Brandis D, Velicky P, Danzl JG, Wong RW, Elgeti J, Hannezo E, and Loose M

Abstract

The emergence of large-scale order in self-organized systems relies on local interactions between individual components. During bacterial cell division, FtsZ-a prokaryotic homologue of the eukaryotic protein tubulin-polymerizes into treadmilling filaments that further organize into a cytoskeletal ring. In vitro, FtsZ filaments can form dynamic chiral assemblies. However, how the active and passive properties of individual filaments relate to these large-scale self-organized structures remains poorly understood. Here we connect single-filament properties with the mesoscopic scale by combining minimal active matter simulations and biochemical reconstitution experiments. We show that the density and flexibility of active chiral filaments define their global order. At intermediate densities, curved, flexible filaments organize into chiral rings and polar bands. An effectively nematic organization dominates for high densities and for straight, mutant filaments with increased rigidity. Our predicted phase diagram quantitatively captures these features, demonstrating how the flexibility, density and chirality of the active filaments affect their collective behaviour. Our findings shed light on the fundamental properties of active chiral matter and explain how treadmilling FtsZ filaments organize during bacterial cell division., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2023.)

Published

2023

21. A self-generated Toddler gradient guides mesodermal cell migration.

Author

Stock J, Kazmar T, Schlumm F, Hannezo E, and Pauli A

Abstract

The sculpting of germ layers during gastrulation relies on the coordinated migration of progenitor cells, yet the cues controlling these long-range directed movements remain largely unknown. While directional migration often relies on a chemokine gradient generated from a localized source, we find that zebrafish ventrolateral mesoderm is guided by a self-generated gradient of the initially uniformly expressed and secreted protein Toddler/ELABELA/Apela. We show that the Apelin receptor, which is specifically expressed in mesodermal cells, has a dual role during gastrulation, acting as a scavenger receptor to generate a Toddler gradient, and as a chemokine receptor to sense this guidance cue. Thus, we uncover a single receptor-based self-generated gradient as the enigmatic guidance cue that can robustly steer the directional migration of mesoderm through the complex and continuously changing environment of the gastrulating embryo.

Published

2022

22. Multitier mechanics control stromal adaptations in the swelling lymph node.

Author

Assen FP, Abe J, Hons M, Hauschild R, Shamipour S, Kaufmann WA, Costanzo T, Krens G, Brown M, Ludewig B, Hippenmeyer S, Heisenberg CP, Weninger W, Hannezo E, Luther SA, Stein JV, and Sixt M

Subjects

Animals, Fibroblasts, Lymphocytes, Mice, Mice, Inbred C57BL, Lymph Nodes, Stromal Cells

Abstract

Lymph nodes (LNs) comprise two main structural elements: fibroblastic reticular cells that form dedicated niches for immune cell interaction and capsular fibroblasts that build a shell around the organ. Immunological challenge causes LNs to increase more than tenfold in size within a few days. Here, we characterized the biomechanics of LN swelling on the cellular and organ scale. We identified lymphocyte trapping by influx and proliferation as drivers of an outward pressure force, causing fibroblastic reticular cells of the T-zone (TRCs) and their associated conduits to stretch. After an initial phase of relaxation, TRCs sensed the resulting strain through cell matrix adhesions, which coordinated local growth and remodeling of the stromal network. While the expanded TRC network readopted its typical configuration, a massive fibrotic reaction of the organ capsule set in and countered further organ expansion. Thus, different fibroblast populations mechanically control LN swelling in a multitier fashion., (© 2022. The Author(s).)

Published

2022

23. Retrograde movements determine effective stem cell numbers in the intestine.

Author

Azkanaz M, Corominas-Murtra B, Ellenbroek SIJ, Bruens L, Webb AT, Laskaris D, Oost KC, Lafirenze SJA, Annusver K, Messal HA, Iqbal S, Flanagan DJ, Huels DJ, Rojas-Rodríguez F, Vizoso M, Kasper M, Sansom OJ, Snippert HJ, Liberali P, Simons BD, Katajisto P, Hannezo E, and van Rheenen J

Subjects

Animals, Intestinal Mucosa cytology, Intestine, Small cytology, Mice, Receptors, G-Protein-Coupled, Wnt Proteins, Cell Count, Cell Movement, Intestines cytology, Stem Cells cytology

Abstract

The morphology and functionality of the epithelial lining differ along the intestinal tract, but tissue renewal at all sites is driven by stem cells at the base of crypts 1-3 . Whether stem cell numbers and behaviour vary at different sites is unknown. Here we show using intravital microscopy that, despite similarities in the number and distribution of proliferative cells with an Lgr5 signature in mice, small intestinal crypts contain twice as many effective stem cells as large intestinal crypts. We find that, although passively displaced by a conveyor-belt-like upward movement, small intestinal cells positioned away from the crypt base can function as long-term effective stem cells owing to Wnt-dependent retrograde cellular movement. By contrast, the near absence of retrograde movement in the large intestine restricts cell repositioning, leading to a reduction in effective stem cell number. Moreover, after suppression of the retrograde movement in the small intestine, the number of effective stem cells is reduced, and the rate of monoclonal conversion of crypts is accelerated. Together, these results show that the number of effective stem cells is determined by active retrograde movement, revealing a new channel of stem cell regulation that can be experimentally and pharmacologically manipulated., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

24. Rigidity transitions in development and disease.

Author

Hannezo E and Heisenberg CP

Subjects

Humans, Wound Healing, Embryonic Development, Physics

Abstract

Although rigidity and jamming transitions have been widely studied in physics and material science, their importance in a number of biological processes, including embryo development, tissue homeostasis, wound healing, and disease progression, has only begun to be recognized in the past few years. The hypothesis that biological systems can undergo rigidity/jamming transitions is attractive, as it would allow these systems to change their material properties rapidly and strongly. However, whether such transitions indeed occur in biological systems, how they are being regulated, and what their physiological relevance might be, is still being debated. Here, we review theoretical and experimental advances from the past few years, focussing on the regulation and role of potential tissue rigidity transitions in different biological processes., Competing Interests: Declaration of interests No interests to declare., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2022

25. Cell surface fluctuations regulate early embryonic lineage sorting.

Author

Yanagida A, Corujo-Simon E, Revell CK, Sahu P, Stirparo GG, Aspalter IM, Winkel AK, Peters R, De Belly H, Cassani DAD, Achouri S, Blumenfeld R, Franze K, Hannezo E, Paluch EK, Nichols J, and Chalut KJ

Published

2022

26. Extracellular hyaluronate pressure shaped by cellular tethers drives tissue morphogenesis.

Author

Munjal A, Hannezo E, Tsai TY, Mitchison TJ, and Megason SG

Subjects

Actomyosin metabolism, Animals, Anisotropy, Behavior, Animal, Extracellular Matrix metabolism, Hyaluronic Acid biosynthesis, Models, Biological, Osmotic Pressure, Semicircular Canals diagnostic imaging, Stereotyped Behavior, Zebrafish embryology, Zebrafish Proteins metabolism, Extracellular Space chemistry, Hyaluronic Acid pharmacology, Morphogenesis drug effects, Organ Specificity drug effects, Pressure, Semicircular Canals cytology, Semicircular Canals embryology

Abstract

How tissues acquire complex shapes is a fundamental question in biology and regenerative medicine. Zebrafish semicircular canals form from invaginations in the otic epithelium (buds) that extend and fuse to form the hubs of each canal. We find that conventional actomyosin-driven behaviors are not required. Instead, local secretion of hyaluronan, made by the enzymes uridine 5'-diphosphate dehydrogenase (ugdh) and hyaluronan synthase 3 (has3), drives canal morphogenesis. Charged hyaluronate polymers osmotically swell with water and generate isotropic extracellular pressure to deform the overlying epithelium into buds. The mechanical anisotropy needed to shape buds into tubes is conferred by a polarized distribution of actomyosin and E-cadherin-rich membrane tethers, which we term cytocinches. Most work on tissue morphogenesis ascribes actomyosin contractility as the driving force, while the extracellular matrix shapes tissues through differential stiffness. Our work inverts this expectation. Hyaluronate pressure shaped by anisotropic tissue stiffness may be a widespread mechanism for powering morphological change in organogenesis and tissue engineering., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

27. Theory of branching morphogenesis by local interactions and global guidance.

Author

Uçar MC, Kamenev D, Sunadome K, Fachet D, Lallemend F, Adameyko I, Hadjab S, and Hannezo E

Subjects

Animals, Animals, Genetically Modified, Genes, Reporter genetics, Intravital Microscopy, Models, Animal, Sensory Receptor Cells physiology, Stochastic Processes, Zebrafish embryology, Models, Biological, Morphogenesis

Abstract

Branching morphogenesis governs the formation of many organs such as lung, kidney, and the neurovascular system. Many studies have explored system-specific molecular and cellular regulatory mechanisms, as well as self-organizing rules underlying branching morphogenesis. However, in addition to local cues, branched tissue growth can also be influenced by global guidance. Here, we develop a theoretical framework for a stochastic self-organized branching process in the presence of external cues. Combining analytical theory with numerical simulations, we predict differential signatures of global vs. local regulatory mechanisms on the branching pattern, such as angle distributions, domain size, and space-filling efficiency. We find that branch alignment follows a generic scaling law determined by the strength of global guidance, while local interactions influence the tissue density but not its overall territory. Finally, using zebrafish innervation as a model system, we test these key features of the model experimentally. Our work thus provides quantitative predictions to disentangle the role of different types of cues in shaping branched structures across scales., (© 2021. The Author(s).)

Published

2021

28. Three-dimensional geometry controls division symmetry in stem cell colonies.

Author

Chaigne A, Smith MB, Lopez Cavestany R, Hannezo E, Chalut KJ, and Paluch EK

Subjects

Animals, Intercellular Junctions, Metaphase, Mice, Mitosis, Stem Cells, Anaphase, Spindle Apparatus

Abstract

Proper control of division orientation and symmetry, largely determined by spindle positioning, is essential to development and homeostasis. Spindle positioning has been extensively studied in cells dividing in two-dimensional (2D) environments and in epithelial tissues, where proteins such as NuMA (also known as NUMA1) orient division along the interphase long axis of the cell. However, little is known about how cells control spindle positioning in three-dimensional (3D) environments, such as early mammalian embryos and a variety of adult tissues. Here, we use mouse embryonic stem cells (ESCs), which grow in 3D colonies, as a model to investigate division in 3D. We observe that, at the periphery of 3D colonies, ESCs display high spindle mobility and divide asymmetrically. Our data suggest that enhanced spindle movements are due to unequal distribution of the cell-cell junction protein E-cadherin between future daughter cells. Interestingly, when cells progress towards differentiation, division becomes more symmetric, with more elongated shapes in metaphase and enhanced cortical NuMA recruitment in anaphase. Altogether, this study suggests that in 3D contexts, the geometry of the cell and its contacts with neighbors control division orientation and symmetry. This article has an associated First Person interview with the first author of the paper., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

29. Cell fate coordinates mechano-osmotic forces in intestinal crypt formation.

Author

Yang Q, Xue SL, Chan CJ, Rempfler M, Vischi D, Maurer-Gutierrez F, Hiiragi T, Hannezo E, and Liberali P

Subjects

Animals, Cell Movement, Cells, Cultured, Computer Simulation, Female, Intestinal Mucosa cytology, Intestinal Mucosa metabolism, Male, Mice, Inbred C57BL, Mice, Transgenic, Microscopy, Confocal, Microscopy, Video, Models, Biological, Morphogenesis, Myosin Type II genetics, Myosin Type II metabolism, Organoids, Osmotic Pressure, Paneth Cells metabolism, Sodium-Glucose Transport Proteins genetics, Sodium-Glucose Transport Proteins metabolism, Stem Cells metabolism, Stress, Mechanical, Time Factors, Mice, Cell Differentiation, Cell Lineage, Intestinal Mucosa physiology, Mechanotransduction, Cellular, Osmoregulation, Paneth Cells physiology, Stem Cells physiology

Abstract

Intestinal organoids derived from single cells undergo complex crypt-villus patterning and morphogenesis. However, the nature and coordination of the underlying forces remains poorly characterized. Here, using light-sheet microscopy and large-scale imaging quantification, we demonstrate that crypt formation coincides with a stark reduction in lumen volume. We develop a 3D biophysical model to computationally screen different mechanical scenarios of crypt morphogenesis. Combining this with live-imaging data and multiple mechanical perturbations, we show that actomyosin-driven crypt apical contraction and villus basal tension work synergistically with lumen volume reduction to drive crypt morphogenesis, and demonstrate the existence of a critical point in differential tensions above which crypt morphology becomes robust to volume changes. Finally, we identified a sodium/glucose cotransporter that is specific to differentiated enterocytes that modulates lumen volume reduction through cell swelling in the villus region. Together, our study uncovers the cellular basis of how cell fate modulates osmotic and actomyosin forces to coordinate robust morphogenesis., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021

30. Roadmap for the multiscale coupling of biochemical and mechanical signals during development.

Author

Lenne PF, Munro E, Heemskerk I, Warmflash A, Bocanegra-Moreno L, Kishi K, Kicheva A, Long Y, Fruleux A, Boudaoud A, Saunders TE, Caldarelli P, Michaut A, Gros J, Maroudas-Sacks Y, Keren K, Hannezo E, Gartner ZJ, Stormo B, Gladfelter A, Rodrigues A, Shyer A, Minc N, Maître JL, Di Talia S, Khamaisi B, Sprinzak D, and Tlili S

Subjects

Models, Biological, Biomechanical Phenomena, Morphogenesis, Signal Transduction

Abstract

The way in which interactions between mechanics and biochemistry lead to the emergence of complex cell and tissue organization is an old question that has recently attracted renewed interest from biologists, physicists, mathematicians and computer scientists. Rapid advances in optical physics, microscopy and computational image analysis have greatly enhanced our ability to observe and quantify spatiotemporal patterns of signalling, force generation, deformation, and flow in living cells and tissues. Powerful new tools for genetic, biophysical and optogenetic manipulation are allowing us to perturb the underlying machinery that generates these patterns in increasingly sophisticated ways. Rapid advances in theory and computing have made it possible to construct predictive models that describe how cell and tissue organization and dynamics emerge from the local coupling of biochemistry and mechanics. Together, these advances have opened up a wealth of new opportunities to explore how mechanochemical patterning shapes organismal development. In this roadmap, we present a series of forward-looking case studies on mechanochemical patterning in development, written by scientists working at the interface between the physical and biological sciences, and covering a wide range of spatial and temporal scales, organisms, and modes of development. Together, these contributions highlight the many ways in which the dynamic coupling of mechanics and biochemistry shapes biological dynamics: from mechanoenzymes that sense force to tune their activity and motor output, to collectives of cells in tissues that flow and redistribute biochemical signals during development., (Creative Commons Attribution license.)

Published

2021

31. Stochastic combinations of actin regulatory proteins are sufficient to drive filopodia formation.

Author

Dobramysl U, Jarsch IK, Inoue Y, Shimo H, Richier B, Gadsby JR, Mason J, Szałapak A, Ioannou PS, Correia GP, Walrant A, Butler R, Hannezo E, Simons BD, and Gallop JL

Subjects

Animals, Drosophila Proteins genetics, Drosophila melanogaster, Fatty Acid-Binding Proteins genetics, Pseudopodia genetics, Xenopus, Xenopus Proteins genetics, Drosophila Proteins metabolism, Embryo, Nonmammalian metabolism, Fatty Acid-Binding Proteins metabolism, Pseudopodia metabolism, Xenopus Proteins metabolism

Abstract

Assemblies of actin and its regulators underlie the dynamic morphology of all eukaryotic cells. To understand how actin regulatory proteins work together to generate actin-rich structures such as filopodia, we analyzed the localization of diverse actin regulators within filopodia in Drosophila embryos and in a complementary in vitro system of filopodia-like structures (FLSs). We found that the composition of the regulatory protein complex where actin is incorporated (the filopodial tip complex) is remarkably heterogeneous both in vivo and in vitro. Our data reveal that different pairs of proteins correlate with each other and with actin bundle length, suggesting the presence of functional subcomplexes. This is consistent with a theoretical framework where three or more redundant subcomplexes join the tip complex stochastically, with any two being sufficient to drive filopodia formation. We provide an explanation for the observed heterogeneity and suggest that a mechanism based on multiple components allows stereotypical filopodial dynamics to arise from diverse upstream signaling pathways., (© 2021 Dobramysl et al.)

Published

2021

32. Rigidity percolation uncovers a structural basis for embryonic tissue phase transitions.

Author

Petridou NI, Corominas-Murtra B, Heisenberg CP, and Hannezo E

Subjects

Animals, Blastoderm cytology, Blastoderm physiology, Cadherins antagonists & inhibitors, Cadherins genetics, Cadherins metabolism, Cell Adhesion, Embryo, Nonmammalian cytology, Morpholinos metabolism, Rheology, Viscosity, Zebrafish growth & development, Embryo, Nonmammalian physiology, Embryonic Development

Abstract

Embryo morphogenesis is impacted by dynamic changes in tissue material properties, which have been proposed to occur via processes akin to phase transitions (PTs). Here, we show that rigidity percolation provides a simple and robust theoretical framework to predict material/structural PTs of embryonic tissues from local cell connectivity. By using percolation theory, combined with directly monitoring dynamic changes in tissue rheology and cell contact mechanics, we demonstrate that the zebrafish blastoderm undergoes a genuine rigidity PT, brought about by a small reduction in adhesion-dependent cell connectivity below a critical value. We quantitatively predict and experimentally verify hallmarks of PTs, including power-law exponents and associated discontinuities of macroscopic observables. Finally, we show that this uniform PT depends on blastoderm cells undergoing meta-synchronous divisions causing random and, consequently, uniform changes in cell connectivity. Collectively, our theoretical and experimental findings reveal the structural basis of material PTs in an organismal context., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

33. DUCT reveals architectural mechanisms contributing to bile duct recovery in a mouse model for Alagille syndrome.

Author

Hankeova S, Salplachta J, Zikmund T, Kavkova M, Van Hul N, Brinek A, Smekalova V, Laznovsky J, Dawit F, Jaros J, Bryja V, Lendahl U, Ellis E, Nemeth A, Fischler B, Hannezo E, Kaiser J, and Andersson ER

Subjects

Animals, Bile Ducts growth & development, Disease Models, Animal, Mice, Mice, Transgenic, X-Ray Microtomography classification, Alagille Syndrome physiopathology, Bile Ducts physiopathology, X-Ray Microtomography methods

Abstract

Organ function depends on tissues adopting the correct architecture. However, insights into organ architecture are currently hampered by an absence of standardized quantitative 3D analysis. We aimed to develop a robust technology to visualize, digitalize, and segment the architecture of two tubular systems in 3D: d o u ble resin c asting micro computed t omography (DUCT). As proof of principle, we applied DUCT to a mouse model for Alagille syndrome ( Jag1 Ndr/Ndr mice), characterized by intrahepatic bile duct paucity, that can spontaneously generate a biliary system in adulthood. DUCT identified increased central biliary branching and peripheral bile duct tortuosity as two compensatory processes occurring in distinct regions of Jag1 Ndr/Ndr liver, leading to full reconstitution of wild-type biliary volume and phenotypic recovery. DUCT is thus a powerful new technology for 3D analysis, which can reveal novel phenotypes and provide a standardized method of defining liver architecture in mouse models., Competing Interests: SH, JS, TZ, MK, NV, AB, VS, JL, FD, JJ, VB, UL, EE, AN, BF, EH, JK, EA No competing interests declared, (© 2021, Hankeova et al.)

Published

2021

34. Abscission Couples Cell Division to Embryonic Stem Cell Fate.

Author

Chaigne A, Labouesse C, White IJ, Agnew M, Hannezo E, Chalut KJ, and Paluch EK

Subjects

Animals, Cell Cycle physiology, Cytokinesis physiology, Endosomal Sorting Complexes Required for Transport metabolism, Humans, Mice, Cell Differentiation physiology, Embryonic Stem Cells metabolism, Mitosis physiology, Mouse Embryonic Stem Cells metabolism

Abstract

Cell fate transitions are key to development and homeostasis. It is thus essential to understand the cellular mechanisms controlling fate transitions. Cell division has been implicated in fate decisions in many stem cell types, including neuronal and epithelial progenitors. In other stem cells, such as embryonic stem (ES) cells, the role of division remains unclear. Here, we show that exit from naive pluripotency in mouse ES cells generally occurs after a division. We further show that exit timing is strongly correlated between sister cells, which remain connected by cytoplasmic bridges long after division, and that bridge abscission progressively accelerates as cells exit naive pluripotency. Finally, interfering with abscission impairs naive pluripotency exit, and artificially inducing abscission accelerates it. Altogether, our data indicate that a switch in the division machinery leading to faster abscission regulates pluripotency exit. Our study identifies abscission as a key cellular process coupling cell division to fate transitions., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2020

35. Tracing the cellular basis of islet specification in mouse pancreas.

Author

Sznurkowska MK, Hannezo E, Azzarelli R, Chatzeli L, Ikeda T, Yoshida S, Philpott A, and Simons BD

Subjects

Animals, Cell Lineage physiology, Computer Simulation, Embryo, Mammalian, Embryonic Development, Female, Genes, Reporter genetics, Imaging, Three-Dimensional, Luminescent Proteins genetics, Male, Mice, Mice, Transgenic, Microscopy, Confocal, Models, Animal, Models, Biological, Organogenesis, Pancreas diagnostic imaging, Stem Cells physiology, Cell Differentiation, Glucagon-Secreting Cells physiology, Insulin-Secreting Cells physiology, Pancreas embryology

Abstract

Pancreatic islets play an essential role in regulating blood glucose level. Although the molecular pathways underlying islet cell differentiation are beginning to be resolved, the cellular basis of islet morphogenesis and fate allocation remain unclear. By combining unbiased and targeted lineage tracing, we address the events leading to islet formation in the mouse. From the statistical analysis of clones induced at multiple embryonic timepoints, here we show that, during the secondary transition, islet formation involves the aggregation of multiple equipotent endocrine progenitors that transition from a phase of stochastic amplification by cell division into a phase of sublineage restriction and limited islet fission. Together, these results explain quantitatively the heterogeneous size distribution and degree of polyclonality of maturing islets, as well as dispersion of progenitors within and between islets. Further, our results show that, during the secondary transition, α- and β-cells are generated in a contemporary manner. Together, these findings provide insight into the cellular basis of islet development.

Published

2020

36. Stem cell lineage survival as a noisy competition for niche access.

Author

Corominas-Murtra B, Scheele CLGJ, Kishi K, Ellenbroek SIJ, Simons BD, van Rheenen J, and Hannezo E

Subjects

Animals, Cell Survival, Female, Homeostasis, Intestines cytology, Intestines growth & development, Kidney cytology, Kidney growth & development, Mammary Glands, Animal cytology, Mammary Glands, Animal growth & development, Mice, Models, Theoretical, Signal-To-Noise Ratio, Stem Cells cytology, Stem Cells physiology, Cell Lineage, Cell Self Renewal, Stem Cell Niche

Abstract

Understanding to what extent stem cell potential is a cell-intrinsic property or an emergent behavior coming from global tissue dynamics and geometry is a key outstanding question of systems and stem cell biology. Here, we propose a theory of stem cell dynamics as a stochastic competition for access to a spatially localized niche, giving rise to a stochastic conveyor-belt model. Cell divisions produce a steady cellular stream which advects cells away from the niche, while random rearrangements enable cells away from the niche to be favorably repositioned. Importantly, even when assuming that all cells in a tissue are molecularly equivalent, we predict a common ("universal") functional dependence of the long-term clonal survival probability on distance from the niche, as well as the emergence of a well-defined number of functional stem cells, dependent only on the rate of random movements vs. mitosis-driven advection. We test the predictions of this theory on datasets of pubertal mammary gland tips and embryonic kidney tips, as well as homeostatic intestinal crypts. Importantly, we find good agreement for the predicted functional dependency of the competition as a function of position, and thus functional stem cell number in each organ. This argues for a key role of positional fluctuations in dictating stem cell number and dynamics, and we discuss the applicability of this theory to other settings., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

37. Defining the Design Principles of Skin Epidermis Postnatal Growth.

Author

Dekoninck S, Hannezo E, Sifrim A, Miroshnikova YA, Aragona M, Malfait M, Gargouri S, de Neunheuser C, Dubois C, Voet T, Wickström SA, Simons BD, and Blanpain C

Subjects

Animals, Animals, Outbred Strains, Cell Differentiation physiology, Cell Division physiology, Cell Lineage genetics, Cell Proliferation physiology, Cells, Cultured, Epidermal Cells pathology, Epidermis metabolism, Female, Male, Mice, Mice, Transgenic, Stem Cells cytology, Epidermal Cells metabolism, Epidermis growth & development, Skin growth & development

Abstract

During embryonic and postnatal development, organs and tissues grow steadily to achieve their final size at the end of puberty. However, little is known about the cellular dynamics that mediate postnatal growth. By combining in vivo clonal lineage tracing, proliferation kinetics, single-cell transcriptomics, and in vitro micro-pattern experiments, we resolved the cellular dynamics taking place during postnatal skin epidermis expansion. Our data revealed that harmonious growth is engineered by a single population of developmental progenitors presenting a fixed fate imbalance of self-renewing divisions with an ever-decreasing proliferation rate. Single-cell RNA sequencing revealed that epidermal developmental progenitors form a more uniform population compared with adult stem and progenitor cells. Finally, we found that the spatial pattern of cell division orientation is dictated locally by the underlying collagen fiber orientation. Our results uncover a simple design principle of organ growth where progenitors and differentiated cells expand in harmony with their surrounding tissues., Competing Interests: Declaration of Interests The authors declare no competing interests., (Crown Copyright © 2020. Published by Elsevier Inc. All rights reserved.)

Published

2020

38. Multiscale dynamics of branching morphogenesis.

Author

Hannezo E and Simons BD

Subjects

Animals, Models, Biological, Stem Cells cytology, Morphogenesis

Abstract

Branching morphogenesis is a prototypical example of complex three-dimensional organ sculpting, required in multiple developmental settings to maximize the area of exchange surfaces. It requires, in particular, the coordinated growth of different cell types together with complex patterning to lead to robust macroscopic outputs. In recent years, novel multiscale quantitative biology approaches, together with biophysical modelling, have begun to shed new light of this topic. Here, we wish to review some of these recent developments, highlighting the generic design principles that can be abstracted across different branched organs, as well as the implications for the broader fields of stem cell, developmental and systems biology., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

39. Active cell migration is critical for steady-state epithelial turnover in the gut.

Author

Krndija D, El Marjou F, Guirao B, Richon S, Leroy O, Bellaiche Y, Hannezo E, and Matic Vignjevic D

Subjects

Actin-Related Protein 2-3 Complex genetics, Actin-Related Protein 2-3 Complex physiology, Animals, Cell Movement genetics, Cell Polarity, Imaging, Three-Dimensional, Intestinal Mucosa metabolism, Mice, Knockout, Models, Biological, Cell Movement physiology, Intestinal Mucosa cytology, Intestinal Mucosa physiology, Mitosis

Abstract

Steady-state turnover is a hallmark of epithelial tissues throughout adult life. Intestinal epithelial turnover is marked by continuous cell migration, which is assumed to be driven by mitotic pressure from the crypts. However, the balance of forces in renewal remains ill-defined. Combining biophysical modeling and quantitative three-dimensional tissue imaging with genetic and physical manipulations, we revealed the existence of an actin-related protein 2/3 complex-dependent active migratory force, which explains quantitatively the profiles of cell speed, density, and tissue tension along the villi. Cells migrate collectively with minimal rearrangements while displaying dual-apicobasal and front-back-polarity characterized by actin-rich basal protrusions oriented in the direction of migration. We propose that active migration is a critical component of gut epithelial turnover., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

40. Tracing the cellular dynamics of sebaceous gland development in normal and perturbed states.

Author

Andersen MS, Hannezo E, Ulyanchenko S, Estrach S, Antoku Y, Pisano S, Boonekamp KE, Sendrup S, Maimets M, Pedersen MT, Johansen JV, Clement DL, Feral CC, Simons BD, and Jensen KB

Subjects

Animals, Disease Progression, Mice, Transgenic, Cell Proliferation physiology, Gene Expression Regulation, Developmental immunology, Homeostasis physiology, Stem Cells cytology

Abstract

The sebaceous gland (SG) is an essential component of the skin, and SG dysfunction is debilitating 1,2 . Yet, the cellular bases for its origin, development and subsequent maintenance remain poorly understood. Here, we apply large-scale quantitative fate mapping to define the patterns of cell fate behaviour during SG development and maintenance. We show that the SG develops from a defined number of lineage-restricted progenitors that undergo a programme of independent and stochastic cell fate decisions. Following an expansion phase, equipotent progenitors transition into a phase of homeostatic turnover, which is correlated with changes in the mechanical properties of the stroma and spatial restrictions on gland size. Expression of the oncogene KrasG12D results in a release from these constraints and unbridled gland expansion. Quantitative clonal fate analysis reveals that, during this phase, the primary effect of the Kras oncogene is to drive a constant fate bias with little effect on cell division rates. These findings provide insight into the developmental programme of the SG, as well as the mechanisms that drive tumour progression and gland dysfunction.

Published

2019

41. Mechanochemical Feedback Loops in Development and Disease.

Author

Hannezo E and Heisenberg CP

Subjects

Animals, Cell Size, Cytoskeleton physiology, Extracellular Matrix physiology, Humans, Protein Conformation, Rheology, Biomechanical Phenomena physiology, Cell Communication physiology, Cell Differentiation physiology, Cell Proliferation physiology, Feedback, Physiological

Abstract

There is increasing evidence that both mechanical and biochemical signals play important roles in development and disease. The development of complex organisms, in particular, has been proposed to rely on the feedback between mechanical and biochemical patterning events. This feedback occurs at the molecular level via mechanosensation but can also arise as an emergent property of the system at the cellular and tissue level. In recent years, dynamic changes in tissue geometry, flow, rheology, and cell fate specification have emerged as key platforms of mechanochemical feedback loops in multiple processes. Here, we review recent experimental and theoretical advances in understanding how these feedbacks function in development and disease., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

42. Tracing the origin of adult intestinal stem cells.

Author

Guiu J, Hannezo E, Yui S, Demharter S, Ulyanchenko S, Maimets M, Jørgensen A, Perlman S, Lundvall L, Mamsen LS, Larsen A, Olesen RH, Andersen CY, Thuesen LL, Hare KJ, Pers TH, Khodosevich K, Simons BD, and Jensen KB

Subjects

Animals, Cell Differentiation, Cellular Reprogramming, Female, Fetus cytology, Intestinal Mucosa cytology, Intestinal Mucosa metabolism, Intestines growth & development, Male, Mice, Receptors, G-Protein-Coupled metabolism, Regeneration, Stem Cell Niche, Cell Lineage, Intestines cytology, Stem Cells cytology

Abstract

Adult intestinal stem cells are located at the bottom of crypts of Lieberkühn, where they express markers such as LGR5 1,2 and fuel the constant replenishment of the intestinal epithelium 1 . Although fetal LGR5-expressing cells can give rise to adult intestinal stem cells 3,4 , it remains unclear whether this population in the patterned epithelium represents unique intestinal stem-cell precursors. Here we show, using unbiased quantitative lineage-tracing approaches, biophysical modelling and intestinal transplantation, that all cells of the mouse intestinal epithelium-irrespective of their location and pattern of LGR5 expression in the fetal gut tube-contribute actively to the adult intestinal stem cell pool. Using 3D imaging, we find that during fetal development the villus undergoes gross remodelling and fission. This brings epithelial cells from the non-proliferative villus into the proliferative intervillus region, which enables them to contribute to the adult stem-cell niche. Our results demonstrate that large-scale remodelling of the intestinal wall and cell-fate specification are closely linked. Moreover, these findings provide a direct link between the observed plasticity and cellular reprogramming of differentiating cells in adult tissues following damage 5-9 , revealing that stem-cell identity is an induced rather than a hardwired property.

Published

2019

43. Bulk Actin Dynamics Drive Phase Segregation in Zebrafish Oocytes.

Author

Shamipour S, Kardos R, Xue SL, Hof B, Hannezo E, and Heisenberg CP

Subjects

Actins physiology, Animals, Cell Polarity physiology, Cytoplasm metabolism, Egg Yolk physiology, Polymerization, Zebrafish embryology, Zebrafish metabolism, Zebrafish Proteins metabolism, Zygote, Actins metabolism, Cell Cycle physiology, Oocytes metabolism

Abstract

Segregation of maternal determinants within the oocyte constitutes the first step in embryo patterning. In zebrafish oocytes, extensive ooplasmic streaming leads to the segregation of ooplasm from yolk granules along the animal-vegetal axis of the oocyte. Here, we show that this process does not rely on cortical actin reorganization, as previously thought, but instead on a cell-cycle-dependent bulk actin polymerization wave traveling from the animal to the vegetal pole of the oocyte. This wave functions in segregation by both pulling ooplasm animally and pushing yolk granules vegetally. Using biophysical experimentation and theory, we show that ooplasm pulling is mediated by bulk actin network flows exerting friction forces on the ooplasm, while yolk granule pushing is achieved by a mechanism closely resembling actin comet formation on yolk granules. Our study defines a novel role of cell-cycle-controlled bulk actin polymerization waves in oocyte polarization via ooplasmic segregation., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

44. Fluidization-mediated tissue spreading by mitotic cell rounding and non-canonical Wnt signalling.

Author

Petridou NI, Grigolon S, Salbreux G, Hannezo E, and Heisenberg CP

Subjects

Animals, Animals, Genetically Modified, Biomechanical Phenomena, Blastoderm cytology, Cell Communication physiology, Cell Division, Cell Movement physiology, Elasticity, Embryo, Nonmammalian cytology, Embryo, Nonmammalian embryology, Mitosis physiology, Viscosity, Zebrafish genetics, Blastoderm embryology, Morphogenesis, Wnt Signaling Pathway physiology, Zebrafish embryology

Abstract

Tissue morphogenesis is driven by mechanical forces that elicit changes in cell size, shape and motion. The extent by which forces deform tissues critically depends on the rheological properties of the recipient tissue. Yet, whether and how dynamic changes in tissue rheology affect tissue morphogenesis and how they are regulated within the developing organism remain unclear. Here, we show that blastoderm spreading at the onset of zebrafish morphogenesis relies on a rapid, pronounced and spatially patterned tissue fluidization. Blastoderm fluidization is temporally controlled by mitotic cell rounding-dependent cell-cell contact disassembly during the last rounds of cell cleavages. Moreover, fluidization is spatially restricted to the central blastoderm by local activation of non-canonical Wnt signalling within the blastoderm margin, increasing cell cohesion and thereby counteracting the effect of mitotic rounding on contact disassembly. Overall, our results identify a fluidity transition mediated by loss of cell cohesion as a critical regulator of embryo morphogenesis.

Published

2019

45. Statistical theory of branching morphogenesis.

Author

Hannezo E and Simons BD

Subjects

Animals, Cell Lineage, Cell Proliferation, Humans, Kidney cytology, Kidney growth & development, Pancreas cytology, Pancreas growth & development, Epithelial Cells cytology, Epithelium growth & development, Models, Biological, Morphogenesis

Abstract

Branching morphogenesis remains a subject of abiding interest. Although much is known about the gene regulatory programs and signaling pathways that operate at the cellular scale, it has remained unclear how the macroscopic features of branched organs, including their size, network topology and spatial patterning, are encoded. Lately, it has been proposed that, these features can be explained quantitatively in several organs within a single unifying framework. Based on large-scale organ reconstructions and cell lineage tracing, it has been argued that morphogenesis follows from the collective dynamics of sublineage-restricted self-renewing progenitor cells, localized at ductal tips, that act cooperatively to drive a serial process of ductal elongation and stochastic tip bifurcation. By correlating differentiation or cell cycle exit with proximity to maturing ducts, this dynamic results in the specification of a complex network of defined density and statistical organization. These results suggest that, for several mammalian tissues, branched epithelial structures develop as a self-organized process, reliant upon a strikingly simple, but generic, set of local rules, without recourse to a rigid and deterministic sequence of genetically programmed events. Here, we review the basis of these findings and discuss their implications., (© 2018 The Authors Development, Growth & Differentiation published by John Wiley & Sons Australia, Ltd on behalf of Japanese Society of Developmental Biologists.)

Published

2018

46. Defining Lineage Potential and Fate Behavior of Precursors during Pancreas Development.

Author

Sznurkowska MK, Hannezo E, Azzarelli R, Rulands S, Nestorowa S, Hindley CJ, Nichols J, Göttgens B, Huch M, Philpott A, and Simons BD

Subjects

Acinar Cells metabolism, Animals, Cell Differentiation physiology, Cell Proliferation physiology, Morphogenesis physiology, Stem Cells metabolism, Cell Lineage physiology, Endocrine Cells metabolism, Gene Expression Regulation, Developmental genetics, Organogenesis physiology, Pancreas growth & development

Abstract

Pancreas development involves a coordinated process in which an early phase of cell segregation is followed by a longer phase of lineage restriction, expansion, and tissue remodeling. By combining clonal tracing and whole-mount reconstruction with proliferation kinetics and single-cell transcriptional profiling, we define the functional basis of pancreas morphogenesis. We show that the large-scale organization of mouse pancreas can be traced to the activity of self-renewing precursors positioned at the termini of growing ducts, which act collectively to drive serial rounds of stochastic ductal bifurcation balanced by termination. During this phase of branching morphogenesis, multipotent precursors become progressively fate-restricted, giving rise to self-renewing acinar-committed precursors that are conveyed with growing ducts, as well as ductal progenitors that expand the trailing ducts and give rise to delaminating endocrine cells. These findings define quantitatively how the functional behavior and lineage progression of precursor pools determine the large-scale patterning of pancreatic sub-compartments., (Copyright © 2018 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2018

47. Clonal analysis of Notch1-expressing cells reveals the existence of unipotent stem cells that retain long-term plasticity in the embryonic mammary gland.

Author

Lilja AM, Rodilla V, Huyghe M, Hannezo E, Landragin C, Renaud O, Leroy O, Rulands S, Simons BD, and Fre S

Subjects

Adult Stem Cells metabolism, Adult Stem Cells pathology, Animals, Cell Transformation, Neoplastic genetics, Cell Transformation, Neoplastic metabolism, Cell Transformation, Neoplastic pathology, Female, Fluorescent Antibody Technique, Gene Expression Regulation, Developmental, Gestational Age, Mammary Glands, Animal embryology, Mice, Mice, Transgenic, Models, Genetic, Morphogenesis, Neoplastic Stem Cells metabolism, Neoplastic Stem Cells pathology, Phenotype, Receptor, Notch1 genetics, Signal Transduction, Single-Cell Analysis, Time Factors, Cell Differentiation, Cell Lineage, Cell Plasticity, Epithelial Cells metabolism, Mammary Glands, Animal metabolism, Mouse Embryonic Stem Cells metabolism, Receptor, Notch1 metabolism

Abstract

Recent lineage tracing studies have revealed that mammary gland homeostasis relies on unipotent stem cells. However, whether and when lineage restriction occurs during embryonic mammary development, and which signals orchestrate cell fate specification, remain unknown. Using a combination of in vivo clonal analysis with whole mount immunofluorescence and mathematical modelling of clonal dynamics, we found that embryonic multipotent mammary cells become lineage-restricted surprisingly early in development, with evidence for unipotency as early as E12.5 and no statistically discernable bipotency after E15.5. To gain insights into the mechanisms governing the switch from multipotency to unipotency, we used gain-of-function Notch1 mice and demonstrated that Notch activation cell autonomously dictates luminal cell fate specification to both embryonic and basally committed mammary cells. These functional studies have important implications for understanding the signals underlying cell plasticity and serve to clarify how reactivation of embryonic programs in adult cells can lead to cancer.

Published

2018

48. A biochemical network controlling basal myosin oscillation.

Author

Qin X, Hannezo E, Mangeat T, Liu C, Majumder P, Liu J, Choesmel-Cadamuro V, McDonald JA, Liu Y, Yi B, and Wang X

Subjects

Actomyosin chemistry, Animals, Animals, Genetically Modified, Drosophila genetics, Female, Fluorescence Resonance Energy Transfer, Light, Male, Microscopy, Confocal, Optogenetics, Oscillometry, Signal Transduction, rho-Associated Kinases, Drosophila metabolism, Drosophila Proteins metabolism, Myosin Type II chemistry, Myosin-Light-Chain Phosphatase metabolism

Abstract

The actomyosin cytoskeleton, a key stress-producing unit in epithelial cells, oscillates spontaneously in a wide variety of systems. Although much of the signal cascade regulating myosin activity has been characterized, the origin of such oscillatory behavior is still unclear. Here, we show that basal myosin II oscillation in Drosophila ovarian epithelium is not controlled by actomyosin cortical tension, but instead relies on a biochemical oscillator involving ROCK and myosin phosphatase. Key to this oscillation is a diffusive ROCK flow, linking junctional Rho1 to medial actomyosin cortex, and dynamically maintained by a self-activation loop reliant on ROCK kinase activity. In response to the resulting myosin II recruitment, myosin phosphatase is locally enriched and shuts off ROCK and myosin II signals. Coupling Drosophila genetics, live imaging, modeling, and optogenetics, we uncover an intrinsic biochemical oscillator at the core of myosin II regulatory network, shedding light on the spatio-temporal dynamics of force generation.

Published

2018

49. Theory of Epithelial Cell Shape Transitions Induced by Mechanoactive Chemical Gradients.

Author

Dasbiswas K, Hannezo E, and Gov NS

Subjects

Cytoskeleton, Diffusion, Humans, Signal Transduction, Cell Shape, Chemotaxis, Epithelial Cells cytology, Mechanotransduction, Cellular, Models, Theoretical

Abstract

Cell shape is determined by a balance of intrinsic properties of the cell as well as its mechanochemical environment. Inhomogeneous shape changes underlie many morphogenetic events and involve spatial gradients in active cellular forces induced by complex chemical signaling. Here, we introduce a mechanochemical model based on the notion that cell shape changes may be induced by external diffusible biomolecules that influence cellular contractility (or equivalently, adhesions) in a concentration-dependent manner-and whose spatial profile in turn is affected by cell shape. We map out theoretically the possible interplay between chemical concentration and cellular structure. Besides providing a direct route to spatial gradients in cell shape profiles in tissues, we show that the dependence on cell shape helps create robust mechanochemical gradients., (Copyright © 2017 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2018

50. A Unifying Theory of Branching Morphogenesis.

Author

Hannezo E, Scheele CLGJ, Moad M, Drogo N, Heer R, Sampogna RV, van Rheenen J, and Simons BD

Subjects

Animals, Female, Humans, Kidney embryology, Male, Mammary Glands, Human embryology, Mice, Prostate embryology, Kidney growth & development, Mammary Glands, Human growth & development, Models, Biological, Morphogenesis, Prostate growth & development

Abstract

The morphogenesis of branched organs remains a subject of abiding interest. Although much is known about the underlying signaling pathways, it remains unclear how macroscopic features of branched organs, including their size, network topology, and spatial patterning, are encoded. Here, we show that, in mouse mammary gland, kidney, and human prostate, these features can be explained quantitatively within a single unifying framework of branching and annihilating random walks. Based on quantitative analyses of large-scale organ reconstructions and proliferation kinetics measurements, we propose that morphogenesis follows from the proliferative activity of equipotent tips that stochastically branch and randomly explore their environment but compete neutrally for space, becoming proliferatively inactive when in proximity with neighboring ducts. These results show that complex branched epithelial structures develop as a self-organized process, reliant upon a strikingly simple but generic rule, without recourse to a rigid and deterministic sequence of genetically programmed events., (Copyright © 2017 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2017