Ref HAL: hal-03676003_v1
DOI: 10.1098/rsif.2022.0026
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Although the polygonal shape of epithelial cells has been drawing the attention of scientists for several centuries, only a decade and a half ago it was demonstrated that distributions of polygon types (DOPTs) are similar in proliferative epithelia of many different plant and animal species. In this study, we show that hyper-proliferation of cancer cells disrupts this universal paradigm and results in randomly organized epithelial structures. Examining non-synchronized and synchronized HeLa cervix cells, we suppose that the spread of cell sizes is the main parameter controlling the DOPT in the cancer cell monolayers. To test this hypothesis, we develop a theory of morphologically similar random polygonal packings. By analysing differences between tumoural and normal epithelial cell monolayers, we conclude that the latter have more ordered structures because of their lower proliferation rates and, consequently, more effective relaxation of mechanical stress associated with cell division and growth. To explain the structural features of normal proliferative epithelium, we take into account the spread of cell sizes in the monolayer. The proposed theory also rationalizes some highly ordered unconventional post-mitotic epithelia.

Ref HAL: hal-03323839_v1
PMID 33927284
DOI: 10.1038/s41598-021-88667-w
WoS: WOS:000656206800045
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All blood cells originate from hematopoietic stem/progenitor cells (HSPCs). HSPCs are formed from endothelial cells (ECs) of the dorsal aorta (DA), via endothelial-to-hematopoietic transition (EHT). The zebrafish is a primary model organism to study the process in vivo. While the role of mechanical stress in controlling gene expression promoting cell differentiation is actively investigated, mechanisms driving shape changes of the DA and individual ECs remain poorly understood. We address this problem by developing a new DA micromechanical model and applying it to experimental data on zebrafish morphogenesis. The model considers the DA as an isotropic tubular membrane subjected to hydrostatic blood pressure and axial stress. The DA evolution is described as a movement in the dimensionless controlling parameters space: normalized hydrostatic pressure and axial stress. We argue that HSPC production is accompanied by two mechanical instabilities arising in the system due to the plane stress in the DA walls and show how a complex interplay between mechanical forces in the system drives the emerging morphological changes.

Ref HAL: hal-03291847_v1
PMID 31732791
DOI: 10.1007/s00018-019-03372-2
WoS: 000560212600012
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During embryogenesis of all vertebrates, haematopoietic stem/progenitor cells (HSPCs) extrude from the aorta by a complex process named endothelial-to-haematopoietic transition (EHT). HSPCs will then colonize haematopoietic organs allowing haematopoiesis throughout adult life. The mechanism underlying EHT including the role of each aortic endothelial cell (EC) within the global aorta dynamics remains unknown. In the present study, we show for the first time that EHT involves the remodelling of individual cells within a collective migration of ECs which is tightly orchestrated, resulting in HSPCs extrusion in the sub-aortic space without compromising aorta integrity. By performing a cross-disciplinary study which combines high-resolution 4D imaging and theoretical analysis based on the concepts of classical mechanics, we propose that this complex developmental process is dependent on mechanical instabilities of the aorta preparing and facilitating the extrusion of HSPCs.

Commentaires: NOTICE A REPRENDRE PAS DE CLE UT AU 15/07

Ref HAL: hal-01996796_v1
DOI: 10.1101/509190
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During embryogenesis of all vertebrates, haematopoietic stem/progenitor cells 16 (HSPCs) extrude from the aorta by a complex process named Endothelial-to-17 Haematopoietic Transition (EHT). HSPCs will then colonize haematopoietic organs 18 allowing haematopoiesis throughout adult life. The mechanism underlying EHT 19 including the role of each aortic endothelial cell within the global aorta dynamics 20 remains unknown. In the present study, we show for the first time that EHT involves the 21 remodelling of individual cells within a collective migration of endothelial cells which is 22 tightly orchestrated, resulting in HSPCs extrusion in the sub-aortic space without 23 compromising aorta integrity. By performing a cross-disciplinary study which combines 24 high resolution 4D imaging and theoretical analysis based on the concepts of classical 25 mechanics, we propose that this complex developmental process is dependent on 26 mechanical instabilities of the aorta preparing and facilitating the extrusion of HSPCs. 27 28 29 We dedicate this work to the memory of our friend and colleague, V. Lorman. 30 31 All rights reserved. No reuse allowed without permission. (which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.

Ref HAL: tel-02176889_v1
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Les méthodes classiques de physique de l'état solide telles que la diffraction des rayons X et la microscopie électronique ont permis la compréhension de la structure des membranes cellulaires. Aujourd'hui, leur composition et structure étant bien connues, les recherches se concentrent sur les processus actifs des membranes. Des processus tels que l'endocytose impliquent des modifications substantielles de la forme des membranes lipidiques, réalisées par des protéines induisant la courbure membranaire. L'une des méthodes expérimentales parmi les plus populaires est dite « TLM-pulling », où la membrane lipidique tubulaire (TLM) est formée à partir de la vésicule en tirant par une force externe. Des structures similaires relient les vésicules endocytiques aux compartiments du donneur et servent de canaux pour le transfert de matière dans la cellule et entre les cellules adjacentes, établissant ainsi une voie de communication intercellulaire. De tels systèmes formés in vitro en raison de leur simplicité et grande homogénéité peuvent être décrits avec précision par la physique théorique.Dans la première partie de la thèse, nous développons un modèle théorique de TLM, basé sur la mécanique classique et la thermodynamique, et l'appliquons aux expériences de « TLM-pulling » avec adsorption de protéines induisant la courbure. Le modèle tient compte de l'asymétrie de la bicouche lipidique, de la tension superficielle, de la force longitudinale appliquée au TLM et de la différence de pression dans le système. Nous modélisons l'action que les protéines exercent sur la TLM via des ensembles de forces normales à la surface de la membrane à l'équilibre mécanique. Cette nouvelle approche multipolaire permet de modéliser les interactions anisotropes, entre les protéines adsorbées à la membrane, qui sont induites par sa déformation. Notre théorie décrit les premiers stades de la formation des échafaudages protéiques, c-à-d la disposition caractéristique des protéines et leur grande affinité avec les extrémités de la TLM. Le comportement collectif des protéines induisant la courbure est extrêmement important pour effectuer des déformations à grande échelle des membranes au cours de processus tels que l'endo et l'exocytose, l'entrée du virus dans la cellule hôte ainsi que la formation et la sortie des virions. L'étude de ce dernier processus pourrait conduire au développement de nouvelles méthodes de traitement en virologie.La deuxième partie de la thèse est consacrée à l'étude de l'aorte dorsale (DA) de l'embryon de poisson Danio-Rerio. On étudie l'évolution de la forme du DA pendant la transition endothélio-hématopoïétique (EHT). Le processus EHT conduit à l'extrusion des cellules souches/hématopoïétiques qui coloniseront en suite la moelle osseuse permettant l'hématopoïèse tout au long de la vie. Ce processus semble être universel et devrait s'appliquer aussi bien aux mammifères qu'aux oiseaux, ce qui fait de son étude un problème fondamental de l'embryologie.Le DA a une géométrie cylindrique et semblable aux TLM, mais en même temps, il est beaucoup plus gros que les tubes lipidiques, a un module de cisaillement non nul et est incorporé dans la matrice des tissus environnants : un système beaucoup plus complexe du point de vue mécanique. Nous relions les changements globaux de forme de l'aorte pendant l'EHT aux principes génériques de la mécanique et montrons que les instabilités mécaniques conduisant à l'évolution de la forme de l'aorte sont invoquées par des stress résultant des inhomogénéités de croissance et de l'interaction avec les tissus environnants. Sur la base de l'analyse théorique et des données en microscopie confocale 4D, nous proposons un schéma détaillé du processus et postulons que les instabilités mécaniques préparent l'ensemble du processus EHT avant son contrôle génétique spécifique, suggérant un mécanisme universel et auto-organisé du processus de réorganisation collective des tissus dans les organismes en croissance.

Ref HAL: hal-01529981_v1
PMID 28000047
DOI: 10.1140/epje/i2016-16128-0
WoS: 000397028700001
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The tubular lipid membranes (TLMs) pulled out from vesicles are often used in in vitro studies of the interactions between curvature-inducing proteins and highly curved membranes. The protein molecules adsorbed at the membrane surface deform the TLM and couple with each other due to the induced strain. Here we propose an approach which models the single curvature-inducing protein action on the lipid bilayer by the multipole, the superposition of the point forces applied to the membrane in the region of the protein adsorption. We show that to be localized in the area of the protein size at the TLM surface, the force multipoles satisfying the mechanical equilibrium conditions should be composed of three or more point forces. The protein coupling energy mediated by the membrane strain is studied in detail. In the region of the tubular membrane stability the maximal distance between two neighboring interacting protein-induced force multipoles is estimated to be of the order of the TLM cross section perimeter. In the vicinity of the TLM instability in the region of the vanishing stretching force applied to the TLM, the interaction radius increases drastically. The high affinity of the single curvature-inducing protein molecule to the regions in the vicinity of the TLM ends is explained and related to the boundary conditions in the experimental set-ups. The reasons for the aggregate formation on the membrane surface are also discussed.

Ref HAL: hal-01935603_v1
Ref Arxiv: 1501.00258
Ref. & Cit.: NASA ADS
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Changes of external parameters in proximity of critical point can increase thermal fluctuations of tubular lipid membrane (TLM) and result in variation of the membrane shape. The phase transitions in the system are shown to be controlled by a single effective parameter, which depends on the pressure difference between inner and outer regions of membrane and the applied stretching force. We determine an interval of the parameter values corresponding to the stability region of the cylindrical shape of TLM and investigate the behavior of the system in the vicinity of critical instabilities, where the cylindrical shape of membrane becomes unstable with respect to thermal fluctuations. The applied boundary conditions strongly influence the behavior of TLM. For example, small negative effective parameter corresponds to chiral shape of TLM only in the case of periodic boundary conditions. We also discuss other three types of phase transitions emerging in the system.

Commentaires: 15 pages, 6 figures, in Russian