Etude de la migration du corps basal au cours de la ciliogénèse

The primary cilium is a sensory organelle present on the surface of most quiescent cells. It possesses numerous receptors on its surface and is responsible for transducing biochemical and mechanical signals to the interior of the cell and playsimportant roles during development and in homeostasis. Defects in primary cilium assembly are the underlying cause of a group of pleiotropic diseases referred to as ciliopathies.The primary cilium is anchored to the plasma membrane through the basal body which is derived from the mother centriole and is connected to three networks of the cytoskeleton. Primary cilium formation is a highly regulated and multi-step process that begins with the maturation of the centriole mother into basal body in the cytoplasm of the cell. One of the first steps of primary cilium assembly is the recruitment of specific proteins to the mother centriole to initiate the formation of a ciliary vesicle at the distal end of the mother centriole. Once formed, the mother centriole migrates to and is anchored to the apical membrane, triggering the elongation of microtubules from the distal end of the mother centriole to form the outer part of primary cilium, or axoneme. In order for this to occur, significant remodeling of the actin cytoskeleton and directe-trafficking of vesicles to the base of the cilium is required. While much progress has been made in characterizing the initial steps of primary ciliogenesis, how the basal body migrates to the plasma membrane is not fully understood.To gain a better understanding of the mechanisms involved in the migration of basal body during ciliogenesis, we developed an experimental system based on the use of adhesive micro-patterns coated with fibronectin. This technology has many advantages. It enables the control of the cell spreading which is imposed by the size of the adhesive area and, in turn, the regulation of cytoskeletal organization and the positioning of subcellular organelles. Furthermore, this technique enables the cell volume induced by the spatial confinement, to be controlled, facilitating the observation and measurement of the centrosome's position in z throughout the primary ciliogenesis process.First, we demonstrated that the shape and architecture of the actin cytoskeleton are major regulators of primary ciliogenesis. Cells spatially confined and starved for 24h on small discoidal micropattern develop an apical web like actin network necessary for the primary cilium growth. In contrast, cells plated on large discs are much more contracted and they develop significant stress fibers on their ventral surface. In this situation, the centrosome remains below the nucleus and the level of contraction prevents the assembly of a primary cilium. The level of contractility therefore modulates the formation of apical actin network that in turn controls the movement of the basal body and the cilium elongation.Secondly, we studied actin cytoskeleton and microtubule reorganization during the basal body migration step that occured just after serum starvation. Our results indicate that migration requires a transient increase in the stability of microtubules, concomitant with an increase in contractility of actin filaments. By RNA interference screening, we have identified genes involved in the migration process including CEP164, which has previously been shown to participate in the anchoring of the ciliary vesicle to the mother centriole. CEP164-deficient cells were found to have defects in cytoskeletal reorganization thereby explaining why basal body transport to the plasma membrane was blocked in these cells.Altogether, these results enable our understanding of how basal body movement to the apical membrane is driven. This requires both significant remodeling and crosstalk between the actin and microtubule cytoskeleton and interaction with ciliary components necessary for the formation of a primary cilium.Le cil primaire, véritable organite sensoriel cellulaire est présent à la surface de la plupart des cellules de mammifères en quiescence. Truffé de récepteurs à sa membrane, le cil capte les signaux mécaniques et chimiques, jouant ainsi un rôle clé dans de nombreux processus développementaux et physiologiques. Un défaut de structure et/ou de fonction du cil est à l'origine de cancérogénèse et de pathologies humaines appelées ciliopathies.Le cil primaire est ancré à la membrane plasmique grâce au corps basal, structure dérivée du centriole père et connectée aux trois réseaux du cytosquelette. La formation du cil primaire nécessite une succession d'étapes cytoplasmiques hautement régulées. Elle débute par la maturation du centriole père en corps basal. Cette étape nécessite le recrutement de protéines spécifiques au centriole père permettant l'association avec une vésicule ciliaire à l'extrémité distale du centriole père. Ce complexe migre et vient s'ancrer à la membrane apicale déclenchant la nucléation de microtubules pour la formation de la partie externe du cil, ou axonème. En parallèle, la ciliogénèse nécessite un remodelage important du cytosquelette d'actine ainsi qu'un trafic de vésicules orienté vers la base du cil. Si la plupart des étapes sont bien caractérisées, celle concernant la migration du corps basal ainsi que la contribution du cytosquelette reste mal comprise.Afin de mieux appréhender les mécanismes impliqués dans la migration du corps basal lors de la ciliogénèse, nous avons développé un système expérimental basé sur l'utilisation de micro-patrons adhésifs recouverts de fibronectine. Cette technologie comporte de nombreux avantages. Elle permet le contrôle de l'étalement de la cellule inhérent à la surface imposée par la matrice extracellulaire régulant ainsi l'organisation du cytosquelette ainsi que le positionnement des organelles subcellulaires. Par ailleurs, le volume cellulaire induit par le confinement spatial facilite l'observation de la position du centrosome en z au cours du temps, indispensable pour l'étude de chaque étape de la ciliogénèse cytoplasmique.Dans un premier temps, nous avons démontré que la forme et l'architecture du cytosquelette d'actine qui en dépend sont des régulateurs majeurs du processus ciliogénique. Les cellules confinées spatialement et sevrées 24h sur des petits disques développent un réseau branché au niveau de leur surface apicale nécessaire à la croissance du cil primaire. A l'inverse, les cellules étalées sur des grands disques sont beaucoup plus contractées. Elles développent d'importantes fibres de stress sur leur surface ventrale. Le centrosome reste sous le noyau et le niveau de contraction empêche l'assemblage du cil. Le niveau de contractilité module donc la formation du réseau d'actine apicale qui contrôle en retour le mouvement du corps basal et l'élongation du cil.Dans un deuxième temps, nous avons étudié la dynamique du cytosquelette d'actine et de microtubules durant l'étape de migration du corps basal c'est à dire juste après la privation de sérum. Nos résultats indiquent que la migration nécessite une augmentation transitoire de la stabilité des microtubules concomitante avec une augmentation de la contractilité des filaments d'actine. Un crible basé sur l'ARN interférence nous a permis d'identifier des gènes impliqués dans le processus de migration dont CEP164, contribuant à l'ancrage du centriole père à la vésicule ciliaire. Les cellules déficientes en CEP164 montrent un défaut de réorganisation du cytosquelette expliquant l'inhibition du transport du corps basal vers la membrane apicale.L'ensemble des résultats nous permet d'avancer dans la compréhension des conditions requises pour le mouvement du corps basal vers la membrane apicale. Celui-ci nécessite à la fois un remodelage significatif du cytosquelette en constant dialogue et en interaction avec certains composants ciliaires nécessaires à la formation du cil primaire

Cell shape and contractility regulate ciliogenesis in cell cycle–arrested cells

Adhesive micropatterns show the effect of spatial confinement and actin network architecture on basal body positioning and primary cilium formation

Puces à cellules et génomique fonctionnelle

À l’interface du vivant et de l’inerte, se développe un ensemble de nouvelles technologies regroupées sous le terme générique de biopuces. Grâce à la miniaturisation, nous pouvons imaginer que, demain, de nombreuses études biologiques et médicales se feront avec des biopuces qui permettront d’accroître de plusieurs ordres de grandeur le parallélisme des analyses, les vitesses de réaction des tests et leur débit, tout en réduisant les coûts. Cette évolution a démarré avec l’apparition des puces à ADN et se poursuit aujourd’hui avec, entre autres, les puces à cellules qui permettent d’accélérer considérablement l’étude des gènes de fonctions inconnues et leurs implications potentielles dans différentes maladies. Bien que la technologie en soit encore à ses prémices, il est vraisemblable que les puces à cellules feront évoluer la biologie et la médecine de manière significative.With the complete sequencing of the human genome, research priorities have shifted from the identification of genes to the elucidation of their function. Methods currently used by scientists to characterize gene function, such as knock-out mice, are based upon loss of protein function and analysis of the resulting phenotypes to infer a potential role for the protein under scrutiny. Until now, these methods have been successful but time consuming and only a few genes at a time could be analyzed. Cell microarrays allow to simultaneously transfect thousands of different nucleic acid molecules, RNA or DNA, into adherent cells. It is then possible to analyze a large pallet of resulting phenotypes in clusters of transfected cells. We are currently manufacturing cell microarrays with collections of full-length cDNA cloned in expression vectors (gain of function analyses) or siRNA (loss of function studies) to unravel function of genes involved in differentiation and proliferation of human cells. Although there are still some technological difficulties to overcome, the potential for cell microarrays to speed up functional exploration of genomes is very promising

Refilins: A link between perinuclear actin bundle dynamics and mechanosensing signaling

Actin cytoskeleton dynamics lie at the heart of cell mechanosensing signaling. In fibroblast cells, two perinuclear acto-myosin structures, the actin cap and the transmembrane actin-associated nuclear (TAN) line, are components of a physical pathway transducing extracellular physical signals to changes in nuclear shape and movements. We recently demonstrated the existence of a previously uncharacterized third apical perinuclear actin organization in epithelial cells that forms during epithelial–mesenchymal transition (EMT) mediated by TGFβ (TGFβ). A common regulatory mechanism for these different perinuclear actin architectures has emerged with the identification of a novel family of actin bundling proteins, the Refilins. Here we provide updates on some characteristics of Refilin proteins, and we discuss potential function of the Refilins in cell mechanosensing signaling

A statistically inferred microRNA network identifies breast cancer target miR-940 as an actin cytoskeleton regulator

International audienceMiRNAs are key regulators of gene expression. By binding to many genes, they create a complex network of gene co-regulation. Here, using a network-based approach, we identified miRNA hub groups by their close connections and common targets. In one cluster containing three miRNAs, miR-612, miR-661 and miR-940, the annotated functions of the co-regulated genes suggested a role in small GTPase signalling. Although the three members of this cluster targeted the same subset of predicted genes, we showed that their overexpression impacted cell fates differently. miR-661 demonstrated enhanced phosphorylation of myosin II and an increase in cell invasion, indicating a possible oncogenic miRNA. On the contrary, miR-612 and miR-940 inhibit phosphorylation of myosin II and cell invasion. Finally, expression profiling in human breast tissues showed that miR-940 was consistently downregulated in breast cancer tissues M icroRNAs are a class of endogenous, small (19–25 nucleotides), single-stranded non-coding RNAs that regulate gene expression in all eukaryotic organisms. In metazoans, microRNAs most commonly bind to the 39 untranslated region (39UTR) of their mRNA target transcript and cause translational repression and/or mRNA degradation. Every microRNA is predicted to regulate from a dozen to thousands of genes, including transcription factors. This fine-tuning of protein expression is known to be involved in many physiological processes, such as development, apoptosis, signal transduction and even cancer progression 1,2. More than 2,000 mature human microRNAs are listed in the 20 th release of miRBase: http://www.mirbase.org (2014) (Date of access:19/08/2013), and some authors hypothesise that the majority of human genes are regulated by microRNAs 3. Since their discovery in 1993 4 , a fair understanding of their role in animal development and in the onset and progression of diseases 2 , as well as of their potential use in therapies 5 , has been gathered. However, the cooperative behaviour of microRNAs is still under investigation. A growing body of experimental evidence suggests that microRNAs can regulate genes through complementarity, meaning that microRNAs can act together to regulate individual genes or groups of genes involved in similar processes 6. For example, Hu and co-workers demonstrated that transducing a cocktail of precursor microRNAs (miR-21, miR-24 and miR-221) can result in more effective engraftment of transplanted cardiac progenitor cells 7. Consistent with these discoveries, Zhu et al. demonstrated that miR-21 and miR-221 coregulate 56 gene ontology (GO) processes 8. In the same study, the authors also showed that cotransfection of miR-1 and miR-21 increases H 2 O 2-induced myocardial apoptosis and oxidative stress. These recent findings support the idea of microRNA-mediated cooperative regulation but also argue for the use of systemic approaches, notably based on graph theory, to decipher individual and complementary roles of microRNAs. Some work has been conducted to use recent high-throughput experiment-derived data sets to infer microRNA synergistic relationships 9–12. Herein, we present a microRNA network based on target similarities among microRNAs to infer clusters of microRNAs. Clusters are defined as groups of microRNAs sharing a set of common targets, predicted by either DIANA-microT v3 13 or TargetScan v6.2 14. Some authors have used GO enrichment analysis as a confirmatory tool for their clustering approach 11. In our case, GO enrichment is not used to infer networks but as a way to estimate the probable metabolic pathway(s) a cluster of microRNAs could co-regulate. Moreover, the novelty of our approach is to consider not only clusters of microRNAs but also OPE

Study of basal body migration during primary ciliogenesis

Le cil primaire, véritable organite sensoriel cellulaire est présent à la surface de la plupart des cellules de mammifères en quiescence. Truffé de récepteurs à sa membrane, le cil capte les signaux mécaniques et chimiques, jouant ainsi un rôle clé dans de nombreux processus développementaux et physiologiques. Un défaut de structure et/ou de fonction du cil est à l'origine de cancérogénèse et de pathologies humaines appelées ciliopathies.Le cil primaire est ancré à la membrane plasmique grâce au corps basal, structure dérivée du centriole père et connectée aux trois réseaux du cytosquelette. La formation du cil primaire nécessite une succession d'étapes cytoplasmiques hautement régulées. Elle débute par la maturation du centriole père en corps basal. Cette étape nécessite le recrutement de protéines spécifiques au centriole père permettant l'association avec une vésicule ciliaire à l'extrémité distale du centriole père. Ce complexe migre et vient s'ancrer à la membrane apicale déclenchant la nucléation de microtubules pour la formation de la partie externe du cil, ou axonème. En parallèle, la ciliogénèse nécessite un remodelage important du cytosquelette d'actine ainsi qu'un trafic de vésicules orienté vers la base du cil. Si la plupart des étapes sont bien caractérisées, celle concernant la migration du corps basal ainsi que la contribution du cytosquelette reste mal comprise.Afin de mieux appréhender les mécanismes impliqués dans la migration du corps basal lors de la ciliogénèse, nous avons développé un système expérimental basé sur l'utilisation de micro-patrons adhésifs recouverts de fibronectine. Cette technologie comporte de nombreux avantages. Elle permet le contrôle de l'étalement de la cellule inhérent à la surface imposée par la matrice extracellulaire régulant ainsi l'organisation du cytosquelette ainsi que le positionnement des organelles subcellulaires. Par ailleurs, le volume cellulaire induit par le confinement spatial facilite l'observation de la position du centrosome en z au cours du temps, indispensable pour l'étude de chaque étape de la ciliogénèse cytoplasmique.Dans un premier temps, nous avons démontré que la forme et l'architecture du cytosquelette d'actine qui en dépend sont des régulateurs majeurs du processus ciliogénique. Les cellules confinées spatialement et sevrées 24h sur des petits disques développent un réseau branché au niveau de leur surface apicale nécessaire à la croissance du cil primaire. A l'inverse, les cellules étalées sur des grands disques sont beaucoup plus contractées. Elles développent d'importantes fibres de stress sur leur surface ventrale. Le centrosome reste sous le noyau et le niveau de contraction empêche l'assemblage du cil. Le niveau de contractilité module donc la formation du réseau d'actine apicale qui contrôle en retour le mouvement du corps basal et l'élongation du cil.Dans un deuxième temps, nous avons étudié la dynamique du cytosquelette d'actine et de microtubules durant l'étape de migration du corps basal c'est à dire juste après la privation de sérum. Nos résultats indiquent que la migration nécessite une augmentation transitoire de la stabilité des microtubules concomitante avec une augmentation de la contractilité des filaments d'actine. Un crible basé sur l'ARN interférence nous a permis d'identifier des gènes impliqués dans le processus de migration dont CEP164, contribuant à l'ancrage du centriole père à la vésicule ciliaire. Les cellules déficientes en CEP164 montrent un défaut de réorganisation du cytosquelette expliquant l'inhibition du transport du corps basal vers la membrane apicale.L'ensemble des résultats nous permet d'avancer dans la compréhension des conditions requises pour le mouvement du corps basal vers la membrane apicale. Celui-ci nécessite à la fois un remodelage significatif du cytosquelette en constant dialogue et en interaction avec certains composants ciliaires nécessaires à la formation du cil primaire.The primary cilium is a sensory organelle present on the surface of most quiescent cells. It possesses numerous receptors on its surface and is responsible for transducing biochemical and mechanical signals to the interior of the cell and playsimportant roles during development and in homeostasis. Defects in primary cilium assembly are the underlying cause of a group of pleiotropic diseases referred to as ciliopathies.The primary cilium is anchored to the plasma membrane through the basal body which is derived from the mother centriole and is connected to three networks of the cytoskeleton. Primary cilium formation is a highly regulated and multi-step process that begins with the maturation of the centriole mother into basal body in the cytoplasm of the cell. One of the first steps of primary cilium assembly is the recruitment of specific proteins to the mother centriole to initiate the formation of a ciliary vesicle at the distal end of the mother centriole. Once formed, the mother centriole migrates to and is anchored to the apical membrane, triggering the elongation of microtubules from the distal end of the mother centriole to form the outer part of primary cilium, or axoneme. In order for this to occur, significant remodeling of the actin cytoskeleton and directe-trafficking of vesicles to the base of the cilium is required. While much progress has been made in characterizing the initial steps of primary ciliogenesis, how the basal body migrates to the plasma membrane is not fully understood.To gain a better understanding of the mechanisms involved in the migration of basal body during ciliogenesis, we developed an experimental system based on the use of adhesive micro-patterns coated with fibronectin. This technology has many advantages. It enables the control of the cell spreading which is imposed by the size of the adhesive area and, in turn, the regulation of cytoskeletal organization and the positioning of subcellular organelles. Furthermore, this technique enables the cell volume induced by the spatial confinement, to be controlled, facilitating the observation and measurement of the centrosome's position in z throughout the primary ciliogenesis process.First, we demonstrated that the shape and architecture of the actin cytoskeleton are major regulators of primary ciliogenesis. Cells spatially confined and starved for 24h on small discoidal micropattern develop an apical web like actin network necessary for the primary cilium growth. In contrast, cells plated on large discs are much more contracted and they develop significant stress fibers on their ventral surface. In this situation, the centrosome remains below the nucleus and the level of contraction prevents the assembly of a primary cilium. The level of contractility therefore modulates the formation of apical actin network that in turn controls the movement of the basal body and the cilium elongation.Secondly, we studied actin cytoskeleton and microtubule reorganization during the basal body migration step that occured just after serum starvation. Our results indicate that migration requires a transient increase in the stability of microtubules, concomitant with an increase in contractility of actin filaments. By RNA interference screening, we have identified genes involved in the migration process including CEP164, which has previously been shown to participate in the anchoring of the ciliary vesicle to the mother centriole. CEP164-deficient cells were found to have defects in cytoskeletal reorganization thereby explaining why basal body transport to the plasma membrane was blocked in these cells.Altogether, these results enable our understanding of how basal body movement to the apical membrane is driven. This requires both significant remodeling and crosstalk between the actin and microtubule cytoskeleton and interaction with ciliary components necessary for the formation of a primary cilium

Spatial integration of mechanical forces by α-actinin establishes actin network symmetry

International audienceCell and tissue morphogenesis depend on the production and spatial organization of tensional forces in the actin cytoskeleton. Actin network architecture is made of distinct modules characterized by specific filament organizations. The assembly of these modules are well described but their integration in a cellular network is less understood. Here we investigated the mechanism regulating the interplay between network architecture and the geometry of cell's extracellular environment. We found that α-actinin, a filament crosslinker, is essential for network symmetry to be consistent with extracellular microenvironment symmetry. It is required for the interconnection of transverse arcs with radial fibres to ensure an appropriate balance between forces at cell adhesions and across the actin network. Furthermore, this connectivity appeared necessary for the cell ability to integrate and to adapt to complex patterns of extracellular cues as they migrate. Our study has unveiled a role of actin-filament crosslinking in the spatial integration of mechanical forces that ensures the adaptation of intracellular symmetry axes in accordance with the geometry of extracellular cues

Les Langerhanoïdes, des organoïdes d’îlots pancréatiques

International audienceLes îlots de Langerhans isolés de donneurs en état de mort encéphalique constituent actuellement la seule source de cellules pour la transplantation de patients atteints de diabète de type 1. Cette approche thérapeutique reste cependant compromise par la rareté des donneurs et par certains aspects techniques. L’utilisation de sources alternatives de cellules productrices d’insuline est donc un enjeu tant thérapeutique que pour la recherche pharmacologique. Plusieurs équipes dans le monde, dont la nôtre, développent des modèles de culture cellulaire en 3D, les Langerhanoïdes, qui sont physiologiquement proches des îlots pancréatiques humains. Dans cette revue, nous décrivons les récentes avancées mimant la niche pancréatique (matrice extracellulaire, vascularisation, microfluidique), permettant ainsi d’accroître la fonctionnalité de ces Langerhanoïdes

Vascularized pancreatic islet-on-chip for type 1 diabetes

International audienceDiabetes is a growing threat to global health, currently affecting 537 million people worldwide, or 1 in 10 adults. The World Health Organization predicts that 783 million people will suffer from diabetes in 2045. Diabetes, type 1 or 2, cause an abnormal and prolonged increase of the blood glucose level, mainly caused by deficiency or failure to use insulin. In the long term, diabetes can lead to many complications, including vasculopathy, neuropathy, retinopathy, and diabetic foot ulcer. There is a need to understand the mechanisms of action in a human model in order to finely-tune the treatment for each patient. Building in vitro analytical tools is crucial to model the complexity of physiology and pathophysiology of pancreatic islets for a better understanding of its basic biology as well as for the screening of new drugs. While most common perifusion systems require pooling of multiple islets to achieve quantifiable insulin concentrations, minimizing the number of islets required for experiments using microfluidic platforms is important given the scarcity of these biological tissues

Development of an amphicrine pancreas-on-a-chip to study tumor initiation in a diabetic microenvironment

International audienceIn 2021, 537 million of the global adult population worldwide were living with diabetes [1]. Type 2 diabetes, which accounts for more than 95% of diabetes mellitus, is associated with an increased risk of pancreatic ductal adenocarcinoma (PDAC) [2]. PDAC is a destructive disease with an unoptimistic prognosis. It ranks 9 th in the incidence of solid cancers but 4 th for cancerrelated deaths [3]. While several studies described potential molecular links between diabetes mellitus and PDAC, there is a lack of pertinent biological models to better elucidate the molecular mechanisms involved [2]. Three-dimensional cell cultures emerge as more relevant models towards organ-emulating constructs superseding the traditional two-dimensional format. Here, we created a perfusable microtissue-laden device using 3D printing technology to investigate the molecular links between diabetic microenvironment and PDAC initiation. Methods We use a 3D-printed device in which fugitive ink has been extruded to form a pancreatic duct. The duct is lined with a hydrogel from healthy or diabetic origin that also contain islets of Langerhans. The duct-mimicking channel is then filled with human pancreatic epithelial cells either healthy or harboring preneoplastic abnormalities. Results We developed an amphicrine pancreas-on-a-chip model that recapitulate diabetic condition and allow immunostaining labelling in 3D, as confirmed by ELISA quantification of insulin secretion in response to glucose stimulation, and light-sheet microscopy. We have also developed a decellularized extracellular matrix of healthy tissue that allows perfusion and good cell survival, a necessary first step towards the preparation of matrix from diabetic tissue. We maintain the perfused devices over several weeks, enabling the study of tumor initiation over long periods. We will further analyze the link between the diabetic environment and the cell activity (proliferation, migration) in cells harboring preneoplastic abnormalities (such as genetic mutations, inflammatory/hyperglycemia exposition) to study the link between cells abnormalities in diabetic patients and the risk for development of pancreatic cancer. Conclusion and significance Our approach allows the fabrication of semi-automatized and standardized devices that can be used for multiple organ models. The advantages of hydrogel-based devices are the possibility of cell self-arrangement in the relatively large bulk of hydrogel. The self-organized cells will then synthesize their own extracellular matrix, and will mature over time. The results are promising to generate glucose-responsive, functional Langerhans islet-based device for a breakthrough research in the early stages of pancreatic adenocarcinoma in diabetic patients, to identify new early diagnostic biomarkers