Role of the collagen receptor DDR1 in epithelial morphogenesis and polarisation

Sogaard, Pia Pernille

January 2017

During development of epithelial organs, epithelial cells collectively migrate and invade into their surroundings to form complex 3D structures, such as the tubular ducts and alveoli of the mammary gland. A prerequisite for coordinating such collective movement is apicobasal cell polarity. This polarity divides the plasma membrane of epithelial cells into an apical domain towards the lumen of structures and a basal domain facing the matrix. Polarity is essential for the functionality of epithelial tissues and signals from the surrounding matrix are known to participate in its establishment. In contrast, loss of polarity has been associated with progression of diseases such as cancer. During epithelial tubulogenesis, the pro-invasive enzyme MT1-MMP is regulated according to apicobasal polarity. This regulation is essential for tubulogenesis to occur and restricts MT1-MMP activity to the tip of protruding tubules by ensuring that the enzyme only localises to the basal, matrix-abutting cell surface in this location. Signals from fibrillar collagen I contribute to regulating the polarised distribution of MT1-MMP. How such signals are transmitted and influence polarised trafficking is however not understood. In this study, I found that inhibition of the collagen receptor DDR1 disturbed the apicobasal distribution of MT1-MMP in MDCK cells. In 3D environments, DDR1 inhibition blocked MT1-MMP-dependent tubulogenesis of epithelial cells, which instead formed compact, multi-layered aggregates. Furthermore, polarisation of the epithelial cell membrane into an apical and a basal domain failed in absence of DDR1 signalling, suggesting that DDR1 affects establishment of epithelial polarity. In support of this, the effects of DDR1 signalling on apicobasal polarity were not limited to MT1-MMP- dependent morphogenesis, but also proved essential for polarisation of cells during 3D morphogenesis that did not require ECM degradation. An investigation of signalling downstream of DDR1 in establishment of apicobasal polarity revealed this to involve modulation of cytoskeletal tension. Inhibition of DDR1 in 2D culture of MDCK cells thus increased ROCK-dependent phosphorylation of MLC along cell-cell junctions, suggesting that DDR1 can suppress ROCK activity. Importantly, the ROCK-suppressing function of DDR1 contributed to establishment of polarity in MDCK cells in 3D matrices, where inhibition of ROCK activity rescued the formation of polarised cysts in absence of DDR1 signalling. The role of DDR1 in epithelial organisation was reflected in the epithelium of the mammary gland of lactating DDR1-null mice, which had smaller alveoli with a diffuse distribution of basement membrane components compared to wild type mice. Furthermore, DDR1 inhibition attenuated formation of milk-producing mammospheres during lactogenic differentiation of mammary epithelial cells in vitro in a ROCK- dependent manner. This suggests that the ROCK-suppressing function of DDR1 observed in MDCK cells is important for morphogenesis of other epithelial cell types as well. Overall, this study suggests that DDR1 signalling contributes to epithelial polarisation and morphogenesis in a manner involving regulation of cytoskeletal organisation, at least partly through regulation of ROCK activity.

Cellular Mechanisms Regulating Single Lumen Formation in the Zebrafish Gut

Lento, Ashley Alvers

January 2014

<p>The formation of a single lumen during tubulogenesis is crucial for the development and function of many organs. Although 3D cell culture models have identified molecular mechanisms controlling lumen formation in vitro, their function during vertebrate organogenesis is poorly understood. In this work we used the zebrafish gut as a model to investigate single lumen formation during tubulogenesis. Previous work has shown that multiple small lumens enlarge through fluid accumulation and coalesce into a single lumen. However, since lumen formation occurs in the absence of apoptosis, other cellular processes are necessary to facilitate single lumen formation. </p><p>Using light sheet microscopy and genetic approaches we identified a distinct intermediate stage in lumen formation, characterized by two adjacent un-fused lumens. These lumens are separated by cell contacts that contain basolateral adhesion proteins. We observed that lumens arise independently from each other along the length of the gut and do not share a continuous apical surface. Resolution of this intermediate phenotype into a single, continuous lumen requires the remodeling of basolateral contacts between adjacent lumens and subsequent lumen fusion. </p><p>Furthermore, we provide insight into the genetic mechanisms regulating lumen formation through the analysis of the Hedgehog pathway. We show that lumen resolution, but not lumen opening, is impaired in <italic>smoothened (smo)</italic> mutants, indicating that fluid-driven lumen enlargement and resolution are two distinct processes. We also show that <italic>smo</italic> mutants exhibit perturbations in the Rab11 trafficking pathway, which led us to demonstrate that Rab11-mediated recycling, but not degradation, is necessary for single lumen formation. Taken together, this work demonstrates that lumen resolution is a distinct genetically-controlled process, requiring cellular rearrangement and lumen fusion events, to create a single, continuous lumen in the zebrafish gut.</p> / Dissertation

Cellular biology

Gut

Lumen

smoothened

Tubulogenesis

zebrafish

A starPEG-heparin hydrogel model of renal tubulogenesis

Weber, Heather

29 May 2017

Currently, the only treatment for end stage renal disease is dialysis or kidney transplantation. These methods contain obvious limitations such as the palliative nature of dialysis treatment and the lack of available organs for transplantation. As a result, there is a dire unmet need for alternative options. Regenerative therapies that focus on stimulating the regrowth of injured tissue can be a promising alternative. A critical step in the development of such therapeutic remedies is obtaining robust models that mimic the complex nature of the human kidney. The proximal tubules are a particular region of interest due to their important role in reabsorption and secretion of the glomerular filtrate and the blood, making them particularly susceptible to nephrotoxicity and renal pathologies. For this reason, the goal of this thesis was to engineer a 3D model of human proximal tubulogenesis that would allow for both developmental and regenerative studies. The ideal assay would mimic the human 3D structure and function of proximal tubules in a tunable, robust matrix that can be easily analyzed in throughput screenings for regenerative medicine and toxicity applications. In this thesis, we show the development, characterization, and application of an in vitro human renal tubulogenesis model using a modular and tunable biohybrid starPEG-heparin hydrogel platform. A range of hydrogel mechanics and compositions were systematically tested to determine the optimal conditions for renal tubulogenesis. The results revealed that only soft hydrogels based on heparin and matrix metalloproteinase (MMP) enzymatically cleavable crosslinkers led to the generation of polarized tubule structures. The generated tubules display polarization markers, extracellular matrix components, and organic anion transport functions which mimic the human renal proximal tubule. To the best of our knowledge, this is the first system where human renal tubulogenesis can be monitored ex vivo from single cells to physiologically sized tubule structures in a 3D tunable matrix. Moreover, it was found that heparin played a role in the polarization of proximal tubule cells in the hydrogel culture. The established starPEG-MMP-heparin based hydrogel model was then tested for its application as a renal tubulogenesis model by the addition of pro and anti-tubulogenic factors. It was found that the addition of growth factors and MMP inhibitors could promote and inhibit tubulogenesis, respectively. This model can be used to modulate tubulogenesis by adjusting the mechanical properties of the hydrogel, growth factor signaling, and the presence of insoluble cues (such as adhesion peptides), potentially providing new insights for regenerative therapy. To examine if the established hydrogel-based renal tubulogenesis model could be applied as a drug toxicity platform, the nephrotoxic, chemotherapeutic drug, cisplatin was incubated with the renal tubule model. The tubular structures showed a dose-dependent drug response resembling the human clinical renal pathology. The injured tubular structures also expressed the early in vivo proximal tubule injury biomarker, kidney injury molecule-1 (KIM-1). In conclusion, a hydrogel-based renal tubulogenesis model was successfully developed, characterized, and applied as a nephrotoxicity assay. Our findings suggest that the established hydrogel-based model can additionally be used for personalized medicine, where a patient’s predisposition to drug-induced renal injury or specific renal regenerative medicine treatments could be examined. This platform provides a novel approach to study human nephrotoxicity and renal regenerative medicine ex vivo, limiting the need for animal models, and potentially paving the way for more reliable preclinical trials.

renal tubulogenesis

Hydrogele

ddc:540

rvk:WW 7001

The Rab5 GTPase is required for lumen formation in the embryonic Drosophila heart

Perry, Katie L.

January 2019

Tube formation, or tubulogenesis, is an elaborate form of epithelial morphogenesis that includes processes such as cell migration and cell shape changes. The embryonic Drosophila heart, or dorsal vessel, is an excellent model of tubulogenesis and more specifically the signaling mechanisms required for cell migration and lumen formation. Similar to vertebrate heart formation, Drosophila heart tubulogenesis begins with the collective migration of cardioblasts that meet at the midline and adhere at specialised junctions, enclosing a lumen between them. Roundabout, and its ligand Slit, are required to restrict cell-to-cell adhesions to the junctional domains of contralateral cardioblasts, as well as maintain the integrity of the lumen. The localisation patterns of Robo, and other luminal cell surface receptors important for lumen formation are significantly modified throughout heart formation. Initial receptor expression is broadly distributed over the cardioblast surface. Receptors are then relocalised to specific cell surface domains by late embryonic development. The mechanisms by which Robo and other cell surface receptors are localised have yet to be determined. Endocytosis is a promising mechanism by which cell surface receptors are targeted and trafficked to cell surface domains. Specifically, vesicular trafficking proteins, such as Rab GTPases, are molecular switches that regulate endocytic events. Here, we investigated the roles of Rab5, Rab11, and Sec6 during heart formation. Of these, only Rab5, a regulator of the early endosome, was required for lumen formation. Particularly, gain of function, loss of function, and overexpression of rab5 resulted in reduced lumen phenotype, characterised by lumen pockets rather than a continuous lumen along the anterior-posterior axis. Perturbed Rab5 function also resulted in the mislocalisation of Robo at the basal domain. Live imaging showed that expression of rab5 dominant negative, constitutively active, and overexpression constructs did not perturb apical membrane motility of migrating cardioblasts in the developing heart. / Thesis / Master of Science (MSc)

tubulogenesis

Drosophila heart formation

endocytosis

Rab GTPases

A starPEG-heparin hydrogel model of renal tubulogenesis

Weber, Heather

06 March 2017

Currently, the only treatment for end stage renal disease is dialysis or kidney transplantation. These methods contain obvious limitations such as the palliative nature of dialysis treatment and the lack of available organs for transplantation. As a result, there is a dire unmet need for alternative options. Regenerative therapies that focus on stimulating the regrowth of injured tissue can be a promising alternative. A critical step in the development of such therapeutic remedies is obtaining robust models that mimic the complex nature of the human kidney. The proximal tubules are a particular region of interest due to their important role in reabsorption and secretion of the glomerular filtrate and the blood, making them particularly susceptible to nephrotoxicity and renal pathologies. For this reason, the goal of this thesis was to engineer a 3D model of human proximal tubulogenesis that would allow for both developmental and regenerative studies. The ideal assay would mimic the human 3D structure and function of proximal tubules in a tunable, robust matrix that can be easily analyzed in throughput screenings for regenerative medicine and toxicity applications. In this thesis, we show the development, characterization, and application of an in vitro human renal tubulogenesis model using a modular and tunable biohybrid starPEG-heparin hydrogel platform. A range of hydrogel mechanics and compositions were systematically tested to determine the optimal conditions for renal tubulogenesis. The results revealed that only soft hydrogels based on heparin and matrix metalloproteinase (MMP) enzymatically cleavable crosslinkers led to the generation of polarized tubule structures. The generated tubules display polarization markers, extracellular matrix components, and organic anion transport functions which mimic the human renal proximal tubule. To the best of our knowledge, this is the first system where human renal tubulogenesis can be monitored ex vivo from single cells to physiologically sized tubule structures in a 3D tunable matrix. Moreover, it was found that heparin played a role in the polarization of proximal tubule cells in the hydrogel culture. The established starPEG-MMP-heparin based hydrogel model was then tested for its application as a renal tubulogenesis model by the addition of pro and anti-tubulogenic factors. It was found that the addition of growth factors and MMP inhibitors could promote and inhibit tubulogenesis, respectively. This model can be used to modulate tubulogenesis by adjusting the mechanical properties of the hydrogel, growth factor signaling, and the presence of insoluble cues (such as adhesion peptides), potentially providing new insights for regenerative therapy. To examine if the established hydrogel-based renal tubulogenesis model could be applied as a drug toxicity platform, the nephrotoxic, chemotherapeutic drug, cisplatin was incubated with the renal tubule model. The tubular structures showed a dose-dependent drug response resembling the human clinical renal pathology. The injured tubular structures also expressed the early in vivo proximal tubule injury biomarker, kidney injury molecule-1 (KIM-1). In conclusion, a hydrogel-based renal tubulogenesis model was successfully developed, characterized, and applied as a nephrotoxicity assay. Our findings suggest that the established hydrogel-based model can additionally be used for personalized medicine, where a patient’s predisposition to drug-induced renal injury or specific renal regenerative medicine treatments could be examined. This platform provides a novel approach to study human nephrotoxicity and renal regenerative medicine ex vivo, limiting the need for animal models, and potentially paving the way for more reliable preclinical trials.

info:eu-repo/classification/ddc/540

ddc:540

renal tubulogenesis

Hydrogele

αPS3βPS1 integrin and its adaptor Talin are essential for Drosophila embryonic heart tubulogenesis

Vanderploeg, Jessica

January 2014

Formation of a tubular organ, such as the heart, requires cells to integrate positional and polarity signals in order to enclose a fluid or gas transporting lumen. Developing tubes must establish a site for lumen initiation, demarcate membrane domains, and modulate cell polarization and morphology. The Drosophila melanogaster embryonic heart is a mesodermal tube model displaying a unique polarity, reminiscent of vertebrate vasculature. We have characterized a role for the transmembrane adhesion receptor αPS3βPS1 integrin and its cytoplasmic adaptor Talin in heart tubulogenesis. βPS1 and Talin are early indicators of the luminal site and Talin-mediated integrin function is essential for cardioblast polarization and morphology prior to and during lumen development. Careful analysis of hearts in embryos homozygous for a null allele of rhea, the gene encoding Talin, reveals that Talin is required to correctly orient the heart cell polarity such that a continuous central open lumen is enclosed. Without proper integrin or Talin function, the luminal determinants Slit and its receptor Robo are not stabilized within the heart, a central lumen fails to form, and the midline is instead marked by continuous adhesion. Furthermore, although Talin is essential for proper βPS1 integrin localization within the heart, either of Talin’s two integrin binding sites are sufficient to stabilize βPS1 along the luminal domain and establish an open cardiac tube. Taken together, our findings reveal an instructive role for integrins and Talin in communicating polarization cues central to heart tubulogenesis. / Thesis / Doctor of Philosophy (PhD)

Drosophila

heart

integrin

tubulogenesis

Talin

cell polarity

lumen

Estudo da adesão, sobrevivência e tubulogênese endotelial em modelo de células de glioma silenciadas para a expressão de Tenascina-C / Study of endothelial adhesion, survival and tubulogenesis in model of glioma cells silenced for Tenascin-c expression

Laila Ribeiro Fernandes

14 August 2013

Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / Recentemente, nosso grupo demonstrou que a matriz extracelular de astrocitomas promove a seleçãode células endoteliais altamente proliferativas, porém com reduzida capacidade tubulogênica, além de determinar a morte de uma segunda sub-população endotelial, por desaderência ou anoikis. Estratégias de simulação dos teores de tenascina-C (TN-C) e fibronectina (FN) nas matrizes de astrocitomas, realizados com ambas as proteínas purificadas na forma de substratos definidos, sugeriram que o balanço TN-C:FN estava relacionado com os fenótipos endoteliais observados. No entanto, este procedimento não permitia abordar a participação de outros componentes da matriz tumoral nativa neste processo. Com objetivo de estudar a modulação do fenótipo angiogênico das células endoteliais por matrizes de astrocitoma, realizamos o silenciamento da expressão de TN-C na linhagem de astrocitoma U-373 MG. O silenciamento foi confirmado por western blotting, PCR em tempo real e ELISA, que permitiram concluir que, no período pós-transfecção (120h) necessário para se obter matrizes tumorais nativas para ensaios funcionais com células endoteliais, as células U-373 MG mantiveram-se silenciadas em índices superiores a 90%. A diminuição de TN-C nas matrizes tumorais resultou em um pequeno (&#8773;18%, em média), porém significativo aumento na taxa de adesão endotelial. HUVECs incubadas com a matriz secretadas por células silenciadas apresentaram uma redução de &#8773;35% do número de núcleos picnóticos, quando comparadas a HUVECs incubadas com a matriz de células U-373 MG (selvagens ou transfectadas com siRNA controle). O silenciamento da expressão da TN-C na matriz nas células U-373 MG restaurou ainda o defeito tubulogênico das células endoteliais, que passaram a apresentar formação de tubos comparável à obtida quando HUVECs foram incubadas com sua matriz autóloga, rica em FN. Tais resultados apoiam observações anteriores do grupo, que já sugeriam que a maior proporção de FN na matriz autóloga, comparada a matriz do astrocitoma, seria o fator principal para a seleção dos fenótipos angiogênicos observados, demonstrando mais uma vez a importância do balanço FN:TN-C na regulação de processos angiogênicos. Dados anteriores sugeriam ainda que a sub-população endotelial que morre por anoikisapós contato prolongado (24 horas) com matrizes de astrocitomas corresponde a células que já haviam entrado na fase S do ciclo celular, no início da incubação. A fim de nos aprofundarmos sobre a participação do ciclo celular neste processo, a expressão da proteína p27, um inibidor de quinases dependentes de ciclinas (CKI), também foi analisada. HUVECs incubadas com a matriz de astrocitoma apresentaram um aumento de 2 a 3 vezes na expressão de p27, quando comparada com HUVECs provenientes de sua matriz autóloga. No entanto, células endoteliais incubadas com matriz secretada por células U-373 MG silenciadas apresentaram um nível de expressão de p27 comparável ao das HUVECs incubadas com matriz secretada por células selvagens, indicando que a expressão de TN-C não modula, ou não está diretamente correlacionada à expressão da proteína p27. Este resultado sugere que outros componentes da matriz tumoral devam estar envolvidos na modulação do ciclo celular endotelial. / We have previously shown that extracellular matrices secreted by high-grade astrocitoma promotes the selection of highly proliferative and tubulogenesis-defective endothelial cells, while also leading to the death, by anoikis, of another endothelial subpopulation. The use of defined adhesion substrata containing various levels of tenascin-C (TN-C) and fibronectin (FN) allowed us to confirm that the balance between TN-C and FN was a major cause of the selection of both endothelial phenotypes. However, this strategy did not allow us to address the potential role of other molecular components present in tumor matrices. In the present work, we studied the effect of a matrix produced by U-373 MG cells previously silenced for TN-C expression in endothelial cell adhesion, survival and tubulogenic differentiation, as compared to the matrix secreted by wild-type astrocitoma cells. U-373 MG cells silencing was confirmed by Western blotting, real time RT-PCR and ELISA, and cells remained silenced (&#8805; 90 %) throughout the 120 hours period necessary for generating immobilized native matrices required for endothelial cell function assays. Human umbilical vein endothelial cells (HUVECs) adhesion to the extracellular matrix secreted by astrocitoma cells silenced for TN-C expression was significantly increased by &#8773;18 %, as compared to wild-type tumor matrix. The number of HUVECs exhibiting picnotic nuclei a hallmark of advanced apoptosis has also been significantly decreased by &#8773;35 %, when endothelial cells were allowed to incubate with TN-C-depleted tumor matrix, as compared to the wild-type tumor matrix. Concerning angiogenic differentiation, endothelial cells incubated with the matrix produced by silenced U-373 cells were strongly attenuated for their tubulogenesis defect, as compared to HUVECs incubated with the TN-C-rich wild-type matrix. Thus, these data corroborated our previous observations that TN-C in astrocitoma matrices crucially interferes with endothelial cell differentiation. Besides adhesion, survival and tubulogenic differentiation, the responses of endothelial cells to astrocitomas matrices are also affected by cell cycle transitions. We have previously shown that endothelial cells undergoing anoikis had already transitioned through the S-phase of cell cycle at the moment of seeding. Thus, we decided to investigate the expression of p27 protein, an inhibitor of ciclin-dependent kinases (CKI) that has been already implicated in glioma angiogenesis. We found that HUVECs incubated with the matrix secreted by U-373 MG wild-type cells for 24 hours exbibited a 2 to 3-fold increase in p27 expression. In contrast to the other results discussed herein, these differences were not correlated with the expression of TN-C by U-373 MG cells, since the matrix produced by tumor cells silenced for TN-C did not alter the expression of p27 in endothelial cells. Overall, the present data suggest that, although TN-C in native tumor matrix does play a major role in endothelial cell angiogenic differentiation, other matrix components may act in concert with TN-C to modulate endothelial cell proliferation in tumor contexts.

Angiogênese

Tenascina-C

Tubulogênese

Adesão

Anoikis

Glioma

Angiogenesis

Tenascin-C

Tubulogenesis

Adhesion

Anoikis

Glioma

MORFOLOGIA

Defining lineage potential and fate behaviour of progenitors during pancreas development

Sznurkowska, Magdalena Katarzyna

January 2018

No description available.

Estudo da adesão, sobrevivência e tubulogênese endotelial em modelo de células de glioma silenciadas para a expressão de Tenascina-C / Study of endothelial adhesion, survival and tubulogenesis in model of glioma cells silenced for Tenascin-c expression

Laila Ribeiro Fernandes

14 August 2013

Fundação de Amparo à Pesquisa do Estado do Rio de Janeiro / Recentemente, nosso grupo demonstrou que a matriz extracelular de astrocitomas promove a seleçãode células endoteliais altamente proliferativas, porém com reduzida capacidade tubulogênica, além de determinar a morte de uma segunda sub-população endotelial, por desaderência ou anoikis. Estratégias de simulação dos teores de tenascina-C (TN-C) e fibronectina (FN) nas matrizes de astrocitomas, realizados com ambas as proteínas purificadas na forma de substratos definidos, sugeriram que o balanço TN-C:FN estava relacionado com os fenótipos endoteliais observados. No entanto, este procedimento não permitia abordar a participação de outros componentes da matriz tumoral nativa neste processo. Com objetivo de estudar a modulação do fenótipo angiogênico das células endoteliais por matrizes de astrocitoma, realizamos o silenciamento da expressão de TN-C na linhagem de astrocitoma U-373 MG. O silenciamento foi confirmado por western blotting, PCR em tempo real e ELISA, que permitiram concluir que, no período pós-transfecção (120h) necessário para se obter matrizes tumorais nativas para ensaios funcionais com células endoteliais, as células U-373 MG mantiveram-se silenciadas em índices superiores a 90%. A diminuição de TN-C nas matrizes tumorais resultou em um pequeno (&#8773;18%, em média), porém significativo aumento na taxa de adesão endotelial. HUVECs incubadas com a matriz secretadas por células silenciadas apresentaram uma redução de &#8773;35% do número de núcleos picnóticos, quando comparadas a HUVECs incubadas com a matriz de células U-373 MG (selvagens ou transfectadas com siRNA controle). O silenciamento da expressão da TN-C na matriz nas células U-373 MG restaurou ainda o defeito tubulogênico das células endoteliais, que passaram a apresentar formação de tubos comparável à obtida quando HUVECs foram incubadas com sua matriz autóloga, rica em FN. Tais resultados apoiam observações anteriores do grupo, que já sugeriam que a maior proporção de FN na matriz autóloga, comparada a matriz do astrocitoma, seria o fator principal para a seleção dos fenótipos angiogênicos observados, demonstrando mais uma vez a importância do balanço FN:TN-C na regulação de processos angiogênicos. Dados anteriores sugeriam ainda que a sub-população endotelial que morre por anoikisapós contato prolongado (24 horas) com matrizes de astrocitomas corresponde a células que já haviam entrado na fase S do ciclo celular, no início da incubação. A fim de nos aprofundarmos sobre a participação do ciclo celular neste processo, a expressão da proteína p27, um inibidor de quinases dependentes de ciclinas (CKI), também foi analisada. HUVECs incubadas com a matriz de astrocitoma apresentaram um aumento de 2 a 3 vezes na expressão de p27, quando comparada com HUVECs provenientes de sua matriz autóloga. No entanto, células endoteliais incubadas com matriz secretada por células U-373 MG silenciadas apresentaram um nível de expressão de p27 comparável ao das HUVECs incubadas com matriz secretada por células selvagens, indicando que a expressão de TN-C não modula, ou não está diretamente correlacionada à expressão da proteína p27. Este resultado sugere que outros componentes da matriz tumoral devam estar envolvidos na modulação do ciclo celular endotelial. / We have previously shown that extracellular matrices secreted by high-grade astrocitoma promotes the selection of highly proliferative and tubulogenesis-defective endothelial cells, while also leading to the death, by anoikis, of another endothelial subpopulation. The use of defined adhesion substrata containing various levels of tenascin-C (TN-C) and fibronectin (FN) allowed us to confirm that the balance between TN-C and FN was a major cause of the selection of both endothelial phenotypes. However, this strategy did not allow us to address the potential role of other molecular components present in tumor matrices. In the present work, we studied the effect of a matrix produced by U-373 MG cells previously silenced for TN-C expression in endothelial cell adhesion, survival and tubulogenic differentiation, as compared to the matrix secreted by wild-type astrocitoma cells. U-373 MG cells silencing was confirmed by Western blotting, real time RT-PCR and ELISA, and cells remained silenced (&#8805; 90 %) throughout the 120 hours period necessary for generating immobilized native matrices required for endothelial cell function assays. Human umbilical vein endothelial cells (HUVECs) adhesion to the extracellular matrix secreted by astrocitoma cells silenced for TN-C expression was significantly increased by &#8773;18 %, as compared to wild-type tumor matrix. The number of HUVECs exhibiting picnotic nuclei a hallmark of advanced apoptosis has also been significantly decreased by &#8773;35 %, when endothelial cells were allowed to incubate with TN-C-depleted tumor matrix, as compared to the wild-type tumor matrix. Concerning angiogenic differentiation, endothelial cells incubated with the matrix produced by silenced U-373 cells were strongly attenuated for their tubulogenesis defect, as compared to HUVECs incubated with the TN-C-rich wild-type matrix. Thus, these data corroborated our previous observations that TN-C in astrocitoma matrices crucially interferes with endothelial cell differentiation. Besides adhesion, survival and tubulogenic differentiation, the responses of endothelial cells to astrocitomas matrices are also affected by cell cycle transitions. We have previously shown that endothelial cells undergoing anoikis had already transitioned through the S-phase of cell cycle at the moment of seeding. Thus, we decided to investigate the expression of p27 protein, an inhibitor of ciclin-dependent kinases (CKI) that has been already implicated in glioma angiogenesis. We found that HUVECs incubated with the matrix secreted by U-373 MG wild-type cells for 24 hours exbibited a 2 to 3-fold increase in p27 expression. In contrast to the other results discussed herein, these differences were not correlated with the expression of TN-C by U-373 MG cells, since the matrix produced by tumor cells silenced for TN-C did not alter the expression of p27 in endothelial cells. Overall, the present data suggest that, although TN-C in native tumor matrix does play a major role in endothelial cell angiogenic differentiation, other matrix components may act in concert with TN-C to modulate endothelial cell proliferation in tumor contexts.

Angiogênese

Tenascina-C

Tubulogênese

Adesão

Anoikis

Glioma

Angiogenesis

Tenascin-C

Tubulogenesis

Adhesion

Anoikis

Glioma

MORFOLOGIA

Role of MKS1 in epithelial homeostasis / Rôle de MKS1 dans l'homéostasie épithéliale

Song, Yuxiang

16 November 2018

Les mutations MKS1 sont impliquées dans un groupe de ciliopathies récessives létales, telles que le syndrome de Meckel-Gruber (MKS) et le syndrome de Joubert (JBT), caractérisées par une dysplasie rénale kystique, des anomalies du système nerveux central (encéphalocèle occipitale), une polydactylie, une dysgénésie biliaire et une fibrose hépatique. MKS1 a été localisée dans la zone de transition du cil dans de nombreux types cellulaires où elle joue un rôle essentiel pour la structure et la fonction des cils, en particulier la régulation de plusieurs voies de signalisation telles que Wnt et Shh.Dans le présent travail, nous avons identifié la fonction pré-ciliaire de MKS1 dans des cellules épithéliales. Nous avons montré que la localisation subcellulaire de MKS1 varie au cours de la maturation de l’épithelium, passant du cytosol où MKS1 co-localise avec le réseau de kératine, aux jonctions cellulaires, où elle co-colocalise avec les caténines. De plus, la translocation de MKS1 des jonctions au cytosol s'est avérée être mécano-sensible, suggérant que MKS1 participe à l'homéostasie épithéliale en stabilisant les jonctions cellulaires, via la transduction des signaux mécaniques liés à la compaction de l’épithelium.L’analyse fonctionnelle a démontré que le « knockdown » de MKS1 désorganise le réseau de kératine, et déstabilise les jonctions adhérentes des cellules épithéliales en culture, avec une diminution de la β-caténine jonctionnelle et une libération de l’E-cadhérine, l’α-caténine et la vinculine dans le cytosol. De plus, la déplétion de MKS1 entraîne une diminution notable du réseau apical d’actine, ainsi que la désorganisation de la structure épithéliale et une transition partielle vers un état mésenchymateux. Ces résultats illustrent une fonction indépendante du cil de MKS1 dans l’homéostasie épithéliale, et apporte de nouvelles hypothèses quant à son rôle et celui des filaments intermédiaires dans les processus d’organogenèse des épitheliums, en particulier la tubulogenèse, qui repose à la fois sur l’équilibre de la transition épithelium/mesenchyme et la mécanotransduction des sollicitations mécaniques durant l’embryogenèseDans le but de caractériser les partenaires de MKS1, des expériences de Co-IP et d’analyses protéomiques ont permis d’identifier l’epiplakine comme un partenaire possible de MKS1. L'Epiplakine est un cytolinker capable de lier la kératine à la membrane et à l'actine ; l’interaction de MKS1 avec l’epiplakine pourrait ainsi rendre compte de la stabilisation à la fois du réseau de kératine et des jonctions cellulaires. Des analyses complémentaires de protéomique et des études fonctionnelles devront compléter ces résultats préliminaires.Finalement, ces travaux ont également permis de révéler le rôle de MKS1 dans la stabilisation des jonctions communicantes ; la déplétion de MKS1 conduisant à une diminution de la CX43 jonctionnelle et à une altération de la fonction de communication intercellulaire dans les cellules épithéliales en culture. Ces travaux, qui constituent la première mention d’une altération possible des jonctions communicantes dans ce type de maladies, devront être approfondis pour caractériser leur impact dans les processus de tubulogenèse.En conclusion, ce travail qui a permis de révéler un rôle pré-ciliaire de MKS1 dans l'homéostasie épithéliale, apporte de nouvelles hypothèses pour l’étiologie de ces maladies, jusqu’alors considérées comme essentiellement consécutives à des défauts de transduction de la signalisation ciliaire. Il propose également de nouveaux mécanismes pour rendre compte des anomalies du développement hépatique, telles que la dysgénésie des voies biliaires, et plus largement des processus de tubulogenèse impliqués dans le développement de nombreux organes. / MKS1 mutations are involved in a group of lethal recessive ciliopathies, such as Meckel-Gruber syndrome (MKS) and Joubert's syndrome (JBT), characterized by cystic renal dysplasia, central nervous system abnormalities (occipital encephalocele) , polydactyly, biliary dysgenesis and hepatic fibrosis. MKS1 has been located in the transition zone of the cilia in many cell types where it plays an essential role in the cilia structure and function, in particular in the regulation of signaling pathways such as Wnt and Shh.In the present work, we have identified the preciliary function of MKS1 in epithelial cells. We have shown that the subcellular localization of MKS1 varies during the maturation of the epithelium, from the cytosol where MKS1 co-localizes with the keratin network, to the cell junctions, where it co-localizes with the catenins. In addition, the MKS1 translocation to cytosol junctions proved to be mechano-sensitive, suggesting that MKS1 participates in epithelial homeostasis by stabilizing cell junctions, via the transduction of mechanical signals related to epithelial compaction.Functional analysis has shown that the knockdown of MKS1 disrupts the keratin network, and destabilizes the adherent junctions of epithelial cells in culture, with a decrease in the junctional β-catenin and a release of E-cadherin, the α-catenin and vinculin in the cytosol. In addition, the depletion of MKS1 results in a significant decrease in the apical actin network, as well as disorganization of the epithelial structure and a partial transition to a mesenchymal state. These results illustrate a ciliary-independent function of MKS1 in epithelial homeostasis, and provides new hypotheses regarding its role and that of intermediate filaments in epithelial organogenesis processes, in particular tubulogenesis, which is based both on the equilibrium of the epithelium / mesenchyme transition and the mechanotransduction of mechanical stresses during embryogenesisIn order to characterize MKS1 partners, Co-IP experiments and proteomic analyzes have identified epiplakin as a possible MKS1 partner. Epiplakin is a cytolinker capable of binding keratin to membrane and actin; the interaction of MKS1 with epiplakin could thus account for the stabilization of both the keratin network and cell junctions. Additional proteomic analyzes and functional studies will complement these preliminary results.Finally, this work has also revealed the role of MKS1 in the stabilization of gap junctions; the depletion of MKS1 leading to a decrease in the junctional CX43 and an alteration of the intercellular communication function in the epithelial cells in culture. This work, which constitutes the first mention of a possible alteration of gap junctions in this type of disease, will have to be further developed to characterize their impact on tubulogenesis processes.In conclusion, this work which revealed a pre-ciliary role of MKS1 in epithelial homeostasis, provides new hypotheses for the etiology of ciliopathies, previously considered as essentially consecutive to signal transduction defects. It also proposes new mechanisms to account for abnormalities of hepatic development, such as bile ducts dysgenesis, and more broadly tubulogenesis processes involved in the development of many organs.

Ciliopathie

Mks1

Polarité

Jonction cellulaire

Kératine

Tubulogenèse

Ciliopathy

Mks1

Polarity

Cell junction

Keratin

Tubulogenesis