The long-term survival of in vitro engineered nervous tissue derived from the specific neural differentiation of mouse embryonic stem cells.

Embryonic stem cells (ESCs) offer attractive prospective as potential source of neurons for cell replacement therapy in human neurodegenerative diseases. Besides, ESCs neural differentiation enables in vitro tissue engineering for fundamental research and drug discovery aimed at the nervous system. We have established stable and long-term three-dimensional (3D) culture conditions which can be used to model long latency and complex neurodegenerative diseases. Mouse ESCs-derived neural progenitor cells generated by MS5 stromal cells induction, result in strictly neural 3D cultures of about 120-mum thick, whose cells expressed mature neuronal, astrocytes and myelin markers. Neurons were from the glutamatergic and gabaergic lineages. This nervous tissue was spatially organized in specific layers resembling brain sub-ependymal (SE) nervous tissue, and was maintained in vitro for at least 3.5 months with great stability. Electron microscopy showed the presence of mature synapses and myelinated axons, suggesting functional maturation. Electrophysiological activity revealed biological signals involving action potential propagation along neuronal fibres and synaptic-like release of neurotransmitters. The rapid development and stabilization of this 3D cultures model result in an abundant and long-lasting production that is compatible with multiple and productive investigations for neurodegenerative diseases modeling, drug and toxicology screening, stress and aging research.

The role of the c-myc gene in pigment cell development and homeostasis

Résumé La dérégulation de c-Myc est un événement fréquent de la transformation cellulaire. Une régulation positive de cette oncoprotéine a été démontrée dans divers mélanomes cutanés primaires et métastatiques et est associée à un pronostic défavorable (Grover et al., 1996; Zhuang et al., 2008). c-Myc est considéré comme une molécule centrale impliquée dans plusieurs processus de l'homéostasie cellulaire. En raison de sa contribution importante dans la progression tumorale, la fonction de c-Myc a été étudiée intensément. Cependant nous connaissons peu le rôle de ce facteur de transcription dans l'embryogenèse et dans la spécification tissulaire. Un déficit total de c-Myc pendant l'embryogenèse conduit à la mort embryonnaire avant 10.5 jours de gestation. Cette mort est causée par de multiples imperfections du développement touchant la taille de l'embryon, le coeur, le péricarde, le tube neural et les cellules sanguines (Davis et al., 1993; Trumpp et al., 2001). Récemment, il a été montré que la plupart de ces anomalies sont secondaires et résultent d'une insuffisance du placenta dans les embryons c-myc-/- (Dubois et al., 2008). Sachant que c-Myc est important dans la maintenance des lignées de la crête neurale (Wei et al., 2007), nous nous sommes intéressés au rôle de c-Myc dans le développement des cellules pigmentaires et à leur homéostasie après la naissance. Un allèle floxé de c-myc (Trumpp et al., 2001) a été utilisé pour supprimer ce gène spécifiquement dans la lignée mélanocytaire à l'aide d'une souris transgénique Tyr::Cre (Delmas et al., 2003). L'ablation des deux allèles de c-myc dans les mélanocytes des souris c-myccKO conduit au phénotype de grisonnement des poils, observé directement après la naissance et associé à une diminution du nombre de mélanocytes dans le bulbe des follicules pileux. Les cellules pigmentaires restantes expriment les marqueurs mélanogéniques (Tyr, TRP-1, Dct and MITF) et semblent être fonctionnelles puisqu'elles peuvent produire et transférer la mélanine. De plus, la capacité de prolifération des mélanocytes déficients en c-Myc dans le bulbe des follicules pileux ne semble pas être affectée chez les nouveaux-nés. Les cellules souches mélanocytaires sont présentes, mais en nombre réduit, dans le bulge des follicules pileux à la fin de la morphogenèse chez les souris c-myccKO âgées de huit jours. Ces cellules sont maintenues sans changement durant le premier cycle pileux (vérifié à l'âge de trente jours), ce qui sous-entend que la fonction de c-Myc n'est pas nécessaire pour ce processus. Ceci explique pourquoi, en supposant que des cellules souches mélanocytaires fonctionnelles sont présentes dans la peau, nous n'observons pas de dilution de couleur de la robe liée à l'âge. Cependant, la présence de ces cellules souches mélanocytaires dans la peau c-myccKO ne suffit pas à assurer une quantité normale de mélanocytes différenciés dans le bulbe des follicules pileux. Cette population de cellules pigmentaires matures est sévèrement affectée par la suppression de c-Myc, ce qui contribue amplement au phénotype de grisonnement des poils. De plus, c-Myc paraît être important pour le développement des mélanocytes. Ainsi, le nombre de mélanoblastes diminue dans les embryons c-myccKO à partir du douzième jour de gestation. A treize jours de gestation, au stade où les mélanoblastes pénètrent dans l'épiderme et prolifèrent, les mélanoblastes déficients en c-Myc ne s'adaptent pas aux signaux de prolifération et se retrouvent en nombre réduit dans l'épiderme. Finalement, nous nous sommes intéressés, au rôle de N-Myc, un homologue proche de c-Myc, dans la lignée mélanocytaire. Nos expériences ont montré que. N-Myc était superflu pour le développement et l'homéostasie des mélanocytes, une seule copie du gène c-myc étant suffisante pour maintenir une pigmentation normale de la robe des souris c-mycc-myccKO/+~N_ myccKO/KO. Cependant, le rôle essentiel de N-Myc dans la maintenance des cellules mélanocytaires précurseurs apparaît lorsque c-Myc est absent, puisque la suppression simultanée des deux Myc résulte en une perte complète de la coloration de la robe. Ceci implique la présence d'un mécanisme compensatoire entre c- et N-Myc dans la lignée mélanocytaire, avec un rôle prédominant de c-Myc. Summary Deregulation of c-Myc is known to be a common event in cellular transformation. Upregulation of this oncoprotein was shown in a variety of primary and metastatic cutaneous melanomas and has been associated with a poor prognosis (Grover et al., 1996; Zhuang et al., 2008). c-myc is seen as a central molecule involved in many aspects of cellular homeostasis. c-Myc function has been intensively studied mostly because of its significant contribution to tumour progression. However little is known on the role of this transcription factor in embryogenesis and tissue specification. Complete loss of c-Myc during embryogenesis results in embryonic death before E10.5 due to multiple developmental defects including embryonic size, heart, pericardium, neural tube and blood cells (Davis et al., 1993; Trumpp et al., 2001). Recently it was discovered that most of these abnormalities are secondary and results of placental insufficiency in c-Myc-/- embryos (Dubois et al., 2008). Here, we focused on the role of c-Myc in pigment cell development and homeostasis after birth, knowing that c-Myc is important in the maintenance of neural crest lineages (Wei et al., 2007). A floxed allele of c-Myc (Trumpp et al., 2001) was used to specifically delete this gene in the melanocyte lineage using Tyr::Cre transgenic mice (Delmas et al., 2003). Removal of both c-Myc alleles in melanocytes of c-MyccKO mouse led to the grey hair phenotype which is seen directly after birth and was associated with a decrease in the melanocyte number in the bulb of the hair follicle. The remaining population of pigment cells express melanogenic markers (Tyr, TRP-1, Dct and MITF) and seem functionally normal since they can produce and transfer melanin. Furthermore proliferation capacity of c-Myc deficient melanocytes in the bulb of hair follicle seems not to be affected in newborn animals. Melanocyte stem cells (MSCs) are present but reduced in numbers in the bulge of the hair follicle at the end of morphogenesis in 8 days old c-MyccKO mice. These cells are maintained through the first hair cycle (as verified at P30) without any further changes, suggesting that c-Myc function is not required for this process. This explains why we did not detect any agerelated coat color dilution, assuming a presence of functional MSCs in the skin. Importantly, presence of MSCs in c-MyccKO skin was not sufficient for assuring a normal number of differentiated melanocytes in the bulb of the hair follicle. This population of mature pigmented cells is severely affected upon c-myc deletion thus largely contributing to the grey hair phenotype. Moreover, c-Myc appears to be important for melanocyte development. Thus, melanoblast number is affected in c-MyccKO embryos day 12 of gestation onwards. At E13.5, when melanoblasts enter the epidermis and proliferate, c-myc deficient melanoblasts failed to adapt to proliferation signals and are therefore reduced in number in the epidermis. Finally, we addressed the role of N-Myc, a closest homologue of c-Myc, in the melanocyte lineage. In these experiments, N-Myc was dispensable for melanocyte development and homeostasis, and even one copy of the c-myc gene was sufficient to maintain normal coat color pigmentation in c-mycc-mycCKO/+ ,N-myccKO/KO mice. However the crucial role of N-Myc in maintenance of melanocyte precursor cells became apparent when c-myc is eliminated since simultaneous deletion of both Myc results in complete loss of coat color pigmentation. This suggests compensatory mechanisms between c- and N-Myc with a predominant role of c-Myc in melanocyte lineage.

Exploring neural cell dynamics with digital holographic microscopy.

In this review, we summarize how the new concept of digital optics applied to the field of holographic microscopy has allowed the development of a reliable and flexible digital holographic quantitative phase microscopy (DH-QPM) technique at the nanoscale particularly suitable for cell imaging. Particular emphasis is placed on the original biological information provided by the quantitative phase signal. We present the most relevant DH-QPM applications in the field of cell biology, including automated cell counts, recognition, classification, three-dimensional tracking, discrimination between physiological and pathophysiological states, and the study of cell membrane fluctuations at the nanoscale. In the last part, original results show how DH-QPM can address two important issues in the field of neurobiology, namely, multiple-site optical recording of neuronal activity and noninvasive visualization of dendritic spine dynamics resulting from a full digital holographic microscopy tomographic approach.

Regulation of dendritic development by neurotrophic factors

AbstractEstablishment of a functional nervous system occurs through an orchestrated multistep process during embryogenesis. As dendrites are the primary sites of synaptic connections, development of dendritic arborization is essential for the formation of functional neural circuits. Maturation of dendritic arbor occurs through dynamic processes that are regulated by intrinsic genetic factors and external signals, such as environmental stimuli, neuronal activity and growth factors. Among the latter, the neurotrophic factor BDNF is a key regulator of dendritic growth. However, the mechanisms by which BDNF controls dendritic development remain elusive.In this study, we first showed that activation of the MAPK signaling pathway and phosphorylation of the transcription factor CREB are required to mediate the effects of BDNF on dendritic development of cortical neurons. However, phosphorylation of CREB alone is not sufficient to induce dendritic growth in response to BDNF. Thus, by using a mutant form of CREB unable to bind its coactivator CRTC1, we demonstrated that BDNF-induced dendritic elaboration requires the functional interaction between CREB and CRTC1. Consistent with these observations, inhibition of CRTC1 expression by shRNA-mediated knockdown was found to suppress the effects of BDNF on dendritic length and branching of cortical neurons.The nuclear translocation of CRTC1, a step necessary for the interaction between CREB and CRTC1, was shown to result from the activation of NMD A receptors by glutamate, leading to the dephosphorylation of CRTC1 by the protein phosphatase calcineurin. In line with these findings, prevention of CRTC1 nuclear translocation in the absence of glutamate, or by inhibiting NMDA receptors or calcineurin suppressed the promotion of dendritic growth by BDNF.Increasing evidence supports a role for the growth factor HGF in the regulation of dendritic morphology during brain development. Despite these observations, little is known about the cellular mechanisms underlying the effects of HGF on dendritic elaboration of cortical neurons. The second part of this study was aimed at elucidating the cellular processes that mediate the effects of HGF on dendritic differentiation. We found that HGF increases cortical dendritic growth through mechanisms that involve MAPK-dependent phosphorylation of CREB, and interaction of CREB with its coactivator CRTC1. These data indicate that the mechanisms underlying the promotion of dendritic growth by HGF are similar to those that mediate the effects of BDNF, suggesting that the role of CREB and CRTC1 in the regulation of dendritic development may not be limited to HGF and BDNF, but may extend to other neurotrophic factors that control dendritic differentiation.Together, these results identify a previously unrecognized mechanism by which CREB and its coactivator CRTC1 mediate the effects of BDNF and HGF on dendritic growth of cortical neurons. Moreover, these data highlight the important role of the cooperation between BDNF/HGF and glutamate that converges on CREB to stimulate the expression of genes that contribute to the development of dendritic arborization.RésuméL'établissement d'un système nerveux fonctionnel s'accomplit grâce à des mécanismes précis, orchestrés en plusieurs étapes au cours de l'embryogenèse. Les dendrites étant les principaux sites de connexions synaptiques, le développement de l'arborisation dendritique est essentiel à la formation de circuits neuronaux fonctionnels. La maturation de l'arbre dendritique s'effectue grâce à des processus dynamiques qui sont régulés par des facteurs génétiques intrinsèques ainsi que par des facteurs externes tels que les stimuli environnementaux, l'activité neuronale ou les facteurs de croissance. Parmi ces derniers, le facteur neurotrophique BDNF est - connu pour être un régulateur clé de la croissance dendritique. Cependant, les mécanismes par lesquels BDNF contrôle le développement dendritique demeurent mal connus.Au cours de cette étude, nous avons montré dans un premier temps que l'activation de la voie de signalisation de la MAPK et la phosphorylation du facteur de transcription CREB sont nécessaires aux effets du BDNF sur le développement dendritique des neurones corticaux. Toutefois, la phosphorylation de CREB en tant que telle n'est pas sûffisante pour permettre la pousse des dendrites en réponse au BDNF. Ainsi, en utilisant une forme mutée de CREB incapable de se lier à son coactivateur CRTC1, nous avons démontré que l'élaboration des dendrites induite par le BDNF nécessite également une interaction fonctionnelle entre CREB et CRTC1. Ces résultats ont été confirmés par d'autres expériences qui ont montré que l'inhibition de l'expression de CRTC1 par l'intermédiaire de shRNA supprime les effets du BDNF sur la longueur et le branchement dendritique des neurones corticaux.Les résultats obtenus au cours de ce travail montrent également que la translocation nucléaire de CRTC1, qui est une étape nécessaire à l'interaction entre CREB et CRTC1, résulte de l'activation des récepteurs NMDA par le glutamate, entraînant la déphosphorylation de CRTC1 par la protéine phosphatase calcineurine. De plus, le blocage de la translocation nucléaire de CRTC1 en absence de glutamate, ou suite à l'inhibition des récepteurs NMDA ou de la calcineurine, supprime complètement la pousse des dendrites induite par le BDNF.De nombreuses d'évidences indiquent que le facteur de croissance HGF joue également un rôle important dans la régulation de la morphologie dendritique au cours du développement cérébral. Malgré ces observations, peu d'éléments sont connus quant aux mécanismes cellulaires qui sous-tendent les effets du HGF sur la croissance dendritique des neurones corticaux. Le but de la seconde partie de cette étude a eu pour but d'élucider les processus cellulaires responsables des effets du HGF sur la différenciation dendritique des neurones corticaux. Au cours de ces expériences, nous avons pu mettre en évidence que le HGF induit la pousse dendritique par des mécanismes qui impliquent la phosphorylation de CREB par la MAPK, et l'interaction de CREB avec son coactivateur CRTC1. Ces données indiquent que les mécanismes impliqués dans la stimulation de la croissance dendritique par le HGF sont similaires à ceux régulant les effets du BDNF, ce qui suggère que le rôle de CREB et de CRTC1 dans la régulation du développement dendritique n'est vraisemblablement pas limité aux effets du HGF ou du BDNF, mais pourrait s'étendre à d'autres facteurs neurotrophiques qui contrôlent la différenciation dendritique.En conclusion, ces résultats ont permis l'identification d'un nouveau mécanisme par lequel CREB et son coactivateur CRTC1 transmettent les effets du BDNF et du HGF sur la croissance dendritique de neurones corticaux. Ces observations mettent également en évidence le rôle important joué par la coopération entre BDNF/HGF et le glutamate, dans l'activation de CREB ainsi que dans l'expression de gènes qui participent au développement de l'arborisation dendritique des neurones corticaux.

Cellular mechanisms underlying the regulation of dendritic development by hepatocyte growth factor.

Acquisition of a mature dendritic morphology is critical for neural information processing. In particular, hepatocyte growth factor (HGF) controls dendritic arborization during brain development. However, the cellular mechanisms underlying the effects of HGF on dendritic growth remain elusive. Here, we show that HGF increases dendritic length and branching of rat cortical neurons through activation of the mitogen-activated protein kinase (MAPK) signaling pathway. Activation of MAPK by HGF leads to the rapid and transient phosphorylation of cAMP response element-binding protein (CREB), a key step necessary for the control of dendritic development by HGF. In addition to CREB phosphorylation, regulation of dendritic growth by HGF requires the interaction between CREB and CREB-regulated transcription coactivator 1 (CRTC1), as expression of a mutated form of CREB unable to bind CRTC1 completely abolished the effects of HGF on dendritic morphology. Treatment of cortical neurons with HGF in combination with brain-derived neurotrophic factor (BDNF), a member of the neurotrophin family that regulates dendritic development via similar mechanisms, showed additive effects on MAPK activation, CREB phosphorylation and dendritic growth. Collectively, these results support the conclusion that regulation of cortical dendritic morphology by HGF is mediated by activation of the MAPK pathway, phosphorylation of CREB and interaction of CREB with CRTC1.

Aging preferentially affects molecular pathways implicated in development and disease of myelinating glial cells

The central and peripheral nervous systems are involved in multiple age-dependent neurological deficits that are often attributed to alterations in function of myelinating glial cells. However, the molecular events that underlie the age-related decline of glial cell function are unknown. We used Schwann cells as a model to study biological processes affected in glial cells by aging. We comprehensively profiled gene expression of the Schwann cellrich mouse sciatic nerve throughout life, from day of birth until senescence (840 days of age). We combined the aging data with the microarray transcriptional data obtained using nerves isolated from Schwann cell-specific neuropathy-inducing mutants MPZCre/+/Lpin1fE2−3/fE2−3 , MPZCre/+/ScapfE1/fE1 and Pmp22-null mice. The majority of age related transcripts were also affected in the analyzed mouse models of neuropathy (54.4%) and in development (59.5%) indicating a high level of overlapping in implicated molecular pathways. We observed that compared to peripheral nerve development, dynamically changing expression profiles in aging have opposite (anticorrelated) orientation while they copy the orientation of transcriptional changes observed in analyzed neuropathy models. Subsequent clustering and biological annotation of dynamically changing transcripts revealed that the processes most significantly deregulated in aging include inflammatory/immune response and lipid biosynthesis/metabolism. Importantly, the changes in these pathways were also observed in myelinated oligodendrocyte-rich optic nerves of aged mice, albeit with lower magnitude. This observation suggests that similar biological processes are affected in aging glial cells in central and peripheral nervous systems, however with different dynamics. Our data, which provide the first comprehensive comparison of molecular changes in glial cells in three distinct biological conditions comprising development, aging and disease, provide not only a new inside into the molecular alterations underlying neural system aging but also identify target pathways for potential therapeutic approaches to prevent or delay complications associated with age-related and inherited forms of neuropathies. *Current address: Department of Physiology, UCSF, San Francisco, CA, USA.

Aging preferentially affects molecular pathways implicated in development and disease of myelinating glial cells

The central and peripheral nervous systems are involved in multiple agedependent neurological deficits that are often attributed to alterations in function of myelinating glial cells. However, the molecular events that underlie the age-related decline of glial cell function are unknown. We used Schwann cells as a model to study biological processes affected in glial cells by aging. We comprehensively profiled gene expression of the Schwann cell-rich mouse sciatic nerve throughout life, from day of birth until senescence (840 days of age). We combined the aging data with the microarray transcriptional data obtained using nerves isolated from Schwann cell-specific neuropathy-inducing mutants MPZCre/þ/Lpin1fE2-3/fE2-3, MPZCre/þ/ScapfE1/fE1 and Pmp22-null mice. A majority of age related transcripts were also affected in the analyzed mouse models of neuropathy (54.4%) and in development (59.5%) indicating a high level of overlapping in implicated molecular pathways. We observed that compared to peripheral nerve development, dynamically changing expression profiles in aging have opposite (anticorrelated) orientation while they copy the orientation of transcriptional changes observed in analyzed neuropathy models. Subsequent clustering and biological annotation of dynamically changing transcripts revealed that the processes most significantly deregulated in aging include inflammatory/ immune response and lipid biosynthesis/metabolism. Importantly, the changes in these pathways were also observed in myelinated oligodendrocyte- rich optic nerves of aged mice, albeit with lower magnitude. This observation suggests that similar biological processes are affected in aging glial cells in central and peripheral nervous systems, however with different dynamics. Our data, which provide the first comprehensive comparison of molecular changes in glial cells in three distinct biological conditions comprising development, aging and disease, provide not only a new inside into the molecular alterations underlying neural system aging but also identify target pathways for potential therapeutical approaches to prevent or delay complications associated with age-related and inherited forms of neuropathies.

An Advocacy for the Use of 3D Stem Cell Culture Systems for the Development of Regenerative Medicine: An Emphasis on Photoreceptor Generation

The availability of stem cells is of great promise to study early developmental stages and to generate adequate cells for cell transfer therapies. Although many researchers using stem cells were successful in dissecting intrinsic and extrinsic mechanisms and in generating specific cell phenotypes, few of the stem cells or the differentiated cells show the capacity to repair a tissue. Advances in cell and stem cell cultivation during the last years made tremendous progress in the generation of bona fide differentiated cells able to integrate into a tissue after transplantation, opening new perspectives for developmental biology studies and for regenerative medicine. In this review, we focus on the main works attempting to create in vitro conditions mimicking the natural environment of CNS structures such as the neural tube and its development in different brain region areas including the optic cup. The use of protocols growing cells in 3D organoids is a key strategy to produce cells resembling endogenous ones. An emphasis on the generation of retina tissue and photoreceptor cells is provided to highlight the promising developments in this field. Other examples are presented and discussed, such as the formation of cortical tissue, the epithelial gut or the kidney organoids. The generation of differentiated tissues and well-defined cell phenotypes from embryonic stem (ES) cells or induced pluripotent cells (iPSCs) opens several new strategies in the field of biology and regenerative medicine. A 3D organ/tissue development in vitro derived from human cells brings a unique tool to study human cell biology and pathophysiology of an organ or a specific cell population. The perspective of tissue repair is discussed as well as the necessity of cell banking to accelerate the progress of this promising field.