Role of the Insulin signalling pathway in coupling oogenesis rate with nutritional cues in Drosophila

Au cours de l’ovogenèse, les stades vitellogéniques nécessitent une énergie considérable, et leur formation doit être ajustée en fonction d’autres besoins physiologiques. En utilisant la drosophile comme modèle, j’ai montré que la signalisation Insuline régule une transition du cycle cellulaire, mitose/ endocyle (M/E), une étape critique qui contrôle l’entrée des follicules en vitellogenèse. Mes travaux montrent que la transition M/E porte le rôle d’un point de contrôle nutritionnel. La carence protéique induit un blocage de cette transition au travers d’une interaction entre FoxO, Cut et Notch, empêchant une perte d’énergie. Ce blocage reste réversible, autorisant la reprise de l’ovogenèse sous retour à une alimentation normale. Ce travail montre qu’un point de contrôle nutritionnel au cours de l’ovogenèse permet de coupler des signaux métaboliques et développementaux pour protéger les tissus des dommages liés à la carence. D’autre part, j’ai montré que la signalisation Insuline contrôle la migration d’une cohorte de cellules d’origine épithéliale pour assurer la fertilité de l’ovocyte. L’insuline participe à la formation d’extensions cytoplasmiques riches en actine. Lors de ce processus, la signalisation Insuline contrôle notamment l’expression de chickadee, qui code pour la Profiline, une protéine nécessaire pour la polymérisation de l’actine qui permet la motilité des cellules. L’ensemble de ce travail montre que des tissus somatiques assurent l’homéostasie de l’ovogenèse malgré des conditions de nutritions fluctuantes. Ces travaux posent les bases de l’étude de nouveaux aspects de l’ovogenèse, potentiellement conservés chez les mammifères.How oogenesis is controlled upon nutrient challenge is a key biological question to understand the balance between reproduction and adult fitness. During Drosophila oogenesis, vitellogenic stages are highly energy consuming so their formation has to be balanced with other physiological needs. We reveal the role of the Insulin pathway and FoxO in regulating the transition from Mitotic-to-Endocycle, a critical step controlling the entry of egg chambers into vitellogenesis. We show that the M/E switch functions as a nutrient checkpoint, blocking the entry into vitellogenesis upon starvation and therefore protecting adults from energy loss. Pausing of the M/E switch involves a previously unknown crosstalk between FoxO, Cut and Notch, a fully reversible process ensuring rapid resuming of oogenesis upon re-feeding. This work reveals a FoxO-dependent nutrient checkpoint integrating metabolic cues with reproduction and protecting tissues from starvation-induced damages. In addition, we show that the Insulin pathway regulates the migration of a subset of epithelial cells to ensure oocyte fertilization. We demonstrate that Insulin signaling regulates the formation of actin-rich cellular extensions in invasive cells. During this process, FoxO represses chickadee expression, which encodes Profilin. Insulin signaling activity leads to the inhibition of FoxO and subsequent Profilin accumulation, which further allows actin polymerization, necessary for cell motility. Altogether, data reveal a crucial role for the conserved Insulin signaling pathway in regulating ovarian follicles through somatic tissues, a process which is likely to share much in common with oogenesis in mammals

Rôle de la voie de signalisation Insuline dans le couplage des informations nutritionnelles et développementales au cours de l'ovogenèse chez la drosophile

How oogenesis is controlled upon nutrient challenge is a key biological question to understand the balance between reproduction and adult fitness. During Drosophila oogenesis, vitellogenic stages are highly energy consuming so their formation has to be balanced with other physiological needs. We reveal the role of the Insulin pathway and FoxO in regulating the transition from Mitotic-to-Endocycle, a critical step controlling the entry of egg chambers into vitellogenesis. We show that the M/E switch functions as a nutrient checkpoint, blocking the entry into vitellogenesis upon starvation and therefore protecting adults from energy loss. Pausing of the M/E switch involves a previously unknown crosstalk between FoxO, Cut and Notch, a fully reversible process ensuring rapid resuming of oogenesis upon re-feeding. This work reveals a FoxO-dependent nutrient checkpoint integrating metabolic cues with reproduction and protecting tissues from starvation-induced damages. In addition, we show that the Insulin pathway regulates the migration of a subset of epithelial cells to ensure oocyte fertilization. We demonstrate that Insulin signaling regulates the formation of actin-rich cellular extensions in invasive cells. During this process, FoxO represses chickadee expression, which encodes Profilin. Insulin signaling activity leads to the inhibition of FoxO and subsequent Profilin accumulation, which further allows actin polymerization, necessary for cell motility. Altogether, data reveal a crucial role for the conserved Insulin signaling pathway in regulating ovarian follicles through somatic tissues, a process which is likely to share much in common with oogenesis in mammals.Au cours de l’ovogenèse, les stades vitellogéniques nécessitent une énergie considérable, et leur formation doit être ajustée en fonction d’autres besoins physiologiques. En utilisant la drosophile comme modèle, j’ai montré que la signalisation Insuline régule une transition du cycle cellulaire, mitose/ endocyle (M/E), une étape critique qui contrôle l’entrée des follicules en vitellogenèse. Mes travaux montrent que la transition M/E porte le rôle d’un point de contrôle nutritionnel. La carence protéique induit un blocage de cette transition au travers d’une interaction entre FoxO, Cut et Notch, empêchant une perte d’énergie. Ce blocage reste réversible, autorisant la reprise de l’ovogenèse sous retour à une alimentation normale. Ce travail montre qu’un point de contrôle nutritionnel au cours de l’ovogenèse permet de coupler des signaux métaboliques et développementaux pour protéger les tissus des dommages liés à la carence. D’autre part, j’ai montré que la signalisation Insuline contrôle la migration d’une cohorte de cellules d’origine épithéliale pour assurer la fertilité de l’ovocyte. L’insuline participe à la formation d’extensions cytoplasmiques riches en actine. Lors de ce processus, la signalisation Insuline contrôle notamment l’expression de chickadee, qui code pour la Profiline, une protéine nécessaire pour la polymérisation de l’actine qui permet la motilité des cellules. L’ensemble de ce travail montre que des tissus somatiques assurent l’homéostasie de l’ovogenèse malgré des conditions de nutritions fluctuantes. Ces travaux posent les bases de l’étude de nouveaux aspects de l’ovogenèse, potentiellement conservés chez les mammifères

Rôle de la voie de signalisation Insuline dans le couplage des informations nutritionnelles et développementales au cours de l'ovogenèse chez la drosophile

Au cours de l ovogenèse, les stades vitellogéniques nécessitent une énergie considérable, et leur formation doit être ajustée en fonction d autres besoins physiologiques. En utilisant la drosophile comme modèle, j ai montré que la signalisation Insuline régule une transition du cycle cellulaire, mitose/ endocyle (M/E), une étape critique qui contrôle l entrée des follicules en vitellogenèse. Mes travaux montrent que la transition M/E porte le rôle d un point de contrôle nutritionnel. La carence protéique induit un blocage de cette transition au travers d une interaction entre FoxO, Cut et Notch, empêchant une perte d énergie. Ce blocage reste réversible, autorisant la reprise de l ovogenèse sous retour à une alimentation normale. Ce travail montre qu un point de contrôle nutritionnel au cours de l ovogenèse permet de coupler des signaux métaboliques et développementaux pour protéger les tissus des dommages liés à la carence. D autre part, j ai montré que la signalisation Insuline contrôle la migration d une cohorte de cellules d origine épithéliale pour assurer la fertilité de l ovocyte. L insuline participe à la formation d extensions cytoplasmiques riches en actine. Lors de ce processus, la signalisation Insuline contrôle notamment l expression de chickadee, qui code pour la Profiline, une protéine nécessaire pour la polymérisation de l actine qui permet la motilité des cellules. L ensemble de ce travail montre que des tissus somatiques assurent l homéostasie de l ovogenèse malgré des conditions de nutritions fluctuantes. Ces travaux posent les bases de l étude de nouveaux aspects de l ovogenèse, potentiellement conservés chez les mammifères.How oogenesis is controlled upon nutrient challenge is a key biological question to understand the balance between reproduction and adult fitness. During Drosophila oogenesis, vitellogenic stages are highly energy consuming so their formation has to be balanced with other physiological needs. We reveal the role of the Insulin pathway and FoxO in regulating the transition from Mitotic-to-Endocycle, a critical step controlling the entry of egg chambers into vitellogenesis. We show that the M/E switch functions as a nutrient checkpoint, blocking the entry into vitellogenesis upon starvation and therefore protecting adults from energy loss. Pausing of the M/E switch involves a previously unknown crosstalk between FoxO, Cut and Notch, a fully reversible process ensuring rapid resuming of oogenesis upon re-feeding. This work reveals a FoxO-dependent nutrient checkpoint integrating metabolic cues with reproduction and protecting tissues from starvation-induced damages. In addition, we show that the Insulin pathway regulates the migration of a subset of epithelial cells to ensure oocyte fertilization. We demonstrate that Insulin signaling regulates the formation of actin-rich cellular extensions in invasive cells. During this process, FoxO represses chickadee expression, which encodes Profilin. Insulin signaling activity leads to the inhibition of FoxO and subsequent Profilin accumulation, which further allows actin polymerization, necessary for cell motility. Altogether, data reveal a crucial role for the conserved Insulin signaling pathway in regulating ovarian follicles through somatic tissues, a process which is likely to share much in common with oogenesis in mammals.NICE-Bibliotheque electronique (060889901) / SudocSudocFranceF

Starvation induces FoxO-dependent mitotic-to-endocycle switch pausing during Drosophila oogenesis.

International audienceWhen exposed to nutrient challenge, organisms have to adapt their physiology in order to balance reproduction with adult fitness. In mammals, ovarian follicles enter a massive growth phase during which they become highly dependent on gonadotrophic factors and nutrients. Somatic tissues play a crucial role in integrating these signals, controlling ovarian follicle atresia and eventually leading to the selection of a single follicle for ovulation. We used Drosophila follicles as a model to study the effect of starvation on follicle maturation. Upon starvation, Drosophila vitellogenic follicles adopt an 'atresia-like' behavior, in which some slow down their development whereas others enter degeneration. The mitotic-to-endocycle (M/E) transition is a critical step during Drosophila oogenesis, allowing the entry of egg chambers into vitellogenesis. Here, we describe a specific and transient phase during M/E switching that is paused upon starvation. The Insulin pathway induces the pausing of the M/E switch, blocking the entry of egg chambers into vitellogenesis. Pausing of the M/E switch involves a previously unknown crosstalk between FoxO, Cut and Notch that ensures full reversion of the process and rapid resumption of oogenesis upon refeeding. Our work reveals a novel genetic mechanism controlling the extent of the M/E switch upon starvation, thus integrating metabolic cues with development, growth and reproduction

The Drosophila insulin pathway controls Profilin expression and dynamic actin-rich protrusions during collective cell migration

International audienceUnderstanding how different cell types acquire their motile behaviour is central to many normal and pathological processes. Drosophila border cells represent a powerful model for addressing this issue and to specifically decipher the mechanisms controlling collective cell migration. Here, we identify the Drosophila Insulin/Insulin-like growth factor signalling (IIS) pathway as a key regulator in controlling actin dynamics in border cells, independently of its function in growth control. Loss of IIS activity blocks the formation of actin-rich long cellular extensions that are important for the delamination and the migration of the invasive cluster. We show that IIS specifically activates the expression of the actin regulator chickadee, the Drosophila homolog of Profilin, which is essential for promoting the formation of actin extensions and migration through the egg chamber. In this process, the transcription factor FoxO acts as a repressor of chickadee expression. Altogether, these results show that local activation of IIS controls collective cell migration through regulation of actin homeostasis and protrusion dynamics

REPTOR and CREBRF encode key regulators of muscle energy metabolism

Abstract Metabolic flexibility of muscle tissue describes the adaptive capacity to use different energy substrates according to their availability. The disruption of this ability associates with metabolic disease. Here, using a Drosophila model of systemic metabolic dysfunction triggered by yorkie-induced gut tumors, we show that the transcription factor REPTOR is an important regulator of energy metabolism in muscles. We present evidence that REPTOR is activated in muscles of adult flies with gut yorkie-tumors, where it modulates glucose metabolism. Further, in vivo studies indicate that sustained activity of REPTOR is sufficient in wildtype muscles to repress glycolysis and increase tricarboxylic acid (TCA) cycle metabolites. Consistent with the fly studies, higher levels of CREBRF, the mammalian ortholog of REPTOR, reduce glycolysis in mouse myotubes while promoting oxidative metabolism. Altogether, our results define a conserved function for REPTOR and CREBRF as key regulators of muscle energy metabolism