30 research outputs found
Quantification de la morphologie mitochondriale dans le disque d'aile de drosophile : recherche du bon outil
No full textNational audienc
DREAM a little dREAM of DRM: Model organisms and conservation of DREAM-like complexes: Model organisms uncover the mechanisms of DREAM-mediated transcription regulation
No full textInternational audienceDREAM complexes are transcriptional regulators that control the expression of hundreds to thousands of target genes involved in the cell cycle, quiescence, differentiation, and apoptosis. These complexes contain many subunits that can vary according to the considered target genes. Depending on their composition and the nature of the partners they recruit, DREAM complexes control gene expression through diverse mechanisms, including chromatin remodeling, transcription cofactor and factor recruitment at various genomic binding sites. This complexity is particularly high in mammals. Since the discovery of the first dREAM complex (drosophila Rb, E2F, and Myb) in Drosophila melanogaster, model organisms such as Caenorhabditis elegans, and plants allowed a deeper understanding of the processes regulated by DREAMlike complexes. Here, we review the conservation of these complexes. We discuss the contribution of model organisms to the study of DREAM-mediated transcriptional regulatory mechanisms and their relevance in characterizing novel activities of DREAM complexes
The Drosophila retinoblastoma protein induces apoptosis in proliferating but not in post-mitotic cells
No full textInternational audienceThe retinoblastoma protein, pRb, plays important roles in many processes implicated in cell fate decisions, including cell cycle, differentiation and apoptosis. In cell cycle regulation, pRb interacts principally with the E2F transcription factor family members to inhibit the transcription of many genes controlling cell cycle progression. In this study, we focused on the role of pRb in apoptosis, which is much less clear than its role in cell cycle regulation. Indeed, pRb has been found to be either pro- or anti-apoptotic. To clarify how the proliferative status of the cells impacts the role of pRb in apoptosis, we used Drosophila to induce RBF (the pRb fly homologue) expression in different cellular and developmental contexts. We found that RBF expression induces apoptosis in different proliferative tissues in a caspase-dependent manner, whereas this effect was not observed in differentiated post-mitotic cells. Furthermore, RBF-induced apoptosis in proliferating cells was inhibited by co-expression of dE2F1, an antagonistic partner of RBF in cell cycle regulation. These results are in agreement with the view that the apoptotic properties of pRb are tightly linked to, and are probably a consequence of, an effect on cell cycle progression. Moreover, we show for the first time that RBF has a direct anti-apoptotic effect on Dmp53-induced cell death in post-mitotic cells only. Taken together, these data clearly show that RBF can exert a dual role in the control of apoptotic processes, and that its properties depend on the proliferative status of the cells
Two different specific JNK activators are required to trigger apoptosis or compensatory proliferation in response to Rbf1 in Drosophila
No full textInternational audienceThe Jun Kinase (JNK) signaling pathway responds to diverse stimuli by appropriate and specific cellular responses such as apoptosis, differentiation or proliferation. The mechanisms that mediate this specificity remain largely unknown. The core of this signaling pathway, composed of a JNK protein and a JNK kinase (JNKK), can be activated by various putative JNKK kinases (JNKKK) which are themselves downstream of different adaptor proteins. A proposed hypothesis is that the JNK pathway specific response lies in the combination of a JNKKK and an adaptor protein upstream of the JNKK. We previously showed that the Drosophila homolog of pRb (Rbf1) and a mutant form of Rbf1 (Rbf1 D253A) have JNK-dependent pro-apoptotic properties. Rbf1 D253A is also able to induce a JNK-dependent abnormal proliferation. Here, we show that Rbf1-induced apoptosis triggers proliferation which depends on the JNK pathway activation. Taking advantage of these phenotypes, we investigated the JNK signaling involved in either Rbf1-induced apoptosis or in proliferation in response to Rbf1-induced apoptosis. We demonstrated that 2 different JNK pathways involving different adaptor proteins and kinases are involved in Rbf1-apoptosis (i.e. Rac1-dTak1-dMekk1-JNK pathway) and in proliferation in response to Rbf1-induced apoptosis (i.e., dTRAF1-Slipper-JNK pathway). Using a transient induction of rbf1, we show that Rbf1-induced apoptosis activates a compensatory proliferation mechanism which also depends on Slipper and dTRAF1. Thus, these 2 proteins seem to be key players of compensatory proliferation in Drosophila
The Drosophila retinoblastoma protein, Rbf1, induces a Debcl-and Drp1-dependent mitochondrial apoptosis
No full textInternational audienceIn accordance with its tumor suppressor role, the retinoblastoma protein pRb can ensure pro-apoptotic functions. Rbf1, the Drosophila homolog of Rb, also displays a pro-apoptotic activity in proliferative cells. We have previously shown that the Rbf1 pro-apoptotic activity depends on its ability to decrease the level of anti-apoptotic proteins such as the Bcl-2 family protein Buffy. Buffy often acts in an opposite manner to Debcl, the other Drosophila Bcl-2-family protein. Both proteins can localize at the mitochondrion, but the way they control apoptosis still remains unclear. Here, we demonstrate that Debcl and the pro-fission gene Drp1 are necessary downstream of Buffy to trigger a mitochondrial fragmentation during Rbf1-induced apoptosis. Interestingly, Rbf1-induced apoptosis leads to a Debcl-and Drp1-dependent reactive oxygen species production, which in turn activates the Jun Kinase pathway to trigger cell death. Moreover, we show that Debcl and Drp1 can interact and that Buffy inhibits this interaction. Notably, Debcl modulates Drp1 mitochondrial localization during apoptosis. These results provide a mechanism by which Drosophila Bcl-2 family proteins can control apoptosis, and shed light on a link between Rbf1 and mitochondrial dynamics in vivo
Apoptosis in Drosophila: which role for mitochondria?
No full textInternational audienceIt is now well established that the mitochon-drion is a central regulator of mammalian cell apoptosis. However, the importance of this organelle in non-mam-malian apoptosis has long been regarded as minor, mainly because of the absence of a crucial role for cytochrome c in caspase activation. Recent results indicate that the control of caspase activation and cell death in Drosophila occurs at the mitochondrial level. Numerous proteins, including RHG proteins and proteins of the Bcl-2 family that are key regulators of Drosophila apoptosis, constitutively or transiently localize in mitochondria. These proteins participate in the cell death process at different levels such as degradation of Diap1, a Drosophila IAP, production of mito-chondrial reactive oxygen species or stimulation of the mitochondrial fission machinery. Here, we review these mitochondrial events that might have their counterpart in human
