Your search keyword '"Egger Boris"' showing total 13 results

1. Compartment and cell-type specific hypoxia responses in the developing Drosophila brain.

Author

Baccino-Calace M, Prieto D, Cantera R, and Egger B

Subjects

Animals, Biosensing Techniques, Cell Differentiation, Cell Hypoxia drug effects, Gene Expression Regulation drug effects, Glycolysis drug effects, Glycolysis genetics, Green Fluorescent Proteins metabolism, Hypoxia genetics, Larva drug effects, Neuroepithelial Cells drug effects, Neuroepithelial Cells metabolism, Optic Lobe, Nonmammalian pathology, Oxygen pharmacology, Brain growth & development, Brain pathology, Cell Compartmentation, Drosophila melanogaster cytology, Drosophila melanogaster growth & development, Hypoxia pathology

Abstract

Environmental factors such as the availability of oxygen are instructive cues that regulate stem cell maintenance and differentiation. We used a genetically encoded biosensor to monitor the hypoxic state of neural cells in the larval brain of Drosophila The biosensor reveals brain compartment and cell-type specific levels of hypoxia. The values correlate with differential tracheolation that is observed throughout development between the central brain and the optic lobe. Neural stem cells in both compartments show the strongest hypoxia response while intermediate progenitors, neurons and glial cells reveal weaker responses. We demonstrate that the distance between a cell and the next closest tracheole is a good predictor of the hypoxic state of that cell. Our study indicates that oxygen availability appears to be the major factor controlling the hypoxia response in the developing Drosophila brain and that cell intrinsic and cell-type specific factors contribute to modulate the response in an unexpected manner.This article has an associated First Person interview with the first author of the paper., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

2. Multiple neurons encode CrebB dependent appetitive long-term memory in the mushroom body circuit.

Author

Widmer YF, Fritsch C, Jungo MM, Almeida S, Egger B, and Sprecher SG

Subjects

Alleles, Animals, Gene Knockout Techniques, Memory, Long-Term, Reproducibility of Results, Appetite physiology, Cyclic AMP Response Element-Binding Protein metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Mushroom Bodies innervation, Mushroom Bodies metabolism, Neurons metabolism, Trans-Activators metabolism

Abstract

Lasting changes in gene expression are critical for the formation of long-term memories (LTMs), depending on the conserved CrebB transcriptional activator. While requirement of distinct neurons in defined circuits for different learning and memory phases have been studied in detail, only little is known regarding the gene regulatory changes that occur within these neurons. We here use the fruit fly as powerful model system to study the neural circuits of CrebB-dependent appetitive olfactory LTM. We edited the CrebB locus to create a GFP-tagged CrebB conditional knockout allele, allowing us to generate mutant, post-mitotic neurons with high spatial and temporal precision. Investigating CrebB-dependence within the mushroom body (MB) circuit we show that MB α/β and α'/β' neurons as well as MBON α3, but not in dopaminergic neurons require CrebB for LTM. Thus, transcriptional memory traces occur in different neurons within the same neural circuit., Competing Interests: YW, CF, MJ, SA, BE, SS No competing interests declared, (© 2018, Widmer et al.)

Published

2018

3. Patterning mechanisms diversify neuroepithelial domains in the Drosophila optic placode.

Author

Mishra AK, Bernardo-Garcia FJ, Fritsch C, Humberg TH, Egger B, and Sprecher SG

Subjects

Animals, Animals, Genetically Modified, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Body Patterning genetics, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Gene Expression Regulation, Developmental, Gene Regulatory Networks, Genes, Insect, Hedgehog Proteins genetics, Hedgehog Proteins metabolism, Larva genetics, Larva growth & development, Larva metabolism, Mutation, Nerve Tissue Proteins genetics, Nerve Tissue Proteins metabolism, Neuroepithelial Cells metabolism, Optic Lobe, Nonmammalian growth & development, Optic Lobe, Nonmammalian metabolism, Photoreceptor Cells, Invertebrate cytology, Photoreceptor Cells, Invertebrate metabolism, Receptors, Notch genetics, Receptors, Notch metabolism, Repressor Proteins genetics, Repressor Proteins metabolism, Signal Transduction, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Eye growth & development, Eye metabolism

Abstract

The central nervous system develops from monolayered neuroepithelial sheets. In a first step patterning mechanisms subdivide the seemingly uniform epithelia into domains allowing an increase of neuronal diversity in a tightly controlled spatial and temporal manner. In Drosophila, neuroepithelial patterning of the embryonic optic placode gives rise to the larval eye primordium, consisting of two photoreceptor (PR) precursor types (primary and secondary), as well as the optic lobe primordium, which during larval and pupal stages develops into the prominent optic ganglia. Here, we characterize a genetic network that regulates the balance between larval eye and optic lobe precursors, as well as between primary and secondary PR precursors. In a first step the proneural factor Atonal (Ato) specifies larval eye precursors, while the orphan nuclear receptor Tailless (Tll) is crucial for the specification of optic lobe precursors. The Hedgehog and Notch signaling pathways act upstream of Ato and Tll to coordinate neural precursor specification in a timely manner. The correct spatial placement of the boundary between Ato and Tll in turn is required to control the precise number of primary and secondary PR precursors. In a second step, Notch signaling also controls a binary cell fate decision, thus, acts at the top of a cascade of transcription factor interactions to define PR subtype identity. Our model serves as an example of how combinatorial action of cell extrinsic and cell intrinsic factors control neural tissue patterning.

Published

2018

4. The Microcephaly-Associated Protein Wdr62/CG7337 Is Required to Maintain Centrosome Asymmetry in Drosophila Neuroblasts.

Author

Ramdas Nair A, Singh P, Salvador Garcia D, Rodriguez-Crespo D, Egger B, and Cabernard C

Subjects

Animals, Cell Cycle Proteins metabolism, Centrioles metabolism, Drosophila Proteins metabolism, Humans, Interphase, Microtubule-Organizing Center metabolism, Nerve Tissue Proteins chemistry, Nerve Tissue Proteins metabolism, Protein Serine-Threonine Kinases metabolism, Proto-Oncogene Proteins metabolism, Sequence Homology, Amino Acid, Spindle Apparatus metabolism, Polo-Like Kinase 1, Centrosome metabolism, Drosophila melanogaster metabolism, Microcephaly metabolism, Neurons cytology, Neurons metabolism

Abstract

Centrosome asymmetry has been implicated in stem cell fate maintenance in both flies and vertebrates, but the underlying molecular mechanisms are incompletely understood. Here, we report that loss of CG7337, the fly ortholog of WDR62, compromises interphase centrosome asymmetry in fly neural stem cells (neuroblasts). Wdr62 maintains an active interphase microtubule-organizing center (MTOC) by stabilizing microtubules (MTs), which are necessary for sustained recruitment of Polo/Plk1 to the pericentriolar matrix (PCM) and downregulation of Pericentrin-like protein (Plp). The loss of an active MTOC in wdr62 mutants compromises centrosome positioning, spindle orientation, and biased centrosome segregation. wdr62 mutant flies also have an ∼40% reduction in brain size as a result of cell-cycle delays. We propose that CG7337/Wdr62, a microtubule-associated protein, is required for the maintenance of interphase microtubules, thereby regulating centrosomal Polo and Plp levels. Independent of this function, Wdr62 is also required for the timely mitotic entry of neural stem cells., (Copyright © 2016 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2016

5. Characterization of tailless functions during Drosophila optic lobe formation.

Author

Guillermin O, Perruchoud B, Sprecher SG, and Egger B

Subjects

Animals, Cell Proliferation, Cell Survival, Crosses, Genetic, Epithelial Cells cytology, Green Fluorescent Proteins metabolism, Neural Stem Cells cytology, Neuroepithelial Cells cytology, Neurons cytology, Receptors, Notch metabolism, Retina embryology, Stem Cells cytology, Drosophila Proteins physiology, Drosophila melanogaster embryology, Gene Expression Regulation, Developmental, Optic Lobe, Nonmammalian physiology, Repressor Proteins physiology

Abstract

Brain development goes through phases of proliferative growth and differentiation to ensure the formation of correct number and variety of neurons. How and when naïve neuroepithelial cells decide to enter a differentiation pathway remains poorly understood. In the Drosophila visual system, four optic ganglia emerge from neuroepithelia of the inner (IPC) and outer (OPC) proliferation centers. Here we demonstrate that the orphan nuclear receptor Tailless (Tll) is a key factor for the development of all optic ganglia. We describe tll expression during larval optic lobe development in unprecedented detail and find a spatiotemporally dynamic pattern. In the larval OPC, symmetrically dividing neuroepithelial cells transform into asymmetrically dividing medulla neuroblast and into lamina precursor cells in a precisely regulated fashion. Using genetic manipulations we found that tll is required for proper neuroepithelium morphology and neuroepithelial cell survival. We show that tll regulates the precise timing of the transition from neuroepithelial cells to medulla neuroblasts. In particular, however, we demonstrate that tll has a crucial role for the specification of lamina precursor cells. We propose that the Tll/Tlx transcription factors have an evolutionary conserved role in regulating neural precursor cell states in the Drosophila optic lobe and in the mammalian retina., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

6. Immunofluorescent labeling of neural stem cells in the Drosophila optic lobe.

Author

Perruchoud B and Egger B

Subjects

Animals, Brain cytology, Female, Genotype, Neural Stem Cells metabolism, Polylysine metabolism, Time Factors, Tissue Fixation, Drosophila melanogaster cytology, Fluorescent Antibody Technique methods, Neural Stem Cells cytology, Optic Lobe, Nonmammalian cytology

Abstract

The Drosophila visual system is an excellent model system to study the switch from proliferating to differentiating neural stem cells. In the developing larval optic lobe, symmetrically dividing neuroepithelial cells transform to asymmetrically dividing neuroblasts in a highly ordered and sequential manner. This chapter presents a protocol to visualize neural stem cell types in the Drosophila optic lobe by fluorescence confocal microscopy. A main focus is given on how to dissect, fix, immunolabel, and mount brains to reveal cellular morphology during early larval brain development.

Published

2014

7. In vitro imaging of primary neural cell culture from Drosophila.

Author

Egger B, van Giesen L, Moraru M, and Sprecher SG

Subjects

Animals, Drosophila melanogaster embryology, Larva cytology, Microscopy, Fluorescence, Cell Culture Techniques, Drosophila melanogaster cytology, Embryo, Nonmammalian cytology, Neurons cytology

Abstract

Cell culture systems are widely used for molecular, genetic and biochemical studies. Primary cell cultures of animal tissues offer the advantage that specific cell types can be studied in vitro outside of their normal environment. We provide a detailed protocol for generating primary neural cell cultures derived from larval brains of Drosophila melanogaster. The developing larval brain contains stem cells such as neural precursors and intermediate neural progenitors, as well as fully differentiated and functional neurons and glia cells. We describe how to analyze these cell types in vitro by immunofluorescent staining and scanning confocal microscopy. Cell type-specific fluorescent reporter lines and genetically encoded calcium sensors allow the monitoring of developmental, cellular processes and neuronal activity in living cells in vitro. The protocol provides a basis for functional studies of wild-type or genetically manipulated primary neural cells in culture, both in fixed and living samples. The entire procedure takes ∼3 weeks.

Published

2013

8. Analysis of cell identity, morphology, apoptosis and mitotic activity in a primary neural cell culture system in Drosophila.

Author

Moraru MM, Egger B, Bao DB, and Sprecher SG

Subjects

Animals, Cell Differentiation physiology, Drosophila Proteins metabolism, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Larva cytology, Larva genetics, Larva metabolism, Neurons metabolism, Primary Cell Culture, Apoptosis physiology, Cell Culture Techniques methods, Cell Shape physiology, Drosophila melanogaster cytology, Mitosis physiology, Neurons cytology

Abstract

In Drosophila, most neurogenetic research is carried out in vivo. Mammalian research demonstrates that primary cell culture techniques provide a powerful model to address cell autonomous and non-autonomous processes outside their endogenous environment. We developed a cell culture system in Drosophila using wildtype and genetically manipulated primary neural tissue for long-term observations. We assessed the molecular identity of distinct neural cell types by immunolabeling and genetically expressed fluorescent cell markers. We monitored mitotic activity of cell cultures derived from wildtype and tumorous larval brains. Our system provides a powerful approach to unveil developmental processes in the nervous system and to complement studies in vivo.

Published

2012

9. Notch regulates the switch from symmetric to asymmetric neural stem cell division in the Drosophila optic lobe.

Author

Egger B, Gold KS, and Brand AH

Subjects

Animals, Cell Differentiation, Cell Division, Drosophila Proteins genetics, Drosophila melanogaster genetics, Mutation, Receptors, Notch genetics, Signal Transduction, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Drosophila melanogaster metabolism, Neurons metabolism, Optic Lobe, Nonmammalian cytology, Optic Lobe, Nonmammalian metabolism, Receptors, Notch metabolism, Stem Cells metabolism

Abstract

The proper balance between symmetric and asymmetric stem cell division is crucial both to maintain a population of stem cells and to prevent tumorous overgrowth. Neural stem cells in the Drosophila optic lobe originate within a polarised neuroepithelium, where they divide symmetrically. Neuroepithelial cells are transformed into asymmetrically dividing neuroblasts in a precisely regulated fashion. This cell fate transition is highly reminiscent of the switch from neuroepithelial cells to radial glial cells in the developing mammalian cerebral cortex. To identify the molecules that mediate the transition, we microdissected neuroepithelial cells and compared their transcriptional profile with similarly obtained optic lobe neuroblasts. We find genes encoding members of the Notch pathway expressed in neuroepithelial cells. We show that Notch mutant clones are extruded from the neuroepithelium and undergo premature neurogenesis. A wave of proneural gene expression is thought to regulate the timing of the transition from neuroepithelium to neuroblast. We show that the proneural wave transiently suppresses Notch activity in neuroepithelial cells, and that inhibition of Notch triggers the switch from symmetric, proliferative division, to asymmetric, differentiative division.

Published

2010

10. Asymmetric stem cell division: lessons from Drosophila.

Author

Wu PS, Egger B, and Brand AH

Subjects

Animals, Cell Lineage, Neoplasms pathology, Spindle Apparatus metabolism, Cell Division, Drosophila melanogaster cytology, Stem Cells cytology

Abstract

Asymmetric cell division is an important and conserved strategy in the generation of cellular diversity during animal development. Many of our insights into the underlying mechanisms of asymmetric cell division have been gained from Drosophila, including the establishment of polarity, orientation of mitotic spindles and segregation of cell fate determinants. Recent studies are also beginning to reveal the connection between the misregulation of asymmetric cell division and cancer. What we are learning from Drosophila as a model system has implication both for stem cell biology and also cancer research.

Published

2008

11. Regulation of spindle orientation and neural stem cell fate in the Drosophila optic lobe.

Author

Egger B, Boone JQ, Stevens NR, Brand AH, and Doe CQ

Subjects

Animals, Body Patterning physiology, Cell Lineage physiology, Cell Polarity physiology, Cell Proliferation, Cytokinesis physiology, Drosophila melanogaster cytology, Drosophila melanogaster metabolism, Larva, Neuroepithelial Cells cytology, Optic Lobe, Nonmammalian cytology, Optic Lobe, Nonmammalian metabolism, Organogenesis physiology, Spindle Apparatus ultrastructure, Stem Cells classification, Cell Division physiology, Drosophila melanogaster growth & development, Neurons cytology, Optic Lobe, Nonmammalian growth & development, Spindle Apparatus physiology, Stem Cells cytology

Abstract

Background: The choice of a stem cell to divide symmetrically or asymmetrically has profound consequences for development and disease. Unregulated symmetric division promotes tumor formation, whereas inappropriate asymmetric division affects organ morphogenesis. Despite its importance, little is known about how spindle positioning is regulated. In some tissues cell fate appears to dictate the type of cell division, whereas in other tissues it is thought that stochastic variation in spindle position dictates subsequent sibling cell fate., Results: Here we investigate the relationship between neural progenitor identity and spindle positioning in the Drosophila optic lobe. We use molecular markers and live imaging to show that there are two populations of progenitors in the optic lobe: symmetrically dividing neuroepithelial cells and asymmetrically dividing neuroblasts. We use genetically marked single cell clones to show that neuroepithelial cells give rise to neuroblasts. To determine if a change in spindle orientation can trigger a neuroepithelial to neuroblast transition, we force neuroepithelial cells to divide along their apical/basal axis by misexpressing Inscuteable. We find that this does not induce neuroblasts, nor does it promote premature neuronal differentiation., Conclusion: We show that symmetrically dividing neuroepithelial cells give rise to asymmetrically dividing neuroblasts in the optic lobe, and that regulation of spindle orientation and division symmetry is a consequence of cell type specification, rather than a mechanism for generating cell type diversity.

Published

2007

12. The egghead gene is required for compartmentalization in Drosophila optic lobe development.

Author

Fan Y, Soller M, Flister S, Hollmann M, Müller M, Bello B, Egger B, White K, Schäfer MA, and Reichert H

Subjects

Animals, Biomarkers, Drosophila Proteins metabolism, Drosophila melanogaster genetics, Eye cytology, Eye embryology, Membrane Proteins metabolism, Mutation, Neuroglia cytology, Optic Lobe, Nonmammalian metabolism, Photoreceptor Cells, Invertebrate embryology, Drosophila Proteins genetics, Drosophila melanogaster embryology, Membrane Proteins genetics, Optic Lobe, Nonmammalian embryology

Abstract

The correct targeting of photoreceptor neurons (R-cells) in the developing Drosophila visual system requires multiple guidance systems in the eye-brain complex as well as the precise organization of the target area. Here, we report that the egghead (egh) gene, encoding a glycosyltransferase, is required for a compartment boundary between lamina glia and lobula cortex, which is necessary for appropriate R1-R6 innervation of the lamina. In the absence of egh, R1-R6 axons form a disorganized lamina plexus and some R1-R6 axons project abnormally to the medulla instead of the lamina. Mosaic analysis demonstrates that this is not due to a loss of egh function in the eye or in the neurons and glia of the lamina. Rather, as indicated by clonal analysis and cell-specific genetic rescue experiments, egh is required in cells of the lobula complex primordium which transiently abuts the lamina and medulla in the developing larval brain. In the absence of egh, perturbation of sheath-like glial processes occurs at the boundary region delimiting lamina glia and lobula cortex, and inappropriate invasion of lobula cortex cells across this boundary region disrupts the pattern of lamina glia resulting in inappropriate R1-R6 innervation. This finding underscores the importance of the lamina/lobula compartment boundary in R1-R6 axon targeting.

Published

2005

13. Patterning mechanisms diversify neuroepithelial domains in the Drosophila optic placode

Author

Mishra, Abhishek Kumar, Bernardo-Garcia, F. Javier, Fritsch, Cornelia, Humberg, Tim-Henning, Egger, Boris, and Sprecher, Simon G.

Subjects

Embryology, Neuroepithelial Cells, Gene Expression, Genes, Insect, Eye, Biochemistry, Animals, Genetically Modified, Cell Signaling, Animal Cells, Basic Helix-Loop-Helix Transcription Factors, Medicine and Health Sciences, Drosophila Proteins, Gene Regulatory Networks, Notch Signaling, Receptors, Notch, Drosophila Melanogaster, Gene Expression Regulation, Developmental, Eukaryota, Animal Models, Insects, Experimental Organism Systems, Larva, Photoreceptor Cells, Invertebrate, Drosophila, Cellular Types, Anatomy, Signal Transduction, Research Article, lcsh:QH426-470, Arthropoda, Precursor Cells, Nerve Tissue Proteins, Research and Analysis Methods, Model Organisms, Ocular System, DNA-binding proteins, Genetics, Animals, Hedgehog Proteins, Gene Regulation, Body Patterning, fungi, Optic Lobe, Nonmammalian, Embryos, Organisms, Biology and Life Sciences, Proteins, Cell Biology, Invertebrates, Regulatory Proteins, Repressor Proteins, lcsh:Genetics, Mutation, Hedgehog Signaling, Eyes, Head, Optic Lobes, Developmental Biology, Transcription Factors

Abstract

The central nervous system develops from monolayered neuroepithelial sheets. In a first step patterning mechanisms subdivide the seemingly uniform epithelia into domains allowing an increase of neuronal diversity in a tightly controlled spatial and temporal manner. In Drosophila, neuroepithelial patterning of the embryonic optic placode gives rise to the larval eye primordium, consisting of two photoreceptor (PR) precursor types (primary and secondary), as well as the optic lobe primordium, which during larval and pupal stages develops into the prominent optic ganglia. Here, we characterize a genetic network that regulates the balance between larval eye and optic lobe precursors, as well as between primary and secondary PR precursors. In a first step the proneural factor Atonal (Ato) specifies larval eye precursors, while the orphan nuclear receptor Tailless (Tll) is crucial for the specification of optic lobe precursors. The Hedgehog and Notch signaling pathways act upstream of Ato and Tll to coordinate neural precursor specification in a timely manner. The correct spatial placement of the boundary between Ato and Tll in turn is required to control the precise number of primary and secondary PR precursors. In a second step, Notch signaling also controls a binary cell fate decision, thus, acts at the top of a cascade of transcription factor interactions to define PR subtype identity. Our model serves as an example of how combinatorial action of cell extrinsic and cell intrinsic factors control neural tissue patterning., Author summary Genetic mechanisms patterning neuroepithelial domains are a critical first step to diversify cellular identity of the developing nervous system. How many cells develop from distinct neuroepithelial domains depends on overall size and growth but also on positioning of boundaries. Using the embryonic optic placode of the fruit fly Drosophila melanogaster as a model, we identify basic genetic mechanisms of how distinct domains with different fates emerge from an early, seemingly uniform, neurogenic region. We show that the boundary between two transcription factors is critical to determine how many cells are incorporated in either domain. This is achieved by coordinated interaction of Hedgehog and Notch signaling, which control proliferation and regulate domain-specific transcription factors. The mechanisms employed here in an epithelial placode to determine photoreceptor precursors display similarities with the ones previously identified in the adult compound eye, further supporting the notion of a common developmental program for the larval eye and adult compound eye.

Published

2017