Your search keyword '"Sense Organs growth & development"' showing total 19 results

1. Lateral inhibition in proneural clusters: cis-regulatory logic and default repression by Suppressor of Hairless.

Author

Castro B, Barolo S, Bailey AM, and Posakony JW

Subjects

Animals, Drosophila growth & development, Drosophila Proteins metabolism, Embryo, Nonmammalian, Gene Expression Regulation, Developmental, Helix-Loop-Helix Motifs, Larva, Molecular Sequence Data, Morphogenesis, Neurons physiology, Phenotype, Recombinant Fusion Proteins metabolism, Repressor Proteins metabolism, Sense Organs embryology, Transcription Factors genetics, Transcription, Genetic, Drosophila embryology, Drosophila Proteins genetics, Repressor Proteins genetics, Sense Organs growth & development

Abstract

Lateral inhibition, wherein a single cell signals to its neighbors to prevent them from adopting its own fate, is the best-known setting for cell-cell communication via the Notch (N) pathway. During peripheral neurogenesis in Drosophila, sensory organ precursor (SOP) cells arise within proneural clusters (PNCs), small groups of cells endowed with SOP fate potential by their expression of proneural transcriptional activators. SOPs use N signaling to activate in neighboring PNC cells the expression of multiple genes that inhibit the SOP fate. These genes respond transcriptionally to direct regulation by both the proneural proteins and the N pathway transcription factor Suppressor of Hairless [Su(H)], and their activation is generally highly asymmetric; i.e. only in the inhibited (non-SOP) cells of the PNC, and not in SOPs. We show that the substantially higher proneural protein levels in the SOP put this cell at risk of inappropriately activating the SOP-inhibitory genes, even without input from N-activated Su(H). We demonstrate that this is prevented by direct ;default' repression of these genes by Su(H), acting through the same binding sites it uses for activation in non-SOPs. We show that de-repression of even a single N pathway target gene in the SOP can extinguish the SOP cell fate. Finally, we define crucial roles for the adaptor protein Hairless and the co-repressors Groucho and CtBP in conferring repressive activity on Su(H) in the SOP. Our work elucidates the regulatory logic by which N signaling and the proneural proteins cooperate to create the neural precursor/epidermal cell fate distinction during lateral inhibition.

Published

2005

2. Opposing inputs by Hedgehog and Brinker define a stripe of hairy expression in the Drosophila leg imaginal disc.

Author

Kwon C, Hays R, Fetting J, and Orenic TV

Subjects

Animals, Animals, Genetically Modified, Basic Helix-Loop-Helix Transcription Factors, Body Patterning genetics, Drosophila growth & development, Drosophila Proteins metabolism, Enhancer Elements, Genetic, Gene Expression Regulation, Developmental, Hedgehog Proteins, Insect Proteins metabolism, Mutation, Repressor Proteins metabolism, Response Elements, Sense Organs growth & development, Signal Transduction, Transcription Factors metabolism, Drosophila genetics, Drosophila Proteins genetics, Insect Proteins genetics, Lower Extremity growth & development, Repressor Proteins genetics, Transcription Factors genetics

Abstract

The sensory organs of the Drosophila adult leg provide a simple model system with which to investigate pattern-forming mechanisms. In the leg, a group of small mechanosensory bristles is organized into a series of longitudinal rows, a pattern that depends on periodic expression of the hairy gene (h) and the proneural genes achaete (ac) and scute (sc). Expression of ac in longitudinal stripes in prepupal leg discs defines the positions of the mechanosensory bristle rows. The ac/sc expression domains are delimited by the Hairy repressor, which is itself periodically expressed. In order to gain insight into the molecular mechanisms involved in leg sensory organ patterning, we have analyzed a Hedgehog (Hh)- and Decapentaplegic (Dpp)-responsive enhancer of the h gene, which directs expression of h in a narrow stripe in the dorsal leg imaginal disc (the D-h stripe). Our studies suggest that the domain of D-h expression is defined by the overlap of Hh and high-level Dpp signaling. We find that the D-h enhancer consists of a Hh-responsive activation element (HHRE) and a repression element (REPE), which responds to the transcriptional repressor Brinker (Brk). The HHRE directs expression of h in a broad stripe along the anteroposterior (AP) compartment boundary. HHRE-directed expression is refined along the AP and dorsoventral axes by Brk1, acting through the REPE. In D-h-expressing cells, Dpp signaling is required to block Brk-mediated repression. This study elucidates a molecular mechanism for integration of the Hh and Dpp signals, and identifies a novel function for Brk as a repressor of Hh-target genes.

Published

2004

3. Integration of complex larval chemosensory organs into the adult nervous system of Drosophila.

Author

Gendre N, Lüer K, Friche S, Grillenzoni N, Ramaekers A, Technau GM, and Stocker RF

Subjects

Animals, Cell Death, Cell Division, Female, Larva, Metamorphosis, Biological physiology, Microscopy, Confocal, Nervous System cytology, Pharynx cytology, Pharynx growth & development, Pupa, Sense Organs cytology, Drosophila growth & development, Nervous System growth & development, Sense Organs growth & development

Abstract

The sense organs of adult Drosophila, and holometabolous insects in general, derive essentially from imaginal discs and hence are adult specific. Experimental evidence presented here, however, suggests a different developmental design for the three largely gustatory sense organs located along the pharynx. In a comprehensive cellular analysis, we show that the posteriormost of the three organs derives directly from a similar larval organ and that the two other organs arise by splitting of a second larval organ. Interestingly, these two larval organs persist despite extensive reorganization of the pharynx. Thus, most of the neurons of the three adult organs are surviving larval neurons. However, the anterior organ includes some sensilla that are generated during pupal stages. Also, we observe apoptosis in a third larval pharyngeal organ. Hence, our experimental data show for the first time the integration of complex, fully differentiated larval sense organs into the nervous system of the adult fly and demonstrate the embryonic origin of their neurons. Moreover, they identify metamorphosis of this sensory system as a complex process involving neuronal persistence, generation of additional neurons and neuronal death. Our conclusions are based on combined analysis of reporter expression from P[GAL4] driver lines, horseradish peroxidase injections into blastoderm stage embryos, cell labeling via heat-shock-induced flip-out in the embryo, bromodeoxyuridine birth dating and staining for programmed cell death. They challenge the general view that sense organs are replaced during metamorphosis.

Published

2004

4. The glial cell undergoes apoptosis in the microchaete lineage of Drosophila.

Author

Fichelson P and Gho M

Subjects

Animals, Animals, Genetically Modified, Animals, Newborn, Axons physiology, Cell Lineage, Cell Survival, Cysteine Proteinase Inhibitors genetics, DNA-Binding Proteins, Drosophila genetics, Drosophila Proteins genetics, Drosophila Proteins metabolism, Epithelial Cells, Epithelium growth & development, Gene Expression Regulation, Developmental, Inhibitor of Apoptosis Proteins, Microscopy, Confocal methods, Nerve Tissue Proteins genetics, Nerve Tissue Proteins metabolism, Neuropeptides genetics, Neuropeptides metabolism, Nuclear Proteins genetics, Nuclear Proteins metabolism, Phagocytosis physiology, Pupa, Trans-Activators genetics, Trans-Activators metabolism, Viral Proteins genetics, Apoptosis physiology, Drosophila growth & development, Neuroglia cytology, Sense Organs cytology, Sense Organs growth & development, Transcription Factors

Abstract

Apoptosis plays a major role in vertebrate and invertebrate development. The adult Drosophila thoracic microchaete is a mechanosensory organ whose development has been extensively studied as a model of how cell division and cell determination intermingle. This sensory organ arises from a cell lineage that produces a glial cell and four other cells that form the organ. In this study, using an in vivo approach as well as fixed material, we show that the glial cell undergoes nucleus fragmentation shortly after birth. Fragmentation was blocked after overexpression of the caspase inhibitor p35 or removal of the pro-apoptotic genes reaper, hid and grim, showing that the glial cell undergoes apoptosis. Moreover, it seems that fragments are eliminated from the epithelium by mobile macrophages. Forcing survival of the glial cells induces precocious axonal outgrowth but does not affect final axonal patterning and connectivity. However, under these conditions, glial cells do not fragment but leave the epithelium by a mechanism that is reminiscent of cell competition. Finally, we present evidences showing that glial cells are committed to apoptosis independently of gcm and prospero expression. We suggest that apoptosis is triggered by a cell autonomous mechanism.

Published

2003

5. A novel thioredoxin-like protein encoded by the C. elegans dpy-11 gene is required for body and sensory organ morphogenesis.

Author

Ko FC and Chow KL

Subjects

Amino Acid Sequence, Animals, Caenorhabditis elegans growth & development, Chromosome Mapping, Molecular Sequence Data, Morphogenesis, Mutation, Oxidation-Reduction, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Caenorhabditis elegans genetics, Caenorhabditis elegans Proteins genetics, Genes, Helminth, Membrane Proteins genetics, Sense Organs growth & development

Abstract

Sensory ray morphogenesis in C. elegans requires active cellular interaction regulated by multiple genetic activities. We report here the cloning of one of these genes, dpy-11, which encodes a membrane-associated thioredoxin-like protein. The DPY-11 protein is made exclusively in the hypodermis and resides in the cytoplasmic compartment. Whereas the TRX domain of DPY-11 displays a catalytic activity in vitro, mapping of lesions in different mutant alleles and functional analysis of deletion transgenes reveal that both this enzymatic activity and transmembrane topology are essential for determining body shape and ray morphology. Based on the abnormal features in both the expressing and non-expressing ray cells, we propose that the DPY-11 is required in the hypodermis for modification of its substrates. In turn, ray cell interaction and the whole morphogenetic process can be modulated by these substrate molecules.

Published

2002

6. Sensory neurons of the Atonal lineage pioneer the formation of glomeruli within the adult Drosophila olfactory lobe.

Author

Jhaveri D and Rodrigues V

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors, Cell Lineage, Drosophila Proteins, Interneurons cytology, Models, Neurological, Nerve Tissue Proteins, Neuroglia cytology, Olfactory Pathways cytology, Sense Organs cytology, Sense Organs growth & development, rac GTP-Binding Proteins isolation & purification, DNA-Binding Proteins isolation & purification, Drosophila growth & development, Neurons, Afferent cytology, Olfactory Pathways growth & development, Smell physiology

Abstract

The first centers for processing of odor information by animals lie in the olfactory lobe. Sensory neurons from the periphery synapse with interneurons in anatomically recognizable units, termed glomeruli, seen in both insects and vertebrates. The mechanisms that underlie the formation of functional maps of the odor-world in the glomeruli within the olfactory lobe remains unclear. We address the basis of sensory targeting in the fruitfly Drosophila and show that one class of sensory neurons, those of the Atonal lineage, plays a crucial role in glomerular patterning. Atonal-dependent neurons pioneer the segregation of other classes of sensory neurons into distinct glomeruli. Furthermore, correct sensory innervation is necessary for the arborization of projection neurons into glomeruli and for the elaboration of processes of central glial cells into the lobe.

Published

2002

7. Cell migration in the postembryonic development of the fish lateral line.

Author

Sapède D, Gompel N, Dambly-Chaudière C, and Ghysen A

Subjects

Animals, Body Patterning, Cell Lineage, Fishes anatomy & histology, Fishes embryology, Mechanoreceptors embryology, Mechanoreceptors growth & development, Microscopy, Video, Neuroglia cytology, Oryzias, Sense Organs embryology, Sense Organs growth & development, Species Specificity, Zebrafish, Cell Movement, Fishes growth & development, Mechanoreceptors cytology, Sense Organs cytology

Abstract

We examine at the cellular level the postembryonic development of the posterior lateral line in the zebrafish. We show that the first wave of secondary neuromasts is laid down by a migrating primordium, primII. This primordium originates from a cephalic region much like the primordium that formed the primary line during embryogenesis. PrimII contributes to both the lateral and the dorsal branches of the posterior lateral line. Once they are deposited by the primordium, the differentiating neuromasts induce the specialisation of overlying epidermal cells into a pore-forming annulus, and the entire structure begins to migrate ventrally across the epithelium. Thus the final two-dimensional pattern depends on the combination of two orthogonal processes: anteroposterior waves of neuromast formation and dorsoventral migration of individual neuromasts. Finally, we examine how general these migratory processes can be by describing two fish species with very different adult patterns, Astyanax fasciatus (Mexican blind cavefish) and Oryzias latipes (medaka). We show that their primary patterns are nearly identical to that observed in zebrafish embryos, and that their postembryonic growth relies on the same combination of migratory processes that we documented in the case of the zebrafish.

Published

2002

8. Postembryonic development of the posterior lateral line in zebrafish.

Author

Ledent V

Subjects

Animals, Body Patterning, Cell Movement, Extremities embryology, Extremities growth & development, Head growth & development, Mechanoreceptors cytology, Mechanoreceptors embryology, Sense Organs cytology, Sense Organs embryology, Species Specificity, Stem Cells, Tail growth & development, Mechanoreceptors growth & development, Sense Organs growth & development, Zebrafish anatomy & histology

Abstract

We examine how the posterior lateral line of the zebrafish grows and evolves from the simple midbody line present at the end of embryogenesis into the complex adult pattern. Our results suggest that secondary neuromasts do not form through budding from the embryonic line, but rather new waves of neuromasts are added anteroposteriorly. We propose that the developmental module that builds the embryonic pattern of neuromasts is used repeatedly during postembryonic development and that additional (secondary) primordia generate the additional neuromasts. We show that differentiated neuromasts migrate ventrally, and eventually generate "stitches" by successive bisections. We also examine the repatterning of the terminal neuromasts, which anticipates the up-bending of the tail leading to the highly asymmetrical caudal fin of the adult (which develops exclusively from the ventral part of the tail). Because terminal repatterning affects all aspects of tail formation, including its sensory development, we speculate that terminal axis bending may have become intimately associated with the terminal Hox genes before the appearance of the tetrapod lineage.

Published

2002

9. The novel C. elegans gene sop-3 modulates Wnt signaling to regulate Hox gene expression.

Author

Zhang H and Emmons SW

Subjects

Amino Acid Sequence, Animals, Caenorhabditis elegans anatomy & histology, Caenorhabditis elegans embryology, Caenorhabditis elegans genetics, Genes, Helminth, Genes, Reporter, Genes, Suppressor, Helminth Proteins chemistry, Helminth Proteins metabolism, Male, Molecular Sequence Data, Proto-Oncogene Proteins genetics, Sense Organs growth & development, Sense Organs physiology, Signal Transduction, Tail anatomy & histology, Tail growth & development, Transcription Factors genetics, Transcription Factors metabolism, Wnt Proteins, Caenorhabditis elegans growth & development, Caenorhabditis elegans Proteins, Cell Lineage, Gene Expression Regulation, Developmental, Genes, Homeobox, Helminth Proteins genetics, Proto-Oncogene Proteins metabolism, Zebrafish Proteins

Abstract

We describe the properties of a new gene, sop-3, that is required for the regulated expression of a C. elegans Hox gene, egl-5, in a postembryonic neuroectodermal cell lineage. Regulated expression of egl-5 in this cell lineage is necessary for development of the sensory rays of the male tail. sop-3 encodes a predicted novel protein of 1475 amino acids without clear homologs in other organisms. However, the sequence contains motifs consisting of homopolymeric runs of amino acids found in several other transcriptional regulators, some of which also act in Hox gene regulatory pathways. The genetic properties of sop-3 are very similar to those of sop-1, which encodes a component of the transcriptional Mediator complex, and mutations in the two genes are synthetic lethal. This suggests that SOP-3 may act at the level of the Mediator complex in regulating transcription initiation. In a sop-3 loss-of-function background, egl-5 is expressed ectopically in lineage branches that normally do not express this gene. Such expression is dependent on the Hox gene mab-5, as it is in branches where egl-5 is normally expressed. Ectopic egl-5 expression is also dependent on the Wnt pathway. Thus, sop-3 contributes to the combinatorial control of egl-5 by blocking egl-5 activation by MAB-5 and the Wnt pathway in inappropriate lineage branches.

Published

2001

10. The EGF receptor and N signalling pathways act antagonistically in Drosophila mesothorax bristle patterning.

Author

Culí J, Martín-Blanco E, and Modolell J

Subjects

Animals, Animals, Genetically Modified, Body Patterning genetics, Drosophila melanogaster genetics, Genes, Insect, In Situ Hybridization, Models, Biological, Sense Organs growth & development, Sense Organs metabolism, Signal Transduction, Wings, Animal growth & development, ras Proteins metabolism, Drosophila melanogaster growth & development, Drosophila melanogaster metabolism, ErbB Receptors metabolism

Abstract

An early step in the development of the large mesothoracic bristles (macrochaetae) of Drosophila is the expression of the proneural genes of the achaete-scute complex (AS-C) in small groups of cells (proneural clusters) of the wing imaginal disc. This is followed by a much increased accumulation of AS-C proneural proteins in the cell that will give rise to the sensory organ, the SMC (sensory organ mother cell). This accumulation is driven by cis-regulatory sequences, SMC-specific enhancers, that permit self-stimulation of the achaete, scute and asense proneural genes. Negative interactions among the cells of the cluster, triggered by the proneural proteins and mediated by the Notch receptor (lateral inhibition), block this accumulation in most cluster cells, thereby limiting the number of SMCs. Here we show that the proneural proteins trigger, in addition, positive interactions among cells of the cluster that are mediated by the Epidermal growth factor receptor (EGFR) and the Ras/Raf pathway. These interactions, which we denominate 'lateral co-operation', are essential for macrochaetae SMC emergence. Activation of the EGFR/Ras pathway appears to promote proneural gene self-stimulation mediated by the SMC-specific enhancers. Excess EGFR signalling can overrule lateral inhibition and allow adjacent cells to become SMCs and sensory organs. Thus, the EGFR and Notch pathways act antagonistically in notum macrochaetae determination.

Published

2001

11. A novel WD40 protein, CHE-2, acts cell-autonomously in the formation of C. elegans sensory cilia.

Author

Fujiwara M, Ishihara T, and Katsura I

Subjects

Amino Acid Sequence, Animals, Base Sequence, Caenorhabditis elegans genetics, Gene Expression Regulation, Developmental, Larva, Molecular Sequence Data, Mutation, Neurons, Afferent, Repetitive Sequences, Amino Acid, Sense Organs growth & development, Caenorhabditis elegans growth & development, Cilia physiology, Helminth Proteins genetics, Helminth Proteins metabolism

Abstract

To elucidate the mechanism of sensory cilium formation, we analyzed mutants in the Caenorhabditis elegans che-2 gene. These mutants have extremely short cilia with an abnormal posterior projection, and show defects in behaviors that are mediated by ciliated sensory neurons. The che-2 gene encodes a new member of the WD40 protein family, suggesting that it acts in protein-protein interaction. Analysis of mutation sites showed that both the amino-terminal WD40 repeats and the carboxyl-terminal non-WD40 domain are necessary for the CHE-2 function. CHE-2-tagged green fluorescent protein is localized at the cilia of almost all the ciliated sensory neurons. Expression of che-2 in a subset of sensory neurons of a che-2 mutant by using a heterologous promoter resulted in restoration of the functions and cilium morphology of only the che-2-expressing neurons. Thus, che-2 acts cell-autonomously. This technique can be used in the future for determining the function of each type of che-2-expressing sensory neuron. Using green fluorescent protein, we found that the extension of cilia in wild-type animals took place at the late embryonic stage, whereas the cilia of che-2 mutant animals remained always short during development. Hence, the abnormal posterior projection is due to the inability of cilia to extend, rather than degeneration of cilia once correctly formed. Expression of che-2 in a che-2 mutant under a heat shock promoter showed that the extension of cilia, surprisingly, can occur even at the adult stage, and that such cilia can function apparently normally in behavior.

Published

1999

12. A glial cell arises from an additional division within the mechanosensory lineage during development of the microchaete on the Drosophila notum.

Author

Reddy GV and Rodrigues V

Subjects

Animals, Animals, Genetically Modified, Cell Division, Drosophila cytology, Drosophila genetics, ELAV Proteins, Gene Expression Regulation, Developmental, Genes, Insect, Homeodomain Proteins genetics, Insect Proteins genetics, Models, Biological, Nerve Tissue Proteins genetics, Neuroglia cytology, Neuroglia metabolism, Nuclear Proteins genetics, Ribonucleoproteins genetics, Sense Organs cytology, Sense Organs growth & development, Sense Organs metabolism, Stem Cells cytology, Stem Cells metabolism, Drosophila growth & development, Drosophila Proteins, Transcription Factors

Abstract

We have used different cell markers to trace the development of the sensory cells of the thoracic microchaete. Our results dictate a revision in the currently accepted model for cell lineage within the mechanosensory bristle. The sensory organ progenitor divides to form two secondary progenitors: PIIa and PIIb. PIIb divides first to give rise to a tertiary progenitor-PIII and a glial cell. This is followed by division of PIIa to form the shaft and socket cells as described before. PIII expresses high levels of Elav and low levels of Prospero and divides to produce neuron and sheath. Its sibling cell expresses low Elav and high Prospero and is recognized by the glial marker, Repo. This cell migrates away from the other cells of the lineage following differentiation. The proposed modification in lineage has important implications for previous studies on sibling cell fate choice and cell fate specification in sensory systems.

Published

1999

13. The spineless-aristapedia and tango bHLH-PAS proteins interact to control antennal and tarsal development in Drosophila.

Author

Emmons RB, Duncan D, Estes PA, Kiefel P, Mosher JT, Sonnenfeld M, Ward MP, Duncan I, and Crews ST

Subjects

Alleles, Animals, Animals, Genetically Modified, Aryl Hydrocarbon Receptor Nuclear Translocator, Base Sequence, Carrier Proteins chemistry, Carrier Proteins genetics, DNA, Complementary genetics, Dimerization, Drosophila genetics, Enhancer Elements, Genetic, Extremities growth & development, Gene Expression Regulation, Developmental, Genes, Insect, Insect Proteins chemistry, Insect Proteins genetics, Mutation, Phenotype, Protein Structure, Quaternary, Receptors, Aryl Hydrocarbon chemistry, Receptors, Aryl Hydrocarbon genetics, Sense Organs growth & development, Carrier Proteins metabolism, DNA-Binding Proteins, Drosophila growth & development, Drosophila metabolism, Drosophila Proteins, Insect Proteins metabolism, Receptors, Aryl Hydrocarbon metabolism, Transcription Factors

Abstract

The Drosophila spineless (ss) gene encodes a basic-helix-loop-helix-PAS transcription factor that is required for proper specification of distal antennal identity, establishment of the tarsal regions of the legs, and normal bristle growth. ss is the closest known homolog of the mammalian aryl hydrocarbon receptor (Ahr), also known as the dioxin receptor. Dioxin and other aryl hydrocarbons bind to the PAS domain of Ahr, causing Ahr to translocate to the nucleus, where it dimerizes with another bHLH-PAS protein, the aryl hydrocarbon receptor nuclear translocator (Arnt). Ahr:Arnt heterodimers then activate transcription of target genes that encode enzymes involved in metabolizing aryl hydrocarbons. In this report, we present evidence that Ss functions as a heterodimer with the Drosophila ortholog of Arnt, Tango (Tgo). We show that the ss and tgo genes have a close functional relationship: loss-of-function alleles of tgo were recovered as dominant enhancers of a ss mutation, and tgo-mutant somatic clones show antennal, leg, and bristle defects almost identical to those caused by ss(-) mutations. The results of yeast two-hybrid assays indicate that the Ss and Tgo proteins interact directly, presumably by forming heterodimers. Coexpression of Ss and Tgo in Drosophila SL2 cells causes transcriptional activation of reporters containing mammalian Ahr:Arnt response elements, indicating that Ss:Tgo heterodimers are very similar to Ahr:Arnt heterodimers in DNA-binding specificity and transcriptional activation ability. During embryogenesis, Tgo is localized to the nucleus at sites of ss expression. This localization is lost in a ss null mutant, suggesting that Tgo requires heterodimerization for translocation to the nucleus. Ectopic expression of ss causes coincident ectopic nuclear localization of Tgo, independent of cell type or developmental stage. This suggests that the interaction of Ss and Tgo does not require additional signals, unlike the ligand-dependent interaction of Ahr and Arnt. Despite the very different biological roles of Ahr and Arnt in insects and mammals, the molecular mechanisms by which these proteins function appear to be largely conserved.

Published

1999

14. Revisiting the Drosophila microchaete lineage: a novel intrinsically asymmetric cell division generates a glial cell.

Author

Gho M, Bellaïche Y, and Schweisguth F

Subjects

Animals, Animals, Genetically Modified, Cell Differentiation, Cell Division, Cell Movement, Epithelial Cells physiology, Green Fluorescent Proteins, Luminescent Proteins analysis, Luminescent Proteins genetics, Microscopy, Confocal, Pupa, Sense Organs cytology, Spindle Apparatus ultrastructure, Time Factors, beta-Galactosidase analysis, beta-Galactosidase genetics, Drosophila growth & development, Epithelial Cells cytology, Neuroglia cytology, Neurons cytology, Sense Organs growth & development

Abstract

The bristle mechanosensory organs of the adult fly are composed of four different cells that originate from a single precursor cell, pI, via two rounds of asymmetric cell division. Here, we have examined the pattern of cell divisions in this lineage by time-lapse confocal microscopy using GFP imaging and by immunostaining analysis. pI divided within the plane of the epithelium and along the anteroposterior axis to give rise to an anterior cell, pIIb, and a posterior cell, pIIa. pIIb divided prior to pIIa to generate a small subepithelial cell and a larger daughter cell, named pIIIb. This unequal division, oriented perpendicularly to the epithelium plane, has not been described previously. pIIa divided after pIIb, within the plane of the epithelium and along the AP axis, to produce a posterior socket cell and an anterior shaft cell. Then pIIIb divided perpendicularly to the epithelium plane to generate a basal neurone and an apical sheath cell. The small subepithelial pIIb daughter cell was identified as a sense organ glial cell: it expressed glial cell missing, a selector gene for the glial fate and migrated away from the sensory cluster along extending axons. We propose that mechanosensory organ glial cells, the origin of which was until now unknown, are generated by the asymmetric division of pIIb cells. Both Numb and Prospero segregated specifically into the basal glial and neuronal cells during the pIIb and pIIIb divisions, respectively. This revised description of the sense organ lineage provides the basis for future studies on how polarity and fate are regulated in asymmetrically dividing cells.

Published

1999

15. Regulation of the spalt/spalt-related gene complex and its function during sensory organ development in the Drosophila thorax.

Author

de Celis JF, Barrio R, and Kafatos FC

Subjects

Animals, Cell Differentiation genetics, Drosophila growth & development, Gene Expression Regulation, Developmental, Hedgehog Proteins, Homeodomain Proteins metabolism, Insect Proteins genetics, Insect Proteins metabolism, Proto-Oncogene Proteins genetics, Proto-Oncogene Proteins metabolism, Sense Organs cytology, Sense Organs metabolism, Transcription Factors metabolism, Wings, Animal growth & development, Wnt1 Protein, Drosophila genetics, Drosophila Proteins, Homeodomain Proteins genetics, Sense Organs growth & development, Thorax growth & development, Transcription Factors genetics

Abstract

The nuclear proteins Spalt and Spalt-related belong to a conserved family of transcriptional regulators characterised by the presence of double zinc-finger domains. In the wing, they are regulated by the secreted protein Decapentaplegic and participate in the positioning of the wing veins. Here, we identify regulatory regions in the spalt/spalt-related gene complex that direct expression in the wing disc. The regulatory sequences are organised in independent modules, each of them responsible for expression in particular domains of the wing imaginal disc. In the thorax, spalt and spalt-related are expressed in a restricted domain that includes most proneural clusters of the developing sensory organs in the notum, and are regulated by the signalling molecules Wingless, Decapentaplegic and Hedgehog. We find that spalt/spalt-related participate in the development of sensory organs in the thorax, mainly in the positioning of specific proneural clusters. Later, the expression of at least spalt is eliminated from the sensory organ precursor cells and this is a requisite for the differentiation of these cells. We postulate that spalt and spalt-related belong to a category of transcriptional regulators that subdivide the thorax into expression domains (prepattern) required for the localised activation of proneural genes.

Published

1999

16. Antagonism of EGFR and notch signalling in the reiterative recruitment of Drosophila adult chordotonal sense organ precursors.

Author

zur Lage P and Jarman AP

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Drosophila genetics, ErbB Receptors genetics, Extremities growth & development, Gene Expression Regulation, Developmental, Larva, Membrane Proteins genetics, Nerve Tissue Proteins, Neurons metabolism, Receptors, Notch, Sense Organs innervation, Signal Transduction, Drosophila growth & development, Drosophila Proteins, ErbB Receptors metabolism, Membrane Proteins metabolism, Sense Organs growth & development, Sense Organs metabolism

Abstract

The selection of Drosophila melanogaster sense organ precursors (SOPs) for sensory bristles is a progressive process: each neural equivalence group is transiently defined by the expression of proneural genes (proneural cluster), and neural fate is refined to single cells by Notch-Delta lateral inhibitory signalling between the cells. Unlike sensory bristles, SOPs of chordotonal (stretch receptor) sense organs are tightly clustered. Here we show that for one large adult chordotonal SOP array, clustering results from the progressive accumulation of a large number of SOPs from a persistent proneural cluster. This is achieved by a novel interplay of inductive epidermal growth factor-receptor (EGFR) and competitive Notch signals. EGFR acts in opposition to Notch signalling in two ways: it promotes continuous SOP recruitment despite lateral inhibition, and it attenuates the effect of lateral inhibition on the proneural cluster equivalence group, thus maintaining the persistent proneural cluster. SOP recruitment is reiterative because the inductive signal comes from previously recruited SOPs.

Published

1999

17. Only a subset of the binary cell fate decisions mediated by Numb/Notch signaling in Drosophila sensory organ lineage requires Suppressor of Hairless.

Author

Wang S, Younger-Shepherd S, Jan LY, and Jan YN

Subjects

Animals, Cell Differentiation, Cell Division, Drosophila cytology, Drosophila genetics, Enhancer Elements, Genetic, Female, Genes, Dominant, Genes, Insect, Juvenile Hormones genetics, Male, Membrane Proteins genetics, Mutation, Receptors, Notch, Repressor Proteins genetics, Sense Organs cytology, Signal Transduction, Drosophila growth & development, Drosophila Proteins, Sense Organs growth & development

Abstract

In Drosophila, an adult external sensory organ (bristle) consists of four distinct cells which arise from a sensory organ precursor cell via two rounds of asymmetric divisions. The sensory organ precursor cell first divides to generate two secondary precursor cells, IIa and IIb. The IIa cell then divides to produce the hair cell and the socket cell. Shortly after, the IIb cell divides to generate the neuron and the sheath cell. The membrane-associated protein Numb has been shown to be required for the first two asymmetric divisions. We now report that a new hypomorphic numb mutant not only displays a double-socket phenotype, due to a hair cell to socket cell transformation, but also a double-sheath phenotype, due to a neuron to sheath cell transformation. This provides direct evidence that numb functions in the neuron/sheath cell lineage as well. Those results, together with our observation from immunofluorescence analysis that Numb forms a crescent in the dividing IIa and IIb cells suggest that asymmetric localization of Numb is important for the cell fate determination in all three asymmetric cell divisions in the sensory organ lineage. Interestingly, we found that in the hair/socket cell lineage but not the neuron/sheath cell lineage, a Suppressor of Hairless mutation acts as a dominant suppressor of numb mutations whereas Hairless mutations act as enhancers of numb. Moreover, epistasis analysis indicates that Suppressor of Hairless acts downstream of numb, and results from in vitro binding analysis suggest that the genetic interaction between numb and Hairless may occur through direct protein-protein interaction. These studies reveal that Suppressor of Hairless is required for only a subset of the asymmetric divisions that depend on the function of numb and Notch.

Published

1997

18. Postembryonic patterns of expression of cut, a locus regulating sensory organ identity in Drosophila.

Author

Blochlinger K, Jan LY, and Jan YN

Subjects

Animals, Central Nervous System physiology, Drosophila Proteins, Drosophila melanogaster embryology, Female, Homeodomain Proteins, Immunohistochemistry, Malpighian Tubules physiology, Mutation genetics, Ovary physiology, Transcription Factors, Wings, Animal growth & development, Drosophila melanogaster genetics, Gene Expression physiology, Insect Hormones genetics, Nerve Tissue Proteins genetics, Nuclear Proteins genetics, Sense Organs growth & development

Abstract

The cut locus is both necessary and sufficient to specify the identity of a class of sensory organs in Drosophila embryos. It is also expressed in and required for the development of a number of other embryonic tissues, such as the central nervous system, the Malpighian tubules and the tracheal system. We here describe the expression of cut in the precursors of adult sensory organs. We also show that cut is expressed in cells of the prospective wing margin and correlate the wing margin phenotype caused by two cut mutations with altered cut expression patterns. Finally, we observe cut-expressing cells in other adult tissues, including Malpighian tubules, muscles, the central nervous system and ovarian follicle cells.

Published

1993

19. Development of adult sensilla on the wing and notum of Drosophila melanogaster.

Author

Hartenstein V and Posakony JW

Subjects

Animals, Cell Differentiation physiology, Cell Division, Microscopy, Electron, Sense Organs ultrastructure, Wings, Animal anatomy & histology, Drosophila melanogaster growth & development, Sense Organs growth & development

Abstract

We have investigated the temporal pattern of appearance, cell lineage, and cytodifferentiation of selected sensory organs (sensilla) of adult Drosophila. This analysis was facilitated by the discovery that the monoclonal antibody 22C10 labels not only the neuron of the developing sensillum organ, but the accessory cells as well. The precursors of the macrochaetes and the recurved (chemosensory) bristles of the wing margin divide around and shortly after puparium formation, while those of the microchaetes and the stout and slender (mechanosensory) bristles of the wing margin divide between 9 h and 18 h after puparium formation (apf). The onset of sensillum differentiation follows the terminal precursor division within a few hours. Four of the cells in an individual microchaete organ are clonally related: A single first-order precursor cell divides to produce two second-order precursors; one of these divides into the neuron and thecogen cell, the other into the trichogen cell and tormogen cell. Along the anterior wing margin, two rounds of division generate the cells of the mechanosensory sensilla; here, no strict clonal relationship seems to exist between the cells of an individual sensillum. At the time of sensillum precursor division, many other, non-sensillum-producing cells within the notum and wing proliferate as well. This mitotic activity follows a spatially non-random pattern.

Published

1989