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Drosophila dorsal/ventral axis detemination How are different tissue types specified at distinct positions on the embryonic dorsal- ventral axis?
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amnio- serosa dorsal ectoderm neuro- ectoderm mesoderm Cell fate specification at the blastoderm stage mesoderm formation fate map dorsal ventral
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Dorsal-Ventral fate map
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Genes identified in a famous screen for Drosophila mutants with embryo patterning defects Torpedo Gurken
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Localized maternal mRNA sets up anterior and posterior poles
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Gurken protein specifies the Anterior-Posterior axis of the Drosophila embryo during oogenesis (Similar to EGF)
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Gurken also signals dorsal pole formation during oogenesis follicle cells anteriorposterior AP V D D V - + - microtubules 71-68 10A gurken expression in the oocyte 10A gurken expression in the oocyte 1-6 migration of nucleus + - - 8 oocyte nucleus
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Expression of the Gurken Message and Protein Between the Oocyte Nucleus and the Dorsal Anterior Cell Membrane
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Gurken signaling inhibits production of an extracellular signal (Spätzle) by follicle cells follicle cells Oocyte pipe expression Ventral follicle cell Pipe (Golgi?) X X Nucleus Wind (ER?) X X X X modified from van Eeden & St.Johnston Gurken = Epidermal Growth Factor (EGF) Torpedo = EGF receptor (in follicle cells)
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Toll Tl - membrane receptor cactus cact - cytoplasmic inhibitor of Dorsal nuclear translocation dorsal dl - transcription factor (morphogen) tube - cytoplasmic protein pelle - ser/thr protein kinase Somatic (follicle cells) ndl, pipe, wbl gd, snk, ea - serine proteases Spätzle spz - ligand Germline (nurse cells) Dorsal protein dorsal RNA Toll protein Spätzle protein Dorsal protein nudel, pipe, wbl amnio serosa dorsal ectoderm neuro- ectoderm mesoderm Dl nuclear protein Maternal effect mutations in dorso-ventral patterning
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Wild type ventralized dorsal mutant cactus mutant dorsalized T1 T2 T3 A1A2 A3A4A5 A6 A7 A8 dorsal and cactus mutants (maternal germline effect) dorsal ventral
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Wild type toll mutant cactus mutant Translocation of Dorsal protein into ventral nuclei but not lateral or dorsal nuclei
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Generation of Dorsal-Ventral Polarity in Drosophila
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Wild type toll mutant Inject wild-type cytoplasm mesoderm neuro-ectoderm (denticle belts) dorsal ectoderm The Toll pathway in dorso-ventral pattern formation into toll mutant eggs dorsalized local rescue ventral dorsal polarity reversal
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Conserved pathway for regulating nuclear transport of transcription factors in Drosophila and mammals
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Cells with highest nuclear Dorsal levels become mesoderm
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Zygotically expressed genes
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Action of Dorsal protein in ventral cells
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High affinity for promoter, Not much Dorsal needed to activate
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Action of Dorsal protein in ventral cells Lower affinity for promoter, More Dorsal needed to activate
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Zygotically expressed genes
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Action of Dorsal protein in ventral cells Snail repression of rhomboid creates domains with distinct gene expression patterns
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twist dpp Dorsal protein dorsal RNA Toll protein Spätzle protein Dorsal protein nudel, pipe, windbeutel Dorso-ventral pattern formation: summary oocyte nucleus dorsal > repression of ventral fate in dorsal follicle cells ventral production of ligand > activation of Toll receptor > graded nuclear uptake of Dorsal morphogen > regulation of zygotic target gene expression > cell fates along DV axis
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Use of a similar regulatory system to pattern insects and vertebrates
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Patterns mesoderm in vertebrates Patterns ectoderm in Drosophila
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Gastrulation in Drosophila
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Schematic representation of gastrulation in Drosophila
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Anterior-posterior patterning in Drosophila
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The fly body plan: each segment has a unique identity and produces distinctive structures 3 head 3 thorax 8 abdomen
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fate maplarva wild-type anteriorbicoid posterioroskar terminaltorso Mutations affecting the antero-posterior axis 3 independent maternal systems: anterior, posterior, terminal single mutants double mutants triple mutants additive phenotypes active systems A P T - P T A - T A P - - - - - P - - - T A - - active systems
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Maternal effect mutations
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Zygotic effect mutations
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Embryo from wild-type mother Embryo from bicoid mother bicoid mutant phenotype
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Wild type blastoderm fate map bicoid mutant Anterior: bicoid is required for head and thorax abdomen head + thorax
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Bicoid mRNA localization in embryo (tethered to microtubules)
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Nuclei divide without cell division in Drosophila to produce a syncytial blastoderm embryo Fig. 9.1
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Bicoid protein gradient in syncytial blastoderm embryo - diffuses after translation from localized mRNA - protein unstable
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