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Know: .patterns of cleavage .sequence of events from fertilization – blastula – gastrula – adult organism . Types of movement during gastrulation . Cleavage in sea urchin . Autonomous specification x conditional specification in sea urchin and C. elegans.
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Know: .patterns of cleavage .sequence of events from fertilization – blastula – gastrula – adult organism . Types of movement during gastrulation . Cleavage in sea urchin . Autonomous specification x conditional specification in sea urchin and C. elegans
8.7 Cleavage in live embryos of the sea urchin Lytechinus variegatus, seen from the side
8.8 Fate map and cell lineage of the sea urchin Strongylocentrotus purpuratus (Part 1)
8.9 Ability of the micromeres to induce presumptive ectodermal cells to acquire other fates
8.10 Ability of the micromeres to induce a secondary axis in sea urchin embryos
8.11 The role of -catenin in specifying the vegetal cells of the sea urchin embryo; -catenin is stained by a fluorescently labeled antibody
8.14 Normal sea urchin development, following the fate of the cellular layers of the blastula (Part 1)
8.14 Normal sea urchin development, following the fate of the cellular layers of the blastula (Part 2)
8.20 Cell rearrangement during the extension of the archenteron in sea urchin embryos
8.22 The imaginal rudiment growing in the left side of the pluteus larva of a sea urchin
8.43 PAR proteins and the establishment of polarity (Part 1)
8.43 PAR proteins and the establishment of polarity (Part 2)
8.44 Segregation of the P-granules into the germ line lineage of the C. elegans embryo
8.45 Deficiencies of intestine and pharynx in skn-1 mutants of C. elegans
8.46 Isolation and recombination experiments show that cell-cell interactions are required for the EMS cell to form intestinal lineage determinants