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Journal ArticleDOI

The ultrastructure of the developing leg ofDrosophila melanogaster.

TL;DR: The ultrastructure of the imaginal discs of Drosophila melanogaster was compared with that of other chitogenous tissues with different developmental capacities, namely, embryonic, larval, pupal and adult epidermis and it was concluded that gap junctions may be a more likely site for the intercellular communication involved in pattern formation than septate desmosomes.
Abstract: The ultrastructure of the imaginal discs ofDrosophila melanogaster was compared with that of other chitogenous tissues with different developmental capacities, namely, embryonic, larval, pupal and adult epidermis. Attention was paid to features which might be correlated with specific morphogenetic activities. Previous morphological studies of imaginal discs of Diptera were analyzed in detail and a somewhat revised view of imaginal disc structure emerged. The results reveal that the imaginal discs ofD. melanogaster consist of three types of cells: cells of the single layered disc epithelium, adepithelial cells and nerves. Four types of specialized junctions connect the cells of the disc epithelium: zonulae adhaerens, septate desmosomes, gap junctions and cytoplasmic bridges. The junctions are discussed in relation to their possible roles in adhesion and intercellular communication. It was concluded that gap junctions may be a more likely site for the intercellular communication involved in pattern formation than septate desmosomes. Evidence is presented that adepithelial cells are the precursors of imaginal muscles and that some cell lines (atelotypic) are in fact lines of adepithelial cells which can differentiate into muscle.Specific imaginal discs can be easily recognized by their overall morphology, i.e. patterns of folds. However, no ultrastructural features were found which we could correlate with the state of determination of the cells. Most differences in the ultrastructure of different discs at several developmental stages were attributable to different phases of cuticle secretion. The cells of the imaginal disc epithelium are packed with ribosomes but very little rough ER. The amount of rough ER increases rapidly at puparium formation. Cuticulin is recognizable 4-6 hours after puparium formation. Six hours after puparium formation, the cells of the disc epithelium are secreting the epicuticle of the pupa. As the imaginal disc of a leg everts from a folded sac to the tubular pupal leg, the cells of the disc epithelium change from tall columnar to cuboidal. A loss of microtubules in the long axis of the columnar cells accompanies this change. Prepupal morphogenesis of the leg appears to be caused by the change in cell shape. Evidence is presented which is incompatible with previous explanations of the mechanism of eversion of imaginal discs.There is some turnover of the cells of the disc epithelium as evidenced by autophagy and the occasional heterophagy of a dead neighbor. However this does not appear to be an important factor in the morphogenesis of discs. Plant peroxidase which was used as a tracer of proteins in the blood was taken up from the hemolymph by the disc epithelium. Imaginal disc cells contain many lipid droplets which coalesce and are replaced by glycogen during the prepupal period.
Citations
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Journal ArticleDOI
TL;DR: Genetic mosaics show that the cells of each ommatidium are not derived from a single mother cell; the cells appear to be recruited at random at the morphogenetic front.

996 citations

Journal ArticleDOI
09 Aug 1991-Cell
TL;DR: The results suggest that a signal transduction process involving guanine nucleotides occurs at the septate junction and is necessary for cell proliferation control in Drosophila epithelia.

918 citations

Journal ArticleDOI
TL;DR: The results raise the possibility that homozygous loss of the myotonic dystrophy kinase may contribute to the development of multiple pilomatrixomas and with other tumors including neurofibromas and parathyroid adenomas.
Abstract: Homozygous loss of the warts (wts) gene of Drosophila, caused by mitotic recombination in somatic cells, leads to the formation of cell clones that are fragmented, rounded, and greatly overgrown compared with normal controls. Therefore, the gene is required for the control of the amount and direction of cell proliferation as well as for normal morphogenesis. The absence of wts function also results in apical hypertrophy of imaginal disc epithelial cells. Secretion of cuticle over and between the domed apical surfaces of these cells leads to a honeycomb-like structure and gives the superficial wart-like phenotype of mitotic clones on the adult. One wts allele allows survival of homozygotes to the late larval stage, and these larvae show extensive imaginal disc overgrowth. Because of the excess growth and abnormalities of differentiation that follow homozygous loss, we consider wts to be a tumor suppressor gene. The wts gene is defined by the breakpoints of overlapping deficiencies in the right telomeric region of chromosome 3, region 100A, and by lethal P-element insertions and excisions. It encodes a protein kinase that is most similar to human myotonic dystrophy kinase, the Neurospora cot-1 protein kinase, two cell-cycle regulated kinases of yeast, and several putative kinases from plants. These proteins define a new subfamily of protein kinases that are closely related to but distinct from the cyclic AMP-dependent kinases. Although myotonic dystrophy is defined by a neuromuscular disorder, it is sometimes associated with multiple pilomatrixomas, which are otherwise rare epithelial tumors, and with other tumors including neurofibromas and parathyroid adenomas. Our results raise the possibility that homozygous loss of the myotonic dystrophy kinase may contribute to the development of these tumors.

859 citations

Journal ArticleDOI
TL;DR: A sequence of 51 visible changes is described during the course of metamorphosis in Drosophila melanogaster, and a series of 24 convenient stages is defined for use in the experimental analysis and exploitation of this part of the insect life cycle.
Abstract: A sequence of 51 visible changes is described during the course of metamorphosis in Drosophila melanogaster, and a series of 24 convenient stages is defined for use in the experimental analysis and exploitation of this part of the insect life cycle. The duration of each stage is estimated and times are suggested for batch collections of symphasic animals.

541 citations

Journal ArticleDOI
30 Jun 1978-Science
TL;DR: Drosophila and vertebrate neoplasms show striking similarities as they grow in a noninvasive, compact fashion, typical of benign tumors, yet they also exhibit malignant qualities such as fast, autonomous, and lethal growth.
Abstract: Malignant neoplasms that develop in 12 recessive-lethal, larval mutants of Drosophila melanogaster are discussed. These mutations affect the adult optic neuroblasts and ganglion-mother cells in the larval brain, the imaginal discs, and the hematopoietic organs. The malignant neoplasms exhibit fast, autonomous growth, loss of the capacity for differentiation, increased mobility and invasiveness, lethality in situ and after transplantation, and histological, fine structural, and karyotypic abnormalities. Intermediate neoplasms are also found. These combine both benign and malignant qualities. They grow in a noninvasive, compact fashion, typical of benign tumors, yet they also exhibit malignant qualities such as fast, autonomous, and lethal growth, loss of differentiation capacity, changes in cellular morphology, and lethal growth after transplantation into wild-type hosts. Thus Drosophila and vertebrate neoplasms show striking similarities.

445 citations

References
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Journal ArticleDOI
TL;DR: The stain reported here differs from previous alkaline lead stains in that the chelating agent, citrate, is in sufficient excess to sequester all lead present, and is less likely to contaminate sections.
Abstract: Aqueous solutions of lead salts (1, 2) and saturated solutions of lead hydroxide (1) have been used as stains to enhance the electron-scattering properties of components of biological materials examined in the electron microscope. Saturated solutions of lead hydroxide (1), while staining more intensely than either lead acetate or monobasic lead acetate (l , 2), form insoluble lead carbonate upon exposure to air. The avoidance of such precipitates which contaminate surfaces of sections during staining has been the stimulus for the development of elaborate procedures for exclusion of air or carbon dioxide (3, 4). Several modifications of Watson's lead hydroxide stain (1) have recently appeared (5-7). All utilize relatively high pH (approximately 12) and one contains small amounts of tartrate (6), a relatively weak complexing agent (8), in addition to lead. These modified lead stains are less liable to contaminate the surface of the section with precipitated stain products. The stain reported here differs from previous alkaline lead stains in that the chelating agent, citrate, is in sufficient excess to sequester all lead present. Lead citrate, soluble in high concentrations in basic solutions, is a chelate compound with an apparent association constant (log Ka) between ligand and lead ion of 6.5 (9). Tissue binding sites, presumably organophosphates, and other anionic species present in biological components following fixation, dehydration, and plastic embedding apparently have a greater affinity for this cation than lead citrate inasmuch as cellular and extracellular structures in the section sequester lead from the staining solution. Alkaline lead citrate solutions are less likely to contaminate sections, as no precipitates form when droplets of fresh staining solution are exposed to air for periods of up to 30 minutes. The resultant staining of the sections is of high intensity in sections of Aralditeor Epon-embedded material. Cytoplasmic membranes, ribosomes, glycogen, and nuclear material are stained (Figs. 1 to 3). STAIN SOLUTION: Lead citrate is prepared by

24,137 citations

Journal ArticleDOI
TL;DR: Endothelial and epithelial tight junctions occlude the interspaces between blood and parenchyma or cerebral ventricles, thereby constituting a structural basis for the blood-brain and blood-cerebrospinal fluid barriers.
Abstract: Certain junctions between ependymal cells, between astrocytes, and between some electrically coupled neurons have heretofore been regarded as tight, pentalaminar occlusions of the intercellular cleft. These junctions are now redefined in terms of their configuration after treatment of brain tissue in uranyl acetate before dehydration. Instead of a median dense lamina, they are bisected by a median gap 20–30 A wide which is continuous with the rest of the interspace. The patency of these "gap junctions" is further demonstrated by the penetration of horseradish peroxidase or lanthanum into the median gap, the latter tracer delineating there a polygonal substructure. However, either tracer can circumvent gap junctions because they are plaque-shaped rather than complete, circumferential belts. Tight junctions, which retain a pentalaminar appearance after uranyl acetate block treatment, are restricted primarily to the endothelium of parenchymal capillaries and the epithelium of the choroid plexus. They form rows of extensive, overlapping occlusions of the interspace and are neither circumvented nor penetrated by peroxidase and lanthanum. These junctions are morphologically distinguishable from the "labile" pentalaminar appositions which appear or disappear according to the preparative method and which do not interfere with the intercellular movement of tracers. Therefore, the interspaces of the brain are generally patent, allowing intercellular movement of colloidal materials. Endothelial and epithelial tight junctions occlude the interspaces between blood and parenchyma or cerebral ventricles, thereby constituting a structural basis for the blood-brain and blood-cerebrospinal fluid barriers.

2,345 citations

Journal ArticleDOI
TL;DR: A new technique, based on the observations of Doggenweiler and Frenks, wMch has allowed us to demonstrate the presence of similar structures in sections of mouse heart and of mouse liver, and it seems likely that, as lanthanum solutions are brought to a high pH, a colloidal compound is formed which permeates the extracellular space as a tracer.

1,314 citations

Journal ArticleDOI
TL;DR: The histochemical uses of the periodic-acid-Schiff’s reagent (PAS) need careful control because of the possibility of attachment of iodate or periodate to tissue constitutents, producing a recoloration of the Schiff's reagent.
Abstract: Periodic acid acts upon the 1,2 glycol linkage (-CHOH -CHOH-) of carbohydrates in tissue sections to produce aldehyde (RCHO+RCHO) which can be colored with Schiff s reagent The method can be used

1,228 citations