Simone Tix - Academia.edu (original) (raw)

Papers by Simone Tix

Development, 1989

We have identified a set of larval neurones in the developing adult optic lobes of Drosophila by ... more We have identified a set of larval neurones in the developing adult optic lobes of Drosophila by selectively labelling cells that have undergone only a few mitoses. A cluster of three cells is located in each of the optic lobes near the insertion site of the optic stalk. Their axons fasciculate with fibres of the larval optic nerve, the Bolwig's nerve, and then form part of the posterior optic tract. These cells are likely to be first order inter-neurones of the larval visual system. Unlike the Bolwig's nerve, they persist into the adult stage. The possibility of a pioneering function of the larval visual system during formation of the adult optic lobe neuropil is discussed.

Development, 1989

Injection of a cell lineage tracer (HRP) into Drosophila embryos before cellularization provides ... more Injection of a cell lineage tracer (HRP) into Drosophila embryos before cellularization provides a way of selectively labelling cells at later stages that have undergone only a few mitoses. All cells born and differentiating during embryogenesis become labelled, whereas further proliferation and growth during postembryonic development causes an almost complete dilution of the marker in the adult cell complement. Early born neurons visualized in this way are good candidates for executing a pioneering function during postembryonic differentiation of the adult nervous system. In all three pairs of leg imaginal discs, a stereotyped set of larval sense organs becomes selectively labelled. Their axons fasciculate with a larval nerve, which connects the leg disc with the central nervous system. Larval sense organs are not present in the other imaginal discs. Larval neurons are not present in the transformed antennal discs of Antp 73B flies. Nonetheless adult axons successfully navigate to the base of these discs as they differentiate to form ectopic legs. We conclude that embryonically formed larval nerves are not essential for the guidance of adult axons within the leg discs.

Journal of Neurogenetics, 1990

Irregular chiasm C (irreC) is an X-linked genetic function necessary for the correct projection o... more Irregular chiasm C (irreC) is an X-linked genetic function necessary for the correct projection of visual fibers in the optic chiasms of Drosophila optic ganglia. In addition to a severe disorganization of the inner optic chiasm irreC mutants display a subtle phenotype in the outer optic chiasm, in which some bundles of axons that leave the posterior equatorial part of the lamina on their way to the anterior medulla take a long detour before eventually finding their specific targets in the medulla neuropile. Deletion and recombination mapping of two irreC alleles (one P-element induced, the other associated with an inversion) have yielded a precise cytogenetic location in 3C4-5. A complex complementation pattern between roughest (rst) and irreC alleles indicates that both genetic functions are structurally and/or functionally closely interrelated. Flies in which the irreC locus is completely deleted by overlapping deficiencies are viable and their defects in the optic chiasms are similar to those seen in the two alleles. The defects in the outer and inner optic chiasms are not epigenetically connected and mosaic analyses have shown them to be independent from the genotype of the compound eye. Although the larval visual nerve looks normal, we have found that in the optic lobes of irreC mutants a group of early differentiating larval neurons is misplaced, suggesting a pioneering function of these cells during organization of the outer optic chiasms.

Cell and Tissue Research, 1997

Different classes of glia cells in the optic lobes of Drosophila melanogaster were defined by the... more Different classes of glia cells in the optic lobes of Drosophila melanogaster were defined by the enhancer trap technique, using expression of the lacZ reporter gene. At both the outer and inner optic chiasms, there are stacks of glia, arrayed from dorsal to ventral, interpersed between the crossings of axonal fiber bundles. The giant glial cells of both the outer and inner chiasms are similar with respect to their nuclear shapes and positions, indicating similar functions of these cell types. Another class of glia is found in the medulla neuropil. Their cell bodies anchor in the most distal region of the neuropil, and their processes extend into the deeper neuropil layers. Birth dating using BrdU shows that both groups of chiasm glia are born early in larval life; they may participate in the development of the optic lobe. The medulla glia are born later and may be involved primarily in adult functions. In the wild type, and in mutants with structurally altered optic lobes, the numbers of tract-associated glial cells in the outer and inner optic chiasms seem to vary with the number of visual columns, whereas the complement of medulla neuropil glia correlates with the volume of the optic lobe.

Development, 1989

We have identified a set of larval neurones in the developing adult optic lobes of Drosophila by ... more We have identified a set of larval neurones in the developing adult optic lobes of Drosophila by selectively labelling cells that have undergone only a few mitoses. A cluster of three cells is located in each of the optic lobes near the insertion site of the optic stalk. Their axons fasciculate with fibres of the larval optic nerve, the Bolwig's nerve, and then form part of the posterior optic tract. These cells are likely to be first order inter-neurones of the larval visual system. Unlike the Bolwig's nerve, they persist into the adult stage. The possibility of a pioneering function of the larval visual system during formation of the adult optic lobe neuropil is discussed.

Development, 1989

Injection of a cell lineage tracer (HRP) into Drosophila embryos before cellularization provides ... more Injection of a cell lineage tracer (HRP) into Drosophila embryos before cellularization provides a way of selectively labelling cells at later stages that have undergone only a few mitoses. All cells born and differentiating during embryogenesis become labelled, whereas further proliferation and growth during postembryonic development causes an almost complete dilution of the marker in the adult cell complement. Early born neurons visualized in this way are good candidates for executing a pioneering function during postembryonic differentiation of the adult nervous system. In all three pairs of leg imaginal discs, a stereotyped set of larval sense organs becomes selectively labelled. Their axons fasciculate with a larval nerve, which connects the leg disc with the central nervous system. Larval sense organs are not present in the other imaginal discs. Larval neurons are not present in the transformed antennal discs of Antp 73B flies. Nonetheless adult axons successfully navigate to the base of these discs as they differentiate to form ectopic legs. We conclude that embryonically formed larval nerves are not essential for the guidance of adult axons within the leg discs.

Journal of Neurogenetics, 1990

Irregular chiasm C (irreC) is an X-linked genetic function necessary for the correct projection o... more Irregular chiasm C (irreC) is an X-linked genetic function necessary for the correct projection of visual fibers in the optic chiasms of Drosophila optic ganglia. In addition to a severe disorganization of the inner optic chiasm irreC mutants display a subtle phenotype in the outer optic chiasm, in which some bundles of axons that leave the posterior equatorial part of the lamina on their way to the anterior medulla take a long detour before eventually finding their specific targets in the medulla neuropile. Deletion and recombination mapping of two irreC alleles (one P-element induced, the other associated with an inversion) have yielded a precise cytogenetic location in 3C4-5. A complex complementation pattern between roughest (rst) and irreC alleles indicates that both genetic functions are structurally and/or functionally closely interrelated. Flies in which the irreC locus is completely deleted by overlapping deficiencies are viable and their defects in the optic chiasms are similar to those seen in the two alleles. The defects in the outer and inner optic chiasms are not epigenetically connected and mosaic analyses have shown them to be independent from the genotype of the compound eye. Although the larval visual nerve looks normal, we have found that in the optic lobes of irreC mutants a group of early differentiating larval neurons is misplaced, suggesting a pioneering function of these cells during organization of the outer optic chiasms.

Cell and Tissue Research, 1997

Different classes of glia cells in the optic lobes of Drosophila melanogaster were defined by the... more Different classes of glia cells in the optic lobes of Drosophila melanogaster were defined by the enhancer trap technique, using expression of the lacZ reporter gene. At both the outer and inner optic chiasms, there are stacks of glia, arrayed from dorsal to ventral, interpersed between the crossings of axonal fiber bundles. The giant glial cells of both the outer and inner chiasms are similar with respect to their nuclear shapes and positions, indicating similar functions of these cell types. Another class of glia is found in the medulla neuropil. Their cell bodies anchor in the most distal region of the neuropil, and their processes extend into the deeper neuropil layers. Birth dating using BrdU shows that both groups of chiasm glia are born early in larval life; they may participate in the development of the optic lobe. The medulla glia are born later and may be involved primarily in adult functions. In the wild type, and in mutants with structurally altered optic lobes, the numbers of tract-associated glial cells in the outer and inner optic chiasms seem to vary with the number of visual columns, whereas the complement of medulla neuropil glia correlates with the volume of the optic lobe.