Multiple roles for<i>u-turn/ventral veinless</i>in the development of<i>Drosophila</i>PNS

Inbal, Adi; Levanon, Dan; Salzberg, Adi

doi:10.1242/dev.00475

Cited by 34 publications

(45 citation statements)

References 52 publications

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“…However, the chordotonal neuron migration phenotypes observed by these authors could be secondary to abnormal morphogenesis of their associated ligament and/or scolopale cells. Indeed, an earlier study has suggested that ligament cells pull the lch5 neurons from a dorsal to a ventral position (Inbal et al, 2003), and time-lapse observations we have made of lch5 migration in the current study (data not shown) support that view.…”

Section: Dorsal Extension Of the Cap Cell Repositions The V'ch1 Neurosupporting

confidence: 87%

“…Whereas chordotonal organs generally possess three accessory cells -ligament, scolopale and cap cells -the v'ch1 organ appears to lack a ligament cell. We base this conclusion on previously published data, which show an absence of a stained cell in the expected position of a v'ch1 ligament cell in embryos stained with anti-Reversed polarity (von Hilchen et al, 2008) and anti-btubulin antibodies (Inbal et al, 2003): both of these antibodies consistently stain ligament cells of other chordotonal organs.…”

Section: Cap Cell Morphogenesis Directs V'ch1 Dendrite Orientation Ansupporting

confidence: 64%

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Netrin-guided accessory cell morphogenesis dictates the dendrite orientation and migration of a Drosophila sensory neuron

et al. 2010

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SUMMARYAccessory cells, which include glia and other cell types that develop in close association with neurons, have been shown to play key roles in regulating neuron development. However, the underlying molecular and cellular mechanisms remain poorly understood. A particularly intimate association between accessory cells and neurons is found in insect chordotonal organs. We have found that the cap cell, one of two accessory cells of v'ch1, a chordotonal organ in the Drosophila embryo, strongly influences the development of its associated neuron. As it projects a long dorsally directed cellular extension, the cap cell reorients the dendrite of the v'ch1 neuron and tows its cell body dorsally. Cap cell morphogenesis is regulated by Netrin-A, which is produced by epidermal cells at the destination of the cap cell process. In Netrin-A mutant embryos, the cap cell forms an aberrant, ventrally directed process. As the cap cell maintains a close physical connection with the tip of the dendrite, the latter is dragged into an abnormal position and orientation, and the neuron fails to undergo its normal dorsal migration. Misexpression of Netrin-A in oenocytes, secretory cells that lie ventral to the cap cell, leads to aberrant cap cell morphogenesis, suggesting that Netrin-A acts as an instructive cue to direct the growth of the cap cell process. The netrin receptor Frazzled is required for normal cap cell morphogenesis, and mutant rescue experiments indicate that it acts in a cell-autonomous fashion.

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Section: Dorsal Extension Of the Cap Cell Repositions The V'ch1 Neurosupporting

confidence: 87%

Section: Cap Cell Morphogenesis Directs V'ch1 Dendrite Orientation Ansupporting

confidence: 64%

Netrin-guided accessory cell morphogenesis dictates the dendrite orientation and migration of a Drosophila sensory neuron

et al. 2010

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“…The Drosophila class III POU factor Dfr/Vvl is an essential factor during development. Dfr/Vvl mutants die during embryogenesis due to defects in tracheal development and in commissural development in the central nervous system (CNS), the brain, and motoneurons, which is consistent with expression of Dfr/ Vvl in the developing embryo, the brain, oenocytes, and wing discs of developing larvae (5,6,8,12,15,18,28,38,43,81). Dfr/Vvl mutations affect wing development by virtue of regulation of the vestigial gene (13), and Dfr/Vvl was shown to regulate the neuronal expression of Dopa decarboxylase (Ddc) (13,30,31), a gene recently shown to also play a role in epithelial immunity (17).…”

mentioning

confidence: 53%

The POU Transcription Factor Drifter/Ventral veinless Regulates Expression of Drosophila Immune Defense Genes

Junell

Uvell

Davis

et al. 2010

Molecular and Cellular Biology

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Innate immunity operates as a first line of defense in multicellular organisms against infections caused by different classes of microorganisms. Antimicrobial peptides (AMPs) are synthesized constitutively in barrier epithelia to protect against microbial attack and are also upregulated in response to infection. Here, we implicate Drifter/Ventral veinless (Dfr/Vvl), a class III POU domain transcription factor, in tissue-specific regulation of the innate immune defense of Drosophila. We show that Dfr/Vvl is highly expressed in a range of immunocompetent tissues, including the male ejaculatory duct, where its presence overlaps with and drives the expression of cecropin, a potent broad-spectrum AMP. Dfr/Vvl overexpression activates transcription of several AMP genes in uninfected flies in a Toll pathway-and Imd pathway-independent manner. Dfr/Vvl activates a CecA1 reporter gene both in vitro and in vivo by binding to an upstream enhancer specific for the male ejaculatory duct. Further, Dfr/Vvl and the homeodomain protein Caudal (Cad) activate transcription synergistically via this enhancer. We propose that the POU protein Dfr/Vvl acts together with other regulators in a combinatorial manner to control constitutive AMP gene expression in a gene-, tissue-, and sex-specific manner, thus promoting a first-line defense against infection in tissues that are readily exposed to pathogens.

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“…Although ch organs reach their basic final shape and position at stage 15, further refinement occurs during later stages, at the time when ATK expression peaks (Carlson et al 1997b;Inbal et al 2003;Kraut and Zinn 2004;Hartenstein 2005). Several studies suggest the importance of the accessory cells in this final process of organ refinement: in the v'ch1 chordotonal organ (Mrkusich et al 2010), the positioning of the growing ciliary dendrite has shown to result from pulling forces that the dorsally extending cap cell exerts on the dendrite tip; and in the lch5 organ, the interaction between ligament and ligament attachment cells ventrally straightens the whole organ (Inbal et al 2004;Klein et al 2010).…”

Section: Atk Is An Ecm Protein Implicated In the Late Morphogenesis Omentioning

confidence: 99%

The Extracellular Matrix Protein Artichoke Is Required for Integrity of Ciliated Mechanosensory and Chemosensory Organs inDrosophilaEmbryos

et al. 2014

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Sensory cilia are often encapsulated by an extracellular matrix (ECM). In Caenorhabditis elegans, Drosophila melanogaster, and vertebrates, this ECM is thought to be directly involved in ciliary mechanosensing by coupling external forces to the ciliary membrane. Drosophila mechano-and chemosensory cilia are both associated with an ECM, indicating that the ECM may have additional roles that go beyond mechanosensory cilium function. Here, we identify Artichoke (ATK), an evolutionarily conserved leucine-rich repeat ECM protein that is required for normal morphogenesis and function of ciliated sensilla in Drosophila. atk is transiently expressed in accessory cells in all ciliated sensory organs during their late embryonic development. Antibody stainings show ATK protein in the ECM that surrounds sensory cilia. Loss of ATK protein in atk null mutants leads to cilium deformation and disorientation in chordotonal organs, apparently without uncoupling the cilia from the ECM, and consequently to locomotion defects. Moreover, impaired chemotaxis in atk mutant larvae suggests that, based on ATK protein localization, the ECM is also crucial for the correct assembly of chemosensory receptors. In addition to defining a novel ECM component, our findings show the importance of ECM integrity for the proper morphogenesis of ciliated organs in different sensory modalities.

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Multiple roles foru-turn/ventral veinlessin the development ofDrosophilaPNS

Cited by 34 publications

References 52 publications

Netrin-guided accessory cell morphogenesis dictates the dendrite orientation and migration of a Drosophila sensory neuron

Netrin-guided accessory cell morphogenesis dictates the dendrite orientation and migration of a Drosophila sensory neuron

The POU Transcription Factor Drifter/Ventral veinless Regulates Expression of Drosophila Immune Defense Genes

The Extracellular Matrix Protein Artichoke Is Required for Integrity of Ciliated Mechanosensory and Chemosensory Organs inDrosophilaEmbryos

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