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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Widerborst Interacts With Bitesize To Regulate Wing Hair Morphogenesis

Joglekar, Chandrashekhar 25 June 2005 (has links) (PDF)
The work presented in the thesis was carried with the aim to understand how Widerborst (Wdb) regulate planar cell polarity in Drosophila wing. In search of proteins interacting with Wdb I carried a Yeast Two Hybrid screen and identified a protein, bitesize, with tandem C2 domains in its C terminus interacting with Wdb. Wdb also interacts with btsz genetically and removal of one copy each of Wdb and btsz enhances the truncated hair phenotype observed in Wdb EMS mutants and btsz P element insertion mutants. There are at least three predicted isoforms of bitesize and loss of the btsz-II isoform is lethal. Clonal analysis of a btsz mutant, btszJ5-2, which removes the btsz II isoform resulted in truncated wing hair outgrowth. On the other hand over expression of a myc-btsz-II construct resulted in hair duplication phenotype. However, over expression of the GFP-CT is sufficient to give wing hair duplication phenotype and this hair duplication phenotype is stronger than that caused by myc-btsz-II over expression. The Myc tagged btsz-II protein shows apical localization. Though most of the protein is confined to cytoplasm, btsz-II also marks the plasma membrane. The GFP-CT construct marks the plasma membrane strongly and is enriched in the apical region. The over expression of CT domain is sufficient to give hair duplication phenotype and the strong difference observed in the localization pattern of full length btsz-II protein and GFP-CT together suggest that regulation of membrane localization of btsz through its CT region is important to regulate hair morphogenesis. As the loss of function (truncated wing hair) and gain of function (hair duplication) both affect the process of hair morphogenesis, it can be said that btsz is a positive regulator of hair morphogenesis. Since no defect in cortical polarization of Fmi was observed in cells lacking btsz-II, btsz is required for establishment of cortical domains. However with the present study it remains unknown how exactly the C2 domains might regulate hair morphogenesis and whether Wdb targets btsz for dephophorylation to PP2A catalytic subunit.
2

Widerborst Interacts With Bitesize To Regulate Wing Hair Morphogenesis

Joglekar, Chandrashekhar 11 July 2005 (has links)
The work presented in the thesis was carried with the aim to understand how Widerborst (Wdb) regulate planar cell polarity in Drosophila wing. In search of proteins interacting with Wdb I carried a Yeast Two Hybrid screen and identified a protein, bitesize, with tandem C2 domains in its C terminus interacting with Wdb. Wdb also interacts with btsz genetically and removal of one copy each of Wdb and btsz enhances the truncated hair phenotype observed in Wdb EMS mutants and btsz P element insertion mutants. There are at least three predicted isoforms of bitesize and loss of the btsz-II isoform is lethal. Clonal analysis of a btsz mutant, btszJ5-2, which removes the btsz II isoform resulted in truncated wing hair outgrowth. On the other hand over expression of a myc-btsz-II construct resulted in hair duplication phenotype. However, over expression of the GFP-CT is sufficient to give wing hair duplication phenotype and this hair duplication phenotype is stronger than that caused by myc-btsz-II over expression. The Myc tagged btsz-II protein shows apical localization. Though most of the protein is confined to cytoplasm, btsz-II also marks the plasma membrane. The GFP-CT construct marks the plasma membrane strongly and is enriched in the apical region. The over expression of CT domain is sufficient to give hair duplication phenotype and the strong difference observed in the localization pattern of full length btsz-II protein and GFP-CT together suggest that regulation of membrane localization of btsz through its CT region is important to regulate hair morphogenesis. As the loss of function (truncated wing hair) and gain of function (hair duplication) both affect the process of hair morphogenesis, it can be said that btsz is a positive regulator of hair morphogenesis. Since no defect in cortical polarization of Fmi was observed in cells lacking btsz-II, btsz is required for establishment of cortical domains. However with the present study it remains unknown how exactly the C2 domains might regulate hair morphogenesis and whether Wdb targets btsz for dephophorylation to PP2A catalytic subunit.
3

Hexagonal packing of Drosophila wing epithelial cells by the Planar Cell Polarity pathway

Classen, Anne-Kathrin 31 August 2006 (has links) (PDF)
The mechanisms that order cellular packing geometry are critical for the functioning of many tissues, but are poorly understood. Here we investigate this problem in the developing wing of Drosophila. The surface of the wing is decorated by hexagonally packed hairs that are uniformly oriented towards the distal wing tip. They are constructed by a hexagonal array of wing epithelial cells. We find that wing epithelial cells are irregularly arranged throughout most of development but become hexagonally packed shortly before hair formation. During the process, individual cell junctions grow and shrink, resulting in local neighbor exchanges. These dynamic changes mediate hexagonal packing and require the efficient delivery of E-cadherin to remodeling junctions; a process that depends on both the large GTPase Dynamin and the function of Rab11 recycling endosomes. We suggest that E-cadherin is actively internalized and recycled as wing epithelial cells pack into a regular hexagonal array. Hexagonal packing furthermore depends on the activity of the Planar Cell Polarity proteins. The Planar Cell Polarity group of proteins coordinates complex and polarized cell behavior in many contexts. No common cell biological mechanism has yet been identified to explain their functions in different tissues. A genetic interaction between Dynamin and the Planar Cell Polarity mutants suggests that the planar cell polarity proteins may modulate Dynamin-dependent trafficking of E-cadherin to enable the dynamic remodeling of junctions. We furthermore show that the Planar Cell Polarity protein Flamingo can recruit the exocyst component Sec5. Sec5 vesicles also co-localizes with E-cadherin and Flamingo. Based on these observations we propose that during the hexagonal repacking of the wing epithelium these proteins polarize the trafficking of E-cadherin-containing exocyst vesicles to remodeling junctions. The work presented in this thesis shows that one of the basic cellular functions of planar cell polarity signaling may be the regulation of dynamic cell adhesion. In doing so, the planar cell polarity pathway mediates the acquisition of a regular packing geometry of Drosophila wing epithelial cells. We identify polarized exocyst-dependent membrane traffic as the first basic cellular mechanism that can explain the role of PCP proteins in different developmental systems.
4

Hexagonal packing of Drosophila wing epithelial cells by the Planar Cell Polarity pathway

Classen, Anne-Kathrin 25 July 2006 (has links)
The mechanisms that order cellular packing geometry are critical for the functioning of many tissues, but are poorly understood. Here we investigate this problem in the developing wing of Drosophila. The surface of the wing is decorated by hexagonally packed hairs that are uniformly oriented towards the distal wing tip. They are constructed by a hexagonal array of wing epithelial cells. We find that wing epithelial cells are irregularly arranged throughout most of development but become hexagonally packed shortly before hair formation. During the process, individual cell junctions grow and shrink, resulting in local neighbor exchanges. These dynamic changes mediate hexagonal packing and require the efficient delivery of E-cadherin to remodeling junctions; a process that depends on both the large GTPase Dynamin and the function of Rab11 recycling endosomes. We suggest that E-cadherin is actively internalized and recycled as wing epithelial cells pack into a regular hexagonal array. Hexagonal packing furthermore depends on the activity of the Planar Cell Polarity proteins. The Planar Cell Polarity group of proteins coordinates complex and polarized cell behavior in many contexts. No common cell biological mechanism has yet been identified to explain their functions in different tissues. A genetic interaction between Dynamin and the Planar Cell Polarity mutants suggests that the planar cell polarity proteins may modulate Dynamin-dependent trafficking of E-cadherin to enable the dynamic remodeling of junctions. We furthermore show that the Planar Cell Polarity protein Flamingo can recruit the exocyst component Sec5. Sec5 vesicles also co-localizes with E-cadherin and Flamingo. Based on these observations we propose that during the hexagonal repacking of the wing epithelium these proteins polarize the trafficking of E-cadherin-containing exocyst vesicles to remodeling junctions. The work presented in this thesis shows that one of the basic cellular functions of planar cell polarity signaling may be the regulation of dynamic cell adhesion. In doing so, the planar cell polarity pathway mediates the acquisition of a regular packing geometry of Drosophila wing epithelial cells. We identify polarized exocyst-dependent membrane traffic as the first basic cellular mechanism that can explain the role of PCP proteins in different developmental systems.

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