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Novel regulators of trafficking in the yeast Golgi-endosomal systemGravert, Maike 09 October 2006 (has links) (PDF)
Over the past few years a large amount of work has provided growing insight into the molecular mechanisms that direct post-Golgi trafficking events in the budding yeast Saccharomyces cerevisae. However, a key event in this process, the formation of secretory vesicles at the Golgi and sorting of cargo into these transport carriers, remains poorly understood. It has been demonstrated that phosphatidylinositol 4-phosphate (PI(4)P) generated by the PI(4)-kinase Pik1p plays an essential role in maintenance of Golgi secretory function and morphology. Up to now relatively few targets of Pik1/PI(4)P signaling at the Golgi have been identified and it thus remains elusive how Pik1p mediates its essential function in Golgi secretion. During my thesis work, I used synthetic genetic array analysis (SGA) of a temperature-sensitive mutant allele of PIK1 (pik1-101) in order to gain better understanding of Pik1p function at the TGN and to isolate new regulators of post-Golgi transport in yeast. I identified a total of 85 genes, whose deletion resulted in a synthetic growth defect when combined with the pik1-101 mutation. 21 isolated deletion mutants were used for further analysis, several of which were found to share common trafficking phenotypes with the pik mutant. A striking result of the screen was the finding that Pik1p interacts genetically with several components of a potential post-translational modification pathway referred to as “urmylation pathway”. In addition, a novel, previously uncharacterized subunit of the Transport protein particle (TRAPP) complex was isolated as genetic interactor of Pik1p, suggesting a function for the TRAPP complex in a Pik1p dependent trafficking pathway. Using tandem affinity purification, I could also demonstrate that TRAPP shows previously unknown interactions with other regulators of post-Golgi transport. The second part of this thesis describes the development of a new visual screening approach. Recent work indicates that secretory cargo in yeast can be transported to the cell surface via at least two different exocytic branches. Upon block of one pathway cargo can be partially redistributed into the other pathway. This partial redundancy of exocytic pathways provides one explanation why genetic screens in the past were largely unsuccessful in identifying the molecular machinery that directs vesicle budding and cargo sorting at the TGN. I collaborated in the development of a novel screening method that was devised to circumvent this problem. The method took advantage of the systematic yeast knockout array and was based on the assumption that a defect in cargo sorting and cell surface transport could be detected as intracellular accumulation of a GFP-tagged model cargo. The suitability of our approach for identifying regulators of secretory transport has been demonstrated in a small-scale pilot study that will be presented in this thesis. The screening method proofed to be applicable on a genome-wide scale and can now be used for the screening of additional markers. This novel approach provides an entry point to the comprehensive study of TGN sorting.
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Unraveling Phosphatidylinositol 4-kinase function in the yeast Golgi-endosomal systemDemmel, Lars 13 September 2005 (has links)
In Saccharomyces cerevisiae, experiments with temperature-sensitive mutants of the PI4-kinase Pik1p revealed that the PI4P pool generated by this enzyme is essential for Golgi morphology and normal secretory function and that the PI4P pool at the Golgi represents a regulatory signal on its own. In order to function as a spatial and temporal regulator of membrane traffic, PI4P synthesis and turnover must be tightly regulated. It remains elusive which factors are involved in the targeting and regulation of Pik1p. Little is also known about PI4P binding proteins mediating the effects of this phosphoinositide on Golgi function. Since it has been shown that multiple pathways leave the Golgi towards the plasma membrane one can ask the question whether Pik1p and its product PI4P specifically control one pathway? Here we demonstrate an interaction of Pik1p with the 14-3-3 proteins Bmh1p and Bmh2p. Interestingly, overexpression of Bmh1p and Bmh2p results in multiple genetic interactions with genes involved in late steps of exocytosis and it affects the forward transport of the general amino acid permease Gap1p. The detected interaction depends on the phosphorylation state of Pik1p and Pik1p phosphorylation accompanies its shuttling out of the nucleus into the cytoplasm where presumably the binding to Bmh1/2p occurs. Therefore, we reason that these interactions might serve the sequestration of Pik1p away from the Golgi. This study reveals that Pik1p shows a strong effect on the delivery of Gap1p to the surface whereas the transport of exocytosis markers implicated in the direct Golgi-to-plasma membrane pathway are not significantly disturbed. Cells carrying a deletion of gga2 also show a strong defect in delivery of Gap1p to the surface. In addition, pik1-101 gga2[delta]double mutants display synthetic genetic and membrane transport phenotypes and recruitment of Gga2 to the TGN partially depends on functional Pik1p. Therefore, our results suggest a role of Pik1p in the TGN to endosome pathway.
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Novel regulators of trafficking in the yeast Golgi-endosomal systemGravert, Maike 29 September 2006 (has links)
Over the past few years a large amount of work has provided growing insight into the molecular mechanisms that direct post-Golgi trafficking events in the budding yeast Saccharomyces cerevisae. However, a key event in this process, the formation of secretory vesicles at the Golgi and sorting of cargo into these transport carriers, remains poorly understood. It has been demonstrated that phosphatidylinositol 4-phosphate (PI(4)P) generated by the PI(4)-kinase Pik1p plays an essential role in maintenance of Golgi secretory function and morphology. Up to now relatively few targets of Pik1/PI(4)P signaling at the Golgi have been identified and it thus remains elusive how Pik1p mediates its essential function in Golgi secretion. During my thesis work, I used synthetic genetic array analysis (SGA) of a temperature-sensitive mutant allele of PIK1 (pik1-101) in order to gain better understanding of Pik1p function at the TGN and to isolate new regulators of post-Golgi transport in yeast. I identified a total of 85 genes, whose deletion resulted in a synthetic growth defect when combined with the pik1-101 mutation. 21 isolated deletion mutants were used for further analysis, several of which were found to share common trafficking phenotypes with the pik mutant. A striking result of the screen was the finding that Pik1p interacts genetically with several components of a potential post-translational modification pathway referred to as “urmylation pathway”. In addition, a novel, previously uncharacterized subunit of the Transport protein particle (TRAPP) complex was isolated as genetic interactor of Pik1p, suggesting a function for the TRAPP complex in a Pik1p dependent trafficking pathway. Using tandem affinity purification, I could also demonstrate that TRAPP shows previously unknown interactions with other regulators of post-Golgi transport. The second part of this thesis describes the development of a new visual screening approach. Recent work indicates that secretory cargo in yeast can be transported to the cell surface via at least two different exocytic branches. Upon block of one pathway cargo can be partially redistributed into the other pathway. This partial redundancy of exocytic pathways provides one explanation why genetic screens in the past were largely unsuccessful in identifying the molecular machinery that directs vesicle budding and cargo sorting at the TGN. I collaborated in the development of a novel screening method that was devised to circumvent this problem. The method took advantage of the systematic yeast knockout array and was based on the assumption that a defect in cargo sorting and cell surface transport could be detected as intracellular accumulation of a GFP-tagged model cargo. The suitability of our approach for identifying regulators of secretory transport has been demonstrated in a small-scale pilot study that will be presented in this thesis. The screening method proofed to be applicable on a genome-wide scale and can now be used for the screening of additional markers. This novel approach provides an entry point to the comprehensive study of TGN sorting.
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The substrate matters in the Raman spectroscopy analysis of cellsMikoliunaite, Lina, Rodriguez, Raul D., Sheremet, Evgeniya, Kolchuzhin, Vladimir, Mehner, Jan, Ramanavicius, Arunas, Zahn, Dietrich R.T. 11 November 2015 (has links)
Raman spectroscopy is a powerful analytical method that allows deposited and/or immobilized cells to be evaluated without complex sample preparation or labeling. However, a main limitation of Raman spectroscopy in cell analysis is the extremely weak Raman intensity that results in low signal to noise ratios. Therefore, it is important to seize any opportunity that increases the intensity of the Raman signal and to understand whether and how the signal enhancement changes with respect to the substrate used. Our experimental results show clear differences in the spectroscopic response from cells on different surfaces. This result is partly due to the difference in spatial distribution of electric field at the substrate/cell interface as shown by numerical simulations. We found that the substrate also changes the spatial location of maximum field enhancement around the cells. Moreover, beyond conventional flat surfaces, we introduce an efficient nanostructured silver substrate that largely enhances the Raman signal intensity from a single yeast cell. This work contributes to the field of vibrational spectroscopy analysis by providing a fresh look at the significance of the substrate for Raman investigations in cell research.
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