Global ETD Search

41	Inquiry of Lipid Membranes Interacting with Functional Peptides and Polyphenol Drug Molecules Ho, Chian Sing 24 June 2016 (has links) Cellular membranes are important targets for many membrane-active peptides and drug compounds. Here we are interested in deciphering how lipid membranes are perturbed by several membrane-active molecules, including the transmembrane domain of the influenza M2 protein (M2TM), aggregates formed by a synthetic polyglutamine peptide, and three polyphenol compounds (i.e., tamoxifen, genistein, and verapamil). We employ phase-separated ternary lipid model membranes in the form of giant unilamellar vesicles (GUVs) to simulate raft-like structures that have been proposed to govern many important processes in plasma membranes (e.g., intracellular singling and trafficking). Specifically, we use fluorescent microscopy to interrogate how those membrane additives modulate the phase behavior of free-standing GUVs, as well as the miscibility transition temperature (Tm). We find that M2TM increases Tm and causes vesicle budding; polyglutamine aggregates disrupt lipid membranes; and the three polyphenol compounds exert disparate effects on GUV Tm. miscibility transition temperature critical fluctuation giant unilamellar vesicle membrane budding fluorescence mode Biophysics Physics
42	Deciphering the Role of Aft1p in Chromosome Stability Hamza, Akil January 2012 (has links) The Saccharomyces cerevisiae iron-responsive transcription factor, Aft1p, has a well established role in regulating iron homeostasis through the transcriptional induction of iron-regulon genes. However, recent studies have implicated Aft1p in other cellular processes independent of iron-regulation such as chromosome stability. In addition, chromosome spreads and two-hybrid data suggest that Aft1p interacts with and co-localizes with kinetochore proteins, however the cellular implications of this have not been established. Here, we demonstrate that Aft1p associates with the kinetochore complex through Iml3p. Furthermore, we show that Aft1p, like Iml3p, is required for the increased association of cohesin with the pericentromere and that aft1Δ cells display sister chromatid cohesion defects in both mitosis and meiosis. Our work defines a new role for Aft1p in the sister chromatid cohesion pathway. Aft1 Iml3 kinetochore cohesion cohesin centromere chromosome stability Ctf19 Chl4 Scc1 mitosis meiosis Rec8 budding yeast
43	Initiating the Spindle Assembly Checkpoint Signal: Checkpoint Protein Mad1 Associates with Outer Kinetochore Protein Ndc80 in Budding Yeast Weirich, Alexandra January 2013 (has links) The spindle assembly checkpoint (SAC) is an evolutionarily conserved mechanism that delays the initiation of anaphase by inhibiting the Anaphase Promoting Complex (APC) until all kinetochores have achieved bipolar attachment on the mitotic spindle. Mad1-3, Bub1, and Bub3, components of the SAC, are conserved from yeast to humans. These proteins localize to unattached kinetochores, though it is unknown with which kinetochore proteins they interact and how these interactions transduce information about microtubule attachement. Here, purification of the checkpoint proteins from Saccharomyces cerevisiae suggests that Mad1 interacts with the outer kinetochore protein Ndc80 in a SAC, cell cycle, and DNA dependent manner. Ndc80 is thought to mediate attachment of kinetochores to microtubules so the interaction between Mad1 and Ndc80 suggests a mechanism by which cells sense kinetochore-microtubule attachment. The SAC is of special importance in some types of cancer where genetic damage and aneuploidy is correlated with mutated SAC genes. A better understanding of the SAC mechanism will aid in the development of targetted cancer therpeutics. protein purification anaphase promoting complex spindle assembly checkpoint Mad1 Ndc80 Budding Yeast mass spectrometry
44	Structure et fonction d'un ligand d'ESCRT-III, LgD/CC2D1A / Structure and function of a ESCRT-III ligand, LgD/CC2D1A, involved in HIV virus budding Martinelli, Nicolas 13 December 2011 (has links) Le bourgeonnement est l'étape finale du cycle viral du virus VIH. Les particules virales vont devoir modifier la topologie de la membrane plasmique afin de promouvoir leur libération dans le milieu extracellulaire ; cette étape est réalisée par le recrutement de protéines ESCRT (en particulier CHMP4 et CHMP2) au point de bourgeonnement. A ce jour, les détails moléculaires de ce recrutement sont méconnus. Lethal Giant Discs (LgD) a été décrite dans la littérature comme un régulateur du traffic endosomal, et une interaction avec CHMP4B a été proposée pour l'orthologue humain CC2D1A. Un point majeur de ce travail aura été de caractériser l'interaction CC2D1A.CHMP4B, mais également de mieux comprendre l'organisation de la protéine. En particulier j'ai résolu la structure d'un fragment de LgD à 2.4 Å, comprenant une région hélicale et un domaine C2 en c-terminal. En outre, nous montrons que CC2D1A inhibe la capacité de CHMP4B à polymériser in vitro. A partir d'une structure cristallographique de CHMP4B et de données biochimiques, nous montrons que le site d'interaction de CC2D1A sur CHMP4B est impliqué dans la polymérisation de CHMP4B, et important pour la fonction de la protéine dans le contexte du bourgeonnement du HIV. Un projet parallèle m'a également conduit à définir un protocole de purification de la protéine CHMP2B recombinante sous forme monomérique, cet isoforme ayant été récemment impliqué dans la formation de structures tubulaires à la membrane plasmique et dans des activités de scission membranaire. En particulier, j'ai pû caractériser la protéine en présence de liposomes et préciser de nouveaux partenaires cellulaires. / Budding is the final step of HIV infection. Viral particles will have to modify the topology of the plasma membrane in order to achieve their correct release from the infected cell, by recruiting ESCRT proteins at the budding point, and among them CHMP4 and CHMP2 isoforms. So far, the molecular details of this recruitment are not precisely known.. Lethal Giant Discs (LgD) has been descibed in the litterature as a regulator of endosomal trafficking, and an interaction with CHMP4B has been proposed. A major point of this research is to propose a structural basis for this interaction, as well as a better understanding of the role and general organization of LgD/CC2D1A. The crystal structure of a LgD fragment (comprising a predicted coiled-coil motif and a c-terminal C2 domain) was solved in our lab at 2.4 A. Moreover, we show that CC2D1A impairs in vitro the ability of CHMP4B to polymerize. Based on a crystallographic structure of CHMP4B and biochemical data, we also show that the binding site of CC2D1A on CHMP4B is itself involved in polymerization, in the context of HIV budding. As a side project, I've also set up a protocole to obtain pure monomeric CHMP2B, which has been shown to polymerize at the plasma membrane, and I've characterized the protein in the presence of liposomes, along with new partners. ESCRT Bourgeonnement VIH Voie Endosomale Cristallographie Complexe de protéines ESCRT Budding HIV Endosomal Pathway Protein Complex 570
45	Identification of Deubiquitinating Enzymes that Control the Cell Cycle in Saccharomyces cerevisiae Mapa, Claudine E. 30 November 2018 (has links) A large fraction of the proteome displays cell cycle-dependent expression, which is important for cells to accurately grow and divide. Cyclical protein expression requires protein degradation via the ubiquitin proteasome system (UPS), and several ubiquitin ligases (E3) have established roles in this regulation. Less is understood about the roles of deubiquitinating enzymes (DUB), which antagonize E3 activity. A few DUBs have been shown to interact with and deubiquitinate cell cycle-regulatory E3s and their protein substrates, suggesting DUBs play key roles in cell cycle control. However, in vitro studies and characterization of individual DUB deletion strains in yeast suggest that these enzymes are highly redundant, making it difficult to identify their in vivo substrates and therefore fully understand their functions in the cell. To determine if DUBs play a role in the cell cycle, I performed a screen to identify specific DUB targets in vivo and then explored how these interactions contribute to cell cycle control. I conducted an in vivo overexpression screen to identify specific substrates of DUBs from a sample of UPS-regulated proteins and I determined that DUBs regulate different subsets of targets, confirming they display specificity in vivo. Five DUBs regulated the largest number of substrates, with Ubp10 stabilizing 40% of the proteins tested. Deletion of Ubp10 delayed the G1-S transition and reduced expression of Dbf4, a regulatory subunit of Cdc7 kinase, demonstrating Ubp10 is important for progression into S-phase. We hypothesized that compound deletion strains of these five DUBs would be deficient in key cellular processes because they regulated the largest number of cell cycle proteins from our screen. I performed genetic analysis to determine if redundancies exist between these DUBs. Our results indicate that most individual and combination deletion strains do not have impaired proliferation, with the exception of cells lacking UBP10. However, I observed negative interactions in some combinations when cells were challenged by different stressors. This implies the DUB network may activate redundant pathways only upon certain environmental conditions. While deletion of UBP10 impaired proliferation under standard growth conditions, I discovered that deletion of the proteasome-regulatory DUBs Ubp6 or Ubp14 rescues the cell cycle defect inubp10∆ cells. This suggests in the absence of Ubp10 substrates such as Dbf4 are rapidly degraded by the proteasome, but deletion of proteasome-associated DUBs restores cell cycle progression. Our work demonstrates that in unperturbed cells DUBs display specificity for their substrates in vivo and that a coordination of DUB activities promotes cell cycle progression. Ubiquitin proteasome deubiquitinating enzyme dub cell cycle budding yeast protein degradation Cell Biology Genetics Molecular Biology
46	Mechanisms of Cellular Entry of Cell Penetrating Peptides and Proteins Sahni, Ashweta 12 September 2022 (has links) No description available. Biochemistry Chemistry
47	OVERT AND LATENT PATHWAYS OF POLARITY SPECIFICATION IN ZYGOTES: THE HAPLOID-TO-DIPLOID TRANSITION Rinonos, Serendipity Zapanta 08 March 2013 (has links) No description available. Cellular Biology Molecular Biology polarity specification cell polarity yeast polarity bud site selection zygotes budding yeast
48	Fine-tuning the orientation of cell polarization by a GTPase activating protein in <i>Saccharomyces cerevisiae</i> Lee, Mid Eum 15 May 2015 (has links) No description available. Cellular Biology Molecular Biology Genetics Cell polarity Saccharomyces cerevisiae Budding pattern GTPase GTPase activating protein
49	Mathematical modeling approaches for dynamical analysis of protein regulatory networks with applications to the budding yeast cell cycle and the circadian rhythm in cyanobacteria Laomettachit, Teeraphan 11 November 2011 (has links) Mathematical modeling has become increasingly popular as a tool to study regulatory interactions within gene-protein networks. From the modeler's perspective, two challenges arise in the process of building a mathematical model. First, the same regulatory network can be translated into different types of models at different levels of detail, and the modeler must choose an appropriate level to describe the network. Second, realistic regulatory networks are complicated due to the large number of biochemical species and interactions that govern any physiological process. Constructing and validating a realistic mathematical model of such a network can be a difficult and lengthy task. To confront the first challenge, we develop a new modeling approach that classifies components in the networks into three classes of variables, which are described by different rate laws. These three classes serve as "building blocks" that can be connected to build a complex regulatory network. We show that our approach combines the best features of different types of models, and we demonstrate its utility by applying it to the budding yeast cell cycle. To confront the second challenge, modelers have developed rule-based modeling as a framework to build complex mathematical models. In this approach, the modeler describes a set of rules that instructs the computer to automatically generate all possible chemical reactions in the network. Building a mathematical model using rule-based modeling is not only less time-consuming and error-prone, but also allows modelers to account comprehensively for many different mechanistic details of a molecular regulatory system. We demonstrate the potential of rule-based modeling by applying it to the generation of circadian rhythms in cyanobacteria. / Ph. D. Cyanobacteria Mathematical Modeling Protein Regulatory Networks Budding Yeast Cell Cycle Circadian Rhythm
50	Effect of chilling, hydrogen cyanamide, hot water and bud scale removal on bud break of 'Tifblue' rabbiteye blueberry Saad, Mohd. Ridzuan Mohd 12 September 2009 (has links) Temperate deciduous fruit trees have poor and delayed bud break when they are grown in warm areas. The delay is due to a lack of the chilling which is required to break bud endodormancy. Bud endodormancy can be overcome in some species by treatments such as H<sub>2</sub>CN<sub>2</sub>, heat, and bud scale removal. We tested the effects of chilling, H<sub>2</sub>CN<sub>2</sub>, heat, and removing scales on bud break of floral and vegetative buds of 'Tifblue' rabbiteye blueberry (Vaccinium ashei Reade). Hydrogen cyanamide was effective in promoting floral bud break of 'Tifblue' only on whole plants, at chilling exposures between 300 to 500 hours. However, vegetative bud break was increased by H<sub>2</sub>CN<sub>2</sub> at a wider range of ~hilling exposures than floral buds in both whole plants and cut shoots. Optimum vegetative bud break was induced by H<sub>2</sub>CN<sub>2</sub> at 125 and 250 mM for whole plants and cut shoots, respectively. Hydrogen cyanamide was highly phytotoxic to floral buds compared to vegetative buds. However, floral buds of whole plants became tolerant to H<sub>2</sub>CN<sub>2</sub> as chilling increased. Injury to vegetative buds was significant only at 500 mM H<sub>2</sub>CN<sub>2</sub>. The chilling requirement for 'Tifblue' floral buds of whole plants was 500 hours. In contrast, vegetative buds did not have a significant relationship with chilling exposure in either cut shoots or whole plants. Heat treatment was effective in promoting floral bud break of cut shoots only at 190 chilling hours at 30 minutes heat exposure. Heat (47°C) for I hr was effective in promoting vegetative bud break, but the effectiveness varied with chilling level and depended on time of heat exposure. Bud scale removal did not promote floral bud break, but increased vegetative bud break, although not significant compared to control. Finally, we discovered that vegetative buds remained dormant even after they had received more than adequate chilling. However, both H<sub>2</sub>CN<sub>2</sub> treatment and floral bud removal resulted in increased vegetative bud break, although the effect of H<sub>2</sub>CN<sub>2</sub> was less than floral bud removal. This suggests that vegetative buds were inhibited by floral buds and that H<sub>2</sub>CN<sub>2</sub> could partially overcome this paradormant effect. / Master of Science LD5655.V855 1992.S232 Blueberries -- Growth Budding (Plant propagation) Hydrogen cyanamide

Search results