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Identification de nouvelles protéines des synapses à ruban / Synaptic machinery at the hair cell ribbon synapseMahaman Bachir Dodo, Sahia 21 November 2014 (has links)
Les cellules sensorielles auditives, les cellules ciliées internes (CCI), transforment les ondes sonores en message nerveux. Les synapses des CCI se distinguent de celles du système nerveux par leur anatomie. En effet, les synapses des CCI sont dotées d'un organite appelé ruban synaptique. Ce dernier a pour fonction de concentrer les vésicules synaptiques à proximité des zones actives. Il est important de souligner qu'un déficit de la libération synaptique à la première synapse auditive est à l'origine de surdités chez l'homme. Si la physiologie des synapses à rubans des cellules ciliées a été intensivement étudiée, la composition moléculaire des ces synapses reste en grande partie inconnue. L'objectif de cette thèse était donc d'isoler les protéines clefs de la machinerie synaptique. Pour ce faire, nous avons utilisé la technique du double hybride à partir d'une banque d'ADN complémentaire de cochlée et de la protéine Ribeye, composant majeur des rubans, comme appât. La difficulté majeure de notre étude provient de la structure de Ribeye, qui est constitué par deux domaines A et B. Tandis que le domaine A est dirigé vers le cœur du ruban synaptique et aurait une fonction structurale, le domaine B est fortement homologue au facteur de transcription Ctbp2. Ainsi, nous avons identifié plusieurs candidats comme étant des facteurs de transcription. Ces derniers interagissent probablement avec Ctbp2 dans le noyau. Nos résultats obtenus soulignent la difficulté d'identifier des protéines d'interactions, inhérente à l'utilisation de Ribeye comme appât. Parmi les autres candidats, nous avons isolés des composants du système de l'ubiquitine, suggérant une régulation ubiquitine-dépendante de l'activité ou de la structure des rubans synaptiques. / Inner hair cells (IHCs) are the sensory cells of the cochlea, the organ of hearing. IHCs transduce sound stimulation into the release of glutamate onto the afferent auditory nerve fibers. To achieve this task, IHCs harbor at their presynaptic side a large organelle, the so-called synaptic ribbon, surrounded by a monolayer of glutamate-filled synaptic vesicles. Exocytosis of glutamate at the hair cell ribbon synapse seems to be unconventional as the synaptic machinery, depicted so far, differs from most of the nervous system synapses. The goal of this work was to identify new members of the synaptic machinery of the hair cell ribbon synapse. To do so, we took advantage of the yeast two-hybrid system using a cochlea cDNA library as the prey and Ribeye (the major ribbon component) as the bait. Transcription factors were highly represented in our screening assay, most probably because Ribeye is highly homologous to the transcription factor Ctbp2. They probably interact with Ctbp2 in the nucleus. Our results underlined the difficulty to identify protein interactions because of the nature of Ribeye itself. However, we found ubiquitin system components among the other candidates, suggesting an ubiquitin-dependent regulation of the activity and/or structure of synaptic ribbons.
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Analyse fonctionnelle des effecteurs nucléaires du parasitisme des nématodes à galle Meloidogyne incognita et caractérisation de leurs cibles végétales / Functional analysis of root knot nematode Meloidogyne incognita nuclear effectors and characterization of their plant targetsTruong, Nhat My 20 December 2016 (has links)
Le nématode à galle, Meloidogyne incognita est un parasite extrêmement polyphage capable d'induire la redifférentiation de cellules racinaires en cellules en cellules nourricières hypertrophiées. / The root-knot nematode Meloidogyne incognita is among the most devastating plant pathogens.
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Protein-Protein Interaction Assay in Phytophthora sojae Using Yeast Two-Hybrid SystemAikebaierjiang, Abasi 06 May 2020 (has links)
No description available.
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ANALYSIS OF MARBURG VIRUS PROTEIN INTERACTIONSVeronica J Heintz (13176234) 29 July 2023 (has links)
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<p>Infection by Marburgvirus (MARV) or the closely related Ebolavirus (EBOV) results in potentially lethal hemorrhagic fever in humans characterized by uncontrolled viremia, a systemic pro-inflammatory response, and multi-organ failure. Currently, there are no approved countermeasures to treat or prevent MARV infection, which leaves a critical need for development of antiviral therapies. One approach to develop antiviral therapies is exploit a virus’s dependency on the host cell and disrupt critical human-viral interactions. While multiple studies identified host-viral interactions involved in EBOV infection, we are currently limited in our knowledge of host-viral interactions that occur during MARV infection and how these interactions influence the viral replication cycle. Thus, the purpose of this research was to identify and further characterize the biological significance of human-MARV protein-protein interactions that occur during infection.</p>
<p>Here, we used genome-wide yeast two-hybrid (Y2H) screens to identify directly interacting human-viral proteins. We identified 431 putative interactions with MARV and used a combination of a novel NanoLuc Y2H assay and confidence criteria to prioritize a final set of 396 interactions. Bioinformatic analysis revealed that the molecular functions of the interacting human genes were significantly enriched in RNA binding, cell adhesion, and cytoskeleton binding. </p>
<p>MARV and EBOV have many similarities in their genomic organization, sequence, and protein structures that could facilitate interactions to common host factors during infection. Thus, to identify shared interactions between these related viruses, we compared the MARV interactions to EBOV interactions identified in a parallel Y2H screen. We identified 145 human proteins targeted by both MARV and EBOV. The majority (77%) of shared interactions occurred between homologous viral proteins. Additional bioinformatic analyses comparing MARV and EBOV interactions revealed that these viruses interact with different host factors with similar molecular functions (RNA binding, DNA binding, actin and microtubule binding. Together, these data support the notion that while MARV and EBOV target common host factors there are still differences in protein interactions that support functions specific to each virus. </p>
<p>To investigate the biological significance of the identified interactions, we focused on host interactions with the viral matrix protein, VP40. VP40 is a multifunctional protein that facilitates viral assembly and budding from the host cell. Y2H assays using VP40 mutants revealed that the WW-containing host protein MAGI1 interacted with the late domain of VP40. This interaction was validated in mammalian cells using coimmunoprecipitation and GFP complementation assays. Based on multiple reports of WW-containing host proteins interacting with VP40, we predict that the interaction between MAGI1 and VP40 regulates viral budding.</p>
<p>In conclusion, the work presented here successfully identified 396 novel human-MARV interactions, which furthers the field’s understanding of host factors involved in MARV infection. Additionally, we identified interactions shared by MARV and EBOV, which could be beneficial in the development of a broad antiviral therapy against filoviruses. Lastly, we validate the interaction between MAGI1 and VP40, which has a potential role in viral budding </p>
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Characterizing the Role of HspB2 in Cardiac Metabolism and Muscle Structure Using Yeast and Mammalian SystemsNeubert, Jonathan Paul 08 August 2012 (has links) (PDF)
HspB2 is a small heat shock protein encoded on human chromosome 11. Less than 1000 base pairs away from HSPB2 and situated in a head-to-head orientation lies the gene encoding another small heat shock protein, CRYAB. Because they are uncommonly close to one another they share regulatory elements. In addition, they share protein homology as sHSPs, suggesting that they perhaps perform aimilar functions. SHSPs such as HspB2 and CryAB are traditionally thought to provide protective effects to cells in response to a variety of stress inducers. In response to stress they form complexes around misfolded proteins or proteins in danger of denaturation. HspB2 has been shown to exhibit protective effects during cellular stress and to localize to the Z-line of skeletal muscle. It has also been implicated in cardiac energetics, specifically in the production of ATP, however little is known about its molecular targets. Here I report the use of yeast two-hybrid screening to uncover the molecular targets of HspB2. I also detail the process by which the screens are performed as well as the verification steps, including co-precipitation experiments in mammalian cells. Through these studies we identify many novelbinding partners of HspB2, including CryAB as well as multiple muscle and mitochondrial proteins. Proteins discovered to bind to HspB2 include such proteins as actin and myosin, enzymes catalyzing various steps of glycolysis and the electron transport chain, as well as redox-, small heat shock protein-, kinase-, and electrolyte-related proteins, among others. Studies of the binding partners of HspB2 in cardiac tissue will provide important information clarifying the involvement of HspB2 in cardiac muscle maintenance and metabolism.
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Characterization Of A Novel Interactor/substrate For The Pro-apoptotic Serine Protease Omi/htra2Stratico, Valerie Anne 01 January 2004 (has links)
OmiHtrA2 is a highly conserved mammalian serine protease that belongs to the HtrA family of proteins. Omi shares homology with the bacterially expressed heat shock protease HtrA, which functions as a protease at higher temperatures and a chaperone at lower temperatures. Additionally, Omi shares sequence similarity with the mammalian homologs L56/HtrA1 and PRSP/HtrA3. Omi was first isolated as an interacting protein of Mxi2, an alternatively spliced form of the p38 stress-activated kinase, using a modified yeast two-hybrid system. Omi localizes in the mitochondria and in response to apoptotic stimuli the mature form of this protein translocates to the cytoplasm. In the cytoplasm Omi participates in both the caspase-dependent as well as caspase-independent apoptosis. Additionally, recent studies suggest that Omi may have another unique function, maintaining homeostasis within the mitochondria. In an effort to further elucidate the function of Omi, a yeast two-hybrid screening was performed to isolate novel interacting proteins. This screening identified a novel protein (HOPS), as a specific interactor of Omi. The predicted amino acid sequence of this protein does not provide any information about its potential function in mammalian cells. However, experiments show that HOPS is cleaved in vitro by Omi. Furthermore, in response to apoptotic stimuli, HOPS is also degraded in vivo. This study suggests that HOPS could be a physiological substrate of Omi that is cleaved and removed during apoptosis.
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Identification of Human Proteins Interacting with the Protein IcsB of Shigella flexneriAlzahrani, Ashwag 26 October 2018 (has links)
Problem: Shigella is a gram-negative enteropathogen that, when passed through fecal particles
from one host to the oral cavity of another host, causes an infectious disease known as
shigellosis. One of the distinctive features of the infection by Shigella is its ability to bypass its
host’s autophagic defenses. It does this through the use of a Type III secretion system,
found in gram-negative pathogens like Shigella, which injects virulent proteins into the host cell.
One of these proteins is IcsB; however, its exact function is not well understood. This study aims
to better understand the role of this protein in the infection.
Methods: A yeast two-hybrid screening test is used in this case to examine the interactions
between variations of the protein IcsB, and a library of host proteins. Given IcsB’s high yeast
toxicity and that resulted in the total absence of yeast colony formation, the first aim was to identify IcsB variants which expression would not prevent yeast growth. The second aim was to use the mutant with reduced cytotoxicity to perform a Y2H screen that will allow for the identification of candidate host proteins interacting with IcsB.
Results: Two mutations of the IcsB protein grew in the Y2HG yeast strain, indicating a
significant reduction in the protein’s toxicity. Of the cultures that reacted, high stringency and
strong interaction was observed between four genes and IcsB proteins. Among the four
identified clones that grew, three corresponded to the gene RNF2, while the last one corresponds
to a non-coding sequence. Key control experiments revealed that the interaction of IcsB with RNF2 is likely false-positive. Thus, when screened full-length IcsB using new epithelial cells cDNAVI libraries, strong interaction was observed between three genes and our IcsB proteins. All the three genes DDX3X, FANCL, and SGT1 passed the false-positive interaction tests. It is interesting to notice that DDX3X and SGT1 interacted with catalytically active and inactive IcsB, suggesting that the interactions established between IcsB and prey proteins does not require the catalytic - C306A mutation and that IcsB most likely does not function as a protease against these two proteins. By contrast, FANCL bound catalytically inactive, but not catalytically active IcsB, suggesting it could be a substrate of IcsB. The literature provides some support for the putative role of DDX3X, FANCL, and SGT1 in regulating the vacuole escape of Shigella through IcsB action.
Conclusion: The aim of this study was to determine the functional of IcsB in the vacuole escape of Shigella. This study successfully identified three candidates interacting partner proteins for IcsB. Key control experiments confirmed the interaction of IcsB with DDX3X, FANCL and SGT1. This study provides a basis for further research, with further study aimed at confirming these results during Shigella infection
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The Role of the Intermembrane Domain of Mulan in Mitophagy and Cell DeathHerbert, Jared M 01 January 2016 (has links)
Mulan is an E3 ubiquitin ligase and an E3 SUMO ligase embedded in the outer mitochondrial membrane. Mulan plays a major role in various cell processes including cell growth, mitophagy, apoptosis, and mitochondrial dynamics. In addition, its deregulation is involved in the development and progression of several human disorders such as neurodegeneration and heart disease. There are two main discernible domains in Mulan: a large cytoplasmic domain that encodes the RING-finger motif and carries out the catalytic activity of the protein; the second domain of Mulan is exposed to the intermembrane space of mitochondria, and its function remains unknown. This part of Mulan is also referred to as the BAM domain and is expected to have a significant function since its amino acid sequence has been conserved through evolution and is found in bacteria, animals, and plants. The purpose of this study is to isolate and characterize potential binding partner proteins of the BAM domain using the yeast two-hybrid system. These studies are expected to provide new information on the physiological function of this domain and how it is potentially used to modulate the ligase activity of Mulan.
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Functional analysis of novel protein-protein interactions involving ROP GTPases in Arabidopsis thaliana and Populus trichocarpaJia, Xiaoyan 02 September 2013 (has links)
We are using the yeast two-hybrid (Y2H) system to identify novel protein-protein interactions (PPI) relevant to wood formation. Bait proteins for Y2H binary assays and screening against a xylem cDNA prey library were selected from approximately 400 Populus trichocarpa genes that are at least 8-fold more highly expressed in differentiating secondary xylem versus phloem-cambium, and designated here as poplar biomass (PB) genes. Here we report some of the interactions involving selected PB proteins and efforts to characterize their functions in Populus and Arabidopsis.
Members of the ROP GTPase family, PB15 in poplar and ROP11 in Arabidopsis, interact with the domain of unknown function (DUF) 620 (DUF620) proteins (e.g., PB129 in poplar). Ectopic co-expression of PB15 and PB129 in Arabidopsis caused outgrowths at the base of flower pedicels and altered leaf morphology. Interestingly, the co-expression phenotype could not be observed in transgenic plants that are only expressing either one of the interacting partners separately. Transgenics altered in expression of PB15 and/or PB129 were prepared in Populus and characterization of transgenic trees will be performed in greenhouse and field.
In addition to DUF620 family proteins, ROP11 also interacts with the COP9 subunit CSN5A in Arabidopsis. We confirmed the interaction of ROP11 and CSN5A in Y2H and employed available mutants for ROP11 and CSN5A in Arabidopsis to genetically characterize this interaction. Surprisingly, loss of ROP11 was found to rescue the csn5a-2 pleiotropic phenotype. Ectopic expression of a ROP11 dominant negative mutant in the csn5a-2 background also complemented the stunted growth phenotype. Transcript analysis and gel blot assays showed that CSN5A transcript levels remained unchanged in all rescue lines, whereas CSN5A protein levels increased relative to WT. Taken together, we concluded that ROP11 negatively regulate CSN5A protein level in plant by some as yet unknown mechanism. / Ph. D.
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Characterization of signaling pathways underlying key growth and development processes in Populus trichocarpaRigoulot, Stephen Bradley 05 September 2018 (has links)
The project goals for this dissertation were to manipulate Populus trichocarpa source-sink relationships to optimize this woody crop species for specific agricultural traits such as increased growth rate, stress tolerance and/or improvements in overall biomass accumulation. We targeted specific tissues such as xylem, where alterations in the relationship of source and sink tissues can lead to the control of xylem cell deposition or of various wood properties. This led to the characterization of 165 protein-protein interactions and 20 protein-DNA interaction which constitute numerous woody tissue related subnetworks. One such network, centered on the DIVARACATA and RADIALIS INTERACTING FACTOR (PtrDRIF), identified PtrWOX13c as an interacting protein. Characterization of PtrWOX13c shows that it displays the ability to control promoters related to lignin biosynthesis genes and overexpression phenotypes show alterations in axillary branch activity. Genes which control the differentiation and specialization of cells such as members of the WOX family are also highly responsive to abiotic stress which can force major changes in plant metabolism and nutrient mobilization. ABA, a prominent plant phytohormone with known roles in the adaptation to stress has shown novel connections in the regulation of growth promoting complexes such as TOR through antagonistic regulatory actions of the SnRK2 protein kinase in Arabidopsis. Characterization of the core ABA signaling in P. trichocarpa has identified a regulatory clade A protein phosphatase which interacts with numerous PtrSnRK2 proteins and when overexpressed in hybrid poplar results in increased height and node production potentially by indirect control of growth promoting complexes like TOR through SnRK2 inhibition. This work has also demonstrated that in addition to the involvement of phytohormones in the regulation of plant development, sugar phosphates such as T6P can exert significant control of plant architecture. Together, these studies comprise the discovery and subsequent characterization of novel wood associated networks, hormone pathways and sugar signaling in the manipulation of P. trichocarpa source-sink relationships for the promotion of biomass accumulation. / PHD / Detailed analyses of gene activity in different tissues or under the influence of various environmental conditions have identified numerous genes that control desirable traits and plant characteristics. However, the activities and functions of the proteins produced from these genes is less understood. One of the ways proteins work is through the formation of complexes with other proteins. Using the commercially valuable tree Populus trichocarpa (poplar) as our research model, we have identified novel complexes of interacting proteins with the potential to sense and respond to the environment and to promote plant growth. We tested the function of some of the members of these newly discovered protein complexes using transgenic poplar. As a result, we revealed previously unknown functions for two poplar proteins: PtrWOX13c promoted increased branching and PtrHAB2 promoted an increase in tree height. Independent of these functional analyses of poplar proteins, we also tested the ability of a sugar phosphate, trehalose6-phosphate, known from previous work to regulate plant growth, for its ability to promote poplar growth. We found that reducing levels of trehalose-6-phosphate resulted in increased branch growth, similar to the impact of the PtrWOX13c protein. In summary, identification of new protein complexes is a valuable strategy for the discovery of proteins that can increase tree growth. Additionally, combining targeted changes in both proteins and regulatory sugars may be a promising path toward future crop improvement and tree domestication.
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