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Prion-like Properties in Vesicle TraffickingMcKeith Pearson II (11205306) 20 August 2023 (has links)
<p>Vesicle trafficking is an important process critical for secretory and endocytic purposes, but it is also crucial for cell homeostasis, <i>e.g.,</i> for maintenance of organelle identity and recycling of membrane components.</p><p>The endomembrane-located adaptor protein Epsin R (Epsin-Related protein) is believed to be important for recycling of SNARES like Vti1b from endosomes to the trans Golgi network (TGN), although its involvement in TGN to endosome transport has been also proposed. Further highlighting its impact in cellular and organismal physiology, certain <i>EPSIN R</i> SNPs have been linked to schizophrenia and Epsin R deficiencies correlate with other pathological conditions related to epidermis homeostasis such as psoriasis and eczema.</p><p>Epsin R belongs to the conserved Epsin family of adaptors and as such it presents a characteristic Epsin N-Terminal Homology (ENTH) domain and a largely unstructured C-terminus. The latter contains binding motifs for important elements of the vesicle trafficking machinery.</p><p>Here we identified a C-terminal region of Epsin R with prion-like characteristics (Prion Forming Region or PFR). We found that GFP-Epsin R is localized in intracellular punctate structures colocalizing with different intracellular markers; however, in contrast to other epsin family members, Epsin R displayed puncta of different size and with different protein content with a substantial contribution of large/bright particles. Importantly, the C-terminal Epsin R’s PFR was required for Epsin R localization and for the formation of large and bright puncta. Further, these structures displayed characteristics shared with other prion-like proteins. Our results therefore suggest that Epsin R possesses PFR-dependent prion properties that play an important role in this adaptor’s localization and function.</p><p>We propose a model in which prion-like proteins like Epsin R can rapidly and stably self-assemble at vesicle budding sites. These proteins would accelerate the formation of vesicle trafficking machinery and the recruitment of cargo. We also speculate that oligomerizing, self-templating reactions would occur under strict control of several cellular factors such as chaperones and post-translational modifications (<i>e.g.,</i> phosphorylation, ubiquitination, etc.) to assure quick and <i>reversible</i> association of prion-like proteins.</p>
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Is the Utricular Striola Specialized to Encode High Frequency Stimuli?Sams, David A. 26 July 2011 (has links)
No description available.
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Studium pohybu polyomavirů z pozdního endozómu směrem k buněčnému jádru / Studies of polyomavirus trafficking from late endosomes towards the cell nucleusŠtach, Martin January 2016 (has links)
Mouse polyomavirus (MPyV) is a model virus of the Polyomaviridae family. Polyomaviruses are small non-enveloped DNA viruses. They cause severe problems to immunocompromised patients. Their oncogenic potential is known in animals and humans. Trafficking of MPyV within the cell is not clear yet. The virus enters via smooth monopinocytic vesicles and continues to early and late endosomes. From there, the virus is transported to the ER by unknown mechanism. It bypasses Golgi aparatus (GA). One possible pathway is from late endosomes to trans-Golgi network (TGN) facilitated by Rab9 GTPase and then in COPI vesicles to the ER. In this thesis, the effect of inhibitors of retrograde transport (Brefeldin A, Golgicide A) on MPyV infection was evaluated. Brefeldin A is not completely specific; it has effect on whole endosomal system. Golgicide A causes specific disruption of transport via TGN and GA. Both inhibitors suppressed infection of MPyV. Confocal microscopy revealed colocalization of some MPyV virions with markers of TGN and COPI vesicles. MPyV didn't colocalize with cis-Golgi marker. Unfortunately, the effect of overexpression of Rab9 dominant negative mutant couldn't been evaluated due to its high cytotoxicity. However, overexpression of wild type Rab9 slightly increased infectivity. The results...
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Study of position effect as a mechanism arising from chromosomal translocations in leukaemiaPapucci, Chiara January 2015 (has links)
The chromosomal translocation of t(14;18)(14q32;18q21) is a characteristic aberration of follicular lymphoma and Diffuse Large B cells lymphoma. By PCR, it was proved that the rearrangement of chromosomes 14 and 18 leads to an overexpression of BCL2, an anti-apoptotic protein, which is one of the factors responsible for the maturation of the diseases. The translocation involves the promoter region of IGH gene and the transcriptional unit of BCL2 gene. Previous studies carried out in Dr Tosi’s lab showed a looping out of the BCL2 gene from its chromosome territory in 15% of the nuclei analysed. This looping out could be possibly responsible for the transcriptional activity of the gene. A further relevant finding concerns the spatial distribution of the genes involved in the translocation in the interphase nuclei. In the Pfeiffer cell line, harbouring the t(14;18) rearrangement, the translocated BCL2 gene was positioned in the cell nuclei according to a bimodal distribution. One could speculate that the distribution in the periphery and in the centre of the nuclei could divide the Pfeiffer cell line in two different subpopulations, consequently from the transcriptional activity. These preliminary data set the ground for more experimental work to test whether genes associated with the nuclear interior were transcriptionally active as opposed to the genes positioned towards the nuclear periphery, transcriptionally inactive. The work here presented focuses on this investigation using RNA-DNA FISH (Fluorescence in situ hybridization). My work enabled the detection of IGH, BCL2 and t(14;18) genes along with their transcripts inside of the nuclei of Pfeiffer cell line. Contrary to what had been hinted by previous work, my results showed multiple nuclear positions of transcriptionally active IGH/BCL2 translocation. The result will need to be further supported by software analysis in order to define its specific nuclear position and to ensure the perfect localization of the genes inside each nucleus.
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Samband mellan hällbilder och runor? : Samlokaliseringar och gemensamma symboliseringar av levnadsvärldenStille, Leif January 2015 (has links)
Författaren till denna uppsats har ett brett allmänt intresse av alla tänkbara relationer mellan hällbilder och runor ur ett vitt spektrum av aspekter såsom kronologiska, kulturella, epokmässiga, geografiska, semiotiska, språkfunktionella och skrifthistoriska. Särskilt intressant vore att kartlägga och analysera, hur hällbilder och runor kan symboliskt uttrycka religiösa, rituella, kosmologiska och livsåskådningsmässiga föreställningar och ideal. Andra viktiga faktorer, som måste beaktas, är kulturkontinuitet och hur forntidens människor såg på sina ännu äldre föregångares kultur, föreställningar och livsföring. Uppsatsen måste dock begränsa sig att främst behandla två specialområden dels lokaler med överlappande förekomster av hällristningar och runor, dels en jämförelse mellan runnamnens semantiska sfärer och symboliseringar av väsentliga delar i livsvärlden hos de mest frekventa skandinaviska hällbildsfigurstyperna. De frågor uppsatsen vill besvara är primärt: 1/ Vilka samlokaliseringar av hällbilder och runor finns det? 2/ Verkar runinskrifterna på dessa samlokaliseringar kommentera eller anspela på hällbilderna och i så fall hur? 3/ Vilka semantiska sfärer representerar runnamnen och vilka komponenter i de dåtida människornas levnadsvärld refererar de till? 4/ Finns det hällbildsfigurer, som rimligen kan sägas symbolisera samma levnadsvärldskomponenter som runorna? För att besvara dessa frågor presenteras: A/ fem samlokaliseringar av hällbilder och runor; B/ tolkningar av samspelet mellan de fem lokalernas hällbilder och runor; C/ en genomgång av de äldre runnamnens betydelser; D/ förslag på hällbildsfigurer, som symboliskt skulle motsvara runnamnen. En angenäm effekt av denna uppsats vore, om den kunde leda till en rekategorisering av hällbildernas motiv och symboler utifrån runsystemets förutsatta levnadsvärld och kosmologi.. / The author of this thesis has a broad general interest in all imaginable relations between rock art and runes out of a wide spectrum of aspects such as cronological, cultural, epochic, geografic, semiotic, linguistic and the history of writing. It would be specially interesting to describe (map down) and analyse how rock art and runes in a symbolic way can express beliefs and ideals out of a religious, ritual and cosmological conception of life. Other important considerations are continuity of culture and how ancient people looked at the culture, beliefs, ideas and living of their ancesters. This thesis has to be limited to deal with two areas, firstly lokacations with overlapping occurrence of rock art and runes and secondly a comparison of the semantic sphere of the names of the runes and symbolizations of important parts of life that can be seen in the most frequently occurring Scandinavian types of rock art figures. The thesis primarily wants to answer the following questions: 1) Which common localisations of rock art and runes are there? 2) Do the runes in these colocalization seem to comment or allude to the rock art? If so, in what way? 3) Which semantic spheres do the names of the runes represent and to which components in the life world of the ancient people do they refere? 4) Are there rock art figures who probably can be said to symbolize the same components of life world as the runes? To answer these questions I will present: A) five common lokalisations of rock art and runes. B) interpretations of the interaction of the rock art and runes in these five lokalisations. C) a catalogue of the meanings of the names of the older runes. D) proposals concerning rock art figures which in a symbolic way could correspond the rune names. A pleasant effect of this thesis would be, if it could leed to a recategorization of the motives and symbols of rock art from the provided life world and cosmology of the runes.
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Nanoscale co-organization of AMPAR and Neuroligin probed with single-molecule based microscopy / Co-organisation nanométrique de AMPAR et Neuroligin sondé avec la microscopie basée sur molécule uniqueHaas, Kalina 16 December 2013 (has links)
Il est bien admis que la compréhension de la structuration moléculaire à l’intérieur des cellules neuronales est essentielle pour appréhender le fonctionnement du cerveau. Pour cette raison, l’étude de l’organisation des molécules clés neuronales et synaptiques contribue grandement à comprendre le mystère du cerveau. AMPA sont des récepteurs ionotropiques du glutamate jouent le rôle central dans la plasticité synaptique et la transmission synaptique basale dans le système nerveux central. Distribution des récepteurs AMPA sur la membrane neuronale est remarquablement hétérogène. Ils sont organisés en agrégats fonctionnels distincts, appelés nanodomaines. Des travaux antérieurs ont montré que Neuroligin, la molécule d’adhésion post-synaptique, ancres récepteurs AMPA par PSD95 dans la membrane post-synaptique et constitue en même temps un complexe d’adhésion trans-synaptique avec présynaptique Neurexin, impliqué dans le recrutement de machines de libération vésiculaire sur le site présynaptique. De cette façon, NRLG fonctionnellement organise synapses par la poste de recrutement de molécules présynaptiques essentielles pour réponse synaptique. Ici, nous avons étudié l’effet de la modulation de NRLG1 (modification du niveau d’expression ou de l’activité) sur le dynamique et nano-organisation des récepteurs AMPA au niveau des synapses individuelles. Notre hypothèse est que le complexe NRX-NRG pourrait être impliquée dans la localisation précise des récepteurs post-synaptiques et son apposition avec zone active présynaptique, jouant ainsi le rôle important dans la transduction du signal approprié. Taille de la densité post-synaptique (PSD) est de l’ordre de 500 nm, alors que diamètre moyen des nanodomaines AMPAR 100 nm. Une telle petite dimension nécessitait l’application de techniques de microscopie de super-résolution, dont la résolution de l’ordre de 20-40 nm est presque un ordre de grandeur mieux que microscopie fluorescence limitée par la diffraction. Nanoscopie fluorescence permettent visualiser des cellules jusqu’au niveau presque moléculaire. Pour atteindre mes objectifs, j’ai mis en place différents nanoscopies de localisation d’une seule molécule, qui s’appuient sur séparés dans l’espace et le temps de détection de population choisi de sondes de fluorescence. Il a été proposé que le trafic membranaire des récepteurs de neurotransmetteurs peut contribuer à la modulation de l’efficacité synaptique. J’ai sondé propriétés diffusionnelles des récepteurs AMPA avec suivi de particules unique, qui a été pendant longtemps appliqué pour sonder l’hétérogénéité de la membrane cellulaire. Localisation relative des biomolécules à la base de la compréhension de leur relation fonctionnelle. Il est bien admis que la juxtaposition de deux objets, ainsi que leur colocalisation, peuvent témoigner de leur association. Avec les récents développements dans l’acquisition multi couleur de la molécule unique et images de super-résolution à base d’ensemble, il est maintenant possible d’explorer la colocalisation à l’échelle nanométrique entre biomolécules dans des cellules vivantes et fixe. Malgré l’ la popularité et l’application très répandue, il n’existe que quelques paradigmes d’analyse quantitative pour la colocalisation des images multicolores super-résolution. Ici, avec l’aide de paradigmes conventionnels de mesure de la colocalisation et statistiques multivariées, nous analysons et présentons en isolement l’échelle du détail et proximité des macromolécules au sein de zones fonctionnelles de synapses. En outre, nous utilisons ces paradigmes pour évaluer marqueurs fluorescents impliqués dans la production de routine de la molécule unique fondée images super-résolution. Nous étendons notre analyse élucider en profondeur le co-agrégation des molécules clés synaptiques, PSD95 et récepteurs AMPA, qui sont impliqués dans l’organisation synaptique et transmission basale. / The brain is made of complex networks of interconnected neuronal cells. All our mental activities are underlain by electrochemical signals passing through dedicated neuronal circuits. Climbing further up on the complexity ladder, information processing by neurons is performed by multiple molecules assembling and interacting together. It is well accepted that the understanding of the molecular structuring inside neuronal cells is essential to apprehend functioning of the brain. For this reason, study of the organization of the key neuronal and synaptic molecules greatly contributes to understand the mystery of the brain. AMPA receptors (AMPARs) are ionotropic glutamate receptors that play a central role in synaptic plasticity and basal synaptic transmission in the central nervous system. The distribution of AMPARs on the neuronal membrane is remarkably heterogeneous. They are organized in distinct functional aggregates, called nanodomains. Previous work demonstrate that the postsynaptic adhesion molecule Neuroligin (NRLG) anchors AMPARs through PSD-95 in the postsynaptic membrane while simultaneously forming a trans-synaptic adhesion complex with presynaptic Neurexin (NRX), and recruiting vesicular release machinery at the presynaptic site. In this way, NRLG functionally organizes synapses by recruiting post and pre-synaptic molecules essential for regulation of synaptic responses. Here we studied the effect of NRLG modulation (modification of expression level or activity) on AMPAR nano-dynamics and nano-organization at individual synapses. Our hypothesis is that the NRX-NRLG complex could be involved in the precise localization of postsynaptic receptors and their apposition with the neurotransmitter release sites in the presynaptic active zone, thus playing important role in proper signal transduction. The size of the postsynaptic density (PSD) is in the order of 500 nm, whereas the average diameter of AMPAR nanodomains 100 nm. Such small dimension necessitated the application of super-resolution microscopy techniques, whose resolution in the range of 20-40 nm is almost an order of magnitude better than diffraction limited fluorescence microscopy. Probe-based far-field fluorescence nanoscopies allow visualizing cells down to almost molecular level. To achieve my goals, I implemented different single-molecule localization nanoscopies which rely on the detection of selected populations of fluorescence probes that are separated in space and time. It was proposed that membrane trafficking of neurotransmitter receptors may contribute to modulation of synaptic efficacy. I have probed diffusional properties of AMPARs with single particle tracking, which has long been applied to probe heterogeneity of the cell membrane. Relative localization of biomolecules provides the basis for understanding their functional relationship. It is well accepted that the juxtaposition of two objects, as well as their colocalization, may give evidence of their association. With the recent developments in multi-color acquisition of single molecule and ensemble based super resolution images, it is now possible to explore the colocalization at the nanoscale between biomolecules in live and fixed cells. Despite the popularity and wide spread application of super resolution imaging, there exist only a few quantitative analysis paradigms for the colocalization of multicolor super-resolution images. Here, with the aid of conventional colocalization measurement paradigms and multivariate statistics, we analyze and report in detail the scale segregation and proximity of macromolecules within functional zones of synapses. Furthermore, we use these paradigms to evaluate fluorescent tags involved in the routine generation of single molecule based super-resolution images. We extend our analysis to elucidate in depth the co-aggregation and clustering of two key synaptic molecules, PSD95 and AMPARs, which are involved in basal synaptic organization and transmission.
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Nanoparticle Probes for Ultrasensitive Biological Detection and Motor Protein Tracking inside Living CellsAgrawal, Amit 09 November 2006 (has links)
Semiconductor quantum dots (QDs) have emerged as a new class of fluorescent probes and labeling agents for biological samples. QDs are bright, highly photostable and allow simultaneous excitation of multiple emissions. Owing to these properties, QDs hold exceptional promise in enabling intracellular biochemical studies and diagnosis with unprecedented sensitivity and accuracy. However, use of QD probes inside living cells remains a challenge due to difficulties in delivery of nanoparticles without causing aggregation and imaging single nanoparticles inside living cells. In this dissertation, a systematic approach to deliver, image and locate single QDs inside living cells is presented and the properties of molecular motor protein driven QD transport are studied. First, spectroscopic and imaging methods capable of differentiating single nanoparticles from the aggregates were developed. These technologies were validated by differentiating surface protein expression on viral particles and by enabling rapid counting of single biomolecules. Second, controlled delivery of single QDs into living cells is demonstrated. A surprising finding is that single QDs associate non-specifically with the dynein motor protein complex and are transported to the microtubule organizing center. Accurate localization and tracking of QDs inside cell cytoplasm revealed multiple dynein motor protein attachment resulting in increased velocity of the QDs. Further, spectrin molecule which is known to recruit dynein motor protein complex to phospholipid micelles was found to associate with the QDs. These results may serve as a benchmark for developing new QD surface coatings suitable for intracellular applications. Since, nanoparticles are similar in size to viral pathogens; better understanding of nanoparticle-cell interactions should also help engineer nanoparticle models to study virus-host cell interactions. (Contains AVI format multimedia files)
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Spectral Image Processing with Applications in Biotechnology and PathologyGavrilovic, Milan January 2011 (has links)
Color theory was first formalized in the seventeenth century by Isaac Newton just a couple of decades after the first microscope was built. But it was not until the twentieth century that technological advances led to the integration of color theory, optical spectroscopy and light microscopy through spectral image processing. However, while the focus of image processing often concerns modeling of how images are perceived by humans, the goal of image processing in natural sciences and medicine is the objective analysis. This thesis is focused on color theory that promotes quantitative analysis rather than modeling how images are perceived by humans. Color and fluorescent dyes are routinely added to biological specimens visualizing features of interest. By applying spectral image processing to histopathology, subjectivity in diagnosis can be minimized, leading to a more objective basis for a course of treatment planning. Also, mathematical models for spectral image processing can be used in biotechnology research increasing accuracy and throughput, and decreasing bias. This thesis presents a model for spectral image formation that applies to both fluorescence and transmission light microscopy. The inverse model provides estimates of the relative concentration of each individual component in the observed mixture of dyes. Parameter estimation for the model is based on decoupling light intensity and spectral information. This novel spectral decomposition method consists of three steps: (1) photon and semiconductor noise modeling providing smoothing parameters, (2) image data transformation to a chromaticity plane removing intensity variation while maintaining chromaticity differences, and (3) a piecewise linear decomposition combining advantages of spectral angle mapping and linear decomposition yielding relative dye concentrations. The methods described herein were used for evaluation of molecular biology techniques as well as for quantification and interpretation of image-based measurements. Examples of successful applications comprise quantification of colocalization, autofluorescence removal, classification of multicolor rolling circle products, and color decomposition of histological images.
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Investigating the role of acetylation of LC3-family proteins in regulating autophagyAli, Mohamed 06 1900 (has links)
L'autophagie maintient l'homéostasie cellulaire en dégradant les composants cellulaires. Chez l'humain, les protéines LC3 jouent un rôle central dans l'autophagie en interagissant avec d'autres facteurs contenant des régions d'interaction LC3 (LIR). Cette thèse porte sur le rôle de différents facteurs contenant des LIR, tels que le facteur nucléaire DOR et la protéine NSs du virus de la fièvre de la vallée du Rift (VFVR). Les protéines LC3 sont principalement présentes dans le noyau des cellules au repos normales, et leur passage au cytosol en réponse au stress nécessite une interaction avec DOR. Récemment, il a été démontré que cette interaction entre DOR et LC3B dépend de la désacétylation de deux résidus lysine conservés (K49/K51 de LC3A et K46/K48 de GABARAP). Cependant, les détails mécanistiques du rôle des résidus lysine individuels dans le transfert d'autres protéines LC3 demeurent inconnus. De plus, la caractérisation de l'interaction NSs-LC3 ainsi que son impact sur l'autophagie lors de l'infection par le RVFV demeurent évasives. Par conséquent, l'objectif de ces études est d'investiguer les différences structurelles et fonctionnelles des protéines humaines LC3 à différents stades de l'autophagie via leur interaction avec DOR et NSs.
Nos études biophysiques et structurales ont permis d’identifier des éléments clés déterminant la spécificité de la région d'interaction LC3 de DOR (DORLIR) pour GABARAP. Nos études structurales ont défini une conformation en feuillet chez DORLIR lorsqu'elle est en complexe avec GABARAP, ce qui joue un rôle important dans l'établissement de cette spécificité. Les études structurales ont également montré que l'acétylation de la deuxième Lys de GABARAP ou LC3A perturbe des interactions clés du W35 de DORLIR, ce qui conduit à une diminution de l'affinité qui est cohérente avec nos résultats ITC. Ces résultats ont été confirmés grâce à des expériences cellulaires en utilisant des substitutions K-en-Q pour imiter l'acétylation des Lys. En cellules, les substitutions K-en-Q à la deuxième Lys ont entravé le transfert cytoplasmique de GABARAP et de LC3A, ainsi que leur colocalisation avec DOR, tandis que les substitutions K-en-Q à la première Lys se comportent comme des protéines de type sauvage. Dans l'ensemble, la désacétylation de la deuxième Lys conservée est cruciale pour le transfert cytoplasmique de GABARAP et LC3A lors de l'autophagie, ce qui diffère de ce qui a été observé auparavant avec LC3B, où la désacétylation des deux Lys était nécessaire. Cette étude fournit également des informations sur les interactions entre la protéine NSs du VFVR et les protéines LC3, ainsi que l'impact de NSs sur l'autophagie lors de l'infection par le VFVR. Nous avons identifié quatre motifs potentiels d'interaction LC3 (NSs1-4) dans la protéine NSs, et des études d’ITC ont démontré que NSs4 interagit avec une affinité sous micromolaire-micromolaire avec les protéines LC3 humaines. De plus, nous avons confirmé que les protéines LC3 interagissent avec NSs dans les cellules, et que chez les cellules infectées par le RVFV, LC3A colocalise avec NSs. Dans l'ensemble, les résultats indiquent que la protéine NSs joue un rôle clé dans la modification de l'autophagie lors des infections par le VFVR. / Autophagy maintains cellular homeostasis through catabolism of cellular components including organelles, proteins, and pathogens. In humans, the six LC3 (Microtubule-associated protein 1 light chain 3) protein (LC3A, LC3B, LC3C, GABARAP, GABARAPL1 and GABARAPL2) play a pivotal role in autophagy through interactions with other factors that contain LC3-interacting regions (LIRs). This study focuses on the role of different factors that contain LIRs such as the nuclear factor DOR and the NSs protein from the RVFV. LC3 proteins are predominantly present in the nucleus of normal resting cells and their shuttling to the cytosol in response to stress requires interaction with DOR. Recently, this interaction between DOR and LC3B was shown to depend on the deacetylation of two conserved Lys residues (K49/K51in LC3 subfamily proteins and K46/K48 in GABARAP subfamily proteins). However, the mechanistic details of the role of the individual Lys residues in the shuttling other LC3 proteins is unknown. In addition, the characterization of NSs-LC3 interaction as well as its impact on RVFV (Rift Valley fever virus) infection on autophagy remains elusive. Therefore, the goal of these studies is to investigate the structural and the functional differences of the six human LC3 proteins in different stages of autophagy through their interaction with DOR and NSs.
Our biophysical and structural studies identified key elements determining the specificity of the LIR from DOR (DORLIR) for the GABARAP subfamily. Our structural studies defined a -sheet conformation in DORLIR when complexed with GABARAP, which is important role for establishing this specificity. ITC studies with acetylated versions of LC3A and GABARAP demonstrated that acetylation of the second Lys significantly decreases binding to the DORLIR whereas acetylation at the first Lys has little to no effect. Our structural studies also demonstrate that acetylation at the second Lys of either GABARAP or LC3A disrupts key interactions between W35 of the DORLIR, which leads to the decreased affinity. The in vitro results were verified in cellular experiments using K-to-Q substitutions to mimic Lys acetylation. In cells, K-to-Q substitutions at the second Lys impaired the cytoplasmic shuttling of both GABARAP and LC3A from the nucleus as well as their colocalization with DOR, whereas K-to-Q substitutions at the first Lys behaved like wild-type proteins. Taken together, the deacetylation of the second conserved Lys is critical for the cytoplasmic shuttling of GABARAP and LC3A during autophagy, which is in contrast to what was observed with LC3B where deacetylation of both Lys was required. This study also provides insights into interactions between the NSs protein of RVFV and LC3 proteins and the impact of NSs on autophagy during RVFV infection. We identified four potential LIR motifs (NSs1-4) in the NSs protein and ITC studies demonstrated that NSs4 interacts with submicromolar-micromolar affinity with the human LC3 proteins. In addition, we confirmed that LC3 proteins interact with NSs in cells and that in RVFV infected cell LC3A colocalizes with NSs. Taken together, the results indicate that the NSs protein plays a key role in altering autophagy during RVFV infections.
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Effects of Shear Stress on the Distribution of Kindlins in Endothelial CellsJones, Sidney V. 29 May 2014 (has links)
No description available.
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