Global ETD Search

51	Analyse des propriétés oncogéniques de cIAP1 : contribution de ses partenaires cdc42 et E2F1 / cIAP1 oncogenic properties analysis : contribution of its partners cdc42 and E2F1 Berthelet, Jean 04 November 2014 (has links) La protéine cIAP1 (cellular Inhibitor of Apoptosis Protein-1) de la famille des IAP (Inhibitor of Apoptosis Protein) est un oncogène avec une activité E3 ubiquitine ligase. Au cours de la différenciation de nombreux modèles cellulaires (macrophages, cellules dendritiques, cellules épithéliales du colon, cellules souches hématopoïetiques, cardiomyocytes), cIAP1 sort du noyau pour se relocaliser dans le cytoplasme, cette relocalisation étant associée à un arrêt de prolifération. La plupart des fonctions connues de cIAP1 sont liées à sa localisation cytoplasmique où il est un régulateur important des voies de signalisation des récepteurs du TNF-a et de NF-?B. Cependant, cIAP1 est principalement exprimée dans le noyau de différents types cellulaires ce qui n’est pas en accord avec son rôle dans la signalisation cellulaire. Mon travail de thèse a permis d’identifier un rôle de cIAP1 dans la prolifération cellulaire. cIAP1 interagit avec le facteur de transcription E2F1 et favorise son recrutement sur les promoteurs des Cycline E et A impliquées dans les transitions G1/S et G2 du cycle cellulaire, ce qui augmente l’expression des transcrits et des protéines de ces deux cibles. Il semblerait que par cette activité, cIAP1 régule la prolifération des cellules et soit important dans l’équilibre entre la prolifération et la différenciation, deux mécanismes cellulaires étroitement liés. Dans un second travail, nous avons montré que cAIP1 est déterminant dans le remodelage du cytosquelette d’actine en réponse au TNF-a. Dans les fibroblastes, le TNF-a induit la formation de fines protrusions membranaires riches en actine appelées filipodes, cette formation étant régulée par cdc42. Mes travaux ont montrés que cIAP1, associé à son partenaire historique TRAF2, régule la formation de ces filipodes. Il est capable d’interagir directement avec la RhoGTPase Cdc42 et de contrôler son activation après un traitement par le TNF- a, mais aussi par l’EGF. De plus, cIAP1 régule également la transformation oncogénique par HRas en augmentant les propriétés invasives et migratoires des cellules. Ces nouvelles fonctions de cIAP1 pourraient contribuer à ses propriétés oncogéniques. / The inhibitor of apoptosis protein cIAP1 (cellular inhibitor of apoptosis protein-1) from the IAP family (Inhibitor of Apoptosis Protein) is an oncogene with an E3 ubiquitin ligase activity. cIAP1 is relocalized from the nucleus to the cytoplasm during the differentiation of many kind of cellular models (macrophages, dendritic cells, colon epithelial cells, hematopoietic stem cells, cardiomyocytes) and this relocalization is associated with a proliferation arrest. The well-known functions of cIAP1 are associated with its cytoplasmic localization, where it regulates the TNFa receptors and NF-?B signaling pathways. However, cIAP1 is mainly expressed in the nucleus on many cell types which is not in accordance with its cell signalling activity. My work identifies a function of cIAP1 in proliferation regulation. cIAP1 interacts with E2F1 transcription factor and favors its recruitment on Cyclins E and A promoters, both involved in G1/S and G2 phases of the cell cycle, which leads to high level of transcript and protein expression of these two targets. It seems that cIAP1 regulates the cellular proliferation and is important for the balance between proliferation and differentiation, two mechanisms tightly connected in cells. In a second work, we showed that cIAP1 is critical for actin cytoskeleton modification upon TNF-a treatment. In fibroblasts, TNF-a induce filipodia formation, a process regulated by cdc42. Our work showed that cIAP1, when associated with its partner TRAF2, interact and control cdc42 activation, a member of Rho GTPases protein family. We also observed that cIAP1 regulates HRas driven oncogenic transformation and increases the motility and invasiveness of the cells. These new functions of cIAP1 in the control of transcription factor and cell cytoskeleton could be important for its oncogenic properties. CIAP1 E2F1 Cdc42 Prolifération TNF-a Cytosquelette d’actine Rho GTPases Filipodes HRas Transformation oncogénique CIAP1 E2F1 Cdc42 Proliferation TNF-a Actin cytoskeleton Rho GTPases Filipodia HRas Oncogenic transformation 572 571.6
52	GTPases Rho e o potencial regenerativo da retina de mamíferos / Rho GTPases and the regenerative potential of the mammalian retina Debbio, Carolina Beltrame Del 09 February 2010 (has links) O Corpo Ciliar (CC) é uma fonte de células tronco da retina de animais adultos, mas sua ativação permanece desconhecida. GTPases Rho são proteínas que reorganizam do citoesqueleto de actina, regulam vias de sinalização e transcrição gênica, sobrevivência celular e proliferação. Neste trabalho, investigamos a expressão das GTPases Rho nas células do CC e seu efeito na regulação do ciclo celular. As GTPases RhoA, RhoB e Rac1 foram expressas nas células do CC e sua ativação pelo ácido lisofosfatidico (LPA) aumentou a expressão dos genes progenitores retinianos Pax6 e Chx10. A inibição das proteínas por Toxina A de Clostridium difficile aumentou a proliferação no CC e potencializou o efeito proliferativo dos fatores de crescimento. A inibição especifica destas proteínas diminuiu a expressão dos transcritos de p21cip, p27kip, p16INK4a e p19INK4d e aumentou de Ki67, CiclinaA e D1. O estudo da via de Wnt indicou que Rac1 regulou os genes de componentes da degradação de -catenina e Lef1. Concluímos que a inativação das GTPases Rho induziu a proliferação das células progenitoras retinianas localizadas no CC e regulou a via de Wnt. Sua ativação induziu o perfil de célula progenitora, sugerindo uma nova ferramenta para o mecanismo de reparo retiniano. / Ciliary Body (CB) is a potential source of stem cells in the adult retina, but its activation is still unknown. Rho GTPases play a role in actin-based cytoskeleton reorganization, regulate signaling pathways and gene transcription, cell survival and cell proliferation. In this study we investigated the expression of Rho GTPases in CB cells and their role on cell cycle regulation. The GTPases RhoA, RhoB and Rac1 were present in CB cells and the activation by lysophosphatidic acid (LPA) increased the expression of the progenitor genes Pax6 and Chx10. The inhibition by Clostridium difficile Toxin A increased the proliferation of CB cells and potentiated the proliferative effect of growth factors. The specific inhibition decreased the expression of p21cip, p27kip, p16INK4a and p19INK4d as well as increased Ki67, cyclinA and D1 transcripts. The Wnt pathway study indicated that Rac1 regulated -catenin degradation genes components and Lef1. Taken together, the inactivation of Rho GTPases stimulated the proliferation of progenitor cells located in CB as well as regulate the Wnt signaling pathway. The proteins activation was correlated to progenitor profile induction. These different mechanisms may provide a potential new approach on retinal repair. Ciliary Body Corpo Ciliar GTPases Rho Progenitores retinianos Proliferação Proliferation Retinal progenitor cells Rho GTPases
53	Caractérisation de Fam65b, un nouvel inhibiteur de RhoA, impliqué dans la réponse des lymphocytes T en aval de CCR7 / Characterization of Fam65b, a new inhibitor of RhoA, and its role in T lymphocytes responses downstream of CCR7 Megrelis, Laura 24 September 2015 (has links) L’efficacité de la réponse immunitaire adaptative repose tout particulièrement sur la motilité des lymphocytes T naïfs entre la circulation sanguine et les organes lymphoïdes secondaires, leur permettant ainsi de rencontrer un antigène spécifique. De nombreuses voies de signalisation sont impliquées dans ce phénomène. En particulier, les Rho GTPases y jouent un rôle central, par leur capacité à moduler le cytosquelette d’actine. Nous avons identifié la protéine Fam65b comme nouveau régulateur de la circulation des lymphocytes T. En effet, nous avons montré que la diminution de l’expression de Fam65b dans des LT primaires humains induit une augmentation de leur polarisation, leur adhésion et leur migration in vitro. Afin d’étudier son rôle dans un contexte plus physiologique, nous avons développé au laboratoire une souris Fam65b-/-, dans laquelle l’expression de Fam65b est supprimée dans le lignage T. Les lymphocytes T issus de ces souris présentent un contenu global en F-actine réduit, une plus grande quantité de L-sélectine et d’intégrines actives à leur surface, et une migration moins rapide et moins rectiligne que leurs équivalents WT. Nous n’avons pu observer, avec nos méthodes, aucune différence significative de polarisation, de migration in vitro ou d’entrée dans les organes lymphoïdes secondaires pour les LT Fam65b-/-. Nous avons identifié les Rho GTPases comme médiateurs de ces effets de Fam65b. Nous avons observé, en cytométrie de flux, que les niveaux de RhoA-GTP et de Rac-GTP sont plus élevés dans les LT murins Fam65b-/-, et que cela est aussi vrai pour RhoA-GTP dans les LT humains exprimant de faibles niveaux de Fam65b. Nous avons identifié, dans des expériences in vitro, le mécanisme par lequel Fam65b inhibe l’activité de RhoA, puisqu’il ralentit sa charge en GTP par les protéines GEF. Nous avons montré, par des techniques de biochimie, que l’activation de RhoA en aval d’une stimulation chimiokine est permise par la dissociation de RhoA et de Fam65b, probable conséquence de la phosphorylation de Fam65b. Cette dissociation a aussi été observée pour Fam65b et Rac1, mais les mécanismes mis en jeu restent à déterminer. D’autre part, l’expression de Fam65b est sous le contrôle du facteur de transcription FOXO1, connu pour son rôle dans le contrôle de l’écotaxie (homing) via la régulation de l’expression de molécules permettant l’entrée dans les ganglions lymphatiques. Fam65b, régulateur atypique de l’activité des Rho GTPases, représente donc un lien inédit entre la voie PI3K/FOXO1 et les Rho GTPases. / The motility of naive T lymphocytes between the blood and secondary lymphoid organs is essential to the efficiency of the adaptative immune response, and allows those cells to meet their cognate antigen. Numerous signaling pathways are involved in this phenomenon, such as Rho GTPases, modulators of the actin cytoskeleton. We have identified Fam65b as a new regulator of T lymphocytes recirculation. We have shown that a decrease of Fam65b expression in human primary T cells increases the morphological polarization, the adhesion and the in vitro migration of those cells. Looking for a more physiological model, we developed, in the lab, a Fam65b KO (Knock-Out) mouse, specific to the T lineage. In those animals, T cells showed decreased levels of F-actin, an increase in the display of L-selectin and integrins, and a slower and less straight migration, compared to WT (Wild-Type) T cells. On the other hand, we weren't able to see any significant differences in the morphological polarisation, the in vitro migration or the homing capacity of the Fam65b KO T cells. We have identified Rho GTPases as mediators of the effects of Fam65b. We showed, in flow cytometry, that the amount of RhoA-GTP and Rac-GTP are increased in the Fam65b KO cells. The RhoA-GTP levels are also increased in human primary T cells expressing low levels of Fam65b. We have identified, in in vitro experiments, that Fam65b slows down RhoA loading with GTP by its GEF proteins, thus inhibiting RhoA activity. Moreover, we showed that Fam65b dissociates from RhoA after chemokine stimulation of T cells, thus allowing RhoA activation. The phosphorylation of Fam65b is a probable cause to this phenomenon. Fam65b also dissociates from Rac1 in these conditions, although no mechanism is yet known. Furthermore, the transcription factor FOXO1 controls the expression of Fam65b. FOXO1 is also known to control the homing capacity of T cells, since it controls the expression of molecules involved in the entry of lymphocytes in the lymph nodes. Fam65b, an atypical regulator of Rho GTPases activity, thus represents a new connection between the PI3K/FOXO1 and the Rho GTPases pathways. Lymphocyte T Fam65b RhoA Rac1 Rho GTPases Migration FOXO1 CCL19 Écotaxie Homing T Lymphocyte 571.96
54	Cell signaling by Rho and Miro GTPases : Studies of Rho GTPases in Cytoskeletal Reorganizations and of Miro GTPases in Mitochondrial Dynamics Fransson, Åsa January 2008 (has links) <p>The Ras superfamily of GTPases embraces six major branches of proteins: the Ras, Rab, Ran, Arf, Rho and Miro subfamilies. The majority of GTPases function as binary switches that cycle between active GTP-bound and inactive GDP-bound states. This thesis will focus primarily on the biological functions of the Rho and Miro proteins. The Rho GTPases control the organization of the actin cytoskeleton and other associated activities, whereas the Miro GTPases are regulators of mitochondrial movement and morphology. </p><p>A diverse array of cellular phenomena, including cell movement and intracellular membrane trafficking events, are dependent on cytoskeletal rearrangements mediated by Rho GTPases. Although human Rho GTPases are encoded by 20 distinct genes, most studies involving Rho GTPases have focused on the three representatives RhoA, Rac1 and Cdc42, which each regulate specific actin-dependent cellular processes. In an effort to compare the effects of all Rho GTPase members in the same cell system, we transfected constitutively active Rho GTPases in porcine aortic endothelial (PAE) cells and examined their effects on the organization of the actin cytoskeleton. We identified a number of previously undetected roles of the different members of the Rho GTPases. Moreover, we demonstrated that the downstream effectors of Rho GTPases have a broader specificity than previously thought. </p><p>In a screen for novel Ras-like GTPases, we identified the Miro GTPases (Mitochondrial Rho). In our characterization of Miro, we established that these proteins influence mitochondrial morphology and serve functions in the transport of mitochondria along the microtubule system. Additionally, we provided evidence that Miro can be under control of calcium signaling pathways. Mitochondria are highly dynamic organelles that undergo continuous change in shape and distribution. Defects in mitochondrial dynamics are associated with several neurodegenerative diseases. In conclusion, our findings have contributed to a deeper understanding of the biological roles of Rho and Miro GTPases.</p> Ras superfamily Rho GTPases cytoskeleton Miro GTPases mitochondrial dynamics Cell and molecular biology Cell- och molekylärbiologi
55	Cell signaling by Rho and Miro GTPases : Studies of Rho GTPases in Cytoskeletal Reorganizations and of Miro GTPases in Mitochondrial Dynamics Fransson, Åsa January 2008 (has links) The Ras superfamily of GTPases embraces six major branches of proteins: the Ras, Rab, Ran, Arf, Rho and Miro subfamilies. The majority of GTPases function as binary switches that cycle between active GTP-bound and inactive GDP-bound states. This thesis will focus primarily on the biological functions of the Rho and Miro proteins. The Rho GTPases control the organization of the actin cytoskeleton and other associated activities, whereas the Miro GTPases are regulators of mitochondrial movement and morphology. A diverse array of cellular phenomena, including cell movement and intracellular membrane trafficking events, are dependent on cytoskeletal rearrangements mediated by Rho GTPases. Although human Rho GTPases are encoded by 20 distinct genes, most studies involving Rho GTPases have focused on the three representatives RhoA, Rac1 and Cdc42, which each regulate specific actin-dependent cellular processes. In an effort to compare the effects of all Rho GTPase members in the same cell system, we transfected constitutively active Rho GTPases in porcine aortic endothelial (PAE) cells and examined their effects on the organization of the actin cytoskeleton. We identified a number of previously undetected roles of the different members of the Rho GTPases. Moreover, we demonstrated that the downstream effectors of Rho GTPases have a broader specificity than previously thought. In a screen for novel Ras-like GTPases, we identified the Miro GTPases (Mitochondrial Rho). In our characterization of Miro, we established that these proteins influence mitochondrial morphology and serve functions in the transport of mitochondria along the microtubule system. Additionally, we provided evidence that Miro can be under control of calcium signaling pathways. Mitochondria are highly dynamic organelles that undergo continuous change in shape and distribution. Defects in mitochondrial dynamics are associated with several neurodegenerative diseases. In conclusion, our findings have contributed to a deeper understanding of the biological roles of Rho and Miro GTPases. Ras superfamily Rho GTPases cytoskeleton Miro GTPases mitochondrial dynamics Cell and molecular biology Cell- och molekylärbiologi
56	Delivery of Cdc42, Rac1, and Brain-derived Neurotrophic Factor to Promote Axonal Outgrowth After Spinal Cord Injury Jain, Anjana 09 July 2007 (has links) Injury severs the axons in the spinal cord causing permanent functional loss. After injury, a series of events occur around the lesion site, including the deposition of growth cone inhibitory astroglial scar tissue containing chondroitin sulfate proteoglycan (CSPG)- rich regions. It is important to encourage axons to extend through these inhibitory regions for regeneration to occur. The work presented in this dissertation investigates the effect of three proteins, constitutively active (CA)-Cdc42, CA-Rac1, and brain-derived neurotrophic factor (BDNF) on axonal outgrowth through CSPGs-rich inhibitory regions after spinal cord injury (SCI). Cdc42 and Rac1 are members of the Rho GTPase family and BDNF is a member of the neurotrophin sub-family. These three proteins affect the actin cytoskeleton dynamics. Therefore, Cdc42, Rac1, and BDNF promote axonal outgrowth. The effect of CA-Cdc42 and CA-Rac1 on neurite extension through CSPG regions was determined in an in vitro model. Rac1 and Cdc42 s ability to modulate CSPG-dependent inhibition has yet to be explored. In this study, a stripe assay was utilized to examine the effects of modulating all three Rho GTPases on neurite extension across inhibitory CSPG lanes. Alternating laminin (LN) and CSPG lanes were created and NG108-15 cells and E9 chick dorsal root ganglions (DRGs), were cultured on the lanes. Using the protein delivery agent Chariot, the neuronal response to exposure of CA and dominant negative (DN) Rho GTPases, along with the bacterial toxin C3, was determined by quantifying the percent ratio of neurites crossing the CSPG lanes. CA-Cdc42, CA-Rac1, and C3 transferase significantly increased the number of neurites crossing into the CSPG lanes compared to the negative controls for both the NG108-15 cells and the E9 chick DRGs. We also show that these mutant proteins require the delivery vehicle, Chariot, to enter the neurons and affect neurite extension. Therefore, activation of Cdc42 and Rac helps overcome the CSPG-dependent inhibition of neurite extension. In an in vivo study, CA-Cdc42 and CA-Rac1 were locally delivered into a spinal cord cavity. Additionally, BDNF was delivered to the lesion site, either individually or in combination with either CA-Cdc42 or CA-Rac1. The dorsal over-hemisection model was utilized, creating a ~2mm defect that was filled with an in situ gelling hydrogel scaffold containing lipid microtubules loaded with the protein(s) to encourage axons. The lipid microtubules enable slow release of proteins while the hydrogel serves to localize them to the lesion site and permit axonal growth. The results from this study demonstrate that groups treated with BDNF, CA-Cdc42, CA-Rac1, BDNF/CA-Cdc42, and BDNF/CA-Rac1 had significantly higher percentage of axons from the corticospinal tract (CST) that traversed the CSPG-inhibitory regions, as well as penetrate the glial scar compared to the untreated and agarose controls. Although axons from the CST tract did not infiltrate the scaffold-filled lesion, NF-160+ axons were observed in the scaffold. Treatment with BDNF, CA-Cdc42, and CA-Rac1 also reduced the inflammatory response, quantified by analyzing GFAP and CS-56 intensity for reactive astrocytes and CSPGs, respectively, at the interface of the scaffold and host tissue. Therefore, the local delivery of CA-Cdc42, CA-Rac1 and BDNF, individual and combination demonstrated the ability of axons to extend through CSPG inhibitory regions, as well as reduce the glial scar components. Spinal cord injury CNS scaffolds Rho GTPases BDNF Nerve regeneration CNS drug delivery
57	Role of inhibition of protein prenylation in the cholesterol-dependent and cholesterol-independent effects of simvastatin Volk, Catherine B. January 2006 (has links) Statins are widely used to treat hypercholesterolemia. Statins inhibit cholesterol biosynthesis, thereby activating genes involved in cholesterol homeostasis, which are under the control of the Sterol Regulatory Element (SRE). Statins also have cholesterol-independent beneficial cardiovascular effects mediated through the phosphoinositide 3-kinase (PI3-K) / Akt signaling pathway and by inhibition of protein prenylation. Because statins inhibit the synthesis of isoprenoids, they can act by inhibiting the small signaling GTPases Ras and Rho, which require post-translational prenylation to become membrane-anchored and functional. We showed that simvastatin-mediated inhibition of protein prenylation does not appear to play a role in activation of SRE transcriptional activity in HepG2 cells. We also found that when isoprenoids were replenished, basal phospho-Akt decreased, suggesting that inhibition of prenylation by simvastatin mediates Akt phosphorylation. Future studies will be needed to investigate the role that inhibition of protein prenylation plays in the activation of the PI3-K/Akt pathway by simvastatin. / Department of Biology Ras proteins -- Inhibitors. Rho GTPases -- Inhibitors. Hypercholesteremia -- Treatment.
58	Synthesis of substituted 4,5-dihydropyrazoles for the inhibition of Staphylococcus aureus Pelly, Rachel Renae 20 July 2013 (has links) Access to abstract permanently restricted. / Aldol condensation to synthesize substituted chalcones -- Synthesis and testing of substituted 4,5-dihydropyrazoles -- Biological testing of synthesized 4,5-dihydropyrazoles. / Access to thesis permanently restricted. / Department of Chemistry Pyrazoles -- Synthesis Rho GTPases -- Inhibitors Cell membranes -- Physiology
59	A molecular genetic analysis of the role of the guanine nucleotide exchange factor trio during axon pathfinding in the embryonic CNS of Drosophila melanogaster / Forsthoefel, David J. January 2005 (has links) Thesis (Ph. D.)--Ohio State University, 2005. / Available online via OhioLINK's ETD Center; full text release delayed at author's request until 2006 September 20
60	A Three-Molecule Model of Structural Plasticity: the Role of the Rho family GTPases in Local Biochemical Computation in Dendrites Hedrick, Nathan Gray January 2015 (has links) <p>It has long been appreciated that the process of learning might invoke a physical change in the brain, establishing a lasting trace of experience. Recent evidence has revealed that this change manifests, at least in part, by the formation of new connections between neurons, as well as the modification of preexisting ones. This so-called structural plasticity of neural circuits – their ability to physically change in response to experience – has remained fixed as a primary point of focus in the field of neuroscience. </p><p>A large portion of this effort has been directed towards the study of dendritic spines, small protrusions emanating from neuronal dendrites that constitute the majority of recipient sites of excitatory neuronal connections. The unique, mushroom-like morphology of these tiny structures has earned them considerable attention, with even the earliest observers suggesting that their unique shape affords important functional advantages that would not be possible if synapses were to directly contact dendrites. Importantly, dendritic spines can be formed, eliminated, or structurally modified in response to both neural activity as well as learning, suggesting that their organization reflects the experience of the neural network. As such, elucidating how these structures undergo such rearrangements is of critical importance to understanding both learning and memory. </p><p>As dendritic spines are principally composed of the cytoskeletal protein actin, their formation, elimination, and modification requires biochemical signaling networks that can remodel the actin cytoskeleton. As a result, significant effort has been placed into identifying and characterizing such signaling networks and how they are controlled during synaptic activity and learning. Such efforts have highlighted Rho family GTPases – binary signaling proteins central in controlling the dynamics of the actin cytoskeleton – as attractive targets for understanding how the structural modification of spines might be controlled by synaptic activity. While much has been revealed regarding the importance of the Rho GTPases for these processes, the specific spatial and temporal features of their signals that impart such structural changes remains unclear. </p><p>The central hypotheses of the following research dissertation are as follows: first, that synaptic activity rapidly initiates Rho GTPase signaling within single dendritic spines, serving as the core mechanism of dendritic spine structural plasticity. Next, that each of the Rho GTPases subsequently expresses a spatially distinct pattern of activation, with some signals remaining highly localized, and some becoming diffuse across a region of the nearby dendrite. The diffusive signals modify the plasticity induction threshold of nearby dendritic spines, and the spatially restricted signals serve to keep the expression of plasticity specific to those spines that receive synaptic input. This combination of differentially spatially regulated signals thus equips the neuronal dendrite with the ability to perform local biochemical computations, potentially establishing an organizational preference for the arrangement of dendritic spines along a dendrite. Finally, the consequences of the differential signal patterns also help to explain several seemingly disparate properties of one of the primary upstream activators of these proteins: brain-derived neurotrophic factor (BDNF). </p><p>The first section of this dissertation describes the characterization of the activity patterns of one of the Rho family GTPases, Rac1. Using a novel Förster Resonance Energy Transfer (FRET)- based biosensor in combination with two-photon fluorescence lifetime imaging (2pFLIM) and single-spine stimulation by two-photon glutamate uncaging, the activation profile and kinetics of Rac1 during synaptic stimulation were characterized. These experiments revealed that Rac1 conveys signals to both activated spines as well as nearby, unstimulated spines that are in close proximity to the target spine. Despite the diffusion of this structural signal, however, the structural modification associated with synaptic stimulation remained restricted to the stimulated spine. Thus, Rac1 activation is not sufficient to enlarge spines, but nonetheless likely confers some heretofore-unknown function to nearby synapses. </p><p>The next set of experiments set out to detail the upstream molecular mechanisms controlling Rac1 activation. First, it was found that Rac1 activation during sLTP depends on calcium through NMDA receptors and subsequent activation of CaMKII, suggesting that Rac1 activation in this context agrees with substantial evidence linking NMDAR-CaMKII signaling to LTP in the hippocampus. Next, in light of recent evidence linking structural plasticity to another potential upstream signaling complex, BDNF-TrkB, we explored the possibility that BDNF-TrkB signaling functioned in structural plasticity via Rac1 activation. To this end, we first explored the release kinetics of BDNF and the activation kinetics of TrkB using novel biosensors in conjunction with 2p glutamate uncaging. It was found that release of BDNF from single dendritic spines during sLTP induction activates TrkB on that same spine in an autocrine manner, and that this autocrine system was necessary for both sLTP and Rac1 activation. It was also found that BDNF-TrkB signaling controls the activity of another Rho GTPase, Cdc42, suggesting that this autocrine loop conveys both synapse-specific signals (through Cdc42) and heterosynaptic signals (through Rac1). </p><p>The next set of experiments detail one the potential consequences of heterosynaptic Rac1 signaling. The spread of Rac1 activity out of the stimulated spine was found to be necessary for lowering the plasticity threshold at nearby spines, a process known as synaptic crosstalk. This was also true for the Rho family GTPase, RhoA, which shows a similar diffusive activity pattern. Conversely, the activity of Cdc42, a Rho GTPase protein whose activity is highly restricted to stimulated spines, was required only for input-specific plasticity induction. Thus, the spreading of a subset of Rho GTPase signaling into nearby spines modifies the plasticity induction threshold of these spines, increasing the likelihood that synaptic activity at these sites will induce structural plasticity. Importantly, these data suggest that the autocrine BDNF-TrkB loop described above simultaneously exerts control over both homo- and heterosynaptic structural plasticity. </p><p>The final set of experiments reveals that the spreading of GTPase activity from stimulated spines helps to overcome the high activation thresholds of these proteins to facilitate nearby plasticity. Both Rac1 and RhoA, the activity of which spread into nearby spines, showed high activation thresholds, making weak stimuli incapable of activating them. Thus, signal spreading from a strongly stimulated spine can lower the plasticity threshold at nearby spines in part by supplementing the activation of high-threshold Rho GTPases at these sites. In contrast, the highly compartmentalized Rho GTPase Cdc42 showed a very low activation threshold, and thus did not require signal spreading to achieve high levels of activity to even a weak stimulus. As a result, synaptic crosstalk elicits cooperativity of nearby synaptic events by first priming a local region of the dendrite with several (but not all) of the factors required for structural plasticity, which then allows even weak inputs to achieve plasticity by means of localized Cdc42 activation. </p><p>Taken together, these data reveal a molecular pattern whereby BDNF-dependent structural plasticity can simultaneously maintain input-specificity while also relaying heterosynaptic signals along a local stretch of dendrite via coordination of differential spatial signaling profiles of the Rho GTPase proteins. The combination of this division of spatial signaling patterns and different activation thresholds reveals a unique heterosynaptic coincidence detection mechanism that allows for cooperative expression of structural plasticity when spines are close together, which in turn provides a putative mechanism for how neurons arrange structural modifications during learning.</p> / Dissertation Neurosciences Biology Cellular biology Autocrine BDNF Biochemical computation Heterosynaptic plasticity Learning and memory Rho GTPases Structural Plasticity

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