Global ETD Search

21	Regulation of the signal transduction pathways of the unfolded protein response during chronic and physiological ER stresses Gomez Vargas, Javier Alejandro 01 August 2016 (has links) The unfolded protein response (UPR) is activated by protein misfolding stress in the endoplasmic reticulum (ER). The UPR is a transcriptional program that aims to maintain ER folding capacity, where imbalances between protein load and processing ability is termed ER stress. Signal transduction of the UPR begins with 3 ER-resident transmembrane sensors: PERK, IRE1 and ATF6. All sensors initiate downstream signaling cascades which culminate in improved protein folding, transcriptional upregulation of genes encoding ER chaperones, and mechanisms to reduce translational and transcriptional ER load, therefore re-establishing ER homeostasis. The signaling cascades of each sensor are distinct but cooperative, and involve a significant amount of crosstalk, feedback and overlap. Indeed, there are many pathological and physiological conditions have an effect on ER protein burden, and therefore on activation of the UPR. Increases in protein load in professional secretory cells, hypoxic conditions in a tumor mass, obesity all induce cause changes in the ER folding environment. Although we understand how the UPR contributes to relieve ER stress under acute conditions (e.g. pharmacological treatment) much less is understood about the contributions to physiological processes and chronic stress conditions. Our overall goal was to understand how the UPR is activated during physiological settings, the mechanisms it uses to maintain folding capacity under these setting and the specific components responsible for adapting the response to various stresses. We first decided to understand a chronic stress from a transgenic approach. By creating a knockout mouse, the genetic deletion functions as a stress and we can understand its physiological role. By compounding two genetic deletions in UPR components (ATF6α and p58IPK) we provide evidence for the developmental role these components play. Homozygous deletion ATF6α bears no gross histological phenotype yet causes synthetic lethality when combined with p58IPK deletion. This also reveals that the UPR is able to adapt to genetic impairment of protein folding in vivo. Next, to better understand these chronic states, we established an experimentally tractable chronic stress treatment in vivo. Our treatment suppressed ATF6α dependent chaperone expression through an mRNA degradative mechanism, which led to long term changes in UPR expression. We determined that chronic conditions can change the sensitivity of the UPR to ER stress, potentially as an adaptive consequence. We also showed that sensitivity to ER stress can be changed during chronic stress. Finally we simulated the UPR in a computational ordinary differential equation (ODE) model in order to determine how various stresses and component interactions determine the output of the UPR. We built a series of equations to describe the UPR signaling network, entrained it on experimental data and refined it through the use of transgenic knockout cells. Our model was robust enough to recreate experimental measurements of UPR components when tested in parallel with knockout cells. We found that stress sensitivity is dependent on the crosstalk and negative feedback connections of the UPR. This study has enhanced our understanding of activation of the UPR under non-acute settings. It demonstrates that the UPR is a signaling hub with a broad output range that is capable of handling a variable degree of insults because of the intrinsic properties of the signaling network. This provides a better understanding for the contributions of the UPR to physiological stresses and certain chronic diseases. Chronic Stress Computer Modeling Liver Mouse Model Unfolded Protein Response Cell Biology
22	ROLE OF MCP-1 AND CCR2 IN ETHANOL-INDUCED DAMAGE IN THE DEVELOPING BRAIN Zhang, Kai 01 January 2019 (has links) Fetal alcohol spectrum disorders (FASD) are caused by alcohol exposure during pregnancy and is the leading cause of mental retardation. Alcohol exposure during development results in the loss of neurons in the developing brain. The underlying molecular mechanisms are unclear and there currently is no cure for FASD. Ethanol-induced neuronal death is accompanied by neuroinflammation. Chemokine monocyte chemoattractant protein 1 (MCP-1) and its receptor C-C chemokine receptor type 2 (CCR2) are critical mediators of neuroinflammation and microglial activation. Using a third trimester equivalent mouse model of ethanol exposure, we found that treatment of Bindarit (MCP-1 synthesis inhibitor) and RS504393 (CCR2 antagonist) significantly reduced ethanol-induced microglia activation/neuroinflammation, and neuroapoptosis in the developing brain. Moreover, ethanol plus MCP-1 caused more neuronal death in a neuron/microglia co-culture system than neuronal culture alone, and Bindarit and RS504393 attenuated ethanol-induced neuronal death in the co-culture system. Ethanol activated TLR4 and GSK3β, two key mediators of microglial activation in the brain and cultured microglial cells (SIM-A9). Blocking MCP-1/CCR2 signaling attenuated ethanol-induced activation of TLR4 and GSK3β. Further, we determined whether knocking out of MCP-1/CCR2 ameliorates neonatal alcohol exposure-induced long-lasting behavioral deficits in adolescent and adult mice. C57BL/6 and MCP-1-/-/CCR2-/- mice were exposed to alcohol (5 g/kg) by subcutaneously injection on PD4. A series of behavioral tests including Open Field (PD 35-36 and PD 70-71), Rotor-Rod (PD 38 and PD 73), Balance Beam (PD 40 and PD75) and Morris Water Maze (PD 42 and PD77) were performed in the adolescence and adulthood. We found that MCP-1-/-/CCR2-/- mice were resistant to neonatal alcohol exposure-induced deficits in motor function in the Rotor-Rod and Balance Beam tests; MCP-1 and CCR2 deficiency also protected mice against neonatal ethanol exposure induced long lasting deficits in learning and memory in the Morris Water Maze testing. Collectively, these results suggest that MCP-1/CCR2 signaling plays an important role in ethanol-induced microglial activation/neuroinflammation and neurodegeneration in the developing brain and also plays an important role in developmental alcohol exposure induced long-lasting behavioral deficits in adolescence and adulthood. Fetal alcohol syndrome chemokines development glia neuroinflammation neurodegeneration unfolded protein response Pharmacology
23	Is Latent Equine Herpesvirus Type 1 (EHV-1) Reactivated by Triggering Activation of the Unfolded Protein Response in Equine Peripheral Blood Leukocytes? 2013 June 1900 (has links) Equine Herpesvirus type 1 (EHV-1) is a worldwide threat to the health of horses. It can cause mild respiratory disease, abortions and deaths of newborn foals as well as a potentially fatal neurologic disorder known as Equine Herpesvirus Myeloencephalopathy (EHM). The virus is maintained in populations by stress-induced periodic reactivation of virus in long-term latently infected horses and transmission of the reactivated virus to susceptible individuals. In horses, peripheral blood leukocytes (PBLs) are thought to be an important site for EHV-1 latent genomes. Since the Unfolded Protein Response (UPR) is a cellular response to a variety of stressors that has been linked to reactivation of herpes simplex virus in humans, a virus closely related to EHV-1, I tested the hypothesis that latent EHV-1 relies on the UPR as a pluripotent stress sensor and uses it to reactivate lytic gene expression. Since little work has been done in defining the UPR in horses, I first successfully developed a quantitative real-time polymerase chain reaction (RT-qPCR) assay to detect and quantitate transcripts for selected UPR genes in equine dermal (E.Derm) cells and PBLs. Activation of the UPR was achieved in both cell types using thapsigargin and a difference in gene expression after activation of the UPR in two equine cell types was found. A nested PCR assay to detect and distinguish latent EHV-1 and EHV-4 was evaluated and the sensitivity of the technique to detect EHV-1 was determined. I discovered that the nested PCR technique was not sensitive enough to detect the estimated one latent viral genome in 50,000 PBLs. Lytic EHV-1 infection was characterized by single step growth curve in E.Derm cells and consistent detection of temporal EHV-1 gene expression by RT-qPCR was achieved. The relationship between EHV-1 gene expression and UPR gene expression during lytic infection was investigated. While EHV-1 infection had no effect on UPR gene expression, activation of the UPR appeared to decrease the expression of EHV-1 genes temporarily and reversibly during the first 4 h after infection. Finally, detection of EHV-1 in PBLs from horses presumed to be latently infected by co-cultivation with E. Derm cells permissive to EHV-1 infection was attempted. To detect viral DNA, PBLs were stimulated with thapsigargin or interleukin 2 (IL-2) which was previously reported to induce reactivation of latent EHV-1. I was not able to reproduce previously published experiments of reactivation in vitro of latent EHV-1 by stimulation with IL-2, and virus reactivation did not occur after stimulation of PBLs with thapsigargin. In summary, a RT-qPCR assay to measure the expression of equine UPR genes was developed and activation of the UPR by treatment of E.Derm cells and PBLs with thapsigargin was successfully achieved. A difference in gene expression after activation of the UPR in two equine cell types was found. In contrast to what has been reported for other alphaherpesviruses, there appears to be no, or only little, interaction between the UPR and EHV-1 during viral infection. Detection of latent EHV-1 genomes in PBLs was not achieved by using a nested PCR, as this technique was not sensitive enough to detect the estimated one latent viral genome in 50,000 PBLs. Finally, latent EHV-1 was not detected in presumed latently infected PBLs or reactivated by triggering the UPR in equine PBLs.
24	Luman/CREB3 is a novel retrograde regulator of sensory neuron regeneration: mechanism of action 2014 July 1900 (has links) Luman (CREB3, LZIP) is a basic leucine zipper transcription factor involved in regulation of the unfolded protein response (UPR), dendritic cell maturation, and cell migration. But despite reported expression in primary sensory neurons, little is known about its role in the nervous system. Luman mRNA from rat sensory neurons was amplified and its coding sequence was determined. The rat Luman cDNA contains a full-length open reading frame encoding 387 amino acids, and the recombinant protein generated from this clone activated transcription from UPR elements. Quantitative RT-PCR revealed rat Luman transcripts in a variety of rat tissues with the highest levels in nervous system tissue. In situ hybridization confirmed the findings and demonstrated that the Luman mRNA hybridization signal localizes to neurons and satellite glial cells in dorsal root ganglia (DRG), the cytoplasm of hepatocytes in liver, and the hippocampal pyramidal cell layers in CA1 and CA3 and the granular cell layer of the dentate gyrus. Luman protein localizes with axonal endoplasmic reticulum (ER) components along the axon length within the sciatic nerve and is activated by sciatic nerve injury. Adult sensory axons also contain Luman mRNA which is translated within the axon and transported to the cell body via the importin-mediated retrograde transport system in response to nerve injury. Further, creation of an N-terminal, C-terminal dual fluorescence-tagged Luman adenoviral construct allowed visualization of the cleavage and retrograde translocation of the N-terminal portion of Luman to the nucleus in real time in vivo and in vitro. Neuronal or subcellular axonal knockdown of Luman significantly impaired the intrinsic ability of injury-conditioned, but not naïve, sensory neurons to extend the regeneration-associated elongating form of neurites. Sciatic nerve crush injury also induced activation of the UPR in axotomized DRGs, including genes linked to cholesterol biosynthesis. Knockdown of Luman decreased the activation of UPR and cholesterol biosynthesis, and axotomy-inducted increases in neurite outgrowth, which could be largely rescued with either mild UPR inducer treatment or cholesterol supplementation. Together these findings provide novel insights linking remote injury-associated axonal ER responses to the regenerative growth capacity of adult sensory neurons via axonal activation and synthesis of Luman and reveal a role for the UPR in regulation of axotomy-induced neurite outgrowth that is critically dependent on Luman. dorsal root ganglion sensory neuron transcription factor axotomy unfolded protein response
25	PLANT RESPONSES TO ABIOTIC STRESSES: TWO MOLECULAR APPROACHES IN ARABIDOPSIS AND MAIZE Humbert, Sabrina 25 August 2011 (has links) Abiotic stress is highly detrimental to crop productivity worldwide. Research is key to meeting the challenges of modern agriculture in a sustainable and positive fashion. This thesis contributes to our understanding of plant stress responses by examining two molecular aspects of abiotic stress. The first part of the work focused on the Unfolded Protein Response (UPR), a general stress response mechanism triggered by the accumulation of unfolded or misfolded proteins in the endoplasmic reticulum. The study was conducted with the model plant Arabidopsis and shed new light on key players in the pathway. An unconventional alternative splicing mechanism, similar to the one identified in other higher eukaryotes, was found to parallel the activation of an ER-resident chaperone. The data suggest that this event is important to alleviate cellular stress in response to adverse environmental conditions such as heat. Further understanding of this pathway will help to develop a more complete view of the mechanisms involved in this response. The second part of the work investigated the interaction between nitrogen limitation and drought at the transcriptional level. A genome-wide transcript profiling experiment was performed to provide a comprehensive view of the response to nitrogen and water limitation in corn. The main finding was the demonstration of a clear synergistic effect between both stresses, an effect that was unexpectedly as important as either stress applied alone. This study adds to our current knowledge of abiotic stress response in plants and should provide the groundwork necessary to build future strategies for crop enhancement. plant nitrogen drought unfolded protein response heat abiotic stress Arabidopsis maize microarray
26	Investigating the Role of ATF6Beta in the ER Stress Response of Pancreatic Beta-cells Odisho, Tanya 09 December 2013 (has links) Endoplasmic reticulum (ER) stress has been implicated as a causative factor in the development of pancreatic beta-cell dysfunction and death resulting in type 2 diabetes. This thesis examined the role of ATF6beta in the ER stress response of beta-cells. Using an ATF6beta-specific antibody, expression of full-length ATF6beta was detected in various insulinoma cell lines and rodent islets and the induction of the active form (ATF6beta-p60) under ER stress conditions. Knock-down of ATF6beta in INS-1 832/13 cells did not affect mRNA induction of known ER stress response genes in response to tunicamycin-induced ER stress, however it increased the susceptibility of beta-cells to apoptosis. Conversely, overexpression of ATF6beta-p60 reduced the apoptotic phenotype. Microarray results suggest ATF6beta functions to induce expression of adaptive genes also regulated by ATF6alpha, but also several specific targets genes. These findings have increased our understanding of the role of ATF6beta in the ER stress response of beta-cells. Diabetes ER stress Apoptosis ATF6beta unfolded protein response ATF6 signaling pathway pancreatic beta-cell 0719
27	Investigating the Role of ATF6Beta in the ER Stress Response of Pancreatic Beta-cells Odisho, Tanya 09 December 2013 (has links) Endoplasmic reticulum (ER) stress has been implicated as a causative factor in the development of pancreatic beta-cell dysfunction and death resulting in type 2 diabetes. This thesis examined the role of ATF6beta in the ER stress response of beta-cells. Using an ATF6beta-specific antibody, expression of full-length ATF6beta was detected in various insulinoma cell lines and rodent islets and the induction of the active form (ATF6beta-p60) under ER stress conditions. Knock-down of ATF6beta in INS-1 832/13 cells did not affect mRNA induction of known ER stress response genes in response to tunicamycin-induced ER stress, however it increased the susceptibility of beta-cells to apoptosis. Conversely, overexpression of ATF6beta-p60 reduced the apoptotic phenotype. Microarray results suggest ATF6beta functions to induce expression of adaptive genes also regulated by ATF6alpha, but also several specific targets genes. These findings have increased our understanding of the role of ATF6beta in the ER stress response of beta-cells. Diabetes ER stress Apoptosis ATF6beta unfolded protein response ATF6 signaling pathway pancreatic beta-cell 0719
28	Post-transcriptional Regulation of Membrane-associated RNAs Jagannathan, Sujatha January 2013 (has links) <p>RNA localization provides the blueprint for compartmentalized protein synthesis in eukaryotic cells. Current paradigms indicate that RNAs encoding secretory and membrane proteins are recruited to the endoplasmic reticulum (ER), via positive selection of a `signal peptide' tag encoded in the protein. Thus RNA sorting to the ER follows protein sorting and the RNA is considered a passive player. However, RNAs have been shown to access the ER independent of the signal peptide and display a wide range of affinities to the ER that does not correlate with signal peptide strength. How and why mRNAs localize to the ER to varying extents and whether such localization serves a purpose besides protein sorting is poorly understood. To establish the cause and consequence of RNA binding to the ER membrane, I pose three primary questions: 1. How are mRNAs targeted to the ER? 2. Once targeted, how are mRNAs anchored to the ER membrane? 3. Are ER localized mRNAs subject to transcript-specific regulation? </p><p>I address cytosolic mRNA targeting to the ER by comparing the partitioning profiles of cytosolic/nuclear protein-encoding mRNA population (mRNACyto) to that of mRNAs encoding a signal peptide (mRNAER). I show that, at a population level, mRNACyto display a mean ER enrichment that is proportional to the amount of ER-bound ribosomes. Thus, I propose that targeting of mRNACyto to the ER is stochastic and over time, the specific interactions engaged by an individual mRNACyto with the ER determines its steady state partitioning profile between the cytoplasm and the ER. </p><p>To address the modes of direct binding of mRNA to the ER, I examined the association of various RNA populations with the ER after disrupting membrane-bound ribosome's interaction with its ER receptor. mRNACyto and most of mRNAs encoding secretory proteins (mRNACargo) are released upon disruption of ribosome-receptor interactions, indicating no direct mRNA-ER interactions. However, the population of mRNAs that encode resident proteins of the endomembrane organelles such as the ER, lysosome, endosome and the Golgi apparatus (mRNARes) maintain their association with the ER despite the disruption of ribosome-receptor interactions. These results indicate direct binding of mRNARes to the ER, further suggesting that the function of the encoded proteins dictates the mode of association of corresponding mRNA with the ER. </p><p>To uncover the mode of mRNARes binding directly to ER, I performed differential proteomic analysis of cytosolic and membrane bound RNA-protein complexes, which revealed a network of RNA binding proteins that interact uniquely with the ER-anchored mRNAs. The anchoring of endomembrane resident protein-encoding RNAs to the ER through these RNA binding proteins may reflect an imprinting of the ER with the information necessary for the continued biogenesis of the endomembrane organelle system even in situations where translation-dependent ER targeting of an mRNA is compromised. </p><p>Finally, I address whether ER-bound mRNAs can be regulated differentially by comparing the fates of two signal peptide-encoding RNAs, B2M and GRP94, during the unfolded protein response (UPR). I show that in response to ER stress, GRP94 mRNA, but not B2M, relocates to stress-induced RNA granules, thus escaping an RNA decay program that operates at the ER membrane during the UPR. Hence, I propose that the mode of RNA association to the ER is subject to regulation and influences the fate of RNAs during cellular stress. Thus, by demonstrating diverse modes of mRNA localization to the ER and differential regulation of ER bound mRNAs during cellular stress, my work has helped establish an emerging role for the ER as a post-transcriptional gene regulatory platform.</p> / Dissertation Cellular biology Endoplasmic reticulum Membrane domain Protein synthesis RNA binding protein RNA localization Unfolded protein response
29	Regulation of mammalian IRE1α : co-chaperones and their importance Amin-Wetzel, Niko January 2018 (has links) When unfolded proteins accumulate in the endoplasmic reticulum (ER), the unfolded protein response (UPR) increases ER protein folding capacity to restore protein folding homeostasis. Unfolded proteins activate UPR signalling across the ER membrane to the nucleus by promoting oligomerisation of IRE1, a conserved transmembrane ER stress receptor. Despite significant research, the mechanism of coupling ER stress to IRE1 oligomerisation and activation has remained contested. There are two proposed mechanisms by which IRE1 may sense accumulating unfolded proteins. In the direct binding mechanism, unfolded proteins are able to bind directly to IRE1 to drive its oligomerisation. In the chaperone inhibition mechanism, unfolded proteins compete for the repressive BiP bound to IRE1 leaving IRE1 free to oligomerise. Currently, these two mechanisms respectively lack compelling in vivo and in vitro evidence required to assess their validity. The work presented here first describes in vivo experiments that identify a role of the ER co-chaperone ERdj4 as an IRE1 repressor that promotes a complex between the luminal Hsp70 BiP and the luminal stress-sensing domain of IRE1α (IRE1LD). This is then built on by a series of in vitro experiments showing that ERdj4 catalyses formation of a repressive BiP-IRE1LD complex and that this complex can be disrupted by the presence of competing unfolded protein substrates to restore IRE1LD to its default, dimeric, and active state. The identification of ERdj4 and the in vitro reconstitution of chaperone inhibition establish BiP and its J-domain co-chaperones as key regulators of the UPR. This thesis also utilises the power of Cas9-CRISPR technology to introduce specific mutations into the endogenous IRE1α locus and to screen for derepressing IRE1α mutations. Via this methodology, two predicted unstructured regions of IRE1 are found to be important for IRE1 repression. Finally, this thesis challenges recent in vitro findings concerning the direct binding mechanism.
30	A proteina FEZ1 : pouca organização estrutural, atividades associadas a elementos do citoesqueleto e formação do fenotipo "flower like" / FEZ1 protein : little organizational structure, activities related to elements of the cytoskeleton and generation of the "flower like" phenotype Lanza, Daniel Carlos Ferreira 14 August 2018 (has links) Orientador: Jorg Kobarg / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-14T01:48:42Z (GMT). No. of bitstreams: 1 Lanza_DanielCarlosFerreira_D.pdf: 39179290 bytes, checksum: cbd84a5b7ba74e985bc1fc48595debd6 (MD5) Previous issue date: 2009 / Resumo: A proteína FEZ1 foi caracterizada inicialmente como um ortólogo da proteína UNC76 de C. elegans, responsável pelo desenvolvimento e fasciculação neuronal nesse verme. Estudos subsequentes demonstraram sua atuação em processos de desenvolvimento neuronal, polarização celular, mecanismos de transporte associado à kinesinas e transporte de vesículas e mitocôndrias. Outros trabalhos demonstraram que a superexpressão de FEZ1 interfere no ciclo de vida de alguns tipos de vírus como HIV e JCV. FEZ1 é capaz de interagir com mais de 51 proteínas diferentes, e participa em muitos processos celulares. Observamos que FEZ1 apresenta ausência de estrutura molecular rígida, sendo pertencente à classe das natively unfolded proteins, e é capaz de formar dímeros em solução. Essa observação condiz com sua extrema capacidade de interagir com muitas proteínas diferentes. A capacidade de FEZ1 interagir com outras proteínas é influenciada pela fosforilação da sua região C-terminal por diferentes isoformas de PKC. FEZ1 interage e colocaliza com NEK1 e com CLASP2 em células de mamífero, em uma região candidata ao centrossomo. Essas interações são dependentes da região coiled-coil presente na parte C-terminal de FEZ1, e ocorrem em regiões coiled-coil de CLASP2 e NEK1. A interação com CLASP2 é rompida quando FEZ1 é fosforilada por PKC. A superexpressão de FEZ1 causa o fenótipo flower like observado em células de alguns tipos de leucemia. Nós observamos que FEZ1 interage e colocaliza com a e ?-tubulinas e que a formação desse fenótipo em células HEK293 ocorre devido a uma alteração na organização dos microtúbulos causada pelo excesso de FEZ1. A formação do fenótipo flower like é influenciada por ativação das vias de PKC e PI3K. Os dados obtidos durante o nosso trabalho indicam que FEZ1 é uma proteína intrinsecamente desenovelada, que atua em processos celulares associados ao citoesqueleto e centrossomo em conjunto com NEK1 e CLASP2, e que defeitos em sua regulação, possivelmente pelas vias de PKC ou PI3K, causam alteração da organização dos microtúbulos originando núcleos flower like. / Abstract: FEZ1 was identified first as a orthologue of C elegans UNC-76 protein, that plays functions related to neuronal development in this worm. Subsequent studies, shows FEZ1 functions in neuronal development process, cell polarization, transport mechanisms associated to kinesins and vesicular and mitochondrial transports. Other works showed that FEZ1 superexpression interfere in the life cycle of some viral types such as HIV and JCV. FEZ1 is able to interact with more than 51 different proteins and participates in several cellular processes. We observed that FEZ1 has a mobile molecular structure, is a member of the natively unfolded protein class, and can form dimers in solution. This observation is in agreement with its capacity to interact with a large number of different proteins. The capacity of FEZ1 to interact with other proteins is influenced by different PKC isoforms phosphorylation in its C-terminal region. FEZ1 interacts and co-localizes with NEK1 and CLASP2 in a centrossomal candidate region of mammalian cells. These interactions are dependent of a coiled coil inside the C-terminal region of FEZ1, and occur in dependence of coiled coil regions of NEK1 and CLASP2. The interaction between FEZ1 and CLASP2 is abolished after FEZ1 phosphorylation by PKC. The FEZ1 overexpression causes the flower like phenotype observed in cells of some leukemias. We observed that FEZ1 interacts and co-localizes with _ and _-tubulins and that the phenotype formation in HEK293 cells is mediated by an atypical organization of microtubule spindles, caused by overexpression of FEZ1. The flower like phenotype formation is influenced by activation of PKC and PI3K pathways. The data generated by our work indicate that FEZ1 is an intrinsically unfolded protein, that works in cellular processes associated to the cytoskeleton in conjunct with NEK1 and CLASP2, and that defects in its regulation, maybe via the PKC or PI3K pathways, causes alterations in microtubule organization and formation of the "flower like" nuclei. / Doutorado / Bioquimica / Doutor em Biologia Funcional e Molecular Proteina intrinsicamente desenovelada Microtubulos Leucemia Neurônios Fasciculação Intrinsically unfolded protein Microtubules Leukemia Neurons Fasciculation

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