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Podjednotka exocystu AtSEC15b: její úloha v morfogenezi rostlinné buńky a charakterizace její interakční Rab GTPázy. / Exocyst subunit AtSEC15b: its role in plant cell morphogenesis and characterization of its Rab interacting partnerToupalová, Hana January 2011 (has links)
Organization of endomembrane compartments in all eukaryotic cells is dependent on continuous transport of membrane vesicles. Major part of the core regulators of intracellular membrane transport is represented by small GTPases from the Rab family. Rab GTPases cycle between the GTP-bound "active" and GDP-bound "inactive" forms. In their active form, they are able to interact with specific effectors and perform their functions. Exocyst is an octameric complex involved in regulation of secretion. It functions as an effector of Rab GTPases in yeast and mammals and tethers secretory vesicles to the plasma membrane prior to the actual membrane fusion. Using publicly available expression data, we have identified candidates from Rab GTPase family for the interaction with exocyst subunit AtSEC15b in plants and demonstrated that AtSEC15b specifically interacts with AtRABA4a GTPase. We also showed that, like in yeast and mammals, Arabidopsis Sec15b binds Rab GTPase also probably in GTP-dependent manner, implying that this interaction is well conserved throughout the eukaryotic kingdoms. We also successfully demonstrated the complementation of yeast thermo-sensitive mutant strain, sec15-1. Based on this observation we concluded that AtSEC15b is able to substitute the function of yeast SEC15 and restore the phenotype....
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Systematic characterization of Rab GTPase cell type expression and subcellular localization in Drosophila melanogasterDunst, Sebastian 08 June 2015 (has links) (PDF)
The Rab family of small GTPases orchestrates intracellular endomembrane transport through the recruitment of diverse effector proteins. Since its first discovery in 1987, almost 70 Rab proteins have been identified in humans to date and their perturbed function is implicated in several hereditary and acquired diseases.
In this Ph.D. thesis, I systematically characterize cell type expression and subcellular localization of all Rab proteins present in Drosophila melanogaster utilizing a genetic resource that represents a major advance for studying membrane trafficking in vivo: the ’Drosophila YRab library’. This collection comprises 27 different D. melanogaster knock-in lines that harbor YFPMyc fusions to each Rab protein, referred to as YRab.
For each YRab, I present a comprehensive data set of quantitative and qualitative expression profiles across six larval and adult tissues that include 23 annotated cell types. The whole image data set, along with its annotations, is publicly accessible through the FLYtRAB database that links to CATMAID for online browsing of tissues.
I exploit this data set to address basic cell biological questions. i) How do differentiating cells reorganize their transport machinery to perform cell type-specific functions? My data indicates that qualitative and quantitative changes in YRab protein expression facilitate the functional specialization of differentiated cells. I show that about half of the YRab complement is ubiquitously expressed across D. melanogaster tissues, while others are missing from some cell types or reflect strongly restricted cell type expression, e.g. in the nervous system. I also depict that relative YRab expression levels change as cells differentiate. ii) Are specific Rab proteins dedicated to apical or basolateral protein transport in all epithelia? My data suggests that the endomembrane architecture reflects specific tasks performed by particular epithelial tissues, rather than a generalized apicobasal organization. I demonstrate that there is no single YRab that is similarly polarized in all epithelia. Rather, different epithelial tissues dynamically polarize the subcellular localization of many YRab compartments, producing membrane trafficking architectures that are tissue- and stage-specific.
I further discuss YRab cell type expression and subcellular localization in the context of Rab family evolution. I report that the conservation of YRab protein expression across D. melanogaster cell types reflects their evolutionary conservation in eukaryotes. In addition, my data supports the assumption that the flexible deployment of an expanded Rab family triggered cell differentiation in metazoans.
The FLYtRAB database and the ’Drosophila Rab Library’ are complementary resources that facilitate functional predictions based on YRab cell type expression and subcellular localization, and to subsequently test them by genetic loss-of-function experiments. I demonstrate the power of this approach by revealing new and redundant functions for Rab23 and Rab35 in wing vein patterning.
My data collectively highlight that in vivo studies of endomembrane transport pathways in different D. melanogaster cell types is a valuable approach to elucidate functions of Rab family proteins and their potential implications for human disease.
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INVOLVEMENT OF DIFFERENT RAB GTPASES IN THE TRAFFICKING OF CXCR4 AND CCR5 HOMO- AND HETERODIMERS BETWEEN THE ENDOPLASMIC RETICULUM AND PLASMA MEMBRANE IN HEK293 AND JURKAT CELLSCharette, Nicholle Jeanine 13 July 2011 (has links)
Little is known about the outward trafficking of receptor dimers from the endoplasmic reticulum to the plasma membrane, or the role that trafficking plays in assembly, targeting and specificity of receptor signalling. Bimolecular fluorescence complementation was used to follow prescribed receptor homo/heterodimers in Jurkat cells and clarify the trafficking itineraries those receptors follow to reach the plasma membrane. Chemokine receptors CXCR4 and CCR5 were chosen due to their implication in numerous pathologies including, HIV and cancer, and their ability to form homo and hetero-oligomers. This study demonstrates that although the individual receptors composing heterodimeric complexes are the same as in homodimeric complexes, the heterodimer traffics and signals independently of its constituent homodimers. The presence of CD4 affects the trafficking of CCR5 containing dimers but not the CXCR4 homodimer. These observations demonstrate the importance of considering receptor heterodimers as distinct signalling entities that should be more carefully and individually characterized.
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Group A Streptococcus modulates RAB1- and PIK3C3 complex-dependent autophagy / A群レンサ球菌はRAB1およびPIK3C3複合体を介したオートファジーを制御するToh, Hirotaka 23 March 2021 (has links)
京都大学 / 新制・課程博士 / 博士(医学) / 甲第23063号 / 医博第4690号 / 新制||医||1048(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 岩田 想, 教授 長尾 美紀, 教授 秋山 芳展 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Structural and biochemical investigation of the regulation of Rab11a by the guanine nucleotide exchange factors SH3BP5 and TRAPPIIJenkins, Meredith L. 29 November 2019 (has links)
Rab11 is a critical GTPase involved in the regulation of membrane trafficking in the endocytic pathway, and it’s misregulation is involved in a variety of human diseases including Huntington’s disease and Alzheimer’s disease. Additionally, de novo mutations (DNMs) of Rab11 have been identified in patients with developmental disorders, and interestingly several parasites, viruses, and bacteria can subvert membrane trafficking through Rab11 positive vesicles to allow for replication and evasion from the immune system. Although Rab11 is one of the best characterized Rab GTPases, hindering the capability to completely understand Rab11 regulation and its role in human disease is the lack of detail describing how Rab11 proteins are activated by their cognate guanine nucleotide exchange factors (GEFs). This thesis is therefore focused on revealing the molecular mechanisms of the GEFs responsible for the activation of Rab11: SH3BP5 and TRAPPII. To investigate the recently discovered GEF SH3BP5, we solved the 3.1Å structure of Rab11 bound to SH3BP5 and revealed a coiled coil architecture of SH3BP5 that mediates exchange through a unique Rab-GEF interaction. The structure revealed a unique rearrangement of the switch-I region of Rab11 compared to other solved Rab-GEF structures, with a constrained conformation when bound to SH3BP5. Mutational analysis of switch-I revealed the molecular determinants that allow for Rab11 selectivity over evolutionarily similar Rab GTPases, and GEF deficient mutants of SH3BP5 show greatly decreased Rab11 activation in cellular assays of active Rab11. To interrogate the highly controversial GEF TRAPPII, we recombinantly expressed and purified the 9 subunit, 427 kDa complex in Spodoptera frugiperda 9(Sf9) cells. We found that the TRAPPII complex is a GEF for both Rab1 and Rab11, and we discovered novel activity for another Rab GTPase. To interrogate the role of these GEFs in human disease, we used HDX-MS and nucleotide exchange assays to show that some DNMs destabilize Rab11 either through a complete or partial disruption of nucleotide binding. Importantly, we discovered that one of these DNMs, K13N, completely prevented SH3BP5 and TRAPPII mediated nucleotide exchange, revealing a putative mechanism of disease. Overall the work completed in this thesis leads to a greater understanding of the molecular mechanisms underlying the activation of Rab11 by its cognate GEFs. / Graduate / 2020-11-25
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Papel da RAB2A, RAB5A, RAB17 e RAB18 na função efetora de células citotóxicas. / Role of RAB2A, RAB5A, RAB17 andRAB18 in effector functions of cytotoxic cells.Vieira, Narciso Junior 24 November 2016 (has links)
Linfócitos T CD8 e células NK atuam no combate à infecções por bactérias intracelulares, vírus e células tumorais, provocando a morte dessas células por meio da secreção de grânulos citotóxicos. Proteínas RAB GTPase têm se destacado em estudos de tráfego intracelular, porém, são escassos dados sobre o papel destas proteínas em células citóxicas. Um estudo prospectivo de proteômica realizado por nosso grupo identificou a RAB2A, RAB5A, RAB17 e RAB18 em grânulos citotóxicos. Análises mais aprofundadas revelaram que a RAB2A está associada a proteínas como LAMP-1 e LAMP-2, enquanto que RAB5A, RAB17 e RAB18 estavam presentes na mesma linhagem em um contexto não contemplado neste estudo. Desenvolvemos ainda uma abordagem de silenciamento gênico da RAB2A, e por fim, adaptamos uma série de protocolos de simples execução e baixo custo para avaliar funções efetoras de células NK. O conhecimento da maquinaria secretória é fundamental, uma vez que defeitos nas vias de tráfego intracelular constituem a base de um grande número de doenças que desencadeiam quadros fatais. / CD8 T lymphocytes and NK cells fight against infections by intracellular bacteria, viruses and tumor cells by killing those cells through the secretion of cytotoxic granules. RAB GTPase has been highlighted in studies of intracellular trafficking, however there are scarce reports regarding the role of these proteins in cytotoxic cells. A proteomic study performed by our group identified RAB2A, RAB5A, RAB17 and RAB18 in cytotoxic granules. Further analysis revealed that RAB2A is associated with LAMP-1 and LAMP-2, while RAB5A, RAB17 and RAB18 were present in the same cell line, but in a context not included in this study. We also have developed a gene silencing approach for RAB2A and adapted a number of protocols, simple and low-cost, that can be used to evaluate effector functions of natural killer cells The knowledge of secretory machinery involved in the movement cytotoxic granules of cytotoxic cells is critical, since defects in intracellular trafficking pathways constitute the basis for a large number of diseases which trigger death.
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Papel da RAB2A, RAB5A, RAB17 e RAB18 na função efetora de células citotóxicas. / Role of RAB2A, RAB5A, RAB17 andRAB18 in effector functions of cytotoxic cells.Narciso Junior Vieira 24 November 2016 (has links)
Linfócitos T CD8 e células NK atuam no combate à infecções por bactérias intracelulares, vírus e células tumorais, provocando a morte dessas células por meio da secreção de grânulos citotóxicos. Proteínas RAB GTPase têm se destacado em estudos de tráfego intracelular, porém, são escassos dados sobre o papel destas proteínas em células citóxicas. Um estudo prospectivo de proteômica realizado por nosso grupo identificou a RAB2A, RAB5A, RAB17 e RAB18 em grânulos citotóxicos. Análises mais aprofundadas revelaram que a RAB2A está associada a proteínas como LAMP-1 e LAMP-2, enquanto que RAB5A, RAB17 e RAB18 estavam presentes na mesma linhagem em um contexto não contemplado neste estudo. Desenvolvemos ainda uma abordagem de silenciamento gênico da RAB2A, e por fim, adaptamos uma série de protocolos de simples execução e baixo custo para avaliar funções efetoras de células NK. O conhecimento da maquinaria secretória é fundamental, uma vez que defeitos nas vias de tráfego intracelular constituem a base de um grande número de doenças que desencadeiam quadros fatais. / CD8 T lymphocytes and NK cells fight against infections by intracellular bacteria, viruses and tumor cells by killing those cells through the secretion of cytotoxic granules. RAB GTPase has been highlighted in studies of intracellular trafficking, however there are scarce reports regarding the role of these proteins in cytotoxic cells. A proteomic study performed by our group identified RAB2A, RAB5A, RAB17 and RAB18 in cytotoxic granules. Further analysis revealed that RAB2A is associated with LAMP-1 and LAMP-2, while RAB5A, RAB17 and RAB18 were present in the same cell line, but in a context not included in this study. We also have developed a gene silencing approach for RAB2A and adapted a number of protocols, simple and low-cost, that can be used to evaluate effector functions of natural killer cells The knowledge of secretory machinery involved in the movement cytotoxic granules of cytotoxic cells is critical, since defects in intracellular trafficking pathways constitute the basis for a large number of diseases which trigger death.
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Systematic characterization of Rab GTPase cell type expression and subcellular localization in Drosophila melanogasterDunst, Sebastian 14 April 2015 (has links)
The Rab family of small GTPases orchestrates intracellular endomembrane transport through the recruitment of diverse effector proteins. Since its first discovery in 1987, almost 70 Rab proteins have been identified in humans to date and their perturbed function is implicated in several hereditary and acquired diseases.
In this Ph.D. thesis, I systematically characterize cell type expression and subcellular localization of all Rab proteins present in Drosophila melanogaster utilizing a genetic resource that represents a major advance for studying membrane trafficking in vivo: the ’Drosophila YRab library’. This collection comprises 27 different D. melanogaster knock-in lines that harbor YFPMyc fusions to each Rab protein, referred to as YRab.
For each YRab, I present a comprehensive data set of quantitative and qualitative expression profiles across six larval and adult tissues that include 23 annotated cell types. The whole image data set, along with its annotations, is publicly accessible through the FLYtRAB database that links to CATMAID for online browsing of tissues.
I exploit this data set to address basic cell biological questions. i) How do differentiating cells reorganize their transport machinery to perform cell type-specific functions? My data indicates that qualitative and quantitative changes in YRab protein expression facilitate the functional specialization of differentiated cells. I show that about half of the YRab complement is ubiquitously expressed across D. melanogaster tissues, while others are missing from some cell types or reflect strongly restricted cell type expression, e.g. in the nervous system. I also depict that relative YRab expression levels change as cells differentiate. ii) Are specific Rab proteins dedicated to apical or basolateral protein transport in all epithelia? My data suggests that the endomembrane architecture reflects specific tasks performed by particular epithelial tissues, rather than a generalized apicobasal organization. I demonstrate that there is no single YRab that is similarly polarized in all epithelia. Rather, different epithelial tissues dynamically polarize the subcellular localization of many YRab compartments, producing membrane trafficking architectures that are tissue- and stage-specific.
I further discuss YRab cell type expression and subcellular localization in the context of Rab family evolution. I report that the conservation of YRab protein expression across D. melanogaster cell types reflects their evolutionary conservation in eukaryotes. In addition, my data supports the assumption that the flexible deployment of an expanded Rab family triggered cell differentiation in metazoans.
The FLYtRAB database and the ’Drosophila Rab Library’ are complementary resources that facilitate functional predictions based on YRab cell type expression and subcellular localization, and to subsequently test them by genetic loss-of-function experiments. I demonstrate the power of this approach by revealing new and redundant functions for Rab23 and Rab35 in wing vein patterning.
My data collectively highlight that in vivo studies of endomembrane transport pathways in different D. melanogaster cell types is a valuable approach to elucidate functions of Rab family proteins and their potential implications for human disease.
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Rab-domain dynamics in endocytic membrane trafficking / Zur Dynamik von Rab-Domänen während endozytotischer TransportprozesseRink, Jochen C. 26 April 2005 (has links) (PDF)
Eukaryotic cells depend on cargo uptake into the endocytic membrane system, which comprises a functionally interconnected network of endosomal compartments. The establishment and maintenance of such diverse compartments in face of the high rates of exchange between them, poses a major challenge for obtaining a molecular understanding of the endocytic system. Rab-GTPases have emerged as architectural key element thereof: Individual family members localize selectively to endosomal compartments, where they recruit a multitude of cytoplasmic effector proteins and coordinate them into membrane sub-domains. Such "Rab-domains" constitute modules of molecular membrane identity, which pattern the endocytic membrane system into a mosaic of Rab-domains. The main objective of this thesis research was to link such "static" mosaic-view with the highly dynamic nature of the endosomal system. The following questions were addressed: How are neighbouring Rab-domains coordinated? Are Rab-domains stable or can they undergo assembly and disassembly? Are the dynamics of Rab-domains utilized in cargo transport? The first part of this thesis research focused on the organization of Rab-domains in the recycling pathway. Utilizing Total Internal Reflection (TIRF) microscopy, Rab11-, but neither Rab4- nor Rab5-positive vesicles were observed to fuse with the plasma membrane. Rab4-positive membranes, however, could be induced to fuse in presence of Brefeldin A. Thus, these experiments complete the view of the recycling pathway by the following steps: a) Rab11-carriers likely mediate the return of recycling cargo to the surface; b) such carriers are presumably generated in an Arf-dependent fission reaction from Rab4-positive compartments. Rab11-chromatography was subsequently carried out in the hope of identifying Rab11-effectors functioning at the Rab4-Rab11 domain interface. An as yet uncharacterized ubiquitin ligase was identified, which selectively interacts with both Rab4 and Rab11. Contrary to expectations, however, the protein (termed RUL for *R*ab interacting *U*biquitin *L*igase) does not function in recycling,but appears to mediate trafficking between Golgi/TGN and endosomes instead.In order to address the dynamics of Rab-domains, fluorescently tagged Rab-GTPases were imaged during cargo transport reactions in living cells. Herefore high-speed/long-term imaging procedures and novel computational image analysis tools were developed. The application of such methodology to the analysis of Rab5-positive early endosomes showed that a) The amount of Rab5 associated with individual endosomes fluctuates strongly over time; b) such fluctuations can lead to the "catastrophic" loss of the Rab5-machinery from membranes; c) Rab5 catastrophe is part of a functional cycle of early endosomes, involving net centripetal motility, continuous growth and increase in Rab5 density. Next, the relevance of Rab5 catastrophe with respect to cargo transfer into either the recycling- or degradative pathway was examined. Recycling cargo (transferrin) could be observed to exit Rab5-positive early endosomes via the frequent budding of tubular exit carriers. Exit of degradative cargo (LDL) from Rab5-positive endosomes did not involve budding, but the rapid loss of Rab5 from the limiting membrane.Rab5-loss was further coordinated with the concomitant acquisition of Rab7, suggesting "Rab conversion" as mechanism of transport between early- and late endosomes.Altogether, this thesis research has shown that first, Rab-machineries can be acquired and lost from membranes. Second, such dynamics provide a molecular mechanism for cargo exchange between endosomal compartments. Jointly, these findings lead to the concept of Rab-domain dynamics modulation in /trans/ between neighbouring domains as mechanistic principle behind the dynamic organization of membrane trafficking pathways.
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Study of the mechanism of Tunneling nanotubes formation and their role in aggregate proteins transfer between cells / Etude du mécanisme de formation des Tunneling nanotubes et leur rôle dans le transfert de protéines agrégées entre les cellulesZhu, Seng 29 September 2017 (has links)
Les Tunneling nanotubes (TNT) sont des protrusions cellulaires à base d'actine qui médient la communication cellulaire en transférant des cargos cellulaires. Les différents types de communication intercellulaires sont de plus en plus considérés comme des cibles potentielles pour le traitement de différentes maladies, telles que les maladies infectieuses liées aux virus et bactéries, les cancers ou les maladies neurodégénératives. Des études récentes ont mis en évidence un mécanisme de propagation d'agrégats protéiques ressemblant à la propagation du prion dans diverses maladies neurodégénératives non infectieuses telles que la maladie d'Alzheimer (AD), la démence frontotemporelle (FTD), la maladie de Parkinson (PD) et la maladie de Huntington. Ces maladies se caractérisent par l'accumulation de protéines mal repliées dans le cerveau des patients. Ainsi, on peut envisager de nouvelles stratégies thérapeutiques pour bloquer la propagation des protéines anormales dans tout le cerveau. Il a été démontré que les TNT pourraient jouer un rôle essentiel dans la propagation des agrégats de prions au sein du système nerveux central (SNC) et périphérique. Par conséquent, l'étude du mécanisme de la formation de TNT pourrait fournir de nouvelles idées sur le mécanisme de propagation de la maladie et de nouvelles cibles thérapeutiques. L'objectif de ma thèse était d'étudier le rôle du transfert des agrégats de protéines par les TNT entre les cellules et d'étudier le mécanisme de formation des TNT. Dans notre laboratoire, nous avons déjà montré que les TNT permettent le transfert de prions entre les cellules. Dans la première partie de mon doctorat, j'ai confirmé que les transferts d'agrégats de prions entre les cellules de CAD neuronales se faisaient par les TNT à l'intérieur de vésicules endocytiques (Zhu et al., 2015). De plus, en collaboration avec un collègue, nous avons fourni des preuves que les agrégats de prions pourraient être transférés entre des astrocytes primaires et des neurones et que ce transfert était médié par un contact cellulaire (Victoria et al., 2016). J'ai également collaboré à une autre étude où nous avons montré que les agrégats d'α-synucléine (caractéristiques de la maladie de Parkinson) peuvent être transférés entre les cellules à l'intérieur des lysosomes, et que ce transfert intercellulaire est médié par les TNT (Abounit et al., 2016). Dans mon deuxième projet, afin d'étudier le mécanisme de la formation de TNT, j'ai effectué un crible à haut débit pour les Rab GTPase. J'ai trouvé que Rab8 et Rab11 peuvent favoriser la formation des TNT, et que les cascades Rab8-VAMP3, Rab11-ERM et Rab8-Rab11 sont impliquées dans la formation des TNT. Mes données suggèrent que la polymérisation de l'actine et le trafic de membranes sont impliqués dans la formation des TNT. Ces résultats permettent d'éclairer le mécanisme de la formation des TNT et de fournir des preuves moléculaires que les Rab GTPases régulent ce processus. / Tunneling nanotubes are actin-based cell protrusions that mediate cell-to-cell communication by transferring cellular cargos. The different types of intercellular communication are increasing by being considered as potential targets for the treatment of various diseases, such as infectious diseases linked to viruses and bacteria, cancers or neurodegenerative diseases. Recent studies have highlighted a prion-like mechanism of propagation of protein misfolding in a variety of common, non-infectious, neurodegenerative diseases such as Alzheimer’s disease (AD), Frontotemporal dementia (FTD), Parkinson’s disease (PD), and Polyglutamine (PolyQ) diseases, which are characterized by the accumulation of misfolded proteins in the brain of patients. Thus, new therapeutic strategies to block propagation of protein misfolding throughout the brain can be envisaged. It has been shown that TNTs might play a critical role in spreading of prion aggregates within the CNS and from the periphery. Therefore, the study of mechanism of TNT formation could provide new insights on the mechanism of disease propagation and novel therapeutic targets. The aim of my thesis was to study the role of TNT-mediate protein aggregates transfer between cells and to investigate the mechanism of TNT formation. In our lab, we already reported TNT mediate prion transfer between cells. In the first part of my PhD, I further confirmed that prion aggregates transfer between neuronal CAD cells through TNT inside endocytic vesicles (Zhu et al., 2015). Furthermore in collaboration with a colleague, we provided evidences that prion aggregates could transfer between primary astrocytes and neurons and the transfer was mediated by cell-to-cell contact (Victoria et al., 2016). I also collaborated to another study where we showed that α-synuclein aggregates (Parkinson’s disease) can transfer between cells inside lysosomes, and the intercellular transfer is mediated by TNTs (Abounit et al., 2016).In my second project, in order to investigate the mechanism of TNT formation, I performed a High-content screening of Rab GTPase. I found that Rab8 and Rab11 can promote TNT formation, that Rab8-VAMP3, Rab11-ERM and Rab8-Rab11 cascades are involved in TNT formation. My data suggests that both actin polymerization and membrane trafficking are involved in TNT formation. These results help to shed light on the mechanism of TNT formation, and provide molecular evidences that Rab GTPases regulate this process.
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