Multiple system atrophy : a translational approach Characterization of the insulin/IGF-1 signaling pathway / L'atrophie multisystématisée : une approche translationnelle

Bassil, Fares

02 September 2015

Ce travail porte sur des approches translationnelles dans les synucléinopathies notamment l’atrophie multisystématisée (AMS). Au-delà de leur rôle dans la régulation du glucose, l’insulin et l’insulin like growth factor-1 (IGF-1) ont des propriétés neurotrophiques. Des études ont montrées que la signalisation de l’insuline/IGF-1 est altérée dans la maladie d'Alzheimer et des données suggèrent l’altération de l’insuline/IGF-1 dans la maladie de Parkinson (MP) et l’AMS. Nous avons mis en évidence une résistance à l’insuline dans les neurones des patients MP et AMS ainsi que dans les oligodendrocytes chez les patients AMS.Mon travail a également consisté à cibler la troncation de l’α-synuclein (α-syn) comme cible thérapeutique. Nous avons démontré dans un modèle murin d’AMS que la diminution de l’α-syn tronquée permettait de réduire l’agrégation d’α-syn et la dégénérescence des neurones dopaminergiques.Enfin, nous avons étudié l’implication dans l’AMS des métalloprotéinases matricielles (MMP), des enzymes impliquées dans remodelage de la matrice, la démyélinisation, la troncation de l’α-syn et la perméabilité de la barrière hémato-encéphalique. Ce travail nous a permis de montrer une augmentation de l’expression et de l’activité de MMPs chez les patients AMS. Nous avons également montré que les cellules gliales sont la source de cette augmentation et que la MMP-2 est retrouvée dans les agrégats des patients AMS.Nous montrons ici de caractéristiques distinctes de l’AMS comme des altérations qui se produisent dans les oligodendrocytes. Nous présentons aussi VX-765 comme un candidat prometteur pour ralentir la progression de la pathologie dans un contexte de synucléinopathie. / This work focused on translational approaches in synucleinopathies and more specifically in multiple system atrophy (MSA). Beyond their role in glucose homeostasis, insulin/IGF-1 are neurotrophic factors in the brain. Studies have shown altered insulin/IGF-1 signalling in Alzheimer’s disease and data suggest impaired insulin signaling/IGF-1 in Parkinson's disease (PD) and MSA. The aim of my work was to characterize insulin/IGF-1 signalling in MSA and PD brain tissue. Both groups showed neuronal insulin resistance. Oligodendrocytes in MSA patients were also insulin resistant.In line with the translational approach, we also targeted α-synuclein (α-syn) truncation pharmacologically in MSA transgenic mice, which led to reduced α-syn aggregation and the protection of dopaminergic neurons.We also assessed the activity and distribution of matrix metalloproteinases (MMPs) in the brain of MSA patients compared to healthy controls. MMPs are involved in the remodelling of the extracellular matrix, demyelination, α-syn truncation and blood brain barrier permeability. We showed altered expression and activity of MMPs in two distinct structures in MSA brains. We were also able to show that glial cells were the source of increased MMPs and show a unique expression of MMPs in α-syn aggregates of MSA patients compared to PD, evidence that might hint at a mechanism that is differently altered between PD and MSA.We here show distinct pathological features of MSA such as key alterations occurring in oligodendrocytes, further supporting MSA as a primary oligodendrogliopathy. We also present VX-765 as a candidate drug for disease modification in synucleinopathies.

Synucléine

Résistance à l'insuline

Métalloprotéinases matricielles

Atrophie multisystématisée

Parkinson

Insuline

Insulin like growth factor-1

Glucagon like peptide-1

Inclusions cytoplasmiques gliales

Synuclein

Insulin resistance

Matrix metalloproteinase

Multiple system atrophy

Parkinson’s disease

Insulininsulin like growth factor-1

Glucagon like peptide-1

Glial cytoplasmic inclusions

Postmortem human brain study

Understanding the Regulatory Steps that Govern the Activation of Mycobacterium Tuberculosis σK

Shukla, Jinal K

January 2013

A distinctive feature of host-pathogen interactions in the case of Mycobacterium tuberculosis is the asymptomatic latent phase of infection. The ability of the bacillus to survive for extended periods of time in the host suggests an adaptive mechanism in M. tuberculosis that can cope with a variety of environmental stresses and other host stimuli. Extensive genomic studies and analysis of knock-out phenotypes revealed elaborate cellular machinery in M. tuberculosis that ensures a rapid cellular response to host stimuli. Prominent amongst these are two-component systems and σ factors that exclusively govern transcription re-engineering in response to environmental stimuli. M. tuberculosis σK is a σ factor that was demonstrated to control the expression of secreted antigenic proteins. The study reported in this thesis was geared to understand the molecular basis for σK activity as well as to explore conditions that would regulate σK activity. Transcription in bacteria is driven by the RNA polymerase enzyme that can associate with multiple σ factors. σ factors confer promoter specificity and thus directly control the expression of genes. The association of different σ factors with the RNA polymerase is essential for the temporal and conditional re-engineering of the expression profile. Environment induced changes in expression rely on a subset of σ factors. This class of σ factors (also referred to as Class IV or Extra-cytoplasmic function (ECF) σ factors) is regulated by a variety of mechanisms. The regulation of an ECF σ factor activity at the transcriptional, translational or posttranslational steps ensures fidelity in the cellular concentration of free, active ECF σ factors. In general, ECF σ factors associate with an inhibitory protein referred to as an anti-σ factor. The release of a free, active σ factor from a σ /anti-σ complex is thus a mechanism that can potentially control the cellular levels of an active σ factor in the cell. M. tuberculosis σK is associated with a membrane bound anti-σK (also referred to as RskA) (Said-Salim et al., Molecular Microbiology 62: 1251-1263: 2006). The extracellular stimulus that is recognized by RskA remains unclear. However, recent studies have suggested the possibility of a regulated proteolytic cascade that can selectively degrade RskA and other membrane associated anti-σ factors. The goal of the study was to understand this regulatory mechanism with a specific focus on the M. tuberculosis σK/RskA complex. The structure of the cytosolic σK/RskA complex and the associated biochemical and biophysical characteristics revealed several features of this /anti-σ complex that were hitherto unclear. In particular, these studies revealed a redox sensitive regulatory mechanism in addition to a regulated proteolytic cascade. These features and an analysis of the M. tuberculosis σK/RskA complex vis-à-vis the other characterized σ/anti σfactor complexes are presented in this thesis. This thesis is organized as follows- Chapter 1 provides an overview of prokaryotic transcription. A brief description of the physiology of M. tuberculosis is presented along with a summary of characterized factors that contribute to the pathogenecity and virulence of this bacillus. The pertinent mechanistic issues of σ/anti-σ factor interactions are placed in the context of environment mediated changes in M. tuberculosis transcription. A summary of studies in this area provides a background of the research leading to this thesis. Chapters 2 and 3 of this thesis describe the structural and mechanistic studies on the σK/RskA complex. The crystal structure of the σK/RskA complex revealed a disulfide bond in domain 4 (σK4). σK4 interacts with the -35 element of the promoter DNA. The disulfide forming cysteines were seen to be conserved in more than 70% of σK homologs, across both gram-positive and gram-negative bacteria. The conservation of the disulfide-forming cysteines led us to further characterize the role of this disulfide in σK/RskA interactions. These were examined by several biochemical and biophysical experiments. The redox potential of these disulfide bond forming cysteine residues were consistent with the proposed role of a sensor. The crystal structure and biochemical studies thus suggest that M. tuberculosis σK is activated under reducing conditions. Chapter 4 of this thesis describes the progress made thus far in the structural and biochemical characterization of an intra-membrane protease, M. tuberculosis Rip1 (Rv2869c). This protein is an essential component of the proteolytic cascade that selectively cleaves RskA. The proteolytic steps that govern the selective degradation of an anti-σ factor were first characterized in the case of E. coli σE (Li, X. et al. Proc. Natl. Acad. Sci. USA, 106:14837-14842, 2009). This cascade is triggered by the concerted action of a secreted protease (also referred to as a site-1 protease) and a trans-membrane protease (also referred to as a site-2 protease). M. tuberculosis Rip1 was demonstrated to be bona-fide site 2 protease that acts on three anti-σ factors viz., RskA, RslA and RsmA (Sklar et al., Molecular Microbiology 77:605-617; 2010). To further characterize the role of Rip1 in the proteolytic cascade, this intra-membrane protease was cloned, expressed and purified for structural, biochemical and biophysical analysis. The preliminary data on this membrane protein is described in this chapter. The conclusions from the studies reported in this thesis and the scope for future work in this area is described in Chapter 5. Put together, the σK/RskA complex revealed facets of σ/anti-σ factor interactions that were hitherto unrecognized. The most prominent amongst these is the finding that an ECF σfactor can respond to multiple environmental stimuli. Furthermore, as seen in the case of the σK/RskA complex, the σ factor can itself serve as a receptor for redox stimuli. Although speculative, a hypothesis that needs further study is whether these features of the σK/RskA complex contribute to the variable efficacy of the M. bovis BCG vaccine. In this context it is worth noting that σK governs the expression of the prominent secreted antigens- MPT70 and MPT83. The studies reported in this thesis thus suggest several avenues for future research to understand mycobacterial diversity, immunogenicity and features of host-pathogen interactions. The appendix section is divided into two subparts- Appendix 1 of the thesis is a review on peptidase V. This is a chapter in The Handbook of Proteolytic enzymes (Elsevier Press, ISBN:9780123822192). Appendix 2 of the thesis includes technical details and an extended materials and methods section.

Mycobacterium Tuberculosis

Mycobacterim Tuberculosis σK Activation

σK Factors

Anti σK Factor RsKA

Mycobacterium Tuberculosis σK Factor

Site-2 Protease (Rip1)

Disulfide Forming Cysteines σK

σK/RsKA Complex

Extra-cytoplasmic Function σ Factor

σ/anti-σ Factor Protein Complexes

Mycobacterium tuberculosis SigK

Bacteriology

Nucleo-cytoplasmic transport of TIS11 proteins and stress granule assembly: two potential new roles for Transportins / Transport nucléo-cytoplasmique des protéines de la famille TIS11 et formation des granules de stress: deux nouveaux rôles potentiels des Transportines

Twyffels, Laure

04 September 2013

The nucleo-cytoplasmic compartmentalization enables eukaryotic cells to develop sophisticated post-transcriptional regulations of gene expression. However, managing the exchanges of macromolecules between the two compartments also represents a formidable challenge for the cells. Nucleo-cytoplasmic exchanges rely on specialized soluble carriers and take place at nuclear pore complexes that span the nuclear envelope. Active nucleo-cytoplasmic transport of proteins, in particular, is performed mainly by a family of carriers called karyopherins, which includes about twenty members in mammals. Some of them, called importins, recognize nuclear localization signals (NLSs) in their substrates and convey them into the nucleus. Others, called exportins, recognize nuclear export signals (NESs) in their substrates and bring them back to the cytoplasm. <p>Many RNA-binding proteins (RBPs) shuttle between the nucleus and the cytoplasm, where they can often fulfill different functions. RBPs also frequently localize into specialized microdomains that are not delimited by a membrane but in which specific factors are concentrated. Those include processing bodies and stress granules, which are cytoplasmic foci associated with mRNA decay, storage and translational repression. Post-transcriptional regulations mediated by RBPs can therefore be modulated rapidly and efficiently through changes in the localization of RBPs.<p>The first part of this work focuses on the subcellular localization and nucleo-cytoplasmic transport of the Drosophila RBP dTIS11. Like its mammalian and yeast homologues, dTIS11 binds AU-rich elements in the 3’UTR of its target mRNAs, and stimulates their rapid deadenylation and decay. Here, we have observed that although dTIS11 appears to be located mostly in the cytoplasm, it is constantly shuttling in and out of the nucleus. We show that the export of dTIS11 from the nucleus depends on the CRM1 exportin and is mediated by a hydrophobic NES that encompasses residues 101 to 113 in dTIS11 sequence. We also identify a cryptic Transportin-dependent PY nuclear localization signal (PY-NLS) in the tandem zinc finger region of dTIS11 and show that it is conserved across the TIS11 protein family. This PY-NLS partially overlaps the second zinc finger (ZnF2) of dTIS11. Importantly, mutations disrupting the capacity of the ZnF2 to coordinate a Zn2+ ion unmask dTIS11 and TTP PY-NLS and promote nuclear import. Taken together, our results indicate that the nuclear export of Drosophila and mammalian TIS11 proteins is mediated by CRM1 through diverging NESs, while their nuclear import mechanism might rely on a conserved PY-NLS whose activity is negatively regulated by ZnF2 folding.<p>In the second part, we present preliminary results which implicate the nucleo-cytoplasmic transport machinery in the assembly of stress granules (SGs) in mammalian cells. SGs contain silenced mRNPs which resemble stalled initiation complexes, and they form transiently in response to acute stress, concomitantly with a global arrest of translation. While their exact role remains undefined, it seems clear that SGs are able to exchange mRNPs with polysomes and with PBs, and that they are connected to post-transcriptional and translational regulations of gene expression during stress. Here, we show that inhibition of Transportin-1 expression or function does not affect the translational status of cells but impairs the assembly of stress granules. Finally, we show that Transportin-1 and -2B, but not -2A, localize into stress granules in response to several stresses. <p>In conclusion, we suggest two potential new roles for Transportins, in the nucleo-cytoplasmic traffic of TIS11 proteins on the one hand and in the assembly of stress granules on the other hand.<p>/<p>Le compartimentage nucléo-cytoplasmique permet aux cellules eucaryotes de réguler l’expression génétique par des mécanismes post-transcriptionnels élaborés. Les ARN messagers subissent plusieurs étapes de maturation dans le noyau avant d’être exportés vers le cytoplasme où ils sont traduits et dégradés. Ces processus sont effectués via des protéines de liaison à l’ARN, ou RBPs. Beaucoup de RBPs exercent des fonctions différentes dans le noyau et dans le cytoplasme, et leur activité peut dès lors être rapidement modulée par une modification de leur localisation.<p>Le transport nucléo-cytoplasmique actif des protéines s’effectue à travers les pores nucléaires et fait majoritairement appel à des transporteurs solubles de la famille des karyophérines. Ceux-ci reconnaissent au sein des protéines à transporter une séquence-passeport appelée NLS (nuclear localization signal) ou NES (nuclear export signal) selon la direction nécessitée. <p>Le présent travail comporte deux parties. La première porte sur la localisation subcellulaire et le transport nucléo-cytoplasmique des protéines de la famille TIS11, et plus particulièrement de dTIS11 qui est le seul représentant de cette famille chez la Drosophile. Comme ses homologues dans d’autres espèces, dTIS11 est une RBP qui favorise la déadénylation et la dégradation de ses ARN messagers cibles. Nos résultats démontrent que dTIS11 fait la navette entre le noyau et le cytoplasme. L’export de dTIS11 hors du noyau est réalisé par la karyophérine CRM1 et fait appel à un NES différent de celui présent chez les protéines TIS11 mammaliennes. Nous identifions également un NLS cryptique au sein du domaine à deux doigts de zinc avec lequel dTIS11 lie l’ARN. Ce NLS correspond partiellement au signal consensus reconnu par la Transportine. Il est démasqué par la mutation du second doigt de zinc ;dans ces conditions, il permet l’import de dTIS11 par la Transportine. Enfin, nous montrons qu’il est conservé dans d’autres protéines de la famille TIS11. <p>Dans la seconde partie, nous nous intéressons aux granules de stress, qui sont des microdomaines cytoplasmiques dans lesquels se concentrent des RBPs et des ARN messagers non traduits en réponse à un stress cellulaire. Nous montrons que les karyophérines appartenant à la sous-famille des Transportines sont présentes dans ces granules et que l’inhibition de l’expression ou de la fonction des Transportines réduit la formation de ces granules en réponse à divers stress cellulaires. Nous écartons la possibilité que ce résultat soit un effet indirect d’un ralentissement du métabolisme traductionnel. Nos résultats suggèrent donc une implication des Transportines dans la formation des granules de stress. <p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Biologie

Sciences exactes et naturelles

Messenger RNA

Proteins -- Physiological transport

ARN messager

Protéines -- Transport physiologique

NES

nuclear export signal

nuclear localization signal

NLS

transportine

transportin

karyopherin

karyophérine

transport nucléo-cytoplasmique

nucleo-cytoplasmic transport

nuclear pore complex

TIS11

ARE

Tristetraprolin

granule de stress

stress granule

M9M

Investigating the Effects of Mutant FUS on Stress Response in Amyotrophic Lateral Sclerosis: A Thesis

Kaushansky, Laura J.

14 August 2015

During stress, eukaryotes regulate protein synthesis in part through formation of cytoplasmic, non-membrane-bound complexes called stress granules (SGs). SGs transiently store signaling proteins and stalled translational complexes in response to stress stimuli (e.g. oxidative insult, DNA damage, temperature shifts and ER dysfunction). The functional outcome of SGs is proper translational regulation and signaling, allowing cells to overcome stress. The fatal motor neuron disease Amyotrophic Lateral Sclerosis (ALS) develops in an age-related manner and is marked by progressive neuronal death, with cytoplasmic protein aggregation, excitotoxicity and increased oxidative stress as major hallmarks. Fused in Sarcoma/Translocated in Liposarcoma (FUS) is an RNA-binding protein mutated in ALS with roles in RNA and DNA processing. Most ALS-associated FUS mutations cause FUS to aberrantly localize in the cytoplasm due to a disruption in the nuclear localization sequence. Intriguingly, pathological inclusions in human FUSALS cases contain aggregated FUS as well as several SG-associated proteins. Further, cytoplasmic mutant FUS incorporates into SGs, which increases SG volume and number, delays SG assembly, accelerates SG disassembly, and alters SG dynamics. I posit that mutant FUS association with stress granules is a toxic gain-of-function in ALS that alters the function of SGs by interaction with SG components. Here, I show that mutant FUS incorporates in to SGs via its Cterminal RGG motifs, the methylation of which is not required for this localization. Further, I identify protein interactions specific to full-length mutant FUS under stress conditions that are potentially capable of interacting with FUS in SGs. Finally, I demonstrate a potential change in the protein composition of SGs upon incorporation of mutant FUS. These findings advance the field of ALS and SG biology, thereby providing groundwork for future investigation.

stress granules

Mutant FUS

Amyotrophic Lateral Sclerosis

ALS

Theses, UMMS

Stress, Physiological

Cytoplasmic Granules

Oxidative Stress

RNA-Binding Protein FUS

Cell Biology

Cellular and Molecular Physiology

Molecular and Cellular Neuroscience

Molecular Biology

Nervous System Diseases

Interaction of Biologically Relevant Nanoparticles with Cells Studied by Cryo Soft X-Ray Tomography

Kepsutlu, Burcu

20 March 2019

In dieser Arbeit, wurden Endozytose und intrazellulären Transportwegen für zwei verschiedene biologisch relevante Nanopartikel (dendritisch Polyglycerolsulfat (dPGS-np) und Polyethylenimin beschichtete Goldnanopartikel (PEI-np)) mit Kryo-Röntgentomographie untersucht. Diese Untersuchungen zeigten, beide Nanopartikeln über Makropinozytose endozytiert werden und dass die meisten Nanopartikel in Endosomen, multivesikulären Körpern und Lysosomen lokalisiert sind. Trotz dieser Ähnlichkeiten im Verhalten beider Partikel gab es auch Unterschiede die zeigten. Im Gegensatz zu PEI-np, wurden einige dPGS-np in Lipidtröpfchen gefunden. Weiterhin verursachen die PEI-np bei einer Konzentration von 0,13 nM ein Zerplatzen von Lysosomen in erheblichem Ausmaß wodurch die Nanopartikel in das Zytoplasma entweichen und teilweise in den Zellkern eindringen. Im Unterschied dazu konnte kein Nachweis für ein Zerplatzen von Lysosomen durch dPGS-np erbracht werde. Interessanterweise wurde ein Wechsel des Endocytose-Weges von der Makropinozytose zu einer mutmaßlichen Caveolae-vermittelten Endozytose beobachtet, wenn die PEI-np-Konzentration um das Zehnfache reduziert wurde. Unter diesen Bedingungen induzierten PEI-np kein Zerplatzen von Lysosomen mehr. Das Ausbleiben von zerplatzten Lysosomen bei dieser niedrigeren Konzentration korreliert mit einer verringerten Zellschädigung und hat somit wichtige Auswirkungen auf die Verwendung von PEI beim Gentransfer. Überraschenderweise stellte sich heraus, dass beide Nanopartikelarten eine bisher nicht beobachtete umfassende zytoplasmatische Veränderungen in den Zellen induzierten. Insbesondere wurden nach der Inkubation mit beiden Diese zytoplasmatischen Veränderungen könnten wichtige physiologische Veränderungen widerspiegeln, jedoch ist hierzu zusätzliche Forschung erforderlich. Diese Beobachtungen deuten darauf hin, dass das Verhalten biologisch relevanter Nanopartikel in Zukunft vorhersehbarer werden kann durch weitere systematische Studien. / In this thesis, the endocytosis and trafficking pathways of two different biologically relevant nanoparticles, namely dendritic polyglycerol sulfate coated gold nanoparticles (dPGS-np) and polyethyleneimine coated gold nanoparticles (PEI-np) were investigated via cryo soft X-ray tomography. Both nanoparticles were found to be endocytosed predominantly via macropinocytosis, and most nanoparticles became localized to endosomes, multivesicular bodies and lysosomes. Despite these similarities in trafficking, there were also key differences. Some dPGS-np were found in lipid droplets but no PEI nanoparticles were found in this compartment. At a concentration of 0.13 nM, PEI-np were observed to induce extensive rupture of lysosomes, leading to significant levels of cytoplasmic escape and nuclear entry. In contrast, no evidence for lysosomal rupture with dPGS-np was detected, and concomitantly very low levels of cytoplasmic escape and no nuclear entry were found. Interestingly, when the PEI-np concentration was reduced by ten-fold, a switch in the endocytosis pathway from macropinocytosis to a putative caveolae-mediated endocytosis was observed. Importantly, under these conditions, PEI nanoparticles no longer induced lysosomal rupture. This lack of lysosomal rupture at the lower concentration was correlated with reduced cellular damage, and so has important implications for use of PEI in gene delivery. Most surprisingly, both nanoparticle types were found to induce similar global cytoplasmic alterations in the cells. These cytoplasmic alterations could reflect important physiological changes, but further work is required to determine this. Our observations suggest that the behavior of biologically relevant nanoparticles might become more predictable in the future by further application of systematic studies.

Endozytose

intrazellulären Transportwegen

biologisch relevante Nanopartikel

Kryo-Röntgentomographie

Lipidtröpfchen

Zerplatzen von Lysosomen

zytoplasmatischen Veränderungen

endocytosis

trafficking pathways

biologically relevant nanoparticles

cryo soft Xray tomography

lipid droplets

lysosomal rupture

cytoplasmic alterations

541 Physikalische Chemie

570 Biologie

615 Pharmakologie und Therapeutik

WE 5360

VE 9857

VX 8567

VG 8977

ddc:541

ddc:570

ddc:615

Spindle-Localized CPE-Mediated Translation Controls Mediotic Chromosome Segregation

Eliscovich, Carolina

11 June 2008

La progresión meiótica y el desarrollo embrionario temprano están programados, en parte, por la activación tradcuccional de mRNAs maternos como lo son los que codifican para las proteinas de ciclina B1 o mos. Estos mRNAs no son traducidos al mismo tiempo ni en el mismo lugar. Por lo contrario, su traducción está especificamente regulada por elementos de poliadenilación citoplasmática (CPEs) presentes en sus 3'UTRs. Los elementos CPEs reclutan a la proteina de unión a CPE (CPE-binding protein CPEB (Colegrove-Otero et al., 2005; de Moor et al., 2005; Mendez and Richter, 2001; Richter, 2007)). Esta proteina de unión al RNA no sólo determina cuándo y en qué medida un mRNA será activado traduccionalmente por poliadenilación citoplasmática (Mendez et al., 2000a; Mendez et al., 2000b; Mendez et al., 2002) sino que también participa, junto con el represor de la traducción Maskin, en el transporte y la localización de sus mRNAs diana hacia los sitios de localización subcelular donde su traducción ocurrirá (Huang et al., 2003; Huang and Richter, 2004). Durante el desarrollo embrionario de Xenopus, CPEB se encuentra localizada en el polo animal de los oocitos y más tarde, sobre el huso mitótico y centrosomas en el embrión (Groisman et al., 2000). Se ha demostrado que embriones de Xenopus inyectados con agentes que interrumpen la traducción dependiente de poliadenilación citoplasmática, detienen la división celular y presentan estructuras mitóticas anormales (Groisman et al., 2000). En este trabajo que derivó en mi tesis doctoral, hemos demostrado que la activación traduccional localizada en el huso mitótico de mRNAs regulados por CPEB que codifican para proteinas con una conocida función en aspectos estructurales del ciclo celular como la formación del huso mitótico y la segregación cromosómica, es esencial para completar la primera división meiótica y para la correcta segregación cromosómica en oocitos de Xenopus.

interkinesis

microtubule organizing center

microtubule-cytoskeleton

chromosome segregation

centrosomes

spindle assembly

germinal vesicle breakdown

prophase-I arrest

meiotic cell cycle progression

Poly(A) tail lengthening

animal and vegetal hemispheres

xenopus oocytes and development

RNA-binding proteins

translational activation

untranslated regions (UTRs)

translational repression

mRNA Localization

Cytoplasmic polyadenylation

translation

CPEB

vesícula Germinal

profase-I

formación del huso mitótico

progresión del ciclo meiótico

elongamiento de la cola de poli(A)

polo animal y vegetal

oocitos de Xenopus

al RNA

proteínas de unión

regiones no traducidas (UTRs)

activación traduccional

citoesqueleto de microtúbulos

localización de mRNAs

represión traduccional

poliadenilación citoplasmática

traducción

centro organizador de microtúbulos

centrosomas segregación cromosómica

Xkid

TPX2

interquinesis

CPEB

Xkid

TPX2

57