Aurora A kinase function during anaphase

Lioutas, Antonio, 1980-

09 November 2012

Aurora A (AurA) is an important mitotic kinase mainly studied for its involvement in cell cycle progression, centrosome maturation, mitotic spindle pole organization and bipolar spindle formation. It localizes to duplicated centrosomes and spindle microtubules (MTs) during mitosis where it regulates various factors participating in metaphase spindle formation. AurA is degraded late in mitosis suggesting that it might also have a function in anaphase. In this study we focused in understanding AurA function during anaphase in two different experimental systems. First, we kept AurA active in cycled Xenopus egg extracts and found that MTs maintained their mitotic organization longer throughout mitotic exit. We also observed chromosome segregation defects and problematic nuclear envelope formation. These observations indicate that AurA activity needs to be down-regulated for the transition from metaphase back to interphase. To get insights into the role of AurA during metaphase-anaphase transition we initially asked whether its kinase activity is still necessary for the maintenance of the metaphase spindle. We saw that the inhibition of AurA kinase activity in metaphase resulted to a collapse of the established metaphase spindle in HeLa cells. Indicating that AurA activity is necessary for the metaphase spindle maintenance. Then, we looked whether AurA kinase activity is still necessary during anaphase. We inhibited AurA at the onset of anaphase in Hela cells and found that anaphase spindles were smaller. We also observed that the MT structure responsible for anaphase spindle elongation, the central spindle, was defectively assembled and organized. Moreover, in cells where AurA was inhibited segregation of chromosomes was defective. These results indicate that AurA kinase activity is necessary for anaphase spindle elongation, central spindle assembly and organization and chromosome segregation. To understand further how AurA regulates anaphase spindle formation we looked known AurA substrates. We depleted TACC3, a known AurA substrate involved in MT formation earlier in mitosis and observed that TACC3 depletion phenocopied AurA inhibition. This indicates that TACC3 has a function in MT organization and chromosome segregation during anaphase and this function could possibly be regulated by AurA. In this study we have demonstrated that AurA activity is essential for metaphase spindle maintenance. We also found that during anaphase when AurA is either maintained active or inhibited MT organization is greatly affected and chromosome segregation is defective. Suggesting that AurA activity needs to be tightly controlled during anaphase for a correct completion of mitosis. / Aurora A (AurA) es una quinasa mitótica importante que se ha estudiado principalmente en su papel durante la progresión del ciclo celular, la maduración del centrosoma, la organización y la formación del polo y del huso mitótico. Durante la mitosis, AurA se localiza en los centrosomas duplicados y en los microtúbulos (MTs) del huso y se ha observado que regula varios factores que participan en la formación del huso mitótico. AurA se degrada al final de la mitosis indicando que pueda tener una función durante la anafase. En este estudio nos hemos centrado en la comprensión de la función de AurA durante la anafase en dos sistemas experimentales diferentes. En primer lugar, utilizando extractos de huevos de Xenopus hemos mantenido AurA activa durante la transición de metafase a anafase y hemos visto que los MTs del huso mitótico mantienen su organización durante más tiempo. También hemos observado que cuando AurA se mantiene activa existen defectos en la segregación cromosómica y la formación de la membrana nuclear. Esto indica que la actividad de AurA tiene un papel regulador sobre los MTs y la chromatina durante la transición de la metafase a la interfase. Para entender cual es la función de AurA durante la transición de metafase a anafase primero hemos estudiado si la actividad de la quinasa es necesaria para el mantenimiento del huso mitótico. Hemos visto que la inhibición de la actividad quinasa AurA resultó en el colapso del huso durante la metafase en células HeLa. Esto indica que la actividad de AurA es necesaria para el mantenimiento del huso mitótico de metafase. A continuación hemos analizamos si la actividad quinasa de AurA sigue siendo necesaria para la anafase. Para ello hemos inhibido AurA en células Hela al inicio de la anafase. En estas condiciones los husos de la anafase son más pequeños y la estructura de los MTs responsable del alargamiento del huso mitótico durante la anafase, el huso central, se organiza defectuosamente. Además, se encontraron errores durante la segregación de los cromosomas. Estos resultados indican que la actividad quinasa de AurA es necesaria para el alargamiento del huso durante la anafase y la organización y segregación cromosómica. Para entender el mecanismo de la función de AurA durante la anafase hemos estudiado a sustratos de AurA. Al estudiar TACC3 , un sustrato conocido de AurA que participa en la formación de MTs en las fase iniciales de la mitosis hemos encontrado que su eliminación de células HeLa produce el mismo fenotipo que la inhibición de AurA. Esto indica que TACC3 tiene una función en la organización de MT y la segregación de cromosomas durante la anafase y que esta función podría estar regulada por la quinasa AurA. En este estudio hemos demostrado que la actividad quinasa de AurA es esencial para el mantenimiento del huso mitótico. También hemos encontrado que durante la anafase cuando la quinasa AurA se mantiene activa o se inhibe la organización de los MTs del huso mitótico se ve muy afectada y los cromosomas se segregan defectuosamente. Por tanto los resultados de este estudio indican que la actividad quinasa de AurA está estrechamente controlada durante la anafase para el correcto cumplimiento de la mitosis.

Fus mitòtic

Xenopus laevis

Embriologia

Centrosomes

Mitosi

HeLa cells

Xenopus egg extract

Cell cycle

Mitotis

Mitotic spindle

Centrosome

Kinase

Anaphase

Central spindle

Microtubules

Aurora A

TPX2

TACC3

Augmin

576

Διερεύνηση των μηχανισμών με τους οποίους χημικές ενώσεις με αντινεοπλασματικές ιδιότητες προκαλούν γενετικές ανωμαλίες / Investigation of the mechanisms by which antineoplasmatic compounds induce genetic instability

Ευθυμίου, Μαρία

26 August 2010

Οι υπερίτες του αζώτου (nitrogen mustards) συνιστούν μία αποτελεσματική ομάδα φαρμάκων που χρησιμοποιούνται στη χημειοθεραπεία του καρκίνου. Πρόσφατα ευρήματα της ερευνητικής μας ομάδας έδειξαν ότι οι υπερίτες του αζώτου μελφαλάνη (MEL), χλωραμπουκίλη (CAB) και ο δραστικός της μεταβολίτης, το PHE, επιδεικνύουν ισχυρή θραυσματογόνο δράση, αλλά επιπρόσθετα, εμφανίζουν ανευπλοειδογόνο δράση, διαταράσσοντας το χρωμοσωματικό αποχωρισμό μέσω τροποποιήσεων της δομής και λειτουργίας της μιτωτικής συσκευής. Στην παρούσα διατριβή, διερευνήθηκε περαιτέρω ο μηχανισμός της ανευπλοειδογόνου δράσης των παραπάνω δραστικών ενώσεων και πραγματοποιήθηκε σύγκριση της γενετικής δράσης δύο νέων στεροειδών αναλόγων του PHE, τα ανάλογα ΕΑ-92 και ΕΑ-97 με αυτήν των MEL, CAB και PHE. Τα στεροειδή ανάλογα σχεδιάστηκαν με στόχο την αύξηση της εκλεκτικότητας της αντινεοπλασματικής δράσης. Η ικανότητα των MEL, CAB και PHE να προκαλούν φαινόμενα χρωμοσωματικής καθυστέρησης μελετήθηκε σε σύγκριση με τα στεροειδή ανάλογα ΕΑ-92 και ΕΑ-97. Η μελέτη πραγματοποιήθηκε σε ανθρώπινα λεμφοκύτταρα in vitro με τη μέθοδο αναστολής της κυτταροκίνησης (CBMN) σε συνδυασμό με τη μέθοδο FISH και τη χρήση πανκεντρομερικού ανιχνευτή. Επιβεβαιώθηκε η θραυσματογόνος και ανευπλοειδογόνος δράση των ενώσεων MEL, CAB και PHE, ενώ φάνηκε ότι τα στεροειδή ανάλογα ΕΑ-92 και ΕΑ-97 προκαλούν αποκλειστικά χρωμοσωματική θραύση. Το φαινόμενο της χρωμοσωματικής καθυστέρησης μελετήθηκε επίσης με τη μέθοδο CREST στην κυτταρική σειρά ποντικού C2C12. Με τη μέθοδο αυτή, επιβεβαιώθηκε η διπλή γενετική δράση των ενώσεων MEL, CAB και PHE. Τα στεροειδή ανάλογα ΕΑ-92 και ΕΑ-97 εμφανίστηκαν ως οι ηπιότεροι επαγωγείς ΜΝ και προκαλούν κυρίως χρωμοσωματική θραύση, ενώ ήπια ανευπλοειδογόνο δράση παρουσίασε μόνο το ανάλογο ΕΑ-92. Ακολούθως, εξετάσθηκε η ικανότητα των υπό εξέταση χημικών ενώσεων ΕΑ-92 και ΕΑ-97, να επηρεάζουν τη δομή και λειτουργία της μιτωτικής συσκευής σε σχέση με αυτήν των ενώσεων MEL, CAB, PHE, με διπλό ανοσοφθορισμό για τη β- και γ-τουμπουλίνη. Παρατηρήθηκε ότι όλες οι ενώσεις, εκτός από το στεροειδές ΕΑ-97 προκαλούν τη δημιουργία πολυπολικών μεταφάσεων, ενώ όλες οι ενώσεις επάγουν το σχηματισμό μεσοφασικών κυττάρων με ανώμαλο αριθμό κεντροσωμάτων. Όλες οι υπό εξέταση χημικές ενώσεις εμφανίζουν κυτταροτοξικότητα και καθυστέρηση του κυτταρικού κύκλου σε καλλιέργειες ανθρώπινων λεμφοκυττάρων και στα κύτταρα ποντικού C2C12. Στη συνέχεια διερευνήθηκε η ικανότητα των υπό εξέταση ενώσεων να επάγουν την απόπτωση και μελετήθηκε ο ρόλος της απόπτωσης στην εκδήλωση της γενετικής δράσης των ενώσεων MEL, CAB και PHE. Η μελέτη αυτή πραγματοποιήθηκε στα κύτταρα C2C12 με τη μέθοδο της διπλής χρώσης Αννεξίνης V/Ιωδιούχου προπιδίου και το διπλό ανοσοφθορισμό β- και γ-τουμπουλίνης, ανεξάρτητα, σε κύτταρα ποντικού C2C12, παρουσία του γενικού αναστολέα της δράσης των κασπασών, Z-VAD-FMK, αλλά και αναστολέων της δράσης συγκεκριμένων κασπασών. Όλες οι υπό εξέταση ενώσεις επάγουν χαμηλά ποσοστά απόπτωσης. Οι κασπάσες-3, -6 και -8 συμμετέχουν στην επαγόμενη από τη MEL απόπτωση αλλά δεν συμμετέχουν στην απομάκρυνση των κυττάρων με μικροπυρήνες που επάγονται από τη δράση της ίδιας ένωσης. Η απόπτωση αποτελεί μηχανισμό απομάκρυνσης των κυττάρων με μικροπυρήνες και κανονικό κεντροσωματικό αριθμό που επάγονται από τις ενώσεις MEL, CAB και PHE. Αντίθετα, τα κύτταρα με υπεράριθμα κεντροσώματα, που προκύπτουν από τη δράση των παραπάνω ενώσεων δεν απομακρύνονται μέσω απόπτωσης. Για την περαιτέρω διερεύνηση του μηχανισμού με τον οποίο οι δραστικές ενώσεις MEL και CAB εκφράζουν τις ανευπλοειδογόνες ιδιότητες τους, μελετήθηκε η επίδραση τους στην έκφραση των πρωτεϊνών Aurora-B, survivin, Aurora-A και γ-τουμπουλίνη σε κύτταρα ποντικού C2C12, με τη μέθοδο της ανοσοαποτύπωσης των πρωτεϊνών. Παράλληλα μελετήθηκε η ένωση ΕΑ-97, η οποία σύμφωνα με τα ευρήματα μας, εμφάνισε αποκλειστικά θραυσματογόνο δράση. Οι ενώσεις MEL και CAB, εκδηλώνουν τις ανευπλοειδογόνες ιδιότητες τους προκαλώντας μείωση της έκφρασης των πρωτεϊνών Aurora-B και survivin και επάγοντας την αύξηση της έκφρασης της πρωτεΐνης Aurora-A. Επιπρόσθετα, η ένωση MEL, προκαλεί αύξηση της έκφρασης της γ-τουμπουλίνης. Τα ευρήματα αυτά υποδεικνύουν τη συμμετοχή των παραπάνω πρωτεϊνών στην εκδήλωση της ανευπλοειδογόνου δράσης των ενώσεων που μελετήθηκαν. Αντίθετα το στεροειδές ανάλογο ΕΑ-97 που εμφανίζει αποκλειστικά θραυσματογόνο δράση, δεν μεταβάλλει την έκφραση των παραπάνω πρωτεϊνών. / Nitrogen mustards represent an effective class of drugs that are used in chemotherapy. Recent findings of our group have shown that nitrogen mustard analogues, melphalan (MEL), chlorambucil (CAB) and PHE, in addition to their clastogenic activity, they exert their aneugenic potential by affecting chromosome segregation due to modifications of mitotic apparatus. In the present study, we investigated the mechanism by which the above compounds display their aneugenicity in comparison with two new steroidal analogues of PHE, EA-92 and EA-97, which were designed aiming at most effective antineoplasmatic activity. The ability of MEL, CAB and PHE to induce chromosome delay events was studied in comparison with the steroidal analogues EA-92 and EA-97. The mechanism of micronucleation was determined by Cytokinesis Block Micronucleus assay (CBMN assay) in combination with Fluorescence In Situ Hybridization (FISH) using pancentromeric DNA probe. It was confirmed that MEL, CAB and PHE generated MNi by two mechanisms, chromosome breakage and chromosome delay, while EA-92 and EA-97 induced the formation of MN originated exclusively from chromosome breakage events. The ability of the tested compounds to induce chromosome delay was also investigated in C2C12 mouse cells by CREST analysis. The dual genetic activity of MEL, CAB, and PHE was confirmed in a different biological system. The analogues EA-92 and EA-97 appeared as weaker MN inducers and they induced mainly chromosome breakage, while a weak aneugenic activity was observed for EA-92. The ability of the nitrogen mustard analogues to affect the organization of mitotic apparatus was investigated in comparison with MEL, CAB and PHE by double immunofluorescence of β- and γ-tubulin in C2C12 mouse cells. It was observed that all compounds, except EA-97, induced mutlipolar metaphases, and also generated interphase cells with abnormal centrosome number. All compounds displayed increased cytotoxicity and they caused cell cycle delay in human lymphocyte cultures and in C2C12 mouse cells. The ability of the tested compounds to induce apoptosis was studied by Annexin V/PI assay. It was revealed that all compounds induced apoptosis. The effect of apoptosis on the genetic activity of MEL, CAB and PHE was investigated by inhibition of apoptosis in the presence of the inhibitor Z-VAD-FMK and the use of specific inhibitors for caspase -3, -6, -8 and -1. For this reason Annexin V/PI assay and double immunofluorescence of β- and γ-tubulin were performed, independently in C2C12 mouse cells. Caspases -3, -6 and -8 are involved in melphalan-induced apoptosis, but they are not involved in the elimination of cells in the presence of melphalan. Apoptosis is the responsible mechanism for the exclusion of cells with MNi and normal centrosome number that are induced by MEL, CAB and PHE. On the contrary, cells exerting supernumerary centrosomes are not eliminated by apoptosis in the presence of the above compounds. To further elucidate the mechanisms by which MEL and CAB exert their aneugenic potential, we examined the ability of the compounds to alter the expression of proteins having important role in chromosome segregation, such as the proteins Aurora-B, survivin, Aurora-A and γ-tubulin. The analysis was performed by Western blot method in C2C12 mouse cells. We also studied the steroid analogue EA-97, which according to our findings acts as a pure clastogen and do not exert aneugenic potential as opposed to MEL and CAB. MEL and CAB exert their aneugenic potential by the reduction of Aurora-B and survivin expression and by enhancing the expression of Aurora-A. γ-tubulin was upregulated in the presence of MEL. These findings show the implication of these proteins in chromosome delay events induced by MEL and CAB. On the other hand, the analogue EA-97 did not affect the expression of the above proteins.

Υπερίτες του αζώτου

Ανευπλοειδία

Μικροπυρήνες

Aurora κινάσες

Απόπτωση

γ-τουμπουλίνη

616.994 061 072 4

Nitrogen mustards

Aneuploidy

Supernumerary centrosomes

Micronucleus

Aurora kinases

Apoptosis

Survivin

γ-tubulin

Estudos estruturais e funcionais das proteínas cinases humanas Nek1 e Nek6 / Structural and functional studies of Nek1 Nek6 protein kinases

Meirelles, Gabriela Vaz

03 April 2011

Orientador: Jorg Kobarg / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-18T17:04:45Z (GMT). No. of bitstreams: 1 Meirelles_GabrielaVaz_D.pdf: 11269390 bytes, checksum: bfd22a079ffc68a78b96b3e50dd60b1c (MD5) Previous issue date: 2011 / Resumo: A proteína NIMA foi identificada e caracterizada funcionalmente em Aspergillus nidulans como sendo uma serina/treonina cinase critica para a progressão do ciclo celular. As Neks (NIMA-related kinases) constituem uma família de cinases composta por 11 membros em mamíferos, que compartilham 40-45% de identidade com a proteína NIMA no domínio catalítico N-terminal. As Neks estão associadas a funções do ciclo celular e diversas patologias, o que as torna potenciais alvos quimioterápicos. Mutações no gene da Nek1 levam ao desenvolvimento da doença renal policistica e ao aparecimento de diversos efeitos pleiotrópicos, sugerindo sua participação em vias reguladoras de vários processos celulares. A Nek6, por sua vez, e ativada durante a mitose, e a super-expressão de mutantes inativos ou a sua depleção por RNAi produz células exibindo defeitos no fuso, anormalidades nucleares, parada na metáfase e apoptose. A Nek6 humana foi recentemente associada a carcinogênese, mas, assim como para a maioria das Neks, sua estrutura molecular, parceiros de interação e vias de sinalização permanecem ainda desconhecidos. Nesse trabalho, introduzimos a hNek6 como uma hub no interactoma humano. Uma extensa comparação de bancos de dados baseada em analises de conectividade mostrou que o quinoma humano e enriquecido em hubs. Nossas redes de interação incluem um amplo espectro de novos parceiros de interação para a hNek6 identificados em screenings de duplo - hibrido em levedura, classificados em 18 categorias funcionais. Alguns novos parceiros de interação da hNek6 são também possíveis substratos e, ainda, colocalizam com a hNek6 e ?-tubulina em células humanas, apontando para uma possível interação centrossomal. Os diversos parceiros de interação conectam a hNek6 a novas vias, como a sinalização de Notch e a regulação do citoesqueleto de actina, ou fornecem novas pistas de como a hNek6 poderia regular vias previamente propostas, como ciclo celular, reparo de DNA e sinalização do NF-?B. Alem disso, obtivemos o primeiro modelo estrutural de baixa resolução para a hNek6 a partir de SAXS. Analises estruturais revelaram que a hNek6 e um monômero em solução, apresentando uma conformação predominantemente globular, mas levemente alongada. Particularmente, a curta região N-terminal desordenada da hNek6 e importante para mediar as interações com seus parceiros. No caso da hNek1, observamos que ela interage com Fez1 e Clasp2 através de seus motivos coiled-coil, e colocaliza com essas proteínas em uma região candidata ao centrossomo / Abstract: NIMA was identified and functionally characterized in Aspergillus nidulans as a critical Ser/Thr kinase for cell cycle progression. The mammalian Neks (NIMA-related kinases) represent an evolutionarily conserved family of 11 serine/threonine kinases that share 40-45% identity with NIMA N-terminal domain. Neks are associated to cell cyclerelated functions and diverse pathologies, which highlight them as potential chemotherapeutic targets. Nek1 gene mutations lead to the development of polycystic kidney disease and the emergence of several pleiotropic effects, suggesting its involvement in pathways regulating various cellular processes. Nek6, in turn, is activated during mitosis, and overexpression of inactive mutants or its depletion by iRNA produces cells exhibiting mitotic spindle defects, nuclear abnormalities, metaphase arrest and apoptosis. Human Nek6 was recently found to be linked to carcinogenesis, but as for the majority of Neks, the molecular structure, interacting partners and signaling pathways remain elusive. Here we introduce hNek6 as a hub kinase in the human interactome. We performed a broad databank comparison based on degree distribution analysis and found that the human kinome is enriched in hubs. Our networks include a large set of novel hNek6 interactors identified in our yeast two-hybrid screens, classified into 18 functional categories. Some novel interactors are also putative substrates and colocalized with hNek6 and ?-tubulin in human cells, pointing to a possible centrosomal interaction. The interacting proteins link hNek6 to novel pathways, e.g. Notch signaling and actin cytoskeleton regulation, or give new insights on how hNek6 may regulate previously proposed pathways such as cell cycle, DNA repair and NF-?B signalings. Furthermore, we obtained the first low-resolution structural model of hNek6 by SAXS. Structural analysis revealed that hNek6 is a monomer in solution with a mostly globular, though slightly elongated conformation. Notably, we found that hNek6 unfolded short N-terminal region is important to mediate the interactions with its partners. In the case of hNek1, we found that it interacts with Fez1 and Clasp2 through coiled-coil motifs and colocalizes with these proteins in a candidate centrosomal region / Doutorado / Bioquimica / Doutor em Biologia Funcional e Molecular

Proteina quinases

Espalhamento a baixo ângulo

Proteínas hub

Redes de interações

Sinalização celular

Centrossomos

Protein kinases

Small angle scattering

Hub proteins

Protein networks

Signal transdution

Centrosomes

Membrane Invaginations Reveal Cortical Sites that Pull on Mitotic Spindles in One-Cell C. elegans Embryos

Redemann, Stefanie, Pecreaux, Jacques, Goehring, Nathan W., Khairy, Khaled, Stelzer, Ernst H. K., Hyman, Anthony A., Howard, Jonathon

09 December 2015

Asymmetric positioning of the mitotic spindle in C. elegans embryos is mediated by force-generating complexes that are anchored at the plasma membrane and that pull on microtubules growing out from the spindle poles. Although asymmetric distribution of the force generators is thought to underlie asymmetric positioning of the spindle, the number and location of the force generators has not been well defined. In particular, it has not been possible to visualize individual force generating events at the cortex. We discovered that perturbation of the acto-myosin cortex leads to the formation of long membrane invaginations that are pulled from the plasma membrane toward the spindle poles. Several lines of evidence show that the invaginations, which also occur in unperturbed embryos though at lower frequency, are pulled by the same force generators responsible for spindle positioning. Thus, the invaginations serve as a tool to localize the sites of force generation at the cortex and allow us to estimate a lower limit on the number of cortical force generators within the cell.

info:eu-repo/classification/ddc/610

ddc:610

Investigation of supernumerary centrosomes accumulation and Caspase-2 activation in human cell lines

Dzhilyanova, Iva Georgieva

28 February 2022

Centrosomes are microtubule-based organelles composed of two centrioles and peri-centriolar material, involved in the formation and organization of the mitotic spindle, serving as microtubule-organizing center and involved in ciliogenesis. Supernumerary centrosomes are detrimental for cell physiology and activate the PIDDosome, a multi-protein complex that serves as a platform for the activation of Caspase-2, composed of: PIDD1, RAIDD and Caspase-2 itself. Caspase-2’s preferred cleavage site based on peptide screening is VDVAD, however Caspase-2, when activated via the PIDDosome, cleaves its bona fide substrate MDM2 (negative p53 regulator) in the FDVPD sequence. Here, I present evidence for VDVADase activity in apoptotic cells lacking Caspase-2, which suggests that this cleavage site is not Caspase-2 specific when the Caspase-2 activation occurs via the PIDDosome. In order to investigate if the mode of activation of Caspase-2 determines its substrate specificities I performed a Caspase-2 rescue experiment and introduced several mutations affecting the Caspase-2 autoproteolytic-processing. Furthermore, I present evidence that exogenous Caspase-2 is able to form the PIDDosome and cleaves MDM2 but when key autoproteolytic sites are mutated no MDM2 cleavage is detectable. Supernumerary centrosomes also accumulate upon overexpression of PLK4 (a kinase regulator of the centriole duplication). Immunofluorescence images of cells overexpressing PLK4 were taken following the centrioles quantification over time. Consequently, a large amount of image data was accumulated, which necessitated the development of a semi-automated pipeline for centrioles counting. This pipeline was generated using the image processing and analysis tool ImageJ and the deep learning segmentation tool MitoS together with the pretrained MitoSegNet model, which was finetuned to count centrioles stained against different centrosomal epitopes, namely Centrin 1, γ-Tubulin and ANKRD26. This semi-automated method of centrioles quantification is easy to use, reproducible and faster than manual quantification. Using this pipeline to quantify centrioles in p53, SCLT1 or ANKRD26 lacking cells we demonstrate accumulation of supernumerary centrosomes in these cells similar to parental cells. / I centrosomi sono organelli cellulari a base di microtubuli, composti da due centrioli e dal materiale pericentriolare che li circonda. I centrosomi sono coinvolti nell'organizzazione dei microtubuli, nella formazione del fuso mitotico e nella ciliogenesi. I centrosomi soprannumerari sono dannosi per la fisiologia cellulare e attivano il PIDDosoma, un complesso multiproteico, composto da PIDD1, RAIDD e Caspasi-2, che funge da piattaforma per l'attivazione della caspasi stessa. Il sito preferenziale di proteolisi di Caspasi-2 è stato individuato tramite screening peptidico nella sequenza VDVAD. Nonostante ciò, quando attivata tramite il PIDDosoma, Caspasi-2 scinde il suo substrato di elezione MDM2 (regolatore negativo di p53) a livello della sequenza FDVPD. In questa tesi presento evidenze di attività VDVAD-asica in cellule apoptotiche prive di Caspasi-2, suggerendo che questo sito di taglio non sia specifico di Caspasi-2 quando la sua attivazione avviene tramite il PIDDosoma. Al fine di indagare se la modalità di attivazione della proteasi determina le sue specificità di substrato, ho eseguito esperimenti di complementazione di Caspasi-2 facendo uso di diversi mutanti che influenzano il suo processamento autoproteolitico. Inoltre, presento prove che Caspasi-2 esogena è in grado di assemblare il PIDDosoma e proteolizzare MDM2 ma quando i suoi siti chiave di autoproteolisi sono mutati non è rilevabile il taglio di MDM2. I centrosomi soprannumerari si accumulano anche in caso di sovraespressione di PLK4 (chinasi regolatrice della duplicazione dei centrioli). Immagini di immunofluorescenza di cellule che sovraesprimono PLK4 sono state acquisite seguendo la cinetica di accumulo dei centrioli nel tempo. Di conseguenza, l’ingente mole di dati generati ha reso necessario lo sviluppo di una procedura semiautomatica per la conta dei centrioli. Questa pipeline è stata generata utilizzando il programma di elaborazione e analisi di immagini ImageJ e il programma di segmentazione basato su deep learning MitoS, insieme al modello MitoSegNet, che è stato affinato per la conta dei centrioli evidenziati tramite immunofluorescenza diretta contro diversi epitopi centrosomiali, ossia: Centrin 1, γ-Tubulina e ANKRD26. Questo metodo semiautomatico di quantificazione dei centrioli è facile da usare, riproducibile e più veloce della quantificazione manuale. Utilizzando questa procedura per quantificare i centrioli nelle cellule prive di p53, SCLT1 o ANKRD26, dimostriamo che l'accumulo di centrosomi soprannumerari in queste cellule è simile a quello riscontrato nelle cellule parentali.

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