Global ETD Search

251	Mécanisme moléculaire de l'endonucléase Mlh1-Mlh3 dans la voie de réparation des mésappariements de l’ADN et dans les processus de recombinaison en méiose / Molecular basis of the dual role of the Mlh1-Mlh3 endonuclease in MMR and in crossover formation during meiosis Dai, Jingqi 24 September 2019 (has links) La méiose est un processus de ségrégation des chromosomes essentiel pour la gamétogenèse chez tous les organismes qui présentent une reproduction sexuée. Ce mécanisme nécessite des connections entre chromosomes homologues et des structures intermédiaires d’ADN appelées Jonction de Holliday. Ces jonctions sont résolues principalement par complexe MutLγ (Mlh1-Mlh3). Des mutations sur les gènes impliqués en méiose s’accompagnent chez l’homme de problèmes allant de la stérilité à des réarrangements chromosomiques comme la trisomie. Mlh1-Mlh3 joue aussi un rôle dans la voie de réparation des mésappariements de l’ADN (MisMatch Repair - MMR). Notre laboratoire a révélé la première structure cristalline de la région C-terminale du complexe MutLα (Mlh1-Pms1) qui est l’endonucléase majeure de la voie MMR. Mon projet de thèse s’insère dans le cadre de l’étude des différentes fonctions des MutL eucaryotes et plus particulièrement sur le mécanisme moléculaire de MutLγ (Mlh1-Mlh3). Au cours de ma thèse, nous avons déterminé la structure cristalline du domaine C-terminale du complexe Mlh1-Mlh3 qui contient le site d’endonucléase et caractérisé 3 états du site actif. Nous avons montré le rôle de Mlh1 dans le site endonucléase. Nous avons caractérisé la spécificité de ce domaine pour les Jonctions de Holliday et proposé un modèle du site de fixation de l’ADN sur le complexe entier. Ce modèle a permis de proposer un nouveau mutant de séparation de fonction de Mlh1-Mlh3, appelé KERE, qui a été analysé par gel retard et génétique. / Meiosis is key process in sexual reproduction, where chromosomes are segregated. During this process, a parental diploid cell divides into haploid gametes. This mechanism requires connections between homologous chromosomes and intermediate DNA structures called Holliday Junctions. These junctions are mainly resolved by MutLγ (Mlh1-Mlh3) complex. Mutations of genes involved in meiosis are associated with human diseases including sterility and chromosomal rearrangements such as trisomy. Mlh1-Mlh3 plays also a role in DNA mismatch repair (MMR). Our laboratory has characterized the first crystal structure of the C-terminal region of the MutLα complex (Mlh1-Pms1) which is the major endonuclease in MMR. My thesis aims at understanding the molecular mechanism of MutLγ (Mlh1-Mlh3) mainly involved in meiosis and to compare it with Mlh1-Pms1 mainly involved in MMR.We determined the crystal structure of the C-terminal domain of the MutLγ complex which contains the endonuclease site. We characterized the structure of three different states of the active site. We showed how Mlh1 is an integral part of the Mlh3 endonuclease site. We characterized the specificity of this domain for Holliday Junctions and proposed a model of the full-length complex and its DNA binding sites. Finally, we design new separation of function allele of Mlh1-Mlh3, called KERE, which was analyzed by EMSA and genetic experiments. Réparation des mésappariement de l'ADN Meiose Cristallographie Biologie Stucturale Interactions des Protéines Santé Humaine DNA mismatch repair Meiosis Crystallography Structural Biology Protein-Protein Interactions Human Diseases
252	Electron tomography of meiotic spindles in males of the trioecious nematode Auanema rhodensis Unger, Anna 19 June 2023 (has links) The nematode Auanema rhodensis has recently been established as a new model organism. A. rhodensis is characterized by the simultaneous existence of three phenotypical sexes (males, females and hermaphrodites; called trioecy), skewed sex ratios which do not follow Mendel's laws, and variant segregation patterns according to sex and type of gametogenesis. Recently, A. rhodensis has been used to study the possible mechanisms for sex determination in three-sexed species and the variability of basic processes during sexual reproduction including meiotic divisions. During male meiosis, a diploid primary spermatocyte undergoes two consecutive divisions to form four haploid spermatids. Surprisingly, male meiosis in A. rhodensis results in two functional and two nonfunctional spermatids depending on the presence of an X-chromatid. A. rhodensis males exhibit a set of paired autosomes and one single X-chromosome, like males of the wellestablished nematode model organism Caenorhabditis elegans. In contrast to C. elegans, however, the X-chromosome in A. rhodensis divides precociously into its sister chromatids during the first meiotic division followed by a lagging X-chromatid and its uneven distribution during meiosis II. Additionally, the second meiotic divi-sion within this species is characterized by an asymmetric organelle distribution and a spindle structure reminiscent of a monopolar spindle. In this study, serial section electron tomography was used to analyse the ultrastructure of the microtubule skeleton in spermatocytes of A. rhodensis. The analysis of spermiogenesis using electron tomography posed some key advantages compared to standard transmission electron microscopy. First, the microtubule (MT) network could be studied in detail including spindle formation, organization of spindle poles, rearrangement of MTs, and inter-action between MTs and chromosomes. Second, the number and shape of chromosomes could be visualized. And third, the morphology of organelles could be observed at high resolution, and different organelles as well as their distribution pattern could be distinguished and quantified. This study provides highresolution 3D information about male meiosis in A. rhodensis. The results of this thesis confirm the complexity of the male meiotic program and the promi-nent position of the X-chromatid in meiosis II in this organism. Like previous light microscopic studies, electron tomography supports the hypothesis of an X-chromatid-dependent distribution of cellular organelles such as fibrousbody membranousorganelles (FB-MOs) and mitochondria. Furthermore, the formation of an asymmetric spindle could be observed with progressing anaphase II and might be associated with the X-chromatid distribution. Additionally, the analysis of the number of chromosome-associating MTs and their association character gives new insights into possible chromosome segregation mechanisms. Finally, significant differences to the male meiotic program in C. elegans have been identified. For the first time, the MT network in A rhodensis spermatocytes of different division stages has been observed in detail, and several different analyses could be done, including an analysis of the length distribution of MTs in the spindles. Because this ultrastructural analysis is based on fixed samples, live-cell imaging should be performed in the future to gain further information on the chromosome dynamics in this species. / Der Fadenwurm Auanema rhodensis hat sich in den letzten Jahren mehr und mehr zu einem neuen Modellorganismus entwickelt. Typisch für A. rhodensis ist das zeitgleiche Vor-kommen dreier phänotypischer Geschlechter (Männchen, Weibchen und Hermaphroditen; die sogenannte Triözie) und deren zahlenmäßig ungleiches Verhältnis zueinander, welches sich nicht durch Mendelsche Regeln erklären lässt. Ebenfalls auffällig sind nach Geschlecht und Gametogenese (Oogenese oder Spermatogenese) abweichende chromosomale Segregationsmuster. Unlängst hat A. rhodensis zu Erkenntnissen über die Geschlechtsdeterminierung in dreigeschlechtlichen Arten und die Varianz grundlegender Prozesse in der Meiose beigetragen. Während der männlichen Meiose (Spermatogenese) teilt sich eine diploide primäre Vorläuferzelle (primäre Spermatozyte) in zwei aufeinanderfolgenden Teilungen in insgesamt vier haploide Spermatiden. Bei A. rhodensis führt die Spermatogenese ungewöhnlicher-weise zu zwei funktionalen und zwei nicht-funktionalen Spermatiden, wobei die Funktionsfähigkeit vom Auftreten eines X-Chromatids abhängt. Männchen von A. rhodensis besitzen, ähnlich wie im Modellorganismus Caenorhabditis elegans, eine Reihe gepaarter Autosomen sowie ein einzelnes X-Chromosom. Im Gegensatz zu C. elegans teilt sich das ungepaarte X-Chromosom in A. rhodensis vorzeitig schon während der ersten meiotischen Teilung in seine Chromatiden, wodurch es zu einer verzögerten und ungleichen Verteilung des X-Chromatids während der zweiten meiotischen Teilung kommt. Diese zweite meiotische Teilung bei A. rhodensis ist außerdem durch eine asymmetrische Verteilung der Organellen und Mikrotubuli gekennzeichnet, letztere ähneln einer monopolaren Spindel. In dieser Arbeit wurde die Methode der seriellen Elektronentomographie genutzt, um die Ultrastruktur der Mikrotubuli in meiotischen Spindeln in Spermatozyten von A. rhodensis zu untersuchen. Zum einen wurden mittels Elektronentomographie das Netzwerk der Mikrotubuli und die Spindelorganisation, die Struktur der Spindelpole sowie die Interaktion zwischen Mikrotubli und Chromosomen drei-dimensional (3D) analysiert. Zum anderen wurde die Form der Chromosomen und die Morphologie und Verteilung der verschiedenen Organellen quantitativ erfasst. Somit stellt diese Studie hochauflösende 3D-Information über den Ablauf der männlichen Meiose in A. rhodensis zur Verfügung und bestätigt damit die Komplexität der männlichen Meiose und die zentrale Rolle des X-Chromatids während der zweiten meiotischen Teilung in diesem Organismus. Basierend auf vorangegangenen lichtmikroskopischen Experimenten an fixierten Proben unterstützt die Elektronentomographie die Hypothese einer vom X-Chromatid abhängigen Verteilung zellulärer Organellen wie spermienspezifischer FB-MOs oder Mitochondrien während der zweiten meiotischen Teilung. Außerdem konnte die Ausbildung einer asymmetrischen Spindel beobachtet werden, welche ebenfalls mit der ungleichen Verteilung des X-Chromatids in Zusammenhang stehen könnte. Eine zusätzliche Analyse chromosomenassoziierter Mikrotubuli brachte erste Erkenntnisse über mögliche zugrundeliegende Mechanismen der Chromosomensegregation. Die Ergebnisse dieser Arbeit konnten mit ähnlichen Untersuchungen in C. elegans verglichen und Unterschiede herausgearbeitet werden. Zum ersten Mal wurden hier meiotische Spindeln unterschiedlicher Teilungsstadien in 3D untersucht und unterschiedliche quantitative Analysen zur Längenverteilung der Mikrotubuli durchgeführt. Da alle hier gewonnenen Ultrastrukturdaten auf fixierten Proben basieren, sollte eine Betrachtung einer transgenen Wurmlinie mit Fluoreszenzmarkern mittels live-cell imaging auf diese Ultrastrukturanalyse folgen. info:eu-repo/classification/ddc/610 ddc:610
253	Modeling meiotic recombination hotspots using deep learning Takla, Emad 12 1900 (has links) La recombinaison méiotique joue un rôle essentiel dans la ségrégation des chromosomes pendant la méiose et dans la création de nouvelles combinaisons du matériel génétique des espèces. Ses effets cause une déviation du principe de l'assortiment indépendant de Mendel; cependant, les mécanismes moléculaires impliqués restent partiellement incompris jusqu'à aujourd'hui. Il s'agit d'un processus hautement régulé et de nombreuses protéines sont impliquées dans son contrôle, dirigeant la recombinaison méiotique dans des régions génomiques de 1 à 2 kilobases appelées « hotspots ». Au cours des dernières années, l'apprentissage profond a été appliqué avec succès à la classification des séquences génomiques. Dans ce travail, nous appliquons l'apprentissage profond aux séquences d'ADN humain afin de prédire si une région spécifique d'ADN est un hotspot de recombinaison méiotique ou non. Nous avons appliqué des réseaux de neurones convolutifs sur un ensemble de données décrivant les hotspots de quatre individus non-apparentés, atteignant une exactitude de plus de 88 % avec une précision et un rappel supérieur à 90 % pour les meilleurs modèles. Nous explorons l'impact de différentes tailles de séquences d'entrée, les stratégies de séparation des jeux d'entraînement/validation et l’utilité de montrer au modèle les coordonnées génomiques de la séquence d'entrée. Nous avons exploré différentes manières de construire les motifs appris par le réseau et comment ils peuvent être liés aux méthodes classiques de construction de matrices position-poids, et nous avons pu déduire des connaissances biologiques pertinentes découvertes par le réseau. Nous avons également développé un outil pour visualiser les différents modèles afin d'aider à interpréter les différents aspects du modèle. Dans l'ensemble, nos travaux montrent la capacité des méthodes d'apprentissage profond à étudier la recombinaison méiotique à partir de données génomiques. / Meiotic recombination plays a critical role in the proper segregation of chromosomes during meiosis and in forming new combinations of genetic material within sexually-reproducing species. For a long time, its side effects were observed as a deviation from the Mendel’s principle of independent assortment; however, its molecular mechanisms remain only partially understood until today. We know that it is a highly regulated process and that many molecules are involved in this tight control, resulting in directing meiotic recombination into 1-2 kilobase genomic pairs regions called hotspots. During the past few years, deep learning was successfully applied to the classification of genomic sequences. In this work, we apply deep learning to DNA sequences in order to predict if a specific stretch of DNA is a meiotic recombination hotspot or not. We applied convolution neural networks on a dataset describing the hotspots of four unrelated male individuals, achieving an accuracy of over 88% with precision and recall above 90% for the best models. We explored the impact of different input sequence lengths, train/validation split strategies and showing the model the genomic coordinates of the input sequence. We explored different ways to construct the learnt motifs by the network and how they can relate to the classical methods of constructing position-weight-matrices, and we were able to infer relevant biological knowledge uncovered by the network. We also developed a tool for visualizing the different models output in order to help digest the different aspects of the model. Overall, our work shows the ability for deep learning methods to study meiotic recombination from genomic data. Méiose recombinaison méiotique apprentissage profond PRDM9 Extraction des motifs Meiosis Meiotic recombination Deep Learning Motif extraction
254	STUDIES ON ARABIDOPSIS PROTEINS REQUIRED FOR THE ESTABLISHMENT AND RELEASE OF SISTER CHROMATID COHESION BOATENG, KINGSLEY A. 23 July 2007 (has links) No description available. Biology, Cell ARABIDOPSIS MEIOSIS COHESIN SISTER CHROMATID COHESION DSY10 SWI1 SWI1.1 SW1.2 DYAD SYN1 SYN2 SYN3 SYN4 RAD21 SCC1 SCC3 SMC1 SMC3 AESP SEPARASE RAD51 ASY1 MITOSIS
255	Quantitative analysis of spermatogenesis and apoptosis in the common marmoset (Callithrix jacchus) reveals high spermatogonial turnover and spermatogenic efficiency. Brinkworth, Martin H., Aslam, H., Krishnamurthy, H., Weinbauer, G.F., Einspanier, A. 07 June 2009 (has links) No / Spermatogenesis is characterized by the succession in time and space of specific germ cell associations (stages). There can be a single stage (e.g., rodents and some macaques) or more than one stage (e.g., chimpanzee and human) per tubular cross section. We analyzed the organization of the seminiferous epithelium and quantified testicular germ cell production and apoptosis in a New World primate, the common marmoset (Callithrix jacchus). Tubule cross sections contained more than one stage, and the human six-stage system could be applied to marmoset spermatogenesis. Stereological (optical disector) analysis (n = 5) revealed high spermatogenic efficiency during meiosis and no loss of spermatids during spermiogenesis. The conversion of type A to type B spermatogonia was several-fold higher than that reported for other primates. Highest apoptotic rates were found for S-phase cells (20%) and 4C cells (15%) by flow cytometric analysis (n = 6 animals); histological analysis confirmed spermatogonial apoptosis. Haploid germ cell apoptosis was <2%. Marmoset spermatogenesis is very efficient and involves substantial spermatogonial proliferation. The prime determinants of germ cell production in primates appear to be proliferation and survival of spermatogonia rather than the efficiency of meiotic divisions. Based on the organizational similarities, common marmosets could provide a new animal model for experimental studies of human spermatogenesis. Spermatogenesis Apoptosis Testicle Meiosis Cell proliferation Spermatogonia Quantitative analysis Flow cytometry Callithrix jacchus Gametogenesis Male genital system Simioidea Primates Mammalia Vertebrata
256	Genetika a genomika hybridní sterility / Genetics and Genomics of Hybrid Sterility Bhattacharyya, Tanmoy January 2013 (has links) Charles University in Prague Faculty of Science Ph.D. study program: Molecular and Cellular Biology, Genetics and Virology Abstract Genetics and genomics of hybrid sterility Mgr. Tanmoy Bhattacharyya Supervisor: Prof. MUDr. Jiří Forejt, DrSc. Praha 2013 Abstract Male-limited hybrid sterility restricts gene flow between the related species, an important pre- requisite of speciation. The F1 hybrid males of PWD/Ph female (Mus m. musculus subspecies) and C57BL/6J or B6 male (Mus m. domesticus) are azoospermic and sterile (PB6F1), while the hybrids from the reciprocal (B6PF1) cross are semi fertile. A disproportionately large effect of the X chromosome (Chr) on hybrid male sterility is a widespread phenomenon accompanying the origin of new species. In the present study, we mapped two phenotypically distinct hybrid sterility loci Hstx1 and Hstx2 to a common 4.7 Mb region on Chr. X. Analysis of meiotic prophase I of PB6F1 sterile males revealed meiotic block at mid-late pachynema and the TUNEL assay showed apoptosis of arrested spermatocytes. In sterile males over 95% of pachytene spermatocytes showed one or more unsynapsed autosomes visualized by anti SYCP1, HORMAD2 and SYCP3 antibodies. The phosphorylated form of H2AFX histone, normally restricted only to XY chromosome containing sex body decorated unsynapsed...
257	Estudo morfológico dos testículos com ênfase na análise da espermatogênese e ultraestrutura de espécies aquáticas de Heteroptera / Pereira, Luis Lenin Vicente. January 2011 (has links) Orientador: Mary Massumi Itoyama / Banca: Fernanda Cristina Alcantara dos Santos / Banca: Sandra Regina de Carvalho Marchesin / Resumo: No presente trabalho verificamos que os testículos possuem morfologias diferentes podendo ser arredondados, arredondados/espiralados ou alongados/espiralados. Com relação à morfometria das células em prófase I, B. micantulum e R. zela foram as que apresentaram as menores células, G. f. flavus foi a que apresentou maior tamanho e R. c. crassifemur e M. brasiliensis apresentaram tamanho intermediário. A avaliação da espermatogênese nos permitiu concluir que as características observadas são semelhantes às das outras espécies de Heteroptera, descritas na literatura, diferindo apenas com relação à morfologia dos testículos, o número de cromossomos e o sistema cromossômico do sexo. A análise das ultraestruturas observadas durante a espermatogênese de Gelastocoris flavus flavus e Martarega uruguayensis mostraram a presença de várias mitocôndrias pequenas e uniformemente distribuidas pelo citoplasma em células em profase I, de ambas espécies, que foram se unindo formando o complexo mitocondrial, que possui no seu interior as mitocôndrias enoveladas, posteriormente este complexo mitocondrial se divide em duas estruturas denominadas derivados mitocondriais, que se dispõem bilateralmente ao axonema. O axonema dessas espécies possui o padrão de 9+9+2. A formação do acrossomo inicia-se nos primeiros estágios da espermiogênese sendo composto de muitas vesículas acrossomais que se unem formando uma única estrutura, sendo observada regiões e algumas estruturas mais coradas em seu interior. Basicamente o processo de espermiogênese não diferiu entre as duas espécies analisadas / Abstract: In this study, we found different morphologies for testes of the Heteroptera species Belostoma anurum, B. micantulum, Gelastocoris angulatus, G. flavus flavus, Rheumatobates crassifemur crassifemur, Buenoa amnigenus, B. unguis, Martarega brasiliensis, M. membranacea, M. uruguayensis, Rhagovelia tenuipes and R. zela. They can by round, round/spiral and elongated/spiral. The size of prophase I cells also varied, being the smallest ones detected in B. micantulum and R. zela, the largest in G. f. flavus, and the intermediate in R. c. crassifemur and M. brasiliensis. The analyses of spermatogenesis allowed us to conclude that, in the studied species, the features are similar to those of other previously described Heteroptera species, differing only as to the testicular morphology, the chromosome number, and the sex chromosome system. Ultrastructural analysis of the spermatogenesis showed several small mitochondrias evenly distributed throughout the cytoplasm, in cells at prophase I of G. f. flavus and M. uruguayensis. The small mitochondrias joined to form the mitochondrial complex. Later, this mitochondrial complex divided into two structures called mitochondrial derivatives, located bilaterally to the axoneme. The axoneme of these species showed the flagellar pattern 9+9+2. The acrosome started to be formed in the early stages of spermiogenesis, being composed of many acrosome vesicles that join to form a single structure. Some regions within this structure were more strongly stained. Basically the process of spermiogenesis did not differ between the species G. f. flavus and M. uruguayensis / Mestre Citogenética animal. Ultraestrutura (Biologia) Hemiptera. Testiculos - Morfologia. Espermatogênese em animais. Cytogenetics of Heteroptera. eng Testicular lobes. eng Meiosis. eng Spermiogenesis. eng Acrosome. eng Mitochondrial derivative. eng Axoneme. eng Nucleolus. eng
258	Meiosis-specific Regulation of the Anaphase-Promoting Complex / Meisis-spezifische Regulation des Anaphase-Promoting Complex Oelschlägel, Tobias 02 March 2006 (has links) (PDF) Meiosis is a specialized cell cycle, which generates haploid gametes from diploid parental cells. During meiosis one round of cohesion establishment during premeiotic DNA replication mediates two rounds of chromosome segregation. During meiosis I homologous chromosomes separate, whereas sister chromatids segregate during the second meiotic division without an intervening round of DNA replication. Both rounds of chromosome segregation are triggered by an ubiquitin ligase called the Anaphase-Promoting Complex or Cyclosome (APC/C). APC/C-dependent destruction of securin/Pds1 is required to activate separase, a thiol protease that mediates chromosome segregation by cleavage of the cohesin complex. The first meiotic division is preceded by an extended prophase I, during which maternal and paternal chromatids undergo recombination. The persistence of cohesion during premeiotic S- and prophase I is essential for recombination and both meiotic nuclear divisions. In order to prevent premature loss of cohesion, the APC/C has to be inactivated during early meiosis. How the APC/C is kept inactive during premeiotic S- and prophase I was unknown. This question has been addressed by studying the APC/C subunit Mnd2 from the budding yeast Saccharomyces cerevisiae. This work demonstrates that Mnd2 is required for the persistence of cohesion during premeiotic S- and prophase I. Mnd2 prevents premature activation of the APC/C by the meiosis-specific substrate recognition factor Ama1. In cells lacking Mnd2, the APC/C-Ama1 enzyme triggers premature ubiquitin-dependent degradation of Pds1, which leads to premature separation of sister chromatids due to an unrestrained activity of separase. Thus, chromosome segregation during meiosis depends on both inhibition of a meiosis-specific APC/C and timely activation of APC/C- dependent proteolysis. / Die Meiose ist ein spezialisierter Zellzyklus, der zum Ziel hat haploide Gameten aus diploiden Vorläuferzellen zu produzieren. Dafür erfolgen nach der prä-meiotischen DNA Replikation zwei aufeinanderfolgende Kernteilungen. In der ersten meiotischen Teilung erfolgt die Trennung der homologen Chromosomen. In einer zweiten meiotischen Teilung werden dann die Schwesterchromatiden getrennt. Die Trennung der Chromosomen wird durch den Anaphase-Promoting Complex oder Cyclosome (APC/C), einer Ubiquitin Ligase, reguliert. Der APC/C initiiert den Abbau von Securin/Pds1, einem Inhibitor der Thiol-Protease Separase, welche für die Trennung der Chromosomen zum Beginn der Anaphase verantwortlich ist. In einer im Vergleich zur Mitose extrem langen meiotischen Prophase I findet Rekombination zwischen maternalen und paternalen Chromosomen statt. Für diesen Vorgang, sowie für die beiden folgenden meiotischen Teilungen, wird Kohäsion zwischen den Schwesterchromatiden benötigt. Ein frühzeitiger Verlust der Kohäsion führt zur frühzeitigen Trennnung der Schwesterchromatiden, wodurch aneuploide Gameten produziert werden können. Daher muss die Aktivität des APC/C während der meiotischen Prophase I inhibiert werden. Wie der APC/C während der Prophase I inaktiviert wird, war bisher unbekannt. Einsicht in dieses Problem ergab sich aus der Untersuchung der APC/C Untereinheit Mnd2 aus der Bäckerhefe Saccharomyces cerevisiae. Es wird gezeigt, dass Mnd2 für den Verbleib der Kohäsion zwischen den Schwesterchromatiden während der meiotischen S- und Prophase I benötigt wird. Während dieser Phase verhindert Mnd2 die frühzeitige Aktivierung der Meiose-spezifischen Form des APC/C-Ama1. In meiotischen Zellen, die kein Mnd2 besitzen, löst das APC/C-Ama1 Enzym die Ubiquitin-abhängige Zerstörung von Pds1 aus. Dies führt zu einer frühzeitigen Aktivierung von Separase, welches die Trennung der Schwesterchromatiden schon während der meiotischen S- und Prophase I zur Folge hat. Die korrekte Verteilung der Chromosomen hängt daher sowohl von der Inhibierung als auch der Aktivierung des APC/C ab. APC/C Anaphase-Promoting Complex Chromosomen Kohaesion Meiosis Securin Separase APC/C Anaphase-Promoting Complex Chromosomes Cohesion securin separase ddc:570 rvk:WE 2500 Anaphase-Promoting-Complex Chromosom Kohäsion Meiose
259	Spindle organization in three dimensions Müller-Reichert, Thomas 14 December 2006 (has links) (PDF) During cell division, chromosome segregation takes place on bipolar, microtubulebased spindles. Here, C. elegans is used to analyze spindle organization under both mitotic and meiotic conditions. First, the role of SAS-4 in organizing centrosome structure was analyzed. Partial depletion of SAS-4 in early embryos results in structurally defective centrioles. The study of this protein sheds light on the poorly understood role of the centrioles in dictating centrosome size. Second, the ultrastructure of wild-type mitotic spindle components was analyzed by electron tomography. This 3-D analysis reveals morphologically distinct microtubule end morphologies in the mitotic spindle pole. These results have structural implications for models of microtubule interactions with centrosomes Third, spindle assembly was studied in female meiosis. Specifically, the role of the microtubule severing complex katanin in spindle organization was analyzed. Electron tomography reveals fragmentation of spindle microtubules and suggests a novel katanin-dependent mechanism of meiotic spindle assembly. In this model, relatively long microtubules seen near the meiotic chromatin are converted into numerous short fragments, thus increasing the total number of polymers in an acentrosomal environment. Taken together, these results provide novel insights into the three-dimensional organization of microtubules during spindle assembly. / Die Segregation der Chromosomen während der Zellteilung wird duch bipolare, von Microtubuli-aufgebauten Spindlen gewährleistet. In der vorliegenden Arbeit wird C. elegans zur Analyse der Spindelorganisation unter mitotischen und meiotischen Bedingungen herangezogen. Erstens wird die Rolle von SAS-4 in der Organisation von Zentrosomen untersucht. Die partielle Depletierung von SAS-4 in frühen Embryonen führt zu strukturell defekten Zentriolen und wirft somit Licht auf die wenig verstandene Rolle der Zentriolen in der Bestimmung der Zentrosomengröße. Zweitens wird die Ultrastruktur der mitotischen Spindelkomponenten im Wildtyp durch Elektronentomographie untersucht. Diese 3-D-Analyse zeigt, dass im mitotischen Spindlepol unterschiedliche Morphologien der Mikrotubulienden zu finden sind. Diese Ergebnisse haben strukturelle Implikationen für Modelle der Mikrotubuli-Zentrosomen-Interaktionen. Drittens wird der Aufbau der Spindel in der weiblichen Meiose, speziell die Rolle des Mikrotubuli-schneidenden Kataninkomplexes in der Spindelorganisation, untersucht. Die Elektronentomographie zeigt hier eine Fragmentierung der Spindelmikrotubuli. Basierend auf diesem Ergebnis wird ein neues Katanin-abhängiges Modell der Formierung der Meiosespindel entwickelt, in dem relativ lange Microtubuli in Nähe des meiotischen Chromatins in zahlreiche kurze Mikrotubuli “zerschnitten” werden. Dies erhöht die Anzahl der verfügbaren Polymere in dieser azentrosomalen Situation. Zusammenfassend bringen diese Ergebnisse neue Einsichten in die räumliche Organisation der Mikrotubuli während des Spindelaufbaus. cell division microtubules electron tomography mitosis 3D- reconstruction meiosis C.elegans Zellteilung Mikrotubuli Elektronentomographie Mitose 3D-Rekonstruktion Meiose C.elegans ddc:570 rvk:WG 2100 Zellteilung Mikrotubulus Elektronenstrahltomographie Mitose Meiose Caenorhabditis elegans
260	Regulation of the anaphase promoting complex (APC/C) in the mitotic and meiotic cell cycle of Saccharomyces cerevisiae / Regulation des Anaphase promoting Komplex (APC/C) im mitotischen und meiotischen Zellzyklus von Saccharomyces cerevisiae Bolte, Melanie 22 January 2004 (has links) No description available. WUH 000 WUK 000 Mathematics and Natural Science Zellzyklus Anaphase promoting Komplex APC/C Mitose Meiose Ime2 Proteinkinase A 570 Biowissenschaften Biologie cell cycle anaphase promoting complex APC/C mitosis meiosis Ime2 protein kinase A 42.30 Mikrobiologie

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