Involvement of Nlrp5 in the Maintenance of Genome Integrity in Murine Oocytes

Velummailum, Russanthy

25 August 2011

Nlrp5, a maternal-effect gene, is required for embryonic progression and female fertility in mice. Previous work indicated an age-related decline in Nlrp5 transcripts in murine oocytes. As maternal age is associated with increased spindle organization defects, studies in this thesis focused on the analysis of meiotic spindle defects in oocytes of Nlrp5-deficient mice. NALP5 protein showed a novel kinetochore-localization pattern, which was disturbed by spindle poisons. Nlrp5-deficient oocytes displayed a higher frequency of spindle abnormalities and chromosomal misalignment. Upon fertilization, these defects translated into increased incidences of multinucleation. As these phenotypes are associated with deficiencies in genome stability, we examined spindle assembly checkpoint (SAC) components. We found that numerous SAC proteins were dysregulated, implying that NALP5 may be critical in sensing oocyte-related SAC defects. We found that Nlrp5-deficient oocytes may have increased DNA damage. Thus, Nlrp5 may be an integral component responsible for preservation of genome integrity in female gametes.

Nlrp5-deficient mice

NALP5

Metaphase II-arrested oocyte

Spindle Assembly Checkpoint (SAC)

DNA damage

0719

0380

0758

Investigating Electrical Properties of Polycrystaline Silver Sulfide from Structure-Property Relation of Ag2S Paramorph

Shaulin, Tahrina Tanjim

24 July 2023

No description available.

Mechanical Engineering

Rôle de la GTPase ARF6 dans la prolifération cellulaire

Bourmoum, Mohamed

10 1900

No description available.

Prolifération

ARF6

ROS

Mitose

Métaphase

Microtubules

Kinétochores

MTOR

CDK1

Proliferation

Mitosis

Metaphase

Kinetochores

Úloha Trim15 a UCHL3 v regulaci buněčného cyklu pomocí ubikvitin signalizace. / The roles of Trim15 and UCHL3 in the ubiquitin-mediated cell cycle regulation.

Jeřábková, Kateřina

January 2019

(ENGLISH) Ubiquitin signaling is a key regulatory mechanism for many important cellular processes such as transcription, differentiation and cell division. Cell division requires duplication of all genetic material during S-phase followed by its precise partitioning between two daughter cells during mitosis. Misregulation of the complex mitotic machinery may lead to aneuploidy and genomic instability, known drivers of tumorigenesis. Indeed, systematic genetic analysis of many cancer tissues over the last decades, indicates the presence of severe chromosome abnormalities in thousands of cancer tissue samples. In this work, I investigated the function of two components of ubiquitin signaling, the deubiquitinating enzyme UCHL3 and the E3 ubiquitin ligase TRIM15. The hypothesized role of E3 ligase TRIM15 in the cell cycle regulation could not be confirmed by our experiments, but I observed an effect on cell adhesion and motility instead. UCHL3 was identified using high-content visual siRNA screen, as a critical factor controlling genome segregation and integrity. Interestingly, it has been previously reported that UCHL3 levels are altered in various cancer types, especially colon cancer. My data demonstrate that UCHL3 drives proper alignment of chromosomes at the metaphase plate by facilitating...

The Role of Dynamic Cdk1 Phosphorylation in Chromosome Segregation in Schizosaccharomyces pombe: A Dissertation

Choi, Sung Hugh

15 February 2010

The proper transmission of genetic materials into progeny cells is crucial for maintenance of genetic integrity in eukaryotes and fundamental for reproduction of organisms. To achieve this goal, chromosomes must be attached to microtubules emanating from opposite poles in a bi-oriented manner at metaphase, and then should be separated equally through proper spindle elongation in anaphase. Failure to do so leads to aneuploidy, which is often associated with cancer. Despite the presence of a safety device called the spindle assembly checkpoint (SAC) to monitor chromosome bi-orientation, mammalian cells frequently possess merotelic kinetochore orientation, in which a single kinetochore binds microtubules emanating from both poles. Merotelically attached kinetochores escape from the surveillance mechanism of the SAC and when cells proceed to anaphase cause lagging chromosomes, which are a leading cause of aneuploidy in mammalian tissue cultured cells. The fission yeast monopolin complex functions in prevention of mal-orientation of kinetochores including merotelic attachments during mitosis. Despite the known importance of Cdk1 activity during mitosis, it has been unclear how oscillations in Cdk1 activity drive the dramatic changes in chromosome behavior and spindle dynamics that occur at the metaphase/anaphase transition. In two separate studies, we show how dynamic Cdk1 phosphorylation regulates chromosome segregation. First, we demonstrate that sequential phosphorylation and dephosphorylation of monopolin by Cdk1 and Cdc14 phosphatase respectively helps ensure the orderly execution of two discrete steps in mitosis, namely sister kinetochore bi-orientation at metaphase and spindle elongation in anaphase. Second, we show that elevated Cdk1 activity is crucial for correction of merotelic kinetochores produced in monopolin and heterochromatin mutants.

Schizosaccharomyces pombe Proteins

Phosphorylation

Chromosome Segregation

Mitotic Spindle Apparatus

CDC2 Protein Kinase

Anaphase

Metaphase

Amino Acids, Peptides, and Proteins

Enzymes and Coenzymes

Fungi

A quantitative analysis of the optical and material properties of metaphase spindles

Biswas, Abin

16 October 2020

Die Metaphasenspindel ist eine selbstorganisierende molekulare Maschine, die die entscheidende Funktion erfüllt, das Genom während der Zellteilung gleichmäßig zu trennen. Spindellänge und -form sind emergente Eigenschaften, die durch komplexe Wechselwirkungsnetzwerke zwischen Molekülen hervorgerufen werden. Obwohl erhebliche Fortschritte beim Verständnis der einzelnen molekularen Akteure erzielt wurden, die ihre Länge und Form beeinflussen, haben wir erst kürzlich damit begonnen, die Zusammenhänge zwischen Spindelmorphologie, Dynamik und Materialeigenschaften zu untersuchen. In dieser Arbeit untersuchte ich zunächst quantitativ die Rolle zweier molekularer Kraftgeneratoren - Kinesin-5 und Dynein - bei der Regulierung der Spindelform von Xenopus-Eiextrakt. Eine Störung ihrer Aktivität veränderte die Spindelmorphologie, ohne die Gesamtmasse der Mikrotubuli zu beeinflussen. Um die Spindelform physikalisch zu stören, wurde ein Optical Stretcher (OS) -Aufbau entwickelt. Obwohl das OS Vesikel in Extrakten verformen könnte, konnte keine Kraft auf Spindeln ausgeübt werden. Die Untersuchung des Brechungsindex der Struktur mittels optischer Beugungstomographie (ODT) ergab, dass es keinen Unterschied zwischen Spindel und Zytoplasma gab. Korrelative Fluoreszenz- und ODT-Bildgebung zeigten, wie sich die Materialeigenschaften innerhalb verschiedener Biomoleküle räumlich unterschieden. Die Gesamttrockenmasse der Spindel skalierte mit der Länge, während die Gesamtdichte konstant blieb. Interessanterweise waren die Spindeln in HeLa-Zellen dichter als das Zytoplasma. Schließlich deckte eine störende Mikrotubulusdichte auf, wie die Gesamttubulinkonzentration die Spindelgröße, die Gesamtmasse und die Materialeigenschaften regulierte. Insgesamt bietet diese Studie eine grundlegende Charakterisierung der physikalischen Eigenschaften der Spindel und hilft dabei, Zusammenhänge zwischen der Biochemie und der Biophysik einer aktiven Form weicher Materie zu beleuchten. / The metaphase spindle is a self-organising molecular machine that performs the critical function of segregating the genome equally during cell division. Spindle length and shape are emergent properties brought about by complex networks of interactions between molecules. Although significant progress has been made in understanding the individual molecular players influencing its length and shape, we have only recently started exploring the links between spindle morphology, dynamics, and material properties. A thorough analysis of spindle material properties is essential if we are to comprehend how such a dynamic structure responds to forces, and maintains its steady-state length and shape. In this work, I first quantitatively investigated the role of two molecular force generators– Kinesin-5 and Dynein in regulating Xenopus egg extract spindle shape. Perturbing their activity altered spindle morphology without impacting total microtubule mass. To physically perturb spindle shape, an Optical Stretcher (OS) setup was developed. Although the OS could deform vesicles in extracts, force could not be exerted on spindles. Investigating the structure’s refractive index using Optical Diffraction Tomography (ODT) revealed that there was no difference between the spindle and cytoplasm. Correlative fluorescence and ODT imaging revealed how material properties varied spatially within different biomolecules. Additionally, spindle mass density and the microtubule density were correlated. The total dry mass of the spindle scaled with length while overall density remained constant. Interestingly, spindles in HeLa cells were denser than the cytoplasm. Finally, perturbing microtubule density uncovered how total tubulin concentration regulated spindle size, overall mass and material properties. Overall, this study provides a fundamental characterisation of the spindle’s physical properties and helps illuminate links between the biochemistry and biophysics of an active form of soft matter.

Metaphasenspindel

Emergenz

Mitose

Xenopus

Quantitative biologie

Optical stretcher

ODT

Metaphase spindle

Emergence

Mitosis

Xenopus

Quantitative biology

Optical stretcher

ODT

570 Biowissenschaften; Biologie

WE 4000

WE 2500

WG 2100

WD 2200

ddc:570