Spatio-temporal control of cell division in fission yeast by Cdr2 medial cortical nodes / Contrôle spatio-temporel de la division cellulaire par les nœuds corticaux médians organisés par Cdr2 chez la levure S. pombe

Guzmán Vendrell, Mercè

30 September 2014

Le but de ces travaux de thèse est d’apporter une meilleure compréhension des mécanismes de régulation contrôlant la division cellulaire au niveau moléculaire. La division cellulaire est composée de la mitose et la cytocinèse. Les deux processus doivent être coordonnés étroitement afin de garantir la stabilité du génome. La division cellulaire doit aussi s’équilibrer avec la croissance cellulaire pour que les cellules conservent une taille constante au cours des cycles successifs. La levure S. pombe est un organisme modèle simple très utilisé pour des études de cycle cellulaire et de cytocinèse. Dans ce modèle, nous avons focalisé ce travail de thèse sur les nœuds corticaux médians, des structures protéiques complexes, qui ont une fonction double dans l’engagement en mitose et dans le positionnement du plan de division. Les nœuds médians corticaux sont organisés par la kinase SAD Cdr2. Leur localisation et leur fonction sont régulées négativement pour la DYRK kinase Pom1 qui forme des gradients émanant des extrémités de la cellule. Les nœuds corticaux médians contiennent une voie d’inhibition pour Wee1 qui promeut l’entrée en mitose. Cette voie implique la kinase SAD Cdr1, un inhibiteur direct de Wee1 et pourrait coupler l’entrée en mitose à la taille de la cellule par levée progressive de l’inhibition exercée par Pom1 quand les cellules s’allongent. Cdr2 recrute aussi l’anillin Mid1 sur les nœuds corticaux médians ainsi qu’une série de composants additionnels, Blt1, Gef2, Nod1 et Klp8, pour former des précurseurs médians de l’anneau contractile de cytocinèse qui se compactent en un anneau fin pendant la mitose. La localisation médiane des nœuds, contrôlée négativement par les gradients polaires de Pom1 prédéfinit ainsi le plan de division au centre géométrique de la cellule. Dans la première partie de ma thèse, j’ai étudié la protéine des nœuds corticaux médians Blt1 dont la fonction restait énigmatique. Nous avons montré que Blt1 promeut une association robuste de Mid1 avec les nœuds corticaux. Blt1 interagit avec Mid1 via le RhoGEF Gef2 pour stabiliser les nœuds au cortex cellulaire durant les premiers stades de l’assemblage de l’anneau contractile. L’extrémité N-terminale de Blt1 est nécessaire à sa localisation ainsi qu’à sa fonction, tandis que son extrémité C-terminale favorise sa localisation au cortex en interagissant avec des phospholipides. Dans des cellules dans lesquelles ni Mid1 ni Blt1 ne peuvent s’attacher à la membrane, les nœuds se détachent du cortex et génèrent des anneaux contractiles de cytocinèse aberrants. Nous en avons conclu que Blt1 agit comme une protéine d’échafaudage pour les précurseurs de l’anneau contractile, et que Blt1 et Mid1 constituent des ancres membranaires redondantes pour le positionnement du plan de division. Dans une deuxième partie de ma thèse, j’ai étudié comment Cdr2 organise les différents composants des nœuds en voies fonctionnelles qui favorisent l’entrée en mitose et la division médiane. J’ai montré que l’interaction de Cdr2 avec Wee1 et Mid1 dépend du domaine UBA de Cdr2 de manière dépendante de l’activité kinase. En revanche, Cdr1 s’associe avec l’extrémité C-terminale de Cdr2, composée des domaines basique et KA1 d’association aux lipides membranaires. De manière intéressante, Mid1 interagit également avec l’extrémité C-terminale de Cdr2 et pourrait ponter les parties N- et C-terminales de Cdr2, alors que Blt1 s’associe à la région centrale de Cdr2. Nous faisons l’hypothèse que l’association des effecteurs de Cdr2 avec différents domaines de Cdr2 pourraient contraindre Cdr1 et Wee1 spatialement pour promouvoir l'inhibition de Wee1 quand la kinase Cdr2 est active. / The aim of this PhD work is to bring a better understanding of the regulatory mechanism controlling cell division in space and time at the molecular level. Cell division is composed of mitosis and cytokinesis. Both processes need to be perfectly coordinated in order to guarantee genome integrity. Cell division also needs to be properly balanced with cell growth to maintain cell size constant during successive cell cycles. Temporal and spatial regulatory mechanisms ensure the coordination of these events. The fission yeast Schizosaccharomyces pombe is a simple rod-shaped model organism well-known for cell cycle and cytokinesis studies. In this model, we focused the work of this thesis on the medial cortical nodes, complexe protein structures that have a dual role in mitotic commitment and in division plane positioning. Medial cortical nodes are organized by the SAD kinase Cdr2. Their localization and function is negatively regulated by the DYRK kinase Pom1 that forms a gradient emanating from the cell tips. Medial cortical nodes contain an inhibitory pathway for Wee1, promoting mitotic entry. This pathway involves the SAD kinase Cdr1, a direct inhibitor of Wee1 and has been proposed to couple mitotic entry to cell size by progressive alleviation of Pom1 inhibition when cells grow longer. Cdr2 also recruits to medial nodes the anillin Mid1 as well as a series of four additional components, Blt1, Gef2, Nod1 and Klp8, to form medial precursors for the cytokinetic contractile ring that compact into a tight ring during mitosis. Nodes medial localization, negatively controlled by Pom1 gradients, predefines thereby the division plane in the cell geometrical center. In a first part of my thesis, I studied the previously enigmatic cortical node protein Blt1. We showed that Blt1 promotes the robust association of Mid1 with cortical nodes. Blt1 interacts with Mid1 through the RhoGEF Gef2 to stabilize nodes at the cell cortex during the early stages of contractile ring assembly. The Blt1 N terminus is required for localization and function, while the Blt1 C terminus promotes cortical localization by interacting with phospholipids. In cells lacking membrane binding by both Mid1 and Blt1, nodes detach from the cell cortex and generate aberrant cytokinetic rings. We conclude that Blt1 acts as a scaffolding protein for precursors of the cytokinetic ring and that Blt1 and Mid1 provide overlapping membrane anchors for proper division plane positioning. In the second part of my thesis, I studied how Cdr2 scaffolds various nodes components to organize them in functional pathways promoting mitotic commitment and medial division. I showed that Cdr2 interaction with Wee1 and Mid1, depends on Cdr2 UBA domain in a kinase activity dependent manner. In contrast, Cdr1 associates with Cdr2 C-terminus composed of basic and KA-1 lipid-binding domains. Interestingly, Mid1 also interacts with Cdr2 C-terminus and may the bridge N- and C-terminal domains of Cdr2 while Blt1 associates with the central spacer region. We propose that the association of Cdr2 effectors with different Cdr2 domains may constrain Cdr1 and Wee1 spatially to promote Wee1 inhibition upon Cdr2 kinase activation.

Cycle cellulaire

Cdr2

Cdr1

Wee1

Mid1

Cytocinèse

Taille cellulaire

Mitose

S. pombe

Levure à fission

Division cellulaire

Cell cycle

Cdr2

Cdr1

Wee1

Mid1

Cytokinesis

Cell size

Mitosis

S. pombe

Fission yeast

Cell division

Studium optimalizace termoizolačních vlastností tvrdých polyurethanových pěn / Study of optimizing thermoinsulation properties of rigid polyurethane foams

Eliáš, Filip

January 2014

The thesis deals with the processes that occur in the course of the manufacturing of rigid polyurethane-polyisocyanurate (PU-PIR) foams, their properties and technology. It deals above all with principles of foam nucleation and stability. The purpose of understanding these principles is their possible use for improving thermo-insulating properties of the material. The experimental part of the thesis studies the influence of additives and ultrasound on the PU-PIR foam properties. It has been found that low molecular weight compounds with perfluorinated chain leads to decreasing foam cell size and its lower thermal conductivity. The additives mentioned act probably on the surfactants principle by facilitating nucleation and stabilizing growing centres of bubbles. They probably form also part of blowing agents mixture inside the foam cells which cause lowering of thermal conductivity as well. Compounds with similar chemical structure have unique influence on the properties of rigid PU-PIR foams. Further research ought to be focused on cheaper modes of producing perfluorinated compounds.

Ultrastructural and Molecular Analyses of the Unique Features of Cell Division in Mycobacterium Tuberculosis and Mycobacterium Smegmatis

Vijay, Srinivasan

January 2013

The Mycobacterium genus contains major human pathogens, like Mycobacterium tuberculosis and Mycobacterium leprae, which are the causative agents of Tuberculosis and Leprosy, respectively. They have evolved as successful human pathogens by adapting to the adverse conditions prevailing inside the host, which include host immune activation, nutrient depletion, hypoxia, and so on. During such adaptation for the survival and establishment of persistent infection inside the host, the pathogen, like M. tuberculosis, regulates its cell division. It is known that M. tuberculosis enters a state of non-replicating persistence (NRP) inside the host, to establish latent infection, which helps the survival of the pathogen under adverse host conditions such as hypoxia and nutrient depletion. The pathogen can reactivate itself, to come out of the NRP state, and establish active infection at a later stage, when conditions are suitable for its proliferation. The altered physiological state of the latent bacterium makes it tolerant to drugs, which are only effective against proliferating tubercle bacilli. In view of this unique behavioural physiology of tubercle bacilli, it is important to study the process of cell division and how it is regulated in the NRP and actively growing states. The work reported in the thesis is an attempt to understand these aspects of mycobacterial cell division. iii Chapter 1. Introduction: This chapter gives a detailed introduction to bacterial cell division and its regulation in various organisms, like Escherichia coli, Bacillus subtilis, Caulobacter crescentus, and others. In the background of this information, the major studies on mycobacterial cell division and its regulation are presented. Chapter 2. Materials and Methods: This chapter describes in detail all the materials and methods used in the experiments, which are presented in the four data chapters, 3-6. Chapter 3. Ultrastructural Study of the Formation of Septal Partition and Constriction in Mycobacteria and Delineation of its Unique Features: Mycobacteria have triple-layered complex cell wall, playing an important role in its survival under adverse conditions in the host. It is not known how these layers in the mother cell participate during cell division. Therefore, the ultrastructural changes in the different envelope layers of Mycobacterium tuberculosis, Mycobacterium smegmatis, and Mycobacterium xenopi, during the process of septation and septal constriction, were studied, using Transmission and Scanning Electron Microscopy. The unique aspects of mycobacterial septation and constriction were identified and were compared with those of E. coli and Bacillus subtilis septation. Further, based on all these observations, models were proposed for septation in M. tuberculosis and M. smegmatis. Chapter 4. Identification of Asymmetric Septation and Division in Mycobacteria and Its Role in Generating Cell Size Heterogeneity: Bacterial populations are known to harbour phenotypic heterogeneity that helps survival under stress conditions, as this heterogeneity comprises subpopulations that have differential susceptibility to stress conditions. The iv heterogeneity has been known to lead to the requirement for prolonged drug treatment for the elimination of the tolerant subpopulation. Hence, it is important to study the different mechanisms, which operate to generate population heterogeneity. Therefore, in this chapter, studies were carried out to find out whether asymmetric septation and division occur in mycobacteria to generate cell size heterogeneity. Subpopulations of mycobacterial mid-log phase cells of M. tuberculosis, M. smegmatis, and M. xenopi were found to undergo asymmetric division to generate cell size heterogeneity. The asymmetric division and the ultrastructure and growth features of the products of the division were studied. Chapter 5. Study of Mycobacterial Cell Division Using Growth-Synchronised Cells: In this chapter, different stages of cell septation and constriction were studied using growth-synchronised M. smegmatis cells. Phenethyl alcohol (PEA), which has been found to reversibly arrest mycobacterial cells, was used for growth synchronisation. The growth-synchronised mycobacterial cells, which were released from PEA block, were studied at different stages of septation and septal constriction, at the ultrastructural and molecular levels. Chapter 6. Identification of the Stage of Cell Division Arrest in NRP Mycobacteria: The exact stage at which the NRP tubercle bacilli are arrested in cell division is currently unknown. In Wayne’s in vitro model for hypoxia-responsive tubercle bacilli, gradual depletion of oxygen leads to hypoxic stress, inducing the bacilli to enter non-replicating persistence (NRP) state. Using this model, the stage of cell division arrest in M. tuberculosis was characterised at the ultrastructural and molecular levels. Hypoxia-stressed M. smegmatis was used as an experimental system for contrast. The thesis concludes with salient findings, a bibliography, and the list of publications.

Mycobacteria - Cell Biology

Mycobacterium Tuberculosis

Mycobacterium Smegmatics - ftsZ Gene

Mycobacterial Cell Division

Mycobacterial Cell Walls

Septation - Mycobacteria

Mycobacteriuim Smegmatis - Cell Division

Mycobacteria Cell Division Arrest

Cell Size Heterogeneity - Mycobacteria

Mycobacterial Cell Division

Septal Partition - Mycobacteria

ftsE Gene

Bacteriology

SIZE MATTERS: INVESTIGATING THE ROLE OF CELL SIZE IN METABOLIC PROCESSES / STORLEKEN SPELAR ROLL: UNDERSÖKNING AV CELLSTORLEKENS ROLL I METABOLA PROCESSER

Diaa Hussein, Marwan

January 2024

Denna studie undersöker cellstorlekens inverkan på metabola processer, med särskilt fokus på skillnader mellan senescenta och icke-senescenta celler under varierande glukosförhållanden. Genom fluorescerande färgning, avbildning och flödescytometri analyserades nukleär och cellulär morfologi, DNA-innehåll, glukosupptag och cellvolym i cellinjerna HeLa Kyoto och DU-145. Resultaten visar signifikanta morfologiska förändringar i senescenta celler, inklusive ökad nukleär och cellulär storlek, högre aspektförhållanden och minskad nukleär konvexitet. Senescens associeras med minskat glukosupptag och förändrad metabolisk aktivitet, där större celler uppvisar lägre metabola hastigheter. Dessa fynd indikerar att cellulär senescens väsentligt påverkar metaboliska processer och morfologi, oberoende av glukoskoncentration. Forskningen förbättrar vår förståelse av cellulär metabolism och senescens, och erbjuder potentiella implikationer för terapeutiska strategier mot metabola störningar och cancer. Framtida studier bör undersöka de specifika mekanismerna bakom dessa förändringar och deras bredare tillämpningar inom medicinsk vetenskap.

Cell size

Metabolism

Senescence

Nuclear morphology

Glucose uptake

DNA content

Cellstorlek

Metabolism

Senescens

Nukleär morfologi

Glukosupptag

DNA-innehåll

A Global Kinase and Phosphatase Interaction Network in the Budding Yeast Reveals Novel Effectors of the Target of Rapamycin (TOR) Pathway

Sharom, Jeffrey Roslan

31 August 2011

In the budding yeast Saccharomyces cerevisiae, the evolutionarily conserved Target of Rapamycin (TOR) signaling network regulates cell growth in accordance with nutrient and stress conditions. In this work, I present evidence that the TOR complex 1 (TORC1)-interacting proteins Nnk1, Fmp48, Mks1, and Sch9 link TOR to various facets of nitrogen metabolism and mitochondrial function. The Nnk1 kinase controlled nitrogen catabolite repression-sensitive gene expression via Ure2 and Gln3, and physically interacted with the NAD+-linked glutamate dehydrogenase Gdh2 that catalyzes deamination of glutamate to alpha-ketoglutarate and ammonia. In turn, Gdh2 modulated rapamycin sensitivity, was phosphorylated in Nnk1 immune complexes in vitro, and was relocalized to a discrete cytoplasmic focus in response to NNK1 overexpression or respiratory growth. The Fmp48 kinase regulated respiratory function and mitochondrial morphology, while Mks1 linked TORC1 to the mitochondria-to-nucleus retrograde signaling pathway. The Sch9 kinase appeared to act as both an upstream regulator and downstream sensor of mitochondrial function. Loss of Sch9 conferred a respiratory growth defect, a defect in mitochondrial DNA transmission, lower mitochondrial membrane potential, and decreased levels of reactive oxygen species. Conversely, loss of mitochondrial DNA caused loss of Sch9 enrichment at the vacuolar membrane, loss of Sch9 phospho-isoforms, and small cell size suggestive of reduced Sch9 activity. Sch9 also exhibited dynamic relocalization in response to stress, including enrichment at mitochondria under conditions that have previously been shown to induce apoptosis in yeast. Taken together, this work reveals intimate connections between TORC1, nitrogen metabolism, and mitochondrial function, and has implications for the role of TOR in regulating aging, cancer, and other human diseases.

Target of Rapamycin

budding yeast

Saccharomyces cerevisiae

yeast

kinase

phosphatase

protein-protein interactions

TOR

nutrients

growth

rapamycin

signaling

network

metabolism

nitrogen catabolite repression

retrograde response

glutamate dehydrogenase

glutamine

glutamate

alpha-ketoglutarate

cell size

aging

lifespan

mitochondria

uncoupled respiration

petite

reactive oxygen species

free radical theory of aging

apoptosis

cancer

glutaminolysis

TORC1

Nnk1

Fmp48

Mks1

Sch9

Gdh2

Ure2

ribosomal protein S6 kinase

S6K

cell biology

molecular biology

0307

0379

0369

0410

0306

A Global Kinase and Phosphatase Interaction Network in the Budding Yeast Reveals Novel Effectors of the Target of Rapamycin (TOR) Pathway

Sharom, Jeffrey Roslan

31 August 2011

In the budding yeast Saccharomyces cerevisiae, the evolutionarily conserved Target of Rapamycin (TOR) signaling network regulates cell growth in accordance with nutrient and stress conditions. In this work, I present evidence that the TOR complex 1 (TORC1)-interacting proteins Nnk1, Fmp48, Mks1, and Sch9 link TOR to various facets of nitrogen metabolism and mitochondrial function. The Nnk1 kinase controlled nitrogen catabolite repression-sensitive gene expression via Ure2 and Gln3, and physically interacted with the NAD+-linked glutamate dehydrogenase Gdh2 that catalyzes deamination of glutamate to alpha-ketoglutarate and ammonia. In turn, Gdh2 modulated rapamycin sensitivity, was phosphorylated in Nnk1 immune complexes in vitro, and was relocalized to a discrete cytoplasmic focus in response to NNK1 overexpression or respiratory growth. The Fmp48 kinase regulated respiratory function and mitochondrial morphology, while Mks1 linked TORC1 to the mitochondria-to-nucleus retrograde signaling pathway. The Sch9 kinase appeared to act as both an upstream regulator and downstream sensor of mitochondrial function. Loss of Sch9 conferred a respiratory growth defect, a defect in mitochondrial DNA transmission, lower mitochondrial membrane potential, and decreased levels of reactive oxygen species. Conversely, loss of mitochondrial DNA caused loss of Sch9 enrichment at the vacuolar membrane, loss of Sch9 phospho-isoforms, and small cell size suggestive of reduced Sch9 activity. Sch9 also exhibited dynamic relocalization in response to stress, including enrichment at mitochondria under conditions that have previously been shown to induce apoptosis in yeast. Taken together, this work reveals intimate connections between TORC1, nitrogen metabolism, and mitochondrial function, and has implications for the role of TOR in regulating aging, cancer, and other human diseases.

Target of Rapamycin

budding yeast

Saccharomyces cerevisiae

yeast

kinase

phosphatase

protein-protein interactions

TOR

nutrients

growth

rapamycin

signaling

network

metabolism

nitrogen catabolite repression

retrograde response

glutamate dehydrogenase

glutamine

glutamate

alpha-ketoglutarate

cell size

aging

lifespan

mitochondria

uncoupled respiration

petite

reactive oxygen species

free radical theory of aging

apoptosis

cancer

glutaminolysis

TORC1

Nnk1

Fmp48

Mks1

Sch9

Gdh2

Ure2

ribosomal protein S6 kinase

S6K

cell biology

molecular biology

0307

0379

0369

0410

0306