Caractérisation de la sous-unité bêta du translocon chez la levure Schizosaccharomyces pombe

Leroux, Alexandre

12 1900

La sécrétion des protéines est un processus essentiel à la vie. Chez les eucaryotes, les protéines sécrétées transitent dans le réticulum endoplasmique par le pore de translocation. Le translocon est composé de trois sous-unités fondamentales nommées Sec61α, β et γ chez les mammifères, ou Sec61p, Sbh1p et Sss1p chez les levures. Tandis que le rôle des sous-unités α et γ est bien connu, celui de la sous-unité β demeure énigmatique. Plusieurs phénotypes distincts sont associés à cette protéine dans différents organismes, mais le haut niveau de conservation de séquence suggère plutôt une fonction universelle conservée. Récemment, Feng et al. (2007) ont montré que le domaine transmembranaire (TMD) de Sbh1p était suffisant pour complémenter plusieurs phénotypes associés à la délétion du gène chez Saccharomyces cerevisiae, suggérant un rôle important de cette région. L’objectif de mon projet de recherche consiste à étudier la fonction biologique de la sous-unité β du translocon et de son TMD chez Schizosaccharomyces pombe. Dans cette levure, j’ai découvert que le gène sbh1+ n’était pas essentiel à la viabilité à 30oC, mais qu’il était requis pour la croissance à basse température. La délétion de sbh1+ entraîne une sensibilité aux stress de la paroi cellulaire et une diminution de la sécrétion des protéines à 23oC. La surexpression de Sbh1p diminue elle aussi la sécrétion des protéines et altère la morphologie cellulaire. Ces phénotypes sont distincts de ceux observés chez S. cerevisiae, où la délétion des deux paralogues de Sec61β entraîne une sensibilité à haute température plutôt qu’à basse température. Malgré cela, les homologues de Sec61β de S. pombe et de S. cerevisiae sont tout deux capables de complémenter la thermosensibilité respective de chaque levure. La complémentation est possible même avec l’homologue humain de Sec61β, indiquant la conservation d’une fonction de Sec61β de la levure à l’homme. Remarquablement, le TMD de Sec61β de S. pombe, de S. cerevisiae et de l’humain sont suffisants pour complémenter la délétion génomique autant chez la levure à fission que chez la levure à bourgeons. Globalement, ces observations indiquent que le TMD de Sec61β exerce une fonction cellulaire conservée à travers les espèces. / Protein secretion is an essential biological process. In eukaryotes, secreted proteins transit into the endoplasmic reticulum through the translocon pore. The core of the translocation channel is composed of three subunits called Sec61α, β and γ in mammals, or Sec61p, Sbh1p and Sss1p in yeasts. While the role of the α and γ subunit is well understood, the function of the β subunit remains ill-defined. Although numerous species-specific phenotypes have been reported for this protein, the striking sequence conservation among species argue in favour of a universal role. Recently, Feng et al. (2007) reported the surprising finding that the transmembrane domain (TMD) of Sbh1p was sufficient to complement different functions of the entire protein in Saccharomyces cerevisiae, suggesting an important role for this region. The aim of my project was to explore the biological function of the translocon β subunit and its TMD in Schizosaccharomyces pombe. In this yeast, we found that the sbh1+ gene is unessential for viability at 30oC, but is required for growth at low temperature. Knockout of sbh1+ results in sensitivity to cell-wall stress and reduced protein secretion at 23oC. Overexpression of Sbh1p also diminishes protein secretion and results in an elongated cell shape. These phenotypes contrast with those observed S. cerevisiae, as deletion of both Sec61β paralogs in this yeast results in heat sensitivity instead of cold sensitivity. Nevertheless, Sec61β homologs from both S. pombe and S. cerevisiae complement the respective temperature sensitivity of either yeast. This functional complementation can also be accomplished by the human homolog of the translocon β subunit, indicating that a fundamental function of Sec61β is conserved from yeast to human. Remarkably, the TMD of Sec61β homologs from S. pombe, S. cerevisiae and human are sufficient to complement the gene knockout in both fission and budding yeasts. Together, these observations indicate that the TMD of Sec61β exerts a cellular function that is conserved across species.

Sec61 bêta

Sec61 beta

Sbh1p

Translocon

Domaine transmembranaire

Transmembrane domain

Levure

Yeast

Complémentation

Complementation

Sécrétion

Secretion

Schizosaccharomyces pombe

Saccharomyces cerevisiae

sbh1

Le vieillissement chronologique de Schizosaccharomyces pombe : Implication des voies de détection du glucose

Roux, Antoine E.

04 1900

La première augmentation de la longévité en laboratoire fût observée à la suite d’une intervention nutritionnelle consistant en une réduction de l’apport alimentaire chez le rat. Plus tard, ce phénomène a été reproduit dans de très nombreuses espèces et référé en tant que restriction calorique. Le développement des techniques de biologie moléculaire moderne a permis de montrer dans des organismes modèles simples que cette flexibilité du processus de vieillissement était régulée par des facteurs génétiques. De fait, plusieurs mécanismes cellulaires ont alors pu être identifiés comme responsables de ce contrôle du vieillissement. Ces voies de régulation ont révélées être conservées entre les espèces, depuis les levures jusqu’aux organismes multicellulaires tels que le nématode, la mouche ou la souris, suggérant l’existence d’un programme universel de vieillissement dans le vivant. La levure s’est avéré à plusieurs reprises être un modèle puissant et fiable pour la découverte de gènes impliqués dans ce phénomène. Mon étude a consisté au développement d’un nouveau modèle unicellulaire d’étude du vieillissement à travers l’espèce Schizosaccharomyces pombe appelée aussi levure à fission. La première étape de mon travail a montré que les voies de détection des nutriments gouvernées par la sérine/thréonine protéine kinase A (Pka1) et la sérine/thréonine kinase Sck2 contrôlent le vieillissement chronologique de ces cellules comme il était connu dans la levure Saccharomyces cerevisiae. Ceci permit de valider l’utilisation de la levure à fission pour l’étude du vieillissement. Ensuite, nous avons analysé plus en détail l’effet pro-vieillissement du glucose en étudiant le rôle de sa détection par le récepteur membranaire Git3 couplé à la protéine G (Gpa2) en amont de la kinase Pka1. La perte du signal du glucose par la délétion de Git3 imite partiellement l’effet d’augmentation de longévité obtenu par baisse de la concentration en glucose dans le milieu. De plus, l’effet néfaste du signal du glucose est maintenu en absence de tout métabolisme du glucose suite à la mutation des hexokinases, premières enzymes de la glycolyse. L’ensemble de ces résultats suggèrent que la signalisation du glucose est prédominante sur son métabolisme pour son effet pro-vieillissement. D’autre part, à la fois la suppression de cette signalisation et la baisse de niveau de glucose disponible allongent la durée de vie en corrélation avec une augmentation de la résistance au stress, une hausse d’activité mitochondriale et une baisse de production de radicaux libres. Finalement, le criblage d’une banque de surexpression d’ADNc a permis d’identifier plusieurs gènes candidats responsables de ces effets en aval de la voie de signalisation Git3/PKA. La recherche sur les mécanismes moléculaires du vieillissement propose une nouvelle approche, un nouvel angle de vue, pour la compréhension des fonctions cellulaires et promet d’apporter de précieuses clefs pour mieux comprendre certaines maladies. En effet, le vieillissement est la première cause d’apparition de nombreuses affections comme les cancers, les maladies cardiovasculaires et métaboliques ou les maladies neurodégénératives tels que les syndromes d’Alzheimer et de Parkinson. / The first increase in life span due to man’s intervention was obtained with rats subjected to a diet reduced in calorie intake. Later, this phenomenon was repeated with many other species and referred as diet restriction or calorie restriction. The development of modern Molecular Biology approaches and the use of simple model organisms demonstrated that the rate of aging was regulated by genetic traits. Indeed, several cellular mechanisms were identified as responsible for the control of aging. These regulatory pathways appear to be conserved throughout species, from yeast to multicellular organisms like nematode, fly and mice, thus suggesting the existence of a universal program of aging. Yeast proved several times to be a powerful and reliable model for discovering genes involved in the regulation of aging. My study consisted in developing Schizosaccharomyces pombe (also called fission yeast) as a new unicellular model to study aging. The first step of my work was to show that pathways of nutrient detection through kinases involving Pka1 and Sck2 control chronological aging in S. pombe, as it was previously demonstrated in Saccharomyces cerevisiae. This first work validated the use of fission yeast for the study of aging. Subsequently, we analysed in more detail the pro-aging effect of glucose focusing on the role of its signalling through the G-protein Gpa2-coupled membrane receptor Git3, which acts upstream of Pka1. The loss of the glucose signal due to deletion of Git3 mimics partially the effect of increasing longevity by reducing glucose in the medium. Moreover, detrimental effects of glucose signal are maintained in absence of sugar metabolism following loss of hexokinases, the first enzymes of glycolysis. Together, these results suggest that the pro-aging effects of glucose signalling are predominant over those due to metabolism of this sugar. Moreover, both obliteration of this signalling pathway and decrease of glucose availability extend life span, and correlate with an increase in stress resistance, in mitochondrial activity and a lower production of free radicals. Finally, screening a cDNA-overexpression library allowed us to identify several genes candidates responsible for the effects on longevity downstream of Git3/Pka1. Research in the molecular mechanisms of aging propose holds the promise to bring precious clues as to this mysterious processes affecting all living creatures, and paves the way to unravel the underlying causes of many human diseases. Indeed, aging is the first cause of numerous late-onset pathologies including cancers, cardiovascular diseases or neurodegenerative diseases like Alzheimer and Parkinson syndromes.

vieillissement

longévité

levure

schizosaccharomyces pombe

phase stationnaire

pka

sck2

aging

longevity

life span

yeast

stationary phase

Do BHA and BHT Induce Morphological Changes and DNA Double-Strand Breaks in Schizosaccharomyces pombe?

Tran, Amy V

01 January 2013

Butylated Hydroxyanisole, BHA, and Butylated Hydroxytoluene, BHT, are commonly used as preservatives for our food as well as additives in many products such as cosmetics, petroleum, and medicine. Although their use has been approved by the Food and Drug Administration (FDA), there have been controversies and debates on whether these phenol derivatives or antioxidants are safe to use. Their accumulative toxicology and side effects need to be thoroughly investigated as we continue to consume them on a daily basis. Data obtained by genomic analysis in Tang lab suggested the involvement of DNA damage checkpoint/repair pathways in the response network to these phenol stress factors. The aims of this thesis are to examine the morphological changes and potential DNA damage induced by exposing cells to BHA and BHT using fission yeast Schizosaccharomyces pombe as a model organism. Fluorescence microscopy was used to assess DNA double-strain breaks (DSBs) by monitoring the nuclear foci formation of Rad22, a DNA repair protein, in the presence of BHA and BHT. Changes in cell morphology were also studied under microscope. Preliminary data showed that cells treated with BHA and BHT exhibited morphological changes. In addition, for the first time in S. pombe cells, Rad22 foci in the nucleus of BHA and BHT treated cells were observed. Further investigation is needed to optimal the experimental condition to continue the study. These results will not only help us to better understand the effect of these phenol derivatives in the cells, but can also establish an experimental system for future studies on the interaction of the cells with stress factors and therapeutic drugs for human-related diseases such as cancer.

BHA

BHT

DNA Double-Strand Breaks

Morphological Changes

Schizosaccharomyces pombe

Cell and Developmental Biology

Genetics and Genomics

Life Sciences

Medicine and Health Sciences

Antisense RNA-mediated gene silencing in fission yeast

Raponi, Mitch, Biochemistry & Molecular Genetics, UNSW

January 2001

The major aims of this thesis were to investigate the influence of i) antisense gene location relative to the target gene locus (?????location effect?????), ii) double-stranded RNA (dsRNA) formation, and iii) over-expression of host-encoded proteins on antisense RNA-mediated gene regulation. To test the location effect hypothesis, strains were generated which contained the target lacZ gene at a fixed location and the antisense lacZ gene at various genomic locations including all arms of the three fission yeast chomosomes and in close proximity to the target gene locus. A long inverse-PCR protocol was developed to rapidly identify the precise site of antisense gene integration in the fission yeast transformants. No significant difference in lacZ suppression was observed when the antisense gene was integrated in close proximity to the target gene locus, compared with other genomic locations, indicating that target and antisense gene co-localisation is not a critical factor for efficient antisense RNA-mediated gene suppression in vivo. Instead, increased lacZ down-regulation correlated with an increase in the steady-state level of antisense RNA, which was dependent on genomic position effects and transgene copy number. In contrast, convergent transcription of an overlapping antisense lacZ gene was found to be very effective at inhibiting lacZ gene expression. DsRNA was also found to be a central component of antisense RNA-mediated gene silencing in fission yeast. It was shown that gene suppression could be enhanced by increasing the intracellular concentration of non-coding lacZ RNA, while expression of a lacZ panhandle RNA also inhibited beta-galactosidase activity. In addition, over-expression of the ATP-dependent RNA-helicase, ded1, was found to specifically enhance antisense RNA-mediated gene silencing. Through a unique overexpression screen, four novel factors were identified which specifically enhanced antisense RNA-mediated gene silencing by up to an additional 50%. The products of these antisense enhancing sequences (aes factors), all have natural associations with nucleic acids which is consistent with other proteins which have previously been identified to be involved in posttranscriptional gene silencing.

fission yeast

Schizosaccharomyces pombe

antisense RNA

dsRNA

gene silencing

lacZ

antisense enhancing sequence

Plant gene silencing

Yeast fungi

Antisense nucleic acids

RNA Silencing Pathways in <em>Schizosaccharomyces pombe</em> and <em>Drosophila melanogaster</em>: A Dissertation

Sigova, Alla A.

03 November 2006

RNA silencing is an evolutionary conserved sequence-specific mechanism of regulation of gene expression. RNA interference (RNAi), a type of RNA silencing in animals, is based on recognition and endonucleolytic cleavage of target mRNA complimentary in sequence to 21-nucleotide (nt) small RNA guides, called small interfering RNAs (siRNAs). Another class of 21-nt small RNAs, called micro RNAs (miRNAs), is endogenously encoded in eukaryotic genomes. Both production of siRNAs from long double-stranded RNA (dsRNA) and biogenesis of miRNAs from hairpin structures are governed by the ribonuclease III enzyme Dicer. Although produced as duplex molecules, siRNAs and miRNAs are assembled into effector complex, called the RNA-induced silencing complex (RISC), as single-strands. A member of the Argonaute family of small RNA-binding proteins lies at the core of all known RNA silencing effector complexes. Plants and animals contain multiple Argonaute paralogs. In addition to endonucleolytic cleavage, Argonaute proteins can direct translational repression/destabilization of mRNA or transcriptional silencing of DNA sequences by the siRNAdirected production of silent heterochromatin. The Schizosaccharomyces pombe genome encodes only one of each of the three major classes of proteins implicated in RNA silencing: Dicer (Dcr1), RNA-dependent RNA polymerase (RdRP; Rdp1), and Argonaute (Ago1). These three proteins are required for silencing at centromeres and for the initiation of transcriptionally silent heterochromatin at the mating-type locus. That only one Dicer, RdRP and Argonaute is expressed in S. pombe might reflect the extreme specialization of RNA silencing pathways regulating targets only at the transcriptional level in this organism. We decided to test if classical RNAi can be induced in S. pombe. We introduced a dsRNA hairpin corresponding to a GFP transgene. GFP silencing triggered by dsRNA reflected a change in the steady-state concentration of GFP mRNA, but not in the rate of GFP transcription. RNAi in S. pombe required dcr1, rdp1, and ago1, but did not require chp1, tas3, or swi6, genes required for transcriptional silencing. We concluded that the RNAi machinery in S. pombecould direct both transcriptional and posttranscriptional silencing using a single Dicer, RdRP, and Argonaute protein. Our findings suggest that, in spite of specialization in distinct siRNA-directed silencing pathways, these three proteins fulfill a common biochemical function. In Drosophila, miRNA and RNAi pathways are both genetically and biochemically distinct. Dicer-2 (Dcr-2) generates siRNAs, whereas the Dicer-1 (Dcr-1)/Loquacious complex produces miRNAs. Argonaute proteins can be divided by sequence similarity into two classes: in flies, the Ago subfamily includes Argonaute1 (Ago1) and Argonaute2 (Ago2), whereas the Piwi subfamily includes Aubergine, Piwi and Argonaute 3. siRNAs and miRNAs direct posttranscriptional gene silencing through effector complexes containing Ago1 or Ago2. The third class of small RNAs, called repeat-associated small interfering RNAs (rasiRNAs), is produced endogenously in the Drosophilagerm line. rasiRNAs mediate silencing of endogenous selfish genetic elements such as retrotransposons and repetitive sequences to ensure genomic stability. We examined the genetic requirements for biogenesis of rasiRNAs in both male and female germ line of Drosophilaand silencing of 8 different selfish elements, including tree LTR retrotransposons, two non-LTR retrotransposons, and three repetitive sequences. We find that biogenesis of rasiRNAs is different from that of miRNAs and siRNAs. rasiRNA production appears not to require Dicer-1 or Dicer-2. rasiRNAs lack the 2´,3´ hydroxy termini characteristic of animal siRNA and miRNA. While siRNAs derive from both the sense and antisense strands of their dsRNA precursors, rasiRNAs accumulate in antisense polarity to their corresponding target mRNAs. Unlike siRNAs and miRNAs, rasiRNAs function through the Piwi, rather than the Ago, Argonaute protein subfamily. We find that rasiRNAs silence their target RNAs posttranscriptionally: mutations that abrogate rasiRNA function dramatically increase the steady-state mRNA level of rasiRNA targets, but do not alter their rate of transcription, measured by nuclear run-on assay. Our data suggest that rasiRNAs protect the fly germ line through a silencing mechanism distinct from both the miRNA and RNAi pathways.

RNA Interference

RNA

Small Interfering

RNA-Induced Silencing Complex

Schizosaccharomyces pombe Proteins

Drosophila Proteins

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Fungi

Regulation of the Cdc14-like Phosphatase CLP1 in <em> Schizosaccharomyces pombe</em> and Identification of SID2 Kinase Substrates: A Dissertation

Chen, Chun-Ti

24 November 2009

Coordination of mitosis and cytokinesis is crucial to generate healthy daughter cells with equal amounts of genetic and cytoplasmic materials. In the fission yeast Schizosaccharomyces pombe, an evolutionarily conserved Cdc14-like phosphatase (Clp1) functions to couple mitosis and cytokinesis by antagonizing CDK activity. The activity of Clp1 is thought to be regulated in part by its subcellular localization. It is sequestered in the nucleolus and the spindle pole body (SPB) during interphase. Upon mitotic entry, it is released into the cytoplasm and localized to the kinetochores, the actomyosin ring, and the mitotic spindle to carry out distinct functions. It is not clear how Clp1 is released from the nucleolus, however, once released, a conserved signaling pathway termed Septation Initiation Network (SIN) functions to retain Clp1 in the cytoplasm until completion of cytokinesis. The SIN and Clp1 function together in a positive feedback loop to promote each other’s activity. That is, the SIN promotes cytoplasmic retention of Clp1, and cytoplasmic Clp1 antagonizes CDK activity and reverses CDK inhibition on the SIN pathway to promote its function and activity. However, at the start of this thesis, the mechanism by which the SIN regulated Clp1 was unknown. The SIN pathway is also required to promote constriction of the actomyosin ring, and the septum formation. However, its downstream targets were still uncharacterized. In two separate studies, we studied how Clp1 is released from the nucleolus at mitotic entry and how the SIN kinase Sid2 acts to retain Clp1 in the cytoplasm. We identified several Sid2 candidate substrates, and revealed other functions of the SIN pathway in coordinating mitotic events.

Schizosaccharomyces pombe Proteins

Protein Tyrosine Phosphatases

Cell Cycle Proteins

Protein Kinases

Gene Expression Regulation

Fungal

Signal Transduction

Amino Acids, Peptides, and Proteins

Cells

Enzymes and Coenzymes

Fungi

Genetic Phenomena

Transkripční faktory CSL a jejich role v kvasince Schizosaccharomyces pombe / Transcription factors CSL and their role in the yeast Schizosaccharomyces pombe

Oravcová, Martina

January 2014

Proteins of the CSL family (CBF1/RBP-Jκ/Suppressor of Hairless/LAG-1) act as effectors of the Notch signalling pathway in metazoan organisms. They function as repressors or activators of gene transcription in the framework of this pathway and influence many developmental processes. Metazoan CSL proteins can regulate gene expression Notch-independently as well. Notch-independent functions of CSL proteins might be evolutionarily ancestral and in cells and organisms may be important equally as Notch-dependent functions. Presence of CSL proteins was identified in several fungal species, organisms lacking the Notch signalling pathway components and most of known metazoan interacting partners of CSL proteins. CSL paralogs of the fission yeast Schizosaccharomyces pombe, cbf11 and cbf12, are non-essential genes encoding proteins localized in the nucleus of the cell. They exert antagonistic effects on regulation of processes like coordination of nuclear and cellular division and cell cycle progression, ploidy maintenance, cell adhesion and other. In this study, we have proved that both CSL paralogs are able to sequence-specifically bind the CSL-response element DNA in vitro and Cbf11 in vivo as well. Both proteins could activate gene expression in vivo and perform the function of transcription factors....

Checkpoint Regulation of Replication Forks in Response to DNA Damage: A Dissertation

Willis, Nicholas Adrian

21 May 2009

Faithful duplication and segregation of undamaged DNA is critical to the survival of all organisms and prevention of oncogenesis in multicellular organisms. To ensure inheritance of intact DNA, cells rely on checkpoints. Checkpoints alter cellular processes in the presence of DNA damage preventing cell cycle transitions until replication is completed or DNA damage is repaired. Several checkpoints are specific to S-phase. The S-M replication checkpoint prevents mitosis in the presence of unreplicated DNA. Rather than outright halting replication, the S-phase DNA damage checkpoint slows replication in response to DNA damage. This checkpoint utilizes two general mechanisms to slow replication. First, this checkpoint prevents origin firing thus limiting the number of replication forks traversing the genome in the presence of damaged DNA. Second, this checkpoint slows the progression of the replication forks. Inhibition of origin firing in response to DNA damage is well established, however when this thesis work began, slowing of replication fork progression was controversial. Fission yeast slow replication in response to DNA damage utilizing an evolutionarily conserved kinase cascade. Slowing requires the checkpoint kinases Rad3 (hATR) and Cds1 (hChk2) as well as additional checkpoint components, the Rad9-Rad1-Hus1 complex and the Mre11-Rad50-Nbs1 (MRN) recombinational repair complex. The exact role MRN serves to slow replication is obscure due to its many roles in DNA metabolism and checkpoint response to damage. However, fission yeast MRN mutants display defects in recombination in yeast and, upon beginning this project, were described in vertebrates to display S-phase DNA damage checkpoint defects independent of origin firing. Due to these observations, I initially hypothesized that recombination was required for replication slowing. However, two observations forced a paradigm shift in how I thought replication slowing to occur and how replication fork metabolism was altered in response to DNA damage. We found rhp51Δ mutants (mutant for the central mitotic recombinase similar to Rad51 and RecA) to slow well. We observed that the RecQ helicase Rqh1, implicated in negatively regulating recombination, was required for slowing. Therefore, deregulated recombination appeared to actually be responsible for slowing failures exhibited by the rqh1Δ recombination regulator mutant. Thereafter, I began a search for additional regulators required for slowing and developed the epistasis grouping described in Chapters II and V. We found a wide variety of mutants which either completely or partially failed to slow replication in response to DNA damage. The three members of the MRN complex, nbs1Δ, rad32Δ and rad50Δ displayed a partial defect in slowing, as did the helicase rqh1Δ and Rhp51-mediator sfr1Δ mutants. We found the mus81Δ and eme1Δ endonuclease complex and the smc6-xhypomorph to completely fail to slow. We were able to identify at least three epistasis groups due to genetic interaction between these mutants and recombinase mutants. Interestingly, not all mutants’ phenotypes were suppressed by abrogation of recombination. As introduced in Chapters II, III and IV checkpoint kinase cds1Δ, mus81Δ endonuclease, and smc6-x mutant slowing defects were not suppressed by abrogation of recombination, while the sfr1Δ, rqh1Δ, rad2Δ and nbs1Δ mutant slowing defects were. Additionally, data shows replication slowing in fission yeast is primarily due to proteins acting locally at sites of DNA damage. We show that replication slowing is lesion density-dependent, prevention of origin firing representing a global response to insult contributes little to slowing, and constitutive checkpoint activation is not sufficient to induce DNA damage-independent slowing. Collectively, our data strongly suggest that slowing of replication in response to DNA damage in fission yeast is due to the slowing of replication forks traversing damaged template. We show slowing must be primarily a local response to checkpoint activation and all mutants found to fail to slow are implicated in replication fork metabolism, and recombination is responsible for some mutant slowing defects.

DNA Damage

DNA Helicases

DNA-Binding Proteins

Endonucleases

S Phase

Schizosaccharomyces

Schizosaccharomyces pombe Proteins

RecQ Helicases

Amino Acids, Peptides, and Proteins

Enzymes and Coenzymes

Fungi

Genetic Phenomena

Role of the Sid2-Mob1 Kinase Complex in Controlling the Onset of Cytokinesis in the Fission Yeast Schizosaccharomyces Pombe: a Dissertation

Hou, Ming-Chin

15 March 2004

Cytokinesis is a fundamental step of cell proliferation by which daughter cells acquire equal amounts of genetic materials and cellular components. Cytokinesis is precisely regulated in a temporal and spatial manner to ensure that cytokinesis does not occur until chromosome segregation is complete. Failed or precocious cell division causes aneuploidy and/or polyploidy, which is often associated with cancer. In order to coordinate cytokinesis with mitosis, signaling networks have evolved in eukaryotic organisms to faithfully control late cell cycle progression by triggering cytokinesis once mitotic events have been successfully accomplished. In the fission yeast Schizosaccharomyces pombe, this conserved signaling network is known as the septation initiation network (SIN), which triggers actomyosin ring constriction and septum formation after chromosome segregation. The key output of the SIN is thought to be Sid2p kinase activity because Sid2p kinase is the most downstream component of the SIN identified so far, and in addition to the spindle pole bodies Sid2p also localizes to the division site at the end of anaphase, suggesting that Sid2p kinase transmits the division signal from the SPB to the division site, thereby triggering actomyosin ring constriction and septum formation. However, how Sid2p kinase activity is regulated during the cell cycle is still unclear. The goal of this thesis is to understand how Sid2p kinase is regulated. We identified and characterized Mob1p as a novel component of the SIN and a binding partner of the Sid2p kinase. We found that Mob1p is an essential regulatory component important for Sid2p kinase function. Furthermore, we found that phosphorylation is essential for activation of Sid2p kinase and that self-association is able to antagonize Sid2p kinase activity. Thus, we conclude that Sid2p kinase may utilize multiple modes of regulation, including Mob1p binding, stimulatory phosphorylation, and self-association, to control initiation of cytokinesis. Considering the conservation of Mob1p and Sid2p families in the eukaryotes, it is likely that other eukaryotic organisms utilize similar mechanism(s) to control cytokinesis.

Cell Division

Gene Expression Regulation, Fungal

Phosphorylation

Protein Kinases

Schizosaccharomyces pombe Proteins

Signal Transduction

Academic Dissertations

Life Sciences

Medicine and Health Sciences

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