Influence Of FtsH Protease On The Medial FtsZ Ring In Escherichia Coli

Bhatt, Brijesh Narayan

08 1900

FtsH is an essential AAA family Zn++ metalloprotease of Escherichia coli, possessing ATPase-dependent chaperon activity and ATP-dependent protease activity. Heat shock transcription factor Sigma32, LpxC, SecY, and bacteriophage protein CII are some of the substrates of FtsH. Although FtsH is known to influence several cellular processes, the role of FtsH in bacterial cell division had not been identified. FtsZ is the principal cell division protein that marks the cell division site at mid-cell by forming a ring structure. Using a pair of ftsH-null and isogenic wild type strain of E. coli, earlier studies in the laboratory had demonstrated that proteolytic function of FtsH is required for the presence of FtsZ rings at mid-cell site. It was also shown that FtsZ is not a substrate for FtsH protease in vivo. In view of these observations, using a pair of ftsH-null and isogenic wild type strain of E. coli, experiments were carried out to find out the mechanism behind the requirement for FtsH protease for the presence of FtsZ ring at mid-cell site. Viability of the cells having ftsH-null status was maintained by a suppressor mutation at another locus, and was found to be comparable to that of isogenic wild type cells. Immunostaining for FtsZ showed that only 20% cells of ftsH-null strain of E. coli has FtsZ ring at mid-cell site, On the contrary, more than 90% cells of isogenic wild type cells had FtsZ ring at mid-cell site. Live cell imaging with FtsZ-GFP also showed similar results. Low fraction of ftsH-null cells having FtsZ ring was found to be independent of slow growth rate of the cells. Confocal microscopy revealed that ftsH-null cells lacked the normal helical spiral-type structure of FtsZ, unlike the intact FtsZ helices present in isogenic wild type cells. FtsZ protein levels in the membrane and cytoplasmic fractions of ftsH-null cells were found to be same as those in the isogenic wild type cells. Exogenous expression of wild type FtsH in ftsH-null cells could restore FtsZ ring status to normalcy, similar to that in the isogenic wild type cells. However, this restoration could not be accomplished by FtsH mutants, which were lacking in ATP binding, ATPase, or protease activities. FtsA anchors FtsZ to the membrane and a specific FtsZ/FtsA ratio is known to be critical for cell division. Further, FtsA and/or ZipA are required for the stabilisation of FtsZ ring at mid-cell site. The levels of FtsA were found to be lower by more than 2.5-fold in all the membrane and soluble fractions of ftsH-null cells. The levels of FtsA were found restored to normalcy upon complementation with exogenous expression of FtsH. Low levels of FtsA were not due to the slow growth of ftsH-null cells. Exogenous expression of FtsA or FtsA-GFP restored FtsZ in more than 90% of ftsH-null cells. Moreover, FtsA mutants, which are defective in the interaction with FtsZ, did not restore FtsZ rings to normalcy. The levels of ZipA were found to be same in ftsH-null and isogenic wild type cells. Expression of ZipA or ZipA-GFP could restore FtsZ rings to normalcy in ftsH-null cells. These data showed that low FtsA levels might be the reason for low percentage of cells having FtsZ ring in ftsH-null cells. It implied that ftsH-null cells might have been managing FtsZ ring stabilisation with ZipA, to facilitate septation. Real time RT-PCR showed that the levels of ftsA mRNA and those of all the other fts genes, except ftsZ, in the 16-gene dcw cluster, were found to be low in ftsH-null cells. Moreover, real time RT-PCR using specific primers designed for multiple promoters of ftsZ and for the RNaseE processing site, just upstream of ftsZ, showed that the levels of transcripts of the genes upstream to RNaseE site were significantly low and that the levels of ftsZ transcripts, which were downstream to RNaseE site, were unaffected. On the contrary, the levels of mRNAs of fts genes, such as ftsE, ftsX, ftsN, and zipA that were located at another part of the genome, were normal in ftsH-null cells. These observations suggested that the reason for the low levels of FtsA protein might be low levels of ftsA mRNA. In addition, the low levels of other fts mRNAs from the dcw cluster, and probably of the respective proteins, might contribute to the slow growth of ftsH-null cells. The ftsH null strains also showed less compact nucleoids and the nucleoids did not look bilobular. This data suggested that there may be some defect in the compaction of nucleoids in ftsH-null cells. On the contrary, isogenic wild type cells, when grown slow like the growth of ftsH-null cells, had no defect in nucleoid compaction and looked bilobular. The proper compaction of nucleoids could be restored only by wild type FtsH, but not by the protease mutant of FtsH. These observations suggest that proteolytic activity of FtsH might be required for the proper compaction of nucleoids, which in turn might have influence on the placement of FtsZ ring at mid-cell site. In parallel, different percentage of silver stained single-dimension SDS-PAGE showed conspicuous difference in the protein profiles of the membrane and soluble fractions of ftsH-null cells, in comparison to those of isogenic wild type cells. FtsZ co-immuno precipitation (CoIP) of total cell lysates of ftsH-null and isogenic wild type cells showed differential interaction of two proteins, the outer membrane protein A (OmpA) and a 50 kDa protein, between the two strains. The level of OmpA was 2.5-fold high in ftsH-null cells, in comparison to that in isogenic wild type cells. However, overexpression of ompA in isogenic wild type cells did not have any effect on FtsZ rings in isogenic wild type cells. Two-dimensional gel electrophoresis for membrane and soluble fractions of ftsH-null cells, in comparison with that of isogenic wild type cells, showed that several proteins in each fraction were either present or absent between these two strains. Most of these proteins were then identified using MALDI-TOF / LC –MS methods. Identification of these proteins, which were present differentially between ftsH-null and isogenic wild type cells, has revealed existence of many more hitherto unidentified potential substrates of FtsH and therefore cell processes, which FtsH may influence.

Bacterial Cell

Escherichia Coli

FtsH Protease

FtsZ Ring

Cell Division Genes

Bacterial Cell Septation

FtsA

E. coli

Biochemistry

Molecular Regulation of Muscle Stem Cell Self-Renewal

Wang, Yu Xin

January 2016

Muscle stem cells self-renew to maintain the long-term capacity for skeletal muscles to regenerate. However, the homeostatic regulation of muscle stem cell self-renewal is poorly understood. By utilizing high-throughput screening and transcriptomic approaches, we identify the critical function of dystrophin, the epidermal growth factor receptor (EGFR), and fibronectin in the establishment of cell polarity and in determining symmetric and asymmetric modes of muscle stem cell self-renewal. These findings reveal an orchestrated network of paracrine signaling that regulate muscle stem cell homeostasis during regeneration and have profound implications for the pathogenesis and development of therapies for Duchenne muscular dystrophy.

Muscle Regeneration

Duchenne muscular dystrophy

Satellite Cell

Muscle Stem Cell

EGFR

Dystrophin

Aurora kinase A

Wnt7a

Cell Polarity

Asymmetric Cell Division

Phylogénomique des structures multiprotéiques eucaryotes impliquées dans le cycle cellulaire et contribution à la phylogénie des eucaryotes. / Phylogenomics of eukaryotic multiprotein structures involved in cell cycle and contribution to the eukaryotic phylogeny

Eme, Laura

01 June 2011

Retracer l'histoire évolutive des eucaryotes est une question majeure en évolution et fait l'objet de nombreux débats. Le développement de techniques à haut débit, en particulier en protéomique et en génomique, a permis d'obtenir de nombreuses données pouvant être exploitées lors d'analyses évolutives. Dans ce contexte, les structures multiprotéiques eucaryotes (SME) constituent des objets d'intérêt. En effet, ces gros complexes protéiques sont impliqués dans de nombreux processus fondamentaux de la cellule eucaryote, et n'ont pas d'homologues chez les procaryotes (même si les fonctions dans lesquelles ils sont impliqués peuvent exister). Ils ont donc certainement joué un rôle prépondérant dans l'eucaryogénèse. L'analyse phylogénomique de deux SME impliquées dans la division cellulaire (le midbody et l'APC/C) montre que ces systèmes ont une origine évolutive ancienne et étaient déjà présents chez le dernier ancêtre commun des eucaryotes (LECA), tout en étant issus d'innovations eucaryotes. Ceci implique que l'émergence de ces deux SME s'est faite après la divergence de la lignée eucaryote et avant la diversification ayant donné naissance aux lignées actuelles. Au-delà de ces considérations évolutives, l'analyse de ces SME ouvre des pistes sur certains aspects de la biologie de ces systèmes. En effet, si ces systèmes ont été globalement bien conservés au cours de la diversification des eucaryotes, leur analyse révèle une grande plasticité de composition dans certaines lignées de protistes. Ceci suggère des changements récents concernant certaines étapes du cycle cellulaire de ces organismes qu'il serait intéressant d'explorerexpérimentalement.En parallèle, ce travail a montré que, bien qu'étant des protéines opérationnelles, lescomposants de ces SME portent un signal phylogénétique exploitable pour inférer les relations de parentés entre lignées eucaryotes. La construction de supermatrices à partir de ces protéines a permis l'inférence de phylogénies de qualité, même si non totalement résolues, dans lesquelles, par exemple, la monophylie des Excavata ou encore le placement des microsporidies au sein des Fungi est bien supporté. La combinaison de ces données avec celles issues d'analyses basées sur des protéines informationnelles montrent des avancées significatives concernant la résolution des arbres inférés. Ces résultats ouvrent le champ des possibles quant à la recherche d'autres marqueurs encore inexploités parmi les protéines opérationnelles. L'intégration de ces nouveaux marqueurs associée à l'augmentation de l'échantillonnage taxonomique représente une piste prometteuse pour l'avenir.Ce travail illustre l'intérêt de généraliser les approches évolutives intégrées des systèmes biologiques pour l'étude de l'évolution et de la phylogénie des eucaryotes. / Tracing back the evolutionary history of eukaryotes is one of the major issues in the field of evolution and is hotly debated. The development of high throughput techniques, especially in proteomics and genomics has yielded extensive data that can be used in evolutionary analyses. In this context, eukaryotic multiprotein structures (EMS) are objects of interest. Indeed, these large protein complexes are involved in many fundamental processes of eukaryotic cells, and have no homologues in prokaryotes (even if the functions in which they are involved may exist) and therefore have certainly played a major role in the eukaryogenesis. The phylogenomic analysis of two EMS involved in cell division (the midbody and the APC/C) shows that these systems have an ancient evolutionary origin and were already present in the last common ancestor of eukaryotes (LECA), while resulting from eukaryotic innovations. This implies that the emergence of these two EMS occurred after the divergence of the eukaryotic lineage and before the diversification that gave rise to the current lineages. Beyond these evolutionary questions, analyses of these EMS uncover some biological aspects of these systems. Indeed, if these systems were generally well conserved during the diversification of eukaryotes, their analysis shows a high plasticity of composition in some protist lineages. This suggests that recent changes regarding certain phases of these organisms cell cycle which would be interesting to explore experimentally. Concomitantly, this work showed that, although being operational protein, components of these EMS carry a phylogenetic signal usable for inferring phylogenetic relationships among eukaryotic lineages. Construction of supermatrixes from these proteins led to the inference of phylogenies of high quality, even if not fully resolved, in which, for example, the monophyly of Excavata or the placement of Microsporidia within Fungi is well supported. Combining these data with those from analyses based on informational proteins show significant progress on the resolution of inferred trees. These results open the field of possibilities to find other markers among the untapped proteins operational. The integration of these new markers associated with increased taxonomic sampling represents a promising approach.This work illustrates the interest of generalizing integrated evolutionary approaches ofbiological systems for studying the evolution and phylogeny of eukaryotes.

Phylogénie

Eucaryotes

Leca

Dernier Ancêtre Commun des Eucaryotes

Phylogénomique

Division cellulaire

Evolution

Phylogeny

Eukaryotes

Leca

Phylogenomics

Cell division

Evolution

Interferindo na progressão do ciclo celular para avaliar possíveis alterações de ploidia em célula tumoral de mama humana. / Interference in the cell cycle progression to analyze possible alteration of ploidy in tumor cell of human breast.

Marina da Costa Rosa

05 December 2011

A maioria dos tumores sólidos apresentam características aneuplóides. Porém a relação entre aneuploidia e transformação maligna, ainda não está definida. Nos últimos anos diversas proteínas têm sido descritas como reguladoras de eventos durante a divisão celular, principalmente as relacionadas com a formação do fuso bipolar e segregação equacional dos cromossomos. Neste estudo propomo-nos a analisar os efeitos da interferência em dois pontos críticos da mitose, a segregação cromossômica e a citocinese, em relação à aneuploidia e à instabilidade genética tumoral. Nossos dados mostraram que o tratamento sequencial de Monastrol e Blebistatina determinou o surgimento de fusos mitóticos anormais, amplificação centrossômica, localização ectópica de Aurora A e aumento de micronúcleos. Esta interferência pode levar a um quadro de instabilidade genética e, consequentemente a progressão tumoral, abrindo novas possibilidades para o estudo dos mecanismos moleculares envolvidos na regulação do ponto de checagem mitótico e resistência a quimioterápicos. / Most solid tumors have aneuploid feature. Therefore the relationship between aneuploidy and malignant transformation is not yet understood. In the last years it has been described many proteins involved in regulation of mitosis, mainly those related to bipolar spindle and chromosome segregation. In this work we propose to study the effects of the interference on two mitotic critical points, the chromosome segregation and cytokinesis, in relation to aneuploidy and genetic tumor instability. Our data showed that sequential treatment with Monastrol and Blebbistatin led to abnormal mitotic spindle, centrosome amplification, Aurora A ectopic and micronucleus increased. This interference can lead to genetic instability and may be involved in a tumor progression, opening news possibilities to study the molecular mechanisms involved in regulation the checkpoint mitotic and resistance to chemotherapy found in genetically unstable cells.

Células cultivadas de tumor

Ciclo celular

Divisão de células

Mama

Mitose

Neoplasias

Cell cycle

Cell division

Mama

Mitosis

Neoplasms

Tumor cells grown

Aplicação de microscopia de série temporal para o estudo da expressão gênica e montagem do divisomo em Bacillus subtilis / Aplications of time-lapse microscopy to study gene expression thoughout cell cycle and divisome assembly in Bacillus subtilis

Theopi Alexandra Varvakis Rados

21 May 2013

A divisão celular nas bactérias requer a formação do divisomo, um complexo protéico que tem como o primeira etapa a polimerização da proteína FtsZ, seguida pela associação de 15 outras proteínas conhecidas. Os mecanismos envolvidos na regulação espacial do divisomo são bem caracterizados, mas o controle temporal da divisão celular em relação a outros eventos do ciclo, como a replicação do cromossomo, segue controversa. Neste trabalho, aplicamos a metodologia de microscopia de série temporal para estudar duas questões fundamentais do processo de divisão: a montagem do complexo que executa a divisão e a possibilidade da oscilação periódica na expressão de um ou mais genes envolvidos em divisão possa participar do controle temporal da montagem do divisomo. Para investigar se há oscilação da expressão gênica, construímos inicialmente variantes instáveis GFP através da adição de sequências peptídicas C-terminais que encaminham para a degradação em B. subtilis e utilizamos estes repórteres para criar fusões transcricionais sob o controle de promotores de genes centrais do processo de divisão. Depois de otimizar as condições de microscopia de série temporal com fusões transcricionais usando a variante instável GFPAISV, observamos que a autofluorescência de B. subtilis interferia nas nossas quantificações. Como forma de contornar a autofluorescência, construímos então fusões transcricionais com duas variantes de YFP (proteína fluorescente amarela) e optamos por trabalhar com Ypet-AISV. A análise de filmes de células individuais, tanto com fusões a GFPAISV como a Ypet-AISV, indicou que apenas o promotor do operon ftsL-pbpB apresentava um padrão de oscilação significativamente diferente de um promotor artificial usado como controle negativo. Esta hipótese, no entanto, não foi confirmada por medidas estáticas de populações de células nas quais correlacionamos intensidade de fluorescência com posição no ciclo celular. Portanto, nossos dados não foram capazes de evidenciar flutuações na expressão dos genes ftsL-pbpB, minCD, ftsZ, ftsA e zapA ao longo do ciclo celular. Para estudar a cinética de montagem divisomo foram realizados experimentos de microscopia de série temporal de FtsZ-mCherry e Pbp2B-GFP, onde observamos que a associação de Pbp2B ao divisomo ocorre 3 minutos após a formação do anel de FtsZ em meio rico e 4 minutos em meio mínimo. Também realizamos experimentos de microscopia de série temporal com uma cepa contendo FtsZ-YFP e DivIVA-CFP, determinando que DivIVA é incorporado ao divisomo 16 minutos após a formação do anel de FtsZ em meio rico e 20 minutos em meio mínimo. Estes dados confirmam que a montagem do divisomo ocorre em três etapas, e não duas, como anteriormente proposto. / Cell division in bacteria requires the formation of the divisome, a protein complex that has as the first step polymerization of FtsZ, followed by the assembly of 15 other known proteins. The mechanisms that underlie spatial regulation of divisome assembly have been largely elucidated, but the temporal control that ties the timing of cell division to other cell cycle events, such as chromosomal replication, remains surrounded by controversy. In this work, we use time-lapse microscopy to address two issues in B. subtilis cell division: the timing of divisome assembly, and the possibility that a periodic oscillation in expression of one or more genes essential for divisome assembly may play a role in defining the timing of cell division. To study the possibility of oscilation in gene expression, we have first built unstable variants of GFP by adding to its C-terminus peptide sequences that target the protein for degradation and used those variants to build transcriptional fusions to access the promoter activity of core cell division genes. After optimizing time-lapse conditions with transcriptional fusions to cell divison genes with the unstable GFPAISV, we observed that B. subtilis autofluorescence was an issue to our quantifications. To improve our signal-to-noise ratio, we built transcriptional fusions with two variants of YFP (Yellow Fluorescent Protein), and decided to work with Ypet. In our single-cell analysis for GFPAISV and for Ypet-AISV, only the ftsL operon promoter presented an oscilating pattern different from our negative control. This was not confirmed, however, when we attempted to correlate fluorescence signal with cell cycle position in static single-cell measurements. Thus, we conclude that that there are no fluctuations in ftsL, pbpB, minCD, ftsZ, ftsA or zapA gene expression throughout the cell cycle. To study divisome assembly we performed time-lapse microscopy of FtsZ-mCherry and Pbp2B-GFP, and determined that the association of Pbp2B occurs 3 minutes after FtsZ polymerization in rich medium and 4 minutes in minimal medium. We also performed time-lapse microscopy with FtsZ-YFP and DivIVA-CFP, determining that DivIVA is incorporated to the divisome in 16 minutes after FtsZ polymerization in rich medium and 20 minutes in minimal medium. This data confirms the assembly of the divisome in three steps rather than two, as previously proposed.

Bacillus subtilis

Divisão celular

Divisomo

Expressão gênica

GFP

Time-lapse

Bacillus subtilis

Cell division

Divisome

Gene expression

GFP

Time-lapse

Estudos evolutivos do divisomo, um complexo multiprotéico responsável pela divisão bacteriana / Evolutionary studies of the divisome, a multiprotein complex responsible for bacterial division

Robson Francisco de Souza

07 November 2007

O mecanismo de divisão mais comum entre procariotos é a divisão binária, na qual a célula- mãe reparte seu genoma e conteúdo citoplasmático de forma igual entre duas células filhas. Esse processo é mediado por um complexo protéico especializado, chamado divisoma, composto por cerca de 20 proteínas, que promovem a constrição da parede celular e membrana citoplasmática, formando o septo de divisão. O complexo é organizado em torno do anel Z, uma estrutura em anel composta pela proteína FtsZ, um homólogo de tubulina presente na maioria dos procariotos e em algumas organelas de eucariotos. Partindo de um levantamento detalhado da distribuição dos genes do divisoma em genomas completos de procariotos, aplicamos métodos de máxima verossimilhança para inferência de estados ancestrais e reconstruímos o conteúdo gênico do divisoma no ultimo ancestral comum das bactérias atuais. Estendendo essas análises com a aplicação de métodos filogenéticos, inferimos os eventos responsáveis pelas variações de composição deste complexo, observadas entre os diferentes grupos de bactérias. Nossos resultados mostram que o último ancestral comum de todas as bactérias já possuía a maior parte dos componentes conhecidos do divisoma, sugerindo a existência de uma parede de peptideoglicano e a presença de um aparato molecular tão ou mais complexo que o observado nas linhagens atuais, incluindo a presença de componentes considerados acessórios e de distribuição relativamente restrita, como as proteínas envolvidas na localização do anel Z (sistema Min) e alguns efetores positivos da polimerização de FtsZ. Observamos também que a evolução do complexo não foi muito afetada por eventos de transferência lateral, mas apresenta vários exemplos de perda de genes, em especial em linhagens com genoma reduzido, o que sugere a redundância de vários componentes já presentes no ancestral e a freqüente redução da complexidade, pelo menos dos componentes centrais do divisoma. Episódios de expansão de famílias de componentes do divisoma em linhagens específicas e os mecanismos evolutivos responsáveis pela incorporação de tais variações são discutidos. A caracterização da história evolutiva detalhada do divisoma, aqui apresentada, poderá servir como ponto de partida para novas análises evolutivas e como base para elaboração de experimentos funcionais. / The most common cell division mechanism among prokaryotes is binary fission, where a mother cell partitions its cytoplasm and genome equally among two daughter cells. This process is mediated by a specialized protein complex, known as the divisome, composed of around 20 proteíns, that promotes constriction of the cell wall and cytoplasmic membrane, thus forming the division septa. The complex is organized around the Z-ring, a ring-shaped struture composed by FtsZ, a tubulin homolog present in most prokaryotes and some eukaryotic organelles. After a detailed revision of the distribution of divisome genes among completely sequenced prokaryotic genomes, we applied maximum likelihood methods for the inference of ancestral states and reconstructed the gene content of the divisome in the last common ancestor of all extant bacteria. We then performed phylogeneticanalysis of all cell division genes and inferred the series of events responsible for the observed variations of the complex´s composition among bactérial lineages and their common ancestor. Our results show that the last common ancestor of all bacteria already possessed most of the known divisome components, thus suggesting the existence of a peptidoglycan cell wall and the presence of a molecular apparatus, perhaps more complex than those found in extant bacteria, including the presence of some accessory components with a somewhat restricted distribution, like the proteíns involved in the localization of the Z-ring (Min sistem) and some positive effectors os FtsZ polimerization. We also observed that the complex´s evolution was almost never the subject of horizontasl gene transfer events, but shows several examples of gene loss, specially in lineages displaying clear signs of genome reduction, thus suggesting the redundancy of several components in the ancestral divisome and a certain degree complexity reduction, at least for core components of the divisome. Lineage specific expansion of divisome component and the evolutionary mechanisms behind such processes are discussed. This characterization of the detailed evolutionary history of the divisome might serve as a starting point for new evolutionary analysis and as a basis for the design of functional experiments.

Bacillus

Divisão celular

Divisoma

Estados ancestrais

Evolução molecular

Máxima verossimilhança

Ancestral states

Bacillus

Cell division

Divisome

Maximum likelihood

Molecular evolution

Construção e caracterização de um vírus Adeno-associado com expressão direcionada para células em divisão / Construction and characterization of adeno-associated virus with limited expression for proliferating cells

Anna Carolina Pereira Vieira de Carvalho

09 April 2010

A utilização do vírus adeno-associado recombinante (AAVr) como vetor de transferência gênica em células tumorais está crescendo. Neste trabalho, o promotor gênico de E2F-1, um promotor ativo durante a divisão celular, foi inserido no AAVr e utilizado para dirigir a expressão do HSV-tk ou luciferase e, simultaneamente, eGFP afim de direcionar a expressão viral para células em proliferação. Em paralelo, foram construídos vetores portadores do promotor constitutivo CMV para servir como controles. O promotor gênico de E2F-1 não foi eficiente em dirigir a expressão dos transgenes na linhagem celular HT1080, enquanto o promotor CMV apresentou uma alta expressão dos repórteres e do gene terapêutico. A baixa eficiência do promotor E2F-1 ainda não foi explorada, mas poderia ser relacionada com o desempenho intrínseco deste promotor, a biologia do vetor AAVr e especificidade celular. Contudo, o bom desempenho do vetor AAVr contendo o promotor CMV abre a possibilidade de realizar novos ensaios de transferência gênica para tratamento e visualização de células tumorais / The utilization of recombinant adeno-associated virus (AAVr) as a gene transfer vector in tumor cells is increasing. In this work, the promoter of the E2F-1 gene, active during cell division, was inserted in an AAVr vector and used to drive the expression of HSV-tk or luciferase and, simultaneously, eGFP with the intent of limiting viral expression to proliferating cells. Also, vectors with the constitutive CMV promoter were constructed to be used as controls. The E2F-1 promoter was not efficient in driving the expression of the transgenes in the HT1080 cell line, while the CMV promoter shows high level expression of the reporter and the therapeutic genes. The low efficiency of E2F promoter has not yet been explored, though this problem could be related to the intrinsic performance of this promoter, the biology of the vector AAV and cell-specific factors. However, the performance of the AAVr containing the CMV promoter creates the possibility of performing new gene transfer protocols for the treatment and visualization of tumor cells.

Divisão celular

Expressão gênica

Neoplasias

Terapia biológica

Transferência de genes

Vetores

Biology therapy

Cell division

Gene expression

Gene transfer

Neoplasm

Vector

Úloha proteinkinázy StkP v regulaci buněčného dělení Streptococcus pneumoniae / The role of protein kinase StkP in regulation of the cell division in Streptococcus pneumoniae

Malíková, Eliška

January 2011

Protein phosphorylation by protein kinases is a key mechanizm that enables both eukaryotic and prokaryotic organizm sense and read environmental signals and convert these signals into changes in gene expression and thus proper biological response. One of the main phosphorylation systems in bacteria consists of eukaryotic-like Ser/ Thr protein kinases. The genome of human pathogen Streptococcus pneumoniae contains single Ser/ Thr protein kinase StkP. StkP regulates virulence, competence, stress resistance, gene expression and plays an important role in the regulation of cell division cycle. Analysis of phosphoproteome maps of both wild type and ΔstkP mutant strain of S. pneumoniae showed that in vivo StkP phosphorylates several putative substrates including the cell division protein DivIVA (NOVÁKOVÁ et al., 2010). DivIVA in S. pneumoniae is localized at midcell and at the cell poles. It was proposed to be primarily involved in the formation and maturation of the cell poles (FADDA et al., 2007). The aim of this thesis was to investigate phosphorylation of the cell division protein DivIVA in S. pneumoniae. Gene divIVA was cloned, expressed in E. coli and protein was purified via affinity chromatography. Phosphorylation of DivIVA by StkP was examined in a kinase assay. We confirmed that DivIVA is a direct...

Coordinating Cytokinesis with Mitosis by a Conserved Signal Transduction Network in the Fission Yeast Schizosaccharomyces Pombe: a Dissertation

Guertin, David A.

08 November 2002

Cytokinesis is the final event of the cell division cycle and results in physical and irreversible separation of a mother cell into two daughter cells. Cytokinesis must only occur after chromosomes have segregated during mitosis to ensure each daughter cell receives the proper complement of genetic material. Failure to execute normal cytokinesis can result in aneuploidy and/or polyploidy, a hallmark of many cancers. Cytokinesis occurs mechanically through constriction of an actin-myosin based contractile ring, while initiation of ring constriction is temporally and spatially mediated by complex signaling networks. It is absolutely crucial that cytokinesis is tightly coordinated with the cell cycle in order to preserve the fidelity of cell division. We hypothesized that to achieve such tight control of cytokinesis, cells may utilize both promotional and inhibitory signals, however how cells maintained this control was poorly understood. The goal of this thesis was to characterize how cells regulate signaling of cytokinesis, both positively and negatively, during cell division using the fission yeast Schizosaccharomyces pombe as a model organism. Two approaches were employed. (1) We first sought to characterize the positive timing mechanism that signals cytokinesis though a detailed investigation of Sid1p, a protein kinase essential for activation of ring constriction. (2) Secondly, we sought to define how cells negatively regulate cytokinesis through investigation of Dma1p, a spindle checkpoint protein implicated in inhibition of cytokinesis. Our results reveal a conserved signaling network, termed the Septation Initiation Network (SIN), of which Sid1p is an intermediate component, that controls temporal and spatial regulation of cytokinesis. We found Sid1p is additionally controlled by Cyclin Dependent Kinase activity, uncovering an important link between mitotic events and initiation of cytokinesis. Furthermore, we found that aberrant SIN activation can override a microtubule-damage-induced spindle checkpoint arrest. This effect is counteracted by Dma1p, which normally inhibits the SIN during checkpoint activation to preserve cell viability until damage is repaired. We conclude that signaling cytokinesis is tightly coordinated with mitosis in S. pombe by positive signals acting through Sid1p and the SIN, and under certain conditions, negative signals acting through Dma1p. Considering the conservation of cell cycle regulators in the eukaryotic kingdom, it is likely that similar mechanisms to control cytokinesis exist in humans.

Cell Cycle Proteins

Cell Division

Schizosaccharomyces pombe Proteins

Signal Transduction

Academic Dissertations

Life Sciences

Medicine and Health Sciences

Cell Size Control in the Fission Yeast Schizosaccharomyces pombe: A Dissertation

Keifenheim, Daniel L.

17 June 2015

The coordination between cell growth and division is a highly regulated process that is intimately linked to the cell cycle. Efforts to identify an independent mechanism that measures cell size have been unsuccessful. Instead, we propose that size control is an intrinsic function of the basic cell cycle machinery. My work shows that in the fission yeast Schizosaccharomyces pombe Cdc25 accumulates in a size dependent manner. This accumulation of Cdc25 occurs over a large range of cell sizes. Additionally, experiments with short pulses of cycloheximide have shown that Cdc25 is an inherently unstable protein that quickly returns to a size dependent equilibrium in the cell suggesting that Cdc25 concentration is dependent on size and not time. Thus, Cdc25 can act as a sizer for the cell. However, cells are still viable when Cdc25 is constitutively expressed suggesting that there is another sizer in the case that Cdc25 expression is compromised. Cdc13 is a likely candidate due to the similar characteristics to Cdc25 and the ability to activate Cdc2. Cdc13 accumulates during the cell cycle in a manner similar to Cdc25. I show that in the absence of Cdc2 tyrosine phosphorylation, the cell size is sensitive to Cdc13 activity showing that Cdc13 accumulation can determine when cells enter mitosis. These results suggest a two sizer model where Cdc25 is the main sizer with Cdc13 acting as a backup sizer in the event of Cdc25 expression is compromised. Additionally, in the absence of Cdc2 phosphorylation by the kinases Wee1 and Mik1, mitotic entry is regulated by the activity of Cdc2. In the absence of Cdc2 phosphorylation, this activity is regulated by binding of cyclins to Cdc2. Under these circumstances, the activity of Cdc13 can regulate mitotic entry provide further evidence that Cdc13 could be a sizer of the cell in the case where Cdc25 expression is compromised. The results I present in this dissertation provide the groundwork for understanding how cells regulate size and how this size regulation affects cell cycle control in S. pombe . The results show how the intrinsic cell cycle machinery can act as a sizer for the G2/M transition in S. pombe . Interestingly, this mitotic commitment pathway is well conserved suggesting a general solution for size control in eukaryotes at the G2/M transition. Understanding the mechanism of how protein concentration is regulated in a size dependent manner will give much needed insight into how cells control size. Elucidating the mechanism for size control will capitalize on decades of research and deepen our understanding of basic cell biology.

Cell Size

Cell Cycle

Cell Cycle Checkpoints

Cell Division

Schizosaccharomyces

Dissertations, UMMS

Cell Biology

Cellular and Molecular Physiology