Estudo comparativo das características citogenéticas e moleculares de Triatoma maculata e Triatoma pseudomaculata (Triatominae, Heteroptera)

Mendonça, Priscila Pasquetto [UNESP]

19 February 2010

Made available in DSpace on 2014-06-11T19:26:03Z (GMT). No. of bitstreams: 0 Previous issue date: 2010-02-19Bitstream added on 2014-06-13T20:33:40Z : No. of bitstreams: 1 mendonca_pp_me_sjrp.pdf: 681812 bytes, checksum: d7353da4e0742a18d8d505b0587fda7b (MD5) / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Os triatomíneos são insetos hematófagos de grande importância para a parasitologia humana, pois são transmissores do Trypanosoma cruzi, protozoário causador da doença de Chagas. Além de sua importância médico-sanitária, os triatomíneos destacam-se pela sua citogenética, pois possuem cromossomos holocêntricos e um modelo de meiose incomum, com meiose invertida para os cromossomos sexuais. Recentes pesquisas com marcadores moleculares em triatomíneos tentam compreender a ancestralidade do grupo. Uma das formas de se compreender a evolução entre espécies é a partir da análise de seqüências do DNA ribossômico (DNAr). Por pertencer a famílias multigênicas, cópias individuais do DNAr não acumulam mutações independentemente, resultando em pequena variação intra-específica e relevante diferenciação interespecífica. No presente trabalho foi realizado um estudo comparativo entre as espécies Triatoma maculata e Triatoma pseudomaculata, com base no uso das técnicas citogenéticas convencionais de orceína lacto-acética, impregnação por íons prata, bandamento-C, reação de Feulgen; da técnica de citogenética molecular de bandamento- C CMA/DAPI; e também por meio da análise da região ITS-1 do DNAr, com base no sequenciamento, com o objetivo de avaliar o grau de homologia entre as espécies estudadas. Os cariogramas das duas espécies indicaram dez pares de autossomos (um deles de tamanho maior) e um par de cromossomos sexuais (2n = 22). No ciclo meiótico foi possível observar a fragmentação da região nucleolar no final do estágio difuso. Corpúsculos nucleolares foram observados em alguns dos núcleos em metáfases meióticas de T. pseudomaculata, evidenciando a persistência nucleolar. A técnica de bandamento-C revelou que o cromossomo Y é heterocromático em ambas as espécies. O sequencimento da região ITS-1, indicou que as espécies apresenta... / The triatomines are hematophagous insects of great concern in public health because they are vectors of Trypanosoma cruzi, a protozoan that causes Chagas disease. Triatomines are also of great genetic interest, because that they present holocentric chromosomes and an unusual form of meiosis with post-reductional segregation of sex chromosomes. Recent studies based on molecular markers try to understand the evolutionary history of triatomines. To understand the evolution of a given species, ribosomal DNA (rDNA) analyses are frequently used, which can help to infer evolutionary relationships among species. Individual copies of rDNA do not accumulate mutations independently because they belong to multigene families, resulting in slight intraspecific and important interspecific variation. In this study, a comparative analysis was performed between the species Triatoma maculata and Triatoma pseudomaculata, based on the cytogenetic techniques of lacto-acetic orcein, silver ion impregnation, Cbanding, Feulgen reaction; and CMA/DAPI C-banding. We also compared the species by sequencing the ITS-1 rDNA internal transcribed region in order to evaluate the degree of homology among the studied species. The cariograms of the two species revealed ten autosomes and one pair of sexual chromosomes (2n= 22). In the meiotic cycle, nucleolar fragmentation during the final stages of meiotic prophase I was found. Nucleolar corpuscles were found in some meiotic metaphases of T. pseudomaculata, which is evidence of nucleolar persistence. The C-banding technique revealed that the Y chromosome is heterochromatic in both species. The ITS-1 rDNA sequences showed that the species presented a discharge proximity to each other, and had a high degree of homology (98.5%). The knowledge obtained in this study contributes to the understanding of the interrelation and distribution of those species, and offers... (Complete abstract click electronic access below)

Citogenética

Espermatogenese em animais

Triatoma

DNA

Acido ribonucleico

Triatomíneos

Cromossomos holocêntricos

DNAr

Triatomines

Holocentric chromosomes

Spermatogenesis

Nucleolar Organizer Region (RONs)

Heterochromatin

Ribosomal DNA

Statistical analysis and modeling of nuclear architecture in Arabidopsis Thaliana / Analyse statistique et modélisation de l'architecture nucléaire chez Arabidopsis thaliana

Arpón, Javier

09 November 2016

Les noyaux des cellules eucaryotes contiennent différents compartiments définis fonctionnellement ou structurellement et à multiples échelles qui présentent une distribution spatiale très ordonnée. Un défi majeur est alors d'identifier les règles selon lesquelles les compartiments nucléaires sont organisés dans l'espace et de décrire comment ces règles peuvent varier en fonction des conditions physiologiques ou expérimentales. Les statistiques spatiales ont rarement été utilisées à cette fin et se sont généralement limitées à l'évaluation de l'aléatoire complet. Ici, nous développons une approche de statistiques spatiales qui combine la cytologie, l'analyse d'image et la modélisation spatiale pour mieux comprendre les configurations spatiales à l'intérieur du noyau. Notre première contribution est un cadre méthodologique qui permet de tester des modèles d'organisation spatiale au niveau de la population. Plusieurs modèles spatiaux ont été proposés et mis en œuvre, en particulier l'aléatoire, l'aléatoire orbitale, la régularité maximale, l'aléatoire territoriale et l'aléatoire territoriale orbitale, pour analyser la distribution d'objets biologiques dans des domaines 3D finis et de formes arbitraires. De nouveaux descripteurs spatiaux, combinés aux descripteurs classiques, sont utilisés pour comparer les motifs observés à des configurations attendues sous les modèles testés. Une version non biaisée d'un test statistique publié précédemment est proposé pour évaluer la qualité de l'ajustement des modèles spatiaux sur les distributions observées. Après, nous étudions les propriétés de l'approche proposée à partir de données réelles et simulées. La robustesse de l'approche proposée aux erreurs de segmentation et la fiabilité des évaluations spatiales sont examinées. En outre, la base d'une méthode pour comparer les distributions spatiales entre différents groupes expérimentaux est proposée. Dans la dernière partie de ce travail, notre approche est appliquée à des images de noyaux cellulaires de la feuille chez A. thaliana, pour analyser la distribution spatiale de compartiments dynamiques et plastiques d'hétérochromatine, les chromocentres, qui ont un rôle important dans la structure du génome. Des noyaux isolés et des cryo-sections provenant de plantes de type sauvage ont été analysés. Nous montrons que les chromocentres présentent une distribution très régulière, ce qui confirme les résultats publiés précédemment. En utilisant nos nouveaux descripteurs, nous démontrons pour la première fois, objectivement et quantitativement, que les chromocentres présentent une localisation préférentielle périphérique. En employant un nouveau modèle spatial, nous rejetons l'hypothèse selon laquelle l'organisation régulière observée est uniquement expliquée par un positionnement périphérique. Nous démontrons en outre que les chromocentres affichent une régularité spatiale proche de la régularité maximale à l'échelle globale, mais pas à l'échelle locale. Enfin, nous utilisons des simulations pour tester un modèle selon lequel le positionnement des chromocentres est déterminé par les territoires chromosomiques et par des interactions avec l'enveloppe nucléaire. Nous avons ensuite vérifié s'il la distribution des chromocentres pouvait être modifiée par différentes mutations. Nous avons analysé les données de noyaux des mutants crwn et kaku, qui sont connus pour influencer la morphologie nucléaire. Les résultats suggèrent que ces mutations impactent en effet la morphologie nucléaire et les caractéristiques de l'hétérochromatine, mais ne modifient pas la régularité de la distribution des chromocentres même si la distance à la frontière du noyau est affectée. La généricité du cadre proposé pour analyser les distributions d'objets dans des domaines 3D finis et la possibilité d'ajouter de nouveaux modèles et descripteurs spatiaux devrait permettre d'analyser des organisations spatiales au sein de différents systèmes biologiques et à différentes échelles. / Eukaryotic cell nuclei contain distinct functionally or structurally defined compartments at multiple scale that present a highly ordered spatial arrangement. Several studies in plants and animals have pointed out to links between nuclear organization and genome functions. A key challenge is to identify rules according to which nuclear compartments are organized in space and to describe how these rules may vary according to physiological or experimental conditions. Spatial statistics have been rarely used for this purpose, and were generally limited to the evaluation of complete spatial randomness. In this Thesis, we develop a spatial statistical approach, which combines cytology, image analysis and spatial modeling to better understand spatial configurations inside the nucleus. Our first contribution is a methodological framework that allows to test models of spatial organization at the population level. Several spatial models have been developed and implemented, including randomness, orbital randomness, maximum regularity, territorial randomness or orbital territorial randomness of biological objects within finite 3D domains of arbitrary shape. New spatial descriptors, in combination with classical ones, are used to compare observed patterns to expected configurations under the tested models. An unbiased version of a previously published statistical test is proposed to evaluate the goodness-of-fit of spatial models over populations of observed patterns. In the second part of this Thesis, we investigate the properties of the proposed approach using simulated and real data. The robustness of the proposed approach to segmentation errors and the reliability of the spatial evaluations are examined. Besides, the basis for a method to compare spatial distributions between different experimental groups is proposed. In the last part of this work, the proposed approach is applied on A. thaliana leaf cell nuclei images to analyze the spatial distribution of chromocenters, which are dynamic and plastic heterochromatic compartments that have an important structural role in the genome. A first application was to analyze isolated and cryo-section nuclei from wild type plants. We show that chromocenters present a highly regular distribution, confirming previously published results. Using new spatial statistical descriptors, we then demonstrate objectively and quantitatively, for the first time, that chromocenters exhibit a preferentially peripheral localization. Employing a new spatial model, we then reject the hypothesis that the regular organization is explained solely by the peripheral positioning. We further demonstrate that chromocenters organization displays a close-to-maximum spatial regularity at the global scale, but not at the local one. Lastly, we use simulations to examine a model according to which chromocenters positioning is constrained by chromosome territories and by interactions with the nuclear boundary. The second application was to elucidate whether chromocenters distribution could be altered under different mutations. We analyze nuclei data from crwn and kaku mutants, which are known to affect nuclear morphology. The results suggest that these mutations impact on nuclear morphology and on heterochromatin features but do not alter the regularity of chromocenters distribution even when the relative distance to the border is affected. The genericity of the proposed framework to analyze object distributions in finite 3D domains and its expandability to add more spatial models and spatial descriptors should be of interest to decipher spatial organizations within biological systems at various scales.

Statistiques spatiales

Processus pontuels

Imagerie biologique 3D

Architecture nucléaire

Hétérochromatine constitutive

A. thaliana

Statistical spatial analysis

Point processes

3D biological imaging

Nuclear architecture

Constitutive heterochromatin

A. thaliana

BMI1 mediated heterochromatin compaction represses G-quadruplex formation in Alzheimer's disease

Hanna, Roy

09 1900

La maladie d'Alzheimer (MA) est la démence la plus importante dans le monde développé. Cette maladie neurodégénérative rend de plus en plus difficile la capacité d'accomplir les tâches quotidiennes de routine, elle peut également faire oublier les mots aux patients, les désorienter dans le temps et l'espace, et à des stades avancés entraîne une perte de mémoire. Malheureusement, la MA est considérée comme le prochain grand défi pour la santé publique de la plupart des pays, le nombre de cas devant doubler au cours des 20 prochaines années en raison du vieillissement de la population. Cette augmentation du nombre de patients s'accompagne d'une augmentation des besoins de financement et de personnel de santé afin de répondre aux demandes et aux besoins de ces patients. La MA peut être divisée en deux entités distinctes: une maladie héréditaire bien définie et bien comprise qui représente jusqu'à 5% de tous les cas de MA appelés maladie d'Alzheimer familiale, et une maladie moins définie appelée maladie d'Alzheimer sporadique. Le facteur de risque le plus défini pour la MA est l'âge, mais récemment, il a été démontré que le cerveau des patients atteints de MA avait un niveau réduit de BMI1 et que la suppression de BMI1 dans les neurones humains ou chez la souris déclenche les caractéristiques de cette maladie. Alors que BMI1 était connu pour être important dans les stades de développement, nous rapportons ici qu'il est crucial dans les cellules adultes pour maintenir la compaction de la chromatine et l’inhibition de la transcription des séquences répétitives. De plus, ces deux fonctions de BMI1 empêchent l'ADN d'acquérir une conformation G4. Cette conformation peut entraîner une instabilité du génome, une augmentation des dommages à l'ADN et une altération de l'expression des gènes, mais surtout, nous avons montré que dans les neurones corticaux, les structures G4 peuvent influencer l'épissage alternatif de divers gènes, notamment APP. Ces résultats apportent un éclairage nouveau sur l'origine de la maladie et l'importance de BMI1 et de la structure secondaire de l'ADN dans le cadre de la MA. / Alzheimer's disease is the most prominent dementia in the developed world. This neurodegenerative disease renders the ability to do the routine daily tasks more and more difficult; it can also cause patients to forget words, be disoriented in time and space, leading to a memory loss. Unfortunately, AD is considered the next big challenge for most country’s public health, with the number of cases thought to be doubling within the next 20 years due to the aging of the population. This increase in the number of patients comes with an increase in the need for funding and for healthcare personnel to meet the demands and the requirements of these patients. AD is divided into two separate entities: a well-defined and understood hereditary disease that makes up to 5% of all AD cases called familial Alzheimer disease, and a less defined one called sporadic Alzheimer disease. sAD most defined risk factor is age, but recently it was shown that brains of sAD patients had a reduced level of BMI1 and that the knockdown of BMI1 in human neurons or mice triggers the hallmarks of this disease. While BMI1 was known to be important in the developmental stages, we report here that it is crucial in adult cells to maintain the compaction of the chromatin and the silencing of the repetitive sequences. Furthermore, these two functions of BMI1 prevent the DNA from acquiring a G4 conformation. This conformation can lead to genome instability, increased DNA damage, and altered gene expression. However, most importantly, we showed that in cortical neurons, G4 structures could influence the alternative splicing of various genes, notably APP. These results shed new light on the origin of AD, and the importance of BMI1 and the secondary structure of the DNA in its context.

BMI1

G-Quadruplex

maladie d’Alzheimer

polycombes

séquences LINE

hétérochromatine

instabilité génomique

G4

Alzheimer’s disease

polycomb

LINE sequences

heterochromatin

genome instability

Evoluce karyotypů a určování pohlaví u leguánů (Squamata: Pleurodonta) / Evolution of karyotype and sex determination in iguanas (Squamata: Pleurodonta)

Altmanová, Marie

January 2013

Squamate reptiles in general possess an unusual variability in karyotype and sex determining mechanisms. However, in these two aspects, iguanas (Pleurodonts) are considered as a relatively conservative group of lizards. So far only genotypic sex determination with male heterogamety has been detected in this lineage. However, the sex chromosomes have not been revealed in many species by classical cytogenetics, probably due to their homomorphy. Significant variability in karyotype was observed only in the species-rich genera Anolis, Sceloporus and Liolaemus. The aim of this thesis was to investigate the genome of available species from the main iguanid lineages using classical and molecular cytogenetic methods. As well as finding the karyotype characteristics, which may represent synapomorphies of main iguanid lineages, the other aim was to try to identify sex chromosomes. This study confirmed previously published karyotypes of 13 species and established new descriptions of karyotype for eight species. The chromosomes of all studied specimens were examined by methods of classical and molecular cytogenetics, 21 species covering eight iguanid families were analysed in this thesis. The majority of studied species shared the apparently ancestral karyotype of the group, with diploid chromosome number...

Évaluation, à partir de modélisations nanodosimétriques, de l'influence de la compaction de la chromatine sur les effets radio-induits précoces et extension aux effets tardifs (réparation des dommages à l’ADN et mort cellulaire). / Evaluation, from nanodosimetric modeling, of the influence of chromatin compaction on early radiation-induced effects and extension to late effects (DNA damage repair and cell death).

Tang, Nicolas

02 October 2019

Ce travail de thèse s'inscrit dans le cadre d'une recherche fondamentale visant à améliorer la compréhension des mécanismes d'interaction des rayonnements ionisants avec la matière biologique en s’intéressant à la prédiction par simulations numériques des dommages précoces radio-induits à l’ADN. Dans un premier temps, une étude sur le rôle des différents niveaux de compaction de la chromatine (hétérochromatine et euchromatine) dans l’induction de ces premiers effets, à savoir les cassures de brins de l’ADN, est proposée. De nouveaux modèles géométriques réalistes de noyaux cellulaires intégrant la compaction de la chromatine ont donc été créés et utilisés dans une chaîne de calcul, basée sur le code Monte Carlo ouvert et généraliste Geant4 et son extension Geant4-DNA, permettant de simuler les étapes physique, physico-chimique et chimique menant aux cassures de brin. Les développements effectués dans cette thèse ont également permis d’étudier l’impact de plusieurs types de rayonnement (protons, alphas, photons) sur les dommages radio-induits. Les différents résultats ont été confrontés à des données expérimentales et en particulier à celles obtenues par l’équipe de radiobiologistes de l’IRSN. Enfin, une étude portant sur les effets plus tardifs comme la réparation de l’ADN et la mort cellulaire a été réalisée par l’utilisation conjointe de la chaîne de calcul et de certains modèles paramétriques issus de la littérature. Ainsi, les résultats obtenus dans cette thèse ont permis d’acquérir de nouvelles connaissances et de développer des outils de calcul qui seront bientôt disponibles en accès libre à la communauté scientifique afin de prédire des effets biologiques de plusieurs types de rayonnement dans la perspective d’améliorer les modèles de risque. / This thesis work is part of a fundamental research aimed at improving the understanding of the mechanisms of interaction of ionizing radiation with biological matter by focusing on the prediction of early radiation-induced DNA damage by numerical simulations. As a first step, a study on the role of the different levels of chromatin compaction (heterochromatin and euchromatin) in the induction of these early effects, namely DNA strand breaks, is proposed. New realistic geometric models of cell nuclei integrating chromatin compaction have therefore been created and used in a calculation chain, based on the open source and general purpose Monte Carlo code Geant4 and its extension Geant4-DNA, to simulate the physical, physico-chemical and chemical stages leading to strand breaks. Developments in this thesis have also allowed studying the impact of several types of radiation (protons, alphas, photons) on radiation-induced damage. The various results were compared with experimental data and in particular those obtained by the IRSN team of radiobiologists. Finally, a study on later effects such as DNA repair and cell death was carried out using both the calculation chain and some parametric models from the literature. Thus, the results obtained in this thesis have made it possible to acquire new knowledge and to develop calculation tools that will soon be delivered in free access to the scientific community in order to predict the biological effects of several types of radiation with the aim of improving risk models.

Geant4/Geant4-DNA

Hétérochromatine

Euchromatine

Dommages à l'ADN

Réparation de l'ADN

Survie cellulaire

Geant4/Geant4-DNA

Heterochromatin

Euchromatin

DNA damage

DNA repair

Cell survival

The Shape of Silence: The Solution-State Conformation of Sir Heterochromatin: A Dissertation

Swygert, Sarah G.

20 August 2015

Heterochromatin is a silenced chromatin region essential for maintaining genomic stability in eukaryotes and for driving developmental processes in higher organisms. A hallmark of heterochromatin is the presence of specialized architectural proteins that alter chromatin structure to inhibit transcription and recombination. Although it is generally assumed that heterochromatin is highly condensed, surprisingly little is known about the structure of heterochromatin or its dynamics in solution. In budding yeast, heterochromatin assembly at telomeres and the HM silent mating type loci requires the Sir proteins: Sir3, believed to be the major structural component of SIR heterochromatin, and the Sir2/4 complex, responsible for SIR recruitment to silencing regions and deacetylation of lysine 16 of the histone H4 tail, a mark associated with active chromatin. A combination of sedimentation velocity, atomic force microscopy, and nucleosomal array capture was used to characterize the stoichiometry and conformation of SIR nucleosomal arrays. The results indicate that Sir3 interacts with nucleosomal arrays with a stoichiometry of two Sir3 monomers per nucleosome, and that Sir2/4 may additionally bind at a ratio of one per nucleosome. Despite Sir3’s ability to repress transcription in vivo and homologous recombination in vitro in the absence of Sir2/4, Sir3 fibers were found to be significantly less compact than canonical magnesium-induced 30 nanometer fibers. However, heterochromatin fibers composed of all three Sir proteins did adopt a more condensed, globular structure. These results suggest that heterochromatic silencing is mediated both by the creation of more stable nucleosomes and by the steric exclusion of external factors.

Chromatin

Chromatin Assembly and Disassembly

Heterochromatin

Saccharomyces cerevisiae

Silent Information Regulator Proteins

Dissertations, UMMS

Biochemistry

Genetics and Genomics

Structural Biology

Recombinational Repair of a Chromosomal DNA Double Strand Break: A Dissertation

Sinha, Manisha

16 March 2009

Repairing a chromosomal DNA double strand break is essential for survival and maintenance of genomic integrity of a eukaryotic organism. The eukaryotic cell has therefore evolved intricate mechanisms to counteract all sorts of genomic insults in the context of chromatin structure. Modulating chromatin structure has been crucial and integral in regulating a number of conserved repair processes along with other fundamental genomic processes like replication and transcription. The work in this dissertation has focused on understanding the role of chromatin remodeling enzymes in the repair of a chromosomal DNA double strand break by homologous recombination. This has been approached by recapitulating the biochemical formation of recombination intermediates on chromatin in vitro. In this study, we have demonstrated that the mere packaging of DNA into nucleosomal structure does not present a barrier for successful capture of homologous DNA sequences, a central step of the biochemical pathway of recombinational repair. It is only the assembly of heterochromatin-like more complex nucleo-protein structure that presents additional constraints to this key step. And, this additional constraint can be overcome by the activities of ATP-dependent chromatin remodeling enzymes. These findings have great implications for our perception of the mechanism of the recombinational repair process of a chromosomal DNA double strand break within the eukaryotic genome.

DNA Repair

Recombination

Genetic

Nucleosomes

Rad51 Recombinase

Saccharomyces cerevisiae Proteins

Chromatin Assembly and Disassembly

Heterochromatin

Amino Acids, Peptides, and Proteins

Cells

Enzymes and Coenzymes

Fungi

Genetic Phenomena

ATP-Dependent Heterochromatin Remodeling: A Dissertation

Manning, Benjamin J.

11 September 2015

Eukaryotic DNA is incorporated into the nucleoprotein structure of chromatin. This structure is essential for the proper storage, maintenance, regulation, and function of the genomes’ constituent genes and genomic sequences. Importantly, cells generate discrete types of chromatin that impart distinct properties on genomic loci; euchromatin is an open and active compartment of the genome, and heterochromatin is a restricted and inactive compartment. Heterochromatin serves many purposes in vivo, from heritably silencing key gene loci during embryonic development, to preventing aberrant DNA repeat recombination. Despite this generally repressive role, the DNA contained within heterochromatin must still be repaired and replicated, creating a need for regulated dynamic access into silent heterochromatin. In this work, we discover and characterize activities that the ATP-dependent chromatin remodeling enzyme SWI/SNF uses to disrupt repressive heterochromatin structure. First, we find two specific physical interactions between the SWI/SNF core subunit Swi2p and the heterochromatin structural protein Sir3p. We find that disrupting these physical interactions results in a SWI/SNF complex that can hydrolyze ATP and slide nucleosomes like normal, but is defective in its ability to evict Sir3p off of heterochromatin. In vivo, we find that this Sir3p eviction activity is required for proper DNA replication, and for establishment of silent chromatin, but not for SWI/SNF’s traditional roles in transcription. These data establish new roles for ATP-dependent chromatin remodeling in regulating heterochromatin. Second, we discover that SWI/SNF can disrupt heterochromatin structures that contain all three Sir proteins: Sir2p, Sir3p and Sir4p. This new disruption activity requires nucleosomal contacts that are essential for silent chromatin formation in vivo. We find that SWI/SNF evicts all three heterochromatin proteins off of chromatin. Surprisingly, we also find that the presence of Sir2p and Sir4p on chromatin stimulates SWI/SNF to evict histone proteins H2A and H2B from nucleosomes. Apart from discovering a new potential mechanism of heterochromatin dynamics, these data also establish a new paradigm of chromatin remodeling enzyme regulation by nonhistone proteins present on the substrate.

Chromatin

Chromatin Assembly and Disassembly

Heterochromatin

Non-Histone Chromosomal Proteins

Transcription Factors

Dissertations, UMMS

Chromosomal Proteins, Non-Histone

Biochemistry

Genomics

Molecular Biology

Molecular Genetics

Structural Biology

Higher-Order Unfolding of Peri/Centric Satellite Heterochromatin is an Early and Consistent Event in Cell Senescence: A Dissertation

Swanson, Eric C.

18 December 2014

Cellular senescence is thought to play an essential role in many biological functions including tumor suppression and organismal aging. Senescent cells, which are permanently removed from the cell cycle, can be found both in vivo in many different tissue types and in vitro within cultures of non-immortalized cells. Despite their inability to proliferate, these cells persist and remain metabolically active for indefinite periods of time. This physiologic process occurs in response to a variety of cellular insults including oxidative stress, shortened telomeres, constitutive oncogene expression, and DNA damage, and can be initiated by upregulation of one of the two known senescent pathways, involving p16/Rb or p53/p21. The senescent cell phenotype is also characterized by changes to cell and nuclear morphology and to the secretory profile of the cell. Related to changes in nuclear morphology, epigenetic modifications to the packaging of DNA are thought to be key to the initiation and maintenance of the senescence program. While a large number of earlier studies focused on the findings that senescent cells gain regions of condensed heterochromatin, often in the form of Senescent Associated Heterochromatin Foci (SAHF), this thesis work shows that there is a marked loss of heterochromatin in the peri/centromeric regions of the genome. In fact, both α-satellite and satellite II sequences across the genome distend in a striking and unanticipated fashion; this can be readily visualized by fluorescence in situ hybridization (FISH) as their structure changes from a condensed spot to highly elongated and fine thread-like signals. We have termed this exceptional decondensation of constitutive heterochromatin Senescence Associated Distension of Satellites (SADS). Importantly, a series of experiments shows that SADS is both a consistent and an early event in the cell senescence process, which occurs as a result of every senescence induction method examined. We also observed that this distension was characteristic of both human and murine cells and in vivo in human benign Prostatic Intraepithelial Neoplasia (PIN) tissue. Furthermore, unlike SAHF formation, SADS can occur due to the activation of either of the two senescence pathways, p16/Rb or p53/p21. Additionally, the cytological dimensions of the thread-like satellite signals indicates that SADS represents “unraveling” of DNA on an unprecedented scale. Thus, it was surprising that this event was not facilitated by changes to several canonical histone modifications associated with condensed heterochromatin, namely H3K9Me3, H3K27Me3, or H3K4Me3, nor is it caused by loss of DNA methylation. Consequently, we believe that this marked distension of satellite DNA is due to changes in higher-order folding of the chromatin fiber. This is important for understanding fundamental events in the cell senescence process, but also provides a unique system for study of chromatin packaging that may provide new insights into the organization of DNA well beyond nucleosome packaging and the ten nanometer fiber. In fact, initial super resolution images of SADS suggest that the satellite sequences may be organized into domains or “globules”. Hence, we suggest that the changes to satellite sequence packaging may be facilitated by changes to higher-order nuclear structural proteins, such as LaminB1, which is reduced in senescent cells. Finally, this work provides analysis of the literature and preliminary experiments to consider the possibility that there are increased levels of cell senescence in Down syndrome (trisomy 21) cells. As individuals with Down syndrome (DS) experience many manifestations of premature aging (including early-onset Alzheimer’s Disease), have a resistance to solid tumor formation, are more susceptible to oxidative stress, and are trisomic for several genes implicated in causing senescence, our analysis provides plausibility for the hypothesis that accelerated rates of senescence may play a significant role in DS physiology. We also provide results of preliminary studies and outline the next steps for experimentation, using DS fibroblasts and a unique genetically engineered DS iPS cell system. As a final note, the quantification of cell senescence in trisomic versus disomic cells for these experiments relies substantially on the new single-cell marker of senescence discovered and established by this theses work, the Senescence-Associated Distension of Satellites.

Cell Aging

Chromatin

Heterochromatin

Satellite DNA

Down Syndrome

Genetic Epigenesis

Protein Unfolding

Dissertations, UMMS

DNA, Satellite

Epigenesis, Genetic

Cell and Developmental Biology

Cell Biology

Cellular and Molecular Physiology

Genetics and Genomics

CAF-1 p150 and Ki-67 Regulate Nuclear Structure Throughout the Human Cell Cycle

Matheson, Timothy D.

09 January 2017

The three-dimensional organization of the human genome is non-random in interphase cells. Heterochromatin is highly clustered at the nuclear periphery, adjacent to nucleoli, and near centromeres. These localizations are reshuffled during mitosis when the chromosomes are condensed, nucleoli disassembled, and the nuclear envelope broken down. After cytokinesis, heterochromatin is re-localized to the domains described above. However, the mechanisms by which this localization is coordinated are not well understood. This dissertation will present evidence showing that both CAF-1 p150 and Ki-67 regulate nuclear structure throughout the human cell cycle. Chromatin Assembly Factor 1 (CAF-1) is a highly conserved three-subunit protein complex which deposits histones (H3/H4)2 heterotetramers onto replicating DNA during S-phase of the cell cycle. The N-terminal domain of the largest subunit of CAF-1 (p150N) is dispensable for histone deposition, and instead regulates the localization of specific loci (Nucleolar-Associated Domains, or “NADs”) and several proteins to the nucleolus during interphase. One of the proteins regulated by p150N is Ki-67, a protein widely used as a clinical marker of cellular proliferation. Depletion of Ki-67 decreases the association of NADs to the nucleolus in a manner similar to that of p150. Ki-67 is also a fundamental component of the perichromosomal layer (PCL), a sheath of proteins that surrounds all condensed chromosomes during mitosis. A subset of p150 localizes to the PCL during mitosis, and depletion of p150 disrupts Ki-67 localization to the PCL. This activity was mapped to the Sumoylation Interacting Motif (SIM) within p150N, which is also required for the localization of NADs and Ki-67 to the nucleolus during interphase. Together, these studies indicate that p150N coordinates the three-dimensional arrangement of both interphase and mitotic chromosomes via Ki-67.

CAF-1 p150

Ki-67

Nuclear Structure

Genome Organization

Heterochromatin

Nucleolus

NADs

Perinucleolar Region (PNR)

Mitosis

Chromosome Biology

Perichromosomal Layer (PCL)

Cell Biology