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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
261

Mitotic Dynamics of Normally and Mis-attached Chromosomes and Post-mitotic Behavior of Missegregated Chromosomes

He, Bin 01 June 2015 (has links)
Equal segregation of the replicated genomic content to the two daughter cells is the major task of mitotic cells. The segregation is controlled by a complex system in the cell and relies mainly on the interaction between microtubules (MTs) of the mitotic spindle and kinetochores (KTs), specialized protein structures that assemble on each chromatid of each mitotic chromosome. By combining computational modeling and quantitative light microscopy, we established a quantitative model of the forces and regulators controlling metaphase chromosome movement in the mammalian cell line derived from Potorous tridactylis kidney epithelial cells (PtK1) (Chapter 2). This model can explain key features of metaphase chromosome dynamics and related chromosome structural changes experimentally observed. Moreover, the model made predictions, which we tested experimentally, on how changes in spindle dynamics affect certain aspects of chromosome structure. This quantitative model was next used to study the metaphase dynamics of chromosomes with erroneous KT-MT attachments (Chapter 3). Once again, the model predictions were tested experimentally and showed that erroneous KT-MT attachment alters the dynamics not only of the mis-attached KT, but also of its sister KT. Even more strikingly, experimental data showed that the presence of a single mis-attached KT could perturb the dynamics of all other, normally attached, KTs in anaphase. Chapter 3 also describe how MT poleward flux ensures correct KT-MT attachment and correct chromosome segregation. Indeed, reduced flux is associated with an increase in merotelically attached anaphase lagging chromosomes (LCs). These LCs form micronuclei (MNi) upon mitotic exit. The final effort of this work focused on the fate of MNi and micronuclated (MNed) cells (Chapter 4). Experimental observations showed that most of the chromosomes in MNi missegregated at the cell division following MN formation and that frequently the chromatin in the MN displayed delayed condensation. This work, thus, established a direct link between LCs and aneuploidy through the MN cell cycle. / Ph. D.
262

Cytosystematics of Gerbils

Knight, Liezel Iris 03 1900 (has links)
Thesis (MSc)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: The objectives of this research were to: (1) accurately identify chromosome homology, (2) identify chromosome rearrangements leading to diploid number variation and chromosome evolution to formulate the ancestral gerbil karyotype and distinguish homoplasy from hemiplasy, and (3) construct a phylogeny using chromosomal characters based on G-banding and fluorescence in situ hybridization (FISH) of ten gerbil species representing five genera (Gerbilliscus, Desmodillus, Psammomys, Meriones, Taterillus), with probes derived from flow-sorted chromosomes of G. paeba (GPA, 2n = 36), and polarised with the murid outgroup, Micaelamys namaquensis. All paints successfully hybridized to all ingroup and outgroup taxa. Three of the 19 G. paeba painting probes (GPA 7, 9 and X [including the X; autosome translocation in T. pygargus]) were conserved as whole chromosomes, and 16 were rearranged (GPA 1-6, 8, 10-17). Chromosome painting correctly identified the homology of the heterochromatic GPA 7, which was conserved as whole chromosomes in all gerbils. Thirteen previously misidentified G-band homologies were correctly identified with FISH; one in D. auricularis, and six each in G. kempi and G. gambianus. Homology maps identified 57 syntenic associations and that 19 rearrangements are responsible for diploid number differentiation among species. Parsimony analysis of the two matrices (syntenic association and rearrangements) retrieved a sister-species relationship between G. gambianus and G. kempi, and P. obesus and M. persicus (syntenic associations), an unresolved clade that included D. auricularis, G. gambianus, P. obesus and M. persicus (chromosome rearrangements) and a basal position for T. pygargus. Phylogenies derived from chromosomal data failed to resolve the deeper nodes. Consequently, characters were subsequently mapped on a molecular consensus tree (including a chronogram). This allowed inferences on the rate of chromosome evolution, which indicates that the basal D. auricularis is separated from Gerbilliscus by nine rearrangements (four Robertsonian fusions, five inversions), at a rate of 1.25/Myr. Gerbilliscus species evolved with an average of 10 Robertsonian rearrangements involving GPA 1–6, 8, 10 – 12, of which four are homoplasies (GPA 1-3, 5), one a potential hemiplasy (GPA 5) to southern African taxa, one a synapomorphy to G. paeba and G. tytonis (GPA 6), two synapomorphies in G. kempi and G. gambianus (GPA 11, 12), and three are synapomorphic to Gerbilliscus (GPA 4, 8, 10). Homoplasic characters across the two clades include GPA 3 (T. pygargus, G. paeba and G. tytonis) and GPA 5p-q prox (D. auricularis, P. obesus and M. persicus). Gerbilliscus (excluding G. paeba and G. tytonis) had the slowest chromosome evolutionary rate of < 1/Myr; G. paeba and G. tytonis were slightly faster at 2/Myr. The clade comprised of M. persicus, P. obesus and T. pygargus evolved faster, at a rate of 4/Myr (seven fissions, five fusions, two inversions), 2.3/Myr (seven fissions, two fusions, four inversions) and 16/Myr (eight fusions), respectively, indicating heterogeneity among Gerbillinae: A slow rate in Desmodillus and Gerbilliscus, and a fast evolutionary rate in Psammomys, Meriones and Taterillus. The putative ancestral karyotype was postulated to be 2n = 56, and included five biarmed autosomes and X chromosome, and 22 acrocentrics. This is provisional, since Brachiones, Desmodilliscus, Pachyuromys, Sekeetamys, Gerbillus and Rhombomys were not analysed. / AFRIKAANSE OPSOMMING: Die objektief van hierdie navorsing was om: (1) akkurate chromosoom homologie te identifiseer, (2) chromosoom herranskikkings te identifiseer wat mag lei tot diploide chromosoom getal variasie en chromosoom evolusie ten einde te formuleer die voorouer karyotiepe van “gerbils” sowel as om te onderskei tussen homoplasie en hemiplasie, en (3) die konstruksie van 'n filogenetiese boomstam gebasseer op chromosoom karakters verkry vanaf G-banding en FISH (fluoressensie in situ hibridisasie) van tien “gerbil” spesies wat vyf genera verteenwoordig (Gerbilliscus, Desmodillus, Psammomys, Meriones, Taterillus), deur van geskikte sondes gebruik te maak wat verkry in deur floei-sorteerde chromosome van G. peaba (GPA, 2n = 36), wat gepolariseerd was met die Murid buitegroep, Micealamys namaquensis. Alle chromosoom verwe het suksesvolgehibridiseer aan al die ingroep en buitegroep taxa. Drie van die 19 G.peaba verfwe (GPA 7, 9 and X (including the X; autosome translocation in T. pygargus) was bewaar as heel chromosome, en 16 herrangskik (GPA 1-6, 8, 10-17). Chromosoom verfwing kon suksesvol die homologie van die heterochromatise GPA7 identifiseer wat gekonserveerd was as heel chromosome in al die “gerbils”, wat moontlik aandui die teenwoordigheid van funksionele gene. Dertien voorheen mis geidentifiseerde G-band homologieë was gekorregeer deurmiddel van FISH, een in D. auricularis, en ses elk in G. kempi en G. gambianus. Homologie kaarte het 57 sintesiese assosiasies geidentifiseer en dat 19 herrangskikings verantwoordelik was vir diploied nommer differensiasies tussen spesies. Parsimonie analises van die twee matrikse (sinteniese assosiasies en herrangskikings) wys 'n suster-spesie verwantskap tussen G. gambianus en G. kempi, en P. obesus en M .persicus (sinteniese assosiasies), 'n unopgeloste klade wat D. auricularis, G. gambianus, P. obesus en M. persicus (chromosoom herrangskikkings) opmaak vorm die basale posisie vir Taterillus pygargus. Filogenetise boomstamme verkry vanaf die chromosomale data misluk egter om die dieper nodes op te los. Karakters was daarna geplot op 'n konsensus boom (insluitend 'n chronogram). Dit het dieper insigte toegelaat soos die tempo van chromosoom evolusie, wat aandui dat die basale D. auricularis geskei is vanaf Gerbilliscus met nege herrangskikkings (vier Robertsonian, vyf inversies) teen 'n tempo van 1.25/Mja. Gerbilliscus spesies het verander met 13 herranskikinge (11 saamsmeltings en twee inversies), waarvan vier potensiele homoplasies/hemiplasies (GPA 1-3, 5). Met die uitsluitsel van G. paeba en G. tytonis, het Gerbilliscus die laagste chromosoom evolutionêre tempo van al die “gerbils” < 1 /Mja, G. paeba en G. tytonis was ietwat vinniger met 'n tempo van 2/Mja. The klade wat bestaan uit M. persicus, P. obesus en T. pygargus verander vinniger as Desmodillus en Gerbilliscus, met 'n evolutionêre tempo van 4/Mja (sewe fissies, vyf samesmeltings, twee inversies) en 2.3 Mja (sewe fissies, twee samesmeltings, vier inversies) onderskeidelik, wat grootendeels tandem was. Die karyotiepe van Taterillus pygarus het agt samesmeltings gehad wat predominant tandem was, teen 'n tempo van 16/Mja. Terwyl meeste van die herrangskikinge synapomorfies was, was sommige homoplasties of hemiplasties. Homoplastiese karakters wat gedeel was tussen die twee klades sluit in GPA 3 (in T pygargus en G. paeba en G. tytonis) en GPA 5p-q prox (D. auricularis, P. obesus en M. persicus). GPA 5 was hemiplasties aan alle suider Afrikaanse taxa. Die analise van sinteniese assosiasies en chromosoom herrangskikings was geanaliseer in PAUP, en gepolariseer met die murid Micealamys namaquensis. Taterillus pygarus het 'n basale posisie in beide filogenetiese boomstamme. Die data stel voor dat FISH meer akkurate resultate lewer op chromosoom homologie as die streng gebruik making van banding patrone. Verder het die tempo van chromosoom evolusie gevarieër vanaf stadig (Desmodillus en Gerbilliscus) tot vinnig (Psammomys, Meriones en Taterillus), chromosoom karakters egter was nie sterk genoeg om dieper filogenetiese verwantskappe te ondersoek nie. Die voornemende voorouerlike karytiepe van “gerbils” was hier gehipotiseer as 2n = 56. Drie bevindinge resoneer uit hierdie studie. Eerstens, chromosoom verwing kon chromosoom homologieë wat voorheen deur banding studies mis ge-identifiseer was korrek identifiseer: hierdie sluit in een konflik in D. auricularis, en ses elk vir G. kempi en G. gambianus. Tweedens, die homologie van die heterochromatiese of C-positiewe autosome, GPA 7, was gedemonstreer as bewaar as 'n heel chromosoom as beide heterochromaties en euchromatiese chromosome in alle “gerbils”, wat aandui dat dit functionele gene dra. Derdens gebasseer op simpleisiomorfe wat geidentifiseer was vanaf die homologie kaarte en vergelykbare opleidings, hipotiseer ek dat die voorgestelde voorouer karyotiepe bestaan uit ses autosome (GPA 7, 9, 13, 15, 16, 17) en die X chromosoom, wat onveranderd gebly het tussen alle suider Afrikaanse taxa. Met die uitsluitsel van GPA 7p/7q, was almal behoue as twee-armige chromosome in die voor ouer karyotiepe. In lyn met hierdie is, 21 akrosentries GPA1p,1q, 2p, 2q, 3p, 3q, 4p, 4q, 5p, 5q, 6p, 6q, 8p, 8q, 10q, 10p, 11p,11q, 12p, 12q en 14, wat lei tot die voorgestelde voor ouerlike diploiede chromosoom getal van 2n = 56. Diè karyotiepe word voorgestel as 'n werkende hipotese deels omdat Brachiones, Desmodilliscus, Pachyuromys, Sekeetamys, Gerbillus en Rhombomys nie geanaliseer was nie, en dat die idiale buite groep vir “gerbils” van die Acomyinae nie gebruik was om die karakters te polariseer was nie.
263

COMPARATIVE GENE MAPPING FOR EQUUS PRZEWALSKII AND E. HEMIONUS ONAGER WITH INVESTIGATION OF A HOMOLOGOUS CHROMOSOME POLYMORPHISM IN EQUIDAE

Myka, Jennifer Leigh 01 January 2003 (has links)
The ten extant species in the genus Equus are separated by less than 3.7 million years of evolution. Three lines of investigation were pursued to further characterize equid genome organization. 1.) The Przewalski.s wild horse (E. przewalskii, EPR) has a diploid chromosome number of 2n=66, while the domestic horse (E. caballus, ECA) has 2n=64. A comparative gene map for E. przewalskii was constructed using 46 bacterial artificial chromosome (BAC) probes previously mapped to 38 of 44 E. caballus chromosome arms and ECAX. BAC clones were hybridized to metaphase spreads of E. przewalskii and localized by fluorescent in situ hybridization (FISH). No exceptions to homology between E. przewalskii and E. caballus were identified, except for ECA5, a metacentric chromosome with homology to two acrocentric chromosome pairs, EPR23 and EPR24. 2.) The onager (E. hemionus onager, EHO) has a modal diploid chromosome number 2n=56 and a documented chromosome number polymorphism within its population, resulting in individuals with 2n=55. Construction of a comparative gene map of a 2n=55 onager by FISH using 52 BAC probes previously mapped to 40 of 44 E. caballus chromosome arms and ECAX identified multiple chromosome rearrangements between E. caballus and E. h. onager. 3.) A centric fission (Robertsonian translocation) polymorphism has been documented in 5 of the ten extant equid species, namely, E. h. onager, E. h. kulan, E. kiang, E. africanus somaliensis, and E. quagga burchelli. BAC clones containing equine (E. caballus, ECA) genes SMARCA5 (ECA2q21 homologue to human (HSA) chromosome 4p) and UCHL1 (ECA3q22 homologue to HSA4q) were FISH mapped to metaphase spreads for individuals possessing the chromosome number polymorphism. These probes mapped to a single metacentric chromosome and two unpaired acrocentrics showing that the centric fission polymorphism involves the same homologous chromosome segments in each species and has homology to HSA4. These data suggest the polymorphism is either ancient and conserved within the genus or has occurred recently and independently within each species. Since these species are separated by 1-3 million years of evolution, the persistence of this polymorphism would be remarkable and worthy of further investigations.
264

Functional identification and mapping of a gene that represses telomerase hTERT transcription in prostate cancer cells

Hasan, Rana January 2010 (has links)
Telomerase is present in over 90% of tumour tissues and immortalized cells and is tightly regulated in most normal somatic cells. This suggests the existence of regulatory mechanisms repressing telomerase in normal cells that somehow have become inactive during cancer development. In this project, I used genetic complementation in the form of microcell-mediated monochromosome transfer (MMCT) to search for chromosomes that repress telomerase activity in a prostate cancer cell line, PC-3. Microcell hybrids generated by introducing normal human chromosome 11 strongly inhibited telomerase. Telomerase is regulated primarily at the level of hTERT transcription, its catalytic subunit. Consequently, endogenous hTERT mRNA levels were measured by quantitative RT-PCR in microcell hybrids generated by transferring normal human chromosomes into a PC-3 sub-clone (PC- 3/hTERT) ectopically expressing hTERT cDNA to prevent senescence. Only hybrids constructed with transferred chromosome 11 showed strong transcriptional repression of hTERT. Next, hybrids were constructed by the MMCT transfer of chromosome 11 fragments (X-ray-induced). FISH analysis of clones with completely silenced endogenous hTERT transcription revealed in all cases a discrete chromosome 11 fragment with both the p-arm and q-arm material. A randomly selected hTERT-repressed clone was treated with ganciclovir to select against the HyTK marker and reverse the phenotype. hTERT expression in majority of GCV-resistant clones returned to levels comparable to the parent PC-3/hTERT cells. Collectively, these results provide strong functional evidence for the presence of a powerful telomerase repressor sequence on the fragment. Transfer of one repressive fragment back into mouse A9 cells was then carried out to facilitate fine-structure mapping of its sequence content. High density STS mapping of the fragment in each of the clones revealed a considerable DNA content heterogeneity across the panel. These content maps, together with a further round of MMCT to confirm hTERTrepressive activity, enabled me to identify three candidate regions on the q-arm of chromosome 11 where the repressor sequence may be located: the first region lies between map positions 64.70Mb to 65.42Mb and the other two regions each flank a single positive STS marker at 69.71Mb and 127.32Mb. KAT5, a histone modifying gene has been identified as a potential candidate for repressing hTERT.
265

Investigating the role of nuclear myosin I in the low serum induced repositioning of chromosome 10 in interphase nuclei

Amira, Manelle January 2010 (has links)
The nucleus of mammalian cells has been proven to be highly organised. A recent study on interphase chromosome positioning has identified low serum induced rapid chromosome repositioning. Chromosome 10 initially localised at an intermediate position in normal proliferating human dermal fibroblasts (HDF) was found to relocate to the nuclear periphery 15 minutes after the cells have been incubated in low serum. Whereas chromosome X has remained in a peripheral position. The relocation of chromosome 10 has been shown to be dependant on both actin and myosin functions. In this project we have further investigated the possible role of nuclear myosin I in chromosome 10 repositioning. Using siRNA to block the expression of the nuclear myosin I (NMI) we were able to identify this nuclear myosin as necessary for the rapid repositioning of chromosome 10. Furthermore, using image analysis software we investigated the effect of the NMI knock down on the overall nuclear size and shape. The analysis has revealed that while the nuclear size of normal proliferating cells remained unchanged after the low serum incubation both in cells expressing the NMI and NMI depleted cells, the knock down of the NMI seems to have affected the nuclear shape when the cells were subjected to the serum incubation. On the other hand, the analysis of the chromosome territories area has revealed significant differences in the chromosome territories sizes before and after the low serum incubation, in normal proliferating HDF cells .
266

Rôle de la kinase CDK11p58 dans la protection de la cohésion des chromatides sœurs au centromère / The role of CDK11 p58 in protection of sister chromatid cohesion at centromere

Rakkaa, Tarik 18 December 2013 (has links)
Pour assurer une ségrégation correcte des chromosomes, la cohésion entre les deux chromatides sœurs doit être protégée au centromère contre la vague de phosphorylation du "prophase pathway", depuis la prophase jusqu'à la transition métaphase-anaphase. Cette protection est sous contrôle de la shugoshine (Sgo1), une protéine recrutée au centromère par la thréonine 120 de l'histone H2A phosphorylée par la kinase Bub1. Mon équipe d'accueil a montré que la déplétion de la désacétylase HDAC3 conduit à l'acétylation et la perte de la di-méthylation de la lysine 4 de l'histone 3 au centromère. Cette acétylation forcée de H3K4 est corrélée avec un défaut de la protection de la cohésion et une perte de la localisation des acteurs majeurs de cette protection. L'objectif général de ma thèse est de déterminer le rôle de la protéine kinase CDK11p58 dans la protection de la cohésion. Nous avons pu confirmer que CDK11p58 est nécessaire à la protection de la cohésion centromérique. Des analyses de déplétion de CDK11 montrent une séparation précoce des chromatides sœurs. Cette séparation est corrélée à une perte de la localisation de Bub1, de la phosphorylation de H2A-T120 et de Sgo1 au centromère, mais la diméthylation de H3K4 reste intacte. Grâce à des expériences de FISH en utilisant des sondes qui ciblent la région centromérique du chromosome 11, nous avons démontré que CDK11 protège la cohésion des chromatides sœurs à partir de la mitose mais pas en interphase. En utilisant des lignées exprimant la forme sauvage ou mutée sur le domaine kinase de CDK11p58, nous avons démontré que l'activité kinase de cette protéine est nécessaire pour ce processus de protection. Les résultats de ma thèse documentent le rôle de l'activité kinase de CDK11p58 dans la protection de la cohésion des chromatides sœurs. Ces résultats montrent l'existence d'un substrat de CDK11p58 impliqué dans le recrutement au centromère des facteurs de cohésion qui assurent la protection des cohésines centromériques contre le "prophase pathway". / Sister chromatid cohesion during the early stages of mitosis is essential to ensure faithful chromosome segregation. Sister chromatid cohesion is established in S phase and is maintained at centromeres until the metaphase to anaphase transition. Protection of cohesion at centromeres is under the control of the Bub1 kinase which phosphorylates histone H2A on threonine 120. Phosphorylated H2AT120 recruits the cohesion protection factor shugoshin (Sgo1) at centromeres. We had previously reported that depletion of the HDAC3 deacetylase induces acetylation of histone H3 lysine 4 at the centromere and loss of dimethylation at the same position. Forced acetylation of H3K4 at centromeres correlates with impaired Sgo1 recruitment and loss of sister chromatid separation. Cdk11p58, a member of the p34cdc2 related protein kinase family, is a G2/M specific protein, involved in different cell cycle events such as centrosome maturation, spindle formation or centriole duplication. It has also been reported as being involved in sister chromatid cohesion. Here we report that, upon cdk11p58 depletion, sister chromatids do not prematurely separate until the early stages of mitosis. We confirm that Cdk11p58 depletion induces a loss of Bub1 and Sgo1 from the centromeres and we show that H3K4 dimethylation is not affected by Cdk11p58 depletion. We report that depletion of endogenous Cdk11p58 in a cell line expressing a kinase-dead version of Cdk11p58 do not rescue the premature sister chromatid separation phenotype. Thus, phosphorylation of an unknown susbtrate by Cdk11p58 is necessary to maintain Bub1 at centromeres and our efforts are now directed towards its identification.
267

Lien entre les réarrangements chromosomiques et la structure de la chromatine chez la Drosophile / Linking large scale genome rearrangement to chromatin structure in Drosophila

Pulicani, Sylvain 28 November 2018 (has links)
Entre espèces, les génomes présentent des différences dans leur organisation, que ce soit au niveau du caryotype ou de l'ordre des gènes. Ceci reste vrai même entre espèces relativement proches comme l'humain et la souris, et est du aux réarrangements chromosomiques. Reconstruire l'histoire évolutive d'une lignée revient donc à déterminer des scénarios de réarrangements qui transforment un génome actuel en un autre. Le génome ancestral se trouve alors être l'un des états intermédiaires atteint par l'un de ces scénarios.Les réarrangements chromosomiques sont des évènements biologiques violents pour la cellule. En effet, de nombreux mécanismes moléculaires ont pour fonction de stopper le cycle cellulaire dans le cas où le génome aurait été altéré. De plus, les réarrangements peuvent être à l'origine de phénotypes aberrants, et donc probablement désavantageux pour leur porteur. Au vu de tout cela, il paraît raisonnable de poser l'hypothèse selon laquelle les scénarios de réarrangements sont parcimonieux.Cependant, il est admis que ce seul critère ne permet pas de reconstruire efficacement l'histoire évolutive des génomes. En effet, quelque soit le modèle utilisé pour générer les scénarios, leur nombre est exponentiel en le nombre de réarrangements. Une autre contrainte biologique doit donc être ajoutée. La conservation de la structure spatiale de la chromatine pourrait être un critère manquant essentiel. Il a été montré in vitro que lors d'une cassure double-brin suivie d'une réparation non-homologue, le brin utilisé pour la réparation se situe spatialement proche de la cassure. Notre hypothèse est donc que les points de cassures qui sont proches en 3D ont plus probablement participé à des réarrangements que les autres. Cela est appuyé par des analyses génomiques sur des cellules somatiques et entre espèces. Nommons cette hypothèse: l'hypothèse de localité.Notre approche a été de proposer une méthode pour utiliser l'information structurale afin de prioriser les scénarios de réarrangements. Les données de Hi-C ont été l'information structurale qui nous a permis d'appliquer la méthode aux scénarios entre D. melanogaster et D. yakuba.Ces résultats nous ont ensuite menés à nous demander si la structure de la chromatine ne pouvait pas elle-même évoluer. Elle serait alors susceptible d'être considérée comme un caractère phylogénétique. Cette idée est appuyée par d'autres résultats montrant la conservation de domaines topologiques entre espèces.Cette question ne semble pas avoir été posée auparavant. Elle est pourtant très intéressante car elle permet d'ouvrir tout un champ d'étude. En effet, si la structure de la chromatine porte un signal phylogénétique, alors il devient possible de s'interroger sur les mécanismes en œuvre lors de la sélection, ou sur la possibilité de reconstruire l'état ancestral de cette structure. Par la suite, il serait même possible de comparer l'évolution de la séquence et celle de la structure de la chromatine.Nous avons ainsi défini une distance entre les structures des génomes, basée sur la comparaison des contacts entre loci orthologues. Nous l'avons appliquée à une ensemble de six espèces comprenant l'humain, la souris et quatre drosophiles. Ces résultats confirment la présence d'un signal phylogénétique dans la structure spatiale des génomes. Ils mettent également en lumière l'intérêt de la mise en place de méthodes permettant de comparer efficacement des données de contacts entre espèces. / Different species have different genome organization. Whether it be the karyotype or gene order, these differences are seen even with relatively close species like Human and Mouse. This is caused by the chromosomal rearrangement. Infererence of rearrangement scenarios that transform one present-day species into another can give insight into evolutionary states, the ancestral genome being one of the intermediates of the true scenario.The chromosomal rearrangements are violent biological events for the cell. Indeed, numerous mechanisms are present to stop the cell cycle when the genome sequence is altered. Moreover, rearrangements can be the source of aberrant phenotypes, which are probably unfavorable for the carrier. With all that, it seams reasonable to assume the rearrangement scenarios are parsimonious.However, it is accepted that this criterion alone is not sufficient to efficiently build the evolutionary history of the genomes. Indeed, for whatever model we choose, the number of scenario is exponential in the number of rearrangements. Another biological constraint is needed. The spatial structure of the chromatin could be an essential missing criterion. It has been shown in vitro that when a double-stranded break of the DNA is non-homologously repaired, the strand used for repairing is close in space to the breakpoint. Our hypothesis is that the closer the breakpoints are in space, the more probable they are to participate in a rearrangement. This hold on genomics analysis of somatic cells, and between species. Let's name that hypothesis the locality hypothesis.We proposed a method to use the structural information in order to prioritize the rearrangements scenarios. The Hi-C data were the structural information that allowed us to apply our method to scenarios between D. melanogaster and D. yakuba.This results led us to ask whether the chromatin structure could evolve by itself. Then, it could be used as a phylogenetic mark. This idea is related to previous results showing the conservation of topological domains between species.This question seams to be new, and could open a new line of investigation. If the chromatin structure holds a phylogenetical signal, it becomes possible to ask ourselves about the mechanisms that occur during the selection, or if it is possible for the ancestral state to be inferred. Then, it could even be possible to compare the evolution of the sequence with the one of the chromatin structure.Thus, we defined a distance between genome structures, based on the comparison of contacts between orthologous loci. We applied this distance to a set of six species, including the Human, the Mouse and four Drosophila. This result confirms the presence of a phylogenetic signal in the spatial structure of the genomes. They also showed that we're in need for efficient methods to compare contacts data between species.
268

Caracterização de rearranjos cromossômicos em pacientes com malformações congênitas múltiplas e/ou retardamento mental (MCA/MR) / Characterization of chromosome rearrangements in patients with multiple congenital malformation and/or mental retardation (MCM/MR)

Oliveira, Mariana Angelozzi de 05 May 2008 (has links)
As alterações cromossômicas estruturais associadas a fenótipos clínicos oferecem a oportunidade de identificação e localização de genes cujas mutações possam estar determinando essas patologias, tendo em vista a possibilidade de que esses genes podem ter sido alterados pelas quebras ou ter o número de cópias modificado. Um número cada vez maior de evidências aponta para a participação de certas seqüências do genoma na formação de rearranjos cromossômicos recorrentes e não recorrentes. Este trabalho compreendeu o estudo de duas translocações cromossômicas aparentemente equilibradas e uma duplicação do braço curto do cromossomo 20 em decorrência de mosaicismo materno. O objetivo foi determinar os pontos de quebra por hibridação in situ fluorescente (FISH) e identificar genes candidatos, alterados pelas quebras dos rearranjos e que pudessem explicar o quadro clínico dos portadores. A caracterização das seqüências nos pontos de quebra e a junção desses rearranjos é fundamental para a compreensão dos mecanismos de formação das alterações cromossômicas. A delimitação precisa dos segmentos deletados é necessária para a correlação com o quadro clínico. / Two apparently \"de novo\" balanced translocations and one duplication of the short arm of chromosome 20 were studied. Our aim was to determine the breakpoints by chromosomal analysis through fluorescentin situ hybridization (FISH) and identify candidate genes and how they were involved with the clinical phenotypes of the patients. Patient 1 carried a duplication of the short arm of chromosome 20 (p11.22p13), inherited from the mother that showed normal and dup(20) lymphocytes. The duplication was determined by FISH using BAC and PAC clones, and nine clones were duplicated except one (20p11.21). The patient shared many of the common characteristics of trisomy 20p including delay in motor development, hypertelorism, poor coordination, round face with prominent cheeks, vertebral and dental abnormalities and cranial asymmetry with high and large forehead. She also had learning difficulties, behavioral disorders and pubertal growth spurt at 12 years. As our patient is an example of pure trisomy 20p, the features are of particular importance to delineate the syndrome. Three genes were mapped on the segment that contain the duplication (20p11.2-13), one of these genes is the SSTR4 (Somatostatin receptor 4). The somatostatin is widely distributed throughout the body and is important regulator of endocrine and nervous system function. It is an inhibitor of growth hormone secretion. The second gene is the BMP2 that produce bone morphogenetic proteins and it has a direct function with the nervous system. The third gene is the GHRH that produce proteins connected with the growth hormone. These genes might have been over expressed and thus contributing to the patient\'s clinical features. Patient 2, carried a 46,XY,t(5;14)(q14.1;q31.3)de novo translocation. On chromosome 14 the breakpoint was mapped to a segment contained in BAC RP11-315O17 (14q31.3). On the chromosome 5 the breakpoint was mapped to a segment contained in BAC RP11-30D15 (5q14.1). Although the breakpoint, on the chromosome 14, has been mapped in 14q31.3, our patient shared many of the common characteristics of terminal 14q32 deletion: mental retardation, dolicocephaly, prominent ears, hypertelorism, strabismus, upturned palpebral fissures, highly arched palate, simian crease, severe myopia, coloboma and palpebral ptosis. As mental retardation and ocular abnormalities were the main patient\'s clinical features, we are suggesting that: 1) a region of segment 14q31.3 was deleted. 2) A gene inside this segment (14q31.3) could be responsible for ocular development and 3) a disrupted gene could interfere on the expression of other genes. On chromosome 5 eleven genes were localized and four of them are expressed in nervous system (AP3B1; SCAMP1; BHMT2 e CMYA5). One of these genes might have been disrupted and is contributing to the patient\'s clinical features. Patient 3 was the carrier of a 46,XY,t(1;15)(p13.2;q25.2)de novo translocation. The breakpoint on chromosome 15 was mapped to the segment contained in clone RP11-152F13 (15q25.2). The breakpoint on chromosome 1 was mapped to the segment contained in clone RP5-1037B23 (1p13.2). The genes mapped at the breakpoint regions of chromosome 1 and chromosome 15 are expressed in nervous system and muscles. Our patient shows few clinical features: speech delay, stutter and learning difficulties, probably because one or more of these genes, mapped at the breakpoint region, could be disrupted.
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Investigation of role of chromosomal aberrations in carcinogenesis by undertaking bioinformatic approaches. / CUHK electronic theses & dissertations collection

January 2011 (has links)
Lam, Man Ting. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2011. / Includes bibliographical references (leaves 128-138). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.
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Chorégraphie de ségrégation des deux chromosomes de Vibrio cholerae / Segregation choreography of the two chromosomes of Vibrio cholerae

David, Ariane 05 December 2013 (has links)
L’objectif de cette thèse est de définir la chorégraphie de ségrégation des deux chromosomes circulaires de Vibrio cholerae, c’est à dire le positionnement de l’information génétique au cours de la croissance de la cellule, ainsi que les mécanismes dirigeant ces ségrégations. Il a longtemps été supposé que les bactéries étaient trop petites pour avoir une organisation intra-cellulaire, et le manque de techniques appropriées ne permettait pas d’infirmer cette hypothèse. Or la taille des chromosomes comparée à celle de la bactérie impose une compaction et aujourd’hui, de nouvelles techniques de microscopie et d’analyse génétique permettent d’affirmer que les chromosomes bactériens étudiés jusqu’à maintenant ont tous une organisation et une chorégraphie de ségrégation précises et différentes selon les espèces. Toutes les espèces étudiées à ce jour ont un chromosome circulaire unique : la réplication du chromosome commence à une origine unique bidirectionnelle, les deux fourches de réplication se déplacent le long des deux bras de réplication (ou réplichores) et finissent la réplication au terminus, diamétralement à l’opposée de l’origine de réplication sur la carte du chromosome. Peu d’espèces ont été étudiées, et Vibrio cholerae émerge progressivement comme un nouveau modèle : son génome est réparti sur deux chromosomes, et la chorégraphie de plusieurs chromosomes dans une cellule n’a jamais été décrite. De plus, cette espèce semble être au croisement évolutif entre Caulobacter crescentus et Escherichia coli : Vibrio cholerae a d’une part une morphologie en croissant, des systèmes de partition aux origines et un positionnement de l’origine du chromosome I, semblables à C. crescentus, et d’autre part un système de compaction du terminus et un set de gènes impliqués dans la maintenance du chromosome ayant co-évolué, qu’on ne retrouve que dans peu d’espèces proches d’E. coli. Une autre caractéristique intéressante de V. cholerae est que le chromosome II semble avoir été acquis récemment et n’est donc peut être pas gouverné par les mêmes mécanismes que le chromosome I, comme en témoignent le positionnement de son origine et son terminus, inédits pour des chromosomes bactériens. Parmi les Vibrios (environ 60 espèces principalement retrouvées dans les environnements aquatiques), certaines espèces sont des pathogènes dévastateurs pour les poissons, le corail, les crustacés ou les fruits de mer. Mais la plus documentée est Vibrio cholerae, car elle provoque chez l’Humain une maladie provoquée par l’ingestion d’eau contaminée qui peut être mortelle si le patient n’est pas réhydraté à temps. Bien que facilement traitable, le choléra fait encore de nombreuses victimes dans les pays en développement où les structures de santé et les règles d’hygiène font parfois défaut. Ainsi l’étude de Vibrio cholerae présente un intérêt médical, mais également par extension aux autres Vibrios, un intérêt environnemental non négligeable. / The aim of this thesis is to define the segregation choreography of the two circular chromosomes of Vibrio cholerae, which is the positionning of the genetic information during cell growth, as well as the mecanisms directing those segregations. It was supposed for a long time that bacteria were too small to have a intra-cellular organization and the lack of appropriate tools could not prove this hypothesis wrong. The size of the chromosomes compared to the size of the cell means there has to be a compaction and today, new tools for microscopy and genetic analysis allow us to affirm that all bacterial chromosomes studied so far have an organization and a segregation choreography which are precise and different between specie. Most bacterial specie studied to this day have a unique circular chromosome : the replication of the chromosome starts at a unique and bidirectionnal origin, both replication forks move along the two replication arms (or replichores) and end the replication at the terminus which is diametrically to the opposite of the origin on the chromosome map. A few specie have been studied, and Vibrio cholerae progressively emerges as a new model : its genome is divided between two chromosomes, and the choreography of several chromosomes in a cell has never been described. Moreover, this species seems to be at the crossover between Caulobacter crescentus and Escherichia coli : Vibrio cholerae as on one hand, a crescent shape, partition systems positionned at both origins and a positionning of the chromosome I origin similar to C. crescentus, and on the other hand a compaction system of the terminus and a set of genes involved on the maintenance of chromosomes that one only finds in very few specie closely related to E. coli. An other interesting characteristic of V. cholerae is that the chromosome II seems to have been acquired recently and thus might not be governed by the same mecanisms as the chromosome I, as shown by the positionning of its origin and terminus which are completely new to bacterial chromosomes. Among Vibrios (about 60 species mostly found in aquatic environments), some species are devastating pathogens for fish, coral, crustacean and shellfish. But the most documented one is Vibrio cholerae, because it induces a disease in humans caused by the ingestion of contaminated water, which can be deadly if the patient is not rehydrated on time. Although easily treatable, cholera still makes a lot of victims in developing countries where health structures and basic hygiene sometimes lack dramatically. The study of Vibrio cholerae has a medical interest, but also by extention to other Vibrios, a non-negligible environmental interest.

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