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The role of cyclin D1 in lymphopoiesis / Le rôle de la cycline D1 dans la lymphopoièseChaves Ferreira, Miguel 23 November 2012 (has links)
Les cyclines D jouent un rôle essentiel dans les mécanismes du cycle cellulaire. Cette famille de protéines est composée de trois membres (D1,D2,D3) qui partagent un domaine très homologue de la « cyclin box » (codée par les exons 1-3). Ce domaine est responsable de leur activité redondante dans la phosphorylation de la protéine du rétinoblastome lors de l'association avec les kinases cycline-dépendantes CDK4/6. Parmi les trois cyclines, la cycline Dl, bien que faiblement exprimée dans les lymphocytes, est la cycline la plus impliquée dans les cancers lymphoïdes ou elle aurait une fonction de facteur de transcription indépendante de Cdk. Etant donné qu'après stimulation antigénique, les lymphocytes T et B ont une capacité remarquable de division, essentielle à la génération d’une réponse immunitaire efficace, nous avons porté un intérêt particulier au rôle des cyclines D dans la lymphopoïèse. Pour étudier le rôle de la cycline Dl dans la différenciation des lymphocytes, nous avons utilisé des souris déficientes pour les exons 1,2,3 de la « cycline box » Dl mais conservé les exons 4 et 5. Étonnamment, ces souris présentaient des phénotypes très différents que nous avons subdivisés en quatre groupes. Dans le groupe I, les souris avaient un thymus réduit car la différenciation de la lignée lymphoide est bloquée à un stade très précoce, avec un faible nombre de cellules progénitrices (CLP) dans la moelle osseuse. Dans le thymus, les progéniteurs des thymocytes (ETP) étaient pratiquement absents et les précurseurs CD4CD8CD3 (TN) immatures essentiellement constitués par des cellules CD44*CD25 (TN1) et CD44*CD25+ (TN2) les plus immatures. De plus, les CD4*CD8* (DP) qui donnent naissance aux thymocytes matures CD4+ et CD8+ étaient présents en très faible quantité. Dans la moelle osseuse, on observe un blocage majeur dans la différenciation de la lignée B au stade pré-proB. Dans les ganglions, la forte réduction du nombre de lymphocytes T observée était liée au faible nombre d'ETP et à l’absence du récepteur aux chimiokines CCR7. Dans le groupe II, les souris présentaient une diminution moins sévère des ETP et une atrophie modérée du thymus. La différenciation était bloquée à un stade ultérieur, soit dans la transition des étapes TN3 à TN4. Dans la moelle osseuse, les lymphocytes B ont subi un blocage partiel au stade pré-proB et une réduction des cellules pré-B. Le nombre de CLP est également réduit, mais dans une moindre mesure que dans les souris du groupe I. dans les groupes III et IV, les souris ont une répartition normale des thymocytes mais présentaient une augmentation du compartiment ETP. Alors que les souris du groupe III contenaient un nombre normal de thymocytes, les souris du group IV présentaient une hyperplasie thymique. Par ailleurs, en comparaison avec des souris normales, bien que la différenciation des lymphocytes B soit normale, on observe dans les deux groupes une augmentation des CLP et des progéniteurs hématopoïétlque (LSK). L’implication de la cycline Dl dans la transition de G1 à S nous a conduit à analyser les divisions cellulaires in vivo. De manière surprenante, les souris du groupe I étaient fortement dépourvues de cellules en cycle dans tous les compartiments lymphoïdes, ce qui peut expliquer les blocages de la différenciation lymphoide. Par contre, dans les trois autres groupes, on observe une augmentation du nombre de divisions cellulaires. Ces résultats différents peuvent être dû à l'expression ou l'absence d'une protéine Dl tronquée qui contient cependant les exons 4-5. Alors que ces ARNm tronqués ne sont pas détectables dans les souris de groupe I, on observe des niveaux élevés d'expression dans les autres groupes. De plus, nous avons observé une corrélation entre l'absence d’expression des exons 4-5 et la très faible expression des gènes CCND2 et CCND3, ce qui attribue à cette protéine tronquée un rôle prépondérant dans la régulation des cyclines D et permet d’expliquer l'aplasie profonde et… / D Cyclins play an essential role connecting exogenous stimulation to the intrinsic cell cycle machinery. This family of proteins is composed of three members sharing a highly homologous domain, the cyclin box (coded by exons 1-3), which is responsible for their redundant role in the phosphorylation of the retinoblastoma protein upon association with cydin-dependent kinases Cdk4/6. Both mature T and B-cells have a remarkable division capability after antigen stimulation, essential to the generation of efficient immune responses, raising the interest of D Cyclins in lymphopoiesis. Cyclin Dl, although weakly expressed by lymphocytes, is the D Cyclin most commonly implicated in lymphoid cancers and as having a Cdk-independent transcriptional role. To study the role of Cyclin Dl, we used mice deficient for the Dl cyclin box but sparing exons 4-5. Surprisingly, individual mice have very different phenotypes that we subdivided into four arbitrary groups. Group I mice show the most precocious block in lymphoid lineage differentiation, illustrated by a low cellularity of common lymphoid progenitor cells (CLP). The thymi showed very few CD4*CD8*, double positive (DP) cells, while the CD4 CD8TCR, triple negative (TN) populations were found to be mostly constituted by the early CD44*CD25' (TNI) and few CD44*CD25* (TN2). TNl's early thymocyte progenitors (ETP) were virtually absent. At the B-cell lineage level in the bone marrow (BM) there was a major block in pre-proB differentiation. The number of peripheral T-cells was severely reduced, mainly in LN, since group I T-cells lack CCR7 expression. Group II mice presented moderate thymus atrophy. The block on TN differentiation occurs at a later stage, i.e., in the TN3 to TN4 transition, and the TNI population was characterized by a less severe depletion of the ETP. Group II mice showed a partial pre-proB block and a reduction in pre-B-cells. CLPs were also reduced but to a lesser extent than in group I mice. Group ill and group IV mice appear to have a normal thymocyte population distribution but showed an increase on ETP compartment. Group IV mice displayed thymic hyperplasia while group III mice possessed normal thymus cellularity. B-cell differentiation on both groups appeared to be normal but BM precursors had an increase in both CLP and early haematopoietic progenitor's (LSK) levels as compared with wild type mice. Cyclin Dl involvement in G1 to S transition led us to analyse in vivo division rates. Strikingly, group I mice were virtually devoid of cycling cellsin all lymphoid compartments, explaining why lymphoid lineage cells do not differentiate in these mice. In contrast, in all other groups we observed an increased BrdU incorporation. These contradicting phenotypes correlated with the expression or absence of a truncated Dl protein coded by exons 4-5. The presence of the cyclin Dl truncated mRNA was not found in group I mice but high levels of expression are consistently observed in the remaining groups. In the absence of the Dl truncated protein only trace values of Cyclins D2 and D3 were found, highlighting the role of this protein as a master D cyclin regulator, which further supports the profound aplasia and arrest in lymphoid lineage division on cells that predominantly express Cyclin D2. These results suggest that, while the function of the Dl cyclin box is redundant, the regulatory domain coded by exons 4-5 is fundamental for lymphopoiesis. Full Dl protein was also eliminated by RNA interference both in vitro and in vivo. These experiments reproduced the phenotype of group I mice. We have developed a lentiviral vector with a truncated Dl (exons 4-5) and conditional knockout (KO) mice by floxing exons 4-5 of cyclin Dl. These tools will allow us to show Cyclin Dl Cdk-independent role as a transcription regulator in lymphopoiesis and to attribute this function to exons 4-5. Understanding how exons 4-5 regulate different transcription factors might be a key in…
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The Role of p21 <sup>CIP1/WAF1</sup> and CDK2/Cyclin E in Regulating Centrosome DuplicationHorn, Henning Friedrich 25 January 2006 (has links)
No description available.
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PROSTATIC REGULATION OF THE ANDROGEN RECEPTOR BY CYCLIN D1: FUNCTION AND DYSFUNCTIONBURD, CRAIG J. 13 July 2006 (has links)
No description available.
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Loss of Chk1 Function and Exogenous Expression of Cyclin A1/Cdk2 Results in Apoptosis after the MBT in Early Xenopus laevis EmbryosCarter, Ayesha DonNell 26 May 2005 (has links)
Early Xenopus laevis embryonic cell cycles exemplify rapid, non-pathological cell cycles without checkpoint pathways to arrest cell cycles in response to DNA assaults. There is no transcription or apoptosis during these cell cycles, and they continue unperturbed until the 12th cell cycle, marking a period called the midblastula transition (MBT). At the MBT, the embryo undergoes a period of developmental remodeling: gap phases are acquired, zygotic transcription is initiated, and the maternal mRNAs are degraded. After the MBT, checkpoint pathways can be activated in response to unreplicated DNA, and apoptosis initiates when continued embryonic survival is compromised. These studies examine how cell cycle regulation and apoptotic regulation are related. Specifically, the role of two cell cycle components, Chk1 and cyclin A1/Cdk2, during apoptosis was studied during early development of Xenopus embryos.
Chk1 is a serine/threonine kinase that inhibits the activity of cyclin-dependent kinases (Cdks) in response to unreplicated DNA. In the pre-MBT embryo, Chk1 is present, but inactive. Injection of mRNA encoding dominant-negative Chk1 (DN-Chk1) into single-celled embryos results in the initiation of apoptosis after the MBT. The loss of Chk1 function also results in the initiation of additional rapid rounds of DNA replication after the MBT. These results suggest that Chk1 has a required function for the embryo after the MBT, possibly through the regulation of a cyclin/Cdk complex responsible for the apoptotic checkpoint.
Cyclin A1 is a maternally provided mRNA that is degraded at the MBT. Prior to the MBT, cyclin A1 complexes exclusively with Cdc2 to regulate mitosis. When embryos are treated with ionizing radiation (IR), cyclin A1 activity and protein level persist after the MBT, and cyclin A1 complexes with Cdk2. When treated with aphidicolin, cyclin A1-associated activity and protein level persists. Injection of cyclin A1/Cdk2 into single-cell embryos results in apoptosis after the MBT; however, inhibition of cyclin A1 expression does not abrogate apoptosis. Therefore, cyclin A1/Cdk2 activity is sufficient, but not required, for the initiation of apoptosis in the early Xenopus embryo. These studies show that Chk1 and cyclin A1/Cdk2 have roles in regulating apoptosis in the post-MBT embryo. / Ph. D.
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The Dynamics of the Unreplicated DNA Checkpoint in Xenopus laevis Embryos and ExtractsAdjerid, Nassiba 23 April 2008 (has links)
When unreplicated or damaged DNA is present, cell cycle checkpoint pathways cause cell cycle arrest by inhibiting cyclin-dependent kinases (Cdks). In Xenopus laevis, early embryonic development consists of twelve rapid cleavage cycles between DNA replication (S) and mitosis (M) without checkpoints or gap phases. However, checkpoints are engaged in Xenopus once the embryo reaches the midblastula transition (MBT). At this point, the embryo initiates transcription, acquires gap phases between S and M phases, and establishes a functional apoptotic program. During the cell cycle, there are two main checkpoints that regulate entrance into S and M phases. The focus of this study is the role of protein kinase Chk1 and the phosphatase Cdc25A in the DNA replication checkpoint. In the absence of active Chk1, Cdc25A activates cyclin dependent kinases (Cdks) allowing the cell to progress into S or M phase. Chk1 regulates cell cycle arrest in the presence of unreplicated DNA in somatic cells by phosphorylating Cdc25A and leading to its degradation. Chk1 is also transiently activated at the MBT in Xenopus laevis embryos, even when there is no block to DNA replication or damaged DNA. One goal of this work is to understand the developmental role and regulation of checkpoint signaling pathways due to its monitoring of DNA integrity within the cell.
Chk1 plays a critical but not fully understood role in cell cycle remodeling and early embryonic development. In order to understand the function and regulation of Chk1 in checkpoints, the features of the MBT that activate Chk1 must be identified. The activation of Chk1 by two time-dependent events in the cell cycle, the critical nuclear to cytoplasmic (N/C) ratio and the cyclin E/Cdk2 maternal timer are explored in this study. Embryos treated with aphidicolin, resulting in a halted replication fork and therefore a reduced DNA concentration, were tested for Chk1 activation and Cdc25A degradation. Chk1 and Cdc25A were observed to undergo activation and degradation, respectively, in embryos with a reduced DNA concentration. In addition, embryos were injected with Δ34Xic cyclin E/Cdk2 inhibitor, in order to disturb the maternal timer and tested for Chk1 activation and Cdc25A degradation. Both Chk1 and Cdc25A were unaffected by the disruption of the cyclin E/Cdk2 maternal time in the embryo. Therefore, the N/C ratio and the cyclin E/Cdk2 maternal timer do not affect Chk1 activation and therefore Cdc25A degradation.
Another means of characterizing the unreplicated DNA checkpoint is through the use of mathematical modeling of the checkpoint-signaling cascade of the cell cycle. Mathematical modeling is the translating of biological pathways into mathematical equations that can simulate interactions without performing laboratory experiments. The Novák-Tyson checkpoint model made important predictions of hysteresis and bistability in the frog egg checkpoint model, predictions that were later confirmed experimentally. The model was updated with additional interactions, such as those including Myt1, a second inhibitor kinase, and lamin proteins, which become phosphorylated at the onset of nuclear envelope breakdown (NEB) at entry into mitosis. Also, experimental data was fit into the model while maintaining hysteresis and bistability. Therefore, the unreplicated DNA checkpoint model was updated with new interactions and experimental data while still preserving previously identified dynamic characteristics of the system.
As described, Cdc25A regulation is dynamic in the embryo. The checkpoint original model represents the activity of Cdc25 phosphatase on the mitosis promoting factor (MPF) that leads the cell into mitosis. In the checkpoint model, Cdc25C is the phosphatase activating MPF. However, the model does not include Cdc25A, which is an integral part of the checkpoint-signaling pathway due to its role in activating the cyclin/Cdk complex allowing entry into S and possibly M phase. Experimental studies were performed in which Cdc25A levels were reduced in embryos and extracts using Cdc25A morpholinos. Embryos and extracts showed delayed cell cycle and mitotic entry, demonstrating the importance of Cdc25A plays in the cell cycle. Based upon experimental data, the mathematical model of the DNA replication checkpoint was expanded to include Cdc25A. The expanded model should more accurately demonstrate how checkpoints affect the core cell cycle machinery. Cdc25A was incorporated into the model by gathering experimental data and designing a signaling cascade, which was translated into differential equations. The updated model was then used to simulate the effect of synthesis and degradation rates of Cdc25A on the entry into mitosis dynamics. Therefore, using mathematical modeling and experimental design, we can further understand the role that Cdc25A plays in cell cycle progression during development.
Understanding the regulation of Chk1 activity at the MBT and the role of Cdc25A in checkpoint signaling will help us further characterize the dynamics of early embryonic development. The use of mathematical modeling and experimental tools both contribute to further our understanding of controls of the checkpoint signaling pathway and therefore leading us one step closer to truly being able to model a pathway and make predictions as to the behavior of the cell during early embryonic development. / Ph. D.
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Temporal organization of the budding yeast cell cycle: general principles and detailed simulationsCalzone, Laurence 09 December 2003 (has links)
The budding yeast cell cycle has attracted attention from many experimentalists over the years for its simplicity and amenability to genetic manipulation. Moreover, the regulatory components described in budding yeast, Saccharomyces cerevisiae, are conserved in higher eukaryotes. The budding yeast cell cycle is governed by a complex network of chemical reactions controlling the activity of the cyclin-dependent kinases (CDKs), proteins that drive the major events of the cell cycle. The presence of these proteins is required for the transition from G1 to S phase (Start) whereas their absence permits the transition from S/M to G1 phase (Finish). The cell cycle of budding yeast is based on alternation between these two states. To test the accuracy of this theory against experiments, we built a hypothetical molecular mechanism of the budding yeast cell cycle and transcribed it into differential equations. With a proper choice of kinetic parameters, the differential equations reproduce the main events of the cell cycle such as: the synthesis of cyclins (Cln1,2; Cln3; Clb1,2; Clb5,6) by their transcription factors (SBF, Mcm1, MBF); their association with stoichiometric inhibitors (Sic1, Cdc6); their degradation by SCF and adaptors of the APC (Cdc20, Cdh1). The emphasis was put on mechanisms responsible for the release of Cdc14 from the RENT complex, Cdc14 being a major player in exit from mitosis. Simulations of the wild type strain and more than 100 mutants showed phenotypes in accordance with experimental observations. Some mutants defective in the Start and Finish transitions and the different ways to rescue them will be presented. / Ph. D.
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Experimental evidnece for hysteresis in the cell cycles of Xenopus Laevis egg extractsSha, Wei 28 August 2002 (has links)
In 1993, Novak and Tyson published a comprehensive mathematical model of the regulation of M-phase promoting factor (MPF) activity in Xenopus laevis eggs and egg extracts. Although this model was in agreement with existing and subsequent experimental data, fundamental predictions that the cell cycle is driven by a hysteresis loop have never been validated experimentally. The model's predictions of bifurcations that create and destroy MPF activity, indicative of hysteresis, were tested in this study.
<u>Prediction 1: The threshold concentration of cyclin B required to activate MPF is measurably higher than the threshold concentration required to inactivate MPF.</u> The difference in thresholds implies that the MPF control system is hysteretic and bistable. To measure these thresholds, extracts in interphase or M-phase were supplemented with varying concentrations of non-degradable human cyclin B1 protein. MPF activity was determined by the morphology of sperm nuclei and by assays of histone H1 kinase activity. Consistent with the model, the activation threshold was determined to be 40 nM, which is two-fold higher than the inactivation threshold, 20 nM.
<u>Prediction 2: For cyclin levels marginally above the activation threshold concentration of cyclin B, there is a dramatic "slowing-down" in the rate of MPF activation.</u> Supra-threshold concentrations of nondegradable cyclin B1 were added to cycloheximide-treated CSF-released extracts, and samples taken at various time-points were analyzed for MPF activity. At 40 nM cyclin B1, just above the activation threshold, the lag time for MPF activation was 45 - 60 minutes; at 50 nM cyclin B1, the lag time was between 30 - 45 minutes; and at 60 nM or higher concentrations of cyclin B1, the lag time was 20 - 30 minutes, thus confirming the prediction of the Novak-Tyson model.
<u>Prediction 3: DNA replication checkpoint increases the activation threshold concentration of cyclin B by increasing the hysteresis loop.</u> Cycloheximide-treated, CSF-released extracts containing 1200 sperm nuclei/μl were treated with aphidicolin, then supplemented with varying concentrations of nondegradable cyclin B1. The activation threshold was 100 nM, 2.5 fold higher than in extracts lacking aphidicolin.
<u>Conclusions:</u> These studies confirm three predictions of the Novak-Tyson model and indicate that hysteresis underlies cell cycle control in Xenopus egg extracts. These experiments validate use of mathematical models to study complex biological control systems such as the eukayotic cell cycle. / Master of Science
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Effects of Macrophage-conditioned Medium on Preadipocyte Cyclin-dependent Kinase Regulation During AdipogenesisIde, Jennifer C. 08 February 2011 (has links)
Macrophage-conditioned medium (MacCM) inhibits the differentiation of rodent and human preadipocytes. Previous studies report that murine J774A.1-MacCM inhibits clonal expansion (early required phase of adipogenesis), including Rb phosphorylation. I hypothesized that MacCM induced alterations in cyclins and/or cyclin-dependent kinases (CDKs) were responsible for impairing Rb phosphorylation. My first objective was to assess the effect of J774A.1-MacCM on CDK4, CDK2, and their regulatory cyclins. Murine 3T3-L1 preadipocytes were differentiated with control medium or J774A.1-MacCM. Expression of cyclin D and A was inhibited by J774A.1-MacCM. Inhibition of cyclin A expression was associated with reduced differentiation-induced CDK2 activity. My second objective was to assess the expression patterns of cell cycle proteins in differentiating human abdominal subcutaneous preadipocytes, which do not undergo clonal expansion in culture. Cyclin E expression increased with differentiation. THP-1-MacCM (a human macrophage cell line) further enhanced this increase. My studies suggest MacCM leads to alterations in cyclin/CDK regulation during adipogenesis in murine and human preadipocyte models.
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Effects of Macrophage-conditioned Medium on Preadipocyte Cyclin-dependent Kinase Regulation During AdipogenesisIde, Jennifer C. 08 February 2011 (has links)
Macrophage-conditioned medium (MacCM) inhibits the differentiation of rodent and human preadipocytes. Previous studies report that murine J774A.1-MacCM inhibits clonal expansion (early required phase of adipogenesis), including Rb phosphorylation. I hypothesized that MacCM induced alterations in cyclins and/or cyclin-dependent kinases (CDKs) were responsible for impairing Rb phosphorylation. My first objective was to assess the effect of J774A.1-MacCM on CDK4, CDK2, and their regulatory cyclins. Murine 3T3-L1 preadipocytes were differentiated with control medium or J774A.1-MacCM. Expression of cyclin D and A was inhibited by J774A.1-MacCM. Inhibition of cyclin A expression was associated with reduced differentiation-induced CDK2 activity. My second objective was to assess the expression patterns of cell cycle proteins in differentiating human abdominal subcutaneous preadipocytes, which do not undergo clonal expansion in culture. Cyclin E expression increased with differentiation. THP-1-MacCM (a human macrophage cell line) further enhanced this increase. My studies suggest MacCM leads to alterations in cyclin/CDK regulation during adipogenesis in murine and human preadipocyte models.
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The mechanisms of ethanol-induced damage to the developing cerebellum effects on the cerebellar granule cells /Li, Zheng, January 2003 (has links)
Thesis (Ph. D.)--West Virginia University, 2003. / Title from document title page. Document formatted into pages; contains vii, 146 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references.
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