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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.
1

Investigating Sex Specific Cell Cycle Regulation in Fetal Germ Cells

Cassy Spiller Unknown Date (has links)
During development, somatic cell cues direct sex-specific differentiation of germ cells that is characterised by two distinct cell cycle states. At 12.5 days post coitum (dpc) in a testis, XY germ cells stop proliferating and enter G1/G0 arrest. In the ovary, XX germ cells bypass G1/G0 arrest and instead enter the first phase of meiosis I from 13.5 dpc. Whilst it is hypothesised that errors in cell cycle control during development precede the formation of testicular germ cell tumours, the mechanism of cell cycle control at this time has not been thoroughly investigated. This project therefore sought to explore the mechanism of XY germ cell G1/G0 arrest using several approaches. Although cell cycle regulation for somatic cells is well established, we know very little regarding germ cell control of this process. Therefore my first aim was to profile this machinery at the transcript level using a cell cycle cDNA array. Purified populations of germ cells were isolated both before and after sex differentiation and expression of 112 cell cycle related genes was assessed. From this study a comprehensive network governing apoptosis and calcium signalling that was common to both XX and XY germ cells was observed. Importantly, the retinoblastoma family and cyclin dependent kinase inhibitor p21 was implicated in the regulation of G1/G0 arrest in XY germ cells. Lastly, XX germ cells displayed a down-regulation of genes involved in both G1 and G2 phases of the cell cycle consistent with their progression past G1 phase. This study has provided a detailed analysis of cell cycle gene expression during fetal germ cell development and identified candidate factors for future investigation in order to understand cases of aberrant cell cycle control in these specialised cells. In order to investigate several candidate genes identified within the cell cycle array, I next sought to generate a germ cell-specific Cre recombinase mouse model for use in conditional knockout studies. As current Cre lines lack specificity or appropriate temporal expression, we used the germ cell-specific regions of the fragilis promoter to drive Cre expression during germ cell specification. Eleven founder lines were generated using this construct and four were analysed using a reporter line. Although we have not achieved germ cell expression from these lines to date, analysis continues in order to identify an invaluable new tool for germ cell research. Following the implication of the retinoblastoma family in XY germ cell G1/G0 arrest, I next investigated the role of RB in these cells using the Rb null mutant. RB is a known cell cycle suppressor that controls this process in many cell types and, subsequently, mice homozygous for the Rb deletion die in utero at 14.5 dpc. Using this model we analysed developing gonads from 14.5 – 16.5 dpc using ex vivo culture techniques. At 14.5 dpc when wild type germ cells have arrested, proliferating germ cells were detected in the absence of Rb using proliferation marker Ki67. This proliferation was accompanied by a slight increase in germ cell number at 14.5 dpc, however, two days later at 16.5 dpc germ cell numbers were slightly decreased in the Rb-/- testes. During this time we could also detect increased expression of other RB family members p107 and p130, suggesting that these factors may compensate for the loss of Rb in the germ line. This investigation has implicated RB in the regulation of XY germ cell G1/G0 arrest and will form the basis for future work aimed at understanding the initiation of this cell cycle state. In addition to RB, a lesser-known transcription factor was also investigated in the initiation and maintenance of XY germ cell G1/G0 arrest. The high mobility group box transcription factor 1 (HBP1) suppresses proliferation and promotes differentiation in various cell types and was recently identified within the XY germ cells at the appropriate time of sex differentiation. In my analysis two Hbp1 transcripts were identified within the XY germ cells that display different sub-cellular localisations in vitro. Next, Hbp1-LacZ reporter lines were generated to aid in understanding the germ cell-specific regulation of these transcripts and lastly, I analysed the genetrap mutation for Hbp1. Surprisingly, this model revealed no aberrations to germ cell-cell cycle control during development. In summary, I have performed the first comprehensive study of the cell cycle machinery utilised by germ cells as they undergo the first stages of sex differentiation. Using loss-of-function models I was able to implicate the cell cycle regulator RB specifically in XY germ cell G1/G0 arrest and, conversely, demonstrate that the transcription factor HBP1 is not required for this process.
2

Investigating Sex Specific Cell Cycle Regulation in Fetal Germ Cells

Cassy Spiller Unknown Date (has links)
During development, somatic cell cues direct sex-specific differentiation of germ cells that is characterised by two distinct cell cycle states. At 12.5 days post coitum (dpc) in a testis, XY germ cells stop proliferating and enter G1/G0 arrest. In the ovary, XX germ cells bypass G1/G0 arrest and instead enter the first phase of meiosis I from 13.5 dpc. Whilst it is hypothesised that errors in cell cycle control during development precede the formation of testicular germ cell tumours, the mechanism of cell cycle control at this time has not been thoroughly investigated. This project therefore sought to explore the mechanism of XY germ cell G1/G0 arrest using several approaches. Although cell cycle regulation for somatic cells is well established, we know very little regarding germ cell control of this process. Therefore my first aim was to profile this machinery at the transcript level using a cell cycle cDNA array. Purified populations of germ cells were isolated both before and after sex differentiation and expression of 112 cell cycle related genes was assessed. From this study a comprehensive network governing apoptosis and calcium signalling that was common to both XX and XY germ cells was observed. Importantly, the retinoblastoma family and cyclin dependent kinase inhibitor p21 was implicated in the regulation of G1/G0 arrest in XY germ cells. Lastly, XX germ cells displayed a down-regulation of genes involved in both G1 and G2 phases of the cell cycle consistent with their progression past G1 phase. This study has provided a detailed analysis of cell cycle gene expression during fetal germ cell development and identified candidate factors for future investigation in order to understand cases of aberrant cell cycle control in these specialised cells. In order to investigate several candidate genes identified within the cell cycle array, I next sought to generate a germ cell-specific Cre recombinase mouse model for use in conditional knockout studies. As current Cre lines lack specificity or appropriate temporal expression, we used the germ cell-specific regions of the fragilis promoter to drive Cre expression during germ cell specification. Eleven founder lines were generated using this construct and four were analysed using a reporter line. Although we have not achieved germ cell expression from these lines to date, analysis continues in order to identify an invaluable new tool for germ cell research. Following the implication of the retinoblastoma family in XY germ cell G1/G0 arrest, I next investigated the role of RB in these cells using the Rb null mutant. RB is a known cell cycle suppressor that controls this process in many cell types and, subsequently, mice homozygous for the Rb deletion die in utero at 14.5 dpc. Using this model we analysed developing gonads from 14.5 – 16.5 dpc using ex vivo culture techniques. At 14.5 dpc when wild type germ cells have arrested, proliferating germ cells were detected in the absence of Rb using proliferation marker Ki67. This proliferation was accompanied by a slight increase in germ cell number at 14.5 dpc, however, two days later at 16.5 dpc germ cell numbers were slightly decreased in the Rb-/- testes. During this time we could also detect increased expression of other RB family members p107 and p130, suggesting that these factors may compensate for the loss of Rb in the germ line. This investigation has implicated RB in the regulation of XY germ cell G1/G0 arrest and will form the basis for future work aimed at understanding the initiation of this cell cycle state. In addition to RB, a lesser-known transcription factor was also investigated in the initiation and maintenance of XY germ cell G1/G0 arrest. The high mobility group box transcription factor 1 (HBP1) suppresses proliferation and promotes differentiation in various cell types and was recently identified within the XY germ cells at the appropriate time of sex differentiation. In my analysis two Hbp1 transcripts were identified within the XY germ cells that display different sub-cellular localisations in vitro. Next, Hbp1-LacZ reporter lines were generated to aid in understanding the germ cell-specific regulation of these transcripts and lastly, I analysed the genetrap mutation for Hbp1. Surprisingly, this model revealed no aberrations to germ cell-cell cycle control during development. In summary, I have performed the first comprehensive study of the cell cycle machinery utilised by germ cells as they undergo the first stages of sex differentiation. Using loss-of-function models I was able to implicate the cell cycle regulator RB specifically in XY germ cell G1/G0 arrest and, conversely, demonstrate that the transcription factor HBP1 is not required for this process.
3

Investigating Sex Specific Cell Cycle Regulation in Fetal Germ Cells

Cassy Spiller Unknown Date (has links)
During development, somatic cell cues direct sex-specific differentiation of germ cells that is characterised by two distinct cell cycle states. At 12.5 days post coitum (dpc) in a testis, XY germ cells stop proliferating and enter G1/G0 arrest. In the ovary, XX germ cells bypass G1/G0 arrest and instead enter the first phase of meiosis I from 13.5 dpc. Whilst it is hypothesised that errors in cell cycle control during development precede the formation of testicular germ cell tumours, the mechanism of cell cycle control at this time has not been thoroughly investigated. This project therefore sought to explore the mechanism of XY germ cell G1/G0 arrest using several approaches. Although cell cycle regulation for somatic cells is well established, we know very little regarding germ cell control of this process. Therefore my first aim was to profile this machinery at the transcript level using a cell cycle cDNA array. Purified populations of germ cells were isolated both before and after sex differentiation and expression of 112 cell cycle related genes was assessed. From this study a comprehensive network governing apoptosis and calcium signalling that was common to both XX and XY germ cells was observed. Importantly, the retinoblastoma family and cyclin dependent kinase inhibitor p21 was implicated in the regulation of G1/G0 arrest in XY germ cells. Lastly, XX germ cells displayed a down-regulation of genes involved in both G1 and G2 phases of the cell cycle consistent with their progression past G1 phase. This study has provided a detailed analysis of cell cycle gene expression during fetal germ cell development and identified candidate factors for future investigation in order to understand cases of aberrant cell cycle control in these specialised cells. In order to investigate several candidate genes identified within the cell cycle array, I next sought to generate a germ cell-specific Cre recombinase mouse model for use in conditional knockout studies. As current Cre lines lack specificity or appropriate temporal expression, we used the germ cell-specific regions of the fragilis promoter to drive Cre expression during germ cell specification. Eleven founder lines were generated using this construct and four were analysed using a reporter line. Although we have not achieved germ cell expression from these lines to date, analysis continues in order to identify an invaluable new tool for germ cell research. Following the implication of the retinoblastoma family in XY germ cell G1/G0 arrest, I next investigated the role of RB in these cells using the Rb null mutant. RB is a known cell cycle suppressor that controls this process in many cell types and, subsequently, mice homozygous for the Rb deletion die in utero at 14.5 dpc. Using this model we analysed developing gonads from 14.5 – 16.5 dpc using ex vivo culture techniques. At 14.5 dpc when wild type germ cells have arrested, proliferating germ cells were detected in the absence of Rb using proliferation marker Ki67. This proliferation was accompanied by a slight increase in germ cell number at 14.5 dpc, however, two days later at 16.5 dpc germ cell numbers were slightly decreased in the Rb-/- testes. During this time we could also detect increased expression of other RB family members p107 and p130, suggesting that these factors may compensate for the loss of Rb in the germ line. This investigation has implicated RB in the regulation of XY germ cell G1/G0 arrest and will form the basis for future work aimed at understanding the initiation of this cell cycle state. In addition to RB, a lesser-known transcription factor was also investigated in the initiation and maintenance of XY germ cell G1/G0 arrest. The high mobility group box transcription factor 1 (HBP1) suppresses proliferation and promotes differentiation in various cell types and was recently identified within the XY germ cells at the appropriate time of sex differentiation. In my analysis two Hbp1 transcripts were identified within the XY germ cells that display different sub-cellular localisations in vitro. Next, Hbp1-LacZ reporter lines were generated to aid in understanding the germ cell-specific regulation of these transcripts and lastly, I analysed the genetrap mutation for Hbp1. Surprisingly, this model revealed no aberrations to germ cell-cell cycle control during development. In summary, I have performed the first comprehensive study of the cell cycle machinery utilised by germ cells as they undergo the first stages of sex differentiation. Using loss-of-function models I was able to implicate the cell cycle regulator RB specifically in XY germ cell G1/G0 arrest and, conversely, demonstrate that the transcription factor HBP1 is not required for this process.
4

Développement de la lignée germinale femelle humaine / Human Female Germ Line Development

Poulain, Marine 23 October 2014 (has links)
La mise en place de la lignée germinale au cours du développement constitue une des étapes fondamentales conditionnant la fertilité de l’individu adulte. Au cours des dernières décennies, le nombre croissant de couples consultant pour une aide médicale à la procréation a fait émerger l’hypothèse d’une altération des fonctions de reproduction chez l’Homme qui pourrait trouver son origine dans la perturbation du développement précoce. Dans l’ovaire fœtal, les cellules germinales s’orienteront vers la voie de l’ovogénèse, caractérisée entre autres par l’entrée en méiose de ces cellules. La majorité des données actuelles relatives à ces évènements sont issues du modèle murin alors que le développement de l’ovaire humain est significativement diffèrent de celui de la souris. Il est donc nécessaire d’approfondir nos connaissances du développement ovarien humain et d’identifier ses éventuelles perturbations. L’objectif de mon travail a été de mettre au point un outil d’étude du développement ovarien et d’identifier de nouvelles voies impliquées dans la régulation de l’entrée en méiose des cellules germinales fœtales humaines et leurs perturbations éventuelles.Nous avons mis au point un nouveau modèle de xénogreffe d’ovaires fœtaux humains du premier trimestre de gestation (au moment de l’apparition des premières cellules méiotiques). Ce modèle nous a permis d’observer un développement de l’organe et une différenciation des cellules germinales similaires à ceux observés in vivo. Ce modèle permettra des travaux à des âges auxquels le matériel d’étude est peu accessible. En couplant ce modèle de xénogreffe à une stratégie d’ARN-interférence, il nous a été possible d’inhiber l’expression d’un gène spécifiquement exprimé dans les cellules germinales ovariennes, DMRTA2, et de mettre en évidence un potentiel rôle de ce gène dans leur différenciation pré-méiotique. Nous avons observé une diminution du nombre de cellules ayant initié la méiose après inhibition de l’expression de ce gène. Par ailleurs, nous avons également identifié la présence dans l’ovaire fœtal de nombreux marqueurs décrits comme testiculaires chez la souris (PLZF, DNMT3L, FGF9, NANOS2 ou CYP26B1). L’expression de ces marqueurs pourrait expliquer la présence de cellules mitotiques tardives dans l’ovaire fœtal humain que nous avons pu observer jusqu’à 30 semaines de gestation. En parallèle de ces travaux, nous avons testé la sensibilité des cellules germinales à la dexaméthasone, glucocorticoïde pouvant être administré au cours de la grossesse. Il a été observé une augmentation de l’expression de PLZF, gène cible de l’activation des récepteurs aux glucocorticoïdes, pouvant expliquer la diminution du nombre de cellules germinales.En conclusion, ce travail de thèse a permis d’identifier un nouveau gène potentiellement régulateur de la transition mitose/méiose dans l’ovaire humain, et d’affiner nos connaissances sur le développement de l’ovaire humain et l’entrée en méiose des cellules germinales. Toutefois, de nombreuses questions restent posées ainsi de futures études devront clarifier si les cellules germinales mitotiques observées à des stades tardifs sont capables de se différencier en ovocytes compétents. / Woman fertility is partially dictated by the set up of the human female germ line. During the last ten years, which saw an increased number of couples consulting for assisted reproductive cares, the hypothesis of an early alteration in reproduction functions has emerged.In the fetal ovary, germ cells enter the path of oogenesis differentiation characterized by meiotic initiation. On this subject, vast majority of the scientific data are obtained from the mouse model, even if differences with human ovarian physiology are widely acknowledged. Therefore it is necessary to extend our knowledge on human ovarian development and identify its perturbations. The objective of my work was to assess a new model to study ovarian growth, studying regulation of meiotic entry and perturbation of germ line differentiation.We sat up a new xenograft model of early human fetal ovaries, when very early meiotic germ cells appear. Organ growth and germ cells differentiation were comparable with in vivo observations. Using this model with an RNA-interference strategy, we inhibited the expression of an oogonia germ cell gene, DMRTA2. This inhibition conducted to a significantly reduced number of germ cells gene that initiated meiosis and DMRTA2 seemed to be required for mitotic-meiotic transition. In another hand, we identified, in the ovary, the expression of germ cells markers described as specifically male in rodent (PLZF, DNMT3L, FGF9, NANOS2 ou CYP26B1). The expression of these markers in the human ovary could explain the observation of mitotic germ cells in late fetal ovaries (30 wpf).In parallel, we tested germ cells sensibility to a synthetic glucocorticoid, dexamethasone, administrated during pregnancy in some justified pathologies. We observed an increased expression of PLZF that could explain the decreased number of germ cells observed in treated ovaries.In conclusion, we identified a new gene expressed in human fetal ovaries, potentially involved in the meiotic entry, and we extended our knowledge to characterized human germ line development. However, many points have to be clarified, as the possible competence of late mitotic germ cells to form oocytes.

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