Global ETD Search

111	Possible Causes of Testicular Germ Cell Tumor and its Association with Male Infertility Badran, Wael Ahmed 11 May 2013 (has links) Testicular germ cell tumors (TGCTs) are thought to arise during early embryogenesis due to the arrest of germ cell differentiation at primordial germ cells (PGCs) or gonocytes. Oxidative stress (OS) is implicated in cancer development as a factor leading to DNA damage. Reactive oxygen species (ROS) -induced instability occurs as a series of progressive steps. The cell has several defense mechanisms against the deleterious effect of ROS (e.g. antioxidants and DNA repair). When the defense mechanisms are exhausted by increasing OS, DNA damage leads to genomic instability with subsequent mutations that can be transmitted during cell division. On the other hand, male infertility is a representation of testicular dysgenesis syndrome, which carries a risk for TGCTs development. The mechanisms underlying both TGCTs and male infertility are thought to be overlapping to some extent. The central hypothesis of this work is that OS induces germ line genomic instability leading to testicular germ cell tumors. To test this hypothesis, mouse germ cell lines were established and subjected to different doses of OS in the form of H2O2. The mutation frequency was associated with the treatment dose 2 uM at days 3, 6, and 9 (p<0.001, p<0.001, and p<0.0003, respectively). The mBAT27 marker showed a mutation frequency fitting quadratic response surface regression. The mutation frequencies pointed to the possible role of OS leading to accumulation of DNA damage and initiating events that lead to TGCTs development that may occur early in life, possibly during the prenatal period. In addition, different panels of microsatellite markers from across the genome were analyzed to test for differential instability in both somatic cells and germline cells. Blood and semen samples from 18 infertile patients and 7 ethnically matched controls were used. Microsatellite markers were selected; 26 on the Y chromosome, 16 on the X chromosome, and 20 on different autosomes. Microsatellite instability was detected in markers located near genes responsible for testis development, spermatogenesis, cell differentiation, and proteins involved in mismatch repair mechanisms. This supports the hypothesis that testicular germ cell tumors may arise during early embryogenesis through acquiring multiple mutations that accumulate over time. Testicular germ cell tumor male infertility microsatellite instability ROS DNA repair Genomic instability DNA purification germ cells
112	Evidence for Endoreduplication: Germ Cell DNA Levels Prior to Chromatin Diminution in Mesocyclops Edax Rasch, Ellen M., Wyngaard, G. A. 01 June 2001 (has links) We studied the functional significance of marked differences in the DNA content of somatic cells and germ line nuclei by static Feulgen-DNA cytophotometry for several species of microcrustaceans that exhibit chromatin diminution during very early stages of embryogenesis. Mature females and males showed many gonadal nuclei with elevated amounts of DNA that persist until dispersal of this "extra" DNA throughout the cytoplasm as fragments and coalescing droplets of chromatin during anaphase of the diminution division. animals chromatin crustacea (cytology genetics) DNA (isolation & purification) DNA replication female germ cells male Biological Sciences
113	An In Vitro Male Germ Cell Assay and Its Application for Detecting Phase Specificity of Genotoxins/Mutagens Habas, Khaled S.A., Brinkworth, Martin H., Anderson, Diana 2017 September 1929 (has links) No / Genotoxic agents can interact with DNA in germ cells possibly resulting in a heritable trait (germline mutation). Thus, in vitro male germ cell tests, which can detect phase specificity of such agents, could be used by regulatory agencies to help evaluate the potential risk of mutation. The male germ cell system now has a well-established model for studying phase specificity using the STA-PUT velocity sedimentation. On treatment with genotoxic agents, differences in chemical structure and metabolic differences in types of male germ cell lead to differing susceptibilities to genotoxicity, so careful investigation is required for phase specificity. This can yield valuable information about the potential mechanisms involved in the genotoxicity responses and thus increase the significance of the findings. This is especially important because mutations induced in the germline could also affect future generations. In this chapter, we briefly review the field of the male germ cell DNA damage response. Comet assay DNA damage Genetics Genotoxicity Male germ cells Phase specificity Spermatogenic cells STA-PUT velocity sedimentation Testis
114	GLS-1, a novel P granule component, modulates a network of conserved RNA regulators to influence germ cell fate decisions Eckmann, Christian R., Schmid, Mark, Kupinski, Adam P., Jedamzik, Britta, Harterink, Martin, Rybarska, Agata 26 November 2015 (has links) (PDF) Post-transcriptional regulatory mechanisms are widely used to influence cell fate decisions in germ cells, early embryos, and neurons. Many conserved cytoplasmic RNA regulatory proteins associate with each other and assemble on target mRNAs, forming ribonucleoprotein (RNP) complexes, to control the mRNAs translational output. How these RNA regulatory networks are orchestrated during development to regulate cell fate decisions remains elusive. We addressed this problem by focusing on Caenorhabditis elegans germline development, an exemplar of post-transcriptional control mechanisms. Here, we report the discovery of GLS-1, a new factor required for many aspects of germline development, including the oocyte cell fate in hermaphrodites and germline survival. We find that GLS-1 is a cytoplasmic protein that localizes in germ cells dynamically to germplasm (P) granules. Furthermore, its functions depend on its ability to form a protein complex with the RNA-binding Bicaudal-C ortholog GLD-3, a translational activator and P granule component important for similar germ cell fate decisions. Based on genetic epistasis experiments and in vitro competition experiments, we suggest that GLS-1 releases FBF/Pumilio from GLD-3 repression. This facilitates the sperm-to-oocyte switch, as liberated FBF represses the translation of mRNAs encoding spermatogenesis-promoting factors. Our proposed molecular mechanism is based on the GLS-1 protein acting as a molecular mimic of FBF/Pumilio. Furthermore, we suggest that a maternal GLS-1/GLD-3 complex in early embryos promotes the expression of mRNAs encoding germline survival factors. Our work identifies GLS-1 as a fundamental regulator of germline development. GLS-1 directs germ cell fate decisions by modulating the availability and activity of a single translational network component, GLD-3. Hence, the elucidation of the mechanisms underlying GLS-1 functions provides a new example of how conserved machinery can be developmentally manipulated to influence cell fate decisions and tissue development. Keimzellen Sperma Oozyten Eizellen Embryos Oogenese Proteintranslation Proteininteraktionen Germ Cells Sperm Oocytes Embryos Messenger RNA Oogenesis Protein translation Protein interactions ddc:610 rvk:XA 10000
115	The susceptibility of primordial germ cells to malignant transformation and isolation and characterization of members of a new gene family differentially expressed in invasive and non-invasive immortalized male germ cells / Die Potenz der Primordialen Keimzellen zur malignen Transformation und Isolierung und Charakterisierung von Mitgliedern einer neuen Genfamilie, die in invasiven immortalisierten Keimzellen überexprimiert sind Ahmed, Manal Bayomi Mahmoud 29 January 2002 (has links) No description available. 570 Biowissenschaften, Biologie Primordial Keimzellen (PGCs) SV40-LTA Testikular Keimzellen Tumoren Genfamilie Primordial germ cells (PGCs) SV40-LTA Testicular germ cell tumors Gene family 42.13 WD
116	Molecular Mechanisms in Primordial Germ Cell Development in Zebrafish / Molekulare Mechanismen in der Entwicklung von Primordialen Keimzellen des Zebrafisches Strasser, Markus 10 October 2007 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science Keimzelle Entwicklung Keimgranulate Dead end MikroRNA Germ cells Development germinal granules Dead end microRNA 42 W
117	Unfolded protein response genes regulated by CED-1 are required for Caenorhabditis elegans innate immunity. Haskins, KA, Russell, JF, Gaddis, N, Dressman, HK, Aballay, A 07 1900 (has links) The endoplasmic reticulum stress response, also known as the unfolded protein response (UPR), has been implicated in the normal physiology of immune defense and in several disorders, including diabetes, cancer, and neurodegenerative disease. Here, we show that the apoptotic receptor CED-1 and a network of PQN/ABU proteins involved in a noncanonical UPR response are required for proper defense to pathogen infection in Caenorhabditis elegans. A full-genome microarray analysis indicates that CED-1 functions to activate the expression of pqn/abu genes. We also show that ced-1 and pqn/abu genes are required for the survival of C. elegans exposed to live Salmonella enterica, and that overexpression of pqn/abu genes confers protection against pathogen-mediated killing. The results indicate that unfolded protein response genes, regulated in a CED-1-dependent manner, are involved in the C. elegans immune response to live bacteria. / Dissertation Animals Apoptosis Caenorhabditis elegans Caenorhabditis elegans Proteins Escherichia coli Genes Germ Cells Green Fluorescent Proteins Immunity, Innate Membrane Proteins Mutation Protein Folding RNA Interference Salmonella enterica Survival
118	Étude de marqueurs de différenciation testiculaire Sox9 et Amh lors d'un développement normal, d'une inversion sexuelle et d'un développement en absence de cellules germinales chez l'amphibien urodèle Pleurodeles waltl. Intérêt pour la physiologie comparée de la reproduction des vertébrés / Study of testis differentiation markers Sox9 and Amh during normal development, sex reversal, and development in the absence of germ cells in the newt Pleurodeles waltl. Interest in comparative physiology of reproduction Al-Asaad, Imane 13 November 2013 (has links) Dans le contexte de la physiologie comparée de la reproduction, les amphibiens sont peu étudiés. Le travail réalisé durant cette thèse visait à analyser des marqueurs de différenciation testiculaire chez l'urodèle Pleurodeles waltl, dont le déterminisme génétique du sexe (ZZ/ZW) peut être influencé par la température. Nos études ont d'abord porté sur le gène sox9 marqueur de la différenciation testiculaire chez les vertébrés supérieurs. Le gène cloné chez le pleurodèle montre une bonne conservation par rapport aux autres vertébrés. Son expression plus élevée dans la gonade mâle n'apparaît que tardivement suggérant qu'il n'est probablement pas impliqué dans les stades précoces de la différenciation testiculaire. En outre, son expression dans le mésonéphros rend difficile son utilisation comme marqueur de différenciation testiculaire. Nous avons ensuite étudié l'Amh, hormone testiculaire impliquée dans la régression des canaux de Müller chez de nombreux vertébrés. Son expression spécifique de la gonade, précocement plus élevée chez les larves ZZ que les ZW en font un excellent marqueur de la différenciation testiculaire. Le fait que les pleurodèles mâles voient les canaux de Müller persister malgré la présence d'Amh suggère que la fonction primaire de cette hormone était en relation avec la différenciation gonadique et que la fonction de régression des canaux de Müller n'est apparue que secondairement au cours de l'évolution. Ces marqueurs ont été mis à profit pour caractériser le phénotype gonadique lors d'inversions sexuelles ou lors de développements en absence de cellules germinales. Ils ont permis de montrer que les cellules germinales ne semblent pas jouer de rôle dans la différenciation gonadique du pleurodèle / In the context of comparative physiology of reproduction, amphibians are poorly studied. This work was dedicated to the analysis of testis differentiation markers in the newt Pleurodeles waltl, which shows a ZZ/ZW genetic mode of sex determination that can be affected by temperature. First, we studied sox9, a testis differentiation marker well characterized in many higher vertebrates. The gene cloned in Pleurodeles shows a good level of identity with other vertebrates. The testis-enriched expression appears late during the testis differentiation process indicating that it is probably not involved in the early steps of testis differentiation. Its use as a marker of testicular differentiation proved difficult since it is expressed not only in the gonads but also in the mesonephros. Then, we studied amh, a testis hormone responsible for müllerian duct regression in many vertebrates. Its early expression in the gonad, significantly higher in male than in female larvae makes it an excellent marker for testis differentiation. Since in Pleurodeles waltl, Müllerian ducts persist in males, it suggests that during the course of evolution, the function of Amh on the regression of Müllerian ducts appeared secondarily after its role in gonadal differentiation. These markers have been used to characterize the gonadal phenotype during sex reversal, or in gonads developed in the absence of germ cells. They showed that these cells do not seem to play a role in gonadal differentiation of Pleurodeles waltl Amphibien Pleurodeles waltl Différenciation gonadique Cellules germinales Sox9 AMH Aromatase Busulfan Amphibian Pleurodeles waltl Gonadal differentiation Germ cells Sox9 AMH Aromatase Busulfan 571.816 571.882
119	Epigenetic reprogramming in mouse germ cells Hajkova, Petra 05 March 2004 (has links) Bei Säugerkeimzellen, Zygoten und Embryos in frühen Stadien kommt der epigenetischen Neuprogammierung eine außergewöhnlich wichtige Rolle in der Regulation der Genomfunktionen in entscheidenden Entwicklungsstadien zu. Die epigenetische Neuprogrammierung in Keimzellen löscht zuerst die Imprinting-Markierungen und Epi-Mutationen und stellt dann geschlechtsspezifische Markierungen (genomische Prägung) wieder her. Die vorliegende Arbeit bezieht sich auf das Löschen epigenetischer Modifikationen in primordialen Mauskeimzellen (primordial germ cells (PGCs)) zwischen dem 10.5 bis 13.5 Tag nach der Befruchtung. Entgegen früheren Annahmen zeigen unsere Ergebnisse, daß primordiale Mauskeimzellen (PGCs) beim Eintritt in die embryonalen Keimdrüsen noch immer DNS Methylierungsmarker besitzen, die ähnlich dem Marker in somatischen Zellen sind. Kurz nach dem Eintritt in die Keimdrüsen werden die DNS Methylierungsmarker, die in Verbindung mit geprägten und nicht geprägten Genen stehen, gelöscht. Für die Mehrzahl der Gene beginnt die Löschung der Marker in männlichen und weiblichen Embryos gleichzeitig und ist innerhalb eines Entwicklungstages abgeschlossen. Diese Kinetik deutet auf einen aktiven Demethylierungsprozess hin, initiiert durch ein somatisches Signal, ausgehend von der embryonalen Keimdrüse. Der Zeitpunkt der Neuprogrammierung in den primordialen Keimzellen ist entscheidend, da er sicherstellt, daß Keimzellen beiden Geschlechts einen epigenetisch äquivalenten Status erhalten, bevor sie geschlechtsspezifisch ausdifferenzieren und anschließend neu elterlich geprägt werden. Vollständiges Verständnis des Prozesses der Neuprogrammierung der Keimzellen ist nicht nur im Hinblick auf genomisches Imprinting wichtig, sondern auch für die Erforschung von Mechanismen für die Wiederherstellung von omnipotenten Zellen bei Klonierung und Stammzellenerhaltung. / Epigenetic reprogramming in mammalian germ cells, zygote and early embryos, plays a crucial role in regulating genome functions at critical stages of development. Germ line epigenetic reprogramming assures erasure of all the imprinting marks and epi-mutations and establishment of new sex-specific gametic imprints. The presented work focuses on the erasure of epigenetic modifications that occur in mouse primordial germ cells (PGCs) between day 10.5 to 13.5 post coitum (dpc). Contrary to previous assumptions, our results show that as they enter the genital ridge the PGCs still possess DNA methylation marks comparable to those found in somatic cells. Shortly after the entry of PGCs into the gonadal anlagen the DNA methylation marks associated with imprinted and non-imprinted genes are erased. For most genes the erasure commences simultaneously in PGCs of both male and female embryos and is completed within only one day of development. The kinetics of this process indicates that is an active demethylation process initiated by a somatic signal emanating from the stroma of the genital ridge. The timing of reprogramming in PGCs is crucial since it ensures that germ cells of both sexes acquire an equivalent epigenetic state prior to the differentiation of the definitive male and female germ cells in which, new parental imprints are established subsequently. Complete understanding of the germline reprogramming processes is important not only in the light of genomic imprinting but also for resolving other mechanisms connected with restoring cellular totipotency, such as cloning and stem cell derivation. Epigenetik Reprogrammierung DNS Methylierung Prägung DNS Demethylierung Keimzellen Gametogenesis epigenetics reprogramming DNA methylation imprinting DNA demethylation germ cells gametogenesis 570 Biowissenschaften, Biologie 32 Biologie WG 3700 ddc:570
120	Estudo investigativo clínico, laboratorial, patológico, morfométrico, molecular de 10 pacientes com pseudohermafroditismo masculino disgenético (ADS 46, XY) / Clinical, pathological and morphometric study of ten male disgenetic pseudohermaphroditism (DSD 46,XY) Guedes, Dulce Rondina 15 January 2010 (has links) O Pseudohermafroditismo masculino disgenético (Anomalia da diferenciação sexual 46,XY ADS 46,XY) é definido como ambigüidade genital num paciente com testículos e/ou cariótipo 46,XY com uma das seguintes características: alteração histológica testicular, ausência ou hipoplasia das células de Leydig em tecido previamente estimulado com gonadotrofina coriônica humana(hCG), falta de resposta de testosterona ao estímulo com hCG sem acúmulo de precursores, ausência de células germinativas, presença de derivados müllerianos indicando inadequada produção do hormônio antiMülleriano (HAM) ou resistência de seus receptores. Esse estudo apresenta uma avaliação clínica, laboratorial, anátomopatológica, morfométrica e molecular de 10 pacientes com ADS 46,XY; dois pacientes apresentaram mutação no SF1 (fator esteroidogênico 1), duas mutações no domínio hingee uma terceira produziu um stop códon na posição 404; três pacientes com deleção da cópia do DAZ2. A morfometria testicular mostrou todos os diâmetros tubulares médios (DTM) moderado a gravemente diminuídos e os índices de fertilidade tubular leve a moderadamente diminuídos. Devido à dificuldade do diagnóstico diferencial e etiológico, o estudo morfométrico e molecular deve sempre acompanhar esses casos de ADS 46,XY. / The dysgenetic male pseudohermaphroditism 46,XY ; disorders of sex development (DSD 46,XY) is defined as sexual ambiguity in patients with testis and/or 46,XY karyotype and one of the characteristics: hystologic alteration of the testis; absence or hypoplasia of Leydig cells; a decreased testosterone response to human chorionic gonadotropin stimulation without accumulation of testosterone precursors; absent germ cells; presence of müllerian duct derivatives showing inappropriate production of antimüllerian hormone (AMH) or resistance to its receptors. This study shows the clinic, laboratory, histologic, morphometric and molecular evaluation of 10 patients with DSD 46,XY; two patients showed mutations in the SF1 gene (steroidogenic factor-1); two in the hinge domain and one stop codon at the position 404 of the protein; three patients exhibited deletion of DAZ2. The testis morphometry showed reduction: marked to severe of all mean tubular diameter (MTD) while the reduction of the tubular fertility index (TFI) were slight to marked. Due to difficulties establishing the differential diagnosis and the etiology, the morphometric and molecular evaluation must be always done in the patients with DSD 46,XY. Células germinativas Disgenesia gonadal Fator esteroidogênico 1 Germ cells Gonadal dysgenesis Pseudo-hermafroditismo Pseudohermaphroditism Seminiferous tubules Steroidogenic factor-1 Túbulos seminíferos

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