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Properties of extruded wheat starch: wheat germ mixtures as affected by temperature, moisture, and level of wheat germSchultz, Maryse Fay. January 1984 (has links)
Call number: LD2668 .T4 1984 S38 / Master of Science
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Germline mutations at expanded simple tandem repeat DNA loci in sentinel mice /Somers, Christopher Michael. Quinn, James S. January 2004 (has links)
Thesis (Ph.D.)--McMaster University, 2004. / Advisor: James S. Quinn. Includes bibliographical references. Also available via World Wide Web.
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THE ROLE OF BAX IN APOPTOSIS OF ECTOPIC PRIMORDIAL GERM CELLS IN THE MOUSESTALLOCK, JAMES PATRICK 17 April 2003 (has links)
No description available.
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Germ cell determination and the developmental origin of germ cell tumorsNicholls, Peter, Page, D.C. 15 December 2023 (has links)
Yes / In each generation, the germline is tasked with producing somatic lineages that form the body, and segregating a population of cells for gametogenesis. During animal development, when do cells of the germline irreversibly commit to producing gametes? Integrating findings from diverse species, we conclude that the final commitment of the germline to gametogenesis - the process of germ cell determination - occurs after primordial germ cells (PGCs) colonize the gonads. Combining this understanding with medical findings, we present a model whereby germ cell tumors arise from cells that failed to undertake germ cell determination, regardless of their having colonized the gonads. We propose that the diversity of cell types present in these tumors reflects the broad developmental potential of migratory PGCs. / This work was supported by the Howard Hughes Medical Institute where D.C.P. is an Investigator, and the Frontier Research Program from the Koch Institute for Integrative Cancer Research, Massachusetts Institute of Technology. P.K.N. is a recipient of the Hope Funds for Cancer Research Fellowship (HFCR-15-06-06) and an Early Career Fellowship from the National Health and Medical Research Council, Australia (GNT1053776).
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Roles of the pluripotency associated Tex19.1 gene in mouse embryonic and germline developmentReichmann, Judith January 2012 (has links)
Chromosome segregation errors that occur in the developing germline generate aneuploidies which are among the leading causes of embryonic lethality, spontaneous abortions and chromosomal disorders, such as Down’s syndrome. Compared to other species, human oocytes appear to be particularly prone to suffer chromosome missegregation and the risk of aneuploid pregnancies in humans increases drastically with maternal age. Despite its particular importance for human health, relatively little is known about the basis for the high incidence of aneuploidies in human oocytes and the maternal-age effect. The identification and analysis of molecular pathways that promote genetic and chromosomal stability is important for our understanding of mechanisms that lead to aneuploidy and how it can be prevented. Here, I examine the role of the pluripotency associated Tex19.1 gene, in preventing aneuploidy during mouse female germ cell development. I demonstrate that Tex19.1-/- females are subfertile when mated with wild type males due to defects in chromosome segregation during meiosis. In contrast to Tex19.1-/- male gem cells, synaptonemal complex formation appears to be completed normally in Tex19.1-/- females but high levels of aneuploidy are evident during the second meiotic stages of oogenesis. The Tex19.1-/- females transmit these aneuploidies to their offspring likely resulting in the observed embryonic death and subfertility. In addition to its role in the female germline, I investigated the function of Tex19.1 during embryonic development. I found that Tex19.1-/- knockout mice are born at a sub- Mendelian frequency and this reduction is exacerbated in diapaused embryos, suggesting that Tex19.1 plays a role during a stage where a pluripotent state is maintained for a prolonged period of time. Furthermore, I identified high levels of aneuploidy accumulating in pluripotent stem cells in the absence of Tex19.1.
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Fetal germ cell development in the rat testis and the impact of di (n-Butyl) phthalate exposureJobling, Matthew S. January 2010 (has links)
During gonad development and fetal life, the germ cells (GC) undergo a range of different developmental processes necessary for correct postnatal gametogenesis and the production of the next generation. If these fetal events are disrupted by genetic or environmental factors, there could be severe consequences that may not present until adulthood. This is of particular importance in relation to human testicular GC tumours (TGCT), the most common cancer of young men, as TGCT is thought to arise from fetal GCs that have failed to differentiate normally during development and thus persist into adulthood, eventually becoming tumourigenic. TGCT is one of several related disorders of male reproductive health thought to comprise a Testicular Dysgenesis Syndrome (TDS), in which faulty testis development in fetal life may predispose to the development of cryptorchidism, hypospadias, reduced sperm count and TGCT. Currently there is no accepted animal model for TGCT, but some insight into human TDS has been gained through the use of a rat model using in utero Di (n-Butyl) Phthalate (DBP) exposure to induce cryptorchidism, hypospadias, low sperm count and reduced fertility (but not TGCT). However, a previous study suggested that DBP exposure can disrupt GC differentiation, resulting in significantly reduced GC number prior to birth and postnatal consequences. This thesis has been directed at investigating the normal process of GC development in the fetal rat and how this is altered by DBP exposure; such understanding may give insights into the origins of human TGCT by showing how and when disruption of normal fetal GC differentiation can occur. The first objective was to characterise GC development in both the rat testis and ovary to understand the normal events that occur between embryonic day (e)13.5 and e21.5, as most data in the literature is based on the mouse. Analysis by immunohistochemical, stereological and mRNA expression indentified that during this time period, a GC will undergo a dynamic sequence of changes involving migration, proliferation followed by differentiation (manifested by loss of specific protein markers), whilst undergoing germ-line specific remethylation. Whilst whole gonad development is vastly different between testes and ovaries, GC development was broadly the same with only minor differences up to the point where GCs in the ovary enter meiosis. Having established the normal process of GC development in the fetal rat testis, the effects of in utero DBP exposure was then investigated. DBP exposure reduced GC number at all ages investigated even after only 24 hours of exposure and simultaneously prolonged GC proliferation. As apoptosis was unaltered by DBP exposure, the consistent reduction in GC number was suggested to be due to an initial reduction in GC number that does not recover to control levels. GC differentiation was assessed by the expression and localization of specific protein markers (OCT4, DMRT1 and DAZL). The pattern of expression of OCT4 and DMRT1 was altered by DBP exposure. GCs in DBP exposed animals also showed a delay in disaggregation from within the centre of seminiferous cords. These results suggested that a delay in GC differentiation was occurring with DBP exposure. This delay in GC development persisted into early postnatal life, following cessation of DBP exposure. Thus at postnatal day (D)6, GC specific re-expression of DMRT1, GC migration to the basal lamina and resumption of GC proliferation all showed a delay. DBP also induced an increase in the presence of multinucleated gonocytes. DNA methylation in the fetal rat testis was also investigated as a mechanism that could be disrupted by DBP exposure. DNA methylation of GCs increased during the last week of fetal life by global methylation of the GC genome and the increased expression of DNA methyl transferases. No effect of DBP exposure was detected. Inhibition of methylation by 5-aza-2’deoxycytidine was then investigated as a way to block GC differentiation in fetal rat testes and this resulted in a similar transient delay in GC differentiation but was perinatally lethal to the fetus. Bisulphite sequencing of the OCT4 promoter was also performed but proved inconclusive. Methylation patterns may be being altered by DBP exposure, but such changes could not be identified in this thesis. To complement the in vivo DBP exposure studies, an in vitro testis explant system using e14.5 testes was investigated. These in vitro testis explants showed some GC effects with MBP, the active metabolite of DBP, and also suggested a novel role for Hedgehog signalling in GC survival in the fetal rat testis. The studies in this thesis have characterised several aspects of fetal GC development in the rat and identified which of these are affected by DBP exposure, resulting in a delay in GC development. As DBP exposure delays but does not block GC differentiation, this may explain why TGCT is not induced in the DBP exposure rat model for TDS.
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Cell-cell interactions in the rat testis: biology and future perspectives鍾穗華, Chung, Shui-wah. January 1999 (has links)
published_or_final_version / Zoology / Doctoral / Doctor of Philosophy
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POU-domain genes expressed in the Xenopus oocyte and early embryoWhitfield, Tanya January 1992 (has links)
No description available.
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XKrk1, a c-kit-related receptor tyrosine kinase expressed in Xenopus embryosBaker, Clare V. H. January 1994 (has links)
No description available.
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Spontaneous generation in the 1870s : Victorian scientific naturalism and its relationship to medicineAdam, Alison E. January 1988 (has links)
In the 1870s a debate over the spontaneous generation of microorganisms took place in Britain. Much opposition to the doctrine of spontaneous generation came from the Victorian scientific naturalists, especially John Tyndall, Professor of Natural Philosophy at the Royal Institution, London. This thesis provides an understanding of and explanations for the beliefs surrounding the spontaneous generation debate, particularly with regard to Victorian scientific naturalism and its relationship to medicine. Spontaneous generation threatened some of the fundamental tenets of naturalism. Furthermore, Tyndall clearly related his opposition to spontaneous generation to his support for the germ theory which he used as a vehicle for advocating a scientific approach to medicine. The thesis concludes that Tyndall's campaign for scientific medicine was part of the scientific naturalists' campaign to spread the naturalistic world-view and to gain cultural leadership. The spontaneous generation debate is examined in detail. The shift in experimental paradigm away from physical conditions towards a bacteriological approach is described. Chapter 5 examines the threats an acceptance of spontaneous generation posed to naturalism in terms of evolution, protoplasm and naturalistic explanations of disease. The effects of Tyndall's campaign for the germ theory on the medical profession are described. In order to understand how scientific knowledge was introduced into medicine, Chapter 6 examines the work of key medical scientists in the field of pathology with reference to their involvement in the spontaneous generation debate and in particular the reasons for their acceptance or rejection of the germ theory. Chapter 7 shows how the spontaneous generation debate impacted the domain of public health from the 1870s-1890s by means of a detailed examination of handbooks of sanitation and hygiene. The gradual introduction of results from the spontaneous generation debate into these works demonstrates the importance of the spontaneous generation debate in forming a bridge from the medical knowledge of the 1860s to the new bacteriology of the 1880s.
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