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Fertilized Oocytes (fertilized + oocyte)

Distribution by Scientific Domains
Life Sciences83%

Selected Abstracts

Germ Line Transformation of Mammals by Pronuclear Microinjection

EXPERIMENTAL PHYSIOLOGY, Issue 6 2000
T. Rülicke
The most popular approach for generating transgenic mammals is the direct injection of transgenes into one pronucleus of a fertilized oocyte. In the past 15 years microinjection has been successfully applied in laboratory as well as in farm animals. The frequency of transgenic founders, although highly different between the species, is efficient enough to render this technique applicable to a wide range of mammals. The expression levels and patterns of a transgene are initially influenced by the construction of the transgene. However, the overall phenotype of a transgenic organism is influenced by several genetic and environmental factors. Due to the features of this technique not all of the genetic factors can be experimentally controlled by the scientist. In this article we will emphasize some peculiarities which have to be taken into account for the successful performance of transgenesis by pronuclear microinjection [source]

Monochorionic-diamniotic twins discordant in gender from a naturally conceived pregnancy through postzygotic sex chromosome loss in a 47,XXY zygote

PRENATAL DIAGNOSIS, Issue 8 2008
Nicolas H. Zech
Abstract Objective It is generally believed that monochorionic-diamniotic twin pregnancies result from one fertilized oocyte with both siblings having the same genotype and phenotype. In rare instances, due to somatic mutations or chromosome aberrations, the karyotypes and phenotypes of the two twins can differ. Method We report cytogenetic, molecular genetic and clinical examinations in monochorionic-diamniotic twins discordant in gender. Results The monochorionic-diamniotic status of the twins was diagnosed by ultrasound and histologic examination of the placenta. Prenatal chromosome examination performed on amniocytes revealed a normal female karyotype in one and a 46,XX(26)/46,XY(3) karyotype in the other twin. Molecular examinations confirmed monozygosity despite discordant sex. Based on the cytogenetic and molecular results of lymphocytes and placental cells, the only explanation for gender discordance was that the conceptus originally had a 47,XXY chromosome complement. Conclusion A 47,XXY zygote appears to have undergone a twinning process. A postzygotic loss of the X chromosome in some cells and the Y chromosome in other cells, either before or after twinning, resulted in 46,XX/46,XY mosaicism in both monozygotic (MZ) twins. The sex discordance of the MZ twins can be explained by different proportions of the 46,XX and 46,XY cell lines in the gonads and other tissues. Copyright © 2008 John Wiley & Sons, Ltd. [source]

Targeted Expression of SHH Affects Chondrocyte Differentiation, Growth Plate Organization, and Sox9 Expression,

JOURNAL OF BONE AND MINERAL RESEARCH, Issue 10 2004
Sara Tavella
Abstract The role of Hedgehogs (Hh) in murine skeletal development was studied by overexpressing human Sonic Hedgehog (SHH) in chondrocytes of transgenic mice using the collagen II promoter/enhancer. Overexpression caused a lethal craniorachischisis with major alterations in long bones because of defects in chondrocyte differentiation. Introduction: Hedgehogs (Hhs) are a family of secreted polypeptides that play important roles in vertebrate development, controlling many critical steps of cell differentiation and patterning. Skeletal development is affected in many different ways by Hhs. Genetic defects and anomalies of Hhs signaling pathways cause severe abnormalities in the appendicular, axial, and cranial skeleton in man and other vertebrates. Materials and Methods: Genetic manipulation of mouse embryos was used to study in vivo the function of SHH in skeletal development. By DNA microinjection into pronuclei of fertilized oocytes, we have generated transgenic mice that express SHH specifically in chondrocytes using the cartilage-specific collagen II promoter/enhancer. Transgenic skeletal development was studied at different embryonic stages by histology. The expression pattern of specific chondrocyte molecules was studied by immunohistochemistry and in situ hybridization. Results: Transgenic mice died at birth with severe craniorachischisis and other skeletal defects in ribs, sternum, and long bones. Detailed analysis of long bones showed that chondrocyte differentiation was blocked at prehypertrophic stages, hindering endochondral ossification and trabecular bone formation, with specific defects in different limb segments. The growth plate was highly disorganized in the tibia and was completely absent in the femur and humerus, leading to skeletal elements entirely made of cartilage surrounded by a thin layer of bone. In this cartilage, chondrocytes maintained a columnar organization that was perpendicular to the bone longitudinal axis and directed toward its outer surface. The expression of SHH receptor, Patched-1 (Ptc1), was greatly increased in all cartilage, as well as the expression of parathyroid hormone-related protein (PTHrP) at the articular surface; while the expression of Indian Hedgehog (Ihh), another member of Hh family that controls the rate of chondrocyte maturation, was greatly reduced and restricted to the displaced chondrocyte columns. Transgenic mice also revealed the ability of SHH to upregulate the expression of Sox9, a major transcription factor implicated in chondrocyte-specific gene expression, in vivo and in vitro, acting through the proximal 6.8-kb-long Sox9 promoter. Conclusion: Transgenic mice show that continuous expression of SHH in chondrocytes interferes with cell differentiation and growth plate organization and induces high levels and diffuse expression of Sox9 in cartilaginous bones. [source]

Ion current activity and molecules modulating maturation and growth stages of ascidian (Ciona intestinalis) oocytes

MOLECULAR REPRODUCTION & DEVELOPMENT, Issue 11 2009
Francesco Silvestre
Electrophysiological techniques were used to study ion currents in the ascidian Ciona intestinalis oocyte plasma membranes during different stages of growth and meiosis. Three stages (A, B, C) of immature oocytes were discriminated in the ovary, with the germinal vesicle (GV) showing specific different features of growth and maturation. Stage A (pre-vitellogenic) oocytes exhibited the highest L-type Ca2+current activity, and were incompetent for meiosis resumption. Stage B (vitellogenic) oocytes showed Na+ currents that remained high during the maturation, up to the post-vitellogenic stage C oocytes. The latter had acquired meiotic competence, undergoing spontaneous maturation and interacting with the spermatozoon. However, fertilized oocytes did not produce normal larvae, suggesting that cytoplasmic maturation plays a specific role in embryo development. Spontaneous maturation was inhibited at low pH whereas trypsin was able to trigger germinal vesicle breakdown (GVBD) regardless of pH; in addition spontaneous maturation was not affected by removal of follicle cells or by inhibiting junctional communication between oocyte and follicle cells. Taken together these results imply: (i) Ca2+ and Na+ currents are involved in meiotic progression, growth, and acquisition of meiotic competence; (ii) trypsin-like molecules may have a role as candidates for providing the physiological stimulus to resume meiosis. Finally, we provide evidence that follicle cells in Ciona are not involved in triggering GVBD as it occurs in other ascidians. Mol. Reprod. Dev. 76: 1084,1093, 2009. © 2009 Wiley-Liss, Inc. [source]

Expression pattern of the maternal factor zygote arrest 1 (Zar1) in bovine tissues, oocytes, and embryos

MOLECULAR REPRODUCTION & DEVELOPMENT, Issue 4 2004
Tiziana A.L. Brevini
Abstract Zygote arrest 1 (Zar1) is an ovary-specific maternal factor that plays an essential role during the oocyte-to-embryo transition in mouse. In this species, Zar1 expression is strictly limited to the oocyte, the zygote and, at a lower level, the 2-cell embryo. Aim of the present study was to analyze the presence and the expression pattern of the Zar1 ortholog in bovine tissues and embryos. Reverse transcription (RT)-polymerase chain reaction (PCR) analysis was performed in a panel of bovine tissues, in oocytes and pre-implantation in vitro produced embryos. The results demonstrated that a Zar1 ortholog is present in cattle. In the adult, the gene is expressed in ovary, testis, muscle, and myocardium. The gene is also expressed in the oocyte, the zygote, and in all the stages of embryonic development until blastocyst formation. A semi-quantitative RT-PCR analysis revealed that Zar1 levels are constant through in vitro development with the exception of the 4-cell stage, when a significant increase is observed. The exposure of fertilized oocytes to the RNA polymerase II inhibitor alpha-amanitin was able to suppress this Zar1 increase indicating that transcription of this gene occurs at the 4-cell stage. Zar1 is conserved in cattle but has an expression pattern different from the mouse. In particular, Zar1 expression in the adult is not limited to the ovary and in the embryo is expressed well beyond the oocyte to embryo transition. Moreover, the identification of Zar1 transcription at the 4-cell stage represents the first characterization of one of the genes expressed in cattle embryos before the major onset of embryonic transcription. Mol. Reprod. Dev. 69: 375,380, 2004. © 2004 Wiley-Liss, Inc. [source]

Maternal chromatin remodeling during maturation and after fertilization in mouse oocytes

MOLECULAR REPRODUCTION & DEVELOPMENT, Issue 2 2004
Marcella Spinaci
Abstract Immunofluorescence staining with antibodies against acetylated histone H4 and 5-methylcytosine was carried out to investigate female chromatin remodeling throughout oocyte maturation and chromatin rearrangement involving both male and female genomes after fertilization. Oocyte cytoplasm remodels female chromatin in preparation of the fertilizing event and the subsequent chromatin rearrangement. Histone H4 are in fact progressively deacetylated whereas demethylating enzymes do not seem to be active over this period. The acetylase/deacetylase balance seems to be cell cycle dependent as female chromatin is deacetylated during maturation and reacetylated at telophase II stage both after fertilization and activation. On the contrary, DNA demethylation seems to be strictly selective. It is in fact confined to the remodeling of paternal genome after fertilization of mature oocytes as the ooplasm is not effective in demethylating either paternal chromatin in germinal vesicle breakdown (GVBD) fertilized oocytes or maternal genome of partenogenetically activated oocytes. Surprisingly, we induced maternal chromatin demethylation after fertilization by treating oocytes with a combination of a methyltransferase inhibitor, 5-azacytidine (5-AzaC), and a reversible and specific inhibitor of histone deacetylase, trichostatin A (TSA). This treatment likely induces a hyperacetylation of histones (thus favoring the access to demethylating enzymes by opening female chromatin structure) associated with a block of reparative methylation by inhibiting methytransferases. This manipulation of chromatin remodeling may have applications regarding the biological significance of aberrant DNA methylation. Mol. Reprod. Dev. 69: 215,221, 2004. © 2004 Wiley-Liss, Inc. [source]