A study of embryotrophic mechanism of human oviductal cells on mouse embryo development in vitro

Xu, Jiasen.

January 2000

Thesis (Ph.D.)--University of Hong Kong, 2001. / Includes bibliographical references (leaves 182-211) Also available in print.

Phage Display to Identify Peptides Binding to or Penetrating the Mouse Zona Pellucida

Lowe, Jeanette

11 July 1999

The objective of this study was to identify peptide ligands, using phage display techniques, which bind sites on mouse embryos, ovaries, cytoplasmic membranes and/or intracytoplasmic components. Specifically, M13 coliphage 7-mer, 12-mer and 15-mer random peptide libraries were used separately for biopanning. Peptides derived from the amplified pools were sequenced and studied. The phage display for in vivo ovary experiments yielded no pool of peptides after two cycles of biopanning and re-amplification. With the same initial concentration of a random 7-mer or 12-mer library, there were repeating sequences derived after three and four biopanning cycles on mouse embryos and unfertilized ova. The sequences were not distinguishable from a control group. Subsequent experimentation using a random 15-mer library to select for internalized phage-peptides yielded two apparent consensus sequences, RNVPPIFNDVYWIAF (9/32 or 28%) and HGRFILPWWYAFSPS (11/32 or 34%). The 15-mer control group yielded no clones. The deduced peptide sequences were compared to known sequences to ascertain their uniqueness. No significant similarities were found, yielding two possible novel motifs. Through this adapted process of phage display and further research, the phage display technology may be used as a tool in the recognition of specific mouse gamete sites. By identifying binding sites of mouse gametes, the peptides might be exploited as a means of studying the embryo cell surface or cytoplasmic components and mouse sperm-egg interactions. Such peptides may also be used for macromolecule delivery in transfection or transgenesis. / Master of Science

phage display

zona pellucida

mouse embryology

transgenesis

Investigating TGFβ signals in cell fate specification in the early mouse embryo

Senft, Anna Dorothea

January 2016

TGFβ signalling via Smad transcription factors is essential for axis patterning and subsequent cell fate specification during mammalian embryogenesis. However, the cellular and molecular mechanisms have been difficult to characterise in vivo due to early embryonic lethality of mouse mutants and redundant functional activities. Here I show that combined deletion of closely related Smad2 and Smad3 in mouse embryonic stem cells impairs induction of lineage specific gene expression during differentiation, while extra-embryonic gene expression is up-regulated. Preliminary data suggest that the underlying mechanism of this differentiation defect reflects the inability of Smad2/3^-/- cells to establish lineage priming. Collectively, these findings identify novel downstream target genes controlled by Smad2/3 and an absolute requirement for Smad2/3 during embryonic differentiation. TGFβ signalling via Smad1 and Smad4 is essential for induction of the transcription factor Blimp1 required for primordial germ cell specification. The direct upstream regulators of Blimp1 are unknown, but T-box factors have recently been suggested to play a role. In a second project, I performed tissue- specific ablation of the T-box transcription factor Eomes as well as components of the TGFβ signalling pathway in either the visceral endoderm or the epiblast to examine tissue-specific functions for Blimp1 induction. I show that Eomes and Smad2 functions in the visceral endoderm as well as Eomes function in the epiblast are dispensable for Blimp1 induction, but rather are required to restrict Blimp1 induction to posterior epiblast cells. In contrast, epiblast-specific Smad4 or Smad1 mutants fail to robustly induce Blimp1 in the epiblast. My preliminary analysis suggests that competence to induce primordial germ cell fate is dependent on the interplay of Smad2/Eomes functions in the visceral endoderm and Smad1/4 functions in the epiblast. Collectively, this thesis provides insight into the transition from pluripotency to cell fate specification in the mammalian embryo that is impossible to obtain from human embryos in vivo.