Cloning of cells from peri-implantation embryos by blastocyst injection was used to investigate the time of X-chromosome inactivation in that part of the ectoderm lineage giving rise to foetal tissues of the mouse. Matings were arranged so that the two X-chromosomes of female donor cells controlled two distinct coat colours and host blastocysts were of a third colour genotype. No coat chimaeras were obtained in experiments using donor cells from the primitive ectoderm of 6th or 7th day embryos or from lactationally delayed implanting or reactivated blastocysts. In contrast, a minimum of 80 unequivocal coat chimaeras were obtained in experiments in which primitive ectoderm cells from 5th day implanting blastocysts were used for injection. The majority of these chimaeras that had received a female cell exhibited both donor colours in addition to host colour in their coats, suggesting that the donor cell had not undergone X-inactivation until one or more cycles after transplantation. The remainder of such chimaeras exhibited only one or other donor coat colour. Determination of the parental origin of the allocyclic X-chromosome in donor metaphase preparations in internal tissues of several chimaeras revealed that the coat pattern did not always reflect the X-activity status of the donor cell clone as a whole. Nevertheless, the findings suggest that X-inactivation takes place shortly after implantation in the primitive ectoderm cell population from which the foetus is derived. Of the 68 chimaeras in which the sex of both the donor and host component was established 62 proved to be fertile. Furthermore, 21 of the 37 fertile chimaeras whose sex corresponded with that of the donor cell yielded functional gametes of donor origin. Injection of cells from a single donor blastocyst into a series of host blastocysts established that at least 2 cells in 5th day primitive ectoderm can give rise to both somatic cells and functional germ cells among their mitotic descendants.
Download full-text PDF |
Source |
|---|
Publication Analysis
Top Keywords
Similar Publications
Trans-scale live-imaging of an E5.5 mouse embryo using incubator-type biaxial light-sheet microscopy.
Life Sci Alliance
March 2025
https://ror.org/023rffy11 Laboratory for Developmental Dynamics, RIKEN Center for Biosystems Dynamics Research (BDR), Kobe, Japan
During mouse embryonic development, the embryonic day (E) 5.5 stage represents a crucial period for the formation of the primitive body axis, where the symmetry breaking of cellular states influences the multicellular system. Elucidating the detailed mechanisms of this process necessitates a trans-layered dynamic observation of the embryo and all internal cells.
View Article and Find Full Text PDFAxillary lesion in a young adult ends up to a peculiar diagnosis: primitive neuro-ectodermal tumor (PNET) of ulnar nerve: a rare case report.
Ann Med Surg (Lond)
October 2024
Department of Pathology, Golsar Hospital, Rasht, Guilan, Iran.
Article Synopsis
- Primitive neuro-ectodermal tumor (PNET) is a rare and aggressive tumor mainly affecting children and young adults, with very few documented cases found in peripheral nerves.
- A 30-year-old male presented with symptoms leading to the discovery of a PNET in the axillary region, diagnosed through imaging and confirmed via histopathological analysis after surgical removal.
- Accurate diagnosis is essential, as treatment typically includes surgical resection combined with chemotherapy and radiotherapy, highlighting the need to consider PNET in differential diagnoses of masses in the axillary area.
A possible origin of the inverted vertebrate retina revealed by physical modeling.
J Biol Phys
December 2024
Independent Researcher, Waalre, The Netherlands.
The evolutionary origin of the inverted retina in the vertebrate eye is unknown. This paper explores a hypothetical evolutionary scenario that explains the unique orientation of the photoreceptors in the vertebrate retina. The proposed scenario follows the scientific accepted scenario for eye evolution and gradually builds up towards an eye prototype by considering light direction detection and increase in achievable spatial resolution as the driving forces.
View Article and Find Full Text PDFThe organizer and neural induction in birds and mammals.
Curr Top Dev Biol
April 2024
Department of Cell and Developmental Biology, University College London, London, United Kingdom. Electronic address:
In avian and mammalian embryos the "organizer" property associated with neural induction of competent ectoderm into a neural plate and its subsequent patterning into rostro-caudal domains resides at the tip of the primitive streak before neurulation begins, and before a morphological Hensen's node is discernible. The same region and its later derivatives (like the notochord) also have the ability to "dorsalize" the adjacent mesoderm, for example by converting lateral plate mesoderm into paraxial (pre-somitic) mesoderm. Both neural induction and dorsalization of the mesoderm involve inhibition of BMP, and the former also requires other signals.
View Article and Find Full Text PDFGastrulation: Its Principles and Variations.
Results Probl Cell Differ
March 2024
Osaka University, Suita, Osaka, Japan.
As epiblast cells initiate development into various somatic cells, they undergo a large-scale reorganization, called gastrulation. The gastrulation of the epiblast cells produces three groups of cells: the endoderm layer, the collection of miscellaneous mesodermal tissues, and the ectodermal layer, which includes the neural, epidermal, and associated tissues. Most studies of gastrulation have focused on the formation of the tissues that provide the primary route for cell reorganization, that is, the primitive streak, in the chicken and mouse.
View Article and Find Full Text PDFWant AI Summaries of new PubMed Abstracts delivered to your In-box?
Enter search terms and have AI summaries delivered each week - change queries or unsubscribe any time!