The amnioserosa is an apomorphic character of cyclorrhaphan flies

In developing insect eggs the cells of the blastoderm adopt either an embryonic or an extraembryonic fate. The extraembryonic tissue consists of epithelia, termed amnion and serosa, which wrap the germ band embryo. The serosa develops directly from part of the blastoderm and surrounds the embryo as well as the yolk. The amnion develops from the margins of the germ band and in most insect species generates a transient ventral cavity for the developing embryo. The amniotic cavity and the serosa have been reduced in the course of dipteran evolution. The insect order of Diptera includes the paraphyletic Nematocera, including gnats and mosquitoes, and the more derived monophyletic Brachycera, the true flies. Nematocera develop within an amniotic cavity and the surrounding serosa, whereas cyclorrhaphan Brachycera do not. This observation implies that the amnion and serosa have been reduced before the radiation of the monophyletic cyclorrhaphan flies. Here I show that an amniotic cavity is formed during embryogenesis of the horsefly Haematopota pluvialis (Tabanidae) and the dancefly Empis livida (Empididae). The results suggest that extraembryonic tissue was reduced in the stem lineage of cyclorrhaphan flies, with consequences for the molecular basis of pattern formation along the anterior-posterior axis of the embryo. Received: 21 October 1999 / Accepted: 17 January 2000     

Tribolium embryogenesis: a SEM study of cell shapes and movements from blastoderm to serosal closure

Embryogenesis in the beetle Tribolium is of increasing interest to both molecular and evolutionary biology because it differs from the Drosophila paradigm by its type of segment specification (short- vs. long-germ) and by the extensive epithelial envelopes – amnion and serosa – that are typical of most insects but not of higher dipterans. Using scanning electron microscopy of DAPI staged embryos we document development in Tribolium castaneum from blastoderm to completion of the envelopes, recording many details not otherwise accessible; we also provide a time table of the respective stages at 30°C. The nascent blastoderm cells remain basally confluent with the yolksac until after the 13th (=last synchronous) mitotic cycle. The cells in the prospective serosa – the first domain to segregate visibly from the uniform blastoderm – carry surface protrusions likely to contact the overlying vitelline envelope. The embryonic rudiment, the other (and larger) blastodermal domain, gives rise to amnion and germ anlage. In the latter, visible differentiation begins with a ”primitive pit” reminiscent of the posterior midgut rudiment of Drosophila. The subsequent invagination of the mesoderm resembles Drosophila gastrulation, except in the head region where the median groove extends through the entire preoral region. The prospective amnion starts differing visibly from the germ anlage during early gastrulation. It then folds underneath the spreading serosa and, advancing with the latter, closes the amniotic cavity at the ventral face of the germband. The largest (=posterior) amniotic fold covers a crestlike protrusion of the yolksac. Together with marked changes in the shape and arrangement of the amnion cells, this protrusion may contribute to the fold’s elevation and early progress. Received: 12 August 1999 / Accepted: 4 November 1999     

Placenta-derived stem cells: new hope for cell therapy?

An urgent current need in regenerative medicine is that of identifying a plentiful, safe and ethically acceptable stem cell source for the development of therapeutic strategies to restore functionality in damaged or diseased organs and tissues. In this context, human term placenta represents a prime candidate, as it is available in nearly unlimited supply, is ethically problem-free and easily procured. Placental cells display differentiation capacity toward all three germ layers, while also displaying immunomodulatory effects, therefore supporting the possibility that they could be applied in an allogeneic transplantation setting. Although promising data have been reported to date, further study is required to fully characterize the differentiation potential of placenta-derived cells and to identify their possible clinical applications. Here, we provide a snapshot of current knowledge regarding the potential of cells from the amniotic membrane of human term placenta to address current shortcomings in the field of regenerative medicine.     

Fusion of epithelial sheets as seen in formation of the chick amnion

Summary Fusion of the amniotic folds over the chick embryo provides an example of epithelial fusion in which one group of ectodermal cells appears to contribute to traction and a second group appears to respond by moving to the midline, becoming internalized and degenerating. Neutral red staining of living embryos and transmission electron microscopy indicate that a patch of dying cells is present in the fusion region. Scanning electron microscopy shows that ectoderm cells at the rim of the amniotic folds are cylindrical in shape with long axes oriented parallel to the rim. These cells have a smooth surface, but show increasing amounts of blebbing toward the midline. Characteristically, a globular region of rounded cells showing extreme blebbing is present at the midline. Just anterior to the globular region, flattened cells are present on the surface with many taut cellular processes. Orientation of ectodermal cells around the region of fusion suggests that traction is exerted from these flattened cells. When treated with cytochalasin D, posterior progression of the zone of fusion is blocked. Also, the flattened cells anterior to the globular region round up, revealing many elongated, anteriorly-directed cytoplasmic processes presumably leading to sites of original attachment.     

Über das Vorkommen eines spezifischen Enzyms der Glucuronsäurebildung im menschlichen Amnion

Zusammenfassung Die Amnien von reifen menschlichen Plazenten wurden auf das Vorkommen der Uridindiphosphatglucose-Dehydrogenase (UDPG-DH), eines Enzyms der Glucuronsäurebildung, untersucht. Dabei konnte sowohl in den Zellen des Amnionepithels als auch in den Fibroblasten des Amnionmesenchyms eine hohe Aktivität festgestellt werden. Die Bedeutung dieses Befundes im Amnion wird im Zusammenhang mit der Stellung der Glucuronsäure im intermediären Stoffwechsel besprochen.

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About the existence of a specific enzyme for the synthesis of glucuronic acid in the human amnion

Summary In order to trace uridine diphosphate glucose dehydrogenase, an enzyme for the synthesis of glucuronic acid, the amnions of mature human placentas were investigated. High activity could be found in the amniotic epithelium as well as in the fibroblasts of the amniotic mesenchyma. These findings are discussed in connection with the task of glucuronic acid in general biological pathways.

Wir danken Herrn Dr. med. vet. J. Schlüns (Institut für Veterinär-Anatomie der Freien Universität Berlin) für wertvolle Ratschläge, unserer technischen Assistentin Frau E. Hartleben für die Unterstützung bei der Bearbeitung des Materials.     

The heptamer sgRNA targeting the human OCT4 mRNA can upregulate the OCT4 expression

TRUE gene silencing is one of the gene suppression technologies. This technology exploits the enzymatic property of the tRNA 3′ processing endoribonuclease tRNase Z^L, which is that it can cleave a target RNA under the direction of a small guide RNA (sgRNA). We have been working on the development of therapeutic sgRNAs for hematological malignancies. In the course of an experiment to examine the ability of the heptamer-type sgRNA H15792 targeting the OCT4 mRNA to differentiate human amnion stem cells, we observed unexpectedly that the amnion cells exhibited a morphology resembling initialized cells. Here we investigated the effect of H15792 on human HL60 leukemia cells, and found that H15792 can upregulate the OCT4 expression and the expression of alkaline phosphatase in the cells.