Temporal expression of pluripotency-associated transcription factors in sheep and cattle preimplantation embryos.

SummaryPluripotency-associated transcription factors (PATFs) modulate gene expression during early mammalian embryogenesis. Despite a strong understanding of PATFs during mouse embryogenesis, limited progress has been made in ruminants. This work aimed to describe the temporal expression of eight PATFs during both sheep and cattle preimplantation development. Transcript availability of PATFs was evaluated by reverse transcriptase quantitative polymerase chain reaction (RT-qPCR) in eggs, cleavage-stage embryos, morulae, and blastocysts. Transcripts of five genes were detected in all developmental stages of both species (KLF5, OCT4, RONIN, ZFP281, and ZFX). Furthermore, CMYC was detected in all cattle samples but was found from cleavage-stage onwards in sheep. In contrast, NR0B1 was detected in all sheep samples but was not detected in cattle morulae. GLIS1 displayed the most significant variation in temporal expression between species, as this PATF was only detected in cattle eggs and sheep cleavage-stage embryos and blastocysts. In silico analysis suggested that cattle and sheep PATFs share similar size, isometric point and molecular weight. A phenetic analysis showed two patterns of PATF clustering between cattle and sheep, among several mammalian species. In conclusion, the temporal expression of pluripotency-associated transcription factors differs between sheep and cattle, suggesting species-specific regulation during preimplantation development.

Characterization and localization of an ATP-diphosphohydrolase on the external surface of the tegument of Schistosoma mansoni.

An ATP-diphosphohydrolase (EC 3.6.1.5) was identified in the tegumental fraction isolated from Schistosoma mansoni worms. Both ATP and ADP were hydrolyzed to AMP at similar rates by the enzyme. Other nucleotides were also degraded by the tegument enzyme, revealing a broad substrate specificity. Electrophoretic separation of tegumental proteins under non-denaturing conditions followed by addition of ATP or ADP as substrate revealed a single band of activity with similar mobility. In addition, similar heat-inactivation profiles were obtained for ATPase or ADPase activities, indicating that a single enzyme is responsible for degrading both nucleotides. The enzyme was not inhibited by vanadate, levamisole, tetramisole, ouabain or sodium azide. The ADPase activity was not affected by adenosine (5')-pentaphospho-(5')-adenosine (Ap5A) or by an excess of glucose and hexokinase used as an ATP-trapping system, thus excluding the presence of any significant adenylate kinase activity. The ATP-diphosphohydrolase displayed micromolar affinities for both Mg2+ and Ca2+, and the calcium-activated enzyme was inhibited by millimolar Mg2+. In intact live worms a calcium phosphate precipitate was formed on the outer tegumental surface upon incubation of the worms with either ATP or ADP, indicating the ectolocalization of this enzyme. In addition, ultrastructural histochemical localization of the enzyme was obtained. A distinct deposition of lead phosphate granules on the outer surface of the tegument was observed by electron microscopy, in the presence of either ATP or ADP as substrate. It is suggested that the ATP-diphosphohydrolase could regulate the concentration of purine nucleotides around the parasites and hence enable them to escape the host hemostasis by preventing ADP-induced platelet activation.

Beneficial effects of anti-growth hormone antiserum in avian muscular dystrophy.

Human subjects and mice have been found to have a milder progression of muscular dystrophy when the disease is associated with genotypically determined dwarfism. In this paper we describe an experimental test for reducing growth hormone in dystrophic chickens that uses rabbit anti-chicken growth hormone anti-serum (anti-cGH). Antiserum was injected daily into dystrophic (line 413) male chickens from day 1 to day 8 after hatching. Dystrophic chickens injected with anti-cGH maintained a significantly higher score in the standardized test for righting ability (P less than 0.001-0.051) from 3 to 9 1/2 wk after hatching when compared with dystrophic controls. The observed prolongation of the functional ability of injected dystrophic animals suggests that growth hormone plays a role in potentiating the symptoms of dystrophy in chickens.