Neoplastic embryoid bodies of embryonal carcinoma C44 as a source of blastocele-like fluid

Abstract. There is a cytotoxic activity in blastocele fluid that kills embryonal carcinoma cells with trophectodermal potential but spares those with embryonic potential [26]. This activity is present when programmed cell death occurs in the inner cell mass (ICM), and the ICM loses its trophectodermal potential [5, 8–10]. Because of the paucity of blastocele fluid, cystic embryoid bodies of embryonal carcinoma C44 were examined ultrastructurally and in tissue culture to determine if they corresponded to late blastocysts and if their fluid corresponded to blastocele fluid. No troph-ectoderm was demonstrated in the embryoid bodies, but embryonal carcinoma and endoderm were present, leading to the conclusion that the embryonal carcinoma corresponded to late ICM that had expressed endodermal potential. As a result the cyst fluid might have contained the toxic activity of blastocele fluid. The cyst fluid of C44 embryoid bodies did contain a soluble, low-molecular-weight, cytotoxic activity that preferentially killed embryonal carcinoma cells with trophectodermal potential while sparing those with embryonic potential. Enough of this fluid was available to determine the chemical nature of this toxic activity.     

Amine oxidases, programmed cell death, and tissue renewal

Embryonal carcinoma cells, with embryonic (ECaE) or trophectodermal (ECaT) potential, have been used in a colony assay to determine regulatory mechanisms in the blastocyst. The mechanism that regulates ECaE and results in chimera formation is dependent upon a soluble factor in blastocoele fluid and contact with trophectoderm. Two mechanisms contribute to the regulation of ECaT: one involves a factor in blastocoele fluid and the other contact with either trophectoderm or inner cell mass which results in differentiation of the cells into trophectoderm, and the other involves the killing of at least 40% of the cells by blastocoele fluid alone. This cytotoxic activity probably causes the programmed cell death that occurs in the inner cell mass during blastulation as it loses the potential to differentiate into trophectoderm. A toxic activity similar to that of normal blastocysts has been obtained from embryoid bodies. This activity is caused by amine oxidase-dependent catabolism of polyamines, and it is postulated that programmed cell death in the embryo and chalone activity in the adult may have similar mechanisms.     

Hydrogen peroxide as a mediator of programmed cell death in the blastocyst

Previous work identified in blastocele fluid a soluble activity which killed embryonal carcinoma cells with trophectodermal potential but not those with embryonic potential [35]. From use of a malignant caricature of the late blastocyst, this toxic activity was postulated to be H2O2 [8]. The purpose of this paper was to determine if blastocele fluid also contained amounts of H2O2 capable of mediating the preferential killing of malignant pretrophectodermal cells (ECa 247). We not only observed that blastocele fluid is not toxic for these cells in the presence of catalase, but that malignant cells with embryonic potential (P19) that normally survive exposure to blastocele fluid become sensitive to it if their intracellular glutathione levels are lowered. Thus, it is concluded that the blastocyst contains amounts of H2O2 toxic to malignant pretrophectodermal cells and that glutathione-dependent mechanisms protect malignant inner cell mass cells with embryonic potential. Apparently, H2O2 production and glutathione-dependent protection mechanisms are developmentally regulated in the inner cell mass. These results are discussed with regards to apoptosis and the regulation of tissue mass.     

Carcinoma is to Embryology as Mutation is to Genetics

Experiments are reviewed that indicate embryonic fields arecapable of regulating the neoplastic attributes of their closelyrelated carcinomas. In the case of blastocyst regulation ofembryonal carcinoma cells the reaction is mediated by contactof the cancer cells with trophectodermal cells in the presenceof blastocele fluid. In the case of regulation of melanoma,the reaction is mediated in the embryonic skin at the time normalmelanocytes migrate into it. A diffusible factor that inhibitscell division and seems to affect differentiation is involved.In the case of neuroblastoma, a degree of regulation is demonstrablein the neural crest migratory pathway, but the maximal effectis found in the adrenal, renal, and testicular primordia. Afactor inhibitory of mitosis for adenocarcinoma of the breastcan be demonstrated in the breast primordium. It is concludedthat there must be an embryonic field capable of regulatingevery kind of carcinoma: understanding of the phenomena maylead to a noncytotoxic cure for carcinoma, and through the useof cancer cells as probes of embryonic development to an understandingof embryonic induction.     

Functions of amine oxidases in plant development and defence

Copper amine oxidases and flavin-containing amine oxidases catalyse the oxidative de-amination of polyamines, which are ubiquitous compounds essential for cell growth and proliferation. Far from being only a means of degrading cellular polyamines and, thus, contributing to polyamine homeostasis, amine oxidases participate in important physiological processes through their reaction products. In plants, the production of hydrogen peroxide (H(2)O(2)) deriving from polyamine oxidation has been correlated with cell wall maturation and lignification during development as well as with wound-healing and cell wall reinforcement during pathogen invasion. As a signal molecule, H(2)O(2) derived from polyamine oxidation mediates cell death, the hypersensitive response and the expression of defence genes. Furthermore, aminoaldehydes and 1,3-diaminopropane from polyamine oxidation are involved in secondary metabolite synthesis and abiotic stress tolerance.     

Oxidation of Polyamines and Brain Injury

Several amine oxidases are involved in the metabolism of the natural polyamines putrescine, spermidine, and spermine, and play a role in the regulation of intracellular concentrations, and the elimination of these amines. Since the products of the amine oxidase-catalyzed reactions - hydrogen peroxide and aminoaldehydes - are cytotoxic, oxidative degradations of the polyamines have been considered as a cause of apoptotic cell death, among other things in brain injury. Since a generally accepted, unambiguous nomenclature for amine oxidases is missing, considerable confusion exists with regard to the polyamine oxidizing enzymes. Consequently the role of the different amine oxidases in physiological and pathological processes is frequently misunderstood. In the present overview the reactions, which are catalyzed by the different polyamine-oxidizing enzymes are summarized, and their potential role in brain damage is discussed.     

Induction of hypersensitive cell death by hydrogen peroxide produced through polyamine degradation in tobacco plants

Screening immediate-early responding genes during the hypersensitive response (HR) against tobacco mosaic virus infection in tobacco (Nicotiana tabacum) plants, we identified a gene encoding ornithine decarboxylase. Subsequent analyses showed that other genes involved in polyamine biosynthesis were also up-regulated, resulting in the accumulation of polyamines in apoplasts of tobacco mosaic virus-infected leaves. Inhibitors of polyamine biosynthesis, alpha-difluoromethyl-ornithine, however, suppressed accumulation of polyamines, and the rate of HR was reduced. In contrast, polyamine infiltration into a healthy leaf induced the generation of hydrogen peroxide and simultaneously caused HR-like cell death. Polyamine oxidase activity in the apoplast increased up to 3-fold that of the basal level during the HR, and its suppression with a specific inhibitor, guazatine, resulted in reduced HR. Because it is established that hydrogen peroxide is one of the degradation products of polyamines, these results indicate that one of the biochemical events in the HR is production of polyamines, whose degradation induces hydrogen peroxide, eventually resulting in hypersensitive cell death.     

A sensitive, rapid, chemiluminescence-based method for the determination of diamines and polyamines

A new sensitive and rapid chemiluminescence-based method for the determination of diamines and polyamines is described. Phosphocellulose paper strips are used for the removal of neutral or negatively charged molecules from polyamine-containing fluid. The procedure is based on the determination of hydrogen peroxide, produced during the oxidation of polyamines, by a fairly specific serum amine oxidase. A plant diamine oxidase is used for the assay of diamines. This method permits the determination of diamines and polyamines in a range of 10 to 100 pmol and may be used for the assay of urinary polyamines.     

Post-implantation development of demi-embryos and induction of decidual cell reaction in mice

Mouse demi-embryos that developed from bisected morulae were transferred to recipients. The eu-blastocysts (distinct inner cell mass and well-developed trophectoderm) contained cells equal to 51% of the controls that developed from zona-free morulae. The rate of decidual cell reaction induced by the eu-blastocysts was not significantly different from that of the controls, but the size of the deciduum containing the egg cylinder was significantly smaller on Day 5.5 of pregnancy (P < 0.001). A significant increase in embryonic loss was observed from Day 7.5 to Day 9.5 in the eu-blastocysts (P < 0.05), while the controls exhibited no significant difference. Although the embryos from the eu-blastocysts showed retardation of developmental stages and decreased size, they attained normal stages and size regulation up to 90% of that of the control on Day 10.5. The pseudo-blastocysts (poorly developed inner cell mass enclosed by trophectoderm) contained cells equal to 25% of those of the controls and showed less than a 10% developmental rate to the egg cylinder stage. The trophectodermal vesicles (no enclosed cells) and nonintegrated forms (disorganized clusters of cells) contained cells less than 18% of those of the controls. They showed lower rates of decidual cell reaction than those in the controls (P < 0.05), and no egg cylinder was found in the deciduum. The results indicate that a severe decrease in the number of embryonic cells affects the regulation of embryonic development and decidual cell reaction in the uterus.     

Polyamine oxidase is one of the key elements for oxidative burst to induce programmed cell death in tobacco cultured cells

Programmed cell death plays a critical role during the hypersensitive response in the plant defense system. One of components that triggers it is hydrogen peroxide, which is generated through multiple pathways. One example is proposed to be polyamine oxidation, but direct evidence for this has been limited. In this article, we investigated relationships among polyamine oxidase, hydrogen peroxide, and programmed cell death using a model system constituted of tobacco (Nicotiana tabacum) cultured cell and its elicitor, cryptogein. When cultured cells were treated with cryptogein, programmed cell death occurred with a distinct pattern of DNA degradation. The level of hydrogen peroxide was simultaneously increased, along with polyamine oxidase activity in apoplast. With the same treatment in the presence of alpha-difluoromethyl-Orn, an inhibitor of polyamine biosynthesis, production of hydrogen peroxide was suppressed and programmed cell death did not occur. A gene encoding a tobacco polyamine oxidase that resides in the apoplast was isolated and used to construct RNAi transgenic cell lines. When these lines were treated with cryptogein, polyamines were not degraded but secreted into culture medium and hydrogen peroxide was scarcely produced, with a concomitant suppression of cell death. Activities of mitogen-activated protein kinases (wound- and salicylic acid-induced protein kinases) were also suppressed, indicating that phosphorylation cascade is involved in polyamine oxidation-derived cell death. These results suggest that polyamine oxidase is a key element for the oxidative burst, which is essential for induction of programmed cell death, and that mitogen-activated protein kinase is one of the factors that mediate this pathway.     

Cell death activation during cavitation of embryoid bodies is mediated by hydrogen peroxide

The formation of the proamniotic cavity is the first indication of programmed cell death associated to a morphogenetic process in mammals. Although some growth factors have been implicated in proamniotic cavitation, very little is known about the intracellular mechanisms that control the cell death process itself. Reactive oxygen species (ROS) are potent activators of cell death, thus, in the present work we evaluated the role of ROS during the cavitation of embryoid bodies (EBs), a common model to study proamniotic cavitation. During cavitation, ROS concentration increases in the inner cells of EBs, and this ROS accumulation appears to be associated with the mitochondrial respiratory activity. In agreement with a role of ROS in cavitation, EBs derived from ES cells that overproduce catalase, an enzyme that specifically degrades hydrogen peroxide, do not cavitate, and caspase activation and cell death is markedly decreased. Notably, cell death, but not the rise in ROS, during EB cavitation is caspase-dependent. The apoptosis-inducing factor (Aif) is released from the mitochondria during cavitation, but EBs derived from Aif^−/y ES cells cavitate and ROS levels in the inner cells remain high. We conclude that hydrogen peroxide is a cell death activating signal essential for EB cavitation, suggesting that cell death during proamniotic cavitation is mediated by ROS.     

Differential role of hydrogen peroxide and staurosporine in induction of cell death in glioblastoma cells lacking DNA-dependent protein kinase

Various DNA double-strand break repair mechanisms, in which DNA-dependent protein kinase (DNA-PK) has a major role, are involved both in the development and treatment of glioblastoma. The aim of the present study was to investigate how glioblastoma cells responded to hydrogen peroxide and staurosporine (STS) and how such a response is related to DNA-PK. Two human glioblastoma cell lines, M059J cells that lack DNA-PK activity, and M059K cells that express a normal level of DNA-PK, were exposed to hydrogen peroxide or STS. The response of the cells to hydrogen peroxide or STS was recorded by measuring cell death, which was detected by three different methods—MTT, annexin-V and propidium iodide staining, and JC-1 mitochondrial probe. The result showed that both hydrogen peroxide and STS were able to induce cell death of the glioblastoma cells and that the former was mainly associated with necrosis and the latter with apoptosis. Glioblastoma cells lacking DNA-PK were less sensitive to STS treatment than those containing DNA-PK. However, DNA-PK had no significant influence on hydrogen peroxide treatment. We further found that catalase, an antioxidant enzyme, could prevent cell death induced by hydrogen peroxide but not by STS, suggesting that the pathways leading to cell death by hydrogen peroxide and STS are different. We conclude that hydrogen peroxide and STS have differential effects on cell death of glioblastoma cells lacking DNA-dependent protein kinase. Such differential roles in the induction of glioblastoma cell death can be of significant value in selecting and/or optimizing the treatment for this malignant brain tumor.     

Single inner cell masses yield embryonic stem cell lines differing in lifr expression and their developmental potential

The unique differentiation potential of inner cell mass derived embryonic stem cells together with their outstanding self-renewal capacity makes them a desirable source for somatic cell therapy of human diseases. Somatic cells are gained by in vitro differentiation of embryonic stem cells, however, the differentiation potential of embryonic stem cells varied even between isogenic cell lines. Variable differentiation potentials may either be a consequence of an inherent inhomogeneity of gene expression in the inner cell mass or may have technical reasons. To understand variations in the differentiation potential, we generated pairs of isogenic, monozygotic twin, and single inner cell mass derived clonal embryonic stem cell lines, and demonstrate that they differentially express the leukaemia inhibitory factor receptor gene. Variations of leukaemia inhibitory factor receptor protein levels are already evident in the inner cell mass and predispose the cardiomyogenic potential of embryonic stem cell lines in a Janus activated kinase dependent manner. Thus, a single inner cell mass may give rise to embryonic stem cell lines with different developmental potentials.     

Culturing the epiblast cells of the pig blastocyst

Summary Pig epiblast cells that had been separated from other early embryonic cells were cultured in vitro. A three-step dissection protocol was used to isolate the epiblast from trophectoderm and primitive endoderm before culturing. Blastocysts collected at 7 to 8 days postestrus were immunodissected to obtain the inner cell mass (ICM) and destroy trophectodermal cells. The ICM was cultured for 2 to 3 days on STO feeder cells. The epiblast was then physically dissected free of associated primitive endoderm. Epiblast-derived cells, grown on STO feeders, produced colonies of small cells resembling mouse embryonic stem cells. This primary cell morphology changed as the colonies grew and evolved into three distinct colony types (endodermlike, neural rosette, or complex). Cell cultures derived from these three colony types spontaneously differentiated into numerous specialized cell types in STO co-culture. These included fibroblasts, endodermlike cells, neuronlike cells, pigmented cells, adipogenic cells, contracting muscle cells, dome-forming epithelium, ciliated epithelium, tubule-forming epithelium, and a round amoeboid cell type resembling a plasmacyte after Wright staining. The neuronlike cells, contracting muscle cells, and tubule-forming epithelium had normal karyotypes and displayed finite or undefined life spans upon long-term STO co-culture. The dome-forming epithelium had an indefinite life span in STO co-culture and also retained a normal karyotype. These results demonstrate the in vitro pluripotency of pig epiblast cells and indicate the epiblast can be a source for deriving various specialized cell cultures or cell lines.     

Iron prochelator BSIH protects retinal pigment epithelial cells against cell death induced by hydrogen peroxide

Dysregulation of localized iron homeostasis is implicated in several degenerative diseases, including Parkinson’s, Alzheimer’s, and age-related macular degeneration, wherein iron-mediated oxidative stress is hypothesized to contribute to cell death. Inhibiting toxic iron without altering normal metal-dependent processes presents significant challenges for standard small molecule chelating agents. We previously introduced BSIH (isonicotinic acid [2-(4,4,5,5-tetramethyl-[1,3,2]dioxaborolan-2-yl)-benzylidene]-hydrazide) prochelators that are converted by hydrogen peroxide into SIH (salicylaldehyde isonicotinoyl hydrazone) chelating agents that inhibit iron-catalyzed hydroxyl radical generation. Here, we show that BSIH protects a cultured cell model for retinal pigment epithelium against cell death induced by hydrogen peroxide. BSIH is more stable than SIH in cell culture medium and is more protective during long-term experiments. Repetitive exposure of cells to BSIH is nontoxic, whereas SIH and desferrioxamine induce cell death after repeated exposure. Combined, our results indicate that cell protection by BSIH involves iron sequestration that occurs only when the cells are stressed by hydrogen peroxide. These findings suggest that prochelators discriminate toxic iron from healthy iron and are promising candidates for neuro- and retinal protection.     

Cellular and subcellular localization of stathmin during oocyte and preimplantation embryo development

Stathmin is a 19 kDa cytosolic phosphoprotein, proposed to act as a relay integrating diverse intracellular signaling pathways involved in regulation of cell proliferation, differentiation, and function. To gain further information about its significance during early development, we analyzed stathmin expression and subcellular localization in mouse oocytes and preimplantation embryos. RT‐PCR analysis revealed a low expression of stathmin mRNA in unfertilized oocytes and a higher expression at the blastocyst stage. A fine cytoplasmic punctuate fluorescent immunoreactive stathmin pattern was detected in the oocyte, while it evolved toward an increasingly speckled pattern in the two‐cell and later four‐ to eight‐cell embryo, with even larger speckles at the morula stage. In blastocysts, stathmin immunoreactivity was fine and intense in inner cell mass cells, whereas it was low and variable in trophectodermal cells. Electron microscopic analysis allowed visualization with more detail of two types of stathmin immunolocalization: small clusters in the cytoplasm of oocytes and blastocyst cells, together with loosely arranged clusters around the outer membrane of cytoplasmic vesicles, corresponding to the immunofluorescent speckles in embryos until the morula stage. In conclusion, it appears from our results that maternal stathmin is accumulated in the oocyte and is relocalized within the oocyte and early preimplantation embryonic cell cytoplasm to interact with specific cytoplasmic membrane formations. Probably newly synthesized, embryonic stathmin is expressed in the blastocyst, where it is localized more uniformly in the cytoplasm mostly of inner cell mass (ICM) cells. These expression and localization patterns are probably related to the particular roles of stathmin at the successive steps of oocyte maturation and early embryonic development. They further support the proposed physiologic importance of stathmin in essential biologic regulation. Mol. Reprod. Dev. 53:306–317, 1999. © 1999 Wiley‐Liss, Inc.