Differentiation of chick blood island erythroblasts into erythrocytes and stability in long-term culture

Clusters of 20-70 erythroblasts from blood islands of early chick blastoderm were cultured in serum-free chemically defined medium for a 3-month period. The erythroblast cluster produces erythroid cells and hemoglobins characteristic of the primitive and definitive erythroid cell lines. It seems there is a progenitor erythroid cell(s) in the erythroblast cluster which starts and/or continues maturing along various pathways of hemopoietic differentiation under simple culture conditions. The erythroid character of these cells is stable during the 3-month culture period.     

Interaction of central subgerminal ooplasm with the elementary tissues (endophyll, Rauber's sickle and upper layer) of unincubated avian blastoderms in culture

By placing a central subgerminal ooplasmic mass over isolated parts (alone or in association) of unincubated avian blastoderms and culture, we obtained an improvement in, or in some cases restoration of normal development. The evolution of small rectangular fragments (isolates) excised from different regions of the unincubated blastoderm was observed in association or not with subgerminal ooplasm. The only type of differentiation that was clearly distinguished in these isolates (taken from the caudocentral area centralis region) was a so-called 'primary neurula' formed by the endophyll and an associated thickened upper layer. In the present study, we also demonstrate that after removal of the area centralis from an unincubated caudal blastoderm quadrant, the upper layer (UL) and endophyll can no longer be restored from the associated subgerminal ooplasm (and form a miniature embryo), as is the case after removal of the endophyll alone. A deep layer (containing the endophyll) reformed during the migration of Rauber's sickle-derived cells into the neighbouring central subgerminal ooplasm only in the presence of the upper layer. This suggests that the upper layer has an early influence on the cells containing the original central deep ooplasm (delta ooplasm) to form the endophyll. The present study offers supplementary arguments in favour of the hypothesis that the endophyll is an inductor of preneurulation.     

Mosaic versus regulation development in avian blastoderms depends on the spatial distribution of Rauber's sickle material

We describe how to prepare unincubated avian eggs to obtain a greater number of clearly visible Rauber's sickles for experimental embryology. After hemi-sectioning of unincubated chicken (Gallus domesticus) blastoderms and cultivating both halves in vitro, two kinds of development can be discerned: (1) when the unincubated blastoderms were hemi-sectioned according to the plane of bilateral symmetry, going through the middle region of Rauber's sickle, we obtained two hemi-embryos (a left and a right one). Each contained a half primitive streak, localized at the cut edge (starting from the most median part of Rauber's sickle) giving rise to a half mesoblast mantle and half area vasculosa, thus indicating mosaic development (each part of the whole fertilized egg would be able to form independently on its own). (2) When the unincubated blastoderm is hemi-sectioned more obliquely, going through a more lateral part of Rauber's sickle (sickle horn), two complete bilaterally symmetrically miniature embryos will form, indicating the so-called regulation phenomena. We demonstrate that these two types of development are in reality due to the different spreading and concentration of Rauber's sickle tissue (containing gamma ooplasm) around the area centralis. Embryonic regulation thus must not be considered as a kind of totipotent regeneration capacity of isolated parts of the unincubated avian blastoderm, but depends on the spatial distribution of a kind of extraembryonic tissue (Rauber's sickle) built up by the oblique uptake of gamma ooplasm (ooplasmic mosaicism) at the moment of bilateral symmetrization (Callebaut [1994] Eur Arch Biol 105:111-123; Callebaut [2005] Dev Dyn 233:1194-1216).     

Intercellular contact in the unincubated chick embryo

Summary The unincubated chick blastoderm, which consists of a complete upper epithelial layer of one cell thickness (epiblast) and an incomplete lower layer (hypoblast), was examined with the electron microscope in order to define the types of cell contact present. The terminal contacts between the cells of the epiblast invariably involved several focal tight junctions, but only occasionally involved tight junctions. Desmosomes were not observed in these areas, but were encountered in various phases of development in the deeper contact regions between epiblast cells. This deeper region also showed sporadic focal tight junctions and frequent micropapillae. These micropapillae were also common on the surfaces of hypoblast cells. Intercellular spaces between epiblast and hypoblast cells and within the hypoblast were often wide, narrowing to occasional focal tight junctions. Tight junctions and desmosomes were not observed in association with hypoblast cells. Gap junctions were not observed in any region of the embryo.These observations are discussed in relation to the morphogenetic movements occurring in the forming hypoblast and also the influence of this layer on the subsequent development of the embryo. Comparisons are drawn between the contact morphology in the unincubated blastoderm and that in later stages of development.Supported by the Medical Research Council of Canada.     

Avian sickle endoblast induces gastrulation or neurulation in the isolated area centralis or isolated anti-sickle region respectively

By the quail-chicken chimera technique, we studied, in culture, the inducing effect of sickle endoblast (derived from Rauber's sickle by centripetal and cranial migration) on the isolated Rauber's sickle-free central part of the area centralis or on the isolated Rauber's sickle-free anti-sickle region from unincubated chicken blastoderms. Just as Rauber's sickle, the flat one-cell-thick sickle endoblast (Stage 2-3, Hamburger & Hamilton, 1951) induces a primitive streak (PS) and a neural plate in the area centralis. If a vitelline membrane is interposed between the sickle endoblast and the area centralis, then a small primitive streak is still induced, suggesting the effect of a diffusible factor on PS formation. In the adjacent upper layer of an isolated anti-sickle region the apposed sickle endoblast induces only a (pre)neural plate. By contrast, this (pre)neural plate inducing effect is rapidly and totally suppressed after grafting on the anti-sickle region of whole unincubated blastoderms. This suggests dominating positional information phenomena emanating from Rauber's sickle over the whole blastoderm. After grafting sickle endoblast either on the isolated area centralis or on isolated anti-sickles, no junctional endoblast and no blood islands developed. This suggests that the differentiation of Rauber's sickle material into sickle endoblast is irreversible. Our results indicate that Rauber's sickle material under the form of sickle endoblast also influences early neurulation phenomena (at distance in space and time). The present study indicates the existence of a temporo-spatially bound cascade of gastrulation and neurulation phenomena and blood island formation in the avian blastoderm, starting from Rauber's sickle, the primary major organizer with inducing, inhibiting and dominating potencies. The latter not only plays a role by secretion of signalling molecules (positional information) but it also influences development by its cell lineages (junctional endoblast and sickle endoblast).     

A hematopoietic-specific transmembrane protein, Art-1, is possibly regulated by AML1

The functions of AML1 in hematopoietic differentiation are repressed by AML1-mutants including the AML1/ETO chimeric protein, which is seen in t(8;21) acute myeloid leukemia. Erythroid progenitors of the patients with t(8;21) AML expressed AML1/ETO. To investigate the effect of AML1/ETO in erythroid cells, we made a tetracycline-regulated AML1/ETO overexpression system in mouse erythroleukemic (MEL) cells. Enforced AML1/ETO repressed the terminal erythroid differentiation. Furthermore, we performed representational difference analysis using this MEL cell system to clone the downstream targets of AML1 in erythroid cell differentiation. We cloned a novel transmembrane protein, Art-1 (AML1-regulated transmembrane protein 1), which is a member of tetramembrane spanning superfamily. Art-1 expression was restricted in hematopoietic cells. It was upregulated by AML1 and downregulated by AML1/ETO in both erythroid and myeloid cells, and increased during erythroid cell differentiation. Art-1 may play an important role in the differentiation of erythroid cells, possibly as a direct downstream target of AML1.     

Avian pluripotent stem cells

Pluripotent embryonic stem cells are undifferentiated cells capable of proliferation and self-renewal and have the capacity to differentiate into all somatic cell types and the germ line. They provide an in vitro model of early embryonic differentiation and are a useful means for targeted manipulation of the genome. Pluripotent stem cells in the chick have been derived from stage X blastoderms and 5.5 day gonadal primordial germ cells (PGCs). Blastoderm-derived embryonic stem cells (ESCs) have the capacity for in vitro differentiation into embryoid bodies and derivatives of the three primary germ layers. When grafted onto the chorioallantoic membrane, the ESCs formed a variety of differentiated cell types and attempted to organize into complex structures. In addition, when injected into the unincubated stage X blastoderm, the ESCs can be found in numerous somatic tissues and the germ line. The potential give rise to somatic and germ line chimeras is highly dependent upon the culture conditions and decreases with passage. Likewise, PGC-derived embryonic germ cells (EGCs) can give rise to simple embryoid bodies and can undergo some differentiation in vitro. Interestingly, chicken EG cells contribute to somatic lineages when injected into the stage X blastoderm, but only germ line chimeras have resulted from EGCs injected into the vasculature of the stage 16 embryo. To date, no lines of transgenic chickens have been generated using ESCs or EGCs. Nevertheless, progress towards the culture of avian pluripotent stem cells has been significant. In the future, the answers to fundamental questions regarding segregation of the avian germ line and the molecular basis of pluripotency should foster the full use of avian pluripotent stem cells.     

Early development of the kelp fly,Coelopa frigida (Diptera). II. Morphology of cleavage and blastoderm formation

Cleavage and blastoderm formation in Coelopa frigida are extremely rapid developmental processes. In short (6–7 minutes) successive cell cycles, nuclei multiply and spread out through the egg. The movement seems to be aided by endoplasmic vesicles and cisternae which are in direct contact with the nuclear membrane. The first cells to separate from the egg plasmodium in early superficial cleavage stages are the pole cells. Precursor material from multivesicular bodies forms the pole cell membranes. The primary nuclei from the posterior pole region are removed from the blastoderm by the pole cell segregation. Blastoderm nuclei from the regions adjacent to the posterior pole migrate into the residual periplasm after pole cell segregation has been completed and constitute the blastoderm nuclei in that region of the egg. Nucleoli are not revealed during internal cleavage. They appear in pole cells shortly after their segregation. The generation time of the blastoderm nuclei increases after the twelfth cleavage. Concurrently, nucleoli form in the blastoderm nuclei and permanent cell membranes separate individual blastoderm cells. After blastoderm cells have been separated from each other, they remain in contact with the interior yolk sac by means of cytoplasmic canals. This contact is maintained at least during the early phases of blastokinesis. Observations on nuclear migration and rapid membrane formation are discussed as examples of protein assembly from subunits as an alternative to de novo protein synthesis in early stages of development.     

Inhibition by 1 alpha,25-dihydroxyvitamin D3 of dimethyl sulfoxide-induced differentiation of Friend erythroleukemia cells

Regulation of erythroid differentiation by vitamin D3 derivatives was examined in Friend erythroleukemia cells. After Friend cells were cultured for 5 days with 1.5% dimethyl sulfoxide (DMSO), as much as 70% of the cells became benzidine-positive and the hemoglobin content increased in parallel with the increase of benzidine-positive cells. The DMSO-induced erythroid differentiation was markedly inhibited by concurrent addition of the active form of vitamin D3, 1 alpha,25-dihydroxyvitamin D3 [1 alpha,25(OH)2D3]. Of the vitamin D3 derivatives tested, 1 alpha,25(OH)2D3 was the most potent in inhibiting DMSO-induced erythroid differentiation. 1 alpha,25(OH)2D3 alone was totally ineffective in both cell growth and erythroid differentiation. These results together with our previous reports indicate that 1 alpha,25(OH)2D3 is somehow involved not only in myeloid differentiation, but also in erythroid differentiation.     

Regulation of differentiation in normal and transformed erythroid cells

Summary Studies are described employing two erythropoietic systems to elucidate regulatory mechanisms that control both normal erythropoiesis and erythroid differentiation of transformed hemopoietic precursors. Evidence is provided suggesting that normal erythroid cell precursors require erythropoietin as a growth factor that regulates the number of precursors capable of differentiating. Murine erythroleukemia cells proliferate without need of erythropoietin; they show a variable, generally low, rate of spontaneous differentiation and a brisk rate of erythropoiesis in response to a variety of chemical agents. Present studies suggest that these chemical inducers initiate a series of events including cell surface related changes, alterations in cell cycle kinetics, and modifications of chromatin and DNA structure which result in the irreversible commitment of these leukemia cells to erythroid differentiation and the synthesis of red-cell-specific products. Presented in the formal symposium on Mechanisms of Cellular Control at the 28th Annual Meeting of the Tissue Culture Association, New Orleans, Louisiana, June 6–9, 1977. These studies were supported in part by grants and contracts from the National Institutes of Health (GM-14552, CA-13696, CA-18314, NO1-CB-4008 and NO1-CP-1008) and the National Science Foundation (NSF-PCM-75-08696). E.F. and R.C.R. are fellows of the Schultz Foundation; A.B. was supported in part as an American Cancer Society Scholar; J.E.S. was supported by a USPHS Medical Scientist Training Grant; and M.T. and G.M.M. are Hirschl Trust Scholars.     

Positional information by Rauber's sickle and a new look at the mechanisms of primitive streak initiation in avian blastoderms

The present experimental in vitro study suggests that a primitive streak (PS) in avian blastoderms is induced by diffusion of morphogenetic substances emanating from Rauber's sickle. Indeed, even without direct contact between a quail Rauber's sickle and the reacting upper layer (by interposition of a vitelline membrane), a PS can be induced in the isolated area centralis or antisickle region of unincubated chicken blastoderms. The so-formed PSs are localized below the vitelline membrane in the immediate neighborhood of the apposed Rauber's sickle material. This seems to indicate that Rauber's sickle organizes the formation of the avian PS according to the basic concept of "positional information." The morphogenetic substances seem to have an effect only on the formation of a PS. Each part of Rauber's sickle seems to have, point by point, the same thickening and PS-inducing effect on each corresponding part of the underlying upper layer (UL). By a mechanism of sliding over the basement membrane and fusion, this finally results in the formation of one single median PS. Our study shows that a PS can be induced in the total absence of hypoblast (sickle endoblast) or caudal marginal zone, by only the presence of Rauber's sickle material. In contrast, the differentiation of mesoblast into blood islands under the influence of Rauber's sickle and neural tissue development are impaired by the interposition of a vitelline membrane. The latter could be due to the absence of a normal interaction of Rauber's sickle-derived sickle endoblast with endophyll and/or upper layer and the absence of cranial migration of the mesoblast. Thus, earlier studies and the present study indicate the existence of a temporospatially bound cascade of gastrulation and neurulation phenomena and blood island formation in the avian blastoderm, starting from Rauber's sickle, the primary major organizer with inducing, inhibiting, and dominating potencies. The latter not only plays a role by secretion of signaling molecules, but also influences development by its cell lineages (junctional endoblast and sickle endoblast).