Differentiating cells of chick embryo hemispheres: Characterization and quantitative evaluation of the cell types and bulk preparation of enriched fractions

Summary A method of fractionation of neuroblasts and spongioblasts perikarya from developing chick embryo cerebral hemispheres is described. The tissue, treated by a mixture of acetone-glycerol-water is dissociated through a nylon sieve. Differential centrifugation on sucrose 1.3 M and 1.8 M has been used to obtain fractions enriched in neuroblasts (80% purity) and spongioblasts (90% purity). The duration of the whole operation is two hours.The evolution and distribution of the cells was studied on dissociated tissue from the 6th day of embryonic life to hatching. The proportion of neuroblasts varies from 13% at 6 days to 36% at 12 days. At the same period the proportion of the sum of indifferent cells and spongioblasts decreases from 81 to 58%, whereas the ependymal cells show little variation (6 to 9%). At hatching these proportions have not changed greatly: neuroblasts, spongioblasts and ependymal cells represent respectively 33, 65 and 2% of the total cells.The cellular differentiation proceeds from the 6th day to hatching. The size of neuroblasts increases and many of them become multipolar. The number of spindle-like cells and small indifferent cells whose origin is probably the germinal layer, decreases together with the thickness of this layer. Early spongioblasts appear only at 10 days and, later on, differentiate into oligodendroblasts and astroblasts.This study is a part of the Doctorat ès-Sciences thesis of C. Judes (Attaché de Recherche au C. N. R. S.).Chargée de Recherche au C. N. R. S.Maître de Recherche au C. N. R. S.     

An electron microscope study of cells in the matrix and intermediate laminae of the cerebral hemisphere of the 45 mm rabbit embryo

Summary The morphology and intercellular relations of cells in the matrix, lower intermediate, and upper intermediate laminae of the cerebral hemisphere of rabbit embryos was studied with the electron microscope. Models of cells reconstructed from serial sections confirm previous observations made with the Golgi technique. Most cells in the matrix lamina appear to be spongioblasts; there are relatively few neuroblasts and columnar epithelial cells. Neuroblasts predominate in the intermediate lamina. Their short processes are intercalated among axons and spongioblast processes in the lower part. A large process, the preapex, distinguishes nerve cells in the upper part of the intermediate lamina, and its orientation in the direction of movement suggests that it may actively participate in the migration of neuroblasts.Serial section analysis confirms the fact that mitotic cells in the matrix lamina are spherical and have no processes. Assuming that neuroblasts are incapable of further division, it seems probable that intermitotic germinal cells have the form of spongioblasts and columnar epithelial cells and that they give rise to neuroblasts and other spongioblasts.Supported by a postdoctoral fellowship from the United Cerebral Palsy Research and Educational Foundation and a United States National Institutes of Health fellowship No. NB 28,013—Olal.     

Early cytological differentiation in the cerebral hemisphere of mice

Summary 1. The parietal region of the telencephalic vesicle of mice embryos and newborn mice has been studied electronmicroscopically. Special attention has been paid to developing glia cells. 2. In early stages it is impossible to differentiate neuroblasts from glioblasts. 3. Late pre-natal stages allow a recognition of glioblasts on account of their ultrastructure, as the overall structure of the nucleus and the cytoplasm of a glioblast has a greater electron-density than that of a neuroblast. 4. Glioblasts have a lobulated nucleus at this stage (20th day i.u.) while neuroblasts possess an ovoid nucleus. The quantity of endoplasmic reticulum and of the number of ribosomes is relatively greater in neuroblasts than in glioblasts.We gratefully acknowledge the support of the Deutsche Forschungsgemeinschaft (Gl. 28/4) and Stiftung Volkswagenwerk.     

Ultrastructure of the sympathetic paravertebral ganglia in rat embryogenesis. I. Cytogenesis and cell differentiation

The development of sympathetic paravertebral ganglia was studied in rat embryos by electron microscopy. The main attention was paid to the initial stages of ganglion formation. The first aggregations of presumptive ganglionic cells were observed in 12 day-old embryos. Single preganglionic terminals appeared in contact with cell bodies sometime later. The appearance of large granular vesicles in the cytoplasm is the first ultrastructural feature of the beginning of neural differentiation of cells. Small granulated cells observed from the 12th day of gestation and neuroblasts differentiate earlier than glial cells. In the ganglia of late fetuses nerve cells varied in the electron density of the cytoplasm, in the degree of distention of rough endoplasmic reticulum and in vacuolization of mitochondria.     

Neuronal cell-surface specific antigen(s) is expressed during the terminal mitosis of cells destined to become neuroblasts

By immunizing mice with cells from embryonic chick motoneuron cultures, an antiserum was produced which recognizes an antigen(s) restricted to cell surfaces of most, or all, neurons. With the use of this antiserum, the appearance of neuron-specific antigenicity in cells of the embryonic spinal cord was examined by indirect immunofluorescence microscopy. The antigen or set of antigens reacting with this antiserum was first detectable in the neural tube of chick embryos at stage 15–16 (V. Hamburger and H. L. Hamilton, 1951, J. Morphol.88, 49–92). In addition to the neuroblasts located in the mantle layer, some mitotic cells as well as some spindle-shaped cells in the germinal layer were antigen positive. Immunofluorescence microscopy combined with autoradiography revealed that none of the antigen-positive cells could be labeled with [³H]thymidine; thus they do not synthesize DNA, and none of the cells in the DNA synthetic phase expressed the antigen(s). As the neuroblasts do not synthesize DNA after they have differentiated from the germinal cells, we believe that the antigen-positive cells are differentiated elements and that the differentiation of membranes specific for neurons begins already before or during the terminal mitosis of cells which will be defined as neuroblasts.     

Autoradiographic studies on the distribution of labeled maternal RNA in early mouse embryos

Maternal RNA of mouse eggs and embryos was labeled by exposure of growing ovarian oocytes to 3H-uridine in vivo 8 to 16 days before ovulation and fertilization. Labeled embryos from the 1-cell stage to the blastocyst stage were collected, fixed, and autoradiographs of plastic sections prepared. The observed grain density was similar in the pronuclei and in the cytoplasm of 1-cell embryos. Knowing the volumes of nucleus and cytoplasm, it was determined that 3% of the maternal RNA was found in the pronuclei. It is suggested that some of this nuclear RNA may be stable small nuclear RNAs (e.g. U1 RNA) retained from the germinal vesicle stage through meiotic maturation. During the 2-cell stage and beyond, maternal RNA is degraded and labeled precursor is reincorporated into nuclear RNA, making it difficult to accurately quantitate the amount of nuclear maternal RNA. It is known that about one third of the total maternal RNA is lost between the 8-cell and blastocyst stages. It was found that cytoplasmic grain densities in inner and outer cells of the morula and blastocyst were not significantly different. Thus, the loss of maternal RNA does not proceed more rapidly in the differentiating trophoblast than in the inner cell mass.     

Kinetic and morphological analysis of the preferential adhesion of chick embryo neuronal cells to astroglial cells in culture

Dissociated cells (mainly neuroblasts) obtained from brain hemispheres of chick embryos adhere to a preformed layer of chick brain astroglial cells faster and to a greater extent than to a layer of chick fibroblasts. At the begining of the experiment the adhered neuroblasts are dispersed on both layers but within a short time neuroblasts on a fibroblast layer migrate, form clusters and only later on begin to differentiate; in contrast those on an astroglial layer remain dispersed and differentiate rapidly. In both cases a number of cells of each inoculum do not adhere to either cellular layer, but these cells do not differ morphologically from those which adhered. Adhesion of neuroblasts to astroglial layers and that to fibroblast layers appear to follow the kinetics of an irreversible one-step reaction in pseudo-first-order conditions only for the first 50 and 60 min respectively. The departure from linearity of the kinetics after these times does not correspond, however, to the occurrence of second-order conditions. Other possible mechanisms of adhesion which could explain the experimental data are compared with those expected for different kinetic mechanisms. A model in which cell adhesion is treated in terms of affinity between receptor and ligands is used to analyse the nature of cell-cell adhesion.     

Somatic nucleus remodelling in immature and mature Rassir oocyte cytoplasm

Successful production of cloned animals derived from somatic cells has been achieved in sheep, cattle, goats, mice, pigs, rabbits, etc. But the efficiency of nuclear transfer is very low in all species. The present study was conducted to examine somatic nucleus remodelling and developmental ability in vitro of rabbit embryos by transferring somatic cells into enucleated germinal vesicle (GV), metaphase I (MI) or metaphase II (MII) oocytes. Microtubules were organized around condensed chromosomes after the nucleus had been transferred into any of the three types of cytoplasm. A bipolar spindle was formed in enucleated MII cytoplasm. Most of the nuclei failed to form a normal spindle within GV and MI cytoplasm. Some chromosomes scattered throughout the cytoplasm and some formed a monopolar spindle. Pseudopronucleus formation was observed in all three types of cytoplasm. Reconstructed embryos with MI and MII cytoplasm could develop to blastcysts. Nuclei in GV cytoplasm could develop only to the 4-cell stage. These results suggest that (1) GV material is important for nucleus remodelling after nuclear transfer, and (2) oocyte cytoplasm has the capacity to dedifferentiate somatic cells during oocyte maturation.     

Oogenesis in the tropical land crab,Gecarcinus lateralis (Freminville)

Summary The ovaries of small and large adult Gecarcinus were studied histologically and histochemically at various stages in the annual cycle. At all seasons of the year, dividing cells are seen within germinal nests in the ovary. Following division, the cells within the germinal nest enlarge and appear to move out into the stroma, forming cords of young oocytes that become encapsulated by follicle cells. Glycogen, not demonstrable in cells within the germinal nests, is present in the perinuclear cytoplasm of both young and mature oocytes. Lipid is distributed peripherally in the cytoplasm of the oocytes. Deoxyribonucleoprotein is demonstrable within the nuclei of germinal nest cells and of the young oocytes; it is not detectable within the nuclei of the large oocytes. The histological observations suggest that oogenesis occurs throughout the reproductive life of Gecarcinus.Dedicated to Professor Berta Scharrer on her 60th birthday in love, respect and admiration. — This work was supported in part by U.S.P.H.S. Training Grant GM-102.I express my thanks to the late Dr. Helen W. Deane and Dr. Dorothy E. Bliss for their help and encouragement.     

Germinal vesicle material is essential for nucleus remodeling after nuclear transfer

Successful cloning by nuclear transfer has been reported with somatic or embryonic stem (ES) cell nucleus injection into enucleated mouse metaphase II oocytes. In this study, we enucleated mouse oocytes at the germinal vesicle (GV) or pro-metaphase I (pro-MI) stage and cultured the cytoplasm to the MII stage. Nuclei from cells of the R1 ES cell line were injected into both types of cytoplasm to evaluate developmental potential of resulting embryos compared to MII cytoplasmic injection. Immunocytochemical staining revealed that a spindle started to organize 30 min after nucleus injection into all three types of cytoplasm. A well-organized bipolar spindle resembling an MII spindle was present in both pro-MI and MII cytoplasm 1 h after injection with ES cells. However, in the mature GV cytoplasm, chromosomes were distributed throughout the cytoplasm and a much bigger spindle was formed. Pseudopronucleus formation was observed in pro-MI and MII cytoplasm after activation treatment. Although no pronucleus formation was found in GV cytoplasm, chromosomes segregated into two groups in response to activation. Only 8.1% of reconstructed embryos with pro-MI cytoplasm developed to the morula stage after culture in CZB medium. In contrast, 53.5% of embryos reconstructed with MII cytoplasm developed to the morula/blastocyst stage, and 5.3% of transferred embryos developed to term. These results indicate that GV material is essential for nucleus remodeling after nuclear transfer.     

A comparative histochemical study of fish (Channa maruleus) and amphibian (Bufo stomaticus) oogenesis

Summary Comparative histochemical studies on the fish (Channa maruleus) and amphibian (Bufo stomaticus) oogenesis demonstrate a great similarity in the growth and differentiation of their egg follicle. The ooplasm, germinal vesicle and egg-membranes show distinct morphological and cytochemical changes during previtellogenesis and vitellogenesis.During previtellogenesis the various components of the follicle are engaged in the synthesis of protoplasm as shown by the proliferation of yolk nucleus substance, mitochondria and some lipid bodies in the ooplasm and of nucleoli in the germinal vesicle. The substance of the yolk nucleus consisting of proteins, lipoproteins and RNA first appears adjacent to the nuclear membrane. Numerous mitochondria of lipoprotein composition, and some lipid bodies consisting of unsaturated phospholipids lie in association with the yolk nucleus which forms substratum for the former. The lipid bodies, present inside the germinal vesicle, follicular epithelium, and adjacent to the plasma membrane in association with some pinocytotic vacuoles, have been considered to play a significant role in the active transport of some substances from the environment into the ooplasm and from the latter into the germinal vesicle. The follicular epithelium itself is very poorly developed, negating its appreciable role in the contribution of specific substances into the oocyte, which seem to be contributed by the germinal vesicle showing a considerable development of nuclear sap, basophilic granules and nucleoli consisting of RNA and proteins; many large nucleoli bodily pass into the cytoplasm during the previtellogenesis of Channa, where their substance is gradually dissolved. The intense, diffuse, basophilic substance of the cytoplasm is believed due to free ribosomes described in many previous ultrastructural studies.During vitellogenesis, the various deutoplasmic inclusions, namely carbohydrate yolk, proteid yolk and fatty yolk, are deposited in the ooplasm. The carbohydrate yolk bodies rich in carbohydrates originate in association with the plasma membrane and correspond to vesicles and cortical granules of previous studies. The proteid yolk consisting of proteins and some lipoproteins, and fatty yolk containing first phospholipids and some triglycerides and then triglycerides only are deposited under the influence of yolk nucleus substance, mitochondria and cytoplasm. The mitochondria and yolk nucleus substance foreshadow in some way the pattern of these two deutoplasmic inclusions and persist at the animal pole of mature egg while the other inclusions of previtellogenesis disappear from view. The pigment granules, which also show a gradient from the animal to vegetal pole in Bufo, are also formed in association with yolk nucleus substance and mitochondria. Some glycogen also appears in both the species. The nuclear membrane becomes irregular due to the formation of lobes. The lipid bodies of the germinal vesicle come to lie outside the nuclear membrane, suggesting active transport of some substances into the ooplasm; many nucleoli bodily pass into the ooplasm of Bufo, where they are gradually absorbed. The amount of basophilic granules is considerably increased in the germinal vesicle during vitellogenesis. Various egg-membranes such as outer epithelium, thin theca, single-layered follicular epithelium, zona pellucida or vitelline membrane surround the vitellogenic oocytes. The zona pellucida formed between the oocyte and follicle cells consists of a carbohydrate-protein complex. The follicle cells show lipid droplets, mitochondria and basophilic substance in their cytoplasm. The various changes that occur in the components of the follicle during vitellogenesis seem to be initiated by gonadrotrophins formed under the influence of specific environmental conditions.The author wishes to express sincere appreciation and gratitude to Dr. Gilbert S. Greenwald, who has made the completion of this investigation possible.Ph. D. Population Council Post-doctoral Fellow.     

Intracellular transport of nuclear ribosomal RNA in Acetabularia mediterranea]

The ribosomal RNA transport from a nucleus to a perinuclear cytoplasm and its following distribution in the cytoplasm of Acetabularia mediterranea cells were studied using transplantation of RNA-labeled rhizoid into unlabeled stalk. In addition rifamycin treatment was used for inhibition of cytoplasmic RNA synthesis. Acetabularia nuclei contain the stable RNA fractions similar to those present in some other eukaryotes. Nuclear 25S and 17S ribosomal RNA rapidly enter the rhizoid cytoplasm whereas the following trasfer of them to other regions of the cell is a very slow process. Within two days only an insignificant part of 25S and 17S ribosomal RNA is transferred from the rhizoid to the stalk and is distributed there over the base-apical gradient. No preferential transfer of the nuclear ribosomal RNA to the apical region was observed.     

Stimulation of fibrillogenesis in granulation tissue]

RNA synthesis by fibroblasts in healing wounds of mice and passage of the newly-formed RNA from the nucleus into the cytoplasm were studied in control mice and those treated by potassium orotate. Potassium orotate accelerated the passage of the RNA from the nucleus into the cytoplasm of the fibroblasts. Formation and maturation of the collagen fibrils in the wounds were studied by scanning electron microscope.     

雌激素受体α和β亚型在文昌鱼神经系统、哈氏窝和性腺中的定位

用兔抗人ER-α和ER-β多克隆抗体对文昌鱼神经系统、轮器哈氏窝和性腺进行免疫细胞化学的定位研究。结果揭示幼年和成年两性不同发育时期文昌鱼在这些部位分布ER-α和ER-β蛋白。ER-α定位在端脑、中脑、后脑和神经管中大多数神经细胞核,少数在胞质及其突起和神经纤维,ER-β则定位在细胞质或细胞膜上,少数在核内。ER—α免疫阳性物质主要分布在哈氏窝下层的上皮细胞核,少数在上层细胞质,β受体则在上层细胞核。在性腺,ER-α分布在卵巢中卵原细胞和小生长期卵母细胞胞质与核仁,生发泡(核)显免疫阴性,在大生长期卵母细胞核膜和核仁的免疫阳性显著增强,成熟期则在卵细胞生发泡表达,ER-β免疫阳性物质分布在卵原细胞和早期卵母细胞质以及成熟卵细胞的卵被膜检测到,生发泡显免疫阴性。在精巢,这两种ER亚型均定位在精原细胞、初级与次级精母细胞和足细胞质,精子细胞在胞核,精子显免疫阴性。另外,双染结果还揭示ER-α和ER-β在上述部位多数共存于同一细胞,少数在不同细胞表达,且在细胞定位有不同。首次发现这两种雌激素受体亚型在文昌鱼有广泛分布,它们介导雌激素对文昌鱼神经内分泌组织的调节作用。α和β受体在靶细胞定位的不同,提示两者在介导雌激素信号路线和基因转录机制可能有不同生理作用。     

Synthesis of serum proteins by the posthaematopoietic feline yolk sac

Summary The feline yolk sac persists even after the end of its haematopoietic phase with prominent ER-cisternae in the endoderm suggesting biosynthetic capacity. Therefore, yolk sac explants from the 54th day and 57th day were incubated with [³H]-l-leucine in order to study its protein biosynthesis. Newly synthesized proteins were discovered in sliced SDS-polyacrylamide gels by the use of scintillation technique and identified by molecular weight determination and isoelectrofocusing, also using stained electropherograms of unlabeled tissue, serum, and marker proteins. The highest radioactive incorporations were found in 69,000–70,000 dalton proteins and interpreted as serum albumin and -fetoprotein. The autoradiography revealed that the cytoplasm of the endoderm is the site of the most active biosynthesis of proteins which were obviously stored in the ER-cisternae for some time. The yolk sac fluid proteins are almost exclusively serum proteins, although in a very low concentration. We regard a large-scale formation of serum proteins in the yolk sac endoderm as the cause of this organ's very late regression in the cat.     

The effect of serum starvation on the efficacy of the nuclear reprogramming of rabbit embryonic fibroblasts

Successful transplantation of mammalian nuclei from differentiated cells has become possible after the application of original methods directed at the synchronization of cell cycles of the donor cell and recipient cytoplasm. We obtained a line of rabbit fetal fibroblasts which was used to study factors affecting the success of reprogramming. The nuclei of fetal fibroblasts (up to the 10th passage inclusive) proved to be capable of reprogramming and ensuring development of the cloned embryos until the preimplantation stages. The influence of synchronization of the cell cycles of the nucleus donor and recipient on the efficiency of reprogramming was studied. The rate of development of the cloned rabbit embryos to the morula-blastocyst stage reached 67% when the nuclei used were from stationary culture cells (G0-phase).     

In vitro culturing and characteristics of transit amplifying epithelial cells from human prostate tissue

The prostatic epithelium is functionally organized in stem cell units. This unit consists of a slow turn over stem cell within the basal epithelial layer which can replenish itself and provide progeny which differentiate down either a neuroendocrine or exocrine pathway. The maturation along the exocrine pathway initially involves transit amplifying cells within the basal layer proliferating and subsequently the progeny maturing into intermediate cells. These intermediate cells migrate into the luminal layer where they terminally differentiate into non-proliferative secretory luminal cells which express prostate specific differentiation markers, like PSA. A growing body of experimental evidence has identified the proliferating transit amplifying/intermediate cells as the cells of origin for the common prostatic adenocarcinomas. Using a series of growth characteristics, and mRNA and protein markers, we have validated that primary cultures can be established in serum free defined media from surgically resected human prostates which are composed of essentially pure population of transit amplifying cells. At each serial passage, the subsequent cultures undergo enhanced maturation into intermediate cells and by the 7-10th passage these cells eventually lose their proliferative ability. This study validates that these cells are a useful and relevant system for the determination of molecular events involved in prostatic carcinogenesis.     

Architecture and cell types of the adult subventricular zone: In search of the stem cells

Neural stem cells are maintained in the subventricular zone (SVZ) of the adult mammalian brain. Here, we review the cellular organization of this germinal layer and propose lineage relationships of the three main cell types found in this area. The majority of cells in the adult SVZ are migrating neuroblasts (type A cells) that continue to proliferate. These cells form an extensive network of tangentially oriented pathways throughout the lateral wall of the lateral ventricle. Type A cells move long distances through this network at high speeds by means of chain migration. Cells in the SVZ network enter the rostral migratory stream (RMS) and migrate anteriorly into the olfactory bulb, where they differentiate into interneurons. The chains of type A cells are ensheathed by slowly proliferating astrocytes (type B cells), the second most common cell type in this germinal layer. The most actively proliferating cells in the SVZ, type C, form small clusters dispersed throughout the network. These foci of proliferating type C cells are in close proximity to chains of type A cells. We discuss possible lineage relationships among these cells and hypothesize which are the neural stem cells in the adult SVZ. In addition, we suggest that interactions between type A, B, and C cells may regulate proliferation and initial differentiation within this germinal layer. © 1998 John Wiley & Sons, Inc. J Neurobiol 36: 234–248, 1998